Copyright © Copyright Task Force Managed Services EID Disclaimer No part of this document may be reproduced in any form without the written permission of the copyright owner.
Content 1
Abstract ..........................................................................................2
1.1
Task Force Output ...........................................................................3
2
Guideline on Trouble Shooting of MINI-LINK Equipment..........4
2.1
Prerequisite......................................................................................5
2.2
Preparation ......................................................................................6
2.3
TOC .................................................................................................8
3
Guideline on Trouble Shooting of Power Related Problem ....27
3.1
Prerequisite....................................................................................28
3.2
Preparation ....................................................................................29
3.3
TOC ...............................................................................................31
4
Enclosure .....................................................................................58
4.1
Transmission AND RBS Data Report............................................59
4.2
Power Data Report ........................................................................63
PAGE 1
1 ABSTRACT After analysis of trouble ticket trend for over 6 months, Managed Services delivery team notices a pattern of recurring problem related to MINI-LINK and power related issue. In an effort to reduce the recurring problem, a task force focusing on the issues were set up, with a goal to find the root cause of the recurring problem. The type of MINI-LINK recurring problem that were focused on included: NPU hanging (stuck in boot process) for AMM 2p B RSL with measurement of -20dB Performance degrading on sites with antenna over 1.2m High temperature leading to MINILINK software hanging in TN R2 Power related problem investigation was focused circuit breaker (MCB) tripping due to: Unbalanced power consumption Insufficient commercial power capacity Low voltage from commercial power Phase failure As an outcome of the investigation, this document is produced as a guideline to help field maintenance technicians & engineers for troubleshooting similar problem Ericsson official documentation for MINI-LINK operational and maintenance guideline should always be the main reference for any operational activities. This document is to be used specific for the problem described above.
PAGE 2
1.1
Task Force Output DOWNTIME CONTRIBUTOR 8,835 in December (1044 less compared to November) 920 less power related problem; due to battery replacement, faster response on RST alarm 144 less problem for other issue, mainly transmission, MCB trip cases; due to task force activity that focused on recurring transmission problem and MCB trip cases TT Type: December 2009
Lease Line, 22, 0% Access Issue, 34, 0% RNC, 1, 0% BTS, 210, 2% Transmission, 157, 2%
Pow er Outage, 7982, 91%
CME, 308, 4% P o wer Outage
CM E
3rd P arty
P ro ject
B SC
Others
Transmissio n
B TS
NODE-B
A ccess Issue
RNC
Lease Line
Downtime contributor 1.600% 1.400% 1.200% 1.086%
1.000% 0.800%
0.704%
0.442%
0.590%
0.600% 0.395%
0.791% 0.557%
0.426%
0.654% 0.634%
0.473% 0.572%
0.400%
0.589% 0.575% 0.531% 0.504% 0.440% 0.372% 0.200% 0.367% 0.290% 0.292% 0.228% 0.213% 0.150% 0.000% Wk Wk Wk Wk Wk Wk Wk Wk Wk Wk Wk Wk 1 43 44 45 46 47 48 49 50 51 52 53 % - EID
% - External
PAGE 3
2 Guideline on Trouble shooting of MINI-LINK Equipment
PAGE 4
2.1
PREREQUISITES This chapter describes the hardware tools & software programs that are needed when trouble shooting shall be done for MINI-LINK equipments. Engineer always needed to bring the right tools for working with troubleshooting on sites. Please do not forget to prepare the required sites permit and necessary coordination to make sure our activities on sites will be done smoothly. Tools that are needed: a. Notebook and accessories cables (USB, Ethernet, and RS232). b. MSS (MINI-LINK Service Software) installed in the notebook. c. Correct SW version for all equipment if upgrades are necessary (include the latest software baseline). d. Basic Tools: digital Volt-meter, LED, screw-driver sets, DDF punch tools, wrist-stripe, etc e. HSE Tools f.
If required, always bring BER meter for checking E1 / STM-1 performance.
g. If needed, always bring HW spares (Ex MMU, TRU, NPU, RAU and dummy) that might need to be replaced. h. If needed, always bring RAU connectors, electrical insulating tape, butyl sealing compound for water protect the RAU connector/cable. Access Permit & Coordination procedures that are needed; a.
Working permit and site key access.
b.
Customer approval for equipment down time if needed
c.
Always Coordinate with Customer NOC / OMC
d.
Approvals from NOC before and after enter the site.
PAGE 5
PREPARATION Considering most of trouble-shootings will be done on existing (with live traffic) sites, we should follow our Network Interruption process. Information on the request form (Day “H”) 1.Site name 2.SOW activity on site 3.Person in charge From EID organzation 4.Site access (related with the request for Key arrangement and Supervisor from Customer) 5. Time frame of the activity
Prepare Request Form to Enter Customer Site Revise data on the form
2.2
The Form send to Customer for approval
No
1.Customer give approval by signing the request form (Day H+1)
All data approved by Customer Yes
Engineer Received Key and information on PIC from Customer Spv
Engineer arrived on site
Before enter the site Call OMC 1.Identify yourself to OMC and Gave information regarding the task 2. Ask if Site has alarm or not 3.Show / give the letter of assignement ot the spv of the sites if one exist .Such as IBS (in building solution )site
Call /report to OMC
Anything Unusual on Site
1. Check Sorrounding of the site for anything unusual Such as Grounding missing;Fence broken etc. 2..Check Inside the shelter , Save alarm or status of the RBS related to Engineer’s work 3.Take Foto for unusual conditional
Engineer doing the Activity
Engineer completing the activity+ Clean Up site
Call OMC before left the sites
1. Make sure that the site is clean 2. Make sure the RBS status has the sama or less alarm status compare before engineer enter the shelter
Give notification to OMC that you already completed the activity on related site Confirmation on the status site from OMC
Return Sheter Key to Custome by filling the report
end
Picture 1
Network Interruption process
PAGE 6
General key-points before starting our trouble-shooting main activities:
a. Inform Customer NOC team about our activity on site, especially if traffic interruption will be done, before and after our activity.
b. Check surrounding condition if any Unusual Condition found, such as; Grounding missing, broken KWH, abnormal indoor temperature, etc. If needed, take capture / picture as evidences and inform to NOC Team.
c. Check Physical condition of ML equipments especially for LED Status and Input DC voltage • If we found RED Light or strange Status, check details by LCT for verification, and take/save Capture & Logs. For more information, see LED Descriptions MINI-LINK TN Operating Instructions, Reference [4] • Measure the Input Vdc using a Digital Voltmeter, and compare it with the specification
Never Turn-Off / Reset the ML equipments before verifying and taking required information.
PAGE 7
2.3
Table of Content
1
Troubleshooting Procedure ...................................................... 9
1.1
Received Alarm / Fault Description .............................................. 9
1.2
Troubleshooting MLTN............................................................... 10
1.2.1
SW troubleshooting MLTN ......................................................... 10
1.2.2
Data Collection MLTN ................................................................ 11
1.3
Troubleshooting MLHC .............................................................. 11
1.3.1
SW troubleshooting MLHC on site ............................................. 11
1.3.2
Data Collection MLHC................................................................ 12
1.4
Hardware Installation Check ...................................................... 12
2
Example problem found in Transmission.............................. 13
2.1
Hardware Faulty ......................................................................... 13
2.1.1
RAU with RSL – 20 dBm ............................................................ 13
2.1.2
AMM 2p B faulty ......................................................................... 14
2.2
Low RSL..................................................................................... 15
2.3
Switching 1+1 HS failed (MMU2 D)............................................ 18
2.4
HCC/RCC Alarm ........................................................................ 20
3
Problem analysis & Escalation Process ................................ 23
4
Replacement Faulty Module.................................................... 24
5
Closing Preparation ................................................................. 25
6
Reporting .................................................................................. 25
7
Reference .................................................................................. 26
PAGE 8
1.
