Table of Content No.
Title
1.
Introduction to Chlorobenzene
2.
Process Description & Process Analysis
3.
Plant Location & Site Selection
4.
Process Flow Diagram (PFD)
5.
Workbook
6.
Material & Energy Balance
7.
Pinch Calculation
8.
Major Equipment Design Piping & Instrumentation Diagram (P&ID)
9.
Plant Layout
10. Capital & Manufacturing Cost 11. Hazard Analysis (Environmental Considerations) 12. References 13. Appendices
Page
Introduction to Chlorobenzene
Chlorobenzene is an aromatic organic compound with the chemical formula C6H5Cl. It is made from chlorine and benzene trough chlorination process. It is a colorless volatile flammable liquid with an almond odor and used as a solvent and in the production of phenol and DDT and other organic compounds. As a group, chlorobenzenes are much less reactive than the corresponding chlorinated derivatives of alkyl compounds and are similar in reactivity to the vinyl halides. They are very stable to nucleophilic attack due to resonance in the molecule resulting in a shortening of the carbon-chlorine bond distance and an increase in bond strength.
Chlorobenzenes are not attacked by air, moisture, or light. at room temperature and pressure. Chlorobenzenes also are not affected by steam, prolonged boiling with aqueous or alcoholic ammonia, other alkalis, hydrochloric acid, or dilute sulfuric acid. To form phenols, hydrolysis takes place at elevated temperatures in the presence of a catalyst.
Hot concentrated sulfuric acid attack chlorobenzenes to form chlorobenzene-p-sulfonic acid. Nitric acid will react with chlorobenzenes at the meta- and parapositions on the ring to form chloronitrobenzenes at -30°C to 0°C (-22°C to 32°F). At higher temperatures, the nitration will either proceed further to form a dinitrochloro-compound, chloronitrophenol, or a nitrophenol.1 Chlorobenzenes are attacked by electrophilic agents. Para- is predominantly substitution for
monochlorobenzene with some ortho-substitution. Electrophilic substitution might be resisted by the higher chlorinated benzenes but can be substituted under extreme conditions.
Some free radical reactions undergo on Chlorobenzenes. Formation of organometallic compounds (grignards, aryl-lithium compounds) provides a useful route to many organic intermediates. Photochemical transformations occur on irradiation of chlorinated benzenes, which are much less stable to radiation than benzene. When subjected to ultraviolet irradiation or pulse hydrolysis in solution, chlorobenzenes may polymerize to biphenyls, chloronaphthalenes, or more complex products. The ability of chlorobenzenes to undergo wide varieties of chemical reactions makes chlorinated benzenes useful as reactants in numerous commercial processes to produce varied products. All chlorinated derivatives of benzene are soluble in lipids. Partition coefficient data for chlorobenzenes show an increase in partition coefficient with an increase in the degree of chlorination. In general, a positive correlation exists between partition coefficient and degree of bioaccumulation.
Identification Chlorobenzene identification in the commercial industry is listed as below in Table 1.2: Chemical Name
Chlorobenzene
Molecular Structure Synonyms
Monochlorobenzene,
Chlorobenzol,
chloride, Benzene chloride IUPAC Name
Chlorobenzene
Classification
Aryl halides
UN Identification Number
UN1134
Hazardous Waste ID No.
D001, U037, D021
Formula
C6H5Cl
Codes/Label Flammable
Class 3
Phenyl
The physical and chemical properties of chlorobenzene can be concluded in the Table 1.1. Properties
Value
Molecular Weight
112.56G
Normal Freezing Point
-45.58 °C
Vapor Pressure
1.17 kPa
Normal Boiling Point,
131.69 °C
Liquid Density
1.11 g/cm3
Reference temperature for liquid
20 °C
Density
Uses Chlorobenzene is usually used as a solvent for pesticide formulations, diisocyanate manufacture, and degreasing automobile parts and for the production of nitrochlorobenzene. Furthermore, chlorobenzene can be used as intermediate in the phenol and dichlorodiphenyltrichloroethane (DDT) production.
Health The United States Environmental Protection Agency (EPA) stated that the exposure of the chlorobenzene to human being appears to be primarily occupational. EPA has listed some information on the health hazard information of chlorobenzene. Acute Effects: Acute exposure to chlorobenzene may cause redness and inflammation of the eyes and eyelids, runny nose, sore throat, redness and irritation of the skin, headache, dizziness, drowsiness, incoherence, ataxia, and loss of consciousness. Furthermore, it also may cause twitching of the extremities, deep and rapid respiration, and irregular heartbeat. Respiratory arrest may follow.
1. A child who ingested chlorobenzene became unconscious and cyanotic and had muscle spasms but recovered completely. 2. Acute inhalation exposure of animals to chlorobenzene produced narcosis, restlessness, tremors, and muscle spasms. 3. Acute animal tests in rats, mice, rabbits, and guinea pigs have demonstrated chlorobenzene to have low acute toxicity by inhalation and moderate acute toxicity from oral exposure. Chronic Effects (Non-cancer): Long term exposure to chlorobenzene may cause chronic central nervous system (CNS) depressions which are headache, dizziness, and somnolence. Based on effects seen in animals, chronic exposure may cause elevated liver enzymes, enlarged and tender liver, and blood, pus, or protein in the urine. Prolonged or repeated skin contact may cause skin burns. 1. Chronic exposure of humans to chlorobenzene affects the CNS. Signs of neurotoxicity include numbness, cyanosis, hyperesthesia (increased sensation), and muscle spasms. 2. Headaches and irritation of the mucosa of the upper respiratory tract and eyes have also been reported in humans chronically exposed via inhalation. 3. The CNS, liver, and kidneys have been affected in animals chronically exposed to chlorobenzene by inhalation. 4. Chronic ingestion of chlorobenzene has resulted in damage to the kidneys and liver in animals. 5. EPA has calculated a provisional Reference Concentration (RfC) of 0.02 milligrams per cubic meter (mg/m3) for chlorobenzene based on kidney and liver effects in rats. The RfC is an estimate (with uncertainty spanning perhaps an order of magnitude) of a continuous inhalation exposure to the human population (including sensitive subgroups), that is likely to be without appreciable risk of deleterious noncancer effects during a lifetime. It is not a direct esimator of risk but rather a reference point to gauge the potential effects. At exposures increasingly greater than the RfC, the potential for adverse health effects increases. Lifetime exposure above the RfC does not imply that an adverse health effect would necessarily occur. The provisional RfC is a value that has had some form of Agency review, but it does not appear on IRIS.
6. The Reference Dose (RfD) for chlorobenzene is 0.02 milligrams per kilogram body weight per day (mg/kg/d) based on histopathologic changes in the liver in dogs. 7. EPA has medium confidence in the study on which the RfD was based because it provided both a no-observed-adverse-effect level (NOAEL) and a lowest-observedadverse-effect level (LOAEL) and incorporated several biochemical and biological endpoints; medium confidence in the database because several subchronic, chronic, developmental, and reproductive toxicity studies provide supportive data, but they did not give a complete assessment of toxicity; and, consequently, medium confidence in the RfD. Reproductive/Developmental Effects: 1. No information is available on the reproductive or developmental effects of chlorobenzene in humans. 2. Chronic inhalation exposure of rats to chlorobenzene did not adversely affect reproductive performance or fertility. However, a slight increase in the incidence of degenerative testicular changes was observed. 3. Chlorobenzene does not appear to be a developmental toxicant and did not produce structural malformations in rats and rabbits acutely exposed via inhalation. Cancer Risk: 1. No information is available on the carcinogenic effects of chlorobenzene in humans. 2. In a National Toxicology Program (NTP) study of rats and mice exposed to chlorobenzene via gavage (experimentally placing the chemical in the stomach), an increased incidence of neoplastic nodules of the liver in high dose male rats was observed, but not in female rats or male or female mice. 3. EPA has classified chlorobenzene as a Group D, not classifiable as to human carcinogenicity.
Handling A worker who handles chlorobenzene should wear protective clothing such as gloves, boots, aprons, and gauntlets to prevent skin contact with chlorobenzene. Eyewash fountains and emergency showers should be available within the immediate work area whenever the potential exists for eye or skin contact with chlorobenzene. Contact lenses should not be worn if the potential exists for chlorobenzene exposure. Use of respirator also should be considered for handling the chlorobenzene. Good industrial hygiene practice requires that engineering controls be used to reduce workplace concentrations of hazardous materials to the prescribed exposure limit. Respirators must be worn if the ambient concentration of chlorobenzene exceeds prescribed exposure limits. Spill and leaks In the event of spill or leak involving chlorobenzene, persons not wearing protective equipment and clothing should be restricted from contaminated areas until cleanup is complete. The following steps should be undertaken following a spill or leak: 1. Do not touch the spilled material. 2. Notify safety personnel. 3. Remove all sources of heat and ignition. 4. Ventilate potentially explosive atmospheres. 5. Water spray may be used to reduce vapors, but the spray may not prevent ignition in closed places. 6. For small dry spills, use a clean non-sparking shovel and gently place the material into a clean, dry container, cover and remove the container from the spill area. 7. For small liquid spills, absorb with sand or other non-combustible absorbent material and place into closed container for later disposal. 8. For large liquid spills, build dikes far ahead of the spill to contain the chlorobenzene for later reclamation or disposal.
