TO
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PROTECTION INMALAYSIA Editor
Dato' HamzahBin Abu Bakar DirectorGeneral Fire and RescueDepartmentMataysia
Thisbookis published by: The Institutionof Fire Engineers(uK) MalaysiaBranch(IFEM) lnAssociation with: Fire and RescueDepartmentMalaysia(JBpM) PertubuhanAkitek Malaysia(pAM) Institutionof EngineersMalaysia(lEM) Associationof GonsultingEngineersMalaysia(AGEM) ill
This book is publishedby: @ The Institution of Fire Engineers (UK) Malaysia Branch (IFEM) 28 Jalan31154,TamanBukitAnggerik,Cheras,56000Kuala Lumpur,Malaysia Tel: +603-91012255 Fax: +603-91017700 Web: www.ife.org.my Email:
[email protected] Firstedition:October1999 Reprint:January2000 Secondedition:March2006 All rightsreserved.No partof thispublication maybe reproduced or transmitted in anyformor by any means includingphotocopying and recording, withoutthe writtenpermission of the copyrightholders,application fc whichshouldbe addressed to the publisher. Suchwrittenpermission mustalsobe obtainedbeforeany partc is storedin a retrieval thispublication systemof any nature. Everyefforthas beenmadeto ensurethe information in this guideis as accurateas possible.This subjet matteris complexand constantly changing,thusthe professionals partiesare advisedt, or otherinterested seekexpertadvicewhenfacedwithspecificproblems.
GraphicsandEditing: YC Creative CoverDesign :www.yccreative.com Printed : YCDPrint Price : RM80.00 tsBN 983€08{95_0
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This book has been made possiblethroughthe smart partnershipbetweenThe Institutionof Fire Engineers(UK) MalaysiaBranch (IFEM) and the Fire and Rescue DepartmentMataysia(JBpM) as well as professional bodies, namely, Pertubuhan Akitek Malaysia (PAM), Institution of EngineersMalaysia(lEM) and Associationof ConsultingEngineersMalaysia(ACEM).
1st Edition(October1999) Main Working Committee 1. Prof.DatukDr Soh Chai Hock 2. PPjBTuan HjZurkarnainbin Mohd Kassim 3. PPjB EdwinGalanTeruki 4. PgBA. Veerasundar 5. PgB K C. RajinderKumar 6. lr Chen Thiam Leong 7. Ar Paul Lai Chu 8. Ar Chee Soo Teng 9. lr Thin ChoonChai 10. lr Wong See Foong 11. MrTay Hao Giang 12. lr FuadAbas
DirectorGeneral,JBPM JBPM JBPM JBPM JBPM ACEM PAM PAM IEM IEM IFEM/MFPA UPM
Sub-Committee 1. PgkBMohdHusainbinAhmadTakin 2. PgB Hamdanbin Ali 3. ArAinonbtAli 4. Ar Chong Lee Siong 5. Ar Hui SheahMing 6. Ar Ng Kim Teh 7. lr Wong Kian Lon 8. Mr Wong Kin Wing 9. lr Wong Shu Leong 10. Mr Lock Peng Wei
JBPM JBPM PAM PAM PAM PAM ACEM ACEM ACEM ACEM
2nd Edition(March2006) Working Gommittee 1. Dato Hamzahbin Abu Bakar 2. Dato Wan Mohd Nor bin tbrahim 3. PKPjBSoimanJahid 4. PKPAhmad lzram bin Osman 5. TPjB MohammedHamdanWahid 6. PKP HjZurkarnianbin Mohd Kassim 7. Mr Tay Hao Giang B. Ar Chee Soo Teng 9. lr ChenThiamLeong 10. lr WongSee Foong 11. Ar Chong Lee Siong 12. N LooCheeKeong
DirectorGeneral,JBPM JBPM JBPM JBPM JBPM JBPM IFEM PAM ACEM IEM PAM PAM
It is my pleasureto pen this forewordfor the second edition of the "Guide to Fire protection in Malaysia".I am especiallypleasedto note that this publicationby The Institution of Fire Engineers (UK) MalaysiaBranchis a productof joint effortbetweenIFEM, the Fire and Rescue Department Malaysiaand the key players in the Fire and Safety Engineeringprofessionals. This fire safety engineeringGuide book reflects the shared vision between the Fire and Safety Engineering Professionalswith the Governmentof Malaysia in respect of the importance of transparency, constantimprovement,innovationand smart partnerships. This "Guide" is an invaluablesource of referenceto all those who are involved in Fire Safety Engineeringand fire protectionindustry.Be it students,academicians,practicingprofessionals, -rnanufacturers, local authorities,Fire and Rescue Departmentpersonnels,fire equipment suppliersor contractors.The second edition of the "Guide to Fire protection in Malaysia,,will clarifythe intentand interpretation of the Fire Safetyaspectsof the UniformBuildingBy-lawsto all the users, and in so doing, bring about consistencyand efficiencyin the industry to benefitthe membersof the public. In this age of globalization,it is imperativethat we all embracechanges as a way of life. lt is also inevitablethat we also have to evolve new legislationto take into consideration the understanding of fire science and technologywhich requires a rethink of conventional solutionsto fire safety for now and the future. once again' I wish to congratulateDato HamzahAbu Bakar, Director General of the Fire and RescueDepartmentMalaysia,his able officersand the team of dedicated local professionalsfrorn The Institutionof Fire Engineers (UK) Malaysia Branch (IFEM), pertubuhan Akitek Malaysia (PAM), Associationof ConsultingEngineersMalaysia (ACEM) and lnstitutionof Engineers Malaysia(lEM) on their commendableeffortsin bringingthis second Editionof the ,,Guideto Fire Protectionin Malaysia"to fruition.
Y.B. DATO'SERI ONG KA TING Ministerof Housingand LocalGovernment
As we move towards acquiring Developed Nation Status, it is essential that in forging ahead to achieve the necessarybenchmarks,we do not forget to continuedevelopingand enhancingour existing infrastructure. Just as new Standardsand Codes are being writtenfor the Buildinglndustry,existingStandards, Guides and Codes have to be reviewed to catch up with changing trends, technology and knowledge. The effort by The lnstitutionof Fire Engineers(UK) MalaysiaBranch and the Fire and Rescue Departmentin updatingthe 2nd Editionof "Guideto Fire Protectionin Malaysia"is commendable, taken into considerationthe time and effort contributedby all authors, officers and the fire safety engineeringprofessionalsover the last few years. Among the changes are - Chapters 15 on Smoke Control System that has been updated with the publicationof the latest MalaysianStandards 1780; entire passive Fire protectionSystem chapter illustrationshas been upgraded from 2-dimensionalto 3-dimensionaldiagrams for ease of understandinglActiveFire ProtectionSystem chapter 5 on Portable Fire Extinguishershad been rewrittenwith the introductionof PerformanceBased MalaysianStandard 1539. The "Guideto Fire Protectionin Malaysia"entailsdesignconcepts,standardand code, guidelines, charts,diagramsand illustrations,systemcheck list, testingand commissioningcheck lists which are very comprehensivefor any fire safety engineering professionals,fire officers and industrial players.This will serve as a common platformfor all fire industrypractitionersto obtain a common understandingand interpretationof the Uniform BuildingBy-laws. Hence, I will like to congratulate and thank all parties concerned for their meticulous effort in making it possible the publication of the 2nd edition of "Guide to Fire protection in Malaysia". Specialcreditshouldgo to Yang Berbahagia(Professor)Datuk(Dr.)Soh Chai Hock (Hon. FlFireE) for initiatingthis project and the Chief Editor for the first edition of "Guide to Fire protection to Malaysia" I will like to express my sincere gratitudeto Yang Berhormat Dato' Seri Ong Ka Ting, Minister of Housingand Local Government,who has been instrumentaland supportiveof Fire and Rescue Department'smission in pursuing world class excellencenot only in fire and rescue operation but also in the fonnrarddirectionof fire safety engineeringfield of technicalstudies and applications.
DATO'HAMZAH BINABU BAKAR DirectorGeneral Fireand RescueDepartment Malaysia
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Forewordby YB Dato'Seri Ong Ka Ting Ministerof Housing& LocalGovernment 1.
Prefaceby DirectorGeneralJBPM Dato'Hamzahbin Abu Bakar
2.
Introduction
3. 3.1. 3.2. 3.3. 3.4. 3.5. 3.6. 3.7. 3.8. 3.9.
Understanding Fire Science lgnition,GroMh and Developmentof Fire Principlesof Fire Propagation Fire Protectionin Buildings Fire HazardsAssessment Good BuildingDesignwith Fire SafetyMeasures ExistingStructureand HistoricalBuildings Fire and The Law Conclusion
VI
vrl
BasicGonceptsof Fire Science& the BuildingConstruction
4.
PassiveFire Protection
4.1. 4.1.1. 4.1.2. 4.1.3. 4.1.4.
PurposeGroups PurposeGroupsand Compartments ShoppingCentresand Shop Compartments Atriums MixedUse Buildings
10
4.2. 4.2.1. 4.2.2. 4.2.3. 4.2.4.
Fire Appliance Access DesignNotes AccessConsiderations PerimeterApplianceAccess lllustrations HydrantLocations
20
4.3. 4.3.1. 4.3.2. 4.3.3. 4.3.4. 4.3.5. 4.3.6. 4.3.7. 4.3.8.
Walls and Floors PartyWalls Recessand Chases Separating/ CompartmentWalls and Floors Stagesin Placesof Assembly Horizontaland VerticalBarriersof the ExternalWall ProtectedServiceShafts Claddingon ExternalWall Referenceto SixthSchedule
28
4.4. 4.4.1. 4.4.2. 4.4.3. 4.4.4. 4.4.5. 4.4.6. 4.4.7.
Means of Escape ExplanatoryNotes BasicPrinciples of Design Meansof Escape Measurementof TravelDistanceto Exits Arrangementof StoreyExits Staircases SmokeLobbies
47
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4.4.8. 4.4.9. 4.4.10. 4.4.11. 4.4.12.
Buildingwith SingleStaircase Protectionfor ExternalEscapeStaircase Handraits EscapeProvisionComputation Seatingin Placesof Assembty
4.5.
Rules of Measurement
16
Appendix1 SpecificationsoJ FireAppliancesfor the Purposeof Designingfor FireAccess for Fire RescueVehicles Active Fire protectionSystem
at
89
5. 5.1. 5.2.
PortableFire Extinguishers Description Design Requirements
5.3.
VisualInspectionChecklist
6. 6.1. 6.2. 6.3. 6.4. 6.5. 6.6. 6.7.
External Fire Hydrant System Description DesignRequirements TestRequirements Maintenance Requirements DesignChecklist VisualInspection Checklist TestingandCommissioning Checklist
gT
7. 7.1. 7.2. 7.3. 7.4. 7.5.
Hose Reel System Description DesignRequirements DesignChecktist VisualInspection Checklist TestingandCommissioning Checklist
105
8. 8.1. 8.2. 8.3. 8.4. 8.5. 8.6. 8.7.
Dry Riser System Description DesignRequirements TestRequirements Maintenance Requirements DesignChecklist VisualInspection Checklist TestingandCommissioning Checklist
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9. 9.1. 9.2. 9.3. 9.4. 9.5. 9.6. 9.7.
Wet Riser System Description DesignRequirements TestRequirements Maintenance Requirements DesignChecklist VisualInspection Checklist Testing andCommissioning Checklist
115
90
IX
123
10. . 10.1
DowncomerSystem DescriPtion
10.2. 10.3. 10.4. 10.5. 10.6. 10.7.
DesignRequirements TestRequirements Requirements Maintenance DesignChecklist Checklist VisualInspection Checklist TestingandCommissioning
11. 11.1. 11.2. 11.3. 11.4. 11.5. 11.6. 11.7.
Automatic Sprinkler System DescriPtion DesignRequirements TestRequirements MaintenanceRequirements DesignChecklist Checklist Visuallnspection Checklist TestingandCommissioning
128
12. 12.1. 12.2. 12.3. 12.4. 12.5.
Automatic GOz Extinguishing System Description DesignRequirements DesignChecklist Checklist Visuallnspection Checklist TestingandCommissioning
142
13. 13.1. 13.1.1. 13.1.2. 13.1.3.
Automatic Fire Detection and Alarm System General SystemConcept DesignRequirements DesignChecklist
151 152
13.2. 13.2.1. 13.2.2. 13.2.3. 13.2.4.
Controland IndicativeEquipment Concept DesignRequirements TestingandCommissioning DesignChecklist
155
13.3. 13.3.1. 13.3.2. 13.3.3. 13.3.4.
AudioandVisualAlarm Concept DesignRequirements TestingandCommissioning DesignChecklist
159
13.4. 13.4.1. 13.4.2. 13.4.3. 13.4.4.
ManualcallPoints(MCP) Concept DesignGuidelines TestingandCommissioning Checklist
161
13.5. FireDetectors 13.5.1. Concept 13.5.2. DesignGuidelines 13.5.3. Testing andCommissioning 13.5.4. Checktist
162
13.6. PowerSupply 13.6.1. Concept 13.6.2. DesignRequirements 13.6.3. Testing andCommissioning 13.6.4. Checklist 13.7. 13.7.1. 13.7.2. 13.7.3. 13.7.4.
167
Gablesand Wirings Concept DesignRequirements Testingand Commissioning Checktist
173
13.8. VoiceAtarmSystem(VAS) 13.8.1. Concept 13.8.2. DesignRequirements 13.8.3. TestingandCommissioning 13.8.4. Checktist
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14. 14.1. 14.2. 14.3. 14.4. 14.5. 14.6. 14.7. 14.8. 14.9.
PressurisationSystem in Buildings Description DesignRequirements SystemComponent pressurisation Typesof Staircase SystemDesign Typesof Lift Lobbypressurisation SystemDesign TestRequirements Designand Installation Checklist Calculation procedures Testingand Commissioning
15.
199
15.1. 15.2. 15.3. 15.4. 15.5.
Smoke Gontrolsystem Using Natural(Displacementlorpowered (Extracted)Ventilation Description DesignRequirements Applications Calculation procedures Testing and Commissioning
16. 10.1. 16.2. 16.3. 16.4. 16.5. 16.6.
Fire Lift Description DesignRequirements TestingRequirements Maintenance Requirements DesignChecktist Testing andCommissioning Checklist
223
XI
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229
17. 17.1.
EmergencyPowerSYstem DescriPtion
17.2 17.3. 17.4. 17.5. 17.6. 17.7.
DesignRequirements TestRequirements MaintenanceRequirements DesignChecklist VisualInspectionChecklist Testingand CommissioningChecklist
18.
Fire Engineering- PerformanceBasedApproach
18.1. 18.2. 18.3. 18.4. 18.5. 18.6. 18.7. 18.8. 18.9. 18.10.
ConcePt DesignRequirements Fire SafetyEngineerRequirements Scopeof Fire Engineering- PerformanceBasedApproach Exclusionof Fire Engineering- PerformanceBasedApproachApplication Fire Engineering- PerformanceBased (FEPB)Report Approval Peer Reviewer Decision Legallmplication
19.
MalaysianIncidentCommandStructure(MICS)
19.1. 19.2. 19.3. 19.4. 19.5. 19.6. 19.7. 18.8.
Introduction UnifiedCommandand Control "lCS" OperationRequirements The Main Organisationand Operation EmergencyResponsePlan IndustrialFacility BulletPointsin ERP Strategies Conclusion
20. 20.1.
Fire ServicesAct 1988(ACT341) lntroduction
20.2. 20.3. 20.4. 20.5. 20.6. 20.7. 20.8. 20.9. 20.10. 20.11. 20.12. 20.13. 20.14. 20.15.
Preambleof theAct of FireServicesDepartment Establishment of the FireServices DutiesandResponsibilities FireHazard Compounding Abatementof Fire-Hazard Order Prohibitory Orderto CeaseActivity Closing Order SpecialPowerof FireOfficers of FireOfficers Protection Act MadeUnderThe FireServices Regulation Penalty Conclusion
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239
245
253
Historical Background - tJniform Building By-taws 1gg4 (UBBL 1gg4)
2.1 INTRODUCTION In the early 50's it was very difficultfor architects,engineersand buildingdesignersto submit standarddesign buildingplans to the variouslocal authoritiesand districtcouncilsin the country. In 1957, the Federationof Malaya Society of Architects- predecessorof pertubuhan Akitek Malaysia(PAM) approachedthe Ministryof Natural Resourcesand Local Government(Ministry o f H o u s i n ga n d L o c a l G o v e r R m e n t t)o u p d a t e t h e U n i f o r m B u i l d i n gB y l a w s t o r e p t a c et h e various outdated LocalCouncilBuildingBy-lawsand SanitaryBoardsOrdinances. The updatingof the UniformBy-lawswas not given priorityuntil May 1969 when the National S e c u r i t yC o u n c i ld i r e c t e dt h e s t a n d i n gc o m m i t t e e st o u p d a t e t h e U B B L f o r i m m e d i a t e implementation. The Kuala Lumpur Municipal(Building)(Amendment)By-laws 1975 was gazettedand between October 1976 - October 1977 a special UniformBuildingand Municipal(Building)(Amendment) By-laws 1985 was drafted. The standingcommitteessought clarificationand advice from various professionalbodies such as Fire OfficersCommittee(FOC) UnitedKingdom- predecessorof Loss preventionCouncil(LpC), AmericanSocietyof Heating,Refrigeratingand Air ConditioningEngineers(ASHRAE),Standards Institutionof Australia(AS),Departmentof Environmentof UnitedKingdomand other international bodies.The first draft of the UBBL was publishedunder GovernmentBill No. 1065 dated 5 April 1973 and was submittedto the Ministrybased on the result of the submissionsreceived.The presentUBBL was publishedby the governmentin 1984for implementation.
2.2 FIRE SAFETY PHILOSOPHY. UBBL 1984 Life Safety is Ultimate in Building Design C h a p t e r s7 a n d 8 o f t h e U B B L 1 9 8 4 a r e o n " F i r e R e q u i r e m e n t s " T . h e s t a n d i n gc o m m i t t e e recommendedthat life safetyof occupantsof buildingsmust be the prime considerationand this can be achievedby minimumfire protectionin respect of the various basic aspects of: . Meansof escapefor the occupants. ' spread of fire withinthe buildingand from one building to another . Meansof detectionand extinguishment of fires. The safetyof life is the ultimateprincipleof fire safetyin a building.In case of a fire in the building, the immediatehazardis to the occupantsand whilststructuralfire protectioncan be precisely defined,the requirementof adequatemeans of escape is an inexactscienceand may vary in differenttypes of occupancy,usage,process,heightand types of buildings. Means of escape for high-risebuildingscan pose new challengesto buildingdesignswhere the occupantsmust be protectedwithin the structure.To protectoccupantsfrom within,the fire must be kept small and personsin the fire area must be able to move to a safe locationwithinthe high-rise structure.
It is probablynot practicalto design buildingsthat under no circumstanceswill any occupantbe trapped in case of fire. lt is also not possibleto secure absolutesafety in buildings,generally becauseof human failureto maintainthe fire protectioninstallationsor to do the right things right when an emergencyarises.The Architects,Engineersand buildingdesignersare thereforefaced with the constraintsof balancinglife safety and fire integrityagainstpracticality,aestheticdesign and the fire regulations. Whilst it is not always possibleto achieve all the requiredfire precautionaryprinciplesin old structuresor existingbuildings,they can be appliedin new buildings. The largerthe space, the greateris the potentialarea, the greaterthe potentialfire risks and the greaterthe likelyfire loss should a fire break out. lt is often necessaryto increasethe height of buildingsin order to obtaina profitablereturnon the investmentsand everyinchof the floor area is in consequencehighlyvalued.
2.3 BUILDINGCONSIDERED AS A WHOLE PassiveandActiveFireProtection Passivefire protectionis basicallya planningmatterand must be consideredat the planningstagein the buildingdesign in terms of mitigationof fire hazardand fire risk. The selectionof fire resiiting rnaterials,sub divisionof the buildinginto fire-tightcells or compartmentsboth verticallyand horizontallyto containan outbreakof fire and spread of smoke heat and toxic fume are baslc precautionsat the planningstage. Effective passive fire precautionsrepresentgood planning, good design and sound construction, which could complementotherbasicfunctionsof a building. Active fire protection is basically the manual or automatic fire protection systems such as: fire alarms,detectors(heat & smoke)rising mains, hose reels,fire telephones,COz fixed installation, automatic sprinklersand smoke spills system etc. to give a warning of an outbreakof fire and the containmentand extinguishment of a fire.The provisionsof adequateand suitablefacilitiesto assist rescue and fire suppressionoperationsare also within the active fire defence strateqies.
2.4THENEWCHALLENGES Theoverallfire defencestrategies for development projectsin Malaysia are basedon the "Fire
Safety Philosophy"of the MalaysianUniformBuildingBy-laws 1984 where life safety is the first consideration.The fire preventionand operationalrequirementsfor both externaland internalfire suppressionmust be consideredtogether. lt must also be possiblefor the fire fightersto operate at any pointin the buildings.Facilitiesmust be builtintothe buildingsto enablethe firefightersto reach the top-mostfloors and carry out rescue and internalfire suppressionoperations.
The world's tallesttwin towers (KLCC),the Kuala Lumpur InternationalAirport,Kuala Lumpur Tower and other mega projects have created new challenges to the Architects, Engineers and buildingdesignersand Malaysianfire fighters.When these mega projectswere proposed,the professionals had to venturebeyondthe perimeterof the "UniformBuildingBy-laws1gg4"and adopt internationalfire safety guides and practicesincluding"Fire Safety EngineeringApproach"and "Performance Based Criteria".
officersvisitedmanyprojectsand highrise buildings The buildingdesignersand fire prevention Fire were also held with variousFire Strategists, the world.Technicaldiscussions throughout to determinethe mostappropriateFireCodes and Test Laboratories Chiefs,StandardInstitutions to be adoptedwithinthe frameworkof the UniformBuildingBy-laws1984. codes,coverabroadrange The UniformBuildingBy-laws1984,similartoallinternationalbuilding of buildingsand useconditionsbuttheycannotbe expectedto adequatelyreflectnewtechnology, conditions. in designanduniquebuildingor occupancy innovation recentrelevantexperience, By-law245of the UniformBuildingBy-laws1984empowersthe To addresssuchconditions, Malaysia,to acceptalternativeto the DirectorGeneralof the Fireand RescueDepartment that the is providedto demonstrate evidence where sufficient in the code contained requirements performance. provide proposedalternative will equivalentor better on fire protectionand the conceptof It is hopedthat this bookwill providea clearerunderstanding practiceand designstrategiesto buildingowners,fire officers,professionals goodfireengineering principlesof UniformBuildingBy-law1984. andstudentsin linewiththe fundamental
FIRESCIENCE 3.1UNDERSTANDING in minutesand kill Fire is essentiallya chemicalreactionknown as combustion.lt can spread it can spread can help in seconds. Knowing the characteristicsof fire and understandinghow safety and property Architects, Engineers and other professionalsto formulate strategieson life protectionin buildingdesigns. REACTION'This Four factorsare neededto starta fire FUEL,OXYGEN,HEAT and CHEMICAL 'Fire a very unchecked, to spread is allowed reaction Tetrahedron'.lf this chemical is knownas the smallfirewill quicklydevelopinto an infernoand becomecatastrophic' DiagramA: Fire Tetrahedron
Let us remember righttime."
'The world's largest fires can be extinguishedby pouring a cup of water at the
chain A fire can easily be extinguishedby removingone of the factors in inhibitingthe chemical fire on the pouring water heat by remove can we reactionof the combustionprocess. For example foam' or blanket fire a or removingthe fuel or cuttingoff oxygensupplyby using
OF FIRE GROWTHAND DEVELOPMENT 3.2 IGNITION, Diagram B: Stages of Fire Development
T m p
(STAGE3) FullyDevelopFire
r t
u e
(srAGE4) Decay
(STAGE1) GroMh Time Slow rateof burning
Developmentof heat and flames
curveof a typicalfire The time/temperature
Fire Dies Out
IGNITION- A processin which fuel reactswith oxygento give heat and light GROWTH- A fire once startedcan grow rapidlyas it createsthe conditionsfor its own growth. I n a n e n c l o s e dc o m p a r t m e n t a , c r i t i c a ls t a g e m a y b e r e a c h e dw h e r e a l l t h e c o m b u s t i o n materialsare heated to flammableconcentrationsof gases and the fire suddenly flashes "flashover" throughoutthe whole compartment- this is knownas a DEVELOPMENT- The fire passesthrougha developmentstage after the initialgroMh. During this stagethe fire temperatureincreasesslowly.Howeverthe fire continuesto spreadinto other areas,which then in turn continuesthe processof rapid initialgroMh and development. DECAY - ln the decay stage,the fire will burn itselfout due to lack of fuel or oxygen. FUEL LOAD - The amountof availableand potentiallycombustiblematerialsto fuel the fire. FLASHOVER- Simultaneousignitionof all combustiblein an enclosedarea. Flashoveroccurs when the majorityof the surface in a space are heated to the point at which they give off flammablegasesthat are hot enoughto sustaincombustion.
3.3 PRINCIPLES OF FIRE PROPAGATION Through natural laws, heat and smoke will travel from hotter to cooler areas by any of the three methods: CONVECTION- More than 75 per cent of the combustionproductsof a fire, eg. smoke, burning particles,toxic gases are dissipatedin rising convectioncurrents of hot gases at temperaturesof 800 - 1000"C.lt willcreatea "mushroomeffect",when the risingconvectioncurrentis blocked,eg. by undersideof floor or ceiling. lt can also smokelogescape routes and prevent escape. RADIATION- Radiantheat is transmittedto all buildingsor materialsthat is adjacentto and not the fire. lt is the transfer of heat energy as electromagneticwaves. Radiationpasses through normal glass windowseasily,and buildingswith many or large windows are more likelyto spreadfire to other buildings. CONDUCTION- The movementof heatthroughmaterialsvia excitationof moleculeseg. metalsare better conductorsof heat than stones. Conductedheat can travel through partitions,floors, ceiling, walls, to adjacentrooms, especiallythrough metal piping, metal frames and joists. Combustible materialsor internal linings of adjacent rooms can be heated to their ignitiontemperatureby conductedheat.
3.4 FIREPROTECTION IN BUILDINGS A totalfiresafetysystemfor anyhighrisebuilding integrity duringfire. mustincludestructural Structuralfailure when occupantsare stillin the buildingis catastrophic. The qualityof workmanship and the sustainability and durabilityof the buildingmaterialsand systemsrequireclose attention. The UBBL 1984 requiresall buildingsto have minimumstructuralintegritybased on its usage. Elementsof constructioncan only be effectiveas fire breaks if they have the necessarydegreeof fire resistance.The three criteriaof fire resistanceare:
INSULATION:The abilityof an elementof constructionto resistor inhibitthe heat. INTEGRITY:The abilityof an elementof constructionto maintainits shapeand structuralproperties and at the same time preventingthe passageof flames and hot gases. STABILITY:The abilityof an elementof constructionto maintainoverallstructuralintegrity The principalrole of structuralfire protectionis to preventthe spread of heat and smoke from the seat of fire to other parts of the building.The best way to controlspread of fire is early detection and extinguishment- and a reliableway of achievingthis is by installinga system and good housekeeping.
3.5 FIRE HAZARDS ASSESSMENT Main factors contributingto fire hazard: . The amountof combustiblematerialspresent. . The potentialheat outputof these materialsin a fire, i.e..their calorificvalue. . The surfaceareas- most materialsburn at or near their surfaces. . The potentialheat source. . Airflowconditionand unrestrictedair supplythat sustaincombustion. . The design and constructionof a building can have as much or even more effect on the developmentof a fire than the contentsof the building. The Architector Engineerhave to assess the fire hazard of the buildingarisingfrom its usage, locationand sit ing, area volume and height,number of people in the buildingand mobilityof its occupants,designand construction. Fire tests have proventhat all combustiblematerialswhen burnt,will producesome asphyxiating or poisonousgases and nearly all produce smoke which hindersvision. Many plasticmaterials producehighlypoisonousvapoursand very dense smoke.lt is importantfor buildingconsultantsto checkon the featuresof certainmaterialsbeforeinstallinginto the building.These include: . Susceptibility to heat,smoke and water damage. . The potentialfor producingburningdroplets- skylightetc. . lssue of repairafterthey have been in a fire. . lssue of maintenanceand replacement.
3.6GOODBUILDINGDESIGNWITHFIRESAFETYMEASURES ' Provideadequatefire appliancesaccess, fire hydrantsand other facilitiesto assist fire and rescuepersonnel. ' P r o v i d ea d e q u a t ef i x e d i n s t a l l a t i o n , w h e r e a p p r o p r i a t e f, o r q u i c k a n d e f f e c t i v ed e t e c t i o n and extinguishment of fires. ' Designingand installingbuildingservices so that they do not assistthe spreadof fire, smoke or toxic fumes. Designingand providingadequateand safe escaperoutesfor the occupants of the building. Selectingmaterialsfor the constructionwhich will not promote the rapid spread of fire or generatedangeroussmoke and poisonousgases. Subdividingbuildingsinto compartmentsof reasonablesizes by means of fire resistingwalls and floors, providingfire stops to protectopeningsbetween floors and compartments. Designingand constructingthe exteriorof a buildingso that fire is unlikelyto spread to it from anotherburningbuilding.
3.7EXISTING STRUCTURE AND HISTORICAL BUILDINGS It is normallyquite straightforwardfor Architectsand Engineersto comply with the various fire protectionrequirementsfor new buildings.However,it is often difficult for any buildingdesignerto meet all the legislativerequirementson fire protectionwhen it comes to upgrading of old buildings. Fire preventionofficersand professionalsshould thereforealways attempt to achieve a reasonable levelof fire precautionfor theirbuildingsto ensureadequatesafetyto occupants.For examplereduce fire resistanceof timberstructuresin historicalbuildingscould be compensated by increased/extra provisionof directiondeviceand alarmstogetherwith extra fire suspensionsystems.
3.8 FIREAND THELAW Architectsand Engineersmust rememberthat the fire safetyregulationsin Malaysia are based on internationalnorms to protectlife. However,some of the fire safety provisions in the UBBL 1984 and the Fire ServicesAct 19BBwill also offer protectionto buildingsand their contents as well as fire fighters.A sectionin this book providedetailrequirementsof the Fire Services Act 19gg. The UBBL 1984 and the Fire ServicesAct 19BBshould not be read in isolation,but shoutdbe read in conjunctionwith all relevantMalaysianand lnternationallegislationsand standards.
3 . 9C O N C L U S T ON When consideringfire protectionmeasuresfor buitdings,it is importantto understand that the safety of occupantsand fire fightersare interrelated, and thal designsolutionshouldaddressthe effectof fire, smoke and toxicfumes in totalitv.
4.1 PURPOSE GROUPS 4.1.1Purpose Groups And Compartments purposeGroups(By-law134)categorisebuildingsor compartmentswithina buildingin accordance with their uses/intendedusage or the dominantuse in accordancewith the Fifth Schedule'The intendeduse or occupancy(PurposeGroup) of a buildingor part of a buildingis a fundamental considerationof the relevantsectionsof the Uniform BuildingBy-laws in establishingminimum standardsthat need to be compliedin orderto achievea satisfactorylevelof life safetyof the users or occupants. Some buildingsexceedthe physicalsize allowablefor its designatedPurposeGroup.In that event, it is dividedinto smallercompartmentsfor Fire Safety managementreasonsto limitthe spread of fire and to restrictthe movementof smoke. Alternatively,a building,designedto accommodate differentactivitiesthat fall under differentPurposeGroupscan be dividedinto compartmentseach housingits own PurposeGroup activityto enableeach compartment'sfire safetyto be considered in relationto the risks associatedwith the differenttypes of usage.A compartmentwhen used in this Fire Safetycontextdenotesa physicallydelineatedvolumetricspaceor part of a buildingwhich is separatedfrom all other parts by one or more compartmentwalls or compartmentfloors or by such walls and floors. The anticipatedfire hazardspresentedby any buildingwill predominantlybe dictatedby the use or purposeto whichthe buildingis put to (PurposeGroup).This is influencedby the nature(residential, workingor publicgathering)and levelof occupancyof the buildingsas well as the typesof material or anticipatedfire loads used in connectionwith that type of occupancy.For example,warehouses differgreatlyfrom departmentstoreswhen it comes to the numberof anticipatedoccupantsas well as the potentialfire load of their contents.Consequently,the minimumrequirementsto ensurefire fire resistance safetysuch as meansof escapefor occupants,permissiblevolumeof compartments, relatedto directly ratingof compartmentwalls,level of fire detectionand fire fightingsystemsare theseusagegroupings.Thesedifferentprovisionsrelatingto the differentusagegroupsin turn form the basisfor both designerssuch as Architectsor Engineersand the FireAnd RescueDepartment of Malaysia(JBPM)to establishthe minimumpassivesafetyrequirementsas well as the minimum necessaryto complywith the UBBL. fire safetyinstallations The Fifth Schedule (Designationof Purpose Groups) in the UBBL (By-law 134, 138) lists the respectiveusage descriptionof each designatedPurposeGroup. Generally,PurposeGroups l, ll and lll cover groups with a Residentialelement where there is sleepingaccommodationand thereforeextradangerin the eventof fire. The remainingfive PurposeGroupscoverusagewith no (See Appendix1) sleepingaccommodation. The Second Table in the Fifth Schedule (By-law 136) lists the physicaldimensionallimits or parameters (height, area and volume) permissiblefor each building or compartmentin the respectivePurposeGroups.(See Appendix2) The PurposeGroup designationarrivedat in turn becomesthe basisfor checkingfor compliance with differentareas of Fire Safety.These are containedin the Sixth Schedule(PermittedLimitsof UnprotectedOpenings- By-laws 142 and 145),the SeventhSchedulecoveringMaximumTravel of OccupantLoadAnd Capacity 170tbl)and Calculation 167t11, 166t21, Distances(By-laws165t41, of Flame 170[c],171[c),175),the EighthSchedule(Restriction Of Exits(By-laws167121,168t21, 204,206), the NinthSchedule(LimitsOf Compartments SpreadOver Walls and Ceilings-By-laws And MinimumPeriodsOf Fire ResistanceFor Elementsof Structure- By-laws143[3],147,158L11' Alarm and the Tenth Schedule(TableOf RequirementsFor Fire Extinguishment 162,213,216121) the of UBBL. SystemsAnd EmergencyLighting By-laws226111,23711))
10
FIFTHSCHEDULE OF UBBL NumberOf PurposeGroup
DescriptiveTitle
Purpose for which building or compartment is intended to be used
I
Smallresidential
Privatedwellinghousedetachedor semidetached(not includinga flat or terracehouse) not comprisingmore than (1) a groundstorey;(2) one upperstorey;and (3) a basemenstoreyor basementstoreys
lnstitutional
Hospital,schoolor othersimilarestablishment used as livingaccommodationfor, or for treatment.care or maintenanceof, personssufferingfrom disabilitiesdue to illnessor old age or otherphysicalormentaldisability or underthe age of 5 years,where such personssleep in the premises
ill
Otherresidential
Accommodation for residentialpurposeotherthan any premisescomprisedin groups I and ll
IV
Office
Office,or premisesused for office purposes,meaning therebythe purposesof administration, clericalwork (includingwriting,book-keeping,sortingpapers,filing, typing,duplicating, machine-calculating, drawingand the editorialpreparationof matter for publication), handlingmoneyand telephoneand telegraphoperating
Shop
Shop,or shop premises,meaningtherebypremisesnot beinga shop but used for the carryingon thereof retail tradeor business(includingthe sale to membersof the publicof food or drink for immediateconsumption, retailsalesby auction,the businessof lendingbooks or periodicalsfor the purposeof grin,and the business o f a b a r b e ro r h a i r d r e s s e r a ) n d p r e m i s e st o w h i c h members of the public are invited to resort for the purposeof deliveringtheir goods for repairor other treatmentor of themselvescarryingour repairsto or othertreatmentof goods
VI
Factory
Factorymeansall premisesas definedin section2 of the Factoriesand MachineryAct 1967,but excluding t h o s e b u i l d i n g sc l a s s i f i e du n d e r p u r p o s eg r o u p V l l l - storageand genera.
vil
Placeof assembly
Place,whetherpublicor private,usedfor the attendance o f p e r s o n sf o r o r i n c o n n e c t i o nw i t h t h e i r s o c i a l , recreational,educational,businessor other activities. and not comprisedwithingroups I to Vl
vill
Storageand general Place for storage,deposit or parkingof goods and materials(including vehicles),and otherpremisesnot comprisedin groups I to Vll
11
ln the interpretationof the applicationof the Tenth Schedule,it is generallyacceptedthat the residentialportion(apartmentsand flats)is excludedfrom consideration. Of Buildings)of the UBBL allows heightof different ln mixed use buildings,By-law 215121(Height compartmentswithin a singlebuildingto be individuallyconsidered(measuredin accordancewith By-law135 of the UBBL) in compliancewith the Sixthto Tenth Scheduleswhen the compartments are separatedby continuousverticalplanes.(See Diagram4.1.4.1). Sprinklershave over time been provento be a most effectiveform of fire control.The effectivenessof automaticsprinklers(coupledwith detectors)as an earlyfire suppressionand containmentsystem in effectextendsthe evacuationtime which occupantshave to make their way to safety (By-law 136).This effectivenessin suppressingand containingfire beforeit gets out of controlis recognised. which the limitsof dimensionsfor areasand volumesin buildingsand compartments Consequently, are installedwith automaticsprinklersare allowedto be doublethat of buildingsor compartments not fittedwith sprinklersto reflectthe reducedrisks in sprinkledbuildings. 4.1.2 Shopping Centres And Shop Compartments Single DepartmentStore buildingsdevelopedand evolvedthrough retail and design innovations into buildingswhere several stores or shops open onto and are linked by a covered or roofed over "street"that combined the circulationpaths for means of egress with pedestrianroutes.Within this mall can be found a mixture of large stores or users termed Anchor Tenants (like a Department Store within a mall or complex) and smaller shops that open onto the mall. lt is generally expected that within this mall will be a mixture of other uses such as food courts and cinemas and occasionallyamusementarcades.Malls extendedverticallybecome the modern day large shoppingcomplexes. of When malls and large shoppingcomplexesbecame popular,they require{ new interpretations in bearing in size or complexity, single typology either fit into any nature did not the UBBL as their in mind the paramountneed to maintainas efficienta flow of shoppertraffic as possible.In the UnitedStates,the code provisionsfor coveredmall buildingsgrew out of many yearsof application of special interpretationsof existingcodes. In Malaysia,the followingrecommendedguidelinesare to be observedwhen designingshopping centres(as containedin the SarawakBuildingOrdinance): (i)
The size of shop compartmentsshallnot exceed: (a) 7,000 cubic metresand 2,000squaremetresfloor areasfor unsprinkleredbuildings; (b) 14,000cubic metresand 4,000 square metresfloor area for fully sprinkleredbuildings from any other partsof the shop area. and shall be fully compartmented
(ii)
Where the floor area of buildingwith fully automaticsprinklerinstallationis subdivided,there shall be no restrictionon the totalarea,providedthat: ( a ) n o t l e s s t h a n 6 0 % o f t h e t o t a l a r e a s h a l l c o n s i s t o f u n i t s o f s e p a r a t es h o p s n o t exceeding280 squaremetreseach of which is enclosedas in paragraphii.; and (b) shop units referredto in paragraph(i). shall be enclosedon three sides by walls having a fire resistanceequal to the compartmentwall as requiredabove; and the frontage onto a coveredmall or open pedestrfanfootpathconstrtutesthe fourth stde,and shops a thrid enclosrhgwall.The remaththgareasmay constSt on a cornersrdewrllnot requr're o f s h o p s l a r g e rt h a n 2 8 0 s q u a r e m e t r e sb u t n o t e x c e e d i n g2 , 8 0 0 s q u a r em e t r e s ; providedthat:
12
(b.1) shop areas exceeding2,000 square metresshall not face each other across a mall or a pedestrianfootpathunless both frontageare protectedby automatically operatedshuttersgivingat leastone hour fire resistance;and (b.2)whereshopswhichadjoinone anotherwith theiropen sidesin a same placeare of floor areas exceeding8,000 square metres each, they shall be protectedby back-upwalls behindthe shop windowsfor a distanceof at least3 metreson both sidesof the interveningwall or be separatedfrom each otherby at leastone small unit of not more than 280 squaremetresarea. Diagram4.1.2.1 Compartmentation of shoppingcentres .* sufficientegressindependentof mall ComparbnenlA (unsprinklered) ancfiorsbrs <7,d)0mt-2.o0om2 Compartnent B --,
,,
aCorner shoprequireonly, 2 enclosingwalls intermediateshops <280m2enclosedon 3 sides by wallswith FRP equalto compartmentwall (2hrl4hr)
(tullyspdnklered) <14,000mt4,000nf
relieson egress from mall
Shop <280m2
i{'"r
Store 2, not an anchorstore >2,000m2 CompartmentB
\\ no restrictionon floorarea if buildingis equippedwith fullyautomaticsprinklers
1
7
ComlartmenlC
/ t
Notes: (ii)(a)ln compartmentB, retailspaces/shops floor area shall be 60% or more of the total compartment area.
13
D i a g r a m4 . 1 . 2 . 2 Arrangementof shops -, A, 41= 2,000- 2,800m2 A2, A3 = 280 - 2,800m' B = shop <280m2 Area of all B > 60% of total area
B=<280m'
f
min3m
(i) where A, A1= 2,000- 2,800m' rnd face each other acrossmall, automaticallyoperated shutter: t hourresistance protectionis necessary.
' /--/ra i'
(ii)where A1 +M =2,000-2,800m2 they shouldbe separatedby smaller shop unitsof not more than 280m2
r'"./qr"'i+_
': .
4:
(iii)whereA2, A3 = 280 - 2,800m' adjoineach other and onto the same place,back up wallsof at least3m on eitherside of interveningwallsshallbe provided.
4.1.3Atriums "A large The NationalFire ProtectionAssociationLife SafetyCode (NFPA 101) definesAtriumas volume space created by a floor opening or a series of floor openings connecting two or more storiesthat is covered at the top of the series of openingsand is used for purposesother than an enclosed stairway;elevatorhoist way; escalatoropening;or utilityshaft used for plumbing, facilities" electrical,air conditioning, or communications
'1991of Englandand Walesdefinean Atriumas "a verticalspacein The BuildingRegulations a buildingwhichopenlyconnectsthreeor more floorsand is enclosedat the top by a roof or floor.(Shaftscontaining stairs,escalators.lifts or servicesare not includedin this exclusively definition)". The two definitionsare not inconsistentand both define a verticallylinkedvolume of space over severalfloors.Atrium buildingsvery often combineaspectsof malls and high rise buildings.The greatestconcern regardingatrium fires involvesthe controlof smoke. Where atriumsare used, there is actuallyan added degree of safetyto the occupantsbecausethere is a large volume of space into which the smoke can be drawn into and then dissipated.However,there is a need to ensure that dangerousconcentrationsof smoke are promptlyremovedfrom the atrium,and the exhaustsystemneeds carefuldesign.
14
Atriumsmay be permittedin buildingsprovidedthe followingconditionsare met: (i)
The minimumhorizontaldimensionbetweenoppositeedges is no less than 6 metresand t h e a r e a o f t h e o p e n i n gi s n o t l e s s t h a n 9 5 s q u a r e m e t r e s .A t r i u m sn e e d n o t o n l y b e rectangularshaped,and for practicalreasons,the horizontaldimensionobviouslycannotbe applt'edth corner or niche locatfons.The minimumdimensionalrequirementsare aimed at e n s u r i n gt h a t t h e a t r i u md e s i g n e r sc r e a t ea l a r g es m o k e a c c u m u l a t i o cn h a m b e r ,w h i c h managesthe smoke concentrationearly in the fire before the buildingsprinklersystem achievescontrolof the fire and beforethe requiredsmoke controlsystembeginsto control smoke accumulation.The geometryspecifiedby the minimumdimensionshelp to keep the atriumopeningfrom behavingas a flue or chimneyin lieu of an initialsmokeaccumulation chamber.The 6 metresand g5 squaremetresrepresentthe best aggregatedthinkingof experts in the field of fire safety.
(i i )
The exits are separatelyenclosed from the atrium. Access to the exits is permittedto be within the atrium.lt is consideredthat given the compliancewith the stringentconditions(i) to (vii)of this part an adequateoverallpackageof safetymeasuresis affordedto allow exit accessto be withinthe atrium.