TROUBLESHOOTING PROCEDURE Please follow our general Technical Trouble-shooting process:
Picture 2
1.1
General trouble-shooting process
Received Alarm / Fault Description The receiver alarm / fault description should include details about the following: a.
Exact date and time of the problem. The time shall be given in relation with the time setting in the affected NEs.
b.
Effect of the problem. Explain the fault events as they occurred, step by step. Specify slot positions when applicable.
c.
Events that might have lead to the fault.
d.
Frequency of the fault.
e.
Software Baseline (SBL) running on the NE when the fault occurred.
PAGE 9
1.2
Troubleshooting of MLTN
1.2.1
SW Troubleshooting MLTN on site Please follow below procedure of trouble-shooting MLTN: a.
Connect to the MLTN (using Ethernet or USB cable)
b.
Check the event / alarms / fault to evaluate what the problem is See more details information in documents of: • Fault Management Operations MINI-LINK TN ETSI, Reference [6] • Alarm Descriptions MINI-LINK TN ETSI Description, Reference [7] • Event Descriptions MINI-LINK TN ETSI Description, Reference [8]
c.
Verifying Radio Link Configuration Parameters Verify that all hop setup parameters are set and correspond to the value in SID / PQR, such as: RSL (Received Signal Level), Tx power, Switching mode, Frequency setting, etc.
d.
Checking for RF Interference If the Radio Link reports unexpectedly bad BER performance but RF input level is normal, the receiver might be interfered by external RF sources. Check RF interference using Far-end Tx-off procedure.
e.
Use a loop on the unit that having problem to trace the fault (i.e.: RF Loop, IF Loop, etc).
f.
Use built-in BERT (Bit Error Ratio Tester) or external BER meter to verify or trace the fault.
g.
Restarting the NE (Network Element) In some cases, if required, we can do a Warm or Cold Restart of the NE.
• A cold restart will disturb the traffic. • Always collect Logs before restarting the NE since the alarm and event logs, as well as power cycling information, are deleted at both cold and warm restarts and potentially valuable information is lost. h.
Take capture of specific problems.
i.
Check and (if required) perform SW upgrade if it’s an older SW-baseline version.
PAGE 10
The SW version should be checked with O&M to synchronize that the MINI-LINK has the same SW baseline in all MLTN. Please perform a software upgrade to the new software baseline according to the MINI-LINK TN ETSI Operating Instruction, Reference [2] or MINILINK Craft User Interface Descriptions, Reference [3], chapter ”Software Upgrade”. For details about recommended upgrade paths of MLTN, please also see the Compatibility Information and Release Note documents.
1.2.2
Data Collection MLTN Take following data from MLTN terminals for any further technical analysis or escalation:
a.
Error log file and Event log / history Always collect alarm logs and event log before any warm/cold restart or power cycling.
b.
Alarm list (needs to be done before power reset)
c.
Get the configuration file and saved report if you don’t have the latest file
d.
Collect PM (Performance Management) data if PDH/SDH MMUs is used (Near & Far end)
1.3
Troubleshooting of MLHC
1.3.1
SW Troubleshooting MLHC on site Please follow below procedure of trouble-shooting MLHC: a.
Connect to the MLHC (using Ethernet or Serial OM cable)
b.
Take Capture of existing parameters needed and Save Configuration for backup purposes
c.
Check the alarms to evaluate what the problem is.
d.
Always upload the Alarm logs of MLHC
e.
Verifying Radio Link Configuration Parameters refer to SID / PQR
f.
Checking for RF Interference
g.
Use loops to trace were the problem is (example : RF Loop, IF Loop, SPI Loop)
h.
If necessary, use external BER meter to verify or trace the fault.
i.
Always take capture of specific problems. PAGE 11
j.
Make a save before any power cycling.
Note: If you have not save before power cycle and you have made any changes the TRU will go back to the latest saved configuration. k.
Perform SW upgrade if it’s an older SW version. This should be checked from the O&M what version that shall be used.
1.3.2 Data Collection MLHC Take following data from MLHC terminals for any further technical analysis and escalation:
a.
Alarm logs from (Near-end and Far-end). Needs to be collected before power reset.
b.
Performance log (monitoring data) from Near-end and Far-end. If performance data is not available, follow the performance setup in as document of Settings for performance measurements in Mini-Link High Capacity, Reference [13]
1.4
c.
Inventory data (Near-end and Far-end)
d.
Configuration file
Hardware Installation Check Aside checking the software status, in some conditions we need to check physical installation also: a.
FAN unit correctly installed on MLTN / MLHC.
b.
Dummy fronts installed (MLTN).
c.
Grounding completely & properly installed according to the installation manuals
d.
Traffic and DC Cabling/Connectors properly installed. See more details in document of Installing Indoor Equipment MINI-LINK TN ETSI Installation Instructions, Reference [1].
e.
Radio cable and the connectors properly installed. (See more details in document of Radio Cable Check [13].
f.
All connectors tightened (DC/traffic/radio)
g.
Check power distribution (battery, DC power level and MCB Ampere). PAGE 12
2.
h.
Modem units correctly inserted and tightened
i.
If the problem is still intermittent, check interfaces on front and the backplanes for broken or damage pins
Example Problem found in Transmission 2.1 Hardware Faulty 2.2 Low RSL 2.3 Switching 1+1 HS failed (MMU2 D) 2.4 HCC/RCC Alarm
2.1
Hardware Faulty
2.1.1 RAU with RSL -20 dBm In the Radio Link Alarm, we found the RSL of the RAU is – 20 dBm. In 1+1 HS configuration, sometimes the switch can not work caused by this problem. There is a known problem with a component handling the attenuation on the RAU. The following steps must follow to solve the problem; 1.
Prepare RAU with same product code.
2.
Unplug jumper cable on MMU.
3.
Replacement RAU with the new one.
4.
Plug jumper Cable onto MMU.
5.
Reset Performance in Near End and Far End
6.
Send the RAU to Ware House with BLUE TAG FORM.
Note: Write in Remark Column; RAU faulty with RSL – 20 dBm.
PAGE 13
2.1.2 AMM 2p B Faulty AMM 2p B faulty with problem NPU stuck in Boot Process. There is a known problem with a bad soldering of the component in the backplane. The Fault LED in NPU was ON. The following steps must follow to solve this problem; 1.
Prepare new AMM 2p B
2.
Turn off DC Source. Unplug DC cable from AMM 2p B (faulty).
3.
Unplug some modules from AMM 2p B: NPU3, MMU and FAU4.
4.
Uninstall AMM 2p B (faulty).
5.
Install new AMM 2p B.
6.
Plug in some modules into new AMM 2p B: NPU3, MMU and FAU4.
7.