Storage Chlorobenzene should be stored in a cool, dry, well-ventilated area in tightly sealed containers that are labeled in accordance with OSHA’s hazard communication standard (29 CFR 1910.1200). Outside or detached storage is preferred. Inside storage should be in a standard flammable liquid storage room. Containers of chlorobenzene should be protected from physical damage and should be stored separately from oxidizers, dimethyl sulfoxide, silver perchlorate, other incompatible material, heat, sparks, and open flame. Only non-sparking tools may be used to handle chlrobenzene. To prevent static sparks, containers should be grounded and bonded for transfers. Because containers that formerly contained chlorobenzene may still hold product residues, they should be handled appropriately.
Market Analysis of Chlorobenzene Demand and consumption pattern Only three of many possible products resulting from the chlorination of benzene continue to have any
large-volume
applications—monochlorobenzene,
o-dichlorobenzene
and
p-
dichlorobenzene—and they are the major focus of this report. These three products combined account for as much as 92–96% of the total chlorobenzenes market. Other chlorobenzenes that have commercial applications but are not produced on a large scale include m-dichlorobenzene, trichlorobenzenes, tetrachlorobenzenes and hexachlorobenzene. Market information on these products is included in the report where available. The following pie chart shows consumption of chlorobenzenes in the major regions:
Monochlorobenzene accounts for nearly 73% of total chlorobenzene consumption. China is the world's largest manufacturer and consumer, accounting for nearly 82% of total consumption in the four major regions shown below. Monochlorobenzene represents about 70% of chlorobenzene consumption in Western Europe, and 52% of consumption in the United States, but only 10% in Japan, where p-dichlorobenzene is a larger factor than in the other regions. Nitrochlorobenzene is the most significant end use for monochlorobenzene. Nitrochlorobenzenes are consumed as intermediates in the manufacture of dyes and pigments, rubber-processing chemicals, pesticides (e.g., parathion and carbofuran), pharmaceuticals (e.g., acetaminophen) and other organic chemicals. Monochlorobenzene has been used for the synthesis of diphenyl ether (also known as diphenyl oxide or DPO) and is increasing in demand for sulfone polymers. o-Dichlorobenzene is a chemical intermediate consumed mostly for 3,4-dichloroaniline in the United States, South America and Western Europe and as an herbicide intermediate in Japan. Worldwide, p-dichlorobenzene is used primarily as a raw material for polyphenylene sulfide (PPS) resins, for deodorant blocks for indoor air, and for moth control. Polyphenylene sulfide is a growing high-performance polymer that is produced only in the United States, Japan and China. PPS resin production has increased rapidly both in the United States and Japan over the past five years and has become significant in China since 2010. PPS production is projected to continue to grow over the next five years, with additional capacity planned in China and the Republic of Korea. There are no producers of PPS resins in Western Europe. The gradual shift in global demand away from industrialized regions and further into developing countries has resulted in a buildup of new chlorobenzene capacity in Asia. China is the world's most diverse market and home to four of the world's five largest producers. It also accounts for an estimated 68–75% of global capacity. With the exception of high-performance polymers, the markets for chlorobenzenes are mature. Demand for chlorobenzenes in more industrialized regions has been on a decline for the past few decades as a result of the substitution of alternative chemistry in the production of such products as phenol, rubber chemicals and moth control agents. Growing environmental concern over usage in herbicides and solvents has additionally contributed to the slow decline. However,
strong growth in China and growing global demand for p-dichlorobenzene have since stabilized this trend, resulting in a moderate, average growth rate of 4% per year for the forecast period. Future Demand for Chlorobenzene The capacity of chlorobenzene in China reached 320 000 t/a at the end of 2003, accounting for 50% of the world total. The output of chlorobenzene in China was around 260 000 tons in 2003. Chlorobenzene is mainly used to produce o- and pnitrochlorobenzene, 2,4-dinitrochlorobenzene and diphenyl ether. It is also used in the synthesis of solvents, pesticides and dyestuffs. The consumption composition of chlorobenzene in 2003 was 73.8% for o- and p-nitrochlorobenzene, 10% for 2,4-dinitrochlorobenzene, 1.7% for diphenyl ether and 14.5% for others. The import and export amounts of chlorobenzene in China are fairly small. The export amount was estimated to be 3 000 tons in 2003. The competition in chlorobenzene and major downstream products is mainly between domestic producers rather than from foreign products. Furthermore, the consumption of chlorobenzene in other sectors is also relatively stable, mainly determined by o a n d p – nitrochlorobenzene production. With the rapid capacity expansion, the production cost of o- and p-nitrochlorobenzene in China has consistently fallen. Foreign countries have slowed down the development of o- and p-nitrochlorobenzene production and mainly depended on the import of downstream fine chemicals derived from o- and p-nitrochlorobenzene such as dyestuffs, pigments, pharmaceuticals and pesticides from China. The export of o- and pnitrochlorobenzene has therefore been promoted. Chlorobenzene will still experience brisk production and sales in China in 2004 and there will be a supply shortage in some areas. If there are no drastic fluctuations in raw material supply, however, the price of chlorobenzene will be kept stable.
Process Description & Process Analysis Continuous process Batch process Raschig process
1. Direct chlorination (Continuous process) C6H6 + Cl2
C6H5Cl + HCl
C6H6 + Cl2
C6H5Cl + HCl
The process begins with a series of small, externally cooled cast iron or steel vessels containing the catalyst (which may consist of Rashig ring of iron or iron wire). The catalyst used is usually Ferric chloride. This can be added as solution in benzene. Chlorine is supplied into each vessel through suitably positioned inlets to maintain a large benzene-to-chorine reaction at all points along the reaction stream. The temperature is maintained about 20
to 40
for this
reaction in order to minimize the production of dichlorobezene which occur at higher temperature. Besides, this range of temperature is the best temperature for production of large amount of monochlorobenzene. This process will produce large amount of monochlorobenzene and small amount of dichlorobenzene. The feed, which are liquid benzene and gaseous chlorine are at temperature 25
and atmospheric pressure then fed to the reactor which operates at 2.4
bars. The reaction is exothermic process. Cooling process is required to maintain the temperature at 40
90% of the HCl formed is first cooled to condense impurities (benzene and
chlorinated product) and then it is scrubbed in a scrubber using refrigerated chlorobenzene. The crude chlorobenzene stream leaving reactor is washed with NaOH solution (20wt%) in order to maintained slightly alkaline to protect downstream equipment from corrosion) in a preneutralizer. The product stream is free from HCl. Then, the product is fed to a Benzene Recovery Column (distillation column). Here, the bottom is almost slightly 100% pure chlorobenzene. The
top contain 98% by weight of benzene and 2% chlorobenzene. All the benzene is recycled to the benzene storage via a purifier. From purifier the monochlorobenzene is sent to the refrigeration system. The bottom contains monochlorobenzene and dichlorobenzene. This bottom product is fed to the chlorobenzene column that may be contain 12-25 trays which operated at 3-7 lb/in2 abs. The temperature may be 100 -200 . The distillate has purity of 99% monochlorobenzene while bottom has purity of 97% dichlorobenzene. This reaction will produce HCI as the side product. All the desired product and undesired product are then fed to the Benzene Recovery Column (distillation column). The advantages of continuous process are, it produce higher amount of monochlorobenzene which is 95% conversion and the process also operate at lower temperature.
2. Batch process In the batch process, benzene is contained in a deep, iron or mild steel vessel lined with lead cooling coils. The catalyst that usually used for this process is FeCl3, is added in a benzene solution. Chlorine is fed to into bottom of the chlorinator through a lead covered at temperature 45
in order to minimize the formation of dichlorobenzene. Then the crude chlorobenzene
stream and HCl stream are collected and treated in the purification and recovery process. For another type of batch process is describe by Faith, Keyes, and Clark’s Industrial Chemicals. The chlorine is bubbled into a cast iron or steel tank containing dry benzene with on percent of its own weight of iron filings. The temperature is maintained at 40°C to 60°C (104°F to 140°F) until density studies indicate that all benzene is chlorinated. Then, the temperature is raised to between 55°C and 60°C (131°F to 140°F) for six hours until the density raises to 1.280g/cm3 (79.91 lb/ft3). The same methods of chlorobenzene purification and HCl recovery in batch form are then employed. At 100% chlorination, the products are 80% of monochlorobenzene, 15 % of p-dichlorobenzene, and 5% of o-dichlorobenzene.
3. Hooker/ Raschiq Process C6H6 + HCl + ½ O2 (AIR) C6H5Cl + H2O
C6H5Cl + H2O
C6H5OH + HCl
This process is conducted at elevated temperature which is in the range of 230 to 270
.
This process involve the reaction between benzene and mixture of hydrochloric acid gas and air in the presence of an oxychlorination catalyst. This catalyst consists of copper and iron chlorides on an inert support. Once-through conversion for this process is limited (10 – 15 percent ) to prevent the excessive formation of polychlorobenzene. The catalyst is put in the beds to prevent damage since this process is exothermic process. In order to control the overall temperature, the benzene is injected at lower temperature. This process is then followed by purification of monochlorobenzene which can be done by fed the product from the reactor into the distillation column which is known as brick-lined column.
The top stream of this column contain water/benzene azeotrope while at the bottom are 1/1 mixture of benzene and chlorobenzenes. The top product which is benzene and water is recycled back into the reactor while the bottom products which are benzene and chlorobenzene is neutralized with caustic soda, washed with water and distillate in two columns to separate the dichlorobenzene, monochlorobenzene and benzene. Then the process is followed by hydrolysis of the monochlorobenzene by steam in the presence of tricalcium phosphate or silica gel base catalyst which can be reactivated periodically to reduce carbon deposited. The formation of dichlorobenzene in the oxychlorination reaction and the polyphenols in the hydrolysis process reduce the yield. The process contains a few disadvantages. The high temperature in the process favours high combustion rates of benzene which cause the reaction uncontrollable. Compare to the other process, this process produce high cost of vapour phase chlorination process which make it become uneconomical process for the production of monochlorobenzene. This process also can only produce small amount of chlorobenzene since this once-through conversion is limited.