(iii)
The atriumis open and unobstructed, with a low to ordinaryhazardcontent.
(iv) The buildingis fully protectedby automaticsprinklers.The entirebuildingratherthan just the atriumopeningand its communicationspace,must be protectedby a supervised sprinklersystem.
(v)
The sprinklersto ceilingor roof of the atrium may be omittedif the ceiling/roofis more than 17 metresabove the floor of the atrium.The reason for this exceptionis that above 15 metres, it has not been demonstratedthat sprinklersdirectly over the fire will effectively respondto the fire in a timely manner.ln fact, the mist resultingfrom the sprinklerspray being evaporatedby the hot column of rising air may most probablyinterferewith the f u n c t i o n i n go f t h e s m o k e c o l l e c t i o nc h a m b e ra t t h e t o p o f t h e a t r i u m b y l o w e r i n gt h e t e m p e r a t u r eo f t h e s m o k e a n d t h u s a f f e c t i n g i t s d e n s i t y a n d a f f e c t i n g t h e p l u m e characteristics.
(vi)
A smoke controlor smoke exhaustsystem is providedfor the atriumand adjacentspaces, complyingwith approvedstandards.The exceptionis when an engineeringanalysiscan demonstratethat life safetyduringthe egressperiodwill not be compromised.
(vii) The smoke controlor smoke exhaustsysteminstalledshall be activatedby: (a) Smoke detectorslocatedat the top of the atriumand adjacentto each of the returnair intakefrom the atriumor beam detectorsat the appropriatelevel;or (b) Theautomatic sprinkler systemservingtheatriumzone/s;or (c) Theautomatic detectorsystem(butnotmanualcallpointsystem); or (d)
Manualcontrolsreadilyaccessible to thefirebrigade.
15
(viii) The atriumis separatedfrom adjacentoccupancyby a fire barrierwith at leastone hour fire resistancewith the exceptionthat: (a) Any numberof levelsof the buildingshall be permittedto open direcflyto the atrium withoutenclosurebased on the resultsof an engineeringanalysisacceptableto JBpM. This engineeringanalysisshalldemonstratethat the buildingis designedto keep the smoke layer interfaceabove the highest unprotectedopeningto adjoiningspaces, or 2,000mm above the highestfloor level of exit access open to the atrium for a time periodequalto 1.5 times the calculatedegresstime or 20 minutes,whicheveris greater. The engineeringanalysisshall includebut not be confinedto the followingelements: (a.1) Fire dynamics,includingfire size and location,materialslikelyto be burning,fire p l u m e g e o m e t r y ,f i r e p l u m e o r s m o k e l a y e r i m p a c to n m e a n s o f e g r e s s a n d tenabilityconditionsduringthe periodof egress. (a.2) Responsetime and performanceof buildingsystemsincludingpassive barriers, automaticdetectionand extinguishingand smokecontror. (a.3) Requiredsafe egresstime for the occupantsto reachbuildingexits,includingtime requiredto exit throughthe atriumas permittedby this guideline. (b) Glass walls may be used in lieu of fire barrierswhere automaticsprinklersare spaced not more than 1.8 metresor less apart along both sidesof the glass wall and not more than 0.3 metre from the glass so that the surfaceof the glass is wet upon operationof the sprinklers.The glass used shall be tempered,wired or laminatedglass held in place by a gasketsystemthat permitsthe glass frame systemto deflectwithoutbreakingthe glass before the sprinklersoperate.The intent of the requirementfor the closely spaced sprinklersto wet the atriumglass wall is to ensure that the surfaceof the glass is wet upon operationof the sprinklers.Automaticsprinklersshallnot be requiredon the atrium side of the glass wall and inoperablewindowswhere there is no walkwayor otherfloor area on the atriumside abovethe main floor level.The conceptof wettingthe glassthat is exposedto fire withoutspecifyinga water applicationrate is that as long as there is some water presentto absorb the heat, the glass will not reach excessivetemperatures that would cause failures.To ensurethat water will reachthe surfaceof the glass,window blinds and security shutters must not be placed betweenthe glass and in the line of closelyspacedsprinklers. (c) Glazeddoors formingpart of the glass walls shall be fittedwith door closers complying with By-law104. (ix)
The selectionof materialsused to line the roof/ceilingover the atriumshas to be made with care. Materialsthat melt and drip molten debris to the atrium floor below can pose an additionalhazard both to users as well as aiding fire spread.Plasticsare to be avoided. ln any event,By-laws203 and 207 are to be compliedwith, and only materialswith a Class O - surfaceof No Flame Spread- ratingshould be used [By-law204A.,a. and b.]. By-law207 - Exceptionrelatingto ceilingsshould be exercised very carefullywhen appli-d to ceilings o v e r a t r i u m s a s t h e r i s k s p o s e d b y t h e e x c e p t i o n sa r e d i f f e r e n tw h e n c o m p a r e dt o conventionalceilingsover non-atriumspacesor voids.
16
Diagram4.1.3.1 Planview of a typical atrium wall must,comply with (viii)
Minimum95m2 opening
wall mustcomply with (viii)
Diagram4-1.3.2 Sectionalview of a typical atrium
wall must comply with (viii)
wall mustcomply with (viii)
17
Dlagramt1.1.3.3 Sprinkler for wetting glass
Sprinklerfor wettingglass
Floorlevelsopeningto atrium.Levels2, 3 and g open to atrium;levels1 and 4 throughI enclosed by glass walls. Sprinklersrequiredon non-atriumside of all glass walls,on atriumside at base of atrium,and on atriumside on other levelswith walkwavs.
1B
4.1.4Mixed Use Buitdings where a buildingcontainsusagefallingunderdifferentpurpose groupsand each is containedwithin compartments,By-law 215 of the UBBL allows the height of each part of the buildinghousinga differentpurposegroup,if they are verticallyseparated, to be consideredseparatelyfor compliance with schedule 6 (calculationof permittedlimitsof unprotectedareas), z (calculationof occupant load and capacityof exits),9 (limitsof compartments and minimumperiodsof fire resistancefor fire extinguishment ararmsystemsand emergencyrighting)in the UBBL. Diagram4.1.4.1 Computation of mixeduse buildingin compliancewith UBBL
f
P! A of BuitdingUse/purposeGroup:Hotet/ltl HT1 to be used for compliance with Schedutes 6, 7, 9, 10 of BvJaw
Verticalcompartmentwall separatang PurposeGrouplll & V By-law215
i
Buirdins Use/PurPose GrouP: 3;Xr?,il HT2 to be usedfor compliance with Schedules6, 7, 9, 10 of Bv_laws
ground level
Compartmentfloor-t/ abovebasement By-law138(d)
depth HT3
II
\-.J* Part C of BuildingUse/purposeGroup: BasementParkingA,/l ll Depth/HT3to be used for comoliance withSchedules7,9, 10 of Bv-laws
19
4.2 FIRE APPLIANCE ACCESS 4.2.1 Design Notes Vehicularaccess to the exteriorof a buildingis neededto enable high reach appliances,such as turntableladdersand hydraulicplatforms,to be used and to enable pumpingappliancesto supply water and equipmentfor fire fightingand rescueactivities. Access requirementsincreasewith buildingsize and height. The table in By-law140 stipulatesthe proportionof the buildingperimeterthat must be accessible to fire fightingappliances. access, considerationshould be given to the design of the In planningthe vehicular/appliance hard standing/accessroad in relationto the buildingwith respectto featuressuch as overhangs, canopies,turningradiusand otherobstructionsto the free operationof the fire fightingappliances. (Seediagram4.2.2.1). Locationof hydrantsmust similarlybe considered.Too close a placementadjacentto the building or beneathan overhangmay expose Fire and Rescue personnelto unnecessaryrisks or worse, render them inoperablein an emergency.Similarly,too close a locationto routesof vehiculartraffic may renderthem susceptibleto damage. 4.2.2Access Gonsiderations Diagram4.2.2.1 Relationship betweenbuildingand accessfor FireAppliance (Mediumto highriseand newbuildings)
A<2m C > 10m will allowuse of both turntableand hydraulicplatform max weightof applianceis 26 tonnes width of applianceis 2.5m min overheadclearancefor accessis 4m max gradientto accessis 1:12
max gradient1:12
20
Type of Appliance Turntable
HydraulicPlatform
(m)
(m)
A. Maximumdistancefrom edge of hardstanding to building
4.9
2.0
B. Minimumwidthof hardstanding of hardstanding to building
5.0
5.5
10.0
7. 5
C. Minimumdistanceof far edge of hardstandingto building
SeeAppendix1 for Specifications of FireAppliances for the purposeof Designing for FireAccess for FireRescueVehicles. 4.2.3PerimeterApplianceAccesslllustrations Diagram4.2.3.1 One sixth perimeter appliance access Buildingvolume7,001m3 to 28,000m3
D,"
-J
FireAppliance
/--..\
\
X
-\___.\
--...---/ )
lsolatedsite/location with an adjacent property/building
>18m
-t\
--'-
----
--)/
/
/
,/
X > 1/6(A+B+C+D)
Note:Turningprovisionrequiredfor the fire applianceif dead end accessexceeds1gm. Turningprovisioncan be in the form of hammer-heador turningcircle.
21
Diagram4.2.3.2 Onesixth and one fourthperimeterapplianceaccess City/Builtup locationwith adjacentbuildings
BuildingVolume 7,001m3 to 28,000m3
L
. \-\ \
.
\ \
6m back lane
/ /
,'
\ Accessibleperimeterof building
\
Main road usedfor appliance accessif not less than 12m wide
Pavement
C > 1 1 6( A + B + C + D ) Applianceaccessfrom main road is sufficientif the buildingvolumedoes not exceed28,000m3. In the event the 6m back lane is accessibleby fire fightingapplianceand the buildingvolume 28,000m3but is lessthan 56,000m3,then, A+C>1/4(A+B+C+D)
22
Diagram4.2.3.3 One half perimeterappliance access Buildingvolume56,001m3 to 84,000m3
',/ at least12m
a'
B+C>1/2(A+B+C+D)
Diagram4.2.3.4 One half perimeter appliance access in city site with adjacent buildings
Buildingvolume56,001m3 to 84,000m3
back lane accessible ';6m to fire appliance
Accessibleperimeterof building A+C>1/2(A+B+C+D)
23
Diagram 4.2.3.5 Three fourth perimeterapplianceaccess
'fBuildingvolume84,001m3 \ to 1'12,000m3
\
Access road of at least 12mwide A+B+C>3/4(A+B+C+D)
Diagram4.2.3.6 Three fourth perimeter appliance access
r. Buildingvolume84,001m3 to 112.000m3
12mwide
// /
B+C+D>3/4(A+B+.+D)
!
7 fffi:J:*ofatleast
Diagram4.2.3.7 lsland site
,.,- Buildingvolumeabove112,000m3
r,'
fire zz- Minimum6m access appliance
D
) o
I
'.-
Accessroad of at least 12m wide
The minimumpermissiblewidth of a FireApplianceAccess is 6m' The minimumturningradiusaroundcornersof buildingshall be providedas follows: Diagram4.2.3.8 Fireapplianceaccess - Building
a-L
L(13m) widthApplianceAccess W = unobstructed L = lengthof largestFireAppliance(currently13m) d - cut-backdistanceis obtainedby intersecting 'A' - 'C' the imaginarycornerof a buildingwith line
W2 (6m min)
25
Thesedimensions are preferred dimensions. Discretion shouldbe appliedin builtup siteseg.citycentres. Diagram 4.2.3.9 Fire applianceturn-around dimensions
i)
T-Turn 18m
----
3.6m >.
min 6m radius i,:'jij
min 6m radius
ii)
Shunt --4..
6m) >-
min 6m radiusj
iii) , . ' ' - D ( 1 2 mm i n )
26
4.2.4HydrantLocations Diagram4.2.4.1 Location of hydrants
r
+--1 ---- ---t _ _ 2m min ,l
<0.61ni
Building
Verandah
\* Pavement/ Shoulder
FireApplianceAccess
Hydrantsshould be located: (i)
away from obstructionssuch as streetfurniture(benches),phonebooths,etc.
(ii)
not less than 2m from adjacentbuildingsand overhangs.
(iii)
between0.61m to2.4m from FireApplianceAccess.
(iv)
away from risksof vehiculardamage.
(v)
n o t m o r e t h a n 9 0 m a p a r t f r o m e a c h o t h e r ( i n n e w b u i l d i n g sa d j a c e n tt o e x i s t i n g a new hydrantor hydrantswill haveto be providedif there is no hydrantwithin developments, 45m radiusof the new building).
27
4.3 WALL AND FLOORS 4.3.1 Party Walls Party walls in the fire safety contextrefer to walls that separateunits of differentownershipas in walls separatinghouses,flats or shops.Partywalls (By-law86) serveto preventthe spreadof fire from one terraceunit to the next. The UBBL statesthat party walls shall be of solid masonryor insitu concreteof not lessthan 200mmthickor if constructedat differenttimes,made up of two skins, eachof not lessthan 100mmthick. 4.3.1.1 Diagram Partywall to terracehouses
Partywall
'l I I I
l I
n
I )
Terraceunit2
/'
ln multi-storeyedflats and terrace houses of reinforced concrete or protected steel framed '100mm. construction,the thicknessof the non-loadbearingparty wall shall not be less than This exceptionappliesto framed residentialbuildingsonly.
28
Party walls must be raised230mm above the upper roof surface measured at right angle to the surface to act as flame deflectors. Diagram4.3.1.2 Junctionof partywall with roof
-
{ \ 230mm
\ ,,/
\-
Party watt
D i a g r a m4 . 3 . 1 . 3 Junction of party wall with roof valley gutter ;
Roof
- Partywall
29
Distancemeasured perpendicular to the roof surface
For low-cost terrace house (not flats), the following detail may be accepted by JBPM. Diagram4.3.1.4 Alternative party wall/roof detail for low-cost terrace house
\
""r,y wall of pc block
The following illustrated T-barrier may be accepted in lieu of the 230mm raised party wall D i a g r a m4 . 3 . 1 . 5 Alternative party wall/roof detail fullyembedded ,,-file *C flame deflector
,"',i Batlen ,,. / 7
//'
1,. '
30
Partywall
4.3.2 Recess and Ghases By-lawsBB and 89 allow recessand chasesto be made in walls but dimensionsare limitedsuch that the minimumfire resistanceintegrityof externaland partywalls are maintained. Diagram4.3.2.1 lllustrationof recessin externalwall Lintolor archwayas necessary
Extemalwall
(x) 330mwide minimummeasured on innersurfaceto externalwall Area of recessshall not be moreJ than 'll2 area of wall
Diagram4.3.2.2 Recessin externalwall
Diagram4.3.2.3 Recess in party wall
31
A chase may be made in a wall for pipesand other seryices.The thicknessof the wall at the back shall not be less than 90mm for-externalwall and 100mmfor party wall. Width of chase shall not exceed200mm. Diagram4.3.2.4 Ghasesin partywall and relevantexternalwall
4.3.3 Separating/CompartmentWalls and Floors By-laws 147 (constructionof separatingwall) and 148 (compartmentwalls and floors) allow separatingand compartmentwalls which are not party walls to be constructedof materialsother than masonryso long as they complywith the requiredFRP [Fire ResistancePeriod].Similarly, structuralelementscarryingthe separatingor compartmentwalls shallthemselvescomplywith the same FRP requirements(By-law217). ln the eventof a compartmentwall separatingtwo or more purposegroups,it shallbe protectedin accordancewith the more stringentrequirementsof the purposegroups.(By-law216 para2). are not requiredto providefire protection Single-storeybuildings(includingfactories/warehouses) part walls.(By-law216). do not form of compartment to their structuresif they Non load-bearingcompartmentwalls (partywalls)separatinga flat or maisonettefrom otherpartsof the same buildingshallnot be requiredto have fire resistanceexceedingt hour unlessthe purpose group of the part of the buildingseparatedby that compartmentwall is different(or is protected shaft)and the minimumperiodof fire resistancerequiredis 1.5 hoursor more (By-law218). By-law 137 stipulatesthat floors in buildingsexceeding30 metres in height shall generallybe constructedas compartmentfloors.(See diagram4.3.3.3)
32
Diagram4.3.3.1 special requirement as to compartment wails and compartment froors Compartmentwall Fire door to have FRP ratedto 112of that for the walls
Junctionshallbe fire-stopped
Diagram4.3.3.2 Separation of ducts/flues in compartment
Ductwith pipes
Non-combustible constructionof not morethan half of FRP of compartmentwall By-law148(5)
Comparlmentwall (X Hr FRP)
33
Diagram4.3.3.3 Floor in building exceeding30 metres to be constructed as compartmentfloor.
Buildingheight exceeds30m
Mezzaninefloorwithin a compartmentmay not be a comoartmentfloor
Floorsbelow9m need not be constructedas compartmentfloorsif the cubiccapacitydoes not exceedcomoartmentlimits
By-law138 Floorover basement storeyexceeding '100m' shall be compartmentfloor Note:Openingsare allowedif an atriumcomplieswith requirementof FireAuthoritres
34
4.3.4 Stages in Places of Assembly The prosceniumwall is to be regardedas a fire isolationwall,allowingthe containmentof fire backstageand to minimiserisk of smoke infiltrationinto the main hall. Diagram4.3.4.1 Stagein placesof assembly(section)
openingareaof (B) and (C) shall not exceed858m2each
Diagram4.3.4.2 Section through stage opening 0.92mmin if roof FRP not complying9th Schedule
----
Wall being extended foundation
,1-
Stage
35
Openingarea:-max 3 openings 2 openingsotherthan stage
Diagram4.3.5.2 Smokebarriersbehindcurtainwalls
0.9m
EXTERNAL
4.3.6ProtectedServiceShafts Protected shaftspenetrate acrosscompartments or floorsin a building.Theycanbe shaftscarrying utilities(piping,electricalandtelecommunication serviceetc.)or areserviceshaftscarryingliftsand includingescapestaircases. In the formercontext,all penetrations of floorsandwallsshallbe fire-stopped. In the latterconlext,they often encloseprotectedstaircasesor lift lobbiesthat will have to be ventilatedor pressurised to allowventingof smokeor preventinfiltration of smoketo providesafe passagefor bothescapingoccupantsand safeaccessfor firefighters.
37
Diagram4.3.6.1 Fire stop at pipe openings in protectedshaft Fire stopFire stop
2
._a Floorlevel t *--
*
'-
'a-
Any openingfor a pipe shall be effectivelyfire stopped
Protectedshaft
r,0" Diagram 4.3.6.2 Ventilation for lift shaft not opening to protected lobby Ventilation (mino o9m' )
-"-ts
Machine room -
Roof level
Ventilation (min 0.09m' ) -
Floorlevel
Externalwalll-
.- Unprotectedlobby
3B
Diagram4.3.6.3 Ventilation for lift shaft not opening to protected lobby ".a
.z'
Ventilation(min 0.09mr) Ventedto exteriorthrough a duct of the requiredFRp as for the lift shaft
- Floorlevel
Unprotectedlobby
Diagram4.3.6.4 Opening of lift shaft or lift entrance shall open into a protected lobby
Note:Protectedlobby may be omittedwhen the foilowingare observed: (i) Fire ratedlandingdoors are providedto life shaft. (ii) This lift shaft is pressurisedto preventsmoke infiltration and spreadto other floors.
39
4.3.7Cladding on ExternalWall Vide a directiveissued by the DirectorGeneralof JBPM in April 1997, all aluminiumcomposite claddingson buildingsabove 1Bm height shall be suppliedwith non-combustible cores. This directivewas issuedto avoid a scenariowhere the occurrenceof a fire in a high rise buildingcould result in the core of a compositepanel catchingfire, meltingand spreadingthe fire by dripping moltenand flamingcore materialto other areas below the sourceof fire. In addition,the dripping molten core materialcould also pose a danger to occupantsleavingthe buildingor Fire Rescue personnelworkingon the fringeof the buildingat groundlevel. 4.3.7.1 Diagram ClassO claddingon externalwall < 1.2mfrom boundary
Lessthan 1.2m
t-
l - . , .
l"-"I F-.t
-
f-*-, I i' .,
\-
i
Boundary
40
Diagram4.3.7.2 ClassO claddingon externalwall > 1.2mfrom boundary no provisionin respect to the boundaries indicated
-t'
ClassO cladding
l I
i
over1Bm i
l l
,.r
I
l
I
up to 18m
lndex not more than 20. Timbercladdingat least9mm thickis also acceptable(the indexrelatesto testsspecified in BS 476 Part6)
Diagram4.3.7.3 Roof inclinationmore than 70" Roof at 70' angleor more
Adjoiningspace
Roof shallbe deemed to be oart of extemal wall or side of a building
Externalwall
41
4.3.8 Referenceto Sixth Schedule a. Background The provisionsof the sixth schedule and By-laws 142 to 146 are based on the objectiveof establishinga reasonablebasisand standardof spaceseparation to be speci1edbetweenbuildings for reasonsof preventionof flame spread and protectionfrom externalfire sources. The externalwallsof a buildingare requiredto resistthe spread of fire over theirsurfacesand from one buildingto another.In assessingthe adequacyof resistance to fire spread,regard must be given to the height,use and positionof the building. In this respect,the roofof a buildingmust also offeradequate resistanceto the spreadof fire across its surfaceand from one buildingto another.Hence the treatment of the roof as a wall element when it is at an angle steeperthan g0 degrees [By_law145a]. Externalwalls serve to restrictthe outward spread of fire to a building beyond the boundary and also help to resistfire from outsidethe building.This is achieved by ensuringthat the walls have adequate fire resistanceand external surfaces with restricted fire spreao. Fire spread between buildingsusuallyoccurs by radiationthroughopeningsin the externalwalls (termed,unprotected areas'). For obvious reasons,if the external wall forms part of the structure, then it or the structuralpart of it must of necessitybe constructedof non-combustiblematerials or as in the case if steel structures, be adequatelyprotectedwith non-combustibremateriars. [By-raw 142.3]. The risk of fire spread and its consequencesare reratedto: (i) the severityof the fire; (ii) the fire resistanceofferedby the facingexternalwalls including the numberand disposition of the unprotectedareas; (iii) the distancebetweenthe buildings;and (iv) the risk presentedto peoplein the oppositebuilding. In general,the severityof a fire will be relatedto the amount of fuel/combustible matedalcontained in the buildingper unit of floor area (fire load density).certain types of buildings,such as shops, industrialbuildings'and warehousesmay containlargequantities of combustiblematerialsand are usuallyrequiredto be sitedfurtherfrom their boundariesthan other types of buildings. The provisionsof the Sixthschedule limitthe extentof unprotected areas in the sidesof a building which will not give adequateprotectionagainstthe external spread of fire from one buildingto another'Based on the generalbackgroundabove,the sixth schedule makes assumptionson the following: (i)
that the size of a fire will depend on the compartmentation of a building,so that a fire may involveone compretecompartment,but wiil not spreadto other compartments;
(ii)
that the intensityof the fire is relatedto the use of the
(iii)
that the amountof radiationthat passesthroughany part of an externalwall that has fire resistancemay be discounted.
building(ie. purposegroup);and
b. Boundaries A relevant boundary as the name impliesrepresents a boundarythat is relevantto that side of the buildingfor the purposesof checkingcompliancewith the sixtn scneoule.(see diagram4.3.g.1)
42
It need not be a legal boundaryas in a land boundaryestablishedby survey which is for the purposesof land ownershipdemarcation.The relevantboundarymarks the base line from which measurementsare taken for the purposeof establishingthe set back distanceof a side or of a This distanceis then used to establishthe buildingfor the purposesof Sixth Schedulecalculations. proposedbuildingfacades. permissible the relevant in percentageof unprotectedopenings lf a buildingabuts onto an existingplaygroundor road, the relevantboundarymay extend into both those spaceseg. centre line, as they are not anticipatedto be occupiedby buildingsin the foreseeablefuture. For the purposeof practicalityand preservationof legal rightsof land owners in an existingbuilt up environmentlike Kuala Lumpur,it is advisedthat the side boundaryfacing an existingbuilding be used as the relevantboundaryfor compliance.lt is impossibleto haul up owners of existing buildingsto reducetheir unprotectedopeningsif their relevantboundariesextendbeyondtheir site/ side boundarieslBy the same token, it would not be fair to expect a new owner to set back further or reducehis openingbecausethe neighbourhad not compliedoriginally. Notional boundary (See diagram 4.3.8.2)is an assumed or imaginedboundary between two buildingsbuiltor to be builton the same site.This boundaryis establishedby referenceto the Sixth Schedule.ln the case of an existingbuildingon site, the notionalboundaryis set by checkingthe buildingagainstthe Sixth Schedule,then it becomesthe basisfor establishingeitherthe set back or permissibleopeningpercentagein the new buildingproposedRelevant Boundary This diagramsets out the rules that apply in respectof a boundaryfor it to be consideredas a relevantboundary. For a (i) (ii) (iii)
boundaryto be relevant,it should: coincidewith, or be parallelto,or be at an angleof not more than B0 degreeto the side of the building
Diagram4.3.8.1 Relevantboundary(Referto By-law142) Sixth SchedulePartll (1) *
This boundaryis parallelto and thereforerelevantto side D
r
I
-l7I v
B U I L D I N G-
This boundarycoincideswith and.is thereforerelevantto side B
The relevantboundarymaY be the centrelineof a road, railway,canalor river
43
This boundaryis parallelto side A
Diagram4.3.8.2 Notional Boundary
Thisdiagramsetsout rulesthatapplywherea buildingis proposed on the samesite as another building, so thata notionalboundary needsto be assumedbetweenthe building.
<--
site boundary
Building
Building B
compliancewith the provisions for space separationin respect of buildingA
compliancewith the provisions for space separationin respect of buildingB
Thenotionalboundary shouldbe set in areabetweenthe buildings usingthefollowing rules: 1.
lt is onlynecessary to assumea notionalboundary whenthe buildingareon the samesite. Thebuildingcanbe newor existing.
2.
The notionalboundaryis assumedto exist,in the spacebetweenthe buildingand is positioned so thatone of the buildingswouldcomplywiththe provisions for spaceseparation havingregardto the amountof its unprotected area.In practice, if the buildingsis existing, the positionof the boundarywill be set by the spaceseparation factorsfor that building.
3.
The sittingof the new buildingor the secondbuildingif bothare new,can then be checked to seethatit alsocomplies- usingthe notionalboundaryas the relevantboundaryfor the secondbuilding
44
Diagram4.3.8.3 Statusof combustiblesurfacematerialas unprotectedarea Area of fire resistingwall with combustible m a t e r i a=l a x b
{l
Area of wall countedas unprotectedarea = 0.5 a x b and is centredon actualarea of combustiblesurfacematerial
\
Area of fire resistingwall withoutcombustiblesurface.
Diagram 4.3.8.4 Unprotected areas which may be disregarded in assessing the separation distance from the boundary 2 or more smallerareas within an area ot 1mz
The unprotectedarea of the extemalwall of a stairwayforminga protectedshaft may be disregardedfor separationdistance purposes
x=1.5mmin distance y=no restriction z=4m min distance
x
.-ff
l
m n i'i i''i
1'-
.-Jry---r Representsanareaol -not more than 0.1m2
Compartmentwall line
45
Compartment floor
Openingof this size represents an unprotectedarea of not more than 1m2whichmay consistof 2 or more smallerareaswithinan area of 1m2
c. Sample Calculations Calculationsof permittedlimitsof unprotectedareas (By-laws142 and 145) Assumptions: - Singlebuildingwhich is not compartmented - PurposeGroup lV (Office) Diagram4.3.8.5 Samplecalculationusingthe SixthSchedule ';
Enclosingrectanglewith relevant olaneof reference9m x 21.4m
f 4.6m
+-
3.6m -f 3.6m
{
3.6m 4-3.6m ----
tut
4m--': _f--
opening C J
q
OpeningB
F,q.
Canopydeemed not part of structure OpeningA set back 2m from plane of reference 9mx3m Partll (2)
to be disregardedbecause C has aggregatearea of less than 1m2.Therefore,it can be disregardedin the unprotectedarea ---qrlculation.SixthSchedulePart 1, Rule 2(ii)Rule2 > 4m from unprotectedarea on same side of building.
Enclosingrectanglesize on relevantplane of reference 9m (w) x2'1.4m(h)= 192.6m2 Relevantboundarydistancefrom enclosingrectangle7.5m UsingTable 1 of Part ll SixthSchedulefor enclosingrectangle234m high,width of 9m, distanceof 7.5m from relevantboundary,the limit of unprotectedpercentageof the enclosingrectangleshall not exceed70%. Calculations to check compliance O p e n i n g ' A ' -9 m ( w )x 3 m ( h ) = 2 7 m 3 O p e n i n g ' B ' -1 0 n o s x 3 m ( w ) x 2 m ( h ) = 6 0 m 2 Total OpeningArea = B7m2 Check 1 - Total area of B7m2 UnprotectedOpeningArea is less than 210m2(purposeGroup lV). Thereforeit satisfiesPart lll 1(a)of Sixth Schedule.
46
Check2 - Unprotectedpercentageof enclosingrectangleis 87m2| 192.6m2= 45.17o/o. Limitof unprotectedpercentageof enclosingrectangleis 70%. Thereforeit satisfiesPart ll of the Sixth Schedule.
4.4 MEANSOF ESCAPE Notes 4.4.1Explanatory (i)
Fire does not normallystart in two differentplacesin a buildingat the same time. At the initialstage,fire poses a dangeronly in the part of the buildingin which it starts.Thus, an importantprinciplein the design of fire safety is to containthe fire within a compartment and to extinguishit while preventingfire and smoke from spreadingto other parts of the building.
(ii)
The itemsthat are the first to be ignitedare often furnishingsand other items not controlled by the regulations.lt is less likelythat fire will originatein the structureof the building.
(iii) The primarydanger associatedwith fire in its early stage is not flame but smoke and noxiousgases producedby the fire. A person can withstanda smoky situationfor only about 3 minutesafterwhich he will faint or die. (iv)
Smoke also obscuresthe way to escape routesand exits and impedemovement.In this situation,a person can move only about 12 metres (40 feet) per minute. In allowinga minute to escape,travel distanceto safety in an unprotectedescape route is generallyto be no more than 12 metres(40 feet).
(v)
Becauseof the danger posed by smoke and fumes,fire safetydesign must limitthe spread of smoke and fumes especiallythroughconcealedspacesin buildings.
4.4.2 Basic Principles of Design (i) In the event of fire, the occupantsof any part of a buildingmust be able to escape safely withoutrelianceon externalassistanceor rescue by the fire serviceand without having to manipulateapplianceor apparatus. (ii)
The design of means of escape should take into accountthe form of the building,the aciivitiesinsidethe building,the likelihoodof fire and the potentialof fire spreadthroughthe building.The UBBL 1984 stipulatesdifferingrequirementsfor differentpurposegroups of buildingsand differingrequirementsfor sprinkleredand non-sprinkleredbuildings.
(iii) There should be alternativemeans of escape in most situationas there is always the p o s s i b i l i t yo f a n e s c a p e b e i n g i m p a s s a b l eb y f i r e o r s m o k e .S i n g l es t a i r c a s e( w i t h n o alternativemeansof escape)and dead ends are allowedundercertainconditionswhere fire risk is low becauseof the small size and low heightof the buildingand the small numberof personsaccommodatedwithin it. (iv)
The provisionof an appropriatewarning and fire extinguishmentsystemsshould be an essentialelementin the overallstrategyfor safety.
(v)
ln additionto safety and egress of occupants,practicaland safe access to the buildingby fire fightersand rescuepersonneland equipmentin orderto stage rescue,fire containment has to be provided. and extinguishment
47
4.4.3 Means of Escape (i) An escape route should lead to a place of safety.The ultimateplace of safety is the open air outsidethe building,clearfrom the effectsof the fire. (ii)
In large complexeswhere this is not possible,it should be possibleto reach a place of reasonablesafety such as a protectedstaircaseor a protectedcorridorfrom where people can travel in relativesafety to a final exit.
(iii)
F o r t h i s t o b e p o s s i b l e ,p r o t e c t e ds t a i r c a s ea n d p r o t e c t e dc o r r i d o rm u s t n o t c o n t a i n combustiblematerialsand are designedto keep out flame,smoke and gases.
(iv)
The maximumpermissibledistanceof an unprotectedescaperoute is workedout by the period a person exposed to fire and smoke can reasonablybe expectedto endure when escapinga fire.
4.4.4 Measurementof Travel Distance to Exits Meansof Escape- Concepts Primary principlesof means of escape: (i)
Alternativemeansof escapeto be made possible.
(ii)
Means of escape is to direct a shortestroute to a place of safety, such as outside the building,or if stillwithina building,a protectedor isolatedpassageway,stairsor refugeareas which lead to the outsideof a building.
(iii)
Generallymeansof escapeconsistof two parts: (a) unprotectedareas,leadingdirectto exit (b) protectedareas, leading direct to exit
Unprotectedareas forming escape routes are to be limited in distance to minimise exposure to smoke and fire, and this is the basisof the limitsof 'traveldistance'. Diagram4.4.4.1 Traveldistance
A+B=Travel distance
4B
Diagram4.4.4.2 Travel distance over steps
B is a straightline inclinedat the same planeas the staircase(not measuredon the flat planeon plan)"
Diagram4.4.4.3 Travel distance from rooms exceeding 6 person occupancy
"'"---'-T i
i1 .
\
RoomB
r\.
Room A ''/ 11
ttF
ta
ffi
\
-":---,"-
WhereA and B are rooms havingnot more than sixoersonsc
49
-.--:
a and b < Dead end traveldistance. lf room A and B has an occupancy exceeding6 persons,then a + c or b + c shallbe lessthanor equalto P P = PermittedTravelDistance
Diagram4.4.4.4. Measurement of travel distance to exit B < Dead-endlimit A + B or C + B (whicheveris less) < PermittedTravelDistance(p)
Diagram4.4.4.5 Dead-end travel distance
A + B < P
50
Diagram4.4.4.6 Dead-endtravel distance
A+B+C
Diagram4.4.4.7 Dead-endtravel distance A+B+Csp
51
Diagram4.4.4.8 Exit and travel distance
"OpenAreas' (OpenPlan ofiices,warehouse, Hallwaysor roomswithoutfixture or furnitureat time of design) u
nsip
Diagram4.4.4.9 Traveldistancewithin rooms
Room not more than 6 persons(distanceY not morethan 15m)
52
Diagram4.4.4.10 Measurement of travel distance within rooms
Room not more ---.'\ than 6 persons
Y distancenot morethan dead end distanceand X + Y not more than permissibletraveldistance in 7th schedule
Diagram4.4.4.'11 Measurements of travel distance to exits
--tt4'+'=+
,l\
L e
a < 15m if room < 6 occupants b s deadend limits c < maximumpermissible distance(p) d + e s max permissible distance(p) c + (d + e) s 2P max permissible distance(p)
53
D i a g r a m4 . 4 . 4 . 1 2 Travel distance through offices
a < 15m if room < 6 occupants b1 < dead end limits b2 < dead end limits c + d < 2P (maximum permissible distance)
Diagram 4.4.4.13 2 storey exits to be provided ,
equalor morethan45"
54
Diagram 4.4.4.14 Gompliance with permitted travel distance Area that does not complywith the -1 provisionof permittedtraveldistance \
At leasteitherc or d < Max.permissibletraveldrsrance (or 213P if space is open plan)
\
Diagram4.4.4.15 Overlapping of travel distance
Recommendedmethodto check positionsof alternativeexits and compliancewith traveldistance
55
4.4.5Arrangement of Storey Exits The principleof this clauseis that once the escaperouteis insidea protectedzone,eg. an isolated/ protectedstaircase,then the routeshall remainprotectedall the way to the final exit, i.e. out of the building.Therefore,the route shall not dischargeinto an unprotectedarea (such as open lobby) priorto the final exit. (Referto By-law 190). Diagram4.4.5.1 FinalExits
Finalexit -
Finalexit
Diagram4.4.5.2 Final Exits '- Storeyexil
I I'
56
Diagram4.4.5.3 Minimum distance between exits
Diagram4.4.5.4 Minimum distance between storey exits
57
Diagram4.4.5.5 Minimum distance betweenexits onto corridor
Diagram4.4.5.6 Storey exits (staircases)
Protectedstaircase
58
Diagram4.4.5.7 Storey exits (balcony approach)
Diagram4.4.5.8 Exit routes to discharge directty to finat exit
1 Escapelevel
Escapelevel,
f--+
Separateaccess/escaperoules to and from basementlevel. Thishelpsin preventing escaping occupantsfrom upperfloors inadvertently enteringthe basementinsteadof finalexit
6q
Diagram4.4.5.9 Egress through unenclosedopenings (mezzanine) - For floorsup to 9m from groundfloor,mezzaninefloors be permittedto be up to S0% of the floor area below. For mezzanineabove 9m from groundlevel,a floor area of up to 1/3 of floor area below may be permitted.
Diagram4.4.5.10 Horizontal exits Protectedstaircase to finalexit /
Horizontalexit
/'
Compartmentwall
Protectedstaircase to final exit
60
4.4.6 Staircases Staircasesare very importantelementswhich often serye as the primaryescape route element in any buildingcontainingmore than one level.As such it is importantin planningand designing staircasesthat considerationbe givento issueslike usability,practicalityand predictability. Humansdevelopa rhythmwhen climbingor going down stairs.An intuitivefuzzy logic.reasoning predictsthe next riser or step. lt is for this reason that pitch lines (an imaginaryline joining all nosingsin a flight)haveto be made as consistentas possible.Unevensteps in a flightof stairscan confuseone'sperceptionand leadto usersstumbling.By the same reason,flightsof lessthan three risersare not allowed.These are calledusabilityconsiderations.From a practicalitypoint of view, minimumtread dimensionsand maximumriserdimensionsare used to controldesignsto ensure that they are physicallyusable. ln Englandand Wales, a maximum pitch angle of 42 degrees is allowedfor staircases.Any steeperand it becomesphysicallychallengingto use, especiallyfor the elderly,very youngand physicallyimpairedor unfit. The followinginformationon steps and stair must be shown on drawingssubmittedto JBPM: (i)
numberof treads(or risers)which shall not exceed 16 in a singleflightunlessit is for stairs withinan individualresidentialunit (By-law108[1]i.
(ii)
dimensionof treadsand risers;treads shall not be less than 255mm, risersshall not be (By-law106t11) morethan 1BOmm.
(iii)
widthsof stepsor stairswhich shall be calculatedin accordancewith By-law168.
(iv)
depth of landingwhich shall not be less than the width (By-law106[3])of the staircase.
(v)
Minimumheadroomof not less than 2 metre measuredverticallyfrom any point over the full width of the stairs.
Diagram4.4.6.1. of riserand tread Measurement x > 255mm y < 180mm
{ x .
{
t
DetailA (straightedge)-
v
/
-"' DetailB (overhangingnosang)
Riser(y) l8ommmax --
' ..,r,f, I
i--r
J ,_--(inclined il riser)-./ ,'-.. DetailC -- ___l tread(x)255mmmin-' I
Tread and riserdimensionsmust be constantwithina staircaseto preventusersfrom trippingand fallingespeciallyin the eventof fire. Dimensionsare stipulatedfor the same reasons. The width of staircaseshall not reducealong its path of travelto the final exit (by-law169). Windersare not permittedin fire escapestaircase.
61
Diagram4.4.6.2 Landingin residentialbuilding (morethan'16risersperflightis notencouraged)
Diagram4.4.6.3 Single riser in staircase not permitted (minimumnumberof riserscan be two but it should be regular)
62
Diagram4.4.6.4 No obstruction in staircases w - width of staircaseto complywith provisionof 7th scheduleand By-law168 d - depthof landingnot less than widthof staircase(w) ByJaw168
-t \
min 2m
\ \
t''/
z''
, a./
oermittedhandrail
-meter box, post box recess
..1within enclosure
.t Meterbox,postboxor otherfittingsare notto intrudeintothisenclosure' "enclosure" handrails)' (exceptpermitted withinthis or intrusion No obstruction
63
Diagram4.4.6.5 Exampleof bad staircasedesign
unenclosedvoid posesa danger to evacueesfallingover in an emergency
Staircasewith long and short flightsas shown above are not encouragedby JBpM for an escape staircase because a person's rhythm of walking down steps is broken especiallyduring an evacuationwhen the staircaseis packedwith evacueesand one cannotsee the steps ahead. Diagram4.4.6.6 Exampleof acceptablestaircasedesign ,"- Brickwall ; Constantriserdesign
The above layout is acceptableprovidedbrickwallsurroundthe void and the flight are regular. This to prevent peoplefrom fallingover the staircaseinto the void in the event of a rush durino evacuation.
64
Diagram4.4.6.1 Recommended standard of escape stair Doorswingto be in .. 'r\ ,;- Door srring to be outside path oftravel on stair \
\ )* /
,z \
'X
Q r )" ^
Stairwidth a = b
--
Wl:i: Diagram4.4.6.8 Staircase serving open balcony approach
+1 fin
(
,
tml fnn
Occupancy
fu) -J
65
4.4.7 Smoke Lobbies Diagram4.4.7.1 Smoke lobby to staircases
Diagram4.4.7,2 Smoke lobby for stair extended to basement
Smoke lobbiescreatea bufferbetweenthe actualoccupiedpremisesand the escape passageor staircase. In its simplestform, it preventsingressof smoke and toxic gases into the escape staircasewhen the staircasefire door is opened,where required,pressurisationof the staircasecan serve the same purposeby creatingpositivepressurewithinthe stairwellto preventsmoke ingress.
66
when the smoke lobby doublesas a fire fighting access lobby, it serves as a point for fire and rescuepersonnelto tacklethe sourceof fire from withinthe same floor.(ReferBy-laws196-1gg). In buildingsexceeding18m abovegroundlevel,protected lobbiesare requiredif the staircasesare not ventilatedor pressurised.(By_law1g7). Diagram4.4.7.3 Ventilationof smokelobby
Permanentopeningor openablewindowof 1m2 minimumto outsideor lightwell (By-taw196)
Smoke lobbyor fire fightingaccesslobby
Diagram 4.4.7.4 Pressurisation of smoke lobby
,- Vertical shaft for z/ ventilationor pressurisation
Internalsmokelobbvor fire fighting access lobby
67
Diagram4.4.7.s Protectedlobby requirementfor building > 18m height (By_law197) Ventilation opening --.
Externalwall
L Buildingmore than 1gm abovegroundlevel
Protectedlobbyrequired-
/
Diagram4.4.7.6 Protected lobby requirement for building > 45m height (By_law 1gll2l) Ventilationopening
No Protected lobbyrequired
.-Building more than 45m abovegroundlevel
6B
Diagram4.4.7.7 Omission of protected lobby for pressurised staircase Ventilationopening -7'
\.
..-- For buildingabove 1Bmbut below45m
No protected lobbyrequired
No protected lobbyrequired
Pressurisedstaircase
Diagram4.4.7.8 ventilation of staircaseenclosure in buildings not exceeding 1gm Can be directaccess Ventilation5% min of stairenclosure Ventilatedlobbies \
n rl
Buildingheight
7- Groundlevel
69
4.4.8 Building with Single Staircase Diagram4.4.8.1 Height of topmost floor of building with single staircase
I
Domesticor Heightoftopmostfloor<12mj - Domestic or
Access level
Diagram4.4.8.2 Maximumtravel distance
--12m
'\.
max
'-;'3 ',5';:. '::j!1
\ii
ri
-1
.- 12mmax
\
By-law't94 stipulateswhen a single staircasemay be permitted.Essentially,this is only allowed where the occupancyabove ground level is confinedto eitherdomesticor office purposes.This presumesa scenariowhere the occupantsare familiarwith the layout of the buildingand floor plates.The groundfloor may be used for shops or car parks(shopoffices,shop houses). All elementsof structureshall have an FRP of not less than t hour except the enclosurefor the staircaseat the groundfloor where the wall shall have an FRP of not less than 2 hours [Refer Bylaw 216], assumingthe groundfloor will not be used for residentialpurposes. Designersare advised to inform their Clients of the need to anticipatethe likelihoodof change in use after the issuanceof the Certificateof Fitnessfor Occupationby not electingto use single staircasedesigns in traditional4 storey shop/officedevelopments.This is a common problem encounteredby JBPM when shop officedevelopmentsend up beingconvertedinto tuitioncentres, shops and entertainmentoutletslike bar loungesand cafes.