Plug in DC Cable to AMM 2p B.
8.
Turn ON DC Source then pressing the BR button of NPU (2-3 seconds after Turn ON DC source).
9.
The LED BR in the NPU will flash. It means, the NPU in Installation mode status.
10.
Log in to ML TN with your laptop.
11. Activate the configuration from RMM card. 12. If AMM 2p B does not have RMM, You have to activate configuration with LOAD CONFIGURATION FILE from your laptop. 13. Otherwise, you should create configuration by manually. 14. Call NOC to check the status of our equipment (RBS and Transmission). 15. Send AMM 2p B to ware house with BLUE TAG FORM. Note: Write in remark column; AMM faulty with problem NPU stuck in Boot Process.
PAGE 14
2.2
Low RSL Low RSL can cause performance degradation in our link. The RSL of the Link have to follow the value from the PQR. The tolerance value is +- 4 dB from PQR. Otherwise we have to realignment the antenna to get expected RSL or reroute the link if the link get obstacle path. Sometime, Low RSL can happened cause by shifted antenna especially for antenna over than 1.2 m which do not have properly for side strut installation of antenna. Please see picture below;
Picture 3
Improperly side strut installation on Tower
PAGE 15
Picture 4
Improperly side strut installation on Pole
The following steps must follow to solve this problem (Low RSL caused by Shifted antenna); 1.
We have to make sure position of antenna in NE and FE site can allow installation side strut with the right way. Please see picture below ;
Picture 5
Proper angle for attaching the side strut
PAGE 16
2.
If needed we have to reinstall antenna on NE and FE; a.
Change leg of tower for attaching antenna
b.
Change handle of antenna from right to left side or vice versa.
3.
If antenna attaching in pole we need install additional mounting for attaching side strut.
4.
Then realignment antenna to get expected RSL (PQR).
5.
Install side strut refer from standard installation document.
6.
Coordination to NOC to check our equipment status.
Note:
For above activity, it shall cause traffic disturbance for 4 – 5 hours. So, please make coordination with the customer for permit activity.
Please see the picture below for properly side strut installation;
Picture 6
Properly side strut installation on tower
PAGE 17
Picture 7
2.3
Properly side strut installation on pole
Switching 1+1 HS failed (MMU2 D) When the RAU N has used for MMU2 D, The switching protection in 1+1 HS does not work. It is caused by software compatibility in the RAU N. Note: If using RAU N with MMU2 D, software of RAU have to over than R2X. The following steps must follow to solve this problem; 1.
Log in to ML TN
2.
Go to the inventory Tab then Check software of the RAU N in NE and FE.
PAGE 18
Picture 8
RAU Software in inventory list
Note:
RAU in Slot 4 is OK, over than R2X RAU in Slot 5 is not OK, below than R2X
3.
Upgrade software for RAU N with Software RAU over than R2X, example R3C.
4.
Testing switch protection to verify the switch is working.
5.
Coordination with NOC to check our equipment status.
PAGE 19
2.4
HCC/RCC Alarm HCC Alarm means communication is lost on Hop Communication Channel, between MMU and far-end MMU. RCC Alarm means Communication is lost on the Radio Communication Channel (RCC), between MMU and RAU. Those problems were caused by bad connection between MMU and RAU or the modules are fault.
Picture 9
Radio Link Alarm
PAGE 20
Picture 10
Alarm List
The following steps must follow to solve this problem; 1.
Log In to ML TN.
2.
Go to Radio Link Alarm Tab then found which slot have problem RCC.
3.
Check installation of connector coaxial at near end and far end.
4.
If needed, reinstall connector coaxial with the right way.
5.
Coordination with NOC to check our equipment status.
PAGE 21
Please see the picture below for bad installation;
Picture 11
Picture 12
Coaxial connector without fold grounding cable and 2.5mm of the dielectric
Coaxial connector without 2.5mm jacket isolation of dielectric
PAGE 22
Please see the picture below for good installation;
Picture 13
3.
GOOD installation
PROBLEM ANALYSIS & ESCALATION PROCESS After getting enough information from sites, we need to analyze it to get the correct solution. Please always refer to: a.
Ericsson Mini-Link technical documentations. Some of those as listed in the Reference chapter at page 11, or more complete documents in Alex / Ericsson CPI documents.
b.
Check to the previous applicable technical report. The purpose is to minimize our trouble-shooting duration. Search any similar and applicable report that can be reused in our problem. We can
PAGE 23
get those from previous Trouble-shooting Report, CSR report, Service Advice document, as well as some sharing experiences in Ericsson Knowledge Based. In case of internal team can not solve the problem, especially which related with competence and product issue, we can escalate it to higher level support. Any escalation to 1st or 2nd line support will need a CSR (Customer Support Request). A CSR is primarily used in situations of a non-emergency nature, indicating a software or hardware design-related problem. It is also used to ask general questions of a technical nature. An emergency request is normally taken care of in another routine, but it is always registered as a CSR afterwards for follow-up reasons. Usually, only one issue can be addressed per CSR. We shall enclose relevant and complete troubleshooting data shall in the CSR as the required procedure. See Data Collection Guidelines MLTN Operating Directions, Reference [5].
4.
REPLACEMENT FAULTY MODULE In case there is/are faulty module/s found based on the fault tracing phase, we can replace that plug-in unit/s accordingly. Please take below precaution and procedure carefully: a.
Identifying Current Hardware and Software
b.
Checking the Compatibility
c.
Uploading Configuration File when Replacing a NPU or RMM
d.
Required Tools and Equipment
e.
Prepare for Software Upgrade: FTP server and SBL firmware
f.
Procedure to replace the Hardware module
g.
Concluding Routines of checking any active alarms, handling faulty unit, etc
PAGE 24
See details in Replacing a Radio or Plug-In Unit MLTN Operating Instruction, Reference [11]
5.
CLOSING PREPARATION After activities had been done, ensure that the following actions have been performed:
6.
a.
Reset Performance Log (if needed to monitor performance link for few days)
b.
Reset alarm list and Event history (if needed to monitor performance link for a few days)
c.
Inform customer NOC team that our activity had been done.
d.
Get confirmation from NOC that all equipments are back to normal operation and there are no active alarms caused by our activity.
e.
Clean up the site for any trashes from our activity.
f.
Lock all doors and leave the site.
REPORTING After activities had been done, spare your time to make report to your supervisor such as;
a.
Create a Troubleshooting Report.
b.
Complete raw data (alarm list, even log, error log, save report and any capture) as evidence.
c.
Collect Photo as evidence (if required).
d.
Fill BLUE TAG Form for any HW Faulty and send to the ware house.
e.
Please fill-in completely as described in HWS RDN (Repair delivery Note), Reference [12]
PAGE 25
7.