Comparison between the three process PROCESS
Raw Material
Reaction Conditions
Reactor
RASCHIQ PROCESS
CONTINUOUS
Benzene
Benzene
Hydrochloric acid
Chlorine
Oxygen (air)
Temperature at range 220 260 and in gas-phase
-
Fixed-Bed Reactor
Temperature at range 20 40
-
and in liquid -phase
Continuous Stirrer Tank Reactor
Catalyst
Advantages
Copper and iron chloride
Large economic
Ferric chloride
advantages because HCl produce in the
labor
hydrolysis of chlorobenzene can be
Economy in steam
High conversion of benzene (95%)
benzene.
Simple operation liquid phase
used for the oxychlorination of
Lower operating
High production of monochlorobenzene
Produce less by
and cooling required
products only
for evaporating and
small amount of
condensing the
dichlorobenzene.
benzene.
Less purification operations.
Disadvantages
Produce many byproducts
High cost of equipments
dichlorobenzene,
material of
tetrachlorobenzene
construction for very
and others.
low temperature.
The benzene
limited,10-15%.
The reaction is uncontrollable because of the high temperature.
High cost of vapour phase chlorination process.
Required special
trichlorobenzene,
conversion is
Has large investment for corrosionresistants hydrochloric acid is highly corrosive
PROCESS
Raw Material
Reaction Conditions
BATCH
Benzene
Chlorine
Temperature at range of 40
- 60
and in
liquid-phase
Reactor
Batch Reactor
Catalyst
Ferric chloride
Advantages
High production of monochlorobenzene compare raschiq process.
Low cost of factory equipment because of the simple design of batch reactor.
Reaction it easy to control due to low temperature.
Disadvantages
Lower conversion compare to continuous (80%).
Produce higher amount of byproducts dichlorobenzene
Only can produce small scale production.
Require strict scheduling and control.
Higher operating labor costs due to equipment cleaning and preparation time.
Many people need to operate the process.
PROCESS SELECTION Based on the review and screening, the most suitable process for the production of the monochlorobenzene is by continuous process. The process was selected because it is more beneficial compare to batch process and Raschig process. The selection is based on a few important criteria that need to be considering in this process. One of the criteria is continuous process can give higher conversion of monochlorobenzene which is 95% conversion. Besides, the temperature used for this process is only between 20 - 40
. At this low temperature, the
operating cost can be reduced because it does not required heating process. Furthermore it is easy to handle the reaction at low temperature and this range of the temperature is the best temperature to produce high amount of the monochlorobenzene. Furthermore, the continuous process also produce high amount of monochlorobenzene and small amount of dichlorobenzene compared to the other two processes that produce dichlorobenzene, tri-chlorobenzene, pentachlorobenzene and also tetra-chlorobenzene. Another criteria is, for this process the benzene that been used is in liquid phase which is cheaper compared if we used benzene in vapor phase. Therefore, it indirectly can reduce the operating cost. Other than that, the continuous process only need a bit of workforce. So, only a few workers need to be hired and it indirectly also can reduce the labor cost.
Review of the process production of monochlorobenzene from benzene and chlorine (from question) Liquid benzene (which must contain less than 30 ppm by weight of water) is fed into a reactor system consisting of two continuous stirred tanks operating in series at 2.4 bar. Gaseous chlorine is fed in parallel to both tanks. Ferric chloride acts as an catalyst produce in situ by the action of the hydrogen chloride on mild steel. Cooling is required to maintain the operating temperature at 328K. The hydrogen chloride gas leaving the reactor is first cooled to condense most of the organic impurities. It then passes to an activated carbon adsorber where the final traces of the impurity are removed before it leaves the plant for use elsewhere. The crude liquid chlorobenzenes stream leaving the second reactor is washed with water and caustic soda solution to remove all the dissolved hydrogen chloride. The product recovery system consists of two distillation columns in series. In the first column (the ―benzene column‖) unreacted benzene is recovered as top product and recycled. In the second (the ―chlorobenzene column‖) the mono- and dichloro-benzenes are separated. The recovered benzene from the first column is mixed with the raw benzene feed, and this combined stream is fed to a distillation column (the ―drying column‖) where water is removed as overhead. The benzene stream from the bottom of the drying column is fed to the reaction system.
Plant Location & Site Selection It is important to have a proper selection of the location of the plant. The geographical location of the plant could give a very strong influence to the success of the plant/industry itself. During the selection of the site of the plant, it is crucial to always keep in mind the objectives of the company. This will lead to a very careful considerations on the various factors that could make the plant to give a big contributions towards its working environment and thus, making it into an economically viable unit. Any mistakes in selecting the plant location could lead to undesired situations or problems to occur, such as; a higher cost and investment, the difficulties in both marketing and transporting of the products, dissatisfaction of the employees and customers, as well as interruptions in the production process and an excessive wastage. Therefore, a complete survey of both the advantages and disadvantages of the various areas should be made prior to selecting the final site/location of the plant. The following are the list of the factors that should be taken into considerations during the selection of the site of the plant: 1. Location, with respect to the marketing area 2. Raw material supply 3. Transport facilities 4. Availability of labour 5. Availability of utilities 6. Availability of suitable land 7. Environmental impact (including the waste/effluent disposal) 8. Local community considerations 9. Climate 10. Political and strategic considerations Other than those listed above, the room for expansion and safe living conditions of the operating plant are also important in the site selection. The following are the details on how the above factors affect the site selection of the plant.
1. Location with Respect to Marketing Area The cost of an industrial land depends on few factors such as the physical characteristic of the land, market economic conditions and most of all its location, with respect to the marketing area. The price of the land site should be as economical as possible to reduce the total investment and construction cost of the plant. It is important to choose the lowest reasonable land price, with good storage and handling infrastructures. The price of the land can be referred to the real estate agency. For materials that are produced in large or bulk quantities, it is important that the proposed plant site should be located as close to the primary market so that the cost of transportation can be maximized. Other considerations include the demand of the product within the area and the availability of the raw materials suppliers should also be taken. 2. Raw Material Supply This is one of the most important factors taken into consideration whenever a selection of plant location/site is made. The nearness of the source of the raw materials for the production of Chlorobenzene (which are benzene and chlorine) has to be considered since this will influence both the transportation and storage charges of the raw materials. This is very important especially if large volumes of raw materials are needed for the Chlorobenzene production process. The nearer the source of the raw materials could reduce the transportation and storage charges. Attention should also be given to the price as well as the purity of the raw materials themselves. 3. Transport Facilities They are three forms of major transport facilities, which are the road network (land-port), seaport and airport. A plant site should be close to at least two of this major form of transport in order to boost the import-export activities. Land-port can be connected via road or railway. Road transport using lorry, etc. is suitable for local distribution from a central warehouse while rail transport using the train is used for long-distance transport of bulk chemical because is cheaper. Good road linkage will aid in the selling of product to local customer. Seaport facilities is connected via waterway such as canal, river and sea; using tankers that is usually practiced if involving import and exportation of product and raw materials with other country. Meanwhile, air transport using the airplane, helicopter, etc. is convenient and efficient for the movement of
personnel and essential equipment and supplies. Transportation factor also important in case of emergency such as an accident at the plant site for example fire at the workplace. Good road linkage from the site to the nearest fire station can prevent further property damage if this kind of accident happens. 4. Availability of Labour This factor has been in the top 10 list (ranked by the Area Development Corporate Survey) of the important factors in site selection. The location of the plant should have sufficient available labors to be employed. Labors are needed for the construction as well as for running the plant. The availability of both the skilled and semi-skilled labors will lead to the efficiency of the operating plant itself. For example, when a large amount of money is invested by a plant, the needs of the skilled labors become very important in order to ensure the operations in the plant could run smoothly. Also, skilled labors such as the electricians and pipe fitters are important in the maintenance of the plant. Unskilled labors however are important as well for training in operating the plant. 5. Availability of Services such as Utilities, Water, Fuel, Power Water, electricity and fuel are very important factors in site selection to ensure the plant can be operated smoothly. Nearness to the available power facility will reduce the plant operation cost. Most chemical processes required a large quantity of water for cooling process and general use. Thus, the plant needs to be located near to the source of water of suitable quality which is usually near to coastal (sea) area or lake. Other source for this process water may come from a river, deep wells, and reservoirs or even purchased from a local authority. Electrical power is a must at all sites, without electrical power, the plant might be shut down. Therefore the availability of power plants near to the plant site is very important. Stable and uninterrupted power of required magnitude, without fluctuations in voltage and frequency is important for the successful operation of the plant. Other than that, a reasonably competitive priced fuel is important for steam and power generation.
6. Availability of Suitable Land It is important to first examine carefully the characteristics of the proposed plant site. This means that the topography of the tract of land and the structure of the soil has to be considered and examined very well. It should be noted that either the land or the soil of the proposed site could affect the cost of the construction. The characteristic of the land that is considered as the most suitable for the construction of a new plant is for it to be flat, well drained and having suitable load-bearing characteristics. Even though there is no immediate expansion is, it is best for a new plant to be constructed at a location with an additional space (for future changes). 7. Environmental Impact, Including Effluent Disposal A plant site needs a smooth operation to maximize the production but in the same time release the minimum amount of waste or effluent so that cause less impact to the environment. For example, constructing a site next to sea coastal may be convenient for cooling water supply but it will cause harm to the local aquatic ecosystem in the water through excessive withdrawals or thermal pollution (from discharges of hot cooling water). All industrial processes will produce waste products. The site selected must have efficient disposal system such as drainage and dumping site. Disposal of toxic and harmful effluent need to follow the local regulations, and during the site survey, appropriate authorities need to be consulted to determine the standards that must be met. 8. Local Community Considerations The proposed plant site should also consider the opinions of the community nearby the location of the plant. The proposed site should be accepted by the local community. It must be ensured that the plant that is going to be constructed at the proposed site will not cause any risks to the local community nearby. The health hazards should be kept at its minimum with all the safety precautions taken as one of the priority in the construction of the plant.