70
4.4.9Protectionfor ExternalEscape Staircase By-law191ensuresthatan "*t"tn"i!Li"".".rr"o forescapepurposes wirrremainprotected fire exposureoriginatingrrom tne Luiroing. from rn"refore, a ,J*'or protectionis extended staircase bothupwardsanddown*";; t; from the ensuresafepassageduringa fire. Theillustration showsthezonewhereno opening shailbe formedor onrytoiretsor otherprotected or openingswith wiredglasswhic-h are t
iil#,1ffi,::,'j"Ti"'J[l'j""":"Jil:,."J":::jiL"::,il::',"JfJ":",*:: area openinss oropeninss
Openingswith wired glassallowed Zone whereopening not permitted Openingsfor toilets can be formed
(
t,'
4.4.10Handrails All flightof stairswith 4 or more risers shall be providedwith at reastone handrair. Diagram4.4.10.1 Staircaseexceeding2225mmwidth requiresintermediatehandrairs
f=-
,f'- ,.,
Adult handrail
Childrenhandrail
2225mm max
71
Diagram 4.4.10.2 Wall mounted handrail
t
I
tr.I ^i'
-Widthof stairs
Diagram 4.4.10.3 Handraildetail
-t
i\ 900mmmin i
.1.,
)'.KS
72
\=-
4.4.11Escape Provision Computation By-law 175 - Calculation of Occupancy Loads By-law 176 - Computing Storey Exit Width By'law 177 - computing Number of staircases and staircase width Workedexampleto calculatenumbersand widthof staircaserequired usingthe Seventhschedule of UBBL 1984 . Officebuilding/Purpose Group lV . 5levels, each leveldesignedas a compartment . Floorareas- Level 1 (Ground)1500m2 -Level2 -1500m2 -Level3 -1500m2 -Level4 -1500m2 -Level5 _1800m2 Exit WidthCalculationsTable
A B
c D E F
Level PurposeGroup/Occupancy Load FloorArea (m2) C+B=Occupancy Exit CapacityRequiredfor Stairs(D + 60) MinimumStaircaselvidth (E x 550mm)
1 lv/10 1500 150 2.5 1375
2 tv/10 1500 150 2.5 1375
3
4
5
rv/10 tv/10 tv/10 1500 150 2.5 1375
1500 150 2.5 1375
1800 180 3.0 1650
Notes PurposeGroup- Referto FifthSchedule occupant Load - Refer to 2nd Column of Seventhschedule,check whether areas to be used is nett or gross. Exit Capacity- Refer to 3rd columnof SeventhSchedule,establish type of exit and exit capacity that is appropriateeg. doors outside,ramps or stairs. (i)
Referringto columnF in the above table,Level 5 is the largestand the exit width (staircase) requiredis 1650mm.Staircaseprovisionmust cater to this requirement.
(ii)
By-laws168 and '177stipulatethat every upperfloor shall have means of egressvia at least two separatestaircase(with exceptionof By-law 194),assumingexitdistances are com pliedwith.A minimumof two staircasesare thereforerequired for Compliance.
(iii)
By-law199(a)requiresthe assumptionthat one of the protectedstaircases is inaccessible. lf two staircasewere provided,theywould thereforeeach have to be minimum1650mm widthto caterfor the occupantload.
73
(iv)
Three-staircasescenario: lf three staircasewere providedsay main staircase/fire fightingstaircasewidth of 12O0mm (minimum1100mm)and two secondarystaircaseof 900mmwidtheach.The checkwould be as follows:
(a) Totalexitwidth: MainStaircase Secondary Staircase 1 Secondary Staircase 2
-
TotalExitWidth
1,200mm 900mm 900mm 3,000mm
(b) Assumingthe wideststaircase(mainstaircase)is inaccessible,remainingexit width is 3,000mm- 1,200mm= 1,800mm. 1,800mm> 1,650mm,thereforethe provisionsatisfiesthe By-laws. 4.4.12 Seating in Placesof Assembly Diagram4.4.12.1 Spacingbetweenseats (By-law184)
I
o
lt
'f--ti 300mm | \ I min.lt
Non-SelfRaisingSeats
+l
Back to back spacing,S > 825mm x+y+675mm>825mm
74
Diagram 4.4.12.2 Maximum number of seating per row (By-law184)
(E
3
o) c o
'
l
l
r
Ilrrrtrrrrlrrl trrrrllrllllrl l
r
O
g !..rrrJ s )
Diagram 4.4.12.3 Seats without dividing arms
I
I
I
I
I
I
tF-l |
l
450mm
I
Diagram 4.4.12.4 Continentalseating I r
No. of seat in a row can be 49 max.
I l
I t
r
lllrrrrlrllrll
F -
E I o l c o l @ t
tI trrrurrrrrrrl I
lrrrrllrrrrrrl 1 lrrrrlrlrtrrrl : 9L lrrrrrrlrlrrrl E !rrrrrrlllrrrl
'
,
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I Illrrtrllrllltt I Irrrrrrlltrrrl
1
1
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L
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' l
l l
l""I
Diagram4.4.12.s Gangway all round Exitdoor
1200mmmin. 1200mmmin
Diagram4.4.12.6 Gangway on 3 sides 200mmmin.
H
l200mmmin.
1200mmmin
76
Diagram4.4.12.7 Parallelgangway required by locat authority
As requiredby localauthority
Diagram4.4.12.8 Guardrails at foot of gangway
Guardrail min. 1.05mheight Normalrailing as requiredunder the UBBL1984 Min. 1.05mheight
77
4.5 RULES OF MEASUREMENT 4.5.1 Description By-law135 in the UBBL 1984setsthe basisfor measuringheights,areasand volumesof buildings/ compartmentsfor use in conjunctionwith the UBBL 1984throughout. It has to be bornein mind that these measurementmethodswill differfrom the basisfor calculatino the same dimensionsfor use with planningguidelinesor other applications. lllustrationsA, B and C describesthe rulesof measurementfor heightsin variousbuildings. Diagram4.5.'|'.1 Heightof building
highestlevelof groundadjacent to outsidewalls
mean groundlevel lowestlevelof ground adjacentto outsidewalls A. Double-pitchedroof
highestpointof flat roof mean roof level
highestpointof parapet
top level of gutter
use heightA or heightB whicheveris greater
meangroundlevel
B. Mansard type roof
7B
highestpointof roof slope
highestlevetof ground adjacentto outsidewalls
height
equal
mean groundlevel
equal
-
il;"";:jff'fl,:,fJ10",,,
C. Flat or monopitch roof
Calculationof area of any storeyor compartmentto be takento finishedinnersurfacesof enclosing walls or to outermostedge of the flooron the side that has no enclosingwalls eg. balconies. The area measuredwouldincludeall internalwallsand partitionsenclosedby the innersurfacesup to externalwalls or edges (as in balconies). Diagram4.5.1.2 Areaof building Area to be calculatedto innersurfaceof enclosed spaces Area to be calculatedto outer edgeof balcony (unenctoseo)
Mirrorlmage Line
79
The area of any part of a roof shall be taken to be the actualvisiblearea of such part measured on a planeparalleltopitch. Diagram 4.5.1.3 Areaof roof Highestpoint(ridge)
A=B Lowestpointof roof eaves
Area of roof is 2 x (X) x (y)
Calculations of cubic capacity of a building or compartment D i a g r a m4 . 5 . 1 . 4 Volume of build compartment
(iii) Measureto undersurface of roof if buildingor compartmentexits to roof.
(iii) Measureto undersurfaceof ceilingof higheststoreyif building/compartment does not extendto roof. (i) Measureto finishedinner surfacesof enclosedwalls.
(iii) lgnorewaltsand floorsif they fall withinthe same companment.
(ii) Measurefrom the upper surfaceof the lowestfloor.
80
DIMENSIONS OVERALLLENGTH OVERALLWIDTH OVERALLHEIGHT WHEELBASE TRACK - FRONT . REAR TURNINGCIRCLE GROUNDCLEARANCE OVERHANG- FRONT - REAR ANGLE - APPROACH - DEPARTURE
6,B00mm 2,100mm 2,400mm 4,280mm 1,757mm 1,853mm 18,000mm 200mm 1,070mm 1,450mm 35" 30"
DESIGNRATINGS FULLYLADEN GROSSVEHICLEWEIGHT
82
4,700k9 5,000k9
DIMENSIONS OVERALLLENGTH OVERALLWIDTH OVERALLHEIGHT WHEELBASE TRACK- FRONT - REAR TURNING CIRCLE GROUNDCLEARANCE - FRONT OVERHANG . REAR ANGLE- APPROACH - DEPARTURE
10,800mm 2,500mm 3,300mm 5,265mm 2,045mm 1860mm 295mm 1,400mm 2,750mm 25" 12"
DESIGNRATINGS FULLYLADEN GROSSVEHICLE WEIGHT
B3
21,000k9 26,000k9
DIMENS!ONS OVERALLLENGTH OVERALLWIDTH OVERALLHEIGHT WHEELBASE TRACK - FRONT - REAR T U R N I N GC I R C L E GROUNDCLEARANCE OVERHANG- FRONT . REAR ANGLE - APPROACH - DEPARTURE
7,800mm 2,500mm 3,400mm 3,900mm 2,100mm 1,752mm 14,000mm 250mm 1,000mm 1,450mm 20" 15"
DESIGNRATINGS FULLYLADEN G R O S SV E H I C L EW E I G H T
84
13,000k9 18,000k9
DIMENSIONS OVERALLLENGTH OVERALLWIDTH OVERALLHEIGHT WHEELBASE TRACK- FRONT - REAR TURNING CIRCLE GROUNDCLEARANCE - FRONT OVERHANG . REAR ANGLE APPROACH - DEPARTURE
10,000mm 2,500mm 3,600mm 4,900mm 2,100mm 1,752mm 17,200mm 250mm 2,600mm 2,600mm 14" 10'
DESIGNRATINGS FULLYLADEN GROSSVEHICLE WEIGHT
85
17,000k9 18,200k9
DIMENSIONS OVERALLLENGTH OVERALLWIDTH OVERALLHEIGHT WHEEL BASE TRACK- FRONT - REAR TURNINGCIRCLE GROUNDCLEARANCE OVERHANG- FRONT - REAR ANGLE - APPROACH . DEPARTURE
14,000nrm 2,500mm 3,900mm 5,900mm 2,045mm 1,B60mm 265mm 4,000mm 4,000mm 20" 10'
DESIGNRATINGS FULLYLADEN GROSSVEHICLE WEIGHT
86
28,000k9 31,000k9
DIMENSIONS OVERALLLENGTH OVERALLWIDTH OVERALLHEIGHT WHEELBASE TRACK- FRONT - REAR TURNING CIRCLE GROUNDCLEARANCE OVERHANG. FRONT - REAR ANGLE- APPROACH -DEPARTURE'
13,060mm 2,500mm 3,600mm 5,900mm 2,045mm 1,860mm 260mm 4,000mm 4,000mm 20" 10.
DESIGNRATINGS FULLYLADEN : GROSSVEHICLE WEIGHT:
87
28,000k9 31,000k9
5.1DESCRIPTION portableFire Extinguishers are elementaryfire fightingequipmentintendedfor firsfaid fire fighting duringthe initialoutbreakof fire incidentto preventescalationinto a full scalefire. Properusageof portaOtefire extinguishersoften effectivelycontroland extinguishera fire even beforefire authorities is summoned.Howeverthey are not supposeto be used againsta large scalefire. portable fire extinguishersshould be suitablyselectedfor the type of fire in accordanceto the classificationand the fire size and sited in suitable locationsin close proximityto the potentialfire hazards portablefire extinguishers shouldhave minimumgrossweightbut with higherfire ratingin orderto be able to be carriedand operatedby one person. shall be user friendlyand portablefire extinguishersshouldbe maintainedand servicedannuallyfor their effectiveness.
5.2DESIGNREQUIREMENTS 5.2.1 Codes and Standards is described (a) Underthe UniformBuildingBy-laws1984,portablefire extinguisherrequirement under By-law 227. (b)
Portablefire extinguishersshall be designed,tested,select,installand maintainin accordanceto: - M.S.1539- Specification for portablefire extinguishers: methodology test and 1 : Construction Part - M.S.1539- Specification for portablefire extinguishers: Part 3 : Selectionand Application- Code of Practice - M.S.1539- Specification for portablefire extinguishers: portable fire extinguishers- Code of practice Part 4: Maintenanceof
(c)
shall be manufacturedwith the followingrequirements: Portablefire extinguishers - SIRIM qualitycertification scheme
5.2.2 Glasses of Fire shouldbe providedfor dealingwith the followingpotentialclassesof fire Portablefire extinguishers identifiedin the risk assessment: (see Figure5-2-2.1) - ClassA : Fires involvingsolid materialsof organicnaturewith the formationof glowingambers, eg. paper,wood, etc - Class B : Firesinvolvingliquidsor liquefiablesolids,eg. petrol,kerosene,diesel,etc - Class C : Firesinvolvinggases,eg. oxygen,LNG, LPG' etc - Class D : Firesinvolvingmetals,eg. sodium,potassium,magnesium,etc - Class E : Firesinvolvingelectricalequipment - Class F : Firesinvolvingfats and cookingoils
90
5.2.3 Selection and Application The typicalmediumfor portablefire extinguishersare as foilows: -
Water Foam Dry ChemicalPowder CarbonDioxide
-
Suitablefor ClassA fires Suitablefor ClassA and Class B fires Suitablefor ClassA, B, C and E fires Suitablefor Class B and E fires
5.2.4Color Coding colour of extinguishercylinder/bodyshall be signal red to RAL 3000. All wordings,diagram, pictogramshall be white in colour and all extinguiihingmedium shal be "oiour;il as foltows: (see Figure5.2.4.1)
Water Foam DryChemical PowderCarbonDioxide Halon
Red Cream Blue Black GoldenYellow
Note : Halonportablefire extinguishers are only allowedfor military,aviationor specialapplications only where permittedby Departmentof EnvironmentMaraysia. 5.2.5 Label Marking All portablefire extinguishersshall be markedas per labels attached. All label markingsshall be fullyvisiblefrom the front (see FigureS.2.S.j and5.2.5.2) 5.2.6 Installation - Generally,portablefire extinguishers shouldbe locatedin conspicuouspositionwhere they can be easily spotted by person followingan escape route. - Siting positionnear to room exits, corridors,stainvays,lobbiesand landingsare most suitable. They shouldnot be sitedwhere a potentialfiremight preventaccess to them. - Extinguishersshould be locatedpreferably within recessedclosetsif they be sited along protected corridorsto avoid obstructionduring evacuation. - They should be sited not more than 20 metres from a potentialfire hazard 5.2.7 PerformanceDesign Fire classes, fire hazard location, extinguisherdistribution,extinguisherperformance as well as applicationshould be the criteria for determiningthe size and quantities of portable fire extinguishers. For dry chemicalpowder extinguisher,vast improvementin chemical content has increasedthe performanceof the extinguisher.Weight is hence no longer the criteriafor selectionbut fire rating determinesthe performanceseg. minimumfire performancerating of a 9kg extinguisherof 30% chemicalpowderis 27A and 144B..A 6kg extinguisherof 50%chemicalpornde, can achievea fire ratingof 27A and 1838. Gross weight of portablefire extinguishersshould be kept to a minimum (recommended to be below 12kg)to ensureportability.Currentweight ratingof portableflre extinguishersis net weight of fire extinguishing mediumexcludingthe weightof tne cyiinoer,valve body, metreand hose;e.g. grossweightof SkgCOz extinguisheris 21kg.
91
It is recommend to designfor 2 smallerextinguishers to achievethe same ratinginsteadof 1 extinguisher to increasethe effectiveness of fire extinguishment. Example1 Fora singlestoreybuildingof floorarea1,600m2, the minimumaggregated classA ratingis 0.065x 1,600= 104A Thetotalfire ratingcan be providedby: BxI3APFE= 1044 4x27APFE = 108A
Bx4kgpFEofl3A 4 x 6 k g p F E o f2 7 A
* PFE- Portable fireextinguisher Note- Portablefireextinguishers of smallercapacitybuthigherfireratingis preferredfor portability and effectiveness
5.3 VISUAL INSPECTIONCHECKLIST 5.3.1Portablefire extinguisher Q Cylinderbodyshouldbe redwithmediumcolourcodedin respective colour o All labelmarkingwordings,diagramsand pictogramsshallbe in whitecolourand shallbe fully visiblefromthe front O LabelshouldcarrySIRIMproductcertification logo Q Extinguishers shallhavevalidFireand RescueDepartment ApprovalLetter O EachExtinguisher shallhavea validFireand RescueDepartment H13certificate o Extinguisher meterindication shouldindicateadequatepressure(GreenZone)within the cylinder Q Cylinderbodyand valveshouldbe rustfree Q Safetypin shouldbe in placeand secured O DischargeHoseshouldhaveno cracks
92
:1 I
I i
Fire involvingsolids,organicin nature,combustionnormallyleadsto formation of glowing embers, carbonaceousfires
Firesinvolvingliquidsor liquefiablesolids
Fire involvinggases Note : 1. Must turn off the gas valve or plug the leak before putting out the fire 2. Preferablyto be handled by trained fire fighters 3. May require protectiveclothing and/or SCBA (SelfContainedBreathingApparatus) Fire involvingmetals Note : 1. 2. 3. 4.
To refer to materialsafety data sheet of types of metals used Preferablyto be handledby trained fire fighters Special applicationand technique required May require,:,protectiveclothing and/or SCBA (Self ContainedBreathingApparatus)
Fire involvingelectricalequipments Note : 1. Extinguishermustpassdielectrictest of 35 kva to carryClassE marking 2. Shallnot be used on live electricalequipment Fire involvingfats and cooking oils
0 . 0 1 5m 2 0.02m2 0.04 m2 0 . 1 1m 2
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6.1 DESCRIPTION Fire hydrant installationconsists of a system of pipework connected direcfly to the water supply mains to providewater to each and every hydrantouilet and is intendedto providewater for the firemento fighta fire' The water is discharged into the fire enginefrom which it is then pumped and sprayedover the fire' where the watersupply is not reliableir inadequate,hydrantpumps should be providedto pressurisethe fire mains. A typicalhydrantinstallationfeed directlyfrom the publicwaler mains is shown in Figure6.1 and Figure6.2 showsa typicalinstallationpressurised by fire pumps. 6.2 DESIGNREQUIREMENTS 6.2.1 Design Standards The requirementfor fire hydrants is described under By-laws 225(2) and 225(3)of the uniform BuildingBy-raws1984,and the rerevantstandards are as foilows: - M.s.1489Part 1 : Hydrant systems, Hose Reersand Foam Inrets; - M.S.1395: Specification for pillarhydrant. 6.2.2Hydrant Ouflets Pillarhydrantsshouldcomplywith M.s.1395and locatedat not more than 30 metresaway from the breechinginletfor the building.The hydrantshould be not less than 6 metresfrom the buildingif it is a high rise buildingso as to allow firemen to operate the hydrant safely, away from the burning buildingor fallingdebris.Generally,hydrants are spaced at not more than 90 metresapart along accessroadsof minimum6 metresin width and capableof withstandinga load of 26 tons fromfire brigadevehicles. Hydrantoutletsare typicallyof the twin outletpillar type with an undergroundsluicevalve.Where these are installedwithinthe owner'sboundary, each should be providedwith 30 metresof 65mm dia' canvashose' instantaneous couplingsand nozzles,all housedwithina steelcabinet besidethe hydrant' Hydrantslocatedalong publicroads need not be providedwith hose stations.Underground hydrantsare not encourageddue to the difficulty of access. For pressurisedinstallations,hydrantswith twin oufletsshould be capableof providing1000 l/min of waterat a minimumrunningpressureof 4 bars but not exceeding7 barsfor instantaneous coupting. where threadedtype of hydrantoutlets are permitteo ov tne iir" nrt ority,the ouflet pressuremay exceed 7 bars' The 1,000 l/min is based on each 65mm diameterouilet of a double ouflet pillar hydrantdischarging500 l/minfrom each outlet pressureregulatingtype simultaneousry. of oulet valves should be used where the pressurefrom the fire mains exceed 7 bars. where the hydrant outlet is locatedwithin the owner's premise,hydrant hose usuallyof canvas should be provided completewith nozzlesat each ouflet. The hydrantmainsare usuallylaid underground althoughthey can also be installedabove ground exceptwhere it crossesa road. The pipingis usually oi cement lined steel pipe. However,piping of AcrylonitrileButadienestyrene (ABS) material may also been used especiallywhere corrosion is a majorconcern.
97
6.2.3Hydrant Pumps The hydrantpumpsdraw waterfrom the fire waterstoragetank and two sets of pumps,one on duty and the other on standby,are provided.The pump capacityis usuallysized to delivera flow rate of 3000 l/min at a runningpressureof not less than 4 bars for any three hydrantouiletsoperating at the same time. This flowratewill have to be increasedif the numberof outletsto be operatingat the same time is more than three. The standbyhydrantpumpsetshouldbe suppliedwith powerfrom the emergencygeneratorif this is available.Otherwise,the standbypumpsetshould be dieselengine driven.Where dieseldriven pumpsetsare used,the dieselengineshall be capableof operatingcontinuouslyfor 2 hours at full load' The dieselengineshouldbe providedwith an integralconstantspeed governorto controlthe engine speed at the rated pump speed under any load conditionup to the full load ratingof the engine.The startermotor and batterycapacityshall be capableof providing6 cycleseach of not less than 15 secondscrankingwith not more than 10 second of rest in between.At the 7th cycle, the starter motor and batteryshould be able to start the diesel engine. Batteriesfor the diesel engine should be of the maintenancefree type. Fuel supply should be adequatefor minimum2 hoursof full load operation. Electricalcablingto supplypowerto the hydrantpumpsshouldbe of fire ratedtype of cable. ln additionto the duty and standbypumpsets,a jockey pump is normallyprovidedto maintain system pressureand avoid havingto start up the duty pumps to maintain system pressure.Jockey pumps are usuallyelectricmotordrivenwith a capacityof around 120 litres/min. The hydrant pumpsets should be protectedfrom the weather and away from locationslikely to be flooded.Pump rooms shouldbe ventilatedby naturalor mechanicalmeans and providedwith the necessarysignage. 6.2.4 Hydrant Tanks The fire water storagetank shouldbe sized for a minimumeffectivecapacityof 135,000litres and shouldbe refilledautomatically from a water supplypipe capableof providinga minimumflowrate of 1,200llmin. For hydrantpumps largerthan 3000 l/min,the make up water flowrateshould be such that togetherwith the water stored,the hydrantpump will be able to operatefor t hour. A 4way breechinginletshouldalso be providedto enablethe fire brigadeto help refillthe tank. The effective capacity of the storage tank is the volume of water between the normal water level and the low water level.The low waterlevelshall be takenas 600mmabovethe highestpoint of the pump suctionpipe inlet opening.Where an approvedvortex inhibitoris used, the low water level shall be taken as the top of the vertexinhibitor'supperflange. Hydranttanks are usuallyseparatefrom otherwaterstoragetanks but may be combined with water storagetanks for other fire fightingsystems.In such cases,the tank capacityshould be the sum total of the water storagefor both hydrantas well as the otherfire fightingsystem. The tank may be of pressed steel, fibreglassreinforcedpolyester(FRp) or concrete.pressed steeltanks if used shouldbe hot dippedgalvanizedand coatedinternallywith bituminouspaint for corrosion protection-The tank should be compartmentedunless they are of reinforced concrete and water level indicatorshouldbe providedto show the amountof water available. The external surfaceof the tank should be paintedred or where this is not desirable,a red band of minimum 200mm should be paintedto indicatethat this is a fire tank.
9B
6.2.5PumpStarterpanelsand Controls Pumpstarterpanelshouldbe complete withindicator lightsas shownin the Figure6.3.Ventitation slotsshouldbe providedwithinsectscreento prevent entryor vermin. Hydrantpumpsshallstartautomatically uponactuation of the pressureswitchesbut shouldonly be stoppedmanually'Usuallythreepressureswitches provided are withthe followingsuggested pressure settings: - startingthe dutypumpsetset g0% at of thesystempressure; - startingthe standbypumpset setat 60%of thesystempressure; and - s t a r t i n ga n d s t o p p i n gt h e j o c k e y p u m p s e st e t a t 9 0 % a n d 1 1 0 %o f t h e s y s t e mp r e s s u r e respectively. Thepressure switchesarenormallyinstalled in thetestanddrainlineon the pumpdischarge side. The pressuresettingsshouldbe clearlylabeledon tags attachedto eachpressureswitch. 6.3 TEST REQUIREMENTS 6.3.1StaticPressureTest Thesystemshouldfirstbe flushedto clearalldebrisfrom theinsideof the riser.TheHydrantpipes are hydranlically testedto a pressure of 14barsor 150%workingpressure, whichever is the higher for 2 hours,measured at thefurthesthydrantanda checkiscarriedoutfor leakage jointsand at the landingvalveconnections.
6.4 MAINTENANCE REQUIREMENTS 6.4.1 Inspection And Testing A flow test should be carriedout to ensure that the pumps are in proper working condition.The pipeworkshouldbe checkedfor leakageand the hydrants,varves,hoses,drain valveand cabinets shouldbe inspectedas recommendedin the checklist attached.
6.5DESIGNCHECKLIST (a)
At leastone hydrantis providedat locationnot morethan 9'1.5mfromthe nearestpointof fire brigadeaccess.
(b)
A minimumflowrateof 500litres/minute at runningpressure of 4 to 7 barsis maintained at eachof the hydrantoutletwhenthreenumbersof thefurthest hydrantare in used.
(c)
Watersource: O Pumpsuctiontank. O Publicwatermain. Q Others:
(d)
Watertankcapacity:
(e)
Watersupplyduration:
ry13
nours.
oo
(f)
Hydranttype :
; size:
(g)
Totalnumberof hydrant: _
nos.
(h)
Hydrant spacing:_
0)
Hydrant :_mm. mainnominalsize
(k)
Numberof fire hoseprovided: _nos.
(l)
Hosesize:_
(m)
Pipe material:
(n)
Levelof undergroundpipe: oUnderdriveway(at|east0.9mdepth):-mdepth. O Otherlocation(at least0.8mdepth): m depth.
(o)
To providefire brigadebreechinginlet.
(p)
To providesectionalisolationvalvesat hydrantringmain.
(q)
Hydraulic calculation.
(r)
pump: Hydrant Q Ratedflow rate:
m.
mm ; length:_
m.
litres/minat
D Ratedpower:_kw. DPipenominalsize:Suction:-mm;De|ivery:-mm.
6,6 VISUAL INSPECTION CHECKLIST 6.6.1Visual Inspection of Water Supplies Incomingwater supplyconnection. Capacityof water available. Compartmentationof water tanks, where applicable. Primingtank (if any). Monitoringof water tank level. Vortexinhibitorsfor watertanks,where applicable. Breechinginlet. 6.6.2Visual Inspection of Hydrant and Accessories Spacingof hydrants. Physicalconditionof hydrants,hoses and accessories.
100
m head.
6.6.3VisualInspectionof pipework Typeof pipesused. Protectionof underground pipework. Paintingof pipework. Supportsfor pipework. 6.6.4VisualInspectionof pumps Protectionof rotatingparts. Mounting of pumps. 6.7 TESTINGAND COMMISSIONING CHECKLIST 6.7.1Testingand Commissioningof WaterSuppties Pumpoperatingcurrentand voltage. Pumpoperatingpressureandflow rate. Pumpoperating RpM. Pumpnotoverheating. Vibrationand noiselevel. Testingof electricalwiringsystem. Alternativepowersupplyfor electricpumps. Batteriesfor dieselpumps. Fuelfor dieselpumps. Automaticoperationof pumps. 6.7.2Testingand Commissioningof pipework Hydrostatic testingof pipework. Flushingof pipework. 6.7.3Testingand Gommissioning of HydrantOuflet Pressureandflow characteristics.
101
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7.1DESCRIPTION Hose reel systemis intendedfor the occupantto use duringthe earlystagesof a fire and comprises hose reel pumps, fire water storagetank, hose reels, pife work and valves.A typical hose reel installationis shown in Figure7.1.
7.2DESIGNREQUIREMENTS 7.2.1DesignStandards Therequirement forhosereelsystems is detailed underthe1Oth schedule oftheUniform Building By-laws1984.Theapplicable standards for hosereelsystemsareas follows;
- M's'1489part 1 : Hydrantsystems, HoseReersand Foamrnrets; - M.S.1447 - Hosereelswithsemi-rigid hose; - M.s.1488: semi-rigid hosesforfirstaidfixedinstailations. 7.2.2HoseReels HosereelsshouldcomplywithM.s.1447andare usuallyplaced suchthatall areasare within30 metrehosecoverageof eachhosereel.one hosereel shouldbe providedfor everyg0osq. metres of usablefloorspace'Hosereelsare usuallylocatedin prominent positionsat eacfrfloorlevelalong escaperoutesor besidesexitdoorsor staircases, preferablywithinrecessedclosets. Eachhosereeloutletis to discharge a minimumof 30 l/minof waterwithin6 metresof all parts of thespaceprotected' Therubberhosesshouldbe to M.s.14BB andaretypically 30 metres in length and25mmin diameter' Nozzles shouldbeof thejet andsprayadjustable typeof different diameters butBmmis a recommended size. Pipework for hosereelsystemis generally 50mmnominaldiameterandthefeedto individual hose reelshouldbe not lessthan 25mmdiameter.The piping shourdbe of galvanised steel medium grade(class B) minimumfor abovegroundpiping and heavygrade(class c) for underground pipes'The pipesshallbe paintedwithprimerand finishedwithred paintor the hosereetpipemay be identifiedwith red bandspaintedat elbowsand tees. 7.2.3HoseReelpumps The hosereel pumpsdrawwaterfromthe fire water storagetank and two sets of pumps,one on dutyand the otheron standby,are provided. The pumpcapacityis usuallysizedto delivera flow rateof 120llminat a runningpressureof not lessthan 2 barsfor any four hosereelsoperatingat thesametime Thestandbyhosereelpumpsetshouldbe supplied withpowerfromtheemergency generator if this is available'otherwise,the standbypumpsetshould be dieselenginedriven.Fuelsupptyshould be adequatefor minimumt hourof operation. Electrical cablingto supplypowerto the hosereel pumpsshouldbe runin galvanised steelconduitor alternativetyl maybe of fireratedtypeof cable. Batteries for the dieserengineshourdbe maintenance-rree type. wherethetotalnumberof hosereelsin thebuilding doesnotexceedfour(4),thestandbypumpset may be electrically drivenand neednotbe providedwithemergencypower.
105
The hose reel pumpsetsshould be protectedfrom the weatherand away from locations likely to be flooded.Pump rooms may be locatedanywherein the buildingor on the roof but should be ventilatedby naturalor mechanicalmeans and providedwith the necessarysignage. 7.2.4Hose ReelTanks The fire water storagetank shouldbe sized based on 2275litresfor the first hose reetand 1137.5 litresfor every additionalhose reel up to a maximumof 9100 litresfor each system. The tank may be of pressedsteel,fibreglassreinforcedpolyester(FRp) or concrete.pressed steel tanks where used should be hot dipped galvanizedand coated internallywith bituminous paint for corrosionprotection.The tank should be compartmentedand water level indicator should be providedto show the amountof wateravailable.The externalsurfaceof the tank shouldbe painted red or wherethis is not desirable,a red band of minimum200mmshouldbe painted to indicatethat this is a fire tank. The hose reel tank should be refilledautomaticallyfrom a water supply pipe of minimum50mm diameterto providea minimumflowrateof 150 l/min. Although hose reel tanks are usually separatedfrom domesticwater storage tanks, the two can be combined. ln such cases, the tank capacity should be the sum total of the water storage for both domestic as well as for hose reels and the tap off point for the domestic use must be above the tap off point for the hose reel system such that the minimum fire reserve for hose reel is always maintained. 7.2.5Pump Starter Panels and Controls Pump starterpanelshouldbe completewith indicatorlightsas shown in the Figure7.2. Ventilation slots should be providedwith insect screen to prevent entry of vermin. Hose reel pumps shall start automaticallyupon actuation of the pressure switches. Usually two pressureswitches are providedwith the followingsuggestedsettings: - startingand stoppingthe duty pumpsetset
at 80% and 100%of systempressurerespectively; and - startingand stoppingthe standbypumpset set at 60% and 100%of systempressurerespectively. For diesel pumpsets,these should be capableof automaticstartingbut should only be stopped manually. 7.2.6 Gravity Feed Hose Reelsystem Wherethe tank is locatedon the roof or upperfloorsand the staticpressure is adequateto achieve the requiredpressure,the hose reels may be fed directlyfrom the hose reel tank. lf pumps are requiredfor the upper floors, a bypass pipe is usually provided.Where excessivepressureis encountered,pressurereducingvalves should be installedwith a manual bypass in case the pressurereducingvalvefails. 7.2.7 Hose Reel Systems Fed from Other Sources The hose reel system may be tapped off from pressurized hydrant provided pressure reducing valves are incorporatedto reduce the pressureto the appropriatelevel. However, hose reels shall not be tappedoff from automaticsprinklersystems.
106
7.3 DESIGNCHECKLIST (a)
Design flow rate at each hose reel shall be 30 litres/min based on the top most four numbersof hose reels in use simultaneously.
(b)
Minimumdesignstaticpressureat entry of each hose reer :
_
bar.
(c)
Hosereettype:
(d)
Hoselength:_
(e)
Watersource. O Pumpsuctiontank. O Gravitytank. D Firewatermain O Others:
(0
Watertankcapacity: ----litres. *( 2,275litresfor the firsthosereel,eachadditional hosereelrequireextra1,137.5litres up to 9,100litres.)
(g)
Pressurereducingvalveset : D Yes.Pressurereducingrange:
metres.
barto _
Q No.
(h)
Hosereetspacing :
m.
(i)
Totalnumberof hosereel :
nos.
0)
Nozzlesare adjustableand spraytype.size :
(k)
Risersize(minimum nominalsize50mm): ..-mm.
(l)
Pipemateriat :
(m)
Hosereelpump: Ratedflow rate :
(n)
litres/minat
Pipenominalsize : Suction:
bar.
nomdiameter.
_mm
_
metrehead.
mm ; Delivery:--
7.4 VISUAL INSPECTIONCHECKLIST 7.4.1VisualInspectionof WaterSupplies Capacity of wateravailable. Compartmentation of watertanks.
107
mm
7.4.2VisualInspectionof Pipework Typeof pipesused. pipework. of underground Protection Paintingof pipework. Pipesupport. Pipesleeves. Fireseal. 7.4.3VisualInspectionof HoseReelsand Accessories valvefor hosereel. lsolating of hosereeldrum,hose,nozzles,etc. Physicalcondition 7.4.4VisualInspectionof PumPs Protectionof rotatingpartsof pumpsets. of pumps. Mounting
CHECKLIST 7.5 TESTINGAND COMMISSIONING 7.5.1Testingand Commissioningof Pipework currentandvoltage. Pumpoperating Pumpoperatingpressureandflowrate. RPM. Pumpoperating Pumpnotoverheating. Vibration and noiselevel. wiringsystem. Testingof electrical Alternativepowersupplyfor electricpumps. 7.5.2Testingand Commissioningof Pipework Hydrostatic testingof pipework. Flushing of pipework. of HoseReel 7.5.3Testingand Commissioning performance test. Hosereel
108
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8.1 DESCRIPTION Dry risersare a form of internalhydrantfor the firemen to use and are only requiredfor buildings where the topmost floor is higher than 18.3 metres and less than 30.5 metres above the fire applianceaccess level' Dry risersare normallydry and depend on the fire engine to pump water into the system.Dry riser system comprisesa riser pipe with landingvalves at each floor and to which canvas hose with nozzles can be connectedto directthe waterjet at the fire. Breechinginlets into which the firemen pumps water are provided ground at level and are connectedto the bottom of the dry risers. A typicaldry riserinstallationis shown in Figure8.1.
8.2 DESIGNREQUIREMENTS 8.2.1 Design Standards ln the uniform BuildingBy-laws 1984,the By-laws pertaining to dry risersare By-laws 230 and 232. The relevantstandardsfor dry risers are: - M.s.1489: Part 1 - Hydrant systems, Hose Reersand Foam Inrets; - M.S.1210: Part2 - Landing Valvesfor Dry Risers; - M.S.1210:Part3 - InletBreeching for RiserInlets; - M.S.1210:part 4 - Boxesfor LandingValvesfor Dry Risers. 8.2.2 Landing Vatve Landingvalves are providedon each floor and should complywith M.s.1210 : part 2.rhey are usually locatedwithin fire access lobbies,protected staircasesor other protectedlobbies, and installedat not more than 0'75 metres above the floor level. To protect the landing valves, boxes may be providedand these shouldcomplywith M.S.1210part 4. Fire hose of not less than 38mm diameter,30 metres in length,completewith 65mm dia. quick couplingand nozzleshouldbe providedat each landing valvel 8.2.3 Breeching Inlet The fire brigadebreechinginlet installedat the bottom of the riser should comply with M.s.1210 : Part 3' where the breechinginlet is enclosedwithin a box, the enclosureshould comply with M's'1210 Part 5 and labeled'DryRiser Inlet'.A drain shouldbe providedat the bottomof the riser to drain the system after use. A two-waybreechinginlet should be providedfor a 1oomm dia. dry riser while a 150mm dia. dry risershouldbe installedwith a 4-way breechinginlet. Breechinginletsshould be locatedno more than 18 metresfrom the fire applianceaccessroad and not moie than 30 metresfrom the nearest externalhydrantouflet. 8.2.4 Riser Pipe The riser pipe diameterusuallylocatedwithinthe fire accesslobbyor staircaseshould be 1sgmm if the highestoutletis more than22.875metresabove the breechinginlet.otherwise,the riserpipe can be 100mmin diameter.The riserpipeshallbe galvanised of iron to B.s.13g7(Heavygauge) or Class C, testedto 21 bars. Horizontalruns of pipeworkfeedingthe risersshould be slopedto enableproperdrainingafter use. An air releasevalve shouldbe installedat the top of the riserto reliefair trappedin the system.
111
The riser pipe should be electricallyearthedor connectedto the buildingearth to achiev equipotential.
8.3 TEST REQUTREMENTS 8.3.1StaticpressureTest The systemshouldfirst be flushedto clearall debrisfromthe insideof the riser.The riser is ther hydraulically testedto a pressureof 14 barsfor 2 hours, measuredat the breechinginletand i checkis carriedoutfor reakage at thejointsandrandingvarveconnections. 8.4 MAINTENANCEREQUIREMENTS 8.4.1Inspectionand Testing The breechinginlets,landingvalvesand hoses, dry riserpipe,drainvalvesandcabinetsshould be inspectedregurarry to ensurethattheyare in goodop"r"iingcondition. 8.5 DESIGNCHECKLIST (a)
Dry riseris requiredfor buildingwhichthe topmost flooris morethan 18.3metresbut less than30.5metresabovefireapplianceaccess.
(b)
Totalnumberof landingvalve _
(c)
Risingmaintocation: O In stairwayenclosure. Q Withina firefightingtobby. Q Other:
(d)
Riserdiameter:
(e)
Pipe materiat:
(f)
Lowestpointof randingvarveat about750mm abovefloorrever.
(g)
Firebrigadebreechinginlet: fl Two-waypumpinginlet e Four_way pumpinginlet
nosperriser.
mm.
8.6 VISUAL INSPECTIONCHECKLIST 8.6.1VisualInspectionof WaterSupplies Breeching inlet.
,
8.6.2VisualInspectionof LandingValves Locationof valves. Capsfor oufletof landingvalves.
112
8.6.3Visual Inspectionof pipework lsolatingvalvefor hosereel. Physicalconditionof hosereeldrum,hose,nozzles,etc. 8.6.4VisualInspectionof pumps Typeof pipesused. Protection of underground pipework. Paintingof pipework. Pipesupports. Pipesleeves. Fireseal.
8.7 TESTINGAND COMMISSIONING CHECKLIST 8.7.1Testingand Commissioningof pipework Hydrostatic testingof pipework. Flushingof pipework.
113
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9.1DESCRIPTION [Wet risers are a form of internal hydrantfor the firemen to use and are always chargedwith water. Wet risersare only requiredfor buildingswhere the topmostfloor is higherthan 30.5 metresabove the fire applianceaccesslevel. Wet risersystemcomprisesduty fire pump with standbypump dischargingintoa 150mmdiameter riserpipewith landingvalvesat each floorand to whichcanvashosewith nozzlescan be connected to directthe waterjet at the fire.A jockeypump is usuallyprovidedto maintainsystempressure.For high rise buildings,each stage of the wet risershouldnot exceed70.15 metres. A typicalwet riserinstallationis shown in Figureg.1.
9.2 DESIGNREQUIREMENTS 9.2.1DesignStandards The requirements for wet risersystemsis describedunderBy-law231,232and248of the Uniform Building By-Laws,1984andthe applicable standards are: -
M . S . 1 4 8 9Part 1 - HydrantSystems,Hose Reelsand Foam Inlets: M . S . 1 2 1 Part 0 1 - LandingValvesfor Wet Risers; M . S . 1 2 1 0Part 3 - InletBreechingfor Riser Inlets; M . S . 1 2 1 0Part 4 - Boxes for LandingValves for Dry Risers.
9.2.2Wet Riser Landing Valve Landingvalves are providedon each floor and should comply with M.S.1210: part 1. They are usually located within fire fighting access lobbies, protectedstaircasesor other protectedlobbies, and installedat not more than 0.75 metresfrom the floor. To protectthe landing valves, boxes can be providedand theseshouldcomplywith M.S.1210: part 4. The pressureat the landingvalve should be no less than 4 bars and not more than Z bars. To achievethis, there are two types of landingvalves i.e. pressurereducingtype with or without relief outlet.Those with reliefoutlets require a wet riser return pipe. Fire hose of the canvas type of not less than 38mm dia. 30 metres in length, completewith 65mm Jia' quick couplingand jet and spray nozzleshould be providedin a hose cradle beside each andingvalve. 9.2.3Breeching Inlet /fith the fire brigadebreechinginlets the firemen can pump water into the wet riser storage tank to nake up for waterused.The breechinginletshouldbe a 4-waytype complyingwith M.S.1210: part l. Where the breechinginlet is enclosedwithina box, the enclosureshouldcomplywith M.S.1210 )art 5 and labelled'Wet Riser lnlet'. A drain should be providedat the bottomof the riserto drain he system after use. 3reechinginletsshouldbe locatedno morethan 18 metresfrom the fire applianceaccessroad and lot more than 30 metresfrom the nearestexternalhydrant.
115
9.2.4Wet Riser Pipe The wet riser mains are usuallylocatedwithin smoke free lobby or protectedareas and such that all spacesare to be withina 45 metrescoveragefrom a landingvalve.Where more than one riser is requiredfor each floor,the distanceapart betweenthe risersshouldnot exceed60 metres.The distancebetweenthe lowestand topmostlandingvalvein any upperstage risershouldnot exceed 60 metres.The riserpipediametershouldbe 150mmgalvanisedironto 8.S.1387(Heavygauge)or ClassC. Where a reliefpipe is required,this returnpipe shall be minimum100mmdia. galvanised iron to 8.S.1387 (Mediumgauge) or Class B, dischargingback to the wet riser tank wherever possible.An air releasevalve should be installedat the top of the riserto reliefair trapped in the system. All wet riserpipesshouldbe coatedwith primerand finishedwith red gloss paint.Alternatively, the pipecan be colourcodedwith red bandsof 100mmwidthand the elbowsand tees paintedred. The riserpipe shouldbe electricallyearthedto achieveequipotentialwiththe building. 9.2.5 Wet Riser Pumps The wet riser pumps draw water from wet riser storage tank and two sets of pumps, one on duty and the other on standby,are provided.The pump capacityis usually sized to delivera flow rate of 1500 l/minat a runningpressureof not less than 4 bars but not more than 7 bars,when any three landingvalvesare in use at the same time. The standbywet riserpumpsetshouldbe suppliedwith powerfrom the emergencygeneratorif this is available.Otherwise,the standbypumpsetshould be diesel enginedriven.Fuel supplyshould be adequatefor minimum2 hours of continuousoperation.Electricalcablingto supply power to the wet riser pumpsshouldbe of MICC or fire ratedtype. Batteriesfor the dieselengineshould be maintenance-free type. The wet riser pumpsetsshould be protectedfrom fire and away from locationslikelyto be flooded. Sump pumps shall be installedwhere the fire pump room is located in the basementbelow external drainagelevels.lt shouldalso be ventilatedby naturalor mechanicalmeansand providedwith the necessarysignage.A carbondioxidetype portableextinguishershouldbe providedas well. 9.2.6 Wet Riser Tanks The fire water storage tank should be sized for a minimum effectivecapacityof 45,500 litres with automatic refill rate of 455 l/min. The intermediatebreak tank for upper stages of the wet riser shouldbe not lessthan 11,375litreswith an automaticmake-upflow of 1365l/min. Wet riser tanks may be of pressedsteel, fibre reinforcedpolyester(FRP) or concrete.pressed steel tanks where used should be hot dipped galvanizedand coated internallywith bituminouspaint for corrosion protection.The water tanks should be compartmentedunless they are of reinforced concrete.Ballfloatvalves,overflowpipes,drain pipesand waterlevelindicatorsshouldbe provided for each compartment.The externalsurfaceof the tank should be paintedred or where this is not desirable,a red band of minimum200mm shouldbe paintedto indicatethat this is a fire tank. The wet riser tanks may be located on the ground floor, first or second basement.The wet riser tanks are usuallyseparatedfrom other water storagetanks. However,it may be combinedwith hose reel tank, in which cases the tank capacity should be the sum total of the water storage for both wet riser as well as for hose reel system. The hose reel tap off level should be above the wet risertap off levelsuch that the wet riserreseryeis maintained.