REFERENCE [1]
Indoor Installation Instruction Mini-link TN ETSI, 1531-CSH 109 32/1-S1 Uen
[2]
Operating Instruction Mini-link TN R3, 1543-CSH 109 32/1-V1 Uen
[3]
MINI-LINK Craft User Interface Descriptions, ML Craft 2.2, 7/1551-CSH 109 32/1-V1 Uen
[4]
LED Description MINI-LINK TN ETSI, 24/1543-CSH 109 32/1-V1 Uen
[5]
Data Collection Guidelines MLTN Operating Directions, 34/1543-CSH 109 32/1-V1 Uen
[6]
Fault Management Operations MINI-LINK TN ETSI, 4/1543-CSH 109 32/1-V1 Uen
[7]
Alarm Descriptions MINI-LINK TN ETSI Description, 5/1543-CSH 109 32/1-V1 Uen
[8]
Event Descriptions MINI-LINK TN ETSI Description, 9/1551-CSH 109 32/1-V1 Uen
[9]
Troubleshooting MINI-LINK TN ETSI Operating Guideline, 5/154 43-CSH 109 32/1-V1 Uen
[10] Troubleshooting Guideline by EID/OP/MR Ronny Stralhed [11] Replacing a Radio or Plug-In Unit MLTN Operating Instruction, 11/1543-CSH 109 32/1-V1 Uen [12] HWS RDN (Repair delivery Note), 2/1546-FAP 130 495 Uen [13] Settings for performance measurements in Mini-Link HC, EAB/FBM/LG-07:001 Uen [14] Radio Cable Check by MO/EAB/JT/GG EMWCRM
PAGE 26
3 Guideline on Trouble Shooting of Power Related Problem
PAGE 27
3.1
PREREQUISITES This chapter describes the hardware tools & software programs that are needed when trouble shooting shall be done for MINI-LINK equipments. Engineer always needed to bring the right tools for working with troubleshooting on sites. Please do not forget to prepare the required sites permit and necessary coordination to make sure our activities on sites will be done smoothly. Tools that are needed: a.
Notebook and accessories cables (USB, Ethernet, and RS232).
b.
Correct SW version for all equipment if upgrades are necessary (include the latest software baseline).
c.
Basic Tools: digital Volt-meter, LED, screw-driver sets, DDF punch tools, , etc
d.
HSE Tools
e.
If needed, always bring HW spares (power & grounding cable, MCB etc a) that might need to be replaced.
Access Permit & Coordination procedures that are needed; a.
Working permit and site key access.
b.
Customer approval for equipment down time if needed
c.
Always Coordinate with Customer NOC / OMC
d.
Approval from NOC before & after enter site
PAGE 28
PREPARATION Considering most of trouble-shootings will be done on existing (with live traffic) sites, we should follow our Network Interruption process. Information on the request form (Day “H”) 1.Site name 2.SOW activity on site 3.Person in charge From EID organzation 4.Site access (related with the request for Key arrangement and Supervisor from Customer) 5. Time frame of the activity
Prepare Request Form to Enter Customer Site Revise data on the form
3.2
The Form send to Customer for approval
No
1.Customer give approval by signing the request form (Day H+1)
All data approved by Customer Yes
Engineer Received Key and information on PIC from Customer Spv
Engineer arrived on site
Before enter the site Call OMC 1.Identify yourself to OMC and Gave information regarding the task 2. Ask if Site has alarm or not 3.Show / give the letter of assignement ot the spv of the sites if one exist .Such as IBS (in building solution )site
Call /report to OMC
1. Check Sorrounding of the site for anything unusual Such as Grounding missing;Fence broken etc. 2..Check Inside the shelter , Save alarm or status of the RBS related to Engineer’s work 3.Take Foto for unusual conditional
Anything Unusual on Site
Engineer doing the Activity
Engineer completing the activity+ Clean Up site
1. Make sure that the site is clean 2. Make sure the RBS status has the sama or less alarm status compare before engineer enter the shelter
Give notification to OMC that you already completed the activity on related site Confirmation on the status site from OMC
Call OMC before left the sites
Return Sheter Key to Custome by filling the report
end
Picture 1
Network Interruption process
PAGE 29
General key-points before starting our trouble-shooting main activities:
a. Inform Customer NOC team about our activity on site, especially if traffic interruption will be done, before and after our activity.
b. Check surrounding condition if any Unusual Condition found, such as; Grounding missing, broken KWH, abnormal indoor temperature, etc. If needed, take capture / picture as evidences and inform to NOC Team.
c. Check Physical condition of ML equipments especially for LED Status and Input DC voltage • If we found RED Light or strange Status, check details by LCT for verification, and take/save Capture & Logs. For more information, see LED Descriptions MINI-LINK TN Operating Instructions, Reference [4] • Measure the Input Vdc using a Digital Voltmeter, and compare it with the specification
Never Turn-Off / Reset the ML equipments before verifying and taking required information.
PAGE 30
3.3
Table of Content 1 1.1 1.1.1 1.1.2 1.1.2.1 1.1.2.2 1.1.3 1.1.3.1 1.1.3.2 1.1.3.3 1.1.3.4 2 2.1 2.2 2.2.1 2.2.2 2.2.3 2.2.4 2.3 2.3.1 2.3.2 2.3.3 2.3.4 2.3.5 2.3.6 2.3.7 2.3.8 3 3.1 3.2 3.2.1 3.2.2 3.3 3.3.1 3.3.2 3.4 3.4.1 3.4.2 3.5 3.6 4
Mini Circuit Breaker (MCB).................................................................32 Definition MCB.......................................................................................32 PLN MCB...............................................................................................32 ACPDB MCB .........................................................................................33 Main MCB ACPDB ................................................................................33 Utility MCB ACPDB ...............................................................................33 DCPDB MCB .........................................................................................34 Main MCB Rectifier................................................................................34 Utility MCB Rectifier / PBC 6500 ...........................................................34 Battery MCB Rectifier ............................................................................35 19” Rack MCB / DCPDU .......................................................................35 Power Root Cause Analysis...............................................................36 MCB Trip Problem Identification............................................................36 Cause of MCB Trip ................................................................................36 Trip of MCB PLN ...................................................................................36 MCB PLN & Main ACPDB.....................................................................36 Trip of MCB Utility ACPDB ....................................................................37 MCB DCPDB .........................................................................................37 Analysis .................................................................................................37 Short Circuit...........................................................................................37 Unbalance Power Consumption............................................................37 Air Conditioning Problem.......................................................................38 Insufficiency PLN Capacity....................................................................38 PLN Problem; Phase Failure, Low Voltage...........................................42 Short Circuit at Air Conditioning Controller ...........................................43 Short Circuit at Air Conditioning ............................................................44 MCB Trip at DOU for MCB DCPDU (19” rack)......................................44 Action Taken Recommendation.........................................................46 Check Installation ..................................................................................46 Balancing Power Consumption .............................................................46 Indoor ....................................................................................................46 Outdoor..................................................................................................47 PLN Capacity.........................................................................................49 PLN Capacity Indoor Sites ....................................................................49 PLN Capacity Outdoor Sites .................................................................50 Air Conditioning Maintenance ...............................................................53 Measurement AC Current for Air Conditioning......................................53 Air Conditioning Phase Controller .........................................................53 Power Source for DCPDB at 19” Rack..................................................54 Exhaust Fan Status ...............................................................................56 Reference .............................................................................................57