9. Climate The characteristics features of the climate of Malaysia are uniform temperature, high humidity and copious rainfall with winds that are generally light. A suitable climate can ensure the plant to operate smoothly and productively. Some natural disaster such as flood, earthquake, typhoon, etc. that occur at the plant location may increase the cost of operation. Thus, careful site consideration needs to be taken to avoid choosing site with adverse climatic conditions. In Malaysia, cases where major disasters such as earthquake or typhoon occur very little; the weather condition is influenced by the Northeast and Southwest monsoon. The Southwest monsoon season usually occur in end of May to September with wind flow is generally light below 15 knots. Meanwhile, the Northwest monsoon occurs in early November to March with wind speed ranging from 10 to 20 knots. During the two inter-monsoon seasons, the winds are generally light and variable. Stronger structure need to be built at locations subject to high winds. Annual rainfall in Malaysia is found to be around 2500 mm per year. Rain falls most heavily during the monsoon season, which is from the end of September to early January for East Malaysia and December to March for West Malaysia. Malaysia is a tropical country that has a daily temperature that varies around 25 to 27 degrees Celsius. The maximum is about 32 oC, while the minimum is about 21oC daily. Highest humidity is achieved during the night and dawn, while the relative humidity value drops to minimum around midday where bright sunlight appears. 10. Political & Strategic Considerations Subsidies and concessions from the government are provided for industries located in certain notified areas. Those areas are the ones that have been declared as industrially backward where low wages, cheap power and tax concessions are offered by the government.
The Several Strategic Locations as the Site For The Manufacture Of Chlorobenzene In order to find the most suitable site location for the production of Chlorobenzene (with 20000KMT/year of Mono-Chlorobenzene and not less than 2000KMT/year of DiChlorobenzene), all the 10 factors stated previously has been considered during the survey of several possible sites. The three main sites that have been considered are as listed below: i.
Tanjung Langsat, Johor
ii.
Gebeng Industrial Estate, Pahang
iii.
Kerteh Industrial Park, Terengganu
Tanjung Langsat Industrial Complex, Johor Iskandar Malaysia which is a development corridor conducted in the southern part of Johor. It is also known as the South Johor Economic Region (SJER). One of the main components of Iskandar Malaysia is as the centre of industrial and manufacturing activities which covers up to 31,132 hector of Pasir Gudang region. The Major Economic Zone D includes the Pasir Gudang Port, Pasir Gudang Industrial Park, Tanjung Langsat Port as well as the Tanjung Langsat Industrial Complex. It is located for about 48km in eastern of Johor Bahru and 8km from the Pasir Gudang industrial area with population of around 100,000 people. One of the main economic activities of Pasir Gudang involves chemicals, oleo chemicals, biofuels and etc. The Tanjung langsat Industrial Complex symbolizes the continuation of the existence of the industrial area of Pasir Gudang and it covers an area of 4,198.52 acres which is reserved for light, medium, and heavy industries. On the other hand, the Tanjung Langsat Industrial Park which covers up to 3764 acres of land has been one of the most successful industrial estates in Malaysia with a tank farm facility being developed for the chemical storage. This location has good connectivity in terms of the transport facilities. It currently is connected by the four-lane Pasir Gudang Highway, a trunk road and a railway line to Johor Bahru. This would therefore ease the transportation process of raw materials (chlorine and benzene) since the supplier of these raw materials are also available in Johor Bahru (HG Chemicals Technology
Sdn. Bhd.) which is only 48km away from Tanjung Langsat. Other than that, the Senai-Desaru Expressway makes it possible for the traffic from the north of Johor Bahru to have an easy access to the Tanjung Langsat Industrial Complex through the 5km four-lane dual carriage road that links Tanjung Langsat to the expressway. Also, this location has seaport nearby (Tanjung Langsat Port that is located adjacent to the 4,000 acres of the industrial land) which would make it easier for the import and export activity of the Chlorobenzene product. Tanjung Langsat Port is designed especially to handle the bulk cargo (LPG and hazardous chemicals). Other than that, Senai Airport is also available for personal businesses. The available area for the industrial activities in Tanjung Langsat is about 2709.94 acres with the price ranging from RM12 – RM14 per square feet (for a 30yr + 30yr lease period). In terms of the available utilities, the current water supply by the Syarikat Air Johor Holdings Bhd (SAJH) to the industrial areas in Iskandar Malaysia is adequate. On the other hand, natural gas is used for the power generation in Malaysia with 24% of the NG being used in heavy industries whereas 4% is used in the housing, commercial and other industrial areas. Supply of NG is made by the Petronas Gas Bhd via pipelines to the factories. In reference to Ramli, Abdul Rahim (2007), the environmental impact of the industrial activities in the Tanjung Langsat area has showed that the industrial development had given positive impacts to the local community in terms of their income, infrastructure as well as public facilities. However, it also creates negative impacts such as pollution of air & water and limitation of area for fishing activities around the Tanjung Langsat. Next, considering the climatic factor, as stated earlier, a suitable climate can ensure the plant to operate smoothly and productively. Natural disasters that occur at the plant location may increase the cost of operation. Thus, it is important to avoid choosing site with adverse climatic conditions. The possibilities of the occurrence of natural disasters in Malaysia are very low. Thus, it could be concluded here that in terms of climatic factor, Tanjung Langsat is also suitable for the site location. Next, the rapid development of the industry in the Pasir Gudang Tanjung Langsat has led to the shortage of manpower or labor to carry out all the operations in the plant. Though some industries have implemented the automated systems, but the need of manpower is still high. Lastly, it is important to have the targeted marketing area as close as possible to the site location. Chlorobenzene is used mostly in the manufacture of pesticides, dyes, and rubber. Thus, it is
important to have the site close to the manufacturer of these three materials. In Johor, there are few rubber industries which are located at Skudai, Johor Bahru which are LekSeng Rubber Industries and N.K. Rubber (M) SDN. BHD.
Gebeng Industrial Estate, Pahang Gebeng Industrial Estate (GIE) has developed rapidly over the past 20 years where it first started in early 90s by the Pahang State Development Corporation (PSDC). GIE is located in Kuantan, Pahang, Malaysia which consist of four development phases that have about 8600 hectares of land and is a world-class petrochemical and chemical industrial zone. It is located 25 km from Kuantan Town and 250 km from Kuala Lumpur; and is strategically located only 5 km from the Kuantan Port. GIE also offers a wide variety of facilities for the investors. For example, the Gebeng bypass that links Kuala Lumpur and Kuantan directly via the East Coast Highway which eases the trafiic flow from the industrial estate to Kuantan Port. Pahang State Government has continuously upgrading the infrastructures around the area mainly its transportation facilities. For example, the railway link that connects Kuantan Port-Gebeng-Kerteh to ensure the import and export activities runs smoothly. 1. Location, with respect to the marketing area
Distance from nearest town : o 25 km from Kuantan town o 250 km from Kuala Lumpur city -
Using land transport is 2 hours drive and by air is 45 minutes.
Distance from nearest port
:
o 5 km from Kuantan Port -
This is very strategic; close proximity to the port save the logistics costs and promotes imports-exports activities.
Market Demand: o Chlorobenzene is widely used in pesticide business. Within the Pahang State itself, there are many pesticide or pest control company that required chlorobenzene for its production, for example:
-
Rentokil Pest Control Kuantan, BINS Pest Control, Kilpest (Pahang) Sdn Bhd, Prima Pest Control & Services, etc. which is all located in Kuantan, Pahang.
o Chlorobenzene also used in synthesis of rubber for example in manufacturing of tire and furniture. There are a lot of tires and rubber-based furniture company in area near to Gebeng such as Uts Tyre Service (Kuantan) Sdn Bhd and TWINS Furniture Manufacture. o Other than that, chlorobenzene also involve in the production of herbicide that widely used to kill weed. Weed killer is popular among farmers and also landscape designer.
2. Raw material supply
The raw materials needed for production of chlorobenzene are chlorine and benzene. There are many suppliers for benzene near to Gebeng, for example PETRONAS Chemicals Group Berhad (PCG) which is located at Gebeng too. Since Gebeng Industrial Estate is located near to Kuantan Port, the availability of raw materials should not be a problem as it can be exported from outside of Gebeng.
3. Transport facilities a) Road facilities: i.
Highway -
East Coast Highway that links Kuantan and Kuala Lumpur which is only 2 hours drive away.
-
Gebeng Bypass Road is being planned to further enhance the traffic flow between the main road and Gebeng.
-
Kuantan Bypass Road will be widened to eased the traffic congestion.
-
Federal Road (Kuantan-Kerteh-Kuala Terengganu)
-
Federal Road (Kuantan-Segamat)
-
Federal Road (Kuantan-Karak-Kuala Lumpur)
ii.