1't6
9.2.7PumpStarterpanelsand Controls Pumpstarterpanelshouldbe complete withindicator lightsas shownin the Figureg.2.Ventilation slotsshouldbe providedwithinsectscreento prevententryof vermin.power supptycablesto the panelshouldbe of mineralinsulated coppercable(MICC)or fireratedtyperoutedwithinareaswith lowfire risk.The pumpstarterpanelshouldbe placedwithinthe sameroom as the fire pumpsit controls. wet riserpumpsareautomatically starteduponactuation of the pressureswitchesbutshouldonly be stoppedmanually'Usuallythreepressureswitchesare providedwiththe followingsuggested pressuresettings: - startingthe dutypumpsetsetat g0%of the systempressure; - startingthe standbypumpsetset at 60% of thesystempressure;and - startingandstopping thejockeypumpsetsetat 90% and110%of thesystempressurerespectively. Thepressureswitchesarenormallyinstalled in thetestanddrainlineon thepumpdischarge side. The pressuresettingsshouldbe clearlylabelledon tagsattachedto eachpr"r"ui" switch. 9.3 TEST REQUIREMENTS 9.3.1StaticPressureTest The systemshouldfirstbe flushedto clearall debrisfromthe insideof the riser. The riseris then hydrauf icallytestedto a pressureof 14 barsor 150o/othe workingpressure,whicheveris the higher for 2 hours,measuredat the lowestlandingvalveanda checkis carriedoutfor leakageat thejoints andlandingvalveconnections. 9.3.2Flow Test A threeway landingvalveshouldbe providedon the roof or topmostfloorfor testingpurposes. Meansshouldbe providedto measurethe waterflowrate. 9.4 MAINTENANGEREQUIREMENTS 9.4.1Inspectionand Testing A flow test shouldbe carriedout to ensurethat the pumpsare in properworking condition.The pipework shouldbe checkedfor leakageandthebreeching inlets,landingvalvesand hoses,drain valvesand cabinetsshouldbe inspectedas recommended in the checklistattached. 9.5 DESIGNCHECKLIST (a)
Wet riseris requiredfor buildingwherethe topmostflooris morethan30.5metres above fireappliance access.
(b)
A minimumflow rate of 500 litres/minute at runningpressureof 4 to 7 bars is maintainedat each landingvalvewhen three numbersof the furthestlandingvalvesare fully opened.
117
(c)
Watersource: Q Pumpsuctiontank. D Firewatermain. Q Other:
(d)
Multi-stagesystemshall be installedfor highestoutletmore than 70.15metresabove pump level.
(e)
Each stageof riserdoes not exceed60 metres.
(0
Landingvalvesshall be pressureregulating/ reducingtype.
(g)
Total numberof landingvalve per stage: . Stage 1 :--nos. .Stage2:-_-nos.
(h)
Three way 63.5mm ouflets are providedat locationabove the roof line.
0)
Riserspacinn'_
_metres.
Risingmain location: O In stairwayenclosure. D Within fire fightingtobby.
(k)
O Other:
(l)
Numberof fire hose provided: _nos.
(m)
Hosesize :_
(n)
Breaktank capacity: 11,375titres.
(o)
Water tank capacity: 45,500 litres
(p)
Minimumnominaldiameterof riser shall be 150mm.
(q)
Pipe material:
(r)
Lowestpointof landingvalveat about7s0mmabovefloorlevel.
(s)
To providefirebrigadebreeching inlet.
mm ; length:
Wet riserpump: . Ratedflow rate:
litres/minat
metrehead.
(t)
. Rated power:
(u)
Pipe nominalsize: Suction:
(v)
For dieselengine: ' Fuel capacitysufficientto run engineat full road for _ hours. ' Reservesupplyof fuel for hours of engine full load running. _
KW mm ; Delivery:--..-
118
mm
9.6VISUALINSPECTION CHECKLIST 9.6.1VisualInspectionof WaterSupplies Capacity of wateravailable. Compartmentation of watertanks. Primingtank(if any). Monitoring of watertanklevel. Vortexinhibitorsfor watertanks. Breeching inlet. 9.6'2visual Inspectionof LandingVarvesand Accessories Locationof landingvalve. Storageof canvashoseand accessories. Physical condition of canvashose,accessories and randingvarve. Capsfor outletof landingvalves. 9.6.3Visual Inspectionof pipework Typeof pipesused. Protection of underground pipework. Paintingof pipework. Pipesupports. Pipesleeves. Fireseal. 9.6.4VisualInspectionof pumps Protection of rotatingpartsof pumpsets. Mounting of pumpsets.
9.7 TESTINGAND COMMISSIONING CHECKLIST 9.7.1Testingand Gommissioningof WaterSupplies Pumpoperating currentandvoltage. Pumpoperating pressure andflowrate. Pumpoperating RpM.
119
Pumpnotoverheating. Vibration and noiselevel. Testingof electricalwiringsystem. Alternative powersupplyfor electricpumps. Batteries for dieselpumps. Fuelfor dieselpumps. Automaticoperationof pumps. 9.7.2Testingand Commissioningof pipework Hydrostatic testingof pipework. Flushingof pipework. 9.7.3Testingand Commissioningof LandingValves Pressureat landingvalveouflet. Flowrateof water.
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10.1DESCRIPTION Downcomersare also a form of internalhydrantfor the firemento use and are always chargedwith water from a water tank locatedat the top of a buildingbut withoutany pumps. Downcomersare only permittedfor privateresidentialbuildingswith open balconyapproachwherethe topmostfloor is not higherthan 60 metresabove the fire applianceaccess level and should be adoptedfor low cost flats only. Downcomersystemcomprisesa high levelwaterstoragetank discharginginto a 150mmdiameter riserpipewith landingvalvesat each floorand to whichcanvashosewith nozzlescan be connected to direct the water jet at the fire. No pumps are provided and therefore the system pressure is limited to the static pressureonly. A typicaldowncomerinstallationis shown in Figure10.1.
10.2 DESIGNREQUIREMENTS 10.2.1DesignStandards The sectionin the UniformBuildingBy-laws1984,relatingto downcomersystemsis the 1Oth Scheduleand relevantstandardsfor downcomersystemsare: M . S . 1 4 8 9 Part 1 M . S . 1 2 1 0Part 1 M . S . 1 2 1 0Part 3 M . S . 1 2 1 0Part 4 -
HydrantSystem,Hose Reels and Foam Intels; LandingValves for Wet Risers; InletBreechingfor Riser lnlets; Boxes for LandingValves for Dry Risers.
10.2.2Downcomer Landing Valve Landingvalves are providedon each floor and should comply with M.S.1210: Part 1. They are usually locatedwithin fire fighting access lobbies, protectedstaircasesor other protectedlobbies, and installedat not more than 0.75 metresfrom the floor. The pressureat the landing valve depends on the static pressureon the valve from the roof tank. Semi-rigid40mm diameterhose and nozzlesshould be providedat every landingvalve on each floor. In addition,two sets of fire hose of the canvas type of not less than 38mm diameter,30 metres in length,completewith 65mm dia. quick couplingand jet and spray nozzleshouldbe providedat the caretakersunit or managementoffice. 10.2.3Breeching Inlet The fire brigadebreechinginletsinto which the firemenpumpswater are providedat the bottomof the riser at the groundfloor so that the firemencan pump water into the downcomersystem.The breechinginlet should be a 4-way type complyingwith M.S.1210: Part 3. Where the breeching inlet is enclosedwithina box, the enclosureshouldcomplywith M.S.1210: Part 5 and labeled 'Downcomer lnlet'.A drain should be providedat the bottomof the riser to drain the system after use. Breechinginletsshouldbe locatedno morethan 1B metresfrom the fire applianceaccessroad and not more than 30 metres from the nearestexternal hydrant.
123
A check valve is installedbetweenthe topmostlandingvalve and the tank to preventback flow of waterfrom the downcomerinto the tank. 10.2.4Downcomer Pipe The downcomermains are usuallylocatedwithinsmokefree lobbyor protectedareas and that all spacesare to be withina 45 metrescoveragefrom a landingvalve.Where more than one riser is requiredfor each floor, the distance apart between the risers should not exceed 60 metres. The riserpipediametershouldbe '150mm galvanisedironto 8.S.1387(Heavygauge)or ClassC. An air releasevalve shouldbe installedat the top of the riserto reliefair trappedin the system. All downcomerpipes shouldbe coatedwith primerand finishedwith red gloss paint.Alternatively, the pipe can be colourcodedwith red bandsof 100mmwidthand the elbowsand tees paintedred. The riserpipe shouldbe electricallyearthed. 10.2.5Fire Water Tanks The fire water storage tank should be sized for a minimum effectivecapacityof 45,500 litres with automaticrefill rate of 455 l/min. The tanks may be of pressed steel, fibre reinforcedpolyester (FRP) or concrete. pressed steel tanks where used should be hot dipped galvanizedand coated internallywith bituminouspaint for corrosionprotection.The water tanks should be compartmentedunless they are of reinforced concrete and ball float valves, overflow pipes, drain pipes and water level indicators should be providedfor each compartrnent.The external surface of the tank should be painted red or where this is not desirable,a red band of minimum200mmshouldbe paintedto indicatethat this is a fire tank. The tanks are usuallylocatedon the roof to providethe maximumstatic pressurepossible.The tank is usually separatedfrom other water storagetanks. However,it may be combined with hose reel tank, in which cases the tank capacity should be the sum total of the water storage for both the downcomer as well as for hose reel system. The hose reel tap off level should be above the downcomertap off level such that the water is reservedfor the downcomer.
10.3TESTREQUIREMENTS 10.3.1 StaticPressure Test The systemshouldfirst be flushedto clear all debrisfrom the insideof the riser.The riser is then hydraulicallytested to a pressureof 14 bars or 150%the working pressure,whicheveris the higher for 2 hours,measuredat the breechinginletand a checkis carriedout for leakageat the joints and landingvalve connections.
10.4MAINTENANCE REQUIREMENTS 10.4.1 Inspection andTesting The pipeworkshould be checkedfor leakageand the breechinginlets,landingvalvesand hoses, drain valvesand cabinetsshouldbe inspectedas recommendedin the checklistattached.
124
1 0 . 5D ES IGNC H E C K L IS T (a)
Downcomersystem( modifiedrequirementby UBBL is only applicablefor flats which ) the topmostfloor is less than 60 metresabovefire applianceaccess but exceedthe maximum heightrequirementof dry risersystem.
(b)
Total numberof landingvalve :
(c)
Numberof fire hose provided: _nos.
(d)
Hosesize :_
(e)
Stack main location: Q In stairwayenclosure. D Withina ventilatedlobby. O Other:
(0
Stackdiameter:
(g)
Pipe material:
(h)
Lowestpoint of landingvalve at about zSommabovefloor level.
(i)
To provide fire brigade breechinginlet.
nos per stack.
mm ; length:_
m.
mm.
10.6VISUALINSPECTION CHECKLIST 10.6.1 VisualInspection of WaterSupplies Capacityof water available. Compartmentation of water tanks. Breechinginlet. 10.6.2Visual Inspection of Landing Valves and Accessories Locationof landingvalves. Storageof canvashose and accessories. Physicalconditionof canvashose, accessoriesand landingvalve. Caps for outletof landingvalves. 10.6.3Visual Inspection of Pipework Type of pipes used. Paintingof pipework. Pipe supports.
125
i
1 0 . 7T E S T I N GA N D C O M M I S S I O N I N C GH E C K L I S T 10.7.1Testingand Commissioningof WaterSupplies Flowrateandpressure of watersupplies. 10.7.2Testingand Commissioningof Pipework Hydrostatic testingof pipework. Flushing of pipework.
126
Figure 10.1Down Comer System Typical Arrangement Drawing SCALE: N.T.S / EQUIPMENT COMPONENT 1 WaterTank 2 4-WayBreechingInlet 3 Vent Pipec/w MosquitoNet 4 AccessOpening 5 Level lndicator 6 ExternalCat Ladder 7 Overflow Pioe 8 WarningPipe 9 Gate Valve 10 CheckValve 11 LandingValve 12 Hose with Nozzleat ManagementOffice '13 Air ReleaseValvec/w Ball Valve
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1 1 . 1D E S GR IP T ION An automaticsprinklersystem is intendedto detect,controland extinguisha fire, and warn the occupantsof the occurrenceof fire. The installationcomprisesfire pumps, water storagetanks, controlvalve sets, sprinklerheads,flow switches,pressureswitches,pipeworkand valves.The system operatesautomaticallywithouthuman intervention.The sprinklerhead has a liquidfilled glass bulb that breaksdue to the heat of the fire and releaseswater that spraysover the fire. The various types of sprinklersystems are as follows: (a)
Wet pipe installationwherethe pipeworkis filledwith waterand readyto dischargeonce the sprinklerbulb breaks.
(b)
Dry pipe installationwhere the pipe is alwaysfilledwith air under pressure.Air is released when the sprinklerbulb breaksand waterfillsthe pipe and is dischargedat the sprinklerhead.
(c)
Pre-actioninstallationwhere the pipeworkis normallychargedwith air under pressure and a valve is openedto fill the systemwith water when fire is detectedby smoke or heat detectors. Water is dischargedonly when the sprinklerbulb breaks.
(d)
D e l u g e i n s t a l l a t i o nw h e r e t h e s p r i n k l e rh e a d h a s n o b u l b a n d w a t e r i s d i s c h a r g e d simultaneously from all headswhen fire is detectedand the delugevalve is opened.
The wet pipe installationis the most commontype and a typicalsprinklersystemis shown in Figure 11.1. Sprinklersinstalledat 17 metres and above the floor to be protected ard no longer effectiveand alternative solutions such as early response sprinkler heads, large droplet spiint
1 1 . 2D E S I G NR E Q U I R E M E N T S 11.2.1DesignStandards Underthe UniformBuildingBy-laws1984,By-laws226 and 228 refer to the requirements for sprinklersystems.The acceptedstandardsfor automaticsprinklerinstallations are : - BS EN 12845:2003- Automatic Sprinkler systems- Design,installation and maintenance. . N F P A1 3 . Wherea particular standardis adopted,the sprinkler systemshouldfollowthe selectedstandard in totalandshouldnotrelyon clausesin otherstandards unlessthespecificaspectis notcovered in the selectedstandard. 11.2.2OccupancyHazardGroups sprinklersystems are designedbasedon the hazardclassification described in the Bs EN 12845 as follows: (a)
Light Hazardfor non-industrialoccupancieswith low quantityand combustibility contents, eg. apartments,schoolsand hospitals.
128
(b)
handlingand storingordinary occupancies and industrial OrdinaryHazardfor commercial grouped under: further is and materials combustible - OH GroupI for offices,restaurants andhotels; - OH Groupll for laundries, bakeriesandtobaccofactory; - OH Group11for carparks,departmental stores,largeretailshopsandcinemas,clothing and andpaintfactories, studios. - oH Groupllls for matchfactories, filmandtelevision
is the hazardclass recommended For high rise buildingswith multipletype of occupancies, OrdinaryHazardGrouPlll. (c)
loadscovering havingabnormalfire occupancies andindustrial HighHazardfor commercial and is hazards liquid flammable and oil and piled hazards storage processhazards,high furthergroupedunder: -
and rubber,woodwooland paintfactories; Processrisk,e.g.clothing, as follows: categories four into divided further is Highpiledstorageriskswhich height; in category| for carpetsandtextileexceeding4 metres Categoryll for furniturefactorypiledabove3 metreshigh; categorylll for rubber,wax coatedpaperpiledhigherthan2 metres; CategorylV for foam,plasticspiledabove1.2metresin height'
11.2.3SprinklerPumPs The sprinklerpumpsdraw waterfrom sprinklerstoragetank to feed the sprinklernetwork.Two togetherwitha jockeypumpto are provided setsof pumps,oneon dutyandthe otheron standby, to meetthe dutiesdefined selected pumpcapacityshouldbe Sprinkler maintainsystempressure. dependon the for the variousclassesof hazards.The nominalpressureand flow requirements heightmeasuredbetweenthe topmostand bottommostsprinklerheadand are as listedbelow: (a)
Light Hazard - 15 metres: 300 cu dm/minat 1.5 bars - 30 metres: 340 cu dm/minat 1.8 bars - 45 metres: 375 cu dm/minat 2.3 bars
(b)
OrdinaryHazardGrouPI - 15 metres: 900cu dm/minat 1-2bars - 30 metres: 1150cu dm/minat 1.9bars - 45 metres: 1360cu dm/minat2.7 bars
(c)
OrdinaryHazardGrouPll - 15 metres: 1750cu dm/minat 1.4bars - 30 metres: 2050cu dm/minat 2.0 bars - 45 metres:2350cu dm/minat 2.6 bars
(d)
OrdinaryHazardGrouPlll - 15 metres:2250cu dm/minat 1.4bars - 30 metres:2700cu dm/minat 2.0bars - 45 metres: 3100cu dm/minat 2.5 bars
129
(e)
OrdinaryHazardGroup llls - 15 metres: 2650 cu dm/minat 1.9 bars - 30 metres : 3050 cu dm/min a12.4 bars
In additionto the above flow requirements, the sprinklerpump shouldbe capableof satisfyingtwo otherflows and pressuresas describedin BS EN 12845. Wherethe buildingexceeds45 metres,multiplestagesof sprinklerinstallations have to be installed such that the multiplestageswill be able to servethe full heightof the buildingwith each stage not exceeding45 metres. The standbysprinklerpumpsetshouldbe suppliedwith powerfrom the emergencygeneratorif this is available.Otherwise,the standbypumpsetshouldbe dieselenginedriven.FuelsJpplyshouldbe adequatefor minimum4 hours of continuousoperationfor OrdinaryHazardand 6 hoursfor High Hazardapplications.Electricalcablingto supplypower to the sprinklerpumps should be of MICC or fire rated type. Batteriesfor the diesel engine should be maintenance-freetype. For sprinklerpumps protectinghigh rise buildings,the staticpressurebetweenthe pump and the lowestsprinklerhead shouldbe added to the above pump pressurerequirement. The sprinklerpumps should be under positivehead as far as possible,protectedfrom fire and away from locationslikelyto be flooded.Sump pumpsshall be installedwhere the fire pump room is locatedin the basementbelow externaldrainagelevels.lt should also be ventilatedby natural or mechanicalmeans and providedwith the necessarysignage.A carbon dioxidetype portable extinguishershouldbe providedas well. Where fire pumps are provided for hydrant systems, the water supply for the sprinkler system can be taken off from the fire mains providedthe fire pumps and tanks are sized for simultaneous operationof the hydrantand sprinklersystems.Pressurereducingvalves should be providedin such cases as the hydrantpressureis usuallyvery much higherthan that requiredfor the sprinkler system. 1'|..2.4Pump Starter Panels and Gontrols Pump starterpanelshouldbe compartmentedfor each of the duty,standbyand jockey pumps and completewith indicatorlightsas shown in the Figure11.2.Ventilationslotsshouldbe provided with insect screen to prevent entry of vermin. Power supply cables to the panel should be of mineral insulatedcopper core (MICC) or fire rated type routed within areas with low fire risk. The pump starterpanelshouldbe placedwithinthe same room as the fire pumps it controls. Three pressureswitchesshouldbe providedat each installation for startingof the sprinklerpumps with the followingsuggestedpressuresettings: - startingthe duty pumpsetset at B0% of the systempressure; - startingthe standbypumpsetset at 60% of the systempressure;and - s t a r t i n ga n d s t o p p i n gt h e j o c k e y p u m p s e t s e t a t 9 O %a n d 1 1 O Yo f t h e s y s t e m p r e s s u r e respectively. Electricalinterlocksshouldbe providedso that the sprinklerpumps at each installationshould not operatein parallelsimultaneously. A buzzershouldbe soundedshouldthe isolatorbe in the off or manualposition, Sprinkerpumpsetsshouldbe capableof automaticstartingbut shouldonly be stoppedmanually.
130
11.2.5Sprinkler Tanks The sprinklerstoragetank not dependenton inflow should have a minimum effectivecapacity depending on the hazard classificationand the height of the lowest to highest sprinklernot exceedingthe following: (a)
LightHazard - 15 metres: 9 cu. metres - 30 metres: 10 cu. metres - 45 metres: 11cu. metres
(b)
OrdinaryHazardGroupI - 15 metres: 55 cu. metres - 30 metres: 70 cu. metres - 45 metres: B0cu. metres
(c)
OrdinaryHazardGroupll - 15 metres: 105cu. metres - 30 metres: 125cu.metres - 45 metres: 140cu. metres
(d)
OrdinaryHazardGrouplll - 15 metres: 135cu. metres - 30 metres: 160cu. metres - 45 metres: 1B5cu. metres
(e)
OrdinaryHazardGrouplllS - 15 metres:160cu.metres - 30 metres:185cu. metres
(f)
High Hazard Storagecapacityshall be dependenton the design densityof dischargein mm/min.
Sprinklertanks may be of pressedsteel,fibre reinforcedpolyester(FRP) or concrete.Pressedsteel tanks where used should be hot dipped galvanizedand coated internallywith bituminouspaint for corrosion protection.The water tanks should be compartmentedunless they are of reinforced concrete and ball float valves, overflow pipes, drain pipes and water level indicatorsshould be provided for each compartment.The external surface of the tank should be painted red or where this is not desirable,a red band of minimum200mm shouldbe paintedto indicatethat this is a fire tank. The sprinklertanksnot dependenton inflowmay be locatedin any location.The sprinklertank may be combinedwith hose reel tank in which cases,the tank capacityshould be the sum total of the water storagefor both the sprinkleras well as for the hose reel system. The hose reel tap off level should be above the sprinklertap off level so that the water reservedfor sprinklersystem is always maintained. 11.2.6Breeching lnlet Breechinginletsare providedso that the firemencan pump water into the sprinklertank to make up for water used. The breechinginlet should be a 4-way type complyingwith M.S.1210:Part 3. Where the breechinginlet is enclosedwithin a box, the enclosureshould complywith M.S.1210: Part 5 and labelled'Sprinklerlnlet'.A drain should be providedat the bottomof the riser,todrain the system after use.
131
Breechinginletsshouldbe locatedno more than 18 metresfrom the fire applianceaccessroad and not more than 30 metres from the nearest externalhydrantouflet. 1'1.2.7Sprinkler Heads Sprinklerheads are generallyof the conventionalpendantor uprighttype. The temperaturerating of the bulb is selectedbased on minimum30"C above the maximumambienttemperatureof the space protected.Typically,this will resultin a nominaltemperatureratingof 6B'C. In kitchenareas, the sprinklerheads shouldhave a temperatureratingof 79.C. The maximumspacingand coverageto be protectedby one sprinklerhead shall be as follows: - 21 sq. m for lighthazardinstallationat not more than 4.6m apart; - 12 sq. m for ordinaryhazardinstallationsat not more than 4m apart;and - 9 sq.m for high hazardinstallationsat not more than 3.7m apart. Generallyall areasof the buildingshould be protectedwith sprinklersexceptfor the following: - Staircasesenclosures; - Electricalrooms; and - Toilets Wherethe ceilingvoid exceeds800mm,sprinklersshouldbe providedwithinthis spaceunlessthey are of non-combustibleconstructionand do not contain combustiblematerials.Electricalwiring withinsuch ceilingvoid shouldbe containedin steel conduitunlessthey are of the fire ratedtype. Sprinklerheadsshouldnot be subjectedto pressurein excessof 12 bars,especiallyin the case of high rise buildings. 11.2.8Installation Control Valve Each sprinklerinstallationshould have installationcontrol valves comprisingmain stop valves, alarm valves,drain line with stop valves,water flow gauges and pressuregauges.The maximum no. of sprinklersto be feed from one set of installationcontrol valve shall be: (a) (b) (c)
Light hazard : 500 sprinkters Ordinary hazard : 1000 sprinklers High hazard : 1000 sprinklers
For sprinklersystemsdesignedfor life safety,the arrangementshall be a duplicatealarm valveset each with downstreamand upstreamstop valves,flow and pressuregauges,and alarm test line. Alternatively, the arrangementcan be a singlealarmvalveset with downstreamand upstreamstop valves,flow and pressuregauges, alarm test line and a bypass with stop valve. All stop valves except for the bypassvalves should be locked in the open positionand its status monitoredby the fire alarm system.Flow switchesshould be providedabove the installationvalves provide to indicationof flow of water. The maximum no. of sprinklersto be feed from one set of installation controlvalve for life safety systemsshall be 200 sprinklersper zone, with no limit on the no. of zones. For car parks, separateinstallationcontrolvalve shall be providedto serve not more than 1000 sprinklerheads each.
132
where the sprinklersystem is sub-dividedinto zones, each floor of the buildingprotectedshould be designed as one or more zone' A flow switch should be provided in the di"trioution pipe to each zone to provideindicationof flow of water to sprinklers withinthat zone. Electricalmonitored subsidiarystop valve shouldbe also be providedfor each zone to give monitoringatarmsignalon the main fire ararmpanerwhenthe varveis not in the fuily open position. 11.2.9Sprinkler pipework sprinklerpipeworkshall be of black steelor galvanizediron to 8.s.13g7 (Mediumgrade) class B minimumwhile undergroundpipeworkshould be heavy gauge of class c. pipes lr ri.", g0mm and belowshouldbe installedwith screwjoints and onrypipeJ 1oommand above may be welded. welding proceduresand materialsshall be in accordance with 8.s.2640 and 8.s.2g71 and should be carriedout by qualifiedwelders.Radiographictests should be carriedout where doubts exist. Alternatively,mechanicalgroovedcouplingcan be used for jointing for all pipe sizesup to 250mm. sprinkler piping should not be concealedin the floor or ceiling concreteslabs. All piping should be painted with primer and finished with red gloss paint or otherwise identifiedwith red bands of 100mmwidth minimumat elbows and tees. For high rise buildings,the pressure loss through the distributionpiping includingrisers and droppersbetweenthe highestdesignpointin the installation and the zone subsidiarystop valve at the same floor shall not exceed 0.5 bars at a flowrate of 1000 l/min. This allowable pressure loss may be increasedfor those sprinklersbelow the highest design point but should not exceed the statichead gain betweenthe sprinklerconcernedand the highestsprinklerpoint.
11.3TEST REQUIREMENTS 11.3.1StaticPressureTest The systemshouldfirstbe flushedto clearall debrisfromthe insideof the riser.The riseris then hydraulically testedto a pressure of 14barsor 150%theworkingpressure, whichever is the higher for 24 hours,measuredabovethe installation controlvalveani a checkis carriedout for leakage at thejointsandlandingvalveconnections. 11.3.2FlowTest Thetestvalveon thedrainlineof the installation controlvalveshouldbe openedto permitfull flow. Theflowrateand pressureshouldbe recordedand checkedagainst the designflowraterequired. Eachzoneshouldbe testedby openingthe isolation valveon thetestline.Theflowswitchfor that zoneshouldindicate an alarmon thefirealarmpanel. 11.4MAINTENANCEREQUIREMENTS 11.4.1Inspectionand Testing \ flowtestshouldbe carriedout at the installation controlvalveto ensurethat the pumpsare in )roperworkingcondition. Thepipework shouldbe checkedfor leakageandthe installation control ralves,sprinklers, breeching inletsand drainvalvesshouldbe inspected as recommended in the :hecklist attached. lhe zone flow switchesshouldbe testedand the alarm shouldbe indicatedon the fire alarm tanel.
133
1 1 . 5D E S IGNC H E C K L IS T (a)
Classificationof fire hazard : _
e D a D
Lighthazard Ordinaryhazard: Highhazard Processhazard:Type
O High piledstoragehazard:fype
C Portablespiritstoragehazard: Type Q Oilandflammable liquidhazard:-fypE fl Other: (b)
SystemType: C Wet D Pre-action Q Deluge C Other:
(c)
For high piled storage hazard : . Storagecommodity: . Storageheight: . Ceilingheight:
(d)
Designdensity:
(e)
Designareaof operation :
(litres/min)/ rpz m2
(f)
Watersource: D Pumpsuctiontank fl Firewatermain fl Gravitytank C Other:
(g)
Designwatersupplycapacity:
(h)
Durationof watersupply:
(i)
Water tank high / low level monitoring.
0)
Hydrauliccalculation: Q Fullycalculated fl Pre-calculated
(k)
Sprinklertype : fl Conventional O Spray tr Other:
(t)
Sprinklertemperature rating: ---*-
m3
minute.
.C
134
11.6.2VisualInspectionof Sprinklers Spacingof sprinkler heads. -
areaof coverage maximumandminimumdistancebetweensprinklers maximumandminimumdistancebetweenwalls/ partitions distancefrombeams,columnsand otherobstructions obstruction belowsprinklers depthand combustibility of ceilingvoid clearspacebelowsprinklers
Physicalcondition of sprinkler heads. Temperature ratingof sprinklerheads. guards. Sprinkler Sparesprinklersand sprinklerspanners. 11.6.3Visuallnspectionof pipework Typeof pipesused. Protectionof underground pipework. Paintingof pipework Numberof sprinklers installed on rangeanddistribution pipes. Pipehangersand supportsfor pipework. Pipesleeves. Fireseal. Flowswitches. Totallengthof pipeworkbetweenalarmvalveandwateralarmgong. 11.6.4VisualInspectionof Sprinklerpumps Protectionof rotatingpartsof pumpsets. Mounting of pumpsets.
11.7TESTINGAND COMMISSIONING CHECKLIST 11.7.1Testingand Gommissioning of WaterSupplies Pumpoperatingcurrentand voltage. Pumpoperatingpressureandflow rate.
136
Pumpoperating RPM. Pumpnotoverheating. Vibrationand noiselevel. Testingof electricalwiringsystem. Alternativepowersupplyfor electricpumps. Batteriesfor dieselpumps. Fuelfor dieselpumps. Automaticoperationof pumps. 11.7.2Testingand Commissioningof pipework Hydrostatic testingof pipework. Flushing of pipework. Spraypatternof sprinkler. Alarmgongoperating. Flowswitchestest. Zonemonitoring (tamperswitch).
137
Table 11.1 Sample of Sprinkler Hydraulic Calculation PROJECT D"riS""d by
Checkedbv
HMARD CLASS , _ INSTALLATION VALVENO. .. DesignPoint Symbol
Floor
Ref. Grid Lines
A
3RD
c-D/3-1
Pipe Dia. (mm) 65
80 100
Annrnvcd
hrr
Job No OrdinaryCroup ltt I-'LOWRATE: 1000L/min Date 1 SIZEOFVALVE : 150mm Sheet Bends Total Static Pipe Total Flow Friction No. Equiv. Equiv. Head Length Loss less Rate Loss off Length Length Gain StaticHead (m) (dm3/min) ( m b ) (m) (m) (mb) (mb) E L O 3.5 1000 122 TE E L O 7 1000 t l l TE E L 2 49 6 1000 240 TE 473
B
3RD
c-Dt3-2
65
1
BO
1.9
t00
20
E L O TE E L O TE E L 1 TE
7
1000
243
1 0
1000
30
23
1000
'101 374
C
2ND
c-Dt2-1
65
10.5
80
16.9
100
28.3
E L O TE E L O TE
EL2 TE
6
I
10.5
1000
365
16.9
1000
268
34.3
1000
150 783
D
2ND
c-Dt2-2
8.8 80
0
100
16.3
E L O TE E L O TE E L 1 TE
3
8.8
1000
306
0
1000
0
19.3
1000
B4
390 E
GRD
c-Dt1-1
65
'10.5
80
38.9
100
2.5
E L O TE EL2 TE
10.5
1000
365
44.9
1000
712
2.5
1000
11
trLU
TE
1088 F
GRD
c-Dt1-2
65
8.9
BO
9.9
100
2.5
E L O TE E L 1 TE E L O TE
8.9
1000
309
12.9
1000
205
2.5
1000
11 525
Note : Pressurerossin a[ sectionsof distributionpipe shourdnot exceeds00mbar.
138
0
473
0
374
380
403
380
10
760
328
760
-235
Table 11.1 Sample of Sprinkler Hydraulic Calculation (Cont) PROJECT Designedby
Checkedby
Approveroy
Job No.
HMARD CLASS :
OrdinaryGroup lll FLOWRI\ TE :
INSTALATIONVALVENO. DesignPoint
1
Symbol
Floor
Ref. Grid Lines
G
3RD
c-D/3-1
Pipe Dia. (mm)
SIZE OF VALVE Bends Total
Pipe Length (m)
No.
BO
7
100
49
E L O TE E L O TE E L 2 TE
o3
off
Equiv. Length (m)
o
1000Umin
Date
50mm
Sheet
Flow Friction Static Equiv. Head Rate Loss Length Gain (dm3/min) (mb) (m) (mb)
3.5
1000
122
7
1000
111
55
1000
240 473
H
3RD
c-Dt3-2
65
80
1.9
100
20
E L O TE E L O TE E L 1 TE
?
1000
243
1.9
1000
30
23
1000
101 374
2ND
c-Dt2-'l
65
10.5
BO
16.9
100
28.3
E L O TE E L O TE E L 2 TE
o
10.5
1000
16.9
'1000
34.3
1000
I
2ND
c-Dt2-2
8.8
80 100
0 16.3
K
GRD
c-Dt1-1
65
10.5
80
38.9
100
z-J
o
L
GRD
c-Dt1-2
8.9 BO
9.9
100
2.5
J
8.8
1000
306
0
1000
0
19.3
1000
84
10.5
1000
365
44.9
1000
7' t2
2.5
1000
11
8.9
1000
309
12.9
1000
205
2.5
1000
11 525
Note : Pressureloss in all sectionsof distributionpipe shouldnot exceed500mbar.
139
0
374
380
403
380
10
760
328
760
-235
150
1088 E L O TE E L 1 TE E L O TE
473
zo6
390 E L O TE E L 2 TE E L O TE
0
365
783 E L O TE E L O TE E L 1 TE
Total Loss less StaticHead (mb)
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i
ll-
1 2 . 1D ES C R IP T ION Carbon Dioxideextinguishingsystemconsistsof carbondioxidecylinders,steel piping,discharge nozzles,heat and/orsmokedetectorsand a controlpanel,which monitorsthe space,activatesboth visualand audio alarmsbeforereleasingthe gas. The carbondioxideis dischargedafter a time delayupon detectionof fire to warn any occupantto evacuatethe room.Such systemis usuallyprovidedfor electricaltransformerrooms,switchrooms and standbygeneratorroomsand should not be installedfor rooms,which are normallyoccupied. A typicalcarbondioxideextinguishinginstallationis shown in Figure12.1.
12.2DESIGNREQUIREMENTS 12.2.1Design Standards The relevantclausein the UniformBuildingBy-laws1984,relatingto carbondioxideextinguishing systemsis By-law235 and the applicablestandardis: - M S 1 5 9 0: 2 0 0 3 . 12.2.2System Operation The quantityof extinguishingagent should be sufficientto ensure rapid extinctionof any fire in the protectedareas and with adequate spare capacity.The protectedarea should be flooded with CarbonDioxidegas with flame extinguishingconcentrationof 50% at21'C and shall be based on total floodingprincipleand/or local applicationwith a time delay periodof 30 seconds,adjustable up to 60 secondsmaximum.The durationof total dischargeshall not exceed '1minuteexceptfor deep seated fires where the total discharge shall not exceed 7 minutes or 30o/odischargewithin 2 minutes. For local applicationusing high pressurestorage,the designquantityof carbondioxideshouldbe increasedby 40% as only liquid portion of the dischargeis effective. All devices shall be designed for the service encounteredand shall not be readily rendered inoperativeor susceptibleto accidentaloperation.They shall be located,installedor suitably protectedagainst mechanical,chemical or other damage, which may render them inoperative. All devicesfor shuttingdown supplementaryequipmentshall be consideredintegralparts of the systemand shallfunctionwith systemoperation. The system shall operatefrom a supply voltage of 240 volts A.C., 50 Hz to the power charger modulewithinthe controlpanel.This voltageis transformedand rectifiedwithinthe panelto 24 volt D.C' A 24 volt D.C standbybatteryof the maintenancefree type shall be providedin case of mains voltagefailure.This batterywill automaticallyand instantaneously be switchedinto use as soon as the mains supplyfails.Such a failureshall be indicatedboth visuallyand audiblyat the panel. The batteryshall be tricklechargedduringnormaloperatingconditions. The space should be protectedby two or more heat or smoke detectors.When one of these detectorsgoes into the alarm condition,the indicatorlight on the controlpanel should illuminate and an audiblewarningsoundedvia the alarm bell. ln order to dischargethe extinguishingagent automatically,at least two detectorzones must be activated.This mode of operationterm as crosszoningwill obviatethe possibilityof falsedischarge of the gas due to one detectoroperatingto conditionswhich are regardedas normal.
142
Also to be providedis the independentfacilityfor emergencyoperationby manuallydischarging the agent via a "breakglass" handletype manual pull box which should be mountedoutsidethe exit door to the protectedspace. The detectorscircuitwiring shall be supervisedcontinuouslyfor line fault.A disconnectionto this circuitwould be indicatedas a fault at the controlpanel both visuallyand audiblyby a fault lamp and buzzer. 12.2.3Carbon Dioxide Cylinders The CarbonDioxidegas is storedin cylindersdesignedto hold the gas in liquefiedform at ambient temperaturesThe gas can be storedat low pressureof 2068 kPa with refrigerationor under high pressureat 5171 kPa at ambienttemperatures.Most systemsuse high pressurestorage due to cost considerations. Cylindersshould be suitablefor a workingpressureof 59 bars at 21"C and pressuretestedat22B bars. A reliablemeansof indicationby weighingshouldbe providedto determinethe amountof gas in the cylinders.Each systemshouldhave a permanentname plate specifyingthe number,fillingweight and the pressurisationlevel of the cylinders.All cylinderssupplyingthe same manifoldouilet for distributionof agent should be interchangeable and of one selectedsize. Where more than three cylindersare required,a pilot cylindershould be providedto activatethe dischargevalve from each cylinder. Each containershould be equipped with a discharge valve of the solenoid operated type to dischargeliquidagent at the requiredrate. Containerswith top-mountedvalves should have an internaldip tube extendingto the bottomof the cylinderto permitdischargeof liquidphase agent. Gas cylinders should be located outside of the hazard which it protects wherever possible. However,the risk of vandalismshouldalso be taken into consideration. 12.2.4Carbon Dioxide Control panel The system controlpanel should indicatethe operationof the system,hazardsto personnet,or failureof any superviseddeviceand complyingwith M.S.1404and B.S.7273.A positivealarm and indicatorshould be providedto show that the system has operated. Afarm should be providedto give warningof a dischargeor pendingdischargewhere a hazard to personnelmay exist.Alarms indicatingfailureof superviseddevicesor equipmentshould give prompt and positive indicationof any failure and should be distinctivefrom alarms indicating operationor hazardousconditions. A device should be incorporatedinto the system to shut down any exhaust fans and activate solenoidoperatedcurtainsacrosslouvresbeforedischarge. Sincea remotemanualcontrolshouldbe a manualpull box type,a pressureswitchin the discharge pipe may be requiredto providethe signal back to the controlpanel that the carbon dioxidegas has been discharged. 12.2.5Discharge Nozzle Discharge nozzles should be selected for use with carbon dioxide and for their discharge characteristics. For low pressurestorage,nozzlepressureshould be 1034 kPa minimumand for high pressurestorage,the nozzle pressureshould be 2068 kPa. The discharge nozzleshould consist of the orifice and any associatedhorn, shield or baffle. Dischargeorificesshould be of corrosionresistantmetal.
143
Dischargenozzleshouldbe permanently markedto identifythe nozzleand to showthe equivalent singleorificediameterregardless of shipe and numberoi orifice.Thisequivalent diametershall referto the orificediameterof the 'standard'single orificetype nozzlehavingthe sameflow rates as the nozzlein question'The markingshouldreadily be discernable afterconnection. Discharge nozzleshouldbe providedwithfrangiblediscor blow out ""f, *n"r" cloggingby foreignmaterials is likely. 12.2.6AutomaticFire Detectorsand AudioA/isuarAtarm units The automaticfire detectionis usuallyby means of eitherheator smokedetectors.The detectors shouldbe resistantto corrosion The audiounit shouldproducean audiblewarning at least65dBnoiselevelor 5dB abovethe ambientnoiselevel'Theaudioalarmunitof alarm 6ell typeshoulobe of the trembling (notsingle stroke)and shalloperatefromthe fire alarmpanel batterysupply.All audio/visual atarm circuitry shallbe designedto be ableto functioncontinuously duringthe fire.The bellsmaybe installed in any location for alarmpurpose. 12.2.7Pipeworkand Fittings Thematerialof pipingandfittings,etc.for the instailation of the systemmustbe of non-combustible heat resistingand must have capacityto maintain its own shape in room temperatureduring the outbreakof fire' All pipingshouldbe of API schedule40 steelpipefor low pressurestorage systems'For highpressurestoragesystems,piping shouldbe of schedule40 for 20mmdia.pipes andschedule80 for25mmdia'andabove.Flexible piping,tubingor hoses(including connections) whereusedshouldbe ableto withstandthe pressure ratings. 12.2.8WarningSigns warningand instructionsignsshouldbe installed at entrancesto and insideprotectedareasat prominent positions.
12.3 DESIGNCHECKLIST (a)
Hazardtypes: tl Flammable liquidmaterials. O Electricalhazard. Q Ordinarycombustibles ( paper,woodand textiles ). I Hazardssolids. Q Other:
(b)
Type of fire to be protected from : seated fire ( solids subjectto smoutdering ! ?""0 ) D Surfacefire ( flammableliquids,gas and solids) Q Other:
(c)
Type of protection: . Totalfloodingsystem . Volume to be protected :--.-ms. . Design carbon dioxide "on""ntr"tion , . Volumefactor: . rtoootngtactor:
. systerniisJ;rg","r*
o/ lo.
kg/minute.
144
Localapplication system Rateby areamethod . Area to be protected : . Area per nozzle: _
7n2.
. Nozzledischarge rate:_ O Rate by volumemethod . Assumedenclosure:
. Systemdischargerate : . Nozzlespacing :
m2.
kg /minutepernozzle.
ry13.
kg/minute. m.
(d)
Totalnumberof nozzle:_
(e)
Nozzletype:
(f)
Durationof discharge :
(g)
Storagetype: O Lowpressure( averagestoragepressure: 2,06gkpa ) . Designnozzlepressure( minimum1,034kpa : kpa. ) ' Pipematerial shailbe minimumof schedule40 or equivarent. A Highpressure ( averagestoragepressure: 5,171kpa ) . Designnozzlepressure( minimum2,06g kpa ) : --..kpa. ' Pipematerialshallbe Schedule40 or equivalent for nominalsizeup to 20mmand minimumscheduleB0or equivalent for nominalsizegreaterthan2omm.
(h)
Totalquantityof carbondioxidecylinder: _---
(i)
Additional quantityof carbondioxide( to compensate for openingcannotbe closedduring extinguishment or specialcondition :_ ) * Forlocalapplication, highpressurestorage,the desigur quantityof carbondioxideshallbe increasedby 40%due to onlyliquiddischargeportionis effective.
0)
Designcalculations.
(k)
Electricalclearance : . Systemvoltage:-.-. Clearanceprovided
(l)
nos. : ; nominalsize
kV.