PAGE 31
1
Mini Circuit Breaker (MCB)
1.1
Definition MCB
1.1.1
PLN MCB Location
: KWH panel
Type
: Blue toggle; CL curve
Band
: Merlin Gerin, ABB, Vyckler, J&P, Okachi
MCB 1 phase – 1 pole
MCB 3 phase – 1 pole
PAGE 32
1.1.2
ACPDB MCB
1.1.2.1 Main MCB ACPDB Location
: ACPDB panel
Type
: Black toggle; C curve; MCB 3 phase-1 pole
Band
: Merlin Gerin, ABB
1.1.2.2 Utility MCB ACPDB Location
: ACPDB panel
Type
: Black toggle; C curve; MCB 1 phase-1 pole
Band
: Merlin Gerin, ABB
Outdoor ACPDB
Indoor ACPDB
PAGE 33
1.1.3
DCPDB MCB
1.1.3.1 Main MCB Rectifier Location
: Rectifier
Type
: Black toggle; C curve; MCB 1 phase-1 pole
Band
: Merlin Gerin, ABB, Nader
Main MCB Rectifier
1.1.3.2 Utility MCB Rectifier/PBC 6500 Location
: Rectifier or PBC 6500
Type
: Black toggle; C curve; MCB 1 pole
Band
: Merlin Gerin, ABB, Nader
Utility MCB Rectifier
Utility MCB PBC6500
PAGE 34
1.1.3.3 Battery MCB Rectifier Location
: Rectifier or PBC 6500
Type
: Black toggle; C curve; MCB -1 pole
Band
: Merlin Gerin, ABB, Nader
MCB Battery Rectifier
MCB Battery PBC 6500
1.1.3.4 19” Rack MCB / DCPDU Location
: 19” Rack
Type
: Black toggle; C curve; MCB -1 pole
Band
: Merlin Gerin, ABB, Nader
DCPDU
: for Transmission equipment
DCPDB RBS
: for RBS
DCPDB RBS – for RBS
DCPDU - Transmission
PAGE 35
2
Power Root Cause Analysis
2.1
MCB Trip Problem Identification Base on data trouble ticket week 39-40, percentage of MCB trip: a. MCB PLN : 60% (14 times) b. MCB PLN & Main ACPDB : 26% (6 times) c. MCB Utility ACPDB : 9% (2 times) d. MCB DCPDB : 5% (1 times)
2.2
Cause of MCB Trip
2.2.1
Trip of MCB PLN A. Cause MCB trip Indoor Sites a. Short Circuit b. Unbalance power consumption c. Air Conditioning problem; high AC current (out off manufacture standard) d. Insufficient PLN capacity e. PLN Problem :Low Voltage PLN, Phase failure B. Cause MCB Outdoor Sites a. Unbalance power consumption b. Insufficient PLN capacity c. PLN Problem :Low Voltage PLN, Phase failure
2.2.2
MCB PLN & Main ACPDB A. Cause MCB trip Indoor Sites a. Short Circuit b. Unbalance power consumption c. Air Conditioning problem; high AC current (out off manufacture standard) d. Insufficient PLN capacity e. PLN Problem :Low Voltage PLN, Phase failure B. Cause MCB Outdoor Sites a. Unbalance power consumption b. Insufficient PLN capacity c. PLN Problem :Low Voltage PLN, Phase failure Location : ACPDB Indoor sites Cause MCB Trip : a. Short circuit at MCB use for Air Conditioning controller. b. Short circuit at MCB use for Air Conditioning
PAGE 36
2.2.3
Trip of MCB Utility ACPDB Location
: ACPDB Indoor sites
Cause MCB Trip
:
a. Short circuit at MCB use for Air Conditioning controller. b. Short circuit at MCB use for Air Conditioning
2.2.4
MCB DCPDB Location
: Rectifier/PBC 6500 Indoor sites
Cause MCB Trip
: Insufficiency rate of MCB DCPDU (19” rack) .
2.3
Analysis
2.3.1
Short Circuit A short circuit between phase - neutral due to the destruction of AC Contactor, outdoor unit, lamp, dc fan, rectifier or all equipment that connected to power. This results in an excessive electric current (over current), and potentially causes circuit damage, overheating, fire or explosion In mains circuits, short circuits are most likely to occur between two phases, between a phase and neutral or between a phase and earth (ground). Such short circuits are likely to result in a very high current and therefore quickly trigger an over current protection device.
2.3.2
Unbalance Power Consumption Indoor: Configuration of connecting power Air Conditioning, Rectifier/PBC module unbalance to all phase, It is making power for each phases are not same or higher than MCB PLN Unbalancing Configuration of power - Indoor Phase R
S
Air conditioning
√
√
Rectifier / PBC
2 unit
1 unit
Lamp, others
T
Remark
1 unit
√
Note: √ = power connection
PAGE 37
Outdoor: Configuration of connecting power PSU module unbalance to all phase, It is making power for each phases are not same or higher than MCB PLN Unbalancing Configuration of power - Outdoor Phase R
S
T
PSU RBS 2G
2 unit
1 unit
1 unit
PSU RBS 3G
1 unit
1 unit
1 unit
Lamp, others
Remark
√
Note: √ = power connection
2.3.3
Air Conditioning Problem Some problems with the Air Conditioning are: The high AC current Air Conditioning cause by problem at Air Conditioning outdoor unit. Short circuit Air Conditioning outdoor unit The high AC current Air Conditioning has make insufficiency PLN MCBm and short circuit make PLN MCB and Air Conditioning MCB trip
2.3.4
Insufficiency PLN Capacity Indoor • Location : sites with PBC 6500 • Cause : Insufficiency PLN capacity • Description : Indoor site use PBC 6500 o PSU : 4x1400 watt o Battery : 3x100Ah o PLN : 10.6 kVA (MCB 3x16A) o Air Conditioning : non Inverter
PAGE 38
Configuration of power – Indoor Phase Air conditioning PBC 6500
R
S
√
√
1 unit
1 unit
Lamp, others
T
Remark
2 unit
√
Current Analysis Full load Phase R
S
Air Conditioning
1892
1892
RBS 2116
1879
1879
Lamp
T
Unit VA
3757
VA
125
VA
Voltage Total
210
210
210
Volt
18
18
18
Amp
PLN MCB
16
16
16
Amp
Note: Will be trip at full consumption
Outdoor • • • •
Location : sites with 2G RBS 2116 Cause : Insufficiency PLN capacity due 4 installed PSU Description : Outdoor site RBS 2G 2116 o PSU : 4x1520 watt o Battery : 4x100Ah o PLN capacity : 10.6 kVA (MCB PLN 3x16A)
PAGE 39
Configuration of power - Outdoor Phase PSU RBS 2G
R
S
T
2 unit
1 unit
1 unit
Lamp, others
Remark
√
Current Analysis Full load Phase
RBS 2116
R
S
T
Unit
3757
1879
1879
VA
125
VA
210
210
Volt
Lamp Voltage
210
Total
18
9
10
Amp
PLN MCB
16
16
16
Amp
Note: Will be trip at full consumption
2. • Location : sites with 2G 3G (RBS 2116 + RBS 3116/3107) • Cause : 4 installed PSU • Description : Outdoor site RBS 2G 3G (RBS 2116 + RBS 3116) o PSU RBS 2G : 4x1520 watt o Battery RBS 2G : 4x100Ah o PSU RBS 3G : 3x1400 watt o Battery RBS 3G : 2x100Ah o PLN capacity : 13.2 kVA (MCB PLN 3x20A)
PAGE 40
Configuration of power - Outdoor Phase R
S
T
PSU RBS 2G
2 unit
1 unit
1 unit
PSU RBS 3G
1 unit
1 unit
1 unit
Lamp, others
Remark
√
Current Analysis Full load Phase R
S
T
Unit
RBS 2116
3757
1879
1879
VA
RBS 3116
1730
1730
1730
VA
125
VA
Lamp Voltage
210
210
210
Volt
Total
26
17
18
Amp
PLN MCB
20
20
20
Amp
Note: Will be trip at full consumption
3
• Location : sites with 2G RBS 2116 • Cause : Insufficiency PLN capacity due 4 installed PSU 2G • Description: Outdoor site (RBS 2116 + RBS 3116+ Nobi TRM) o PSU RBS 2G : 3x1520 watt o Battery RBS 2G : 4x100Ah o PSU RBS 3G : 3x1400 watt o Battery RBS 3G : 2x100Ah o Nobi TRM : 2x2000 watt o Battery Nobi TRM : 2x100Ah o PLN capacity : 13.2 kVA (MCB PLN 3x20A)
PAGE 41
Configuration of power – Outdoor Phase PSU RBS 2G
R
S
T
1 unit
1 unit
1 unit 1 unit
PSU RBS 3G
1 unit
1 unit
Rectifier Nobi TRM
1 unit
1 unit
Lamp, others
Remark
√
Current Analysis Full load Phase R
S
T
Unit
RBS 2116
1879
1879
1879
VA
RBS 3107
1730
1730
1730
VA
Nobi TRM
1167
1167
0
VA
Lamp
125
VA
Voltage Total
210
210
210
Volt
23
23
17
Amp
PLN MCB
20
20
20
Amp
Note: Will be trip at full consumption
2.3.5
PLN Problem; Phase Failure, Low Voltage Cause
: PLN voltage drop bellow 190V AC
Description : PLN Voltage drop (Below 190V AC) led to increase AC current and PLN capacity is not sufficient to make power requirement.