Railway -
Have a railway link that connects the integrated petrochemical complex in Kerteh (Terengganu) to Gebeng and Kuantan Port. This railway link has strengthen the chemical and petrochemical linkage between Gebeng and other industrial centers by which it ensures a much more safer form of transporting dangerous goods by train rather than by road.
b) Airport facilities: -
The nearby airport to Gebeng is the Kuantan Airport. Since airport transportation is used to ease the movement of personnel and essential equipment and supplies from Gebeng to other places, Kerteh Airport and Kuala Lumpur International Airport (KLIA) also available for this purpose.
c) Seaport facilities: -
The main seaport facility in Gebeng is Kuantan Port which is only located 5 km from the industrial estate. (*More details about Kuantan Port are described in latter section.)
-
Other seaports that connect with Kuantan Port are Kemaman Port and Kerteh Minor Port for better transport of goods for import and exports activities.
4. Availability of labour
Labors, of both the skilled and semi-skilled labors are needed for the construction as well as for running the plant. Training institution with customized courses are available such as: -
Universiti Teknologi Malaysia, Indera Mahkota
-
Institut Latihan Perindustrian
-
Politeknik Sultan Ahmad Shah (POLISAS)
-
Institut Kemajuan Ikhtisas Pahang (IKIP)
5. Availability of utilities
a) Electricity
The main electricity supplier in Gebeng Industrial Estate is Tenaga Nasional Berhad (TNB) which supply 132/11 kV main intake for Phase I and II; and for Phase III, there are two sources of electricity available which are Centralized Utility Facilities (CUF) and 12/275 kV main intake.
Other sources of electricity may be from the nearest electric generators which are: -
Paka Power Plant
-
IPP YTL Power Generation Sdn. Bhd.
-
Tasik Kenyir Hydro-Electric
b) Water Supply
The main water supply in Gebeng Industrial Estate is from the Semambu Water Treatment Plant with capacity of 2 MG/D.
Others are from the reservoirs at Bukit Penggorak with capacity of 2 MG/D and 1.5 MG/D; and reservoirs at Bukit Merah with capacity of 0.5 MG/D and 1.0 MG/D.
Government of Pahang have taken few steps in order to ensure efficient water supply in Gebeng which are: i.
Increase the water supply to 64 MG/D
ii.
Building of a new 200 acres dam in Sungai Lembing, Kuantan
iii.
Building of new pipes and water tanks in Gebend Industrial Estate
c) Natural gas utility
The current natural gas suppliers for Gebeng Industrial Estate are Gas Malaysia and Petronas Gas Berhad which supply gases within the estate to fulfil the tremendous demand for existing and further petrochemical projects in the area.
Other than that, availability of natural gases, Butane and Propane are supplied by the Peninsular Gas Utilization Network (PGU).
d) Telecommunications
Telecommunication services such as Integrated Systems Digital Network (ISDN), digital line, MAYPAC, Internet and video conferencing in Gebeng is supplied by the Telekom Malaysia.
e) Fire Fighting facilities
As one of the most developed industrial estate in the nation with various kinds of plant, factory, buildings, etc., Gebeng Industrial Estate is built near to the Pahang Fire and Rescue Department in order to handle any emergencies. In addition, near to Gebeng area is also the Petronas Centralized Emergency Facilities. Both of these stations are equipped with HAZMAT (hazardous material) facilities.
Alliance between Government agencies and private manufactures in Gebeng has set up a voluntary crisis management organization called the Gebeng Emergency Mutual Aid (GEMA) which is to execute proactive action and offer expert services to overcome emergencies situation.
f) Piperack link
Centralized Tankage Facilities which is located at Kuantan Port links Gebeng and Kuantan Port with a common piperack / pipeline network to transport gases.
6. Availability of suitable land
The preferable type of industrial activities in Gebeng Industrial Estate is chemical, petrochemical and general.
The land / site available are originated from the State Land.
There are four development phases available in Gebeng Industrial Estate, which is very convenient for additional space needed for future changes such as expansion of plant and so on. They are Gebeng Phase I with space 700 acres (283.28 hectares), Gebeng Phase II with 1400 acres (566.57 hectares), Gebeng Phase III with 2500 acres (1,011.73 hectares) and Gebeng Phase IV with 4000 acres (1,618.76 hectares).
Land price (RM psf) :
(Note: Price change without notice) -
RM16.00 per square feet (Industrial Lot Ready Land)
-
RM20.00 per square feet (Small Medium Enterprise- SME Lot 129 Complete with infrastructure)
-
RM12.00 per square feet (Raw Land)
The leasehold for the site is 99 years upon the issuance of titles.
Total Planned Area is about 2468.60 hectares, Total Land Developed around 2408.08 hectares; and the Total Land Available is 1,528.5 hectares.
Quit Rent per Annum (RM) is subjected to RM15.00 for every 100 m2 portion of it for the first 2 hectares and RM10.00 for every 100 m2 or portion of it subject to a minimal taxation of RM150.00 per ownership.
The Annual Assessment is 7% of the property / land value.
Kerteh Industrial Park, Terengganu
Kerteh also known as Kertih, is a town in the district of Kemaman in southern Terengganu, Malaysia. Kerteh is the base of operations for Petronas in Terengganu, overseeing the oil platform operations off the state's coast as well as petrochemicals production and crude oil refining in nearby Paka.
Terengganu is known with its industrial land being the cheapest among the other lands in Malaysia. It ranges from RM0.18 – RM5.60 per square foot. Other states land price usually ranging from as low as RM2.00 – RM4.50 psf to as high as RM18.00 – RM22.00 psf. The land price in Kerteh Industrial Area is ranging from RM9 - RM14 psf. While for land with ready-built factories with pre-installed facilities like broadband, water and power, which reduces the time required to get a project off the ground is ranging from RM45 - RM60 per square meter.
As for the utilities supply, the Centralized Utility Facility (CUF) which is located in Kerteh operates independently of the national grid. CUF supplies wide range of industrial utilities to the selected industrial area. This includes the electricity, steam, industrial gases as well as other byproducts (de-mineralized water, raw water, cooling water, effluent treatment and etc.). Since
power is generated by CUF from natural gas. Thus, it is less prone to lighting and power surges in the grid, and therefore making it an efficient source of utilities. The availability of this facility allows the Kerteh industrial area to save up to 20% of its operating and investment costs since they do not need to build any extra infrastructure to generate utilities.
In terms of closeness of the plant with the targeted markets, for the Kerteh Industrial Park, this location is quite close with the Mardec Processing Sdn. Bhd. (MPSB) Kuala Berang Factory which manufactures rubber (one of the product in which the process of the production uses chlorobenzene). The distance between Kerteh and Kuala Berang is about 108km difference. Another targeted market is the manufacturer of pesticide which is the Felda Agricultural Services Sdn Bhd located Kuala Lumpur. The distance between Kerteh and Kuala Lumpur is about 326km difference. One of the raw materials suppliers that provide benzene for production of chlorobenzene in Kerteh Industrial Park is Aromatics Malaysia Sdn Bhd in conjunction with PETRONAS, MJPX Co. Ltd. that was built in July 2000. It has a capacity of 188,000 tonnes per annum (tpa) Benzene. Meanwhile, liquid chlorine may be supplied by Malay-Sino Chemical Industrial Sdn Bhd which is located in Kemaman Terengganu. This somehow increases the transportation cost of raw materials since raw materials are obtained from two different suppliers. As a developed town, Kerteh is equipped with a good transportation facility. As for road facilities, Kerteh Industrial Area is located within the East Coast Industrial Corridor (ECIC) of Pennisular Malaysia and also Kerteh-Kuantan Port Railway Line is available for transportation of goods via train. The railway is 77 km is a single-track line that links Kerteh Petrochemical Complex in Terengganu with Kuantan Port in Pahang with a direct connection to Gebeng Industrial Estate. East Coast Expressway is the highway that connects Kerteh, Terengganu with Kuala Lumpur. As in terms of airport facility, Kerteh Airport is available, that is only 3.54 km to Kerteh town center. This airport is owned and operated by Petroleum Nasional Berhad (Petronas), and was built to serve the purpose of airlifting its employees and ExxonMobil employees to their various oil platforms located 100–200 km offshore South China Sea. Other than that, this airport is also used to transport Petronas and ExxonMobil employee from Kerteh to Sultan Abdul Aziz Shah Airport, Subang near to Kuala Lumpur. As for seaport facility, Kertih
Port Marine Terminal which is operated by Petronas Penapisan Sdn Bhd is available in the South China Sea. The supporting Kerteh marine facilities include six berths that can accommodate chemical tankers of up to 40,000 tonnes. Another port is the Kemaman Port which is situated only 7 km from Kerteh, about 9 minutes of travel via road.
Comparison Among The Possible Sites (Using Concept Screening & Scoring) For the concept screening of the potential sites, only five main criterions are considered and evaluated. The criterions are as follow: Criterion
Alternatives 1 (Gebeng)
1
2
Kuantan Town (25 km) Kuala Lumpur (250 km) Targeted markets are mainly located in Kuantan, Pahang +
2 (Reference:Kertih)
supplied from PETRONAS Chemicals Group Berhad (PCG) in Gebeng itself.