Detection type:
( m ) Actuationtype: (n)
Manualoperating device:
145
nos ( _kg
per cylinder)
12.4VISUALINSPECTION CHECKLIST 12.4.1Visual inspection of cylinders Capacityof cylinders. Locationof cylinders. Pilotcylinders. Flexiblehoses. Safety valve. Support brackets. Weighingfacility. 12.4.2Visual inspection of pipework Type of pipes used. Paintingof pipework. Pipe support. Pipe sleeves. Fireseal. Nozzles. 12.4.3Visual inspection of detectors Physicalconditionof detectors. Conduitfor allwiring. 12.4.4Visual inspection of panels Protectionof panel. Mountingof panel. 12.4.5Visual inspection of accessories Flashinglights. Trippingdevices. Signage. Visibleand audiblealarms. Electricaland mechanicalmanualactivation.
146
12.5 TESTINGAND COMMISSIONING CHECKLIST 12.5.'lTestingand commissioningof pipework Pneumatic testingof pipework. 12.5.2Testingand commissioningof detectors Detectortest. Electrical wiringtest. Interfacing of detectorsand controlpanel. 12.5.3Testingand commissioningof panel LEDtest. 1 zonealarmtest. 2zonealarmtest. Dischargetest. Faulttest. Connection to mainfirealarm. 12.5.4Testingand commissioningof system Simulated automatic discharge test. Simulated manualdischarge test. Actualdischargetest. Bracketsupportduringactualdischargetest.
147
Table 12.1Sampleof Carbon Dioxide ExtinguishingSystem PROJECT Job No. :
Date: C a l c .B y :
Chkd.By :
CARBON DIOXIDEEXTINGUISHING SYSTEM
1. ROOM DIMENSIONS Room Name Room Dimensions(in feet)
: :
ElectricalSwitch Board Room 3.4m (L) x 3.0m (W) x 4.0m (H)
2. DESIGNCRITERIA DesignCode HazardType DesignConcentration Rate of Application
: : : :
Room Temperature
:
NFPA12:1985 TotalFlooding- Deep Seated 50o/o Completedischargein Z minutesor 30% dischargein 2 minutes(Minimum) 81oF(27.2oC)
3. AGENT DISCHARGE Volumeof Space (V) FloodingFactor(F) BasicCO, Quantity(W)
: : :
40.8 m3 1.6 kg/m3 40.8 (V) x 1.6 (F) = 65.28kg
4. TOTALAGENT QUANTITY Basic CO, Quantity(W) Safetyfactor (5%) TotalCO, Quantity(Wr) Agent Weight per Cylinder(W) No. of Cylinders No. of CylindersProvided
: : : : : :
65.28 kg 3.264 kg 68.5214 kg 45 kg 68.544(Wr) / 45 (Wc)= 1.5232Nos. 2 (Nos.)x 45 (kg)each
148
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1 3 . 1G E N E R A L 13.1.1System Concept to providewarningof the outbreakof fireandallow Firedetection andalarmsystemsaredesigned appropriate fire fightingactionto be takenbeforethe situationgetsout of control.As all systems to protectlife,property, this placesa greatresponsibility are designedprimarily on the designer becauseeachbuildingwill presenta differentset of problemsin relationto the riskof fireandfire spread.Eachfire detection and alarmsystemthereforemustbe speciallydesignedto meetthe requirements for eachbuilding. 13.1.2DesignRequirements (i) Codesand Standards (a) AutomaticFireDetection andAlarmSystemshallbe designedbasedon: 8.5.5839 : Part 1 - Code of Practicefor Design,Installationand Servicing. 8.5.5839 : Part 3 - Specificationfor AutomaticRelease Mechanismfor certain Fire ProtectionSystems. 8.5.5839: Part 5 - Specificationfor Optical Beam Smoke Detectors M . S . 1 1 7 6: P a r t5 - Specification for Componentsof AutomaticFire DetectionSystems Part 5 : Heat SensitiveDetectors- Point Detectorscontaininga Static ElementSystem M . S . 1 1 7 6: P a r t 7 - Specificationfor Componentsof Automatic Fire DetectionSystems Par17 : Specificationfor Power-typeSmoke Detectorusing ScatteredLight,Transmitted Lightor lonization M . S . 1 1 7 6: P a r tB - Specificationfor Componentsof Automatic Fire DetectionSystems Part B : Specificationfor High TemperatureHeat Detectors M . S . 1 1 7 6: P a r t9 - Specificationfor Componentsof Automatic Fire DetectionSystems Part 9 : Methodsof Test of Sensitivitvto Fire M . S . 1 4 7 1: P a r t3 - Vocabularyon Fire Protection Part 3 : Fire Detectionand Alarm M . S . 1 7 4 5: P a r t1 - Fire Detectionand FireAlarm Systems Part 1 : Introduction M.S.1745:Part2 - Fire Detectionand FireAlarm Systems Part.2: Controland IndicativeEquipment
152
M.S.1745 : Part3 - FireDetectionand FireAlarmSystems Part3 : AudibleFireAlarmDevices M.S.1745 : Parl4 - FireDetectionand FireAlarmSystems Part4 : PowerSupplyEquipment M . S . 1 7 4:5P a r t1 1 - FireDetectionand FireAlarmSystems Part11 : ManualCallpoint 8.5.7273:Part1 - Codeof Practice forthe Planning, lnstallation andServicing of Electrical Equipment for Actuationof GaseousFireSuppression System 8.S.6266 - Codeof Practicefor FireProtection for ElectronicDataProcessingInstallations (b) Automatic Firedetection andAlarmsystemrequirements shallbe basedon:
-
By-law133- UBBL1984 By-law225(1)- UBBL1984 By-law237- UBBL1984 By-law238- UBBL1984 By-law239- UBBL1984 By-law240- UBBL1984 By-law241- UBBL1984 By-lawz4a @)- UBBL1984 By-law245- UBBL1984 By-law246- UBBLi9B4 - UBBLi9B4 Tenthschedute
(c) Otherrelevantstandards:
8.5.5588:Part1 8.5.5588: PartB 8 . 5 . 5 5 8 8P: a r t1 0 Type of Protection and Coverage When designinga fire detectionand alarm system,the objectivehas to be established whether it is for protectingthe buildingand its contentsor enhancingthe safety of the occupants. (a) Manual A systemwhich providesmanualalarmonly (b) Automatic A system that automaticallydetects a fire and initiatesan effectivealarm.
153
(c) Actuationof AncillaryServices Firedetectionand alarmsystemshallalso be designedwith the provisionto closeor open the circuitof ancillaryservicesby means of relaysor similardevices.The provision shall be for fire suppressionsystem activationindicatorsor for activationof activefire suppressionsystems. (d) Life protection This classificationprovidesfor the protectionof life, which is the safety of the occupants. It caters for the detectionof a fire, initiatesan alarm of fire, and providessufficienttime for the occupantsto escapefrom the building. (e) Propertyprotection This classificationprovidesfor the protectionof propertyand its contents.lt catersfor the automaticdetectionof a fire, initiatesan alarm of fire, indicatesthe locationof the fire withinthe premisesand summonsthe fire brigade. (iii)
ZoneConfiguration One majorfunctionof a fire detectionand alarm system is to indicatethe locationof a fire as preciselyas possible.Hence detectorsare groupedinto zones. For conventionalsystem, each zone is connectedto the controllerby a separatecircuit. For addressablesystems, one circuit may connect up to gg detectorsand protectseveral zones. (a) Zones configuration guidelines - The maximumfloor area of a zone should not exceed 2OOm2 - The search distance - the total travel distance by a searcher within a fire zone to determinevisuallythe positionof a fire should not exceed 30 metres. - A singlezone may extend to cover severalfire compartmentsbut shall lie along compartmentboundaries.
(iv)
Type of Fire Detection System There are four types of fire detectionsystems: (a) Conventionalsystem (b) Addressablesystem (c) Analogueaddressablesystem (e) Air samplingsystem
13.1.3Design Checklist (i) Systemshall be designedin accordanceto UBBL and relevantstandards. (ii)
All requirementsand limitationsstatedwithin UBBL shall be observed. a. Systemtype : Conventional/ Addressable/ AnalogueAddressable/ Air sampling b. Totalfloorarea :
m2
c. Buildingheight:
d. Totalnumberof Zones:
154
e. Max area per zones i f.
m2
Max number of detector I zone-.
g. Numberof loops :
h. Alarmmode : Manual/Automatic I3.2 CONTROLAND INDICATTVE EQUIPMENT 13.2.1 Concept lontrolandlndicative Equipment willcomprise equipment for thereception, indication, controland elayingof signalsoriginating fromdetectorsor manualcallpointsconnected to it, andfor activation rf alarmsoundersand alarmsignalingdevices. 13.2.2 DesignRequirements i) Codesand Standards Controland Indicative Equipment for automaticfiredetectionandalarmsystemshallcomply with: 8.5.5839:Part1 - AutomaticFireDetectionandAlarmSystemfor Buildings: Codeof practice for SystemDesign,lnstallation and Servicing 8.S.1404:Part4 - Specification for controland indicativeequipment ii)
OperationRequirements ( a ) T h e m a i nC o n t r o a l n d I n d i c a t i v eE q u i p m e nst h a l lb e l o c a t e di n t h e b u i l d i n gf i r e command/controlcentrein areaon the groundfloor.lf command/ controlcentreis not available, it shallbe sitedwhereit can be underconstantobservation in a positionclearly visiblefromthe mainentrance. (b) Noiseor othersoundlevelsin the vicinityof the Controland lndicativeEquipment shouldnot maskthe audiblealarmof sounderslocatednearthe controlpanel. (c) Theambientlightlevelin thevicinityof the Controland lndicative Equipment shouldbe suchthatanyvisualindications canbe clearlyseen,andanyinstructions for usecan be clearlyread. (d) Controland IndicativeEquipmentshouldbe sitedin areasof low risk,so that the equipmentis unlikelyto be involvedin a fire beforeadequatewarninghas beengiven. (e) lf the systemusesautomaticdetectors,thenthe areawherethe Controland Indicative Equipment is sitedshouldbe protectedby the detectionsystem. (f) Thefirealarmsystemshouldindicatethe originof the fire.The indications shouldbe suchthattheycan be easily,quicklyand unambiguously relatedto the positionin the building fromwhichthealarmhasoriginated.
155
(g) The primaryindicationof the originof the alarm should be an indicationof the zone of origin. (h) The method of identificationshould be developedto match the extent of the premises. The methodused shouldensure rapid locationof the fire, and should enabledecisions to be made as to which parts (usuallyfire compartments)need to be evacuated. 0) The locationmay be shown by one or more of the following: - A displayof lettersand / or numbers,togetherwith a suitablekey (whichmay be the planof a building). - A permanentmimicdiagram. Note: Printersare not consideredsuitableas a primaryindication,since in the eventof ink, ribbonor paper being exhausted,the indicationwill be lost.They may, however,be acceptanceas a backupto anotherdisplay. (k) On or adjacentto the Controland IndicativeEquipmentshouldbe a completeset of the latestarchitecturebuildingplans indicatingthe layoutsof all fire protectionsystemsand equipment,the circulationarea and escaperoutes,and all fire alarm zones. (l) All Controland lndicativeEquipmentshouldbe connectedto the nearestfire station throughCMS system. (m) The operationof all manualcontroland isolatingdevicesshouldbe limitedto authorised personnel.Where controlsneed to be operatedduring afire, access should not be controlledby a key - entered code. (n) A logbookshallbe kept in whichdetailsof all alarm(genuine,practice,test or false)fault, isolation,test and serviceshallbe recordedin this logbook.Whenthe fire alarmsystemis equippedwith a printer,the printout informationmay be the event log record,but shall be tagged and recorded in the logbook.A recommendedformat for the logbook is describedin Table 13.1. TABLE 13.1 Log record for Automatic Fire Detection and Alarm system.
156
13.2.3Testing and Gommissioning (i)
Checkand ensureControland IndicativeEquipmentis locatedin the controlroom on the groundfloor near the main entranceof the building.
(ii)
Ensurethe ambient light and noise environmentwill not affectthe proper operationof the Controland lndicativeEquipment.
(iii)
Checkand ensurethat the Controland IndicativeEquipmentis locatedin the area of low risk.
(iv)-
Check and ensurethat the controlroom is protectedby automaticfire detectionand alarm system.
(v)
Checkand ensurethat the Controland IndicativeEquipmentis testedto MS 1404 : Parl4 : 1996and is type approvedby the Fire and RescueDepartmentMalaysia.
(vi)
Check and ensure that the facial featuresand the monitoringfacilitiesprovidedfor at the Controland IndicativeEquipmentcomplywith the requirementsof the Fire Rescue DepartmentMalaysia.
(vii)
Check and ensurethat a completeset of the latestarchitecturebuildingplans indicatingthe layoutsof all fire protectionsystemsand equipment,the circulationarea and escaperoutes, and all fire alarmzones is kept in the controlroom.
(viii) Check and ensurethat a logbookis kept in the controlroom for loggingall eventsto-date. (ix)
Before initiatingtest, ensure that the back-up batteryis properlyconnectedand ensure main power is beingsuppliedto the Controland lndicativeEquipment.
(x)
With the Controland IndicativeEquipmentswitchedon, ensurethe " Mains On " and " DC On" indicationsare illuminated.Ensurealso " MainsFail " and " ChargerFail " indicationsare not illuminated.
(xi)
The voltagereadingat the voltmetreat the Controland IndicativeEquipmentshould read 24 ! 4 volts.The amperemetre shouldregisterminimumor no readingat all.
(xii)
" lnitiate Test Battery"by activatingthe toggleswitch and ensurevoltmetrereadingis at24 volts,with the ammetrereadingcertainchargingcurrent.
ixiii) Initiatetests of detectorsand MCPs at differentzone respectivelyand ensurethe signal is relayedbackto the correspondingzone thougheach respectiveindicationson the Control& lndicativeEquipment. ixiv) lnitiateauxiliaryequipmentand ensure the status is monitoredas per indicationon the ControlIndicativeEquipment. ixv)
For addressablesystem,initiatetestsof detectorsand MCPsat differentdetectorsand MCPs and ensurethat the signatureof each of them is correctlyprogrammedin accordanceto the intendedzonings.
ixvi) For all auxiliaryshut down outputs,initiatetest on activatingdeviceand recordthe response at the auxiliaryequipmentto ensurecircuitryis working. 157
i
(xvii) Initiatetest of detector/ MCPs to ensuretwo stagealarm is in correctoperatingmode. (xviii) Initiatefault on detector/ MCPs and ensure signal is monitoredback to the Control & IndicativeEquipmentat the respectivezone. (xix) Disableindependentzone and initiatetest on detector/ MCPs and ensurethat even though visualalarm indicationis registeredon the Controland IndicativeEquipment,there is no audioalarm withinany partsof the building. (xx)
Initiatelamp test on the Controland IndicativeEquipmentand ensurethat all indicating lightsare illuminated.
(xxi) Initiate" Evacuation"switchand ensuremasteralarmindicationis illuminatedand all system sounderunitsare activatedfor full evacuation. (xxii) For all tests conductedwhich involvedthe initialisation of an alarm signal,ensurethat the mastersounderdevice on top of the Controland IndicativeEquipmentis activatedas per requirementstated in the standard. (xxiii) For all tests conductedwhich involvedthe initialisation of a fault signal,ensurethat the buzzerwithinthe ControlandIndicativeEquipmentis activated. (xxiv) Turn off mains power supply to the Controland IndicativeEquipmentand ensure that the back-uppower supply is healthyand is able to sustainthe load as per the requirementin accordanceto the standards. 13.2.4Design Checklist a. Controland IndicativeEquipmenttestedto : b.
Controland IndicativeEquipmentApprovedtype :
c.
BOMBA Approval Certificate:
d.
Expiry Date of BOMBA Approval Certificate:
e.
Zone Alarm Indication/ RockerSwitch
f.
Zone Fault Indication/ Rocker Switch
g.
Zone lsolateIndication/ RockerSwitch
h.
MainsOn Indication
j.
DC On Indication
k.
MainsFailIndication
m.
BatteryFail Indication
n.
ChargerFail Indication
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n.
Bell Line Fault lndication
o.
Lamp Test ToggleSwitch/ Full Indication
p.
BatteryTest Toggle Switch
q.
Buzzer SilenceToggle Switch
r.
Bell SilenceToggleSwitch
s.
System Rest Toggle Switch
t.
Fire BrigadeToggle Switch
u.
Duty Pump Run Indication
v.
StandbyPump Run lndication
w.
JockeyPump Run Indication
x.
Pump ManualIndication
y.
A.H.U.Trip Indication
z.
Fire SuppressionSystemDischargelndication
13.3Audio & VisualAlarm 13.3.1 Concept Duringa fire,if firealarmsystemis installed,activation of an alarmsounderis to arousetheattention of the occupantsso thatevacuation can be carriedout withoutcausingharmto the occupants. 13.3.2DesignRequirements (i) Godeand Standard AudioandVisualFireAlarmSystemshallbe designed to: 8.5.5839: Part1 - FireDetection andAlarmSystemForBuildings Codeof Practice for SystemDesign,lnstallation and Servicing (ii)
DesignGuidelines (a) A minimum is soundlevelof 65 dB (A),or 5 dB (A)aboveambientnoiselevel(whichever greater)sustainable period produced for a of minimum30 secondsshouldbe by the SounderUnit. (b) ForSounderUnitthatneedto arousesleepingperson,the minimumsoundlevelshould be 75 dB (A)at bedheadwithall doorsclosed. (c) Thetype,numberandlocation of fireAlarmSounders shouldbe thatthe alarmsoundis distinctive frombackground noise.
159
(d) AllAlarm Sounderswithina buildingshouldhave similarsound characteristics. (e) In areaswhere a normaltype of soundermay be ineffective,visualalarmsignalneed to be provided.ln general,visualalarmsignalshouldonly be usedto supplementaudible alarm,and shouldnot be used on its own. 13.3.3Testingand Commissioning (i) Checkand ensureAlarm SounderUnit is properlysecured. (ii)
Checkand ensureAlarm SounderUnit wiring is properlysecuredto its terminals.
(iii)
Check and ensure cable carryingconduitconnectedto the Alarm Sounder Unit is secured with cable lug.
(iv)
Check and ensure all circuitrycables of Alarm Sounders Unit are of correcttype and correct size in accordanceto the requirementsof the Code.
(v)
Alarmsounderunit shouldbe testedby activationusing ManualCall Pointof the same zone: note the sequenceof the alarm.
(vi)
Alarm Sounder Unit should be tested by simulationof activationof fire detectorsof the same zone; note the sequenceof alarm.The same Alarm SounderUnit shouldalso be tested by simulationof activationof fire detectorsof differentzone; note sequenceof alarm.
(vii)
Other than A/C power supply,Alarm SounderUnit shouldalso be tested using back-up batterypowersupplysimulatinga powerfailure.
(viii) Qualitativeassessmentof Alarm SounderUnit shouldbe carriedout in generalto assessthe audibilityof alarmsignal.When in doubt,quantitativeassessmentshouldbe carriedout. (ix)
All visualalarmunitsshouldbe testedfor theirflash rate and theirfrequencies.They should also be testedagainstbackgroundlightingconditionand ensurethere is no maskingof the visualsignalby any other lightfittings.
13.3.4 Design Checklist a. Alarm SounderUnittestedto :
b.
AlarmSounderUnitApproved type:
c.
BOMBA Approval Certificatenumber :
d.
ExpiryDateof BOMBAApprovalCertificate:
e.
SoundLevelOutput@ 1m:
f.
Frequency/ FrequencyRange : -
g.
Type : Mechanical/Electrical/Electronic
h.
Heightfrom floor level :
j.
Type and size of cable used :
dB(A) Hz -
160
kHz
13.4 Manual Gall Points (MCP) 13.4.1Concept Everyfiredetection systemmustincludecallpoints,so thatin theeventof a fire,helpcanbe called immediately. All callpointsin the sameinstallation shallhavethe samemethodof operation. All call pointsshouldbe clearlyidentifiable and shouldnot requireinstructions as to their modeof actuation. '13.4.2 DesignGuideline (i) Codesand Standards ManualCallPointshallbe basedon: (a) B.S.5839 : Part1 : 19BB - FireDetection andAlarmSystemForBuildings code of Practice for systemDesign,Installation andservicing (b) 8.5.5839: Part2 : 1983 - Specification for ManualCall points (ii)
Design Guideline (a) ManualCall Point shall be locatedon exit routesand in particularon the floor landings or stairwaysand at exits to open air. (b) ManualCall Point shall be locatedso that to raise an alarm, no person in the premises need travel more than 30 metres. (c) Manual Call Point shall be mountedat a height of 1.4 metres from the floor, easily accessible,well illuminatedand conspicuouspositionsfree from obstruction. (d) Manual Call Point shall be sited againsta contrastingbackgroundto assist in easy
recognition. (e) The delay betweenoperationof a call point and the giving of the generalalarm should not exceed 3 seconds. (f) ManualCall Pointmay be flushedmountedwherethey may be seem readily.In locations where they may be viewed from the side (eg. in corridor)they should be surface mountedor semi-recessedin order to presenta side profilearea of not less than 750mm2. (g) All coloursof the ManualCall Pointthroughoutthe entirepremisesshall be of the same colour and shall be in brightred colourunlessotherwiseapprovedby Fire and Rescue DepartmentMalaysia. 13.4.3Testing and Commissioning (i) Checkand ensureManualCall point is properlysecured. (ii)
Checkand ensureManualCall Pointwiringis properlysecuredto its terminals.
(iii)
Checkand ensurecablecarryingconduitconnectedto the ManualCall Pointis securedwith cablelug.
161
(iv)
cablesof ManualCallPointareof correcttypeandcorrectsize Checkandensureallcircuitry of the Code. in accordance to the requirements
(v)
Testthe ManualCallPointusingtestingkey.
(vi)
Testthe ManualCallPointphysically andtimethe response of theAlarmSounderUnitto be within3 seconds.
(vii) FortwostageFireAlarmSystem,testthe ManualCallPointandensurethesequence of the to zoneconfiguration. FireAlarmis correctin accordance 13.4.4Checklist a. ManualCallPointtestedto : b. ManualCall PointApprovedtype :
number: c. BOMBAApprovalCertificate d. ExpiryDateof BOMBAApprovalCertificate: e. DistancebetweenMCP(30 metres): f. Heightfrom floor level('1.4metres): g. Type and size of cable used : h. Surface/ FlushMounted:
13.5 Fire Detectors 13.5.1Goncept (i) Firedetectorsaredesignedto detectone or moreof the threecharacteristics of a fire- smoke, heat and flame.No one typeof detectoris suitablefor all applications and the finalchoicewill dependon individual circumstances. (ii) Most,if notall,fire detectorsare affectednotonlyby the detectedphenomena butalsoby the behaviourof the phenomena withtime.However,all firedetectorswill alsorespondto someextent to phenomena otherthanfire. 13.5.2DesignGuidelines (i) Codesand Standards (a) 8.5.5839: Part5 - Specification for OpticalBeamSmokeDetectors ( b ) M . S . 1 1 7 6: P a r t5 - Specificationfor Componentsof Automatic Fire DetectionSystems Part 5 : Heat SensitiveDetectors- Point Detectorscontaininga Static ElementSystem ( c ) M . S . 1 1 7 6P : ar1.7 - Specificationfor Componentsof AutomaticFire DetectionSystems Part.7: Specificationfor Power-typeSmoke Detectorusing ScatteredLight,Transmitted Lightor lonization
162
( d ) M . S . 1 1 7 6: P a r tB - Specificationfor Componentsof Automatic Fire DetectionSystems Part B : Specificationfor High TemperatureHeat Detectors (e) M.S.1176 : P a r t9 - Specificationfor Componentsof Automatic Fire DetectionSystems Part 9 : Methods of Test of Sensitivitvto Fire 8.S.5839: Part 1 - Fire Detectionand Alarm Systemfor Buildings Code of Practicefor SystemDesign,Installationand Servicing. (f) AS 1603 : Part B - AutomaticFire Detectionand Alarm System,MultipointAspiratedSmoke Detectors. (ii)
Types of Fire Detector (a) Heat Detector - FixedTemperatureHeat Detector - Rate-of-RiseTemperatureHeat Detector - Linear/Line Detector (b) Smoke Detector - lonizationSmoke Detector - OpticalSmoke Detector - AspiratingSmoke Detector - Beam Detector (c) Flame Detector - Ultra Violet Flame Detector - lnfra-redFlame Detector
(iii)
DesignGuidelines (a) Heat Detector(Point Detector) - For open areas underflat horizontalceilings,the horizontaldistancefrom any point in the area to the detector nearestto that point should not exceed 5.3 metres. - In a corridorless than 5 metreswide, the horizontaldistancegiven in item a above may be increasedby half the differencebetween5 metresand the width of the corridor.For corridorwider than 5 metres,it shouldbe treatedas an open area. - Undersame conditionstatedin a, for estimationpurposes,in any roomor compartment, the number of point type heat detectorsfitted should not normally be less than the room or compartmentarea dividedby 50m2. - Heatdetectorshouldbe sitedso that theirsensitiveelementsare not lessthan 25mm or morethan 150mmbelowthe ceilingor roof. - For pitchedroof or north-lightroof,heat detectorsshouldbe installedwithineach apex. - Detectorsshould not normallybe mountedon ceilingshigherthan the general limits statedin Table 13.2.
163
( b ) Smoke Detector(PointDetector) - For open areas underflat horizontalceilings,the horizontaldistance from any point in the area to the detectornearestto that pointshouldnot exceed2.5 metres. - In a corridorlessthan 5 metreswide,the horizontaldistancegiven in an abovemay be increasedby half the differencebetween5 metresand the width of the corridor.For corridorwiderthan 5 metres,it shouldbe treatedas an open area. - Undersameconditionstatedin a, for estimationpurposes, in any roomor compartment, the numberof pointtype smoke detectorsfittedshould not normallybe less than the room or compartmentarea dividedbv 100m2. - Smokedetectorshouldbe sitedso that theirsensitive elementsare not lessthan25mm or more than 600mm belowthe ceilingor roof. - For pitchedroof or north-lightroof, heat detectorsshould be installedwithin each apex. - Detectorsshould not normallybe mountedon ceilings higherthan the generallimits in Table13.2. Table 13.2 Limits of Ceiling Height
Ceiling Heights
Detector Type
General Limits Heat detectors BS 5445 : Part 5 Grade 1 Grade 2 Grade 3
Rapid Attendance
9.0 7.5 6.0
13.5 12.0 10.5
Point Smoke Detector
10.5
15.0
High TemperatureHeat Detector BS 5445 : Part 8
6.0
10.5
OpticalBeamDetector
25.0
40.0
(c) AspiratingSmoke Detector - Dependingon the sensitivityof the aspirateddetectors and the responsetime required, the area coverageof each aspiratedsmoke detectorshould generallybe limitedto '1000m2. - Each air samplingpointor capillaryheadsetshould be sitedso that is not less than 25mm or more than 600mm belowthe ceilingor roof. - Aerodynamicdesignedfittingsshouldbe used to ensuresmoothtransportation of smoke particlesfrom the fire source to the detectionchamber. - For open areas underflat horizontalceilings: - Samplingholes of 2 mm diametershould be separatedby intervalsas specifiedin AS 1670 : 1995 and typicallyin the rangeof 2 to 8 metresintervalsalongthe length of the pipeworkas well as betweeneach adjacentair-samplingpipework.
164
- Each Samplinghole shallbe identifiedin accordancewith AS 1670 : 1995. - For low ceilingheightor raisedfloor void protection,the horizontaldistancebetween air-samplingpoint shouldbe as per itemed.The horizontaldistancebetweeneach pipeworkshouldbe reducedto coincidewith the angleof incident adjacentair-sampling of the smoke Particles' - All air-samplingpipeworkshouldcomplywith BS 6099 or AS 2053 of 25mm nominal overalldiameterand should be identifiedas a Fire DetectionSamplingPipe with imprintat intervalsnot exceeding2 metres' - All air-samplingpipeworkshould be supportedwith properbracketingat intervalsnot more than 1.2 metresand shall be installedin accordancewith AS 3000. (d) Optical beam detector - Optical Beam Detectorshould be installedin accordancewith the manufacture's instructions,with not more than 3 metresof the beam within 500mm of any wall or partitionexcept those part of the beam within 500mm of the beam's transmitter, receiveror reflectors. - The maximumlength of the area protectedby a singleopticalbeam detectorshould not exceed 100 metres.Withinthis limitation,the manufacture'srecommendationshould be followed. - lf thereis a possibilityof peoplewalkingin the area of the beam,then the beam should be at least 2.7 metres above the floor. - When optical smoke detectorsare used in roof void areas having dropping smoke curtains,the beams shouldbe so arrangedso that they are not brokenby the smoke curtainswhen theYare droPPed' (e) Flame detector - Flame detectorsshould be chosenfor applicationwhere there is the likelihoodof rapid flame development,so that an alarm is requiredbeforeproductsof combustionor heat will reacha thresholdlevelto raisean alarm' - Flame detectorsare essentially"line of sight" deviceswhich can sensethe presenceof flames in a set field of view. This field is generallydescribedby the cone of vision angle and the maximumperpendicularsensitivityin metres,althoughother considerations are imPortant. - Considerationshould be to providefull coverageof the area to be protectedwith maximummultiplecoverageto accountfor any detectormalfunction. 13.5.3Testingand Commissioning (i) Checkand ensureDetectoris properlyinstalled' (ii)
Check and ensureDetectorwiringis properlysecuredto its terminals'
(iii)
conduitconnectedto the ManualCall Pointis securedwith Checkand ensurecable-carrying cablelug.
165
i
(iv)
Check and ensure all circuitrycables of Detectorare of correct type and correct size in accordanceto the requirementsof the code.
(v)
Test the detectorusing standardtesting procedurein accordanceto the recommendationof the standards.
(vi)
ForAspiratedSmokeDetector,the criteriafor testingthe systemis the responsetime.The responsetimeis definedas the timeregistered fromthe momenttestsmokeparticlesare introduced at the leastfavorablepointto the timetheyare detectedat the smokedetector chamber. Themaximum response timeshouldnotexceed90 seconds. Theresponse registered at the controllershouldbe at least30%of the sensitivity of the detectorsystem.
13.5.4Checklist (i) PointDetector a. Detectortestedto : b. Detectortype : R.O.R i lonization/ Optical/ Infrared/ UV c. DetectorMode : Conventional/ Addressable d. BOMBAApprovalCertificatenumber: e . ExpiryDateof BOMBAApprovalCertificate : f.
Manufacture :
g . Countryof origin: h . Distancebetweendetector: j.
Heightfromfloorlevel:
k. Distancefromthe slab:
t. Typeand sizeof cableused m. Typeof conduitused: (ii)
AspiratedDetector a. Detectortestedto : b. Detectortype : c. BOMBAApprovalCertificate number: d. ExpireDateof BOMBAApprovatCertificate : e. Manufacturer: f. Countryof origin: g. Type of air-samplingpipe :
166
j.
Types of pipe fittings :
k. Distancebetweensamplingpoints: l.
Distancebetweensamplingpipes :
m. Heightfrom floor level : n. Distancefrom the slab : o. Type and size of cable used :
p. Typeof conduitused:
13.6.Power Supply 13.6.1Concept A vast majorityof the fire alarmsystemrelieson electricalpowerfor theiroperation.No electrical powersourceis totallyreliable;everypowersourcewill fail sometimes,even if it is for a limited periodonly. The requirements for fire alarm systempowersupply is generallybasedon the principlethat the unreliability of its mainsuppliessourceshouldnot affectthe reliability withwhicha firealarm respondsto a fire. In general,high reliabilityof the powersupplyof fire alarmsystemcan be realisedby a normal supplyfrompublicmains,backedup by readilyconnected batteryback-upsupplyin caseof main supplyfailure. 13.6.2DesignRequirements (i) Gode& Standard PowerSupplyshallbe designedbasedon: M.S.1745:Part4 - FireDetectionand FireAlarmSystems Part4: PowerSupplyEquipment (ii)
General (a) Any cablesdirectlyconnected to a publicor privatedistribution boardshouldbe in accordance witha currentissueof IEEWiringRegulations. ( b ) C o n n e c t i o on f m a i np o w e rs u p p l yt o f i r e a l a r mp a n e ls h o u l db e v i a a n i s o l a t i n g protection device(eg.isolating fuse)reserved solelyfor thatpurpose. Thecovershould be colouredredand labeled"FireAlarm:Do NotSwitchOff'. (c) Arrangement powersupplyto the shouldbe madeso thatthe continuity of theelectrical firealarmsystemis ensured. to Particular careshouldbe takenwherethereis a tendency power when switched off of machinery, supplyto a switchboardeg. Duringmaintenance unoccupied or for economyin theconsumption of electricity.
167
(iii)
Types of Power Supply (a) Normalsupply - Normalsupplyshallbe from the publicmains,through private a switchboard. In the absenceof publicpower supply,privategeneratedpower may be used. (b) Secondarybatteries - T h e m o s t c o m m o n l yu s e t y p e o f s t a n d b ys u p p l y i s a s e c o n d a r yb a t t e r yw i t h a n automaticcharger. - Wheresucha batteryis used,it shouldbe of a type havinga lifespanof at least4 years underthe conditionof use likelyto be experiencedinsidethe fire alarm panel. - Since the life of the batteryis frequentlydependent on its chargingconditions,care shouldbe takenthat the batterychargersatisfiesall requirementsspecifiedby the battery manufacturer. - where replacementbatteriesor battery capacities, refer to (iv) and (v) - The chargingrateof the batteryshouldbe such that, havingbeen dischargedto its final voltage,the batterycan be chargedsufficientlyto comply with the recommendations of (v), after a chargingperiodof 24 hours. (c) SecondaryBatterieswith StandbyGenerator - In most premises,other than suppliestaken from the publicmains,an emergency generatoris providedwhich startsautomatically on failureof the normalsupply. - Sincethereis a time delaybetweenthe mainspower failureuntilthe generatorcranked into life to provideemergencybackup power supply,the secondarybatteriespower supplyis essentialto providecontinuousoperationof the fire alarm system.They are also essentialshouldthe emergencygeneratorfail to be activated.
(iv)
Maximum Alarm Load (a) The maximumalarm load is the maximumload imposedby the automatic fire alarm systemon a powersupplyunderfire conditions.lt includesthe powerrequiredto operate all the sounderssimultaneously,togetherwith any visibleor audibleindications at the Controland IndicativeEquipment,any power drawnfor the operationand/ or indication of ancillaryservicesand the transmission of signalsto remotemannedcentres.Becauseof the possibilityof spreadof fire throughoutthe building,the systemshould be able to s u p p o r tt h e m a x i m u mn u m b e r o f d e t e c t o r st h a t c a n s i m u l t a n e o u s l yg i v e signals indicatingfire, and the operationof manualcall pointat all zones. (b) Mrmal and standbypowersupplyshouldeach be capableof supplying the maximum alarm load irrespectiveof the conditionsof othersupply. (c) The load imposedon the power supply by the simultaneousoperation of detectorsand / or manualcall pointsshouldnot cause an existingfire alarm to cease.In system using microprocessors or storedprograms,the impositionof the maximumalarm load should not cause incorrectoperation.
168
(v)
Duration of the Standby Supply (a) The standbypowersupplyshouldbe capableof automatically maintainingthe systemin normaloperationfor a periodof not less than 24 hours after the detectionof a fault in the normalsupplyand the initiationof remedialaction. (b) lf the buildingis likelyto be unoccupiedand the fire alarm systemunsupervisedfor periods longer than 24 hours, so that on reoccupation,the standby supply could be exhaustedand the system inoperable,then facilitiesshouldbe providedto give protection for a period of at least 24 hours after reoccupation,with sufficientcapacityat the end of that time to sound an evacuationalarm in all zonesfor at least30 minutes. ( c ) F o r i t e m 1 3 . 6 . 2V . b . , n o r m a l l yt h e a s s u m p t i o nf o r t h e l o n g e s tu n o c c u p i e da n d unsupervisedperiodis taken over a long weekend,which is 72 hours.
(vi)
Baftery Charger (a) To preservethe life of the Standby backup batteries,the proper selectionof the battery charger is very important. (b) Incorrectselectionof batterychargerand chargingmethodwill causethe batteryto be overchargedthereby causingdeteriorationof the electrodesand hence the performance and the life span of the battery. (c) For maintenancefree sealed Lead-acidBattery,the Constantvoltageconstantcurrent charge methodis recommended.As chargingproceeds,there is a rise in batteryvoltage, the constantvoltagechargerwill detectthe voltageincreaseand controlof the charger amount. (d) The constantvoltageconstantcurrentchargerhas currentlimitationto preventthe initial current (at low batteryvoltage)from increasing.
(vii)
Battery Installationand Servicing (a) standby batteriesshould be secured from excessivevibrationor impact. (b) All standbybatterieswhen housedwithinthe Controland IndicativeEquipmentshould be compartmentand positionedaway from any heat generatingbody (eg. transformer). Batteriesshould be stored in upright positionwith batterycompartmentwell ventilated. (c) Batteriesmay producea combustiblegas. Avoid installationof closedequipmentnear sparks(i.e.near a switchor fuse). (d) Usingvinylchloridesheathedcableor a vinylchloridesheetmay inducecrackon battery containeror cover. (e) Avoid usingbatteriesin the followingareas: - Area exposedto directsunlight - Area where there is excessiveradioactivity,infra-redradiation,or ultra-violetradiation - Area filledwith organicsolvent,vapor,dust, salt,or corrosivegases. - Area of abnormalvibration (f) When connectingthe batteryto a charger or a load, keep the circuit switch OFF and connectthe battery's(+) pole to the (+) pole of the chargeror the load and the (-) pole to the (-) pole of the chargeror load.
169
(g) Neveruse batteriesof differentcapacities,batteriesof differentperformances,or new and old batteriestogether. (h) Inspectand checkfor the followingabnormalities,discoverthe cause and replaceany defectivebatteries: - Any voltageabnormalities - Any physicaldefects (eg. crackedor deformedcontainer) - Any electrolyteleakage - Any abnormalheat builtup (viii) BatteryCapacityCalculation (a) For batterycapacitycalculation,referto Table 13.3 13.6.3Testing and Commissioning (i) Ensure batteriesare properlyconnectedto each respectiveterminal. (ii)
Check batterycapacitywith volt metre to ensure the batteryis fully charged.Healthybattery should record 24 volts.
(iii)
Recordthe date of commissioningon the batterieswith markerpen.
(iv)
Turn off the mains power supply of the fire alarm indicatingand control panel, the volt metre on the panel surfaceshouldregister24 volts t 4 volts.The amperemetre should registerlitle or no readings.
(v)
Usingthe facilitiesprovidedon the Controland IndicativeEquipment,initiatea mainspower failure.
(vi)
Initiateall sounders,manualcall points,selecteddetectors,ancillaryoutputsand any other power consumptiondevicesfor 30 minutes.
(vii)
Monitorthe performanceof the batteriesand comparewith the power curve providedby the manufacturerto ensure compliancewith the specification.
(viii) Rechargedthe batteriesto fully charged status before conductingthe standby power test.
,
(ix)
For standbypowertest, repeatctauses 13.6.3(ii), 13.6.3(iv) and 13.6.3(v)
(x)
Recordtime of conductingtest and lock and seal the Controland lndicativeEquipmentand controlpanelincludingthe batterycompartment.
(xi)
Record the battery72 hours later with volt metre. Initiateall soundersfor 30 minutes,the batteryshouldbe able to sustainsuch operation.
(xii)
Turn the mains power supplyback on and ensurethe durationrequiredto rechargethe batteriesthe batteriesto full charge capacity is within the duration specified by the manufacturerand as stipulatedby the standards.
(xiii) Check each batterywith voltmetreto ensure batteriesregistered24 volts.
170
13.6.4Ghecklist BatteryManufacturer: a. b.
Makeand Model:
c.
: Countryof manufacture
d.
: TestStandard
e.
Lifeexpectancyof Battery:
f.
BOMBAapprovalcertificatenumber:
g.
: ExpiryDateof BOMBAapprovalcertificate
h.
BatteryCapaci$:-
j.
BatteryVoltage:
k.
TypeofCharger:
l.
Methodof charging :
m.
ChargerCapacity:
n.
(charger): Countryof manufacture
o.
No of zoneson FireAlarmPanel:
p.
: No of Sounders
q.
No of ManualCall Points:
r.
No of Detectors :
s.
on panel: No of Indications
t.
No of Ancillaryoutput:
Years
AH Volts
171
Table 13.3 Battery Standby Power RequirementCalculation
zones_
FireControlandlndicativePanel
1.
MasterController
1 x-
2.
C.M.S.to FireBrigade
1
3.
ZoneUnit
4.
SmokeDetectors
5.
HeatDetectors
6.
Smoke/ HeatDetector
7.
l.R./U.V.Detector
_x_
8.
AudioFireAlarmUnits
_x_
9.
VisualFireAlarmUnits
X
rype
x
_x_ X
10. Audio/ VisualF.A.Units Points 11. ManualCall 12. PumpIndications 13. A.H.U.Tripping FireSupp.Sys. _ x _ 14. Energized WarningLg. 15. GasDischarge
X
DropCurtain 16. Energized 17. B.A.S. 18. RollerShutter
_x_
DoorHolder 19. Magnetic
_x_
20.
SmokeExtractSystem
21.
Interface Units
22.
OtherAncillaryOutputs
X
x
=
TotalAlarmLoad
172
Amp
B
Standby Load
1.
MasterController
1 x_
2.
C.M.Sto FireBrigade
1 x-
3.
ZoneUnit
4.
SmokeDetectors
5.
HeatDetectors
_x_
6.
Smoke/ HeatDetectors
_x_
7.
l.R./U.VDetectors
8.
AudioFireAlarmUnits
9.
VisualFireAlarmUnits
Ampere
Ampere
_x_ X
X
1 0 . Audio/ VisualF.AUnits ' t 1 . Manual CallPoints
_x_ X
12. InterfereUnits 1 3 . OtherAncillary Outputs
=
_x_
Total StandyLoad
Amp ==============
BatteryCapacitySizing= (A x 1 H) + (B x 24 H) AmpereHour =_
X 10%(SafetyFactor)
=_
A.H (AmpereHour)
=_
A.H (ToManufacturer's Requirement)
Note:Batterycapacitysizinghasto be selectedbasedon the manufacturer's availablesize.The selectionshouldonlybe basedon selecting the nextsizeup fromthe manufacturer's tableif the exactsizecalculated is notavailable on the market. 13.7 Cables & Wirings 13.7.1Concept ForfireDetection andAlarmsystemto functionsatisfactorily duringa firecondition, all interconnections betweencomponents shouldbe intactandshouldbe operational. 'l3.7.2 DesignRequirements (i)
Codeand Standard Cablewiringshallbe designedbasedon: 8.S.5839: Part1 - FireDetection andAlarmSystemForBuildings - Codeof Practice for SystemDesign,lnstallation and Servicing. 173
(ii)
General A wide varietyof cablescan be used in variouspartsof a fire alarmsystem.However,because of their varyingabilitiesto resistsfire and electricalor mechanicaldamage,many of these cables may be restrictedin their suitabilityfor specificapplications.The applicationis cfassifiedaccordingto the need for fire protectionas in Clauses7 .24 and 7.25.
(iii)
Application (a) Prolongoperationduringa fire is required: - Cablesusedfor the interconnection of components of a firedetectionand alarmsystems and requiredto continueto operateaftera fire is discovered,eg. Controland Indicative Equipment,sounders,power supply. - Cablesusedwithinthe protectedpremisesfor the transmission of the alarmto a remote centreshouldbe includedin this class. (b) Prolongoperationduringa fire is NOT required: - Cableswhich are not requiredto continueto appreciatedperiodsafter the fire is discoveredor they are attacked by fire. - Thesecableswill usuallybe only thoseto detectorsor manualcall points,but may also includethoseancillarydevices(suchas door holders)in whichfailureof the cabledue to a fire will not lead to a dangerouscondition.