PAGE 42
Current Analysis Full load (Nominal Voltage)
Current Analysis Full load (Under Voltage) Phase
Phase R
S
T
Unit
RBS 2116
1879
1879
1879
VA
RBS 3116
1730
1730
1730
Lamp
R
S
T
Unit
RBS 2116
1879
1879
1879
VA
VA
RBS 3116
1730
1730
1730
VA
125
VA
Lamp
125
VA
Voltage
210
210
210
Volt
Voltage
180
180
180
Volt
Total
17
17
18
Amp
Total
20
20
21
Amp
PLN MCB
20
20
20
Amp
PLN MCB
20
20
20
Amp
- High AC Current at under voltage, makes PLN MCB not sufficient. - PLN MCB will be trip
2.3.6
Short Circuit at Air Conditioning Controller Short circuit location :
Air Conditioning controller using relay Omron MY 2
Cause
the connection R phase and S phase as controller to close
:
Description: There are Air Conditioning controller designs: a. Air Conditioning controller relay 1-phase b. Air Conditioning controller relay 2-phase using relay Omron MY 2 c. Air Conditioning controller relay 2-phase using CAD 32 M7
PAGE 43
Relay Omron MY 2
CAD 32 M7
Air Conditioning controller using relay Omron willing to use 2-phase for the work of Air Conditioning. The advantage using 2-phase controller is if one phase is off the other phase will be backup. Since use 2-phase to controller Air Conditioning than there will be 2 voltages into relay. The relay Omron found connection 2-phase is to narrow, and if the 2-phase are start at the same time it cause short circuit than MCB Air Conditioning will trip
2.3.7
Short Circuit at Air Conditioning Short circuit location
: Air Conditioning outdoor unit
Cause
: Short of body Air Conditioning
Description
:
Short circuit because Air Conditioning often switch off
2.3.8
MCB Trip at DOU for MCB DCPDU (19” rack) Location MCB Trip : DOU 2x10A Cause
: Insufficient of MCB rate as power source DCPDU (19” rack)
Description
:
Power Line Connection: PAGE 44
›
DOU 1x125A connected to DCPDB RBS-----ÆConnected to RBS 2G
›
DOU 2x10A connected to TRM 19” rack (via DCPDU) o Connected AMM20p o Connected exhaust fan
Power Analysis: Total Power consumption = 500 watt ( -48V; 11 Amp) TRM Amm20p (5 radio) = 300 watt DC fan = 200 watt
Picture: Power cable connection
PAGE 45
3
Action Taken Recommendation
3.1
Check Installation Check tightened of power cable connection Check for short circuit: ¾
Use buzzer (AVO meter) to no short circuit at the system KWH, ACPDB
¾
Measure at MCB Air Conditioning, MCB Lamp, etc
¾
Connection one probes to neutral bar and other toon top MCB connection
¾
“biiiiiiiiip” sound mean there are short circuit
3.2
Balancing Power Consumption
3.2.1
Indoor
Connected Air Conditioning power cable to R phase and S phase
Maximum 4 unit PSU/Rectifier module and connected with configuration; 1 unit at R phase, 1 unit at S phase, 2 unit at T phase Configuration of power – Indoor Phase Air conditioning PBC 6500 / Rectifier
R
S
√
√
1 unit
1 unit
T
Remark
2 unit
Lamp, others
√
Procedure to balancing power consumption: ¾ Turn on both Air Conditioning, wait until outdoor unit are working ¾ Measure current and voltage for R phase, S phase and T phase ¾ Check power connection of Air Conditioning: o 1 unit at R phase, 1 unit at S phase, 1 unit at T phase (if available) ¾ Check power connection of rectifier module or PBC 6500 PSU : o Maximum 4 unit PSU/Rectifier o Configuration; 1 unit at R phase, 1 unit at S phase, 2 unit at T phase o If available 5 PSU/module removed or unplug, make sure no alarm appear
PAGE 46
3.2.2
Outdoor Maximum number PSU at RBS 2G and 3G are = 3 unit Incase there Nobi rectifier enclosure the maximum rectifier module = 3 unit Table configuration PSU connection Configuration of power – Outdoor Phase PSU RBS 2G
R
S
T
1 unit
1 unit
1 unit 1 unit
PSU RBS 3G
1 unit
1 unit
Rectifier Nobi TRM
1 unit
1 unit
Lamp, others
Remark
√
Procedure balancing power ¾
Using Clamp- Ampere Meter to measure AC current for R phase, S phase and T phase
¾
Check PLN MCB ratting (PLN Capacity)
¾
Check power connection of rectifier module or RBS PSU: o
o
PLN 6,6 kVA (MCB 3x10A),
RBS 2G (3 PSU) or
Nobi TRM (2-3 mdl)
PLN 10.6 kVA (MCB 3x16A),
o
o
PLN 13.2 kVA (MCB 3x20A),
RBS 2G (4 PSU),
RBS 2G (3 PSU) + RBS 3G (3 PSU)
PLN 16.5 kVA (MCB 3x25A),
¾
RBS 2G (3 PSU) + Nobi TRM (2 mdl)
RBS 2G (3 PSU) + RBS 3G (3 PSU) +Nobi Rectifier (3 PSU)
Check MCB ratting at ACPDB o
MCB for RBS 2G, RBS 3G and Nobi Rectifier
o
MCB 3x16A (minimum)
o
MCB 3x20A (recommendation)
PAGE 47
¾
Site 2G 3G with PLN capacity 13.2 kVA, RBS 2G have 4 PSU, as temporary solution do unplug 1PSU (PSU number 4), with no alarm appear
¾
Site 2G 3G Nobi Rectifier and Nobi TRM with PLN capacity 13.2 kVA, as temporary solution do unplug 1PSU RBS 2G (PSU number 1) and Unplug 1 PSU RBS 3G (PSU number 2), with no alarm appear
Configuration of power – Outdoor Phase R
S
T
PSU RBS 2G
0 unit
1 unit
1 unit
PSU RBS 3G
1 unit
0 unit
1 unit
Rectifier Nobi TRM
1 unit
1 unit
1 unit
Lamp, others
Remark
√
Current Analysis Full load Phase R
S
T
Unit
RBS 2G
1879
1879
0
VA
RBS 3G
1730
0
1730
VA
0
1167
1167
VA
Nobi TRM Lamp
0
VA
Voltage
208
200
198
Volt
Total
17
15
15
Amp
PLN MCB
20
20
20
Amp
PAGE 48
3.3
PLN Capacity
3.3.1
PLN Capacity Indoor Sites 1. PLN 10.6 kVA (MCB PLN 3x16A) a.