Benzene
Kuala Berang (108km) Kuala Lumpur (326km)
0 2 suppliers: Kemaman, 41.9km and in Kerteh Increase in transportation cost
East Coast Highway Gebeng Bypass Road Kuantan Bypass Road Federal Road Kerteh-Kuantan Port Railway Line Kuantan Airport Kuantan Port
Kerteh-Kuantan Port Railway Line East Coast Expressway Kerteh Airport Kertih Port Marine Terminal
Centralized Utility Facility (CUF) Centralised Tankage Facilities
Centralized Utility Facility (CUF)
RM12 – RM16 --
+
48km from Tanjung Langsat
+
Four-lane Pasir Gudang Highway, a trunk road and a railway line Senai-Desaru Expressway Tanjung Langsat Port Senai Airport +
SAJH (water supply) Petronas Gas Bhd. (power supply)
0
+ 5
Targeted markets are located in Skudai, Johor
0
+ 4
0
-3
3 (Tanjung Langsat)
RM 9 – RM 14 0
0
RM 12 - RM14 --
Total
2
0
2
Rank
1
3
1
Where the criterion are as follow:
1 = Location, with respect to the marketing area
2 = Raw material supply
3 = Transport facilities
4 = Availability of utilities
5 = Availability of suitable land
Based on the concept scoring, both proposed sites which are in Gebeng Industrial Estate, Pahang and Tanjung Langsat Industrial Complex, Johor has a higher ranking than the reference site in Kerteh Industrial Area, Terengganu. Therefore, both proposed sites are further judged in the concept scoring as shown below. Alternatives Criterion
Weight
1
3
1
35%
5
4
2
25%
2
4
3
15%
5
4
4
20%
5
3
5
5%
2
2
Total Score
4.10
3.70
Rank
1
2
By comparing both proposed sites that have passed the concept scoring, it was found that the best alternative is the one with the highest score which is the Gebeng Industrial Estate with total score of 4.10 against Tanjung Langsat Industrial Complex with total score of 3.70. Thus, Gebeng Industrial Estate has been chosen as the site location for the production of Chlorobenzene.
Process Flow Diagram (PFD)
PFD for the production of Chlorobenzene
Workbook Heat and Material Balance Table Stream ID
B--OUT
B-1
B-2
B-FEED
From
SEP1
SEP3
DC1
To
HEATER
DC1
Phase
LIQUID
LIQUID
LIQUID
B-IN
CL2-FEED CL2-OUT
COND-OUT DIST-1
HEATER
HEATER2 CONDNSER SEP2
MIXER
REACTOR1 HEATER2
SPLITER
SEP2
SEP3
LIQUID
VAPOR
VAPOR
MIXED
LIQUID
VAPOR
DIST-2
HCL-OUT
MIX-OUT
R1-OUT
DC1
SEP2
MIXER
REACTOR1 REACTOR2 SEP3
SPLITER
SEP1
REACTOR2 CONDNSER MIXER
REACTOR1 REACTOR2
LIQUID
MIXED
VAPOR
LIQUID
VAPOR
R2-OUT
RECYCLE SPLIT-1
MIXED
VAPOR
SPLIT-2
W-OUT
SPLITER
SEP1
VAPOR
LIQUID
Substream: MIXED Mole Flow
lbmol/hr
C6H6
70.21297
0.0
0.0
62.34210
70.21297
0.0
0.0
7.870874
7.870874
0.0
0.0
70.21297
41.42565
7.870874
7.870874
0.0
0.0
0.0
CL2
0.0
0.0
0.0
0.0
0.0
139.0676
139.0676
73.01193
0.0
0.0
73.01193
0.0
40.74648
73.01193
0.0
69.53380
69.53380
0.0
HCL
0.0
0.0
0.0
0.0
0.0
0.0
0.0
66.05566
0.0
0.0
66.05566
0.0
28.78732
66.05566
0.0
0.0
0.0
0.0
C6H5CL
0.0
58.62853
.0165002
0.0
0.0
0.0
0.0
58.62853
58.62853
58.61203
0.0
0.0
28.78732
58.62853
0.0
0.0
0.0
0.0
P-DIC-01
0.0
3.713564
3.555722
0.0
0.0
0.0
0.0
3.713564
3.713564
.1578421
0.0
0.0
0.0
3.713564
0.0
0.0
0.0
0.0
H2O
0.0
0.0
0.0
.3132769
0.0
0.0
0.0
0.0
0.0
0.0
0.0
.3132769
0.0
0.0
0.0
0.0
0.0
.3132769
Total Flow
lbmol/hr
70.21297
62.34210
3.572202
62.65538
70.21297
139.0676
139.0676
209.2806
70.21297
58.76990
139.0676
70.52625
139.7468
209.2806
7.870874
69.53380
69.53380
.3132769
Total Flow
lb/hr
5484.591
7145.040
524.5567
4875.412
5484.591
9860.644
9860.644
15345.23
7759.862
6620.482
7585.372
5490.235
10414.91
15345.23
614.8226
4930.322
4930.322
5.643771
Total Flow
cuft/hr
104.9297
109.3135
7.829402
89.47071
33431.60
53581.76
60176.79
87193.84
121.4675
110.9598
65951.02
104.9700
12598.08
24653.12
3648.030
30088.40
30088.40
.0941140
Temperature
F
138.0930
184.7300
384.5992
76.73000
201.0930
67.73000
130.7300
184.7300
184.7300
306.0184
184.7300
138.0930
130.7300
130.7300
184.7300
130.7300
130.7300
138.0930
Pressure
psia
14.50377
14.50377
24.65642
14.50377
14.50377
14.50377
14.50377
14.50377
14.50377
24.65642
14.50377
14.50377
34.80906
34.80906
14.50377
14.50377
14.50377
14.50377
Vapor Frac
0.0
0.0
0.0
0.0
1.000000
1.000000
1.000000
.8830702
0.0
0.0
1.000000
0.0
.5022436
.6563256
1.000000
1.000000
1.000000
0.0
Liquid Frac
1.000000
1.000000
1.000000
1.000000
0.0
0.0
0.0
.1169298
1.000000
1.000000
0.0
1.000000
.4977564
.3436744
0.0
0.0
0.0
1.000000
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
23377.86
7694.139
3344.977
20857.45
38298.11
-108.7071
410.5660
-5323.835
9618.068
13315.22
-18048.10
22758.96
632.5283
-9539.589
37895.68
410.5660
410.5660 -1.2252E+5
299.2802
67.13311
22.77911
268.0454
-72.60725
87.02643
118.1989
-330.8876
292.3561
8.487232
-130.1023
Solid Frac Enthalpy
Btu/lbmol
Enthalpy
Btu/lb
Enthalpy
Btu/hr
Entropy
Btu/lbmol-R
-56.41256
Entropy
Btu/lb-R
Density Density
490.2871
-1.533129
5.790335
485.1353
5.790335
5.790335
-6800.626
11948.94 1.30683E+6 2.68902E+6
-15117.63
57096.43 -1.1142E+6 6.75313E+5 7.82534E+5 -2.5099E+6 1.60510E+6
88393.78 -1.9965E+6 2.98272E+5
28548.22
28548.22
-38381.17
-55.26235
-49.08018
-59.44399
-32.88386
-.1537557
.7762084
-9.876595
-54.42879
-48.51741
3.913583
-56.24713
-26.65722
-17.91827
-33.50052
.7762084
.7762084
-38.00291
-.7221858
-.4821766
-.3342333
-.7639324
-.4209746 -2.1685E-3
.0109471
-.1346985
-.4924839
-.4306881
.0717502
-.7225372
-.3576852
-.2443720
-.4288690
.0109471
.0109471
-2.109482
lbmol/cuft
.6691428
.5703057
.4562548
.7002893 2.10020E-3 2.59543E-3 2.31098E-3 2.40018E-3
.5780390
.5296502 2.10865E-3
.6718707
.0110927 8.48901E-3 2.15757E-3 2.31098E-3 2.31098E-3
3.328696
lb/cuft
52.26918
65.36284
66.99831
54.49171
.1640541
.1840299
.1638612
.1759899
63.88425
59.66557
.1150152
52.30290
.8267063
.6224461
.1685355
.1638612
.1638612
59.96739
78.11364
114.6102
146.8441
77.81315
78.11364
70.90540
70.90540
73.32374
110.5189
112.6509
54.54450
77.84668
74.52704
73.32374
78.11364
70.90540
70.90540
18.01528
99.54653
102.8150
6.490596
88.47795
99.54653
113.3212
113.3212
230.1390
113.9742
96.32442
116.1649
99.63711
163.8012
230.1390
11.15917
56.66059
56.66059
.0905787
Average MW Liq Vol 60F
cuft/hr
1.64143E+6 4.79669E+5
Material Balance Basis being used: 330 days/year of operation. In which, it is required to produce 50000 metric tonne/year of monochlorobenzene (MCB) with not less than 2000 metric tonne/year of dichlorobenzene (DCB).