(iv)
Recommended Cable Types Types of cables recommendedsubjectedto the restrictionon their use and the recommendationsfor further protectionin Clauses7 .24 and 7 .25. (a) Mineral-insulated copper sheathed cable complyingwith BS 6207, with or without an overallPVC sheath. (b) Cablescomplyingwith BS 6387, meetingat leastthe requirements for categorisation as AWX or SWX. (c) Cablescomplyingwith BS 6387, meetingat leastthe requirementsfor categorisationas A or S. (d) PVC-insulated and sheathedcablescomplyingwith BS 6004. (e) PVC-insulated non-sheathedcablescomplyingwith BS 6004. (f) PVC-insulated cablesof type BK, BR and BU complyingwith BS 6231. (g) PVC-insulated and sheathedsteel-wire-armoured cable complyingwith BS 6346. (h) General- purposeelastomer-insulated polyethylene textile-braided or hard ethylene propylenerubberinsulationcomplyingwith BS 5467. PVC-sheathedcoaxialcable,with a centralconductorof not less 0) Polyethylene-insulated than 16 strandsI 0.2mm in diameter,but otherwisecomplyingwith the dimensional requirementsof BS 2316 : Part 3 for UniradioSheetM210.
174
(k) Cablesdesignedfor the detectionof heat. (v)
Gable Protection from Fire (a) Prolongoperationduringa fire is required: - Cablesrequiredto continueto operateduringexposureto a fire shouldbe type Clauses 13.7.2.(iv)(a) and 13.7.2.(ivXb). - Other cables may be used if they are buried in the structureof the buildingand protectedby the equivalentof at least 12mm of plaster. (b) Prolongoperationduringa fire is NOT required: - Where prolongedoperationduring a fire is not required,any cableslistedin Clauses 13.7.2.(iv)can be used withoutany additionalfire protection. (a.2)shouldstillcomply (a.1) and 13.7.2.(v)(a) Note:Cableslistedin Clauses13.7.2.(v)(a) with the requirementsin Clause 13.7.2.(vi)
(vi)
Cable Protection from Electrical or Mechanical Damage (a) ElectricalProtection - M.l.C.C.cablesshouldbe electricallyprotectedby ensuringthat associatedequipment complieswith the cable manufacture'srequirementfor voltage surge protection. - Polyethylene-insulatedcoaxial cable should not be used with nominalvoltages exceedinq50 volts. - CablesOl.ign"O for the detectionof heat shouldbe used withintheir manufacturer's ratings. (b) MechanicalProtection - Some of the cableslistedin Clause 13.7.2.(iv)are not sufficientlyrobustto withstand mechanicalhazards,such as impact,abrasion,etc. In order to protectsuch cablesfrom damage both during and after installation,it will be necessaryto providemechanical protectionsby installationin conduit,ducting or trunkingor by layingthe cables in a channel. - Recommendations for mechanicalprotectionare as follows: . C a b l e si n C l a u s e s1 3 . 7 . 2 . ( i v ) ( a ) , 1 3 . 7 . 2 . ( i v ) (ahn) ,d 1 3 . 7 . 2 . ( i v X j m ), ay be used without mechanicalprotection. . Cablesotherthan Clause 13.7.2.(vi)(a) shouldalways have mechanicalprotection.
(vii)
Conduit, Ducting and Trucking (a) Metalor high impactrigid PVC conduitmay be used for cabling.High impactrigid PVC conduitshouldcomplywith classification40511or 42511of BS 6099 : Section2.2. (b) lf fire alarmcablesare run in trunkingor ducting,then eithermetaltrunkingor ducting; or non-metallicductingor non-flamepropagatingtrunkingcomplyingwith BS 4678: Part4 shouldbe used. (c) All bracketingfor conduits,trunkings,ducting should be properlyconstructedand securedat recommendedspecificintervals.
175
13.7.3Testingand Commissioning (i) Checkand ensurethat cableselectionfor each partof the Fire Detectionand Alarmsystemis correct. (ii)
Ensureall cablesmet relevantfire, electricaland mechanicalprotections.
(iii)
Ensureall conduits,trunkings,ductingcomplywith relevantstandard.
(iv)
Ensureproperelbowsand tees with inspectionopenings,junctionboxesare usedwith conduit for cabling.
(v)
Ensureconduitsare properlysecuredto junctionbox,elbowand tees to preventcablingbeing severedby dislocationof the fittings.
(vi)
purposesand for ease of maintenance. Ensureall cablesare colourcodedfor easy identification
(vii)
Check and ensurebracketingat recommendedspecificintervals.
13.7.4Checklist Type of Cablesused : a. b.
Size of cable :
c.
Countryof Manufacture :
d.
MakeandModel:
e.
StandardTested to :
f.
BOMBAApprovalCertificateNumber:
g.
ExpiryDateof BOMBAApproval:
h.
Type of Conduit:
j.
Size of Conduit:
k.
: Countryof Manufacture
l.
MakeandModel:
m.
Testedto : Standards
n.
BOMBAApprovalCertificate Number:
o.
Expiry Date of BOMBA Approval Certificate:
p.
Type of Trunking:
q.
Size of Trunking:
176
r.
Countryof Manufacture :
s.
Makeand Model:
t.
StandardTested to :
u.
BOMBAApprovalCertificateNumber:
v.
ExpiryDateof BOMBAApprovalCertificate:
13.8 VOTCEALARM SYSTEM (VAS) 13.8.1Goncept (i) A voicealarmsystemis intendedto be usedin conjunction with a fire detectionand alarm systemto controlthe safeevacuation of buildingoccupantsbe providing: (a) A clearandunambiguous spokeninstruction for evacuation of the areaof immediate risk (b) Voicemessages andsignalwhichcontribute to the management of an emergency. (ii)
VoiceAlarmSystem(VAS)linkedto FireDetectionandAlarmSystems(FDAS)mayalsobe usedto givewarningof otherincidents, eg.bombalert,chemical spillageandextinguishing agentdischarge.
(iii)
Thesystemmayalsobe usedfor otherfunctions, suchas broadcast of music,pagingor general providedthat suchfacilitiesare alwaysoverriddenin the eventof an announcement emergency.
(iv)
Oncea fireis detected,it is essentialthatpeoplebe evacuated fromthe areasof immediate dangeras quicklyas possibleto minimizeriskto life.This may presentfew problemsif occupantsare familiarwiththe layoutof the site and has undergoneevacuationprocedure drill.Forpublicassemblyareaswhereoccupantsare notfamiliarwiththe layoutof the siteor haveno experience in evacuationprocedure, preciseverbalinstruction will be necessary on the actionsrequiredof them.
13.8.2DesignRequirements (i) Codes& Standards (a) VoiceAlarmSystem(VAS)shouldbe designedbasedon: 8 . S . 5 8 3 9P: a r t1 - FireDetection andAlarmSystemForBuildings Codeof Practice for SystemDesign,lnstallation andServicing. B.S.5839: PartB - FireDetection andAlarmSystemfor Buildings Codeof Practice for the Design,Installation andServicing of VoiceAlarmSystem. (ii)
General (a) Components of VASshouldbe compatible to ensuretheeffectiveness andintelligibility of broadcast messages.
177
(b) Compatibility shouldbe ensuredbetweenmicrophones, amplifiers,loudspeakers and interconnecting cablesfor optimumperformanceof the system.Care shouldbe takento ensurecompatibility withcableparameters, suchas capacitance and signalcharacteristics. (c) The VAS should"latch"on when receivinga signalfrom the FDAS untilde-latchedby a separatecommandfrom the FDAS. (d) The interfacebetweenthe FDASand VAS shouldbe such that any delayin the automatic transmissionof the relevantpre-recordedmessageis minimised. (e) The delaybetweenoperationof a manualcall pointand the startof VAS broadcastshould not exceed 3 seconds. (0 lf the automatictransmission of the pre-recorded messageis in responseto a signalfrom an automaticfire detector,the broadcastshouldbeginwithin 10 secondsafter the detector responded. (iii)
Loudspeaker Circuit (a) The integrityof VAS should be equivalentto that recommendedby BS 5839 : Part 1 for sounderunits. (b) lt is recommendedthat the wiringof the speakercircuitsshould be arrangedthat, in the event of a short-circuitdevelopedduring a fire, a minimum of one speaker should continueto operate. (c) All loudspeakercircuitsshouldbe protectedagainstfire and mechanicaldamage. (d) An open-circuitor short-circuitfault on one loudspeakercircuit should not affect the operationof any othercircuitor loudspeakerzone. (e) A short-circuit fault on a loudspeakercircuitshouldnot cause damageto the associated amplifier. (f) Any failureof a loudspeakercircuitshouldresultin a fault warningat the FDAS Control and IndicativeEquipment. (g) Additionalloudspeakercircuitsshouldbe providedin the followinghuge assemblyarea (typicallywithina singlespace): - Transportation - Mall areas of coveredshoppingcomplexes. - Publicareas of . cinemas,theatresand other placesof entertainment . large departmentalstores . lecturetheatres.centers - Any uncompartmented publicspaceswithina buildingif the space is: . Greaterthan 4000m2in area or . Designedto accommodatemore than 500 membersof the public
178
(iv)
VisualAlarm Signal (a) In areas with high backgroundnoise or where occupant is wearing car protectorsor impairedin hearing,the broadcastmessagesshouldbe supplementedwith visual alarm signals. (b) Visualalarmsignalsshouldalwaysbe providedif backgroundnoiselevelsexceedgOdBA.
(v)
lnterfacedwith Other Sound Systems (a) lf thereare other independentsystemon site eg. publicaddress,pipedmusic systemor soundreinforcementsystem,pipedmusicsystemor sound reinforcementsystem, switchingoutputshouldbe providedfor automaticallymutingsystems. (b) Cancellation of the mute shouldonly be possibleat the Controland IndicativeEquipment of FDAS.
(vi)
Gombined Use with Fire Atarm Sounder when the VAS is supplementaryto the fire alarm system, it is recommendedthat: (a) The operationof the fire alarm soundersshould not cause the intelligibility of the voice broadcastto be below the recommendedvalue. (b) Attention-drawingsignal for introducingvoice messageshould be the same as those producedby the fire alarm soundersfor a similar stage of alarm. (c) The procedurefor operatingsuch systemsshould be such as to avoid confusion in an emergency. (d) lf it is necessaryto silencethe fire alarm soundersin order to broadcastthe voice messages,restartingof the fire alarm soundersshould be automaticwithin 10 seconds.
(vii)
LoudspeakerZoning (a) The VAS should be capableof being subdividedinto loudspeakeremergencybroadcast zones determinedby specificevacuationprocedure. (b) Loudspeaker zonesneed not necessarilyfollowor be the sameas otherfire detectionzones. (c) Loudspeaker emergencybroadcastzonesshouldbeiselectedso that an effectiveevacuation of the building can be carried out without confusionor misinterpretationof the warning message. (d) Loudspeakerzone boundariesshould,where possiblecoincidewith compartmentation walls,permanentpartitionsor doorswithinthe buildingfor distinctivezone separation. (e) For loudspeaker zonings,careshouldbe takento ensurethata singleloudspeaker zonings may containone or more fire detectionand alarm zonings but NO single fire detection and alarmsystemzone shouldcontainmore than one loudspeakerzone.
(viii)
Protection of Loudspeaker (a) To ensurethat failureof the associatedcircuitis unlikelyto occur if the loudspeakeris exposedto fire beforeevacuationis completed,the designmeasuresshould include:
179
use of materialblockswith a meltingpointof not lessthan 650'C eg. ceramicmaterial, or use of terminalblocksof a lower meltingpoint but protectedwith thermalinsulation. or - designof the terminalblocks such that, on melting,an open-circuitor a short-circuit does not occur. (b) ln order to preventinadvertentcontact and damage by falling objectsor any other accidentaldamages,everyflush-mounted ceilingloudspeakers shouldbe fittedwith a rear enclosure.This shouldbe constructedfrom non-combustible materialwith a melting pointat least800"C,eg. steel. (ix)
Fire Microphone (a) Fire microphoneshould be providedas a means of overridingpre-recordedemergency broadcastmessages. (b) As the microphoneis commonto all areasof broadcast,which may have variedambient noiselevel,it shouldbe of a suitablegrade to achievethe requiredintelligibility of sound reproductionthroughoutthe entireinstallation. (c) The recommendedtypes of microphoneare as follows: - u n i d i r e c t i o n am l , o u n t e do n a f l e x i b l eo r f i x e d w i t h b u i l t - i nw i n d s h i e l dt o p r e v e n t "popping" noisewhilstspeaking.The recommendedminimum+- 5 dB frequencyrange for this type of microphoneis 200H2to 3kHz. - hand-heldclose-talkingnoise-cancelling, with an integralpress to talk switch.The recommendedminimum+- 5 dB frequencyrangefor this type of microphoneis 250H2 to SkHz. ( d ) The sitingof fire microphone(s) shouldbe agreedwith the Fire and RescueDepartment ( e ) Care shouldbe taken in locatingmicrophoneto avoid:
-
soundcolouration feedbackfrom system loudspeakers pick-upand amplificationof backgroundnoise reverberantacousticconditionsat microphone,all of which can reducethe quality of the signal
(f) Fore accessibility, the fire microphoneshouldeither: - be dedicatedpurelyto the broadcast of emergencymessages- careshouldbe takento preventits use for non-emergencyfunctions. - be used for emergencyand non-emergency functions- care shouldbe exercisedand meansshouldbe providedto preventnon-emergency broadcastfrom overridinga prerecordedemergencybroadcast.
180
(x)
Message Generator (a) For an effectiveVAS, the reliability and integrityof associatedmessagegeneratoris vital as the sourcefor providingand deliveringpre-recordedemergencymessages. (b) Messagegeneratorshouldbe designedto use solid-state electronic exclusively for message storageand control.Apart from relays(associatedwith statusor fault indication),there shouldbe no moving parts;tape playeror disk drives,for exampleshouldnot be used. (c) The recordingshould be storedin non-volatilememoryand the recordedmessages(s) shouldbe protectedfrom unauthorizedchanged. (d) The broadcastvoice shouldsoundnaturalwith high qualityrecording.No synthesised voiceshouldbe used unlessthe resultantbroadcastsoundis indistinguishable from that of a humanvoice. (e) Each messagegeneratorshouldbe monitoredcontinuouslyto ensurethe availabilityof audio output.
(xi)
Messages (a) Everymessageshouldbe precededby an attention-drawing signal.This is a non-speech signalin accordancewith 9.4.1.and 9.4.5.of BS 5839: Part 1 : 1988.The attentiondrawingsignalused for Alertand Evacuatealarmsshouldbe identical.Wherethis is not the case,the signalshouldnot be in accordancewith 9.9 of B.S. 5839 : part 1 : 19gg. (b) The messageshouldbe clear,concise,intelligible and deliveredin a calmand commanding manner. (c) Live messagesshould be broadcastonly by operatorstrainedin the proper use of the microphone. ( d ) E x c e p tw h e r e a F i r e O f f i c e ro r t r a i n e d p e r s o n i n a u t h o r i t yn e e d t o m a k e s p e c i a l announcements in an emergencysituation,the operatorshouldbroadcastagreedstandard messages,readingfrom a script. (e) For pre-recorded messages, the recordingshouldbe madeby personstrainedin the proper use of the microphone.The recordingsshouldbe made in a recordingstudioor a room with a controlledacousticenvironmenthavingan ambientnoiselevel no greaterthan 30 dB and a reverberationtime no greaterthan 0.5 secondsfrom 150 Hz to 1OkHz. (0 For EvacuationBroadcast,the time sequenceand formatof the broadcast.from startto finish,shouldbe : -
Attentiondrawing signal - lasting4 secondsto 10 seconds followedby
-,"r1,,',ly"loTfro Brief$ilence to2 secol.rds
.
"T;l"tJ[";"n" ,
Silence- lasting2 seconOs,to S seconds
181
- Greenfor indicationof energisationand selectionof loudspeakerzone - Any other indicationswithinVAS shouldnot be Red or Green (d) The Controlequipmentshouldbe designedto functionreliablywheneverservicedand maintainedin accordanceto the manufacturer'sinstructions.Equipmentshould be designedto have a servicelife of at least 15 years. (xiii) Power Supply (a) The operationof VAS is more complexthan that of alarm sounders,where the power supplyshouldbe in accordancewith BS 5839 : Part4 and followthe recommendations for life safetysystemsof BS 5839 : Part 1 : 1988. (b) The standbybatterycalculationsshould be as follows: = 1.25i(Dr x Tr x tr) + (DzX Tz x lz)) Cmin Cmin(AH) Tr lr (Amp)
Tz (hr) lz (Amp) Dr
Dz
1.25
is the minimumcapacityof the batteryal20'C when new [in amperehours(AH)] is the batterystandbyperiod[in hours] is the batterystandby(quiescent)load current[in amperes]lr is measured or calculatedas the sum of the quiescentcurrentof all the componentsof the VAS, based upon operationsat the nominalvoltage(V), including contributionssuch as the currenttaken by the fault monitoringcircuits is the alarm conditionperiod[in hours] is the total batteryload currentwith all loudspeakerzones in full alarm condition[in amperes] is a de-ratingfactorderivedfrom the manufacturer's data,based upon the quiescent time Tr. This factor is the standby currentlrand the discharge de-ratingfrom the 20 hours rate data, based upon full is a de-ratingfactorderivedfrom the manufacturer's alarm load currentlz and the dischargedtime Tz. This factor is the derating factor from the 20 hours rate and takes into account that the dischargetime is not greaterthan 20 hours the multiplying factoris includedto allowfor some ambienttemperature variationand batteryageing
13.8.3Testingand Gommissioning (i) Documentationshouldbe providedwithinor adjacentto the controlequipment: (a) OperationInstruction(Ol) for the correctactionin the eventof an emergencyor fault indication. (b) Systemlogbook,similarto the fire detectionand alarmsystem. (ii)
Drawingsshouldbe providedto the user, showingthe positionsof the variousitems of equipment,the size and routesof all cablesand wiringfor maintenanceand recordpurpose.
(iii)
The completedinstallation shouldbe inspectedto ensurethatthe work has beencarriedout in a satisfactorymanner,that the methods,materialsand componentsused are in accordance with BS 5839 : PartB : 1998.
toJ
(iv)
The systemshouldbe testedto ensurethat: (a) The soundlevelproducedby the loudspeakers is audiblethroughoutthe areaof coverage. (b) Each loudspeaker zone shouldbe testedto ensurethe correctalarmmessageis given in responseto bothautomaticinitiationand manualcontrols.Simulationof the automatic initiationshouldbe conductedvia the Fire Detectionand Alarm svstem. (c) Each loudspeakerzone shouldbe testedfor all othermessagesthrougheach and every mode of initiationsimulatedthroughthe normaloperatingprocedure. (d) Ensurethe interfacewith the Fire Detectionand Alarmsystemand any signalto ancillary equipment,such as visualbeaconsare operatingsatisfactory.
(v)
The installershould supply to the submittingperson and the Authoritya certificatestating that the installationis in accordancewith the recommendations given in relevantstandards.
(vi)
Shouldtherebe any deviationfrom the standards,and providedthesestandardshave been agreed and approvedby the Fire and Rescue DepartmentMalaysia,statementsof these deviationsshould be given by the installertogetherwith the submissionsof the complete certificate.
13.8.4Checklist (i) Voice AlarmSystem
a. VASmanufacturer: b. MakeandModel: c. Countryof Manufacture : d. VASTestStandard: e. BOMBAApprovedCertificateNumber: f. ExpiryDateof BOMBACertificate: (ii)
Back-upBattery a. Backupbatterymanufacturer: b. Make and Modelof Batterv:
c. Countryof Manufacture : d. BatteryTestStandard: e. BOMBAApprovalCertificateNumber:
f. ExpiryDateof BOMBAApproval: g. Lifeexpectancy of back-upBattery :
184
Years
h. Back-upBatteryCapacity: j. (iii)
Voltageof Batterypercell:
Volts
BatteryCharger a. Chargermanufacturer : b. Type and Methodof Charging : c. Chargercapacity:
d. Countryof chargermanufacturer : (iv) Loudspeaker a. Loudspeaker Manufacturer : b. Type of Loudspeaker: c. Make and Model of Loudspeaker: d. LoudspeakerTest Standard: e. Dynamicrange of Loudspeaker: _
Hz to
k{z
f. No of Loudspeaker Zones: g. Countryof Manufacture : h. BOMBAApprovalCertificateNumber:
j. (v)
Expirydateof BOMBAApproval:
Fire Microphone a. Fire Microphonemanufacturer: b. Make and Modelof Fire Microphone: c. Countryof Manufacture: d. Type of Fire Microphone:
e. FireMicrophone TestStandards : f.
DynamicRangeof Fire Microphone: _
g. BOMBAApprovalCertificateNumber:
h. Expirydateof BOMBAApproval:
185
Hz to
kHz
(vi)
Cable a . CableManufacturer: b . Sizes of Cable/Cables:
: Countryof manufacture d
Make& Model:
e . CableTest Standard: f.
BOMBAApprovalCertificateNumber:
g. Expirydateof BOMBAApproval: (vii) Conduit a . Conduit Manufacturer: b.
Sizesof Conduits:
c . Countryof manufacture : d . Make& Model: e . ConduitTest Standard: f.
BOMBAApprovalCertificateNumber:
g. Expirydateof BOMBAApproval: (viii) Trunking/Ladder a . Trunking/Ladder Manufacturer : b . Sizesof Trunking/Ladder
Countryof manufacture: d.
Make& Model:
e . Trunking/Ladder Test Standard: +
BOMBAApprovalCertificateNumber
g . Expirydateof BOMBAApproval:
186
1 4 . 1D ES C R IP T ION systemis intendedto keep protectedescaperoutesof a buildingclearof smokeby A pressurisation meansof introducingsufficientfresh air to maintaina positivepressurein protectedescaperoutes againstaccommodationarea.Protectedroutesmay includestaircases,lobbiesand in some cases, the corridor. Pressurisationsystem may be omitted if there is sufficientprovisionof natural ventilationin protectedescape routesin accordanceto the UniformBuildingBy-lawsrequirementsand/orother acceptablestandards.
1 4 . 2D ES IGNR E QU IR E ME N T S 14.2.1Design Standards systemshall be designedin accordanceto: Pressurisation (i) (ii) (iii)
On1d 2 O 2 o f t h eU B B L1 9 8 4 B y - l a w1s 9 6 ,1 9 7 , 2 O O , 2 a M51472 AS1668
14.2.2Methods of Pressurisation (i) Method1 - PressurisingStaircaseonly The protectiongiven by this method is entirelyconfinedto the verticalpart of the escape route. lt shouldbe used only when a staircaseis approacheddirectlyfrom the accommodation spaceor througha simplelobby. Each stackof staircaseshall be servedby an independent pressurisation system. (ii)
Method2 - Pressurisingthe Staircaseand Lobby lf a lobbyseparatingthe staircasefromthe accommodation spaceis otherthana simplelobby, this lobbyshallbe pressurised independently of the staircase.The pressurelevelat the lobby shall be about 5 Pa less than the oressurelevelat staircase.
(iii)
Method3 - PressurisingStaircase,Lobbyand Corridor lf a corridoris of 30 minutesfire resistanceor more and forms part of a protectedescape route,this corridorshallbe equippedwith eithera pressurisation systemor smokeextraction system.The pressurelevelat the lobby/corridor shallbe about5 Pa lessthan the pressurelevel at staircase.
'l4.2.3 Detailed Design Requirements The pressurisation systemsshall be designedin accordanceto the followingparametres:(i) Method1 - PressurisingStaircaseonly (a) The pressurelevel at staircaseshould be 50 Pa higher than the pressurelevel at accommodationspace. (b) A minimumegressvelocityof 1.0 m/s is requiredwhen 1 no. of staircasedoor is opened. The no. of openeddoors shall be based on minimum2 nos. of doorsor no. of doorsfor 10ohof the totalfloors(worstcase condition),whicheveris higher.
188
(ii)
Method2 and 3 - PressurisingStaircase,Lobbyand Corridor(whereapplicable) ( a ) T h e p r e s s u r el e v e l a t s t a i r c a s es h o u l db e 5 0 P a h i g h e rt h a n t h e p r e s s u r el e v e l a t accommodationspace. (b) The pressurelevelat lobby/corridor shallbe higher(up to 45 Pa)thanthe pressurelevelat adjacentaccommodationspace,but less than the pressurelevelat staircase. (c) A minimumegressvelocityof 1.0 m/s is requiredwhen one lobbydoor and one staircase dooron the samefloor are opened.The no. of openeddoorsfor bothstaircaseand lobby shall be based on minimum2 nos. of doors each or no. of doors for lOYoof the total floors(basedon worst case condition),whicheveris higher. Worstcaseconditionrefersto the 10%floo(s) that havethe mostnumberof egressdoors.
14.3SYSTEMCOMPONENT The installationand equipmentassociatedto a pressurisation systemshallaccountfor: 14.3.1Air Intake Arrangement Air intakeshallbe arrangedin a mannerthat it has minimumeffectfrom wind velocityand direction and is at least5m away from any contaminatedexhaustoutlet. 14.3.2Fan Gapacity and Operation (i) 10o/o or 25% of additionalvolumeflowrateshall be allowedfor sheet-metalor builders'work ducting (masonryshaft) respectively. (ii)
Essentialpowershall be providedfor the operationof pressurisation fan.
(iii)
Pressurisation fan shallautomatically startunderfire mode.Manualcontrolshall be provided at bothfire commandcentreand on fan controloanel.
14.3.3Supply Air Outlets (i) Air outletsshall be installedat not less than every 3 floorsin a staircase,in order to provide efficientdistributionand even pressurefor the entirestaircase. (ii)
Thereshallbe at least1 no. outletper floorfor lift lobbypressurisation system.These outlets shall not be locatedcloseto the main leakagepath.
14.4TYPESOF STAIRCASE PRESSURISATION SYSTEMDESIGN 14.4.1 FixedAir SupplywithPressure ReliefDampers Fresh air is continuouslypumped into staircaseregardlessof the differentialpressurebetween the staircaseand accommodationarea.The controlof differentialpressurebetweenstaircaseand accommodation area relieson the operationof pressurereliefdampers. Pressurerelief dampers shall open or close to maintaina 50 Pa differentialpressure between staircaseand accommodationarea, when none of the doors are opened. Pressurereliefdampers shall be providedat not more than 15 metres vertical intervalto maintain an even pressure throughoutthe entirestaircase.
189
14.4.2VariableAir Supply with MotorisedBy-PassDamper For such application,the air quantityflow into staircaseshallbe controlledby a motorisedby-pass damper locatedat ductworkconnectingthe fan and the staircase.A differentialpressuresensor shall be installednear the bottom of the staircaseand shall measure the pressuredifference betweenaccommodationarea and the staircase. In the event that the differentialpressureis more than 50 Pa, the motorisedby-passdamper will bleedthe excessair into the atmosphereto maintainthe pressurelevel. 14.4.3Variable Speed Fan The operationof this type of pressurisationsystem is similarto Clause 14.4.2except that this system is equipped with variablespeed fan instead of having motorisedby-pass damper. The speedof the fan will vary in orderto maintaina differentialpressureof 50 Pa betweenstaircaseand accommodation area.
14.5 TYPES OF LIFT LOBBY PRESSURISATION SYSTEM DESIGN 14.5.1FixedAir Supply with PressureRelief Dampers This systemis similarto Clause 14.4.1exceptpressurereliefdampersare locatedat everyfloor,in orderto maintaina differentialpressurebetweeneach lift lobbyand adjacentaccommodationarea at every floor. Fusiblelink fire dampersshall be installedwith the relief dampersto maintainfire integritybetweenlobby and accommodationareas. 14'5.2VariableAir Supply with Motorised Fire DamperControl and Motorised By-pass Damper Each lobby is equippedwith a motoriseddamper air outletand differentialpressuresensor. All motoriseddampers shall be controlledin a manner that the differentialpressurebetween each lobby and adjacentaccommodationarea is maintainedat up to 45 Pa. Excessair will be relieved into the atmosphereby the motorisedby-passdamperat the fan discharge. 14.5.3VariableAir Flow with Motorised Damper Control and Variable Speed Fan This system is similar to Clause 14.5.2except the motorisedby-pass damper is replacedwith variablespeedfan.
14.6 TEST REQUIREMENTS 14.6.1Duct Pressure Test The entire pressurisationductwork shall be tested in accordanceto SMACNA HVAC Duct ConstructionStandards- Metaland Flexibleand manufacturer's recommendation. This is to ensure that air leakageis lessthan 10%. 14.6.2Flow Test Each outletshall be balancedand testedto achievethe requireddesiqnairflow. 14.6.3 Performance Test (i) A simulationtest shallbe carriedout with the no. of opendoorsas per design.The velocity acrosseach openeddoorshallbe not lessthan 1.0 m/s. (ii)
Differentialpressurebetweenstaircaseand accommodationspace and betweenlobby and accommodation spacewhen all doorsare closedshallbe measuredby usinga manometeror digitalpressuremeteror analogytype pressuremeter.
190
14.7 DESIGN AND INSTALLATION CHECKLIST 14.7.1Design Gode and Standard Adopted (i) Ms1472 (ii) AS1668 (iii) By-laws196,197,200,201,202of UBBL 1984 (iv) Other Standards,(to specify) 14.7.2Design Checklist (i) No. of floors (ii) No. of doors per floor (iii) Determineno. of closedand openeddoors (iv) Air leakagethroughcloseddoor (v) Air flow throughopeneddoor (vi) Fan sizing 14.7.3Visual Inspection Checklist (a) Visual Inspectionof Ductwork& Fittings (i) Sealant (ii) Fusible-link fire dampers (iii) Motoriseddampers (iv) Fire Rated Ductwork (v) Fire Seal (b)
Visual Inspectionof Fan and Wiring (i) Fan Installation (ii) FlexibleConnection (iii) Wiringtermination (iv) Cablesize (v) Fan controlpanel (vi) Pressuresensor (vii)Controlcomponents
14.7.4Testingand CommissioningChecklist (a) Duct PressureTest (i) Test pressure (ii) Test Duration (iii) Duct area (iv) Theoreticalleakage (v) Pressuredrop (vi) Actualleakage (vii)Test Apparatus (b)
Flow Test (i) Currentand voltage (ii) Flow acrosseach outlet (iii) Totalflow (iv) Theoreticalflow
(c)
PerformanceTest (i) Air speed acrossopeneddoors (ii) Differentialpressurebetweenstaircaseand accommodationspace
19'1
(iii) Differentialpressurebetweenlobbyand accommodation space (iv) Differentiar pressurebetweencorridorand accommodationspace (v) Operationof motoriseddampers (vi) Operationof pressurereliefdampers
14.8CALCULATION 14'8'l Example of Staircase and Lift Lobby Pressurisation System calculation 14.8.1,1GeneralDescriptionof Building A 30 storey office buildingwith 2 staircasesconstructed from ground floor up to roof level. Both staircasesare connectedto fire fightinglift lobbies,which in turn are connectedto accommodation areas' There is only one singleleaf door per floor for staircase. As for fire fightinglift lobby,there is only one singleleaf door separatingeach lift lobbyand the accommodationareas. There is one door connectingthe lift lobbyto a serviceshaft. However, this is not to be taken into accountas it is opened into an enclosedarea. Therefore,there are 30 doors in total for both staircaseand fire fightinglift lobbies.Referto Figure14.1 14.8.1.2Design Condition (i) The staircaseand lift robbieswiil be independenflypressurised. (ii)
All pressurisation shaftsare not providedwith sheet
(iii)
Accordingto UBBL,the no. of openeddoorsshall be minimum2 nos. or no. of doors at 10% of the totalfloors(worstcondition),whicheveris higher. Hence,for this case study,therewill be 3 floorswhere all staircaseand lift lobbydoors=are assumedto be opened.
(iv)
The designof pressurisation systemshallbe basedon constantspeedfan with pressure relief system.
metalductwork.
14.8.2sample carcuration for staircase pressurisation system 14.8-2-1Estimation of Air vorume Frowing past Doors when Doors Are Grosed (i) Designcriteriabasedon M51472 (ii)
LeakageArea Calculation: Basedon 50 Pa pressuredifferentialand interpolation of data from Table
3 and 4 (MS1472).
CaseA
Singleleafopeningintoa pressurised space
2.0m(H) 0.8m(W)
210cmh
CaseB
Singleleafopeningoutwardsfroma pressurised space
2.0m(H) O.Bm(w)
420 cmh
CaseC
Doubleleafopeninginto pressurised space
2.0m(H) 1.6m(W)
630 cmh
No. of singleleaf doors openinginto pressurisedarea = 27 No. of singleleaf doors openingoutwardsfrom an pressurised area = 0 No. of openedsingleleaf doors = 3
192
14.8.2.2Calculation of Air Leakage through Closed Doors (i) (CaseA) Air leakagefor 27 no. of door = 210 CMH x 27 = 5670 CMH (ii)
(CaseB) Air leakagefor 0 no. of door = 420 CMH x 0 = 0 CMH
(iii)
(CaseC) Air leakagefor 0 no. of door = 630 CMH x 0 = 0 CMH
14.8.2.3Calculation of Total Air Leakage T o t a la i r l e a k a g e= 5 6 7 0+ 0 + 0 = 5 6 7 0C M H . . . . . . . . . . ........ . . .(.A ) 14-8.2.4Estimation of Air Flow Past 3 Opened Doors (i) The size of each door is 2.00m (H) x 0.Bm(W) (ii)
Therefore,area of door is 1.60m2
(iii)
Basedon designcriteriaof 1 m/s air flow throughdoor when the door is opened,air flowrate = 1.60m2x 1.0 m/s x 60 sec x 60 min = 5760 CMH
(iv)
For 3 openeddoors,the air quantity = 5 7 6 0C M Hx 3 = i T 2 8 0 C M H . . . . . . . . . . . . . . . . . (. B )
'14.8.2.5Selection of Capacity for Pressurisation Fan (i) The minimumair required = (A) + (B) = 5670 + 17280CMH = 22950CMH (ii)
Add 25% leakagefactor (masonry shaft) = 28688CMH Note: lf masonryshaft is of reinforcedconcrete,10% leakagefactoris adequate
(iii)
The airflowof fan selected: = 29000 CMH
14.8.3Sample Catculationfor Lift Lobby Pressurisation System 14.8.3.1Estimation of Air Volume Flowing Past Doors when Doors are closed (i) Designcriteriabased on M51472 (ii)
LeakageArea Calculation: Based50 Pa pressuredifferentialandinterpolation of data from Table 3 and 4 (MS1472).
193
TypeOf Door
Size
LeakagePer Door (cMH)
CaseA
Singleleaf openinginto a pressurisedspace
2 . 0 m( H ) O.Bm(W)
210
CaseB
froma Singleleafopeningoutwards pressurised space
2 . 0 m( H ) O.Bm(W)
420
CaseC
Doubleleafopeningintopressurised space
2 . 0 m( H ) 1.6m(w)
630
CaseD
Liftlanding door2.0m(H)
2.0m(H) 2.0m(W)
ReferSection 5.3.2.3(MS1472)
No. of singleleaf doorsopeninginto pressurisedarea = 27 No. of singleleaf doors openingoutwardsfrom a pressurisedarea = 0 No. of openedsingleleaf door = 3 No. of lift landingdoors = 30 14.8.3.2Calculation of Air Leakage through Closed Lobby Doors (i) (CaseA) Air leakagefor 27 nos.of door = 210 CMH x 27 = 5670 CMH (ii)
(CaseB) Air leakagefor 0 no. of door = 420 CMH x 0 = 0 CMH
(iii)
(CaseC) Air leakagefor 0 no. of door = 630 CMH x 0 = 0 CMH
14.8.3.3Calculationof Air Leakagethrough Closed Lift Landing Doors Referto Equation(14)of sub-section 5.3.2.3of MS1472 E q u a t i o n : Q o = Qxc F n where, is the air leakagefrom one lobby past one lift door, Qo is the air leakagefor an isolatedlift door (valuetaken from Table 4 or derivedfrom Qc = Q" 0.0496x (Pr)1/2where PE is the pressurisation levelfor the lobby, F is the factordependingon vent size in lift shaftand takenfrom the appropriatecolumnof Table6 (MS 1472), N is the numberof pressurisedlobbyopeningsinto the lift shaft Hence,when appliedto; (iv)
(CaseD)
Qo (forone lobby) = Qc x F (assumelift shaftvent size = 0.16m2) n = 0.0496 x (50)1/2x 2.66m3/s
= 1 1 2C M H
30
194
Numberof lift(s)
- 1
Totalleakage
= 112 CMH x 30 landingsx 1 lift = 3360 CMH
T a b l e6 ( M S 1 4 7 2 )
No. of pressurisedlobbiesopeninginto the lift shaft (=n) 1 2 3 4 5 6 7 I I 10 12 14 16 above1 6 14.8.3.4Calculationof TotalAir Leakage Total air leakage(beforeadjustment)= 5670 + 0 + 3360 = 9 0 3 0C M H . . . . . . . . . .
Valueof F for vent size 0.1m2
0.16m2
0.860 1.280 1.460 1.540 1.580 1.610 1.620 1.630 1.640 1.645 1.650 1.655 1.660 1.660
0.94 1.60 1.99
2.22 2.35 2.44 2.49 2.53 2.56 2.58 2.60 2.62 2.63 2.66
(C)
14.8.3.5Estimation of Air Leakage through 3 Opened Doors (i) The totalno. of doorsis 30. Therefore,the designcalculationshallconsider3 nos. of opened singleleaf doors. (ii)
The sizeof the door is 2.00m(H)x 0.80m(W)
(iii)
Therefore,area of door is 1.60m2
(iv)
Basedon designcriteriaof 1 m/s air flow throughdoor when the door is opened: = 1.60m2x 1.0 m/s x 60 sec x 60 min = 5760CMH
(v)
For 3 openeddoors,the air quantity: = 5 7 6 0C M H x 3 = 1 7 2 8 0C M H . . . . . . . . . . . , ( D )
14.8.3.6Selection of Pressurisation Fan Capacity (i) The minimumair volumerequired = (c) + (D) = 9030 + 17280CMH = 26310CMH
195
(ii)
Allow leakagefactorof 25o/o(masonryshaft) = 32888CMH
(iii)
The airflowof fan selected = 33000CMH
1 4 . 9 T E S T I N G A N D C O M M I S S I O N I N GP R O C E D U R E S 14.9.1 Each individualpressurisationsystem should be testedthoroughlyin terms of (but not limitedto) staticpressureachievable,velocityof air throughdesigneddoors,operationand fail safe operation of motoriseddampers(if installed)and activatedon receiptof the appropriatesignalingdevice. 14.9.2 The MasterControlPanelshouldprovidethe necessarypressurisation fan switchesfor testingand manualoverrideof fan operationby authorisedpersonnel. 14.9.3 All test data must be recordedand witnessedby the Client'srepresentativeand this information must also be loggedin the O & M (Operation& Maintenance)Manual. A full set of as-builtdrawings,systemsequencecontrol,schematicand servicingdata must also be partoftheO&MManual. 14.9.4Example of Testing and Commissioning Record Sheet 14.9'4.1Function Test for Staircase/LiftLobby/Corridor Pressurisation System Projecttitle:........... Owner: Consultant: Contractor: 14.9.4.2Function Test for Staircase Pressurisation System StaircaseNo. (i)
Measurethe differential pressurebetweenaccommodation areaand staircasewhenall staircase doors are closed. Item
Description
Requirement
Measured
1.
Differential Pressure
50 Pa
. . . . . . . . . . . .p. a ...
196
Tick if Comply
(ii)
Measurethe velocityacrossopenedstaircasedoorwhenthe no. of doorsequalto the designed
no.of openeddoorsareopenedrandomly: Item Description
Requirement
Measured
1.
1 m/s
................m/s
VelocityAcross OoenedDoor
Tick if Comply
FunctionTest for Lift Lobby/CorridorPressurisationSystem L i f tL o b b yN o . . . . . . . . . . . . . . . . . . . . . . . . . / C oNr or i.d o r (i)
Measurethe differentialpressurebetweenstaircase/lift lobby/accommodation area when all lobbydoors and staircasedoors are closed.
Item Description
Requirement
1.
50 Pa
Differential
Measured
Tick if Comply
Pa
Pressurebetween staircase/ accommodation 2.
(ii)
Differential 40-50 Pa Pressurebetween lift lobby / accommodation
Pa
Measurethe velocityacrossopeneddoor when the no. designedlift lobbydoorsare opened. Item
Description
1.
VelocityAcross OpenedDoor
Requirement
1 m/s
Measured
Tick if Comply
................m/s
TestCarriedout by:
Figure 14.1
W i t n e s s ebdy : . . . . . . . . . . . . . Approveb d y :. . . . . . . . . . . . . Date:..........
197
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This chapterdescribessmoke controlby means of natural(displacementof exhaust)ventilation, powered(extractor exhaust and depressurrisation) ventilationor a combinationof both. Smoke controlby meansof pressurisation is describedseparatet/unoertne chapteron pressurisation. 15.2 DESIGN REQUIREMENTS 15.2.1Design Standards Designshallconsiderthe followingStandards: (i)
UniformBuildingBy-laws1984 By-law244 - The use of additionardesignstandards as appropriate. By-law245 - standardsotherthan those listed in UBBL 1984to be approvedby DGFRDM. By-law249 - smoke ventingin windowless,undergrouno structureand large area factories for safe use of exit. By{aw 250 - Naturaldraughtsmokeventsto be openedautomatically by an approvedmeans in the event of a fire. By-law251 - smoke vents providedunder By-law 249, shall be adequatelydesignedwith an
By-|aw'5' if l"il,li,'ii:11 ilT ['5r,,,,":";";; ; sys rem !r:}il: K5"il
By-law2sr - MaraysianStandardsto supersede ail otherstandards. (ii) MS 1780 (iii) BS 5588 parts4, 7, 10, 11 (iv) BS 7346 parts j, 2, 3 (v) BS 4422 part 5 (vi) BR 186 and 258 (vii) OtheracceptableStandards (viii) Fire SafetyEngineering_ performance BasedApproach
15.2.2Design Concepts (i) smoke obscuresvisibilityand can contributetowards fatalitiesin a fire incident.In fact smoke killsmore peoplein fires than heat,flamesor structuralcottapse.lt is thereforeincreasingly realisedthat occupantsafetyin a fire can be greatryimproveoby providingefficientsmoke controlsystems'Moreover,such systemscan timitp.p"rty damage,both diiecflyby reducing the spreadof smoke,and indirectlyby providing betteivisibilityand thus easieraccessto the seat of the fire for fire fighters. 'ii)
'
smoke controlis one of the toolswhich the fire safetyengineermay use to ensureadequate fire safetywithin a building. As such it should noi b" consideredin isolation,but as an integralpart of the total packageof fire safety rn"""rr", designedfor the building.Thus the need for smoke controlin any buildingtu"ib" oesignlo in conjunctionwith the means of escape' compartmentationand active suppressioi systems.Smoke controlshould be consideredunderthe followingcircumstances. (a) Smoke ControlforLife Safetv smoke controlfor life safetyprrpor", is of benefitin buirdingswhere meansof escapeto the open air cannotbe achievedwithina short perioJ of time and in which the meansof escapecould be severelycontaminatedwith smokeand becomeimpassable.Examples includeshoppingmalls,atriumbuildingsand highrisebuildingswith phasedevacuation i'e' when a proportionof the occupants are expectedto stay in the buildingfor the durationor part durationof the fire.
200
( b ) SmokeExtractionfor Fire FighterAccess
Smokeextractionfor fire fighteraccessis desirablefor buildingswhere either: - fire brigadeaccess is difficult,eg. basementsand high rise buildings;or - rapidattackon fire is necessaryto reducefire spreadand propertydamage. Buildingswhere smoke clearanceby naturalmeans may be difficult(eg. basements,windowless b u i l d i n g and s buildingswithoutopenablewindows)will requirea poweredsmoke purging/dilution system. 15.2.3Methods of Smoke Control The efficiencyof the smoke control system may be adverselyaffected by wind or outside temperatures.Pressuresgenerated by wind may affect operationof the extractionof smoke by providinga positivepressureat the point of extraction.Internalclimaticconditionsmay also affectthe movementof smoke particularlyin spaceswith large volumes,such as atriums.This is becauseforcedair circulationmay preventthe smoke of low-buoyancyfrom reachinginitiallythe pointof detection.The stack effectin tall buildingsand temperatureinversionmay also need to be considered. The varioustechniquescommonlyused for smoke controlare as describedbelow: (a)
SmokeContainment(passivemethod) Smoke Containmentrelieson physicalbarriersto limitthe spreadof hot smoky gases from one compartmentin a buildingto another. Passivecompartmentation such as doors,walls and floorscan be usedto providesome protectionagainstsmokeingress.The extentto which smokewill leakthroughthesebarrierswill dependon the sizeand shapeof leakagepathsand the pressuredifferentialsacrossthe paths.