Air Conditioning
: 2 PK inverter (AC current 7.4A ; 220V AC)
b.
Rectifier
: 2x200 watt or 3x2000 watt
Current Analysis Full load Phase R
S
Air Conditioning
1628
1628
Rectifier
1069
1069
Lamp
T
Unit VA
1069
VA
125
VA
Voltage
210
210
210
Volt
Total
13
13
6
Amp
PLN MCB
16
16
16
Amp
PAGE 49
2. PLN 13.2 kVA (MCB PLN 3x20A) a. Air Conditioning
:
b. Rectifier or PBC 6500 :
2 PK non inverter (AC current 10.6A ; 220V AC) maximum 4 unit
Current Analysis Full load Phase R
S
Air Conditioning
2438
2438
Rectifier
1069
1069
Lamp
3.3.2
T
Unit VA
2138
VA
125
VA
Voltage
210
210
210
Volt
Total
17
17
11
Amp
PLN MCB
20
20
20
Amp
PLN Capacity Outdoor Sites 1. PLN 6.6 kVA (MCB 3x10A),
RBS 2G (3 PSU) or
Nobi TRM (2-3 mdl)
PAGE 50
Configuration of power – Outdoor Phase
PSU RBS 2G
Current Analysis Full load Phase
R
S
T
1 unit
1 unit
1 unit
Lamp, others
√
RBS 2116
R
S
T
Unit
1879
1879
1879
VA
125
VA
Lamp Voltage
210
210
210
Volt
Total
9
9
9
Amp
PLN MCB
10
10
10
Amp
2. PLN 10.6 kVA (MCB 3x16A),
RBS 2G (3 PSU) + Nobi TRM (2 mdl)
Configuration of power – Outdoor Phase
Current Analysis Full load Phase
R
S
T
PSU RBS 2G
1 unit
1 unit
1 unit
Nobi TRM
1 unit
1 unit
Lamp, others
√
R
S
T
Unit
RBS 2116
1879
1879
1879
VA
Nobi TRM
1297
1297
Lamp
VA 125
VA
Voltage
210
210
210
Volt
Total
15
15
10
Amp
PLN MCB
16
16
16
Amp
PAGE 51
3. PLN 13.2 kVA (MCB 3x20A),
RBS 2G (4 PSU),
RBS 2G (3 PSU) + RBS 3G (3 PSU)
Configuration of power – Outdoor Phase
Current Analysis Full load Phase
R
S
T
PSU RBS 2G
1 unit
1 unit
1 unit
PSU RBS 3G
1 unit
1 unit
1 unit
Lamp, others
√
R
S
T
Unit
RBS 2116
1879
1879
1879
VA
RBS 3116
1370
1370
1370
VA
125
VA
Lamp Voltage
210
210
210
Volt
Total
18
18
18
Amp
PLN MCB
20
20
20
Amp
4. PLN 16.5 kVA (MCB 3x25A),
RBS 2G (3 PSU) + RBS 3G (3 PSU) + Nobi Rectifier (3 PSU)
Configuration of power – Outdoor Phase
Current Analysis Full load Phase
R
S
T
PSU RBS 2G
1 unit
1 unit
1 unit
PSU RBS 3G
1 unit
1 unit
1 unit
Nobi TRM
1 unit
1 unit
Lamp, others
√
R
S
T
Unit
RBS 2116
1879
1879
1879
VA
RBS 3116
1370
1370
1370
VA
Nobi TRM
1297
1297
125
VA
Voltage
210
210
210
Volt
Total
24
24
18
Amp
PLN MCB
25
25
25
Amp
PAGE 52
3.4
Air Conditioning Maintenance
3.4.1
Measurement AC current for Air Conditioning Procedure: ¾ Turn on Air Conditioning, wait until the outdoor unit is working ¾ Take Clamp-Ampere Meter to measure AC current at line for Air Conditioning only ¾ AC Current allowed <=13 Amp ¾ If more than 13 amp indication Air Conditioning failure , please call FM MS
3.4.2
Air Conditioning Phase Controller Air Conditioning controller 2-phase using relay Omron MY 2, where MCB 1x4A at R-phase and MCB 1x4A S phase • Temporary solution :
›
Switch off one of MCB connected to relay
›
For standard switch off MCB 1x4A at S phase
• Recommendation Solution
›
Additional timer delay equipment to delay Phase S connected to Relay
›
Band/Type
: Omron / H3CR
PAGE 53
›
3.5
Wiring diagram
Power Source for DCPDU at 19” Rack Power capacity for DCPDU at 19” rack: MCB ratting at Rectifier / PBC 6500:
› MCB 2x25A (minimum) › MCB 2x32A (recommendation) Recommendation for Indoor site configuration: ›
DC Power source
: PBC 6500
›
PSU
: 4x1400 watt
›
Battery
: 3x100Ah
›
DOU
: DOU 1x125A + DOU 2x10A
›
Load
:
o
RBS 2G – RBS 2216/2206
o
TRM Amm20p
o
Exhaust fan
PAGE 54
›
Procedure: o
Change power source for TRM 19” rack to DOU 1x125A
o
DOU 1x125A connected to DCPDB RBS •
Connected to RBS 2G
•
Connected to DCPDU TRM Connected AMM20p
♦
Connected Exhaust fan
Exhaust fan and EAS connected power to DOU 2x10A
DOU 2x10A connected to: •
o
♦
Exhaust fan
Wiring Power connection
Recommendation – Power Connection
PAGE 55
3.6
Exhaust Fan Status Problem
:
High Temperature
Cause
:
Exhaust fan not working properly due external alarm panel is broken
Description : Exhaust fan is the emergency fan to circulate the hot air out of shelter when the Air Conditioning is not working properly. The exhaust fan is trigger by temperature sensor at external alarm system (EAS), if the sensor detection high temperatures (set 30oC) in the shelter than the fan will working and send alarm to NOC (Alarm “high temperature”)
Temporary Recommendation: If in the site found EAS is broken 1. Use phase failure as trigger working of the exhaust fan Procedure: o
Removed power connection for exhaust fan from relay EAS to relay phase failure
o
Use relay R phase failure and connection DC power of exhaust fan
R-phase
PAGE 56
Recommendation Solution: Additional thermostat for triggering exhaust fan start relay The thermostat will bet at 30°C for trigger the relay and send alarm “high temperature”
4
Reference 2008-09-16 - 198/1551-LZA 701 0001 Uen A Technical Description RBS 2111 EID-08:013998 Uen Rev. A Petunjuk Instalasi RBS 2000 Ericsson Indonesia EID-08:017130 Uen Rev. A Petunjuk Instalasi RBS 3000 Ericsson Indonesia EID-09:010738 Uen Rev. A Configuration of Sites Using The Outdoor Enclosure (NOBI)
PAGE 57
4 Enclosure
PAGE 58
4.1
TRANSMISSION AND RBS DATA REPORT
SITE BUKIT PAMULANG MEGAH NTS Project
Contents 1
Abstract ................................................................................................60
2
Problem .................................................................................................60
3
Alarm & Data Capture ...........................................................................60
3.1
Alarm & Data Capture Transmission.....................................................60
3.2
Alarm & Data Capture RBS...................................................................61
4
Actual Configuration ..............................................................................61
4.1
Actual Configuration Transmission........................................................61
4.2
Actual Configuration RBS......................................................................61
5
Analyze..................................................................................................62
6
Solution Recommendation ....................................................................62
7
Supporting Document............................................................................62
PAGE 59
1. Abstract This document describes reporting site BTTG005 Bukit Pamulang Megah. 2. Problem BFU Problem: (from TT-20090923-00068). Action Taken by MS: FM replaced BFU module.