Balance Around Reactors The reaction that occurred around the reactor is as follow: Reaction 1 : C6H6 + Cl2
C6H5Cl + HCl
Reaction 2 : C6H5Cl + Cl2
C6H4Cl2 + HCl
The balance around Reactor 1:
𝑛 Cl2 = 69.53380 lbmol/hr SPLIT-1
𝑛tot = 139.7468 lbmol/hr B-IN 𝑛tot = 70.21297 lbmol/hr 𝑥B=1
Inlet streams:
R1
R1-OUT 𝑥o B = 0.2964 𝑥 0 Cl2 = 0.2916 𝑥 o HCl = 0.2060 𝑥 o MCB = 0.2060
B-IN
=1
B
SPLIT-1
=
Cl2
Components in outlet R1-OUT stream: B
=
Cl2
=
HCl
=
MCB =
The balance around Reactor 2:
𝑛 Cl2 = 69.53380 lbmol/hr SPLIT-2
R1-OUT
R2-OUT
R2
𝑛tot = 139.7468 lbmol/hr
𝑛tot = 209.2806 lbmol/hr
𝑥B = 0.2964 𝑥 Cl2 = 0.2916 𝑥 HCl = 0.2060 𝑥 MCB = 0.2060
𝑥B 𝑥 Cl2 𝑥 HCl 𝑥 MCB 𝑥 DCB
Inlet streams: For stream R1-OUT =
B
=
Cl2
=
HCl
=
MCB
For stream SPLIT-2 =
Cl2
Components in outlet R2-OUT stream: B
=
Cl2
=
HCl
=
MCB = DCB
=
= 0.0376 = 0.3489 = 0.3156 = 0.2801 = 0.0177
Balance around Separator & DC
The balance around the first separator 1:
Assumption is that all the water contained in the liquid benzene fed to the inlet stream of this separator goes to the top stream of the separator:
W-OUT 𝑛tot = 0.3132769 lbmol/hr 𝑥 H2O = 1
Sep1
MIX-OUT 𝑛tot = 70.52625 lbmol/hr 𝑥B = 0.9956 𝑥 H2O = 0.0044
𝑛tot = 70.21297 lbmol/hr 𝑥B=1 B-OUT
Balance for each component is as follow: B:
inlet = outlet
70.215935
70.21297
H2O: inlet = outlet
0.3103155
The balance around the separator 2:
0.3132769
Where hydrochloric acid and chlorine are removed in this step:
DIST-1 𝑛tot = 70.21297 lbmol/hr 𝑥B = 0.1121 𝑥 MCB = 0.8350 𝑥 DCB = 0.0529
Sep 2
COND-OUT 𝑛tot = 209.2806 lbmol/hr 𝑥B 𝑥 Cl2 𝑥 HCl 𝑥 MCB 𝑥 DCB
𝑛tot = 139.0676 lbmol/hr
= 0.0376 = 0.3489 = 0.3156 = 0.2801 = 0.0177
𝑥 HCl 𝑥 Cl2 HCL-OUT
Balance for each component is as follow: B:
inlet = outlet
7.86895 Cl2:
inlet = outlet
73.01800 HCl:
7.87087
73.01049
inlet = outlet
66.04896
66.05711
58.61950
58.62783
MCB: inlet = outlet
DCB:
inlet = oulet
= 0.4750 = 0.5250
3.70427
3.71427
The balance around the separator 3:
Assumption is that all the benzene remained in the inlet stream of the separator goes to the top stream of this unit and is recycled back together with the feed:
RECYCLE 𝑛tot = 7.870874 lbmol/hr 𝑥B
Sep. 3
DIST-1 𝑛tot = 70.21297 lbmol/hr
𝑛tot = 62.34210 lbmol/hr
𝑥B = 0.1121 𝑥 MCB = 0.8350 𝑥 DCB = 0.0529
𝑥 MCB = 0.9404 𝑥 DCB = 0.0596 B-1
Balance for each component is as follow: B:
inlet = outlet
7.87087
7.87084
MCB: inlet = outlet
58.62783 DCB:
=1
58.62651
inlet = oulet
3.71427
3.71559
The balance around the Chlorobenzene column:
Based on the process description, it is required to produce product with 99.7 wt% of MCB and 99.6 wt% of DCB:
DIST-2 𝑛tot = 58.76990 lbmol/hr 𝑥 MCB = 0.997 𝑥 DCB = 0.003
B-1
Distillation Column
𝑛tot = 62.34210 lbmol/hr 𝑥 MCB = 0.9404 𝑥 DCB = 0.0596
𝑛tot = 3.572202 lbmol/hr 𝑥 MCB = 0.0046 𝑥 DCB = 0.9954 B-2
Balance for each component is as follow: MCB: inlet = outlet
58.62651 DCB:
58.61002
inlet = oulet
3.71559
3.73208
Balance around Heat Exchangers & Mixer/Splitter
Balance around Mixer
RECYCLE 𝑛tot = 7.870874 lbmol/hr 𝑥B= 1
MIX-OUT 𝑛tot = 70.52625 lbmol/hr 𝑥B = 0.9956 𝑥 H2O = 0.0044
𝑛tot = 62.65538 lbmol/hr 𝑥B = 0.995 𝑥 H2O = 0.005 B-FEED
Balance for each component: B:
inlet = outlet
70.21298
70.21593
0.31328
0.31032
H2O: inlet = outlet
Balance around the Splitter
SPLIT-1 𝑛 Cl2 = 69.53380 lbmol/hr
CL2-OUT 𝑛tot Cl2 = 139.0676 lbmol/hr 𝑛 Cl2 = 69.53380 lbmol/hr SPLIT-2
Balance for each component: Cl2 :
inlet = outlet
Balance around the HEATER:
B-OUT
B-IN 𝑛tot = 70.21297 lbmol/hr
𝑛tot = 70.21297 lbmol/hr
𝑥B=1
𝑥B=1
B:
inlet = outlet
Balance around the HEATER2:
CL2-FEED 𝑛 Cl2 = 69.53380 lbmol/hr
B:
inlet = outlet
69.53380
Balance around CONDENSER:
CL2-OUT 𝑛 Cl2 = 69.53380 lbmol/hr
R2-OUT
COND-OUT
𝑛tot = 209.2806 lbmol/hr 𝑥B 𝑥 Cl2 𝑥 HCl 𝑥 MCB 𝑥 DCB
𝑛tot = 209.2806 lbmol/hr
= 0.0376 = 0.3489 = 0.3156 = 0.2801 = 0.0177
𝑥B 𝑥 Cl2 𝑥 HCl 𝑥 MCB 𝑥 DCB
Balance for each component:
B:
inlet = outlet
7.86895
Cl2:
inlet = outlet
73.01800
HCl:
inlet = outlet
MCB:
inlet = outlet
DCB:
inlet = outlet
= 0.0376 = 0.3489 = 0.3156 = 0.2801 = 0.0177
Energy Balance Energy Balance For Reactors
Energy Balance for reactor 1:
Overall chemical equation C6H6 + C6H5Cl + 2Cl2 C6H5Cl + 2HCl + C6H4Cl2 (
)
= -184711 kJ/kmol
= 13.06 kmol/hr
= 13. 06 kmol/hr X (-184711 kJ/kmol) =
Cl2 = 31.54 kmol/hr T=328K C6H6=31.85 kmol/hr
Reference C6H6, Cl2, HCl and MCB at 298 Component nin (kmol/hr) Hin (kJ/kmol) C6H6 31.85 H1 Cl2 31.54 H2 HCl MCB -
H1= (Cp328 – Cp298 ) = 142.96 -136 = 6.92 kJ/kmol
Total= 63.39 kmol/hr 0.2964 C6H6 0.2916 Cl2 T=328K 0.2060 HCl 0.2060 MCB
nout (kmol/hr) 18.79 18.48 13.06 13.06
Hout(kJ/kmol) H3 H4 H5 H6
H2 = ∫ = 11.59 – 10.49 = 1.0992 kJ/kmol H3= H1 = 6.92 kJ/kmol
H4 = H2 = 1.0992 kJ/kmol H5 = ∫ = 0.879 kJ/kmol H6 = (Cp328 – Cp298 ) = 157.19 – 152 = 5.19 kJ/kmol
∑ =
∑ (18.79 6.92)+(18.48 1.0992)+(13.06 0.879)
+(13.06 5.19)) – ( (31.85 6.92)+(31.54 229.60 – 255.07) - 25.47 kJ/hr
= = =
Where
=
kJ/hr
1.0992))
Energy Balance for reactor 2:
Cl2 = 31.54 kmol/hr
Total= 94.93 kmol/hr
Total= 63.39 kmol/hr 0.2964 C6H6 0.2916 Cl2 T=328K 0.2060 HCl 0.2060 MCB
Reference C6H6, Cl2, HCl and MCB at 298 Component nin (kmol/hr) Hin (kJ/kmol) C6H6 18.79 H1 Cl2 50.02 H2 HCl 13.06 H3 MCB 13.06 H4 DCB -
H1 =(Cp328 – Cp298 ) = 142.96 -136 = 6.92 kJ/kmol H2 = ∫ = 11.59 – 10.49 = 1.0992 kJ/kmol
H3 = ∫ = 0.879 kJ/kmol H4 = (Cp328 – Cp298 ) = 157.19 – 152 = 5.19 kJ/kmol H5 = H1 = 6.92 kJ/kmol
0.0376 C6H6 0.3489 Cl2 0.3156 HCl 0.2801 MCB 0.0177 DCB
nout (kmol/hr) 3.57 33.12 29.96 26.59 1.68
Hout(kJ/kmol) H5 H6 H7 H8 H9
H6=H2 = 1.0992 kJ/kmol H7 = H3 = 0.879 kJ/kmol H8 = H4 = 5.19 kJ/kmol H9 = (Cp328 – Cp298 ) = 111.35 – 0 = 111.35 kJ/kmol
= 15.22 kmol/hr (
)
= -184711 kJ/kmol ∑ =
∑ (3.57 6.92)+(33.12 1.0992)+(29.96 0.879)
+ (1.68
) ) – ( (18.79 6.92)+(50.02
= 148.24 = -2809851.76 kJ/hr
Where
=
kJ/hr
1.0992)+ (13.06
+(26.59 5.19) )+(13.06 5.19))
Energy Balance for DC
Energy Balance for Distillation Column F 10 =129.7 kmol/h 0.9954 DME 0.0046 CH3OH 0 H2O
Total = F 9 =328.23 kmol/h 0.3976 DME 0.1976 CH3OH 0.4048 H2O F 11 =198.6 kmol/h 0.0071 DME 0.3238 CH3OH 0.6692 H2O Reference MCB and DCB at 298K Component nin (kmol/hr) Feed DME 129.1 Feed CH3OH 64.9 Feed Water 132.9 Distillate DME Distillate CH3OH Bottom DME Bottom CH3OH Bottom Water -
Cp at 298K : MCB = 152 kJ/kmol DCB = 0 kJ/kmol H1 = Cp298 – Cp298 = 0 kJ/kmol H2 = Cp298 – Cp298 = 0 kJ/kmol
Hin (kJ/kmol) H1 H2 H3 -
nout (kmol/hr) 1.4 0.6 1.4 64.3 132.9
Hout(kJ/kmol) -
H4 H5 H6 H7 H8
H3 = Cp425.4 – Cp298 Value Cp425.4 by interpolation: T Cp 400 170 425.4 X 450 181 X= 175.588 kJ/kmol H3 = 175.588 – 152 = 23.588 kJ/kmol
H4 = Cp425.4 – Cp298 Value Cp425.4 by interpolation: T Cp 400 238 425.4 X 450 296 X= 267.464 kJ/kmol H4 = 267.464 – 0 = 267.464 kJ/kmol H5 = Cp468.92 – Cp298 Value Cp468.92 by interpolation: T Cp 450 181 468.92 X 500 192 X= 185.162 kJ/kmol H5 = 185.162 – 152 = 33.162 kJ/kmol H6 = Cp468.92 – Cp298 Value Cp468.92 by interpolation: T Cp 450 296 468.92 X 500 366
X= 322.488 kJ/kmol H6 = 322.488 – 0 = 322.488 kJ/kmol
∑ ∑ = ((26.58 23.588) + (0.08
= 1167.8 kJ/hr
Where
= 1167.8 kJ/hr
0.007 33.162)+( 1.61
Pinch Calculation Table of data: Stream
Condition
Tin (K)
Tout (K)
3
Hot
1.03
328
298
1
Cold
1.23
293
328
2
Cold
4.034 x 10-6
293
328
Cp (kW/K)
Step 1: The minimum approach temperature is chosen to be 10
Step 2: The Temperature Interval Diagram
Stream 65°C (338 K) 55°C (328K) 30°C (303K) 25°C (298K)
∑ 3 1 2 1.03 1.23 kW/K (kW) ___________________________________________ 55°C (328K) -12.3 A ___________________________________________ 45°C (318K) -5.00 B ___________________________________________ 20°C (293K) 5.15 C ___________________________________________ 15°C (288K) _____ -12.15
Step 3: The Cascade Diagram
A -12.30 COLD UTILITY
HOT UTILITY
QH = 12.30
Tpinch -------------------------------------------------------------------------------------------------- Tpinch QH = 5.00
B -5.00
Tpinch --------------------------------------------------------------------------------------------------- Tpinch QH = 5.15
A 5.15
Step 4: The Calculation for Minimum Number of Heat Exchanger i.