(b)
Smoke Dilution Smoke Dilutiondescribesany method of mixingthe smoky gases with enough clear air to increasethe availablevisibilityand to reducethe threatfrom toxic productsof combustion. Applicationincludescar parkingarea where the low ceilingheightand exhaustductwork configuration may make smoke reservoirprincipleimpractical.
(c)
Smoke ReservoirExhaustVentilation(See also Clauses 15.2.4& 15.2.S) This is a methodthat providesa separationbetweenan upperlayerof smokeand a lowerlayer of relativelyclear air. This is achievedby continuouslyextractingsmoke from the buoyant smokereservoir(or layer),usingeithernaturalextractventilatorsor poweredsmokeexhaust fans.This air is then replacedby outdoorair, whichre-entersthe spacebelowthe baseof the smoke layer.
(d)
Depressurisation Depressurisation involvesthe controlof smoke using pressuredifferentialsin which the air pressurein the spacecontainingthe fire is reducedbelowthat in the adjacentspacesrequiring protection.This methodcan be combinedwith a variationof othersystemdesigns. Examples of applicationare internalroomsof an officefloor with a total floor area exceeding1,000m2 where the introductionof low level replacementair is impractical.
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15.2.4Engineered Smoke Control System EngineeredSmoke ControlSystemprovidesthe followingintent: (i)
The systemwill safelycontrolthe movementand spreadof smoke withinthe building.
(ii)
The systemis designedto removesmoke producedby a fire type and risk associatedwith a specificbuildinguse.
(iii)
T h e c o n t r o la n d r e m o v a lo f s m o k e w i l l e n h a n c et h e c o n d i t i o n si n s i d et h e b u i l d i n gf o r purposesof safe evacuationfrom the buildingand ingressfor searchand rescueoperation.
(iv)
T h e c o n t a i n e da n d d e s i g n e dm o v e m e n to f t h e s m o k e w i l l e n h a n c et h e o p e r a t i o n a l effectivenessof the sprinklers.
(v)
The containmentof the smokewithinthe smokereservoirwill minimisethe spreadof smoke throughoutthe buildingand thus reducethe costs associatedwith smoke damage to the buildingfabric,stock and capitalitems.
(vi)
The controland removalof smoke will maintainclearerand safer conditionsfor peopleto evacuatethe premises.This is done by keepingthe movementlevel of peopleclear from smoke and hot toxic gases and increasingthe visibilitylevelsto aid safe escape.
15.2.5Smoke Reservoirs/Zones (i) A smokereservoirwill preventthe spreadof hot smokeand gasesthroughoutthe wholearea of the building. lt will also assist in keepingthe smoke as hot as possibleand therefore maintainmaximumbuoyancyand movementtowardsthe extractionpoint. (ii)
The reservoirservesas a collectionpointfor the smokeand the designneedsto ensurethe smokereservoiris maintainedabovehead height,therebyensuringmaximumconditionsfor breathingand visibility(and minimisingconditionsfor panic). Minimumsmoke layer base (head heightclearance)shall be:
For the LowestFlooror SingleStorey = 2.75m (naturaldisplacementventilation) or 2.00m (powered extractionventilation) UpperStorey = 3.00m (naturaldisplacementventilation) or 2.00m (poweredextractionventilation) (iii)
Smoke reservoircreatesa singlepositionfrom which smoke can be extracted.
(iv)
For naturalsmoke ventilation,the limit of each smoke reservoir/zonewould be 2,000m2. Also referto Clause '15.3.8.
(v)
For poweredsmoke ventilation,the limitof each smoke reservoir/zone would be 2,600 m2 Also referto Clause 15.3.8.
(vi)
The maximumlengthof a smokereservoir/zone would be in the regionof 60 metresunless provenotherwiseby engineeredcalculation.
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(vii)
The amountof smokeextractionfrom the reservoirshouldbe sufficientto preventthe smoke layerfrom buildingdown to belowthe design head heightclearance.
(viii) The rateof extraction(naturalor powered)must be sufficientto meetthe designrequirements, in that it mustbe capableof extractingthe amountof smokewhichis enteringthe baseof the smoke layer.
(ix)
For any ventilationsystemto work effectivelythere must be an adequatesupplyof make up freshair (replacement air)to'balance'thesystem.
(x)
The replacement air must be introducedat the lowestpossiblelevel(at least0.5 metresbelow the base of the smoke layer).This is to ensurethat the smoke layer is not disturbedby the flow of air intothe building.The air velocityshouldbe minimisedto a value not exceeding 5 metres/second.
(xi)
The preferenceis for the replacementair to be introducednaturally,for examplevia: Louvres,doors,rollershutters,windows,or ventilators,all of which must open automatically so that the supplyof fresh air is guaranteed.
(xii)
Poweredreplacementair should not exceed 75o/oor be less than 50% of the extractedair volume.
15.3 APPLICATIONS 15.3.1Basement Smoke Control System (i) Wherethe totalaggregatefloorareaof all basementstoreysdoesnot exceed1,000m2,smoke vents in accordancewith Clause15.3.1(iii)may be providedin lieu of engineeredsmoke controlsystem. (ii)
Where the total aggregatefloor area of all basementstoreysexceeds1,000m2,engineered stipulatedin Clause15.3.8shallbe smokecontrolsystemthat complieswith the requirements providedfor all parts of basementwith the followingexceptions: (a) Wherethe basementor a portionof the basementis used as carpark,Clause 15.3.1(iv) can be adoptedfor the carpark,providedit is compartmentedfrom rest of the basement. (b) PlanVequipmentroom with floor area not exceeding250m2and compartmentedfrom the rest of the basement and providedwith two doors for better reach in fire fighting . operation. (c) PlanUequipment room with floor area exceeding250m2but not exceeding1,000m2, smokeventsin accordancewith Clause15.3.1(iii)or smokepurgingsystemof at least10 air-changesper hour shall be provided. (d) Serviceareassuchas laundries,officestoreroomand workshops(restrictedto staffonly) smokeventingprovisionin accordancewith Clause15.3.1(iii) whichare compartmented, or smoke purgingsystemof at least 10 air-changesper hour may be acceptedfor those areasin lieu of the engineeredsmokecontrolsystem.Automaticfire alarm/extinguishing systemshallalso be providedwhere requiredunderthe UBBL.
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(iii)
Smokeventsshallbe uniformlydistributed to induceand enhancecrossventilation adequately alongperimeterof basementand theiroutlets(whichshalleffectivelydischargedirecly to the outside)shall be easilyaccessibleduringfire fightingand rescueoperations.Installation shall complywith the followingrequirements: ( a ) The numberand theirsizesshallbe suchthatthe aggregateeffectivevent openings shall not be less than 2.5% of the basementfloor area served. (b) The vent outletsif coveredundernormalconditions shallbe breakable/openable in caseof fire. Breakablecoversshouldbe capableof beingopenedby the fire servicefrom outside the buildingand permanentnoticeidentifyingthe area they serveshouldbe providedon or adjacentto the covers. (c) The vent outletsare sited not less than 5 metresawav from exits. (d) Where ducts are requiredto connectthe vent to outlets,the ducts shall be constructed to give at least t hour fire resistancerating. (e) Separateducts and vent outletsor equivalentarrangementssuch as sub-ducts shall be providedfor each basementstorey.
(iv)
Where poweredventilationsystemis requiredfor car parkingareas in basementswith total floorarea exceeding1,000m2,a smoke purgingsystemwhich is independentof any system servingother partsof the buildingshall be providedto give a purgingrate of not less than 10 air changesper hour. lnstallationshall complywith the followingrequirements: (a) The smoke purgingsystem shall be activatedautomaticaltyby the building fire alarm system. In addition,a remote manual start-stopswitch shall be located at the fire commandcentre,or at the mainfire alarmpanel.Visualindicationof the operation status of the smoke purgingsystem shall also be providedwith this remote control switch. (b) Supply air shall be drawn directlyfrom the externaland its intakeshall not be less than 5 metresfrom any exhaustdischargeopening. (c) Wherethere is naturalventilationfor such basementcarparkbasedupon openingsequal to not less than 25% of the floor area of such storey,such naturalventilation may be consideredas a satisfactorysubstitutefor the replacementair of the smokepurging system for that storey. ( d ) Exhaustair shallbe dischargeddirectlyto the externaland shall not be less
than 5m from
any air intakeopening.
(e) Separateductsor equivalentarrangements suchas sub-ductsshallbe providedfor each compartmentedbasementstorey. (f) Whereductsare usedfor the basementcarparksmokepurgingsystem, they shallcomply with the requirementsof the DGFRDM. , (v)
Whereengineeredsmokecontrolsystemis preferred,it shallbe providedas specified under C l a u s e1 5 . 3 . 8 .
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15.3.2Smoke Controlsystem forAbove Ground premises (i) where the totalnon fire compartmented aggregatefloorarea exceeds1,000m2or the volume exceeds7,000m:,a smoke controlsystemshall be provided. (ii)
Wherenaturalsmokeventilationis provided,the smokeventsshall be in accordancewith Clause15.3.2.(v)
(iii)
Where poweredsmoke controlsystemis provided,thisshallcomply with Ctause15.3.2.(vi)
(iv)
Whereengineeredsmokecontrolsystemis provided,this shallcomply with the requiremenrs as stipulated in Clause15.3.g.
(v)
Smokeventsshallbe positionedat high levelabovethe smoketayer baseand conformto the requirementsspecifiedbelow: (a) The numberand theirsizesshallbe such that the aggregate effectivevent openingsshall not be less than 2.5% of the floor area served. (b) The vent outlets(whichshall effectivelydischargedirectly to the outside)shal be of the permanentlyopenedtype or will open automaticallyunder a fire mode conditionwithout human intervention. (c) Replacementair shall be by meansof naturalventilation. (d) Conformanceto Clause 15.2.s
(vi)
EngineeredSmoke ControlSystem design shall be applicable only for ceiling heights exceeding2 or 3 metres(SeeClause15.2.5)for the smokereservoirprinciple to be effective. Below2 or 3 metres(See Clause15.2.5)ceilingheights,powered smoke purging/dilution systemof at least 10 air changesper hour shall be providedto suit the conceptsadopted. Make up or replacementair shail be providedin the foilowingmanner: (a) For smokedepressurisation concept,no purposeprovidedreplacementair is necessary. However,pressuredifferentialbetweendepressurisedzone and the adjacent zone shall be maintainedat between10 to 50 pa. (b) For smoke dilutionconcept,replacementair may be introduced at any level but, if powered,shall be limitedto not less than 50% and not greater than75% of the exhaust air volume.
15.3.3Smoke Control System for Fire Fighting Access Lobby (i) Firefightingaccesslobbywhere not mechanicallypressurised, shall be smoke ventedin compliancewith the requirementsspecifiedbelow: (a) The openableareaof windowsor areaof permanentventilation shallnot be less than 2s% of the floor area of the lobby, and if ventilationis by means of openabte windows, additionalpermanentventilationhavinga free area of q64 cm, shall be provided. (ii)
A smoke lobbyshall be treatedas a protectedstainrvay as describedunder Clause 1s.3.4.
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Stairway 15.3.4SmokeControl System for Protected pressurisedshouldbe providedwith either: mechanically not where Protectedstainruay (i) levelhavinga clearopenablearea not (a) openablewindowsat each upperstoreyor landing |essthanSo/oofthecrosssectionaIareaofthestairway;or (b)Anopenab|eventout|etatthetophavingac|earareaofnot|essthan1m2. 15.3.5Smoke Control of Hotel Internal Corridors (i)Whereinterna|corridorsinhote|sarenotmechanical|ypressurised,suchcorridorssha|lbe smokepurgedatapurgingrateofnot|essthanl0airchangesperhour. (ii)Engineeredsmokecontro|systemmaybeappliedon|yforcorridorsexceeding2or3metres height(Clause1 5'2'5)' ( i i i ) N a t u r a l v e n t i | a t i o n i s p e r m i s s i b | e o n | y i f i n d u c e d c r o s s v e n t i l a t i oserved n i s a vcan a i l abe b|eandthe than 2'5% ol the floor area aggregateeffectivevent openingsof not less provided. Theaters etc) 15.3.6Smoke Control for Auditorium (Cinemas' than 2'5o/oof the floor area served shall be less not of Smoke vents with effectiveopenings (i) to auditoriahavingf|oor area providedfor auditoriawhich "," not sprink|erprotectedand more than 500m2if sprinklerprotected' (ii)
preferred,it shall conformto clause 15'3'8' where engineeredsmoke controlsystemis
15.3.7Atrium Smoke Control System specifiedin UBBL 1984 are relaxedfor atrium where the requirementfor compartmentation (i) providedfor a steriletube atriumtype as spacesin a building,smoke controlsystem shall be sPecifiedbelow: less and the volume of the atrium is (a) where the heightof the atriumis 17 metresor 19 m3/sor 6 air changesper hour' 17.000nior less,the smoke exhaustrate shall be whicheveris greater' ( b ) W h e r e t h e h e i g h t o f t h e a t r i u m i s l T m e t r e s o r | e s s a n d t h e v o | u m e o f t hper e ahour' triumismore be 19 m3/sor 4 air changes than 17,000m3,the smoke exhaustrate shall whicheveris greater' (c)WheretheheightoftheatriumismorethanlTmetres,thesmokeexhaustratesha||beat a minimumof 4 air changesPerhour' (d)Whereengineeredsmokecontro|systemispreferred,itsha||beprovidedasspecifiedin Clause15.3.8. (ii)
(iii)
controlsystemcomplyingwith the For a non steriletube atriumtype, engineeredsmoke requirementsasstipu|atedinC|ause15.3.Bshal|beadopted. The smoke controlsystemshall be activatedby: adjacentto each returnair-intake (a) smoke detectorslocatedat the top of the ittlutn and levels; from the atriumor beam detectorsat the appropriate
206
(b) the automaticsprinklersystemservingthe atriumzone/s; (c) automaticdetectorsystem(but not manualcall point); (d) manualcontrolsreadilyaccessibleto the Fire Brigade. 15.3.8EngineeredSmoke Control System systemby natural smokecontrolsystemshallbe in the form of a smokeventilation (i) Engineered or poweredextractiondesignedin accordancewith: (a) BR 186 - Designprinciplesfor smoke ventilationin enclosedshoppingcentres;or (b) BR 258 - Designapproachesfor smoke controlin atriumbuildings;or (c) Otheracceptablestandards,such as: - WarringtonFire ResearchConsultants(WFRC) - Societyof Fire ProtectionEngineersPublication(SFPE) Engineers(ASHRAE) - AmericanSocietyof Heating,Refrigerating and Air-Conditioning (NoteBR 186 and BR 258 are reportspublishedby the Fire ResearchStation,Building UK). ResearchEstablishments, (ii)
The buildingto be providedwith engineeredsmokecontrolsystemshallhave a smoke layer temperaturenot exceeding250'C.
(iii)
Capacityof the smokeventilationsystemshallbe calculatedbasedon the incidenceof a likely maximumfire size for a sprinklercontrolledfire as recommendedin the followingtable:
Fire Size Occupancy(Sprinklered)
HeatOutput (MW) 5 1.5 0.5 2.5 2.5 10 7 1.5
Shops ffices HotelGuestRoom HotelPublicAreas AssemblyOccupancywith fixingseating Warehouse BasementServiceArea (LorryParks) Car parks
Perimeterof Fire (m) 12 12 6 12 12 1B 15 13.5
(iv)
The capacityof a smokeventilationsystemshall be capableof handlingthe largestdemand for smokeexhaustunderthe worst case scenario'
(v)
The designsmoke layer base shall be abovethe headsof peopleescapingbeneathit. The minimumheightshallbe as describedunderClause15.2.5.
(vi)
to preventthe lateralspreadof smokeand to collectsmokefor removalshall Smokereservoirs constructioncapableof withstandingsmoke temperatures' be of non-combustible
207
(vii)
For cases where smoke is removedfrom the room of originthe smoke reservoirsize for a smoke ventilationsystemshouldnot exceed: (a) 2,000m2for naturalsmokeventilationsystem (b) 2,600m2for mechanicalsmoke ventilationsystem
(viii) For cases where smoke is removedfrom the circulationspace or atrium space the smoke reservoirsize for a smoke ventilationsvstemshouldnot exceed: (a) 1,000m2for naturalsmoke ventilationsystem (b) 1,300m2for poweredsmoke ventilationsystem (ix)
For cases where smoke is removedfrom the circulationspace or atriumspace, the rooms dischargingsmoke into the circulationspace/atriumspacesshouldeither: (a) have a floor area not exceeding1,000m2(for naturalventilationsystem)or 1,300m2 (for powered ventilationsystem) or (b) be subdividedsuchthat smoke is ventedto the circulationspaceor atriumonly from part of the room with floor area not exceeding1,000m2for naturalventilationsystem or 1,300m2for poweredventilationsystem, that are adjacentto the circulationspace or atrium.However,the remainderof the room needsto be providedwith independent smoke ventilationsystem/s.
(x)
The maximum length of the smoke reservoirshould not exceed 60 metres,unless proven otherwise.
(xi)
Adequatearrangement(s)shall be made in each smoke reservoirfor the removalof smoke in a way that will preventthe formationof stagnantregions.
(xii)
Replacementair shall be drawn directlyfrom the externalor adjacentspaces,and; (a) The design replacementair dischargevelocityshall not exceedSm/sto preventthe escapees being affectedby the air flow. (b) Replacementair intake shall be sited at least 5 metres away from any exhaust air discharge. (c) Replacement air shallbe dischargedat low level,at least0.5 metresbeneaththe designed "fogging" smoke layer,to prevent of the lowestclearzone. (d) Where the inlet cannot be sited at least 0.5m belowthe smoke layer,a smoke curtain or a baffleshall be used to preventreplacementair distortingthe smoke layer. (e) Where replacementair is takenthroughinletair ventilatorsor doorurays, devicesshallbe incorporatedto automatically open such inletventilatorsand doorsto admit replacement air upon activationof the smoke ventilationsystem.
(xiii) For caseswherethe smokereservoiris abovethe falseceiling,the ceilingshallbe of perforated type or evenlydistributedair inletswith at least 10% openings.
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(xiv) The smoke ventilationsystemshall be providedwith secondarysourceof power supply. (xv)
In conjunctionwith Clause 15.3.7(iii),the smokeventilationsystemshall be activatedby smoke detectorslocatedin the smoke controlzone. Use of smoke detectorsfor activation must be carefullydesignedso that accidentalor prematureactivationof smokedetectorsat a non-firezone due to smoke spillor spreadfrom otherareas is avoided.
(xvi) A remote manual activationand controlswitchas well as visual indicationof the operation statusof the smokeventilationsystemshallalso be providedat the fire commandcentreand where there is no fire commandcentre.at the main fire indicatorboard. (xvii) Exceptfor ventilationsystemsfor escaperoutesand smokelobbies,all otherair conditioning and ventilationsystemswithin the areas servedshall be shut down automaticallyupon activationof the smoke ventilationsystem. (xviii) Fans shall be capableof operatingat 250'C for 2 hours. (xix) The fans and associatedsmokecontrolequipmentshallbe wiredin protectedcircuitsdesigned to ensurecontinuedoperationin the eventof the fire. (xx)
The electricalsupplyto the fans shallbe by meansof cablesof at least2-hoursfire resistance.
(xxi) Smoke ventilationducts (bothexhaustand replacementair ducts) passingthroughanother fire compartmentshall be constructedto have fire resistanceratingnot less than that of the compartment. (xxii) Non-motorised fire dampersshall not be fittedin the smoke ventilationsystem. (xxiii) The time takenfrom the smokeventilationsystemwithina smokezone to be fullyoperational shall not exceed 60 seconds from system activation. (xxiv) For naturalsmoke ventilationsystemthe naturalventilatorsshall be: (a) defaultedin the "open"positionin the eventof power/systemfailure;and (b) positionedsuch that they will not be adverselyaffectedby positivewind pressure. (xxv) Naturalexhaustventilationshall not be used togetherwith poweredreplacementair or poweredsmoke exhaustventilation. (xxvi) All smokecurtainswhere required,unlesspermanently fixedin position,shallbe broughtinto positionautomaticallyto provideadequatesmoke{ightnessand effectivedepth. (xxvii)Smoke curtainor other smoke barrierat any accessrouteformingpart of or leadingto a meansof escapeshall not in theiroperationalpositionobstructthe escapeof peoplethrough such route. (xxviii)Whereglasswalls or panelsare used as smoke screensto form a smoke reservoiror as channelingscreens,they shall be able to withstandthe highestdesignsmoke temperature. (xxix) All smoke controlequipment(includingsmokecurtains)shall be suppliedand installedin accordancewith the acceptedstandardssuch as BS 7346.
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(xxx) To minimisethe phenomenaof plugholing,multipleinletsshouldbe (calculated or modelled) usedfor poweredsmokeextractionsystem. Also,the maximummass flowratethrougheach exhaustinletmust be limitedto suit the depth of smoke layer belowthe exhaustinlet. (xxxi) The ceilingjet producedwhen smokeplumehitsthe ceilingcan impactthe effectiveness of a poweredsmokeventingsystem.To containthis impact,smokeextractionshouldbe designed for a minimumsmoke layerdepthof 10% of the floorto ceilingheight.
15.4 CALCULATION 15.4.1Examples of Basement Carpark Smoke Gontrol System 15.4-1.1Descriptionof Building A 12-storeyofficebuildingconsistingof 3 basementcarparklevels. 15.4.1.2 Design Consideration The 3 levelsof belowgradecarparkshallbe independently smoke controlledby meansof powered exhaustsystemwith naturalreplacementsupplyair. The carparkventilationsystem is designedwith low and high level exhaust inletsto ensure the removalof heavierthan air toxic carbon monoxideand dioxide gases as well as rising hot air. Under smoke spill mode,the principleof smoke reservoirmay not be practicaldue to the low <3 metres headroomas well as the need to remove the heavierCO and COz gases at low level. Hencethe dilutionmethodof smokeextractionwill be more practical. Each level of carparkshall be compartmentalised by meansof fire rated rollershuttersinstalledat the ingressramps to limit its volumeto 42,000m3per compartmentedzone to complywith UBBL 1984. The ventilationrate shall be 6 air-changesper hour (ACH)for normaloperationand 10 ACH for fire mode operation. 15.4.1.3Design Calculation Each Carparklevel = 13,000mz Nett FloorArea Floorto FloorHeight = 3 m = 39.000m3 Volume = 108.3m3/s 10 ACH 4 Fan rooms located at 4 cornersof each carparkfloor. 2 ReplacementAir Shaftslocatedat oppositeends. Referto Figure15.4.1 15.4.1.4 Design Specification For each carparklevel Under normalmode,fans in operation(to provideminimum6 ACH) - 8-off @ 9.1 m3/s= 72.8 m3ls Under Fire mode,fans in operation(to provideminimum10 ACH) - 12-off@ 9.1 m3/s= 109 m3/s
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15.4.2Example of Smoke Control System for Office Floors 15.4.2.1 Description of Building A 12-storeyofficebuildingconsistingof 3 basementcarparklevels,3 publicarea podium levels,5 officelevels,a Mechanical& ElectricalPlantroomleveland incorporating a 7 storeyatrium. 15.4.2.2 Design Consideration The smoke controldesign for the office floors adopts the guidelinesissued by Warrington Fire ResearchConsultants(WFRC)as well as the "Designof Smoke ManagementSystems"published by American Society of Heating, Refrigeratingand Air ConditioningEngineers(ASHRAE) and Societyof Fire ProtectionEngineers(SFpE). Fig. 15.4.2 illustratesthe concept of the Office Floor Smoke Control system. A sandwiched pressurisation- smoke extract system is adopted, whereby the floor on fire will be under a negativelypressuredsmoke spill mode whilstthe floor immediatelyabove and below the fire floor are positivelypressurised. 15.4.2.3 Description of Engineering Design Each officefloor contains6 Air HandlingUnit (AHU) rooms. Replacementair is delivered into the AHU rooms by primaryAHU's (6 nos.) locatedat Level 6 (L6) plantroom.6 nos. smoke spill fans locatedat L6 plantroomare ducted into each AHU room and connectedto the return air ducts. By means of a series of motorisedsmoke dampers,smoke is extractedfrom the fire floor and dischargedabove the roof line. The positivelypressurisedfloors are achievedby actuating the respectivefloor AHUs to operate under pressurizationmode - Refer Fig. 15.4.21or clarity.The smoke spill mode for each office floor is activatedby any of the followingdevices: (i)
Smokedetectorsmountedwithinthe raisedfloor plenum,ceilingand returnair intake
(ii)
Sprinklerflow switchesservingeach officefloor
(iii)
Remotemanualcontrolsfrom the Main Fire control panel
15.4-2.4Calculation TypicalOfficeFloorarea Raisedfloor height Slab to raisedfloor ht Ceilingto raisedfloor ht
= 3.610 m2 = 0.4 m = 3.475 m = 2.7 m
DesignFireSize HeatOutput,e = 1.5 MW (Clause1S.3.8) FirePerimeter, P = 12m (Clause15.3.8) UsingWFRC Guidelines, M = 0.19 Pytrz Where M = mass of smoke (kg/s) y = heightfrom floorto smoke layer base (m) ThereforeM = 0.19x 12 x 3.13t2 = 12.44kgls
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Temperatureof smoke layerabove ambient, 0 = Q= 1500 = 120.6"C 12A4 M Ambienttemperature, To =273+33
= 306K
Smoke Temperature, Tc =306+120.6 =426.6K SmokeVolume, V =MxTc 3545
= 1 2 . 4 4 x 4 2 6 . 6= 1 5 m 3 / s 3545
Basedon volumetricspace,this translatesto 4.3 ACH 15.4.2.5 Design Specification 6 nos. smoke spill fans are specifiedto divide the smoke reservoirinto 6 zones, each less than 2.600m2. 6 fans each of 2.5 m3/sare selected,to give a total capacityof 15 m3/s Thesefans can also be utilisedfor the followingfunctions: (i) Smoke purgingafterfire (ii) Normalmode air flushingfor avoidanceof Sick BuildingSyndrome 15.4.3Examples of Smoke Control System for Atrium 15.4.3.1Descriptionof Building A 12-storeyoffice buildingconsistingof 3 basementcarparklevels,3 publicarea podiumlevels,5 a 7-storeyatrium. officelevels,a Mechanical& ElectricalPlantroomlevel and incorporating 15.4.3.2 Description of Atrium The atrium consistsof 7 levels (LG1 to L5). Level LGI which is the base of the atrium extends beyondthe foot printof the atriumvoid to enclosecommonarea lobbiesand foyers.The occupied roomsadjacentto thesecirculationareas are separatedby barriers(wallsetc). The ground floor level can be classifiedgenerallyas being opened directlyto the atrium from the exterior.The office levels(L1 to L5) are separatedfrom the atriumvoid by glass enclosures. However,each office level incorporatesa perimetercirculationbalconyoverlookingthe atrium. Escape routes for office tenants into the 4 protected lobbies/staircasesneed not transversethese exposedbalconies. The buildingis fully sprinklered.The glasswalls separatingthe balconiesand the officespaceare protectedwith closerangedsprinklersspaced1.Bmapart.However,the atriumvoid whichexceeds 17m height,is not sprinklered. The arrangementof this atriumcan be classifiedas a fully open atrium due to the open access balconyon each level.ReferFig. 15.4.3.
212
15.4.3.3 Descriptionof EngineeringDesign The atriumvoid smokespillfans are installedat the L6 Plantroom withthe air extraction points locatedabovethe highestoccupiedoffice(L5) level.The extracted air is directedto discharge at theroofopeningsby meansof fire-rated ducts. The smoke spillfans are activatedby any of the followingdevices: (i) Smokedetectors(beamtypes)locatedat L6 and L1 heightsfor detectionof the void area (ii)
Smoke detectorslocated at each office level balcony ceiling
(iii)
Smokedetectorsservingunenclosedpublic/commonareas of the Groundand LG1 floors
(iv)
Smoke detectorslocatedat the returnair intakeof the atriumair handlingunits.
(v)
Sprinklerflow switch serving the atrium balcony floors
(vi)
Remotemanualcontrolsat the Main Fire Controlpanel
15.4.3.4Calculation and Assumptions (a) Basedon Clause 15.3.7.1(i) (c) for steriletube Atriumtype (for comparisonpurposesonty). (i) Heightof atrium = 34.475m (ii) Volumeof atrium= LG1:1125m2x 4.025m = GF: 1300m2x 6.3 m = L1 to L5: 919 m2x 4.025m x 5 = L6 void: 919 m2x 4.025m
= 4528 m3 = 8 1 9 0m 3 = 18495m3
=___3699_rn1 34,914m3
Smoke extractionrate at 4 ACH = 39 m3/s (b)
Basedon Designof "SmokeManagementSystems"publishedby ASHRAE and SFpE. The worst case scenariois for a fire located in the centre of the atrium floor with an axisymmetricplume.
213
UsingEquation10.9of the SFPEGuide Zt
= 0.166Eco'1
WhereZ
= limitingheightabovefuel
E
= convectiveheat releaserate of fire = 1.5 MW
E"
= effectiveheat releaserate of fire = 0.7 x 1.5 MW
ThereforeZ = 0.166(0.7x 1500)o'1 = 2.68m Sincethe limitingheightis less than the clear smokeheightot 29.43m, the latteris used for calculation. subsequent UsingEquation10.8of the SFPEguide m
= 0.071Eclr:Zs + 0.0018Ec
where m
= massrate of smokeproduction
Z
= heightfromtop of fuel surfaceto bottomof smokelayer
Thereforem = 0.071(0.7x 1500)1/329.43vs + 0.0018x 0.7 x 1500 = 2O4.25kg/s AppfyingEquation1O.12ot the Guide =Cm V e whereV
= Volumetricsmokeproductionrate
C
= entrainmentconstiant= 1
e
= densityof plumegas = 1.2 kg/m3
ThereforeV = 1 x2M.25= 170.2m3/s 1.2 15.4.3.5DceignSpecification in thisinstance,as the said Clause15.3.7(i) (c) is clearlyinadequate Fromthe abovecatculations, 4 ACH methodappliesto steriletube Atriumtype only. method Hence,usingthe ASHRAE/SFPE (i) Calculatedsmokeextractionrate = 170.2m3/s Specifiedsmokespillfans 24 nos.each7.1 m3/s = 170.4m3/s
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(ii)
Freshair intakefrom and 1B (a) LG1lowlevelsuppliedby AHU/L6/1A opened) (b) GroundfloorMainentrancedoors(automatically
(iii)
check: Plugholing Vcnr =2(gxdsx0xTo)o's Tc
MinNo.of extractpoints= V Vcrit
Where d = Centrelineof extractto smokelayerbase of smokelayeraboveambient("C) 0 = Temperature = (K) To Ambienttemperature = To + 0 Tc = Smoketemperature g = 9.81m2ls 15.4.4Exampleof SmokeControl Systemfor a Warehouse '15.4.4.1 Descriptionof Building openedroofventilators. withoutjackroofor permanently warehouse A singlestoreyairconditioned is fullysprinklered. Warehouse 15.4.4.2DesignConsideration Consultants FireResearch issuedby Warrington Thesmokecontroldesignadoptsthe guidelines (WFRC).Figure15.4.4showsthe variouscriticaldimensions. 15.4.4.3DesignCalculation = 200m L x 20 m W x 15 m H. dimension Warehouse Floorarea
= 4000m2
(Clause15.2.4). the maximumsize= 2,000m2 smokereservoir, Fornaturalventilated or dropdowntype) a smokecurtain(eitherpermanent Hence,thewarehouseneedsto incorporate to dividethe smokereservoirinto2 zonesof 2,000m2each. of fire(Clause15.3.8) Firesizeshallbe,Q = 10 MW heatoutputand P = 1Bmperimeter heightto lifesafetydesign Minimumsmokeclearance y = 3m (Clause15.2.4) Massflowrateof smoke. m = 0.19ey3/2(xg/s) Hencem = 0.19x 18x 3 3/2kg/s= 17.8kg/s of smokelayeraboveambient, Temperature
215
0 , 0 0 0= 5 6 1 . 8 . c 0 " c = Q = 1-T7E-
m
This calculated smoke layer temperatureexceeds 250"C, which is deemed as the highest temperaturesuitablefor safe escape below the smoke layer. However,for a fully sprinklered building, the maximum smoke layer temperature is assumed as 250'C due to the cooling providedby the activatedsprinkler/s.Hence,this calculatedsmoke layertemperatureis meantfor unsprinkleredbuildingconsideration. This worked example will demonstratethe calculationfor both sprinkleredand unsprinklered applicationfor comparisonpurposes. For unsprinkleredbuilding,to limit the smoke layer temperatureto 250'C maximum,then if the ambienttemperatureis 33"C, the temperaturerise shouldnot exceed250"C - 33'C = 217"C. Next,allowfor the buildingstructureto absorb up to one thirdof the energyof the fire,then
- ZI_ :C =3 2 3 .9 " C 0 .6 7 Theny =n O )lr" e
I o . t s x e x o1 r , .
= ll 1o,ooo ;lzs [oTsxrBx323qlz,a = 4 . 3 3m andm
=0.19xPxy3r2 = 30.8kg/s
Smoketemperature, = To (Ambient +g Tc temperature) = (273+ 33 + 250)K = 556Kfor sprinklered warehouse or = (273+ 33 + 323.9)K = 629.9Kfor unsprinklered warehouse Smokevolume,V m3/s =mxTc 354.5 = 17.8x 556 = 27.9 m3/sfor sprinklered warehouse 354.5 = 30.8x 629.9 = 54.7mr/sfor unsprinklered warehouse 354.5 Vent Area (wherevent area (Av) = inletarea (Ai) is derivedfrom: ffy = mT os (2BB+ T)o.smz 54(Oe;os WhereT=288+0 d = distancebetweencentreline of vent and base of smoke layer
216
0'5 05 = 4.01 m2of ventilationper smokezone ThereforeAv = 17.8 x 538 (826) m2 for sprinkleredwarehouse 54 11t+s1 2501o's or 05 zone per Av = 30.8x 611.905 899.9 m2 =7.2 m2of ventilation smoke o s warehouse for unsprinklered 141i154331 32ag if the maximum size of the Note that for powered smoke extractionsystem in this example' for both zones shall be activated smoke reservoirzone is not preferred,then smoke spill fans and all fans shall be under emergencypowersupply' simultaneously
15.5 TESTING AND COMMISSIONING PROCEDURES 15.5.1 with temperaturesproduced Smoke Controlsystemsare designedfor use duringa fire condition conditions'Therefore'the use of by the fire that are significantlyhigherthan ambienttemperature control system as designed' smoke the of cold smoke tests ooJs not reflectlhe efficientoperation by the smoke extract induced potentially What it will do, is to show the airflow patternsthat will be "cold shoppingcentres states equipment.BR 186-Designprinciplesfor smokecontrolin enclosed smoke ventilationsystems. Whilst smoke tests are sometimesused for the acceptancetesting of and therefore activate allthe this cold smoke can be used to operate the smoke detectionsystem that sincethe smoke itselfis cold it componentsof the smokeventilationsystem,it shouldbe noted would have, and cannottherefore would not have the buoyancythat smoke in a true fire condition adequatelytest the ventilationefficiencyof the system"' 'foggingmachine'at floor producedby a This is particularlyrelevantin high buildingswhere smoke pointof extraction' level,has very littletemperaturein itselfto rise quicklyto the low levelexhaust(eg. carparks) Designutilisingthe techniqueof smoke dilutionand incorporating such test, the smoke spill During can be adequatelytested with cold smoke (foggingmachine). visibilityshouldbe maintainedfor fan/s shouldbe allowedto activateunder its automaticmode and evacuationPUrposesat alltimes. and efficiencyof the equipment There have been realfire tests usingfull sizefires to assessthe effect be limitedto projectsof high should necessary, and parametresfor design. However,such tests, if analysis is Dynamics/Modulation Fluid complexity.Verificationusing establishedcomputational also applicablefor such projects. thereforebe able to show that the The designerand installer(who may be differentpeople),must whilst the equipmentalso conformsto design follows acceptedand publisheddesign principles, equipment'ln this way there can the test and certificationproceduresrequiredfor smoke control and in the equipmentto meet be confidencein the abilityof the design to meet the requirements the design. '15.5.2 signaling receiptof the aPProPriate The systemshouldbe testedthoroughlyand the activationon is required.The abilitYof the device (from whicheverdetectionmethod chosen and approved) systemio fail safe to the designpositionshouldalso be checked.
15.5.3 sequenceand and operational The MainFireAlarmPanelshouldprovidethe correctinformation withotheralliedsystemsshouldbe checked' the interfaces
217
15.5.4 and this informationalso Alltest data must be recordedand witnessedby the client'srepresentative loggedin the O & M Manual.A full set of as-builtdrawings,systemsequencecontrol,schematic and servicingdata must also be part of the O & M manual. 15.5.5Example of Testing & Commissioning Record Sheet FunctionTest for Smoke ControlSystem ProjectTitle:.......... Owner: Consultant: Contractor: A.
(Firemodesimulatedon this Floor) Floor:................ Requirement
Item Description 1.
Units Air Handling
Run
2.
ReturnAir DamPer
Close
3.
SmokeSpillDamper
Open
4.
FreshAir Damper
Open
B.
to Flooraboveand belowFireFloori.e. .....................
Tick if Comply
Requirement Tick if Comply
Item Description 1.
Units Air Handling
Run
2.
ReturnAir Damper
Close
3.
SmokeSpillDamper
Close
4.
FreshAir Damper
Open
C. 1.
after5 minutes GeneralFireAlarmactivated Trip AHU'son all Floorsexcept- and-.
2.
SmokeSpillDamperson all Floorsexcept-
Close
powersupply NOTE:Testwithbothnormalandemergency Testcarriedout by: Witnessedby:
Approvedby: D a t e .: . . . . . . . .
218
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219
Figure 15.4.2Office Floor Smoke Control
OFFICESPACE
AHU ROOM
AIR RISERS FRESH AIR
NOTE: 1 ) U N D E RF I R EM O D E , OTHERAHU'S SHALLTRIPAND MSD'SAND MFD CLOSED
AIR-COND SUPPLYAIR
f +
+ +
_____l__--_L-----.r
+ +
LEGEND: MSD - MOTORSED SMOKEDAMPER MFD - MOTORSEDFIRE DAMPER FA- FRESHAIR
?777V777,- FIRERATEDDUCT
MODE 1. NORMALAIR-CONDITIONING OFFICESPACE
AHU ROOM
AIRRISERS FRESH AIR
50 TO REPLACEMENTAIR OR SMOKE EXTRACT
+
+
+
____1____J-____1 2. F|REMODE (THISFLOORON FIRE) AIR PURGINGSYSTEM THIS SMOKESPILLSYSTEMCAN DOOBLEUP AS 1OO% AIR RISERS AHU ROOM OFFICESPACE FRESH AIR
+VE
50 TO REPLACEMENTAIR OR SMOKE EXTMCT
+ + + L____1____ ____J____
3. FIREMODE( FLOORNOT FIREBUT lS ONE FLOORABOVEOR BELOWFIREFLOOR)
220
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16.1DESCRIPTION In a buildingwhere the topmostoccupied floor is over 18.5 metres above fire appliance access level'fire lifusshallbe provided.A penihouse occupyingnot more than 50% of the area of the ftoor immediatelybelowshall be exemptedfrom this measurement.
!fi:rffiJean
liftscapableof beingcommandeered for excrusive use by firemenduringan
16.2DESIGNREQUIREMENTS 16.2.1Design Standards
;ffi il]il'.f,[H|,',]lT (i) (ii) (iii) (iv) (v)
desisned andinstalled rorverticattransportation orriremen inaccordance
UniformBuildingBy_taws 1984 Factories and Machinery Regulation 1967 Occupationat SafetyanOtteattnAct 1994 BS 265s Otheracceptable Standards
Buirdingrayoutpranindicating the rocationof fire riftssharlbe submitted to FRDM and DOSH. Malaysiafor approvaland/orrecord. 16.2.2Location of Fire Lifts Fire lifts shall be located at not more than 61 metres traver distancefrom the furthermost point of the floor' The fire lifts shall also be located not more than 61 metres travel distance from the main entranceof the buildingon the designated floor or the fire controlroom whicheveris nearer. A fire lift shall be locatedwithin a separatelyprotected shaft if it opens into a separate tobbv. 16.2.3Number of Fire Lifts Fire lifts shall be provided at the rate of one.lift in every group of lifts that discharge into the same protectedencrosureor smoke robby containingthe rising;mar;s. 16.2.4Number of Ftoors to be Served Fire lifts sha, serve at floors incruding the topmost occupied 16.2.5 Lift Weil/Shaft Fire lifts shall be located in protected lift shafts
froor.
of at least 2 hours fire resistanceprotection (FRp).
No piping' conduit or equipment other than that forming part of the lift or necessaryfor its maintenanceshail be instailedin any rift shaft or riftshaft encrosure. 16.2.6Landing Doors Landingdoors shall have a FRP of not less than half of the FRp of the lift shaft structurewith a minimumFRp of halfan hour.
No glass shall be used for landingdoors exceptfor vision in which case any vision panel shall be glazedwith wired safetyglass,and shall not be more than 0.0161m2and the total area of one or morevisionpanelsin any landingdoorshallbe not morethan0.0156m2.Eachclearpanelopening shall rejecta sphere 150mmin diameter. Provisionshall be made for the opening of all landing doors by means of an emergencykey irrespectiveof the positionof the lift car. 16.2.7Wiring and Gabling All wiringand cablingfor fire liftsshallbe of fire resistingcables,routedalongareasof leastfire risk. The cablesshall be sizedto continuouslycarry currentrequiredby the equipmentit is supplyingto withoutfailure. 16.2.8Other Requirementsfor Fire Lifts Lift Speedshall be such that it will run its full traveldistancein not more than 1 minute. Lift Lobbywidth shall be as a minimumtwice the car depth. Lift lobbyshall have a floor areaof not less than 5.57m2. Fire lifts shall have an effectiveplatformarea not less than 1.45m2and be capableof carryinga load not lessthan 550k9.The liftsshall have poweroperateddoorsgivinga minimumclearopening width of 800mm. 16.2.9Fire Lift Switch A fire lift switchshallbe installedadjacentto the lift openingat fire controllevel.The switchshall be of the type that does not require a key for operation. 16.2.10lllumination Approved self containedemergency light shall be provided in fire lifts. Such emergency light shall be activatedwhen there is a power failure.The emergencylight shall be of the following specifications: (i) (ii) (iii)
B watt fluorescenttube, providea minimumof 3 hoursof emergencylightingafter12 hoursof recharging, approvedby FRDM and EC (EnergyCommission)
16.2.11Fire Mode Operation The fire mode operationshall be initiatedby a signal from the fire alarm panel which may be activatedautomaticallyby one of the alarm devicesin the buildingor activatedmanually. lf mains power is available,all lifts shall return in sequence directlyto the main access floor, commencingwith the fire lifts,without answeringany car or landingcalls and at the same time overridingthe emergencystop buttoninsidethe car, but not any otheremergencyor safetydevices, and park with doorsfully open. All landingcall pointsand controlswitchesshall be renderedinoperativeand sole controlvestedin the car controlstationensuringthat any collectivecontrolbecomesinoperative. All fire liftsshall be availablefor use by the fire brigadeon operationof the fire lift switch. Underthis mode of operation,the fire liftsshall only operatein responseto car callsbut not to landingcalls. 'Fire at the liftconsole. A sign indicating Mode'operation shallbe illuminated
225
16.2.12Emergency Power Supply Mode with and without Fire Mode Operation On failure of mains power, all lifts shall return in sequence directly to the designatedfloor, commencingwith the fire lifts, without answeringany car or landing calls and park with doors open. After all liftsare parked,the liftsconnectedto emergencypowershall resumenormaloperation. Providedthat where sufficientemergencypower is availablefor operationof all lifts,this mode of operationneed not apply. ln the event of fire mode operationunder mains power supplyfailure,there shall be emergency power supplyprovidedto all the lifts,to operatethe fire liftscontinuouslyand to bring all the other lifts to park at the designatedfloors. When liftsare operatedunderthe'Mains Power FailureMode'a sign indicatingthis mode shall be illuminatedat the lift console.
16.3TESTINGREQUIREMENTS The system shall be tested for but not limited to the following: (i) (ii)
Full system performancetest under power failure and fire mode. The test shall be recordedin the test form attached.