3. Alarm and Data Capture 3.1 Alarm and Data Capture Transmission Alarm List Capture;
Picture 1
RSL Capture
PAGE 60
3.2 Alarm and Data Capture RBS Alarm List Capture;
Picture 2
Alarm List
4. Actual Configuration 4.1 Actual Configuration Transmission AMM Type
: AMM 2p
Configuration network
: 1+0 ML TN 18 GHz
Hop Name
: BTTG005 B Pamulang Megah to JBKD052 Wr Poncol.
Software Baseline
: R7M06 (Release 2.4.10)
4.2 Actual Configuration RBS RBS Type
: 2116
Configuration network
: 2/2/2
Site Name
: BTTG005 Bukit Pamulang Megah.
PAGE 61
5. Analyze Transmission: No Transmission problem found. RBS: When BFU Module was fault, The RBS do not have Battery backup system. And DC source to transmission equipment was disconnected. It is hardware faulty.
6. Solution Recommendation FM already changed the BFU with the new one. Now, The RBS have been in service and have stable condition.
7. Supporting Document
BTTG005 B Pamulang Megah (TRM).rar
BTTG005 B Pamulang Megah (RBS).rar
PAGE 62
4.3
POWER DATA REPORT
SITE BUKIT PAMULANG MEGAH
NTS Project Contents 1
Introduction....................................................................................................64
1.1
Purpose .........................................................................................................64
1.2
Reference......................................................................................................64
1.3
Site Location .................................................................................................64
2
Power Data....................................................................................................65
2.1
kWh Panel .....................................................................................................65
2.2
ACPDB ..........................................................................................................65
2.3
Power Supply ................................................................................................66
3
Problem Identification....................................................................................66
4
Analysis .........................................................................................................67
4.1
Check Balancing Power ................................................................................67
5
Recommendation Solution ............................................................................68
6
Supporting Document ...................................................................................68
PAGE 63
1
Introduction
1.1 Purpose This document explains about root cause analysis of site problem 1.2 Reference EID-08:013998 Uen Rev. A Petunjuk Instalasi RBS 2000 Ericsson Indonesia EID-08:017130 Uen Rev. A Petunjuk Instalasi RBS 3000 Ericsson Indonesia 1.3 Site Location Site Name
: BTTG 005, Bukit Pamulang Megah
PAGE 64
2
Power Data
2.1 KWh Panel Description MCB Input Brand and Capacity Surge Protection Single Phase Mains Input Voltage (R‐N/S‐N/T‐N) Three Phase Mains Input Voltage (R‐S/S‐T/R‐T) N‐G Voltage Current for Phase R Current for Phase S Current for Phase T
Value MG; 3xCL20A OBO type B / 3+1 ( 3X255V AC 50kA & 1XC255V AC 125kA) 209.4/217.3/210.2 361.8/382.6/3721.9 0.4V 2.1A 2.5A 2.0A
2.2 ACPDB Description ACPDB PANEL Check MCB Input Brand and Capacity Check Surge Protection Check MCB Input Capacity for RBS Outdoor R phase Check MCB Input Capacity for RBS Outdoor S phase Check MCB Input Capacity for RBS Outdoor T phase
Value MG; 3x63A OBO type C /3+1 ( 3XV20C & 1XC25‐B+C) 32A 32A 32A
PAGE 65
2.3 Power Supply
Description Rectifier Type (brand, type of Power System)
2G: PSU RBS 2116
Rectifier Capacity (qty module x capacity per module)
2G: 3xPSU 1520 watt
MCB Input (Qty x Ratting MCB, Brand/Type in ACPDB) MCB Input (Qty x Ratting MCB, Brand/Type in Rectifier) Surge Protection Type and Condition (arrester brand/type) Input Current Phase R (ACPDB to Rectifier) Input Current Phase S (ACPDB to Rectifier) Input Current Phase T (ACPDB to Rectifier) Load Configuration (RBS/TRM/DXX) Load Current Total
3X32A MERLIN GERIN NA NA 2.1A 2.5A 2.0A RBS 2G AMM2P 6.7A
Battery Brand and Type Battery Capacity (qty bank x capacity Ah) MCB battery ‐ 1(Brand, ratting ) MCB battery ‐ 2(Brand, ratting ) MCB battery ‐ 3(Brand, ratting ) MCB battery ‐ 4(Brand, ratting )
3
Value
Fiamm FIT 100 4X100Ah BFU +24/250A NA NA NA
Problem Identification No power issue
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4
Analysis
4.1 Check Balancing Power Configuration Load Rebalancing Configuration of power Phase PSU RBS 2116
Remark
R
S
T
1 psu
1 psu
1 psu
Lamp
√
Power balancing analysis average load: Current Analysis average load Phase R S PSU RBS 2116 2.1 2.5 Lamp
T 2.0
Unit Amp Amp
Total
2.1
2.5
2.0
Amp
PLN MCB
20
20
20
Amp
Power balancing analysis full load: Current Analysis Full load Phase
RBS 2116
R
S
T
Unit
1879
1879
1879
VA
Lamp Voltage
125
VA
210
217
210
Volt
Total
9
9
9
Amp
PLN MCB
20
20
20
Amp
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5
Recommendation Solution
•
Keep balancing phase R, phase S, phase T with changing connection phase power PSU module Connected PSU’s RBS 2116 with configuration; 1 module at R phase, 1 module at S phase, 1 module at T phase
•
Rebalancing Configuration of power Phase R
S
T
PSU RBS 2116
1 mdl
1 mdl
1 mdl
PSU RBS 3116
1 mdl
1 mdl
1 mdl
Lamp
6
Remark
√
Supporting Document
BTTG 005 Bukit Pamulang Megah (Power).rar
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