16.4 MAINTENANCE REQUIREMENTS 16.4.1 lnspection AndTesting The system performanceunder power failure and fire mode should be tested half yearly.A log book of the testingactivitiesshall be maintainedin the motorroom for inspectionby FRDM.
16.5 DESIGNCHECKLIST UniformBuildingBy-laws1984 Requirements of DOSH BS 2655 FireLiftrequirement shallfulfillthefollowing conditions; a.
ln a buildingwherethetopmostoccupiedflooris over18.5metresabove fireappliance accesslevelfireliftsshallbe provided. A penthouse occupying notmorethan50%of the areaof thefloorimmediately belowshallbe exempted fromthismeasurement.
O
b.
Fire lift is locatednot more than 61 metresfrom the buildingmain entrance or the fire control room whicheveris nearer.
A
c.
Fire lift is located not more than 61 metres travel distancefrom the furthermost pointof the floor.
O
226
d.
Thereis a fire lift allocatedin everygroupof liftsthatdischargeintothe the risingmains. sameprotectedenclosureor smokelobbycontaining
El
e.
Fireliftsserveallfloors
B
f.
Fire lift is locatedwithina separatelyprotectedshaftif it opensintoa separatelobby. D
g.
Cable& wiringmaterial:
h.
Fireliftcar platformareais
i.
Widthof fire lift lobbyis -
k.
Firelift dooris of an openingwidthof
l.
Fire lift switchis locatedat
m.
is provided Emergencylllumination
sq. metres timesthe depthof cardepth.
16.6 TESTINGAND COilIMISSIONINGCHECKLIST PerformanceTestfor PowerFailureand Fire Mode- SampleRecordSheet ProjectTitle:
Project Location: Owner: Consultant: Gontractor: Lift Manufacturer: Lifi ldentification No: Item Description 1.
FireMode Operation UnderMains PowerSupply Situation
Tick if Comply
Requirement All liftsretumin sequencedirectly floor,commencing to the designated answering lifts, without withthe fire any car or landingcalls,overriding the emergencystopbuttoninsidethe car and ParkwithdoorsoPen.
D
Fire liftsoperatein responseto fire lift switchoperation.
B
227
2.
3.
Fire Mode Operation Under Standby Power Supply Situation
Fire Lift Switch
All lifts return in sequencedirecfly to the designatedfloor,commencing with the fire lifts,without answering any car or landingcalls,overriding the emergencystop buttoninsidethe car and park with doors open.
o
Fire lifts operate in responseto fire lift switchoperation.
a
On operationof the fire lift switch, the fire lift is operationalunderfire mode operation
D
Test carried out by:
Date:
Witnessedby:
Date:
Approved by:
Date:
228
1 7 . 1D ES C R IP T ION An emergencypowersystemshallbe providedto supplyelectricalpowerautomatically in the event of failureof the normalsupplyto equipmentessentialfor safetyto life. The supplysystemfor emergencypurposesshall comprisea generatorset drivenby prime mover and of sufficientcapacityto supply circuits carryingemergency loads with suitable means for automaticstartingof the primemoveron failureof the normalservice. A typicalemergencypowersysteminstallationis as shown in Fig. 17.1
1 7 . 2D ES IGNR E QU IR E ME N TS 17.2.1Design Standards The installationshall be designedand installedfor supplyingof electricalpower in case of mains power failure in accordancewith the latest editionof: UniformBuildingBy-laws1984 ElectricityRegulation Requirementof the EnergyCommission Emergencypowersystemshallprovidepowerfor the followingemergencyloadsthat are associated with fire protectionsystem: pressurisation (i) system (ii) smoke controland managementsystem (iii) fire alarm and monitoringsystem pumpsetsfor fire fighting (iv) (v) emergencypublicaddresssystem (vi) fire lifts (vii) emergencylighting (viii) other emergencyfire systems The main schematicdrawingshall be submittedfor FRDM approvaland/orrecord. 17.2.2Standby Generator Set The generator shall provide adequate capacity and rating for the emergency operationof all equipmentconnectedto the systemincludingsimultaneousoperationof all fire lifts. The engine of the generatorshall be capable of meeting all the specifiedrequirementswhile operatingon 'ClassA'fuel to BS 2869. In the event of failure of normal power supply to or within the building or group of buildings concerned,100% of the emergencypowershall be availablewithin 30 secondsof interruptionol the normalsupply. When normalsupplyis restored,the generatorshallcontinueto run for not less than 3 minutes. 17.2.3Automatic Mains Failure Board (AMF Board) An automatic mains failure board (AMF board) shall be provided to control and monitor the generator. This AMF board shall be locatedwithin the same compartmentas the generatorset The AMF board shall includethe followinofeatures:
230
(i) (ii) (iii) (iv) (v) (vi) (vii) (viii) (ix) (x)
faultalarmbell batterychargingstatus emergencystopbutton generatorstarUstopindication temperaturetripindication/alarm oil pressure tripindication/alarm overspeedtripindication/alarm lowfuellevelindication/alarm extralowfuel levelalarm/alarm failto startindication/alarm
Underany circumstance shouldthe generator fail to start,a signalshallbe sentto the mainfire consoleindicatingsuchan event. 17.2.4FuelTank A fuel tankwith cover-platehavinga minimumcapacitysufficientfor 4 hourscontinuousduty for emergency useshallbe provided. Thisfueltankshallbe locatedwithinthe samecompartment as the generatorset. A kerbof notlessthan100mmheightand '100mm widthshallbe constructed continuously around the fuettankto containthe full volumeof fuel shouldtherebe a tankleakage. 17.2.5Wiring& Cabling All wiringand cablingfor emergencysystemsshallbe in metalconduitor of fire resistingcables, routedalongareasof leastfire risk.Thecablesshallbe sizedto continuouslycarrypowerrequired by the equipment it is supplyingwithoutfailurein thecaseof normalserviceinterruption. Thecables shallbe sizedin accordance with BS 7671-Requirements for Electricallnstallation: IEE Wiring Regulations. 17.2.6Batteryand Gharger A storagebatterywitha chargershallbe providedwithsufficientcapacityto providesix successive abortivestartsof the enginewithoutrecharging, comprising 15 secondscrankingand 15 seconds rest betweeneachcycle.The batteryand chargershallbe locatedwithinthe samecompartment as the generatorset. The batterychargershall be of constantchargingtype and shall be suitablefor continuous operationat full ratedloadoutputwithoutthetemperature riseof thetransformer chokeor anyother componentexceeding55'C. The batterychargershallbe sizedsuchthat the batteriescan be fully chargedwithin18 hoursof charging. 17.2.7TotalGas FloodingSystem TotalGas FloodingSystem(suchas CarbonDioxide)whereprovidedfor the generatorroomshall be configured suchthat in the casewhenthe generatorroomis on fireor the gas (suchas carbon dioxide)is discharged, a signalshallbe fed to the generator fromthe TotalGas FloodingSystem controlpaneltostopthegenerator. 17.3 TESTINGREQUIREMENTS Thesystemshallbe testedfor (butnotlimitedto)thefoilowing: ' Batteryperformance testfor six successive abortivegeneratorstarting . Fullsystemperformance test underpowerfailureand fire mode Thetestshallbe recordedin theformatas perFormt herein.
231
17.4 MAINTENANCEREQUIREMENTS 17.4.1lnspectionand Testing Thecoolant,battery,batterycharger, fuelsupply,automatic change-over deviceandgenerator set shouldbe inspected at leastmonthly. The generator set shouldbe testedregularly on testmodewithandwithoutload,to ensureit can be runup and provideemergency powerwhenthe needarises. A log bookof the inspection and testingactivitiesshallbe maintained in the generatorroomfor inspection by FRDM.
1 7 . 5D E S I G NC H E C K L I S T Emergencypower system is requiredbased upon the following: . Fire lifUs,if installed . Pressurisationand/or Smoke Control System, if installed ' Electricfire pumpsets,if installedfor fire fighting systems(i.e.hydrant,hose reel,sprinkler and wet riser) . Other life supportsystems,if installed,and as requiredby FRDM b.
The capacityof generatoris . . . . . .
KVA
load sheddingschemeis designed load sheddingschematicsubmitted main schematicsubmitted generatorcapacitycalculationsubmitted (Form 2) load sheddingschemeis acceptable generatorcapacityis acceptablebased on the calculation
o o D D
tr D
The followingfeatures are provided: . . . . . . . . . . . . . , d . e.
automaticchange over device fault alarm bell alarm indicationlights battery chargingstatus emergencystop button generatorstarUstopindication temperaturetrip indication oil pressuretrip indication over speedtrip indication low fuel levelindication extra low fuel level alarm/alarm fail to start indication/alarm indicationat main fire alarm panel
a o o a o a D
o E
e a tr
Fuel tank capacitysufficientto run engineat full load for Cable & wiringmaterial:
232
hours.
17.6VISUALINSPECTION CHECKLIST 17.6.1Visual Inspection of Standby Generator Set Generatorset is locatedwithina fire ratedcompartment 17.6.2Visual Inspection of Automatic Mains Failure Board The followingfeatures are provided: . automaticchangeover device . fault alarm bell . alarm indicationlights . batterychargingstatus . emergencystop button . generatorstarUstopindication . temperaturetrip indication . oil pressuretrip indication . over speed trip indication . low fuel level indication . extra low fuel level alarm/alarm . failto start indication/alarm . indicationat main fire alarm panel
e o a tr a a D
tr tr o tr a D
17.6.3Visual Inspection of Fuel Tank ' Fuel tank is locatedwithinthe same compartment as the generatorset . The volumeof the tank is mm x mm x _ mm . Fueltank is toppedup to the;equired level ' Min. 100mmx 100mmcontinuouskerb aroundthe fueltank is provided
o a a o
17.6.4Visual Inspection of Wiring & Cabting ' cable materialis eitherfire resistingtype or in metalconduits . Cableis installedin accordanceto relevant code of practice . Cables is terminatedin accordancewith code of practice
a o o
17.6.5Visual Inspection of Battery Charger AH volts (DC or AC) . Charger setting is acceptable
o o a
. Batterycapacityis . Batteryvoltageis
17.7TESTINGAND COMMISSIONING CHECKLIST Form 1: PerformanceTest for Power Failure and Fire Mode - Sample Record Sheet Project Title: Project Location: Owner: Consultant:
233
Contractor: GeneratorManufacturer: AlternatorEngine Model& SerialNo: by shuttingdownpowersupplyat the intake Test SimulationGondition:Powerfailuresimulated point.At the sametimea fire modeshallbe simulated (in orderof preference) by eithersprinkler activated alarmor heator smokedetector activated alarmor manualbreakglassactivated alarmor others. Item Description
Requirement
Tick if Comply
1.
GeneratorStarting and ChangeOver Time
100% load in less than 30 seconds
0
2.
The generator started withoutany interruption?
Yes
fl
3.
Lift Homingunder gensetmode (whereapplicable)
- All lifts homed to main accessfloor and doors remainfully open.
tr
- Fire lifts homed to main access floor and doors remainopen.
A
- Fire lifts becomeoperationalwhenfire lift switch is activated.
O
4.
- All affectedPressurisation Pressurisation and and Smoke Control System Smoke Control System activated. (whereapplicable)
5.
Fire pumpsets (where applicable)
6.
PublicAddressSystem - Able to performpublicpagingclearly. (whereapplicable)
7.
Emergencylights
- llluminated
o
B.
Fire ControlConsole
- Remainoperationalwithout disruption
D
9.
Air-conditioning System
- Shut down (wheredesignated)on fire mode operation
D
10.
Load Shedding (whereapplicable)
- Able to load shed certainessential (but non emergency)loadssupplied by generatorset underfire mode operation(if the schemeis designed)
o
- All affected fire pumpsetsactivatedand performingto requirements.
234
o
a a
11.
Total Flooding (CarbonDioxide) System
- The generatorset stops upon alarm from the Total Gas Floodingsystem controlpanelfor the generatorroom
e
12.
Batteryperformance test
- Able to providesix successiveabortive generatorstartingand generatorstarted on the seventhstart
o
Testcarriedout by:
Date:
Witnessedby:
Date:
Approvedby:
Date:
Form2: GeneratorSizingForm TableI TotalConnectedLoad Of EmergencySystem ItemNo. 1 2 3 4 5 6 7 8 I 10 11
SystemDescription
Total ConnectedLoad At 0.85 Lagging p.f.
Pressurisation System SmokeControlSystem FireAlarmAnd MonitoringSystem SprinklerSystem HoseReelSystem Wet RiserSfstem, HydrantSystem PublicAddressSystem Fire Lift kVA OtherLifts*(referto note 1) OtherLife SupportSystems(to list)
KVA KVA KVA KVA KVA KVA KVA KVA KVA KVA
a) b) c)
KVA KVA KVA
Total ConnectedLoad of EmergencySystem (Totalsum of items 1 to 11)
kvA
*Note 1: Connected load of non-firelifts (numberof lifts as per lift homingrequirement),if the nonfire lifts depend on the generatorfor homingduring normal power outage.Otherwise these need not to be included.
235
Table2 Loadof Essential(but Non Emergency)System
Item,No. 1 2 3
'4
SystemDescription
TotalGonnected LoadAt 0.85Laggingp.f.
lllumination Escalators Travellators OtherEssentialSystems(to list) a) b) c)
KVA KVA KVA KVA
TotalConnectedLoad of EssentialSystem (Totaisum of itenrs t to 4)
KVA
MaximumDemandof Essentialsystem at a diversity factor of _ '
kvA
Table 3 Load of Essential System Shed off During Fire Mode Operation
ItemNo.
SystemDescription
TotafConneptedLoadAt 0.85 Laggingp.f.
1
KVA KVA
b)
KVA .KVA
c)
KVA tlaximum Demandof Essential System at a diversity factor of
kvA
Generator Capacity Sizing The followingshall be the minimumtotal generatorcapacityat a powerfactorof 0.85 lagging: (i)
for installationwhere no load sheddingis designed The GeneratorCapacity= TotalConnectedLoadof EmergencySystem(Table1) + Maximum Demandof EssentialSystem(Table2)
(ii)
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1 8 . 1C ON C E P T The Fire Engineering- PerformanceBased Approach (FE-PBA) is a methodologyfor design, evaluationand assessmentoffice safety in buildings.lt identifies an engineeringapproach to buildingfire safety,and gives guidanceon the applicationof scientific and engineeringprinciples, to the protectionof people and propertyfrom unwantedfire. Additionally, it ouilin"s a structured approach,to assessmentof total buildinqfire safetysystemeffectiveness, and to the achievement of pre-identified designobjectives The methodologyfacilitatesperformance-based design that meets the fire safety objectivesof Building Codes. Many factors, including a building'sform of construction,,""n, of escape, occupancyfactors,smoke management,detection,alarmand fire suppression facilities,contribute to the achievementof fire-safetyobjectives.The guidelinesof Fire Engineering- performance Based Approach,are based on the premisethat all these measures, form part of an integrated fire safetysystemfor the building,which must respondto any fire developingwithin that building. consequently,it is requiredthat designersrecognisethe interactions betweenelementsof a fire safetysystemand that they developcompleteand integrateddesign solutions. The basicprinciplesof Fire Engineering- PerformanceBased Approachmay be appliedto speci1c types of buildingsand their uses. However,the principleand the guidelines developeddo NoT cover buildingswhich are used for bulk storage or processing of flammable liquids, industrial chemicalsor explosivematerials.The intrinsicrisksassociatedwith such buildingswillnecessitate specialconsiderationand is beyondthe scopeof this chapter. The Fire Engineering- PerformanceBased Approachconcept is intendedfor applicationduring the conceptualphaseof buildingfire safetysystemdesign,prior to the detaildesign,specification and documentationphase of selected fire-safetysub-syst,ems(or elements).Fire Engineering procedures require early consultationand co-operation between the project manager, Architect and other membersof the designteam, togetherwith the Fire and RescueDepartmentMalaysia. The detaileddesignand specificationof fire-safetysub-systems(which will followagreementof the conceptualdesign)may not be specificduringthis stage.But it is imperativethat when executed, these strictlyadhereto the decisionsand agreementsreachedduring the conceptualphase.
18.2 DESIGNREQUIREMENTS 18.2.1Codes and Standards (i) Fire SafetyEngineeringGuidelinepublishedby the AustralianBuilding CodesBoard(ABCB) (ii) Bs 7974: Applicationof Fire SafetyEngineeringPrincipteto the Designof Building- Code of Practice
1 8 . 3F I R ES A F E T YE N GIN E E R EQUIREM ENTS The Fire Engineering- PerformanceBased Approach study should only be carried out by e qualified,and experienceand accreditedFire Safety Engineer(FSE) whln acting as part of e designteam' This will permitachievementof the requisitelevel of fire safetyfor a buildingwithou imposingunnecessaryconstraintson otheraspectsof its design. The qualificationand capabilityof a FSE should be accredited by an appropriateprofessiona institutionor by FRDM' The criteriaof an appropriateFire safety Engineershall be a person,whc by educationtrainingand experienceis:
240
(i)
familiarwith the natureand characteristics of fire and associatedproductsof combustion.
(ii)
one who has understanding of how fires originate,spreadwithinand outsidebuildinqs/ structures,and/orextinguished
(iii)
ableto anticipate the behaviour of materials, structures equipmentand processesretatedto the protectionof life and propertyfrom fire.
(iv)
able to use appropriatequantitative fire engineeringmethodology as well as understanding all the techniquesutilisedin respectto assumptions,limitationsand uncertainties.
(v)
awareof mattersof fire safetymanagement,includingthe role of fire preventionand the risks to buildingfire-safetyassociatedwith construction,installation, operationand maintenance.
(vi)
familiarwith relevantBuildingCodes,Standards,Codesof Practice,legislation,etc.
(vii)
is registeredwith the Boardof Engineers,Malaysiaas a ProfessionalEngineeror Boardof Architects,Malaysiaas a ProfessionalArchitect.
- PERFORMANCE 18.4SCOPEOF FIREENGINEERING BASEDAPPROACH The applicationof FE-PBAshall be restrictedas follows: (i) NormalBuildingCategory(referto UBBLT1984 Tenth Schedute). - ShallfollowUBBL 1984requirements eg. schools,shop houses,factories (ii)
High Rise BuildingCategory - ShallfollowUBBL 1984requirement - FE-PBAshallbe appliedonly to specificarealspacesnot coveredby UBBL 1984 eg. Kuala LumpurCity Centre,MenaraKuala Lumpur
(iii)
Mega Projectand SpeciatUse - FE-PBAmay be apptied eg. Kuala LumpurInternational Airport
. PERFORMANCE 1 8 . 5E X C L U S ION OF F IR EE N GINEERING BASEDAPPROAC H APPLICATION The followingtype of buildingsshall be excluded from the applicationof Fire EngineeringPerformanceBased Approach: (i)
Buildingsused for bulk storage
(ii)
Buildingsused for processingof : (a) flammableliquids (b) industrialchemicals, (c) explosivematerials.
The intrinsicrisks associatedwith such buildingswill necessitatespecial considerationand is beyondthe scopeof this study.
241
- PERFORMANCE 18.6FIREENGINEERING BASED(FEPB)REPORT The format of the FEPB Report may depend on the nature and scope of the Fire EngineeringPerformanceBasedstudy and shall containthe followinginformation: (i) Objectiveof the Study (ii)
Descriptionof the buildingand type of occupancy
(iii)
Membersof the DesignTeam
(iv)
Resultsof the designoverview (a) Fire safety objectives (b) Resultsof hazardidentification (c) Basis for selectingfire scenariosfor analysis (d) Acceptancecriteria (e) Trial conceptdesign (f) Redundanciesbetweenand within sub-systems (g) Influenceof Fire Safety Management
(v)
Analysisof Results (a) Assumptions (b) Engineeringjudgement (c) Calculationprocedures (d) Validationof methodotogies (e) Sensitivityanalysis (0 Evaluationof the resultsof the analysisagainstthe acceptancecriteria
(vi)
FinalConceptualDesign& Conclusion (a) Fire Protectionmeasuresrequired (b) AppliedManagementissuewhich is integralto the design
(vii)
Reference (a) Drawings (b) Designdocumentation (c) Technicalliterature
Based on the contents of FEPB Report, it is desirable that the main body of text provides an overviewof the study The calculations,computeroutputs,detailedanalysisand other documents shouldbe includedin the appendices. It is also important that the FEPB Report draws a clear distinctionbetween life safety, property protectionand environmental protection,so that the buildingowner,managerand Fire and Rescue DepartmentMalaysiaclearlyunderstandthe purposeof the proposedmeasures.
18.7APPROVAL Fire Engineeringis a developingdisciplineand some of the judgementneededmay be subjective. ' Therefore,the Fire and RescueDepartment Malaysiamust be consultedfor priorapprovalof the overall conceptbeforefinal parametersand assumptionsare laid down for the Fire Engineering designusing PerformanceBasedApproach.
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Fire Engineeringdesign begins with QualitativeDesign Review During the QualitativeDesign Review,the scope and objectivesof the fire safety design shall be defined,performancecriteria establishedand one or more potentialdesignsolutionsproposed. QuantitativeAnalysis shall apply the fundamentalfire science and engineeringmethodology to evaluatethe potentialsolution proposed in the QualitativeDesign Review The Quantitative Analysisshall includethe followingcriteria: (i) (ii) (iii) (iv) (v) (vi)
Fire initiationand developmentwithinthe enclosure Smoke Developmentand Managementwithinand beyondthe enclose Firespreadand managementbeyondthe enclosureof origin Firedetectionsuppression Occupantavoidance Communication and responseby Fire and RescueDepartmentMalaysia
All the results from the quantitativeanalysis shall be compared with the, acceptancecriteria identifiedduringthe QualitativeDesignReview Three types of approachesmay be considered: (i) (ii) (iii)
Deterministic Probabilistic Comparative
The FEPB Reportsshall be certifiedby a FSE for presentationto the DirectorGeneralof the Fire and RescueDepartmentMalaysia
18.8PEERREVIEWER A FEPB Reportshallbe supportedby a Peer ReviewReportconfirmingits findings. The Fire SafetyEngineerpreparingthe Peer ReviewReportshall be independentand shall NOT be engaged by the same Fire Safety Engineerwho is conductingthe FE-PBAor by the project managementteam or by the owner of the said project or anyone who is related to the same project. The Fire Safety Engineerpreparingthe Peer Review Report shall be appointedby the Fire and RescueDepartmentMalaysia,and the cost incurredshall be borne by the owner The Peer Review Report shall be submittedindependentlyto the DirectorGeneralof Fire and RescueDepartmentMalaysiaas a basisof comparisonof the assumptionsand criteriaset forth by the FEPB Report. The requirementsof a Peer Reviewershall be as follows: (i) (ii) (iii) (iv)
in accordancewith the requirementsas stipulatedin section18.3 shall have at least 15 years of relevantworkingexperience shall be currentlyinvolvedin or has accessto researchand developmentactivitiesin the fire engineeringfield shall be an approvedProfessionalEngineeror ProfessionalArchitect
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1 8 . 9D E C tS ION The Decisionof the DirectorGeneralof Fire and Rescue DepartmentMalaysiashall be final in accordanceto UBBL 1984,By-law245.
1 8.1O LEGAL IMPLICATION The applicationof Fire Engineering- PerformanceBased Approach is a complex exercisethat involvespublic safety. Hence, the qualified,competentand experiencedprofessionaladopting Fire Engineering- PerformanceBasedApproachshall be responsibleand accountableshouldthe designdeviatefrom the UBBL 1984 and subsequentlyfail during a fire. For the professionalwho practicesFire Engineering- PerformanceBasedApproach,noticeshall be takenwhereby: (i)
"Judicialnotice" underthe EvidenceAct 1950 is not accordedto the responsiblesubmitting Architectand/orEngineer.
(ii)
Underthe Law of Negligence,generallyif there is professionalnegligence,pursuantto the EvidenceAct '1950,the burdenof provingnegligenceis on the partywho wantsjudgement from the court and the standardof proof is generallyof balanceof probabilities.
(iii)
adoptingthe Fire Engineering-Performance BasedApproach,whereby Shouldthe professional the engineeringdesignis withinthe knowledgeof the designer,then the doctrineof res rpsa Iquidorwill apply wherebythe burdenof provingnegligenceassertedby the plaintiffwill be shiftedto the professionalto provethat he is not negligent.
(iv)
ln normal negligencesuit, the legal burden is on the plaintiffto prove the existenceof negligenceon the part of the professional.
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Two thousand five hundred year ago, a Master military strafegisf said; "in peace prepare for war, in war prepare for peace" - MasterSun Tzu, Art of War, 506 B.C. Similarly in time of normalcy prepare for disaster, in time of disaster prepare for quick return to normalcy.
1 9 . 1I N T ROD U C T ION The submittingperson is requiredto submit the Fire OperationManual (FOM) before Certificate of Fitnessis issuedto a building.The Fire OperationManualessentiallyconsistsof the overallasbuilt Fire ProtectionSystemsand the EmergencyResponsePlan (ERP).In the past the FOM only consistslittle informationon the ERP for the building.Howeverprofessionalsmust now update their knowledgeon ERP. The Fire and RescueDepartmenthave establisheda Malaysianincident CommandStructure(MICS) for the protectionof plants.This standardis based on the National Fire ProtectionAssociation12 - IncidentCommandStructure(lCS)which is widelypractisedby all hazardousindustriesin many developedcountries. The ERP is a detailEmergencyPlanningsystemwhich involveslife safety,evacuation,mitigation, fire fightingand rescue,etc. and will requirea qualifiedand experiencedpersonto draft the plan, taking into considerationvariousaspectssuch as anticipatedstrategiesbased on some logicalor variablescenarioin a particularbuilding,the type of risks (fire risk assessment),and many other factorsdependingon nature,size,occupancy,etc of the building.
1 9 . 2U N I FIE D C OMMA N D A N DC ONTROL The Big Picture ' The incident Command Structurewas developed by a multi-agencytask force after a major wildlandfire which destroyeda large portionof SouthernCalifornia,USA in 1970. ' The ICS is designedas a systemwhich can be usedfrom the initialstagesof any incidentuntilthe situationreturnsto normalcy.lt is also applicableto bothdailysituations(non-emergency) as well as very largeand complexincidents.lt is designedto be used in responseto emergenciescaused by fires, earthquakes,floods, riots, explosionor hazardouschemicalspillsand other naturalor man-madeincidents. ' The structureof the ICS is not restrictiveand operateslikea numberof boxes,whereit can expand or contractdependingon the demand and changingconditionof an incident.However,it should be staffedand operatedby trainedand qualifiedpersonnelfrom any emergencyserviceseg. Fire and RescueDepartmentMalaysia,Police,army, hospital,etc. ' As such,thisstrategicsystemcan be usedfor any typeor sizeor emergencyinvolvingsingleagency to multipleagenciesand from 5 hamburgerto 500,000hamburgerrequirements. ' The ICS establishesproceduresfor controlof personnel,facilities,equipment,communications, commont'erminology and operatingprocedures.lt will also ensurethe timelycombinationof resourcesduringan emergency.
. This systemwill ensuredifferentagenciescouldwork togethertowardsa commonobjectivein an effectiveand systematicmanner.
REQUIREMENTS 19.3THEMAIN"ICS''OPERATION ls an organisational structureof respondingagenciesadaptableto any emergenciesor incidentto whichthe Fire and RescueDepartmentMalaysiawould be expectedto respond.lt must providefor the followingkindsof operations: . Singlejurisdiction/single agencyinvolvement . Singlejurisdictionwith multi-agencyinvolvement . Multijurisdiction/multi-agency involvement It must be applicableand acceptableto users both nationallyand cross boarder operation,if necessary- eg. IndonesiaForestFires,Turkeyand Taiwanearthquakes,etc. It should be easilyand readilyadaptableto new technologyand local conditions- DirectiveNSC No. 20. (ArahanMKN No. 20) ls flexible and able to expand in a logical manner from an initial attach situationinto a major incident. Has a common basic element in organisation,terminologyand procedureswhich will ensure continuationof a total mobilityconcept. shouldhave the leastpossibledisruptionto existingsystems. It's implementation ls effective in fulfillingall the above requirementsand yet be simple enough to ensure low operationaland maintenancecostswhen in use. The ICS has considerableflexibility,where it can grow or shrinkto meet differingneeds.lt is a cost effectiveand efficientmanagementsystem,and can be applied to a wide variety of emergencyand non-emergencysituationssuch as: . . . . . . . . . .
incident Fire and explosions,hazardsin multi-casualty Multijurisdictionand multiagencydisasters(UnifiedCommand) Floodand earthquake Major forest fires Pest eradicationand diseasecontrol Oil spill responseand recoveryincident accident Air, rail,water or groundtransportation parades, concerts celebrations, Plannedeventse.g. Privatesectoremergencymanagementprogrammes State or local major natural hazard management
19.4 ORGANISATION AND OPERATION The ICS organisationfocuses on flve major functionalareas - but it is easily rememberedas "CommandercannotFLOP"which is:
247
Command Finance Logistics Operation Planning Commandis responsiblefor overallmanagementand controlof the incidentsupportedby trained and qualifiedstaff. The commandfunctionin the ICS can be managed by a singlecommand or UnifiedCommand.
INGIDENT GOMMAND SYSTEM
Diagram of lncident Command System
19.5EMERGENCY RESPONSE PLAN An EmergencyResponsePlan (ERP) is a plan for survivalin an emergencyand mitigation and is perhapsthe most importantelementof emergencymanagement.Mitigation is the daily effortto reducethe hazardsand quick recoveryfrom disasterdependson pre-planning. The ERp can help us to preventand preparethe effectsof a disaster.Developmentof an ERp is truly proactive as well as reactiveand also one that is effectiveand practical.lt is usefulto re-emphaiis" ", well as expandupon the five basic principles: ' ProperEmergencyPlanningbeginswith Owners, Operations,and Managersof the Facility involvedin or contributingto a potentialor actualemergency.
248
Communicationplays an especiallyvital role in both the preventionof and the responseto any emergency Lack of co-ordination between emergency servicesand other communitysupport services
Lack of establishedchain of command;lack uniform commandsignals;lack of standardterminology
Failure No standradisation of equipment usedby different responding agencies
Interference withsite operations by crowdsof curiouspublic as wellas standby response personnel
Uncontrolled accessto siteby politicians andmassmedia personnel
Commoncausesof failurein emergencyresponseoperations pranningfor Corporate Emergency Response "* ,,lrf!,'r!; i!!f"?i, On-goingfacilityauditsand practicedrillsare essentialforupdatingand refiningan ERp. There can be no properemergencyresponsewithoutthe existenceof a practised,on site chain of command.
19.6 INDUSTRIAL FACILITY Regardless of thetypeof facility,an ERPfor an industrial facilityshouldcontain(ata minimum) the followingbasiccategoriesof information: . . . . . . . . . . . . . . .
Objectives Responsibility andAuthority Distribution of plan Emergency Equipment andSupplies Locationof Data/ information Assessment of Hazard Generalprocedures Notification procedures EvacuationProcedures procedures Containment SpecialProcedures (e.g.fire,explosion, flood,toxicgas release) Equipment shutdown Returnto NormalOperations TrainingDocumentation lnformational appendices
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19.7BULLETPOINTSIN ERPSTRATEGIES The objectiveof any disasterplan mustbe to ensurethe bestqualitytreatmentof the survivorin an effortto minimisethe risksof mortalitv. In the realevent,successwilldependon priorplanning,thoroughtraining,medicalreinforcement, co-operationwith other agenciesand availabilityof suitablemedicalassetsand transportation. will be fundamentalto successfulcommandand the effective Clearand efficientcommunications co-ordinationof rescue efforts. of a simpleyet flexible A favourableoutcomewill be the resultof the intelligentinterpretation plan that has been rehearsedand frequentlyreviewed. - Managementof Disasterand their aftermath,UK
PEOPLE'SSOCIALAND MANAGING NEEDSAFTER PSYCHOLOGICAL DISASTER Crisis lmmediate post crisis
Pre-crisis
I
Long term post crisis
Shortterm post crisis
Shock LRealisati LAcknowledgement+
Adaptation The time continuumof psychologicalrehabilitation.(From Gibsonwith permission.)
PaulA. Erikson, EmergencyResponsePlanningfor Corporateand MunicipalManager
19.8 CONCLUSTON ERP is a plan for survivaland may determinebetween life and death for emergencyresponse personneland thoseat risk in any emergencydisastermanagementcontrol.The ultimatechallenge to the ERP strategistis the survivaland safetyof those at risk and quick returnto normalcy. Fireman Soh's Experience,Highland Towers Tragedy, 1993
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20.1INTRODUCTION In 1976 the Federal Constitution was amendedand the issue of preventionand extinguishment of fire, includingFire Servicesand Fire Brigadeswere listed in the Federal List. However,the FederalGovernment,alongwith State Governments,have jurisdictionin matterscontainedin the ConcurrentList i.e. mattersin FireSafetyand Fire Precautionin the Constructionand Maintenance of Buildings.Pursuantto Article 74(11of the Federal Constitution, Parliamentmay enact laws on matterslistedin the FederalList or in the ConcurrentList, and bv virtueof this Articlethe Fire Services Act 1988 was enacted.
20.2PREAMBLEOF THEACT The Fire ServicesAct 1988 which appliesthroughoutMalaysiawas enactedforthe effectiveand efficientfunctioningof the Fire Services Departmentand for the protectionof life and propertyfrom fire risks and purposesconnectedthere with. This Act came into force on the 1st of January1989 as publishedin the Gazette PU. (B) 701.
DEPARTMENT OF FIRESERVICES 20.3ESTABLISHMENT The DirectorGeneralof the Fire Services Departmentheads the structureof the Fire Services Departmentpursuantto section 3(2) of the Act. He is currentlyassistedby Deputy Directors Generaland AssistantDirectorsGeneral.Furthermore,by virtueof section 3(3) of the Act there is a Directorof Fire Servicesfor each of the States of Malaysia.lt is to be noted that every Fire Officer shall be subjectedto the controland directionof the DirectorGeneral.Pursuantto section 7 of the Act the DirectorGeneralmay delegatethe exerciseof his power or the performanceof his duties underthe said Act to any Fire Officerin writingvia delegationof power.There is also delegationof power vide authorisationpursuantto sections 38, 40, 41, 43, 44, 50, 52 and 59 of the said Act. Authorisedofficermeans authorisedby the DirectorGeneralin writingto act underthe provisions of the Act. The MalaysianFireServicesstructurealso includesauxiliaryFireOfficerswho may be appointedby the DirectorGeneralwith the concurrenceof the Ministerof Housingand LocalGovernment.These auxiliaryFire Officers are subjectedto the immediatecontrol and directionof the respectiveState Directorand are paid allowances.BesidesauxiliaryFire Officers,the structureof the Fire Services Departmentmay includeprivatefire-brigades,voluntaryfire-brigadesand cadetfire-brigades.
OF THE FIRESERVICES 20.4DUTIESAND RESPONSIBILITIES of the Fire Servicesare providedfor in section 5 of the Act whict The dutiesand responsibilities includes: Takingof lawfulmeasurefor: fighting,preventionand controllingfires. extinguishing, Protectinglife and propertyin the event of a fire. The makingof investigation into the cause,originand circumstanceof fire.
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. The Ministermay directthe Departmentto performsuch other dutiesin additionto the above or imposedby law.
20.5FIREHAZARD 'Fire 'Fire The definitionof Hazard'shall be read togetherwith FightingEquipmentor Fire Safety installation'in order to have in-depthunderstandingwhich is the importantaspect for eventual laMul enforcementand prosecutionand those definitionsas providedin section 2 of the Act. 'Fire-FightingEquipment or Fire Safety installation' meansany equipmentor installation for: . Extinguishing, fighting,preventing,or limitinga fire . Givingwarningof a fire . Providingaccessto any premisesfor extinguishing, fighting,preventing,or limitinga fire . Providingemergencypower supplyin the event of normalpowerfailure . Providingemergencylightingfor purposesof escapefrom buildings . Giving directiontowards an escape route or place of refuge,or . Providingadequate,safe egressfor the purposeof evacuationor exit of occupantsin the event of fire 'Fire-hazard'means: . Any unlawfulalterationto any buildingsuch as might render escape in the event of a fire materiallymore difficultor less easy than it would be if the alterationhad not been made. . The over-crowdingof any place of public entertainmentor publicgatheringsuch might render escape in the event of a fire difficult. . A n y r e m o v a lo r a b s e n c ef r o m a n y b u i l d i n go f a n y F i r e - f i g h t i n gE q u i p m e n to r F i r e S a f e t y installationthat is requiredby law to be providedin the building. . The presencewithin or outside any buildingof any Fire-fightingEquipmentor Fire Safety installationor any facility,installedin accordancewith the requirementof any writtenlaw or as requiredby the Fire ServicesDepartment,that is not in efficientworking order. ' Inadequatemeansof exit from any part of a buildingto any place,whetherwithinor outsidethe building,that providessafetyto personsin the event of a fire, or . Any othermatteror circumstances that materiallyincreasethe likelihoodof a fire or the dangerto life or propertythat would resultfrom the outbreakof a fire, or that would materiallyhamperthe Fire ServicesDepartmentin the dischargeof its dutiesin the event of a fire.
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2 0 . 6C OMP OU N D IN G Based on the Fire Services (Compounding of Offences) Regulations 1991 which came into force on the 6th August 1991, the followingare compoundableoffences: Section 22(U - any person in controlor owner of such premiseswho fails to comply with any directiongiven by the DirectorGeneral or any authorisedofficer to providefacilitiesand water supplyfor fire fightingpurpose. section 23(11- any works that affectany fire hydrantor the frow of water Section 23(21- hydrantnot in good working conditionupon the completionof any works carried out. Section 25(21- any person who refuses to allow the fixing of hydrant plate or obstructsin the course of the fixing or removes or defaces any such plate. Section 26 - any personwho coversup, encloses,or concealsany fire hydrantso as to renderits locationdifficultto ascertain,or tampers with any fire hydrant,or uses a fire hydrant other than for fire fighting purposes. Section 32(21- make a materialchange to the premiseswhile a fire certificateis in force. Section 33 - No fire certificatein force in respect of any designatedpremises. Section 47 - Unauthorisedpresencein premiseswhich has been taken over bv the Fire Services Departmentas a result of a fire. Section 52 - Failureto complywith directiongiven by an authorisedofficer.
20.7ABATEMENTOF FTRE.HAZARD ' Section 8 (1) - the DirectorGeneral,if satisfiedof the existencein any premisesof any fire hazard,may serve an abatementnotice in Form A requiringhim to abate the fire hazardwithin the specificperiod.lf the fire hazardis likelyto recur, he may also, by the fire-hazardabatementnotice under subsection(1) or by a subsequentfire-hazardabatementnoticein Form B requirethe person on whom the notice is served to do whateveris necessaryto preventingthe recurrenceol the fire hazardpursuantto subsection(2). ' Section 9 - Power of DirectorGeneralto abate fire hazardin vacant or unoccupiedpremisesir which the fire hazardexists. ' Section 11 - Powerof DirectorGeneralto abate fire hazard on non-compliance with fire hazard abatementnoticeand the expensesincurredcan be recoverablein court pursuantto section16 of this Act.
r
' Section 12 - Powerof DirectorGeneralto abatefire hazardin any premises in caseof urgencyanc eXpensesincurredcan be recoverablein court pursuantto section17 of this Act.
256
NB:
Abatementof fire hazardpursuantto sections 9, 11 and 12 of this Act can be done either by removing,demolishingand etc. thus avoidingexistenceof fire hazard.
20.8PROHIBITORY ORDER General to applyto a courtfora prohibitory Section35allowstheDirector orderto anypremises, if the risk to personsor propertyin case of fire is so serious,untilstepshave been taken to reduce the fire to a reasonablelevel.
20.9ORDERTO CEASEAGTIVITY Section 35A of the Act allowsthe DirectorGeneralby order to directthe owner or occupierof the premisesto cease activity if he is satisfiedthat: a.
any continued activity in any premiseswould constitutean immediatedanger of fire prejudicialto the safety of life or property,and
b.
delay in applyingfor a prohibitoryorder would substantiallyincreasethe risk to life or property.
20.10CLOSINGORDER Section13 of the Act prohibitsthe use of any premiseswhich may materiallyincreasethe likelihood of a fire or the danger to life or propertyresultingfrom the outbreak of a fire.
20.11SPECIAL POWEROF FIREOFFICERS 20.11.1 Pursuantto section 18 of the Act. a Fire Officer on the occasion of a fire mav: . Removeany personinterferingby his presenceor actionswith the operationsof the Fire Services Department. . Enter,break,possessor demolishany premisesfor the purposeof puttingan end to the fire or rescue any person. . Close any street near the site of the fire or controlthe traffic or crowd in any such street. . Use any convenientsupplyof water duringfire operation. 20.11.2 Pursuantto section 46(1) of the Act, the DirectorGeneralmay at any time within seven days after the occurrenceof the fire, take possessionof the premisesand other propertydamaged or destroyedby the fire. 20.11.3 Section 19 of the Act providespowersto the Fire Officersin emergenciesnot involvingfire.
257
20.11.4 Pursuantto section 38(1) of the Act, an authorisedofficermay, togetherwith such otherofficers, enter any premisesfor the purposeof: . Ascertainingwhetherthere is any contraventionof the Act. . Obtaininginformationconcerningthe premisesfor fire-fighting. . Ascertainingwhetherthere existsany fire hazardin the premises. . Make any enquiryon matterswithinthe Act. ' Exercisingany poweror performingany duty of the DirectorGeneralunderany otherwrittenlaw. 20.11.5 Pursuant to section 40(1) of the Act, any authorised officer may without warrant arrest any person: . Foundcommittingan offenceunder Section 47, or ' Whom he reasonablysuspectsto have committedany otheroffenceunderthis Act if the person: (a) refusesto furnishhis name and address (b) furnishedan addressout of Malaysia (c) thereare reasonablegroundsfor believingthat he has furnisheda falsenameand address (d) that he is likelyto abscond 20.11.6 Section a1(1) of the Act providesthat any authorisedofficershall have the power to investigate any offenceunderthis Act. 20.11.7 Section 44 providesthat every authorisedofficershall have the authorityto appear in court and conduct any prosecutionin respect of any offence under this Act provided such officer has been given a writtenauthorisationby the Public Prosecutoror the DeputyPublicProsecutor.
20.12PROTECTION OF FIREOFFICERS Section 20 providesthat no Fire Officeror AuxiliaryFire Officeracting bona fide under this Act shall be liableto any actionfor damagesfor any act done or omittedto be done by him in connectionwith his dutieson the occasionof a fire or any calamity.
20.13REGULATION MADEUNDERTHE FIRESERVICES ACT The Ministerof Housingand Local Governmentmay make regulationspursuantto section 62 of the Act for the bettercarryingout of the purposesand the provisionsof this Act.
258
20.14 PENALTY 20.14.1 Section 10 and section 13(5)providethat if any personfailingto complywithfire hazardabatement notice and knowinglycontravenethe closingorder respectivelyshall be guilty of an offence and shall,on conviction,be liableto a fine not exceedingfive thousandringgitor to imprtsonmentfor a term not exceedingthree years or to both and shall be also liableto a furtherfine of one hundred ringgitfor each day duringwhich the offenceis continuedafterthe conviction. 20.14.2 Section 35(5) of the Act, providesthat if any personwho withoutreasonableexcuse knowingly contravenesa prohibitoryorder shall be guiltyof an offenceand shall,on conviction,be liableto a fine not exceedingten thousandringgitor to imprisonmentfor a term not exceedingfive yearsor to both and shall also be liableto a furtherfine of one hundredringgitfor each day duringwhich the offence is continuedafter the conviction. 20.14.3 Section 58 of the Act providesthat if any personguilty of an offenceunder this Act for which no penaltyis expresslyprovidedshall, on conviction,be liableto a fine not exceedingfive thousand ringgitor to imprisonmentfor a term not exceedingthree years or to both.
20.15 CONCLUSION This explanqtionon the Fire Services Act 1988 is only skeleton in nature, but in order to understandin depth or in total one has to make close referenceto the Fire ServicesAct itself.The Fire ServicesAct shouldnot be read in isolationbut referenceshouldbe made to other regulations enacted under this Act. Further referencemust also be made to the Uniform BuildingBy-laws 1g84,and other acceptedrelevantbuildingcodes and standards.For effectiveprosecutiondetail referencemust also be made to the latestversionof the EvidenceAct 1950, CriminalProcedure Act 1948 & 1967 and other relevantActs in Malaysiatogetherwith relevant Code, Interpretation case laws.
259