Above the Pinch H.U 17.3 17.3 1 43.05
3 25.75 25.75 2
4
Since there are two arrows, thus minimum number of heat exchanger above the pinch is two. Nmin,a = 2.
ii.
Below the Pinch
3 5.15 5.15 C.U 5.15
Since there is only one arrow, thus minimum number of heat exchanger below the pinch is one. Nmin,b = 1. Step 5: Design of the heat exchanger network
Above The Pinch
Stream
3
1
𝑚𝐶 p
1.03
1.23
2 4.034 x 10-6 328
338 QHU = 17.3
327.97
318
H
328 Q1 = 25.75
328
303
1
The calculation for change in temperature: For stream 3: For stream 1: For Hot Utility:
313.9 1
293
Below The Pinch
Stream
3
1
𝑚𝐶 p
1.03
1.23
2 4.034 x 10-6 293
303 298
288
298 C
293
QCU = 5.15
The calculation for change in temperature: For stream 3: For Cold Utility:
Major Equipment Design
The Distillation Column (Chlorobenzene Column):
inside diameter : 0.94 m
height of top disengaging section: 0.3 m
height of bottom separation section: 0.4 m
Design pressure: 1.7bar
The vessel is subjected to external pressure of :0.5405 kgf/cm2
Design temperature: 25
Shell material: carbon steel(sp. Gr.=7.7) (IS:2002-1962, GRADE I)
Permissible tensile stress: 950 kgf/cm2
Insulation material: asbestos
Density of insulation: 2700 kg/m3
Insulation thickness: 50 mm
Down comer plate material: stainless steel(sp. Gr.: 7.8)
The shell thickness calculation: Assuming first that the thickness of the shell is 6mm By using a stiffener channel of C-60, 18x4, of CSA=18 in2 With Wt =51.9 lb/ft The data needed for the calculation of allowable P: Do = 0.952 m L = 0.305 m B = 13100 Therefore;
=
= 0.3204
Thus, P allowable?
Pallowable = 1.7 bar =
4
4
(
)
⁄
t = 1.757 x 10-3m = 1.757mm
From the calculated value above, it shows that the thickness assumed (6mm) is allowable under the operating condition. Taking into consideration the corrosion correction of 2mm, therefore the thickness becomes: 6 + 2 = 8mm.
Piping & Instrumentation Diagram (P&ID)
Plant Layout The economic construction and operation of a process unit will depend on how well the plant equipment specified on the process flow sheet and laid out. Plant layout for the plant will consist of the process units involved, which is located in the main plant and other auxiliary buildings. The layout, which refers to each department, must be arranged in order to maximize efficiency and minimize the cost of ownership and plant operating; and also to minimize the time spent by personnel in travelling between buildings. The principal factors to be considered when designing the plant are: 1. Economic consideration: construction and operation cost. 2. The process requirement 3. Convenience of operation 4. Convenience of maintenance 5. Safety 6. Future expansion Other than the lists above, it is also advisable to check up the insurance regulations from the view of getting the best coverage at minimum cost for plant building and inventory. The auxiliary buildings and services required on site, in addition to the main processing units (buildings), will include: i.
Storages for raw material and products : Tank farms and Ware house
ii.
Maintenance workshops.
iii.
Store for maintenance and operating supplies.
iv.
Control room.
v.
Laboratories for process control.
vi.
Fire stations and other emergency services.
vii.
Utilities: steam boilers, compressed air, power generation, transformer station.
viii.
Effluent disposal plant.
ix.
Offices for general administration.
x.
Canteens, surau and other amenity buildings, such as medical centres.
xi.
Car parks.
xii.
Guard house / security posts.
1. Costs -
The cost required to build a plant need to be kept at possible minimum value
so that less modal will be used and more profits will be generated. The cost of construction can be minimized by choosing a land site with cheapest price but has a good facilities and utilities provided. Other than that, the layout needs to have the shortest run of connecting pipes between all equipment and also least amount of structural steel work. However, this will not necessarily be the best arrangement for operation and maintenance. In plant layout, economic is considered mainly with steelwork, concrete, piping and electric cabling.
2. Process Requirement -
All the required equipment need to be placed properly and strategically so that
can achieves smooth flow for transportation from raw materials to final product storage. The installation of the auxiliaries also need to be placed in such was so that it will occupy the least space. Process units are normally spaced at least 30 meters apart. Administration offices and laboratories, in which a relatively large number people will be working, should be located well away from potentially hazardous process control rooms. The siting of the main process units will determine the layout of the plant roads, pipes, alleys and drains. Access roads will also be constructed for operation and maintenance purpose. Utility building should be sited to give the most economical run of the processing units. The main storage areas should be placed between the loading and unloading facilities and the process units they serve. Storage tanks containing hazardous materials should be sited at a safe distance from other buildings which is at least 70 meter from site boundary.
3. Operation -
Any equipment that required frequent operation should be located near to the
control room so that easier for the operators to monitor the operation. All valves, sample points, and instruments should be located at convenient position and height. The working space and headroom must be sufficient to allow easy access to equipment. Since some of the equipment might need replacement if some parts is broken, thus sufficient space must be provided to allow access for lifting the equipment.
4. Maintenance -
All equipment needs to be prepared with maintenance facilities so that if any
problems arise during the process, the source of problem will be detected and solved at a fast rate. Heat exchangers need to be sited so that the tube bundles can be easily withdrawn for cleaning and tube replacement. Vessels that require frequent replacement of catalyst or packing should be located on the outside of buildings. Equipment that requires dismantling for maintenance, such as compressors and large pumps, should be placed under cover.
5. Safety -
Since most chemicals are hazardous and have the potential to explode in
wrong condition, blast walls may need to be built in order to separate potentially hazardous equipment and thus confine the effects of an explosion. Other than that, at least two escape routes for operator must be provided from each level in the process building and assembly point need to be built at an easy access and the emergency route need to be stated clearly.
6. Plant Expansion -
Equipment should be located so that it can be conveniently tied in with any
future expansion of the process. Space should be left on pipe alleys for future needs, and service pipes should be over-sized to allow for future requirements. Free space for plant expansion is important so that if the production rate need to be increased, more equipment should be added to the plant, thus free space will allow future expansion to be able to accommodate the equipment required. This expansion space is also very important because the additions of equipment and pipes can be erected and tested with the minimum interference to plant operations. Plant Layout Description As mentioned in the site selection section, the plant was decided to be built in Gebeng Industrial Estate, Kuantan, Pahang that was estimated to cover about 10 hectares of industrial lot ready land with price of RM16.00 per square feet. Gebeng is located in Pahang in the East coast of Malaysia. Every year Pahang experiencing Northeast Monsoon that brings rain and wind. Thus, the structure of the plant is placed in
upwind direction. The buildings need to be placed in such that the wind will not affect the plant and brings any inconvenience. Strategic placement of the buildings relative to wind direction can assist to cool down process equipment during the process. By referring to the plant layout provided in the following figure, administration building is the main and most visited building for many purposes in a plant. It should be located on the public and safe side of security point and as close as possible to main entrance. Administration offices and laboratories, in which a relatively large number of people will be working, are located well an away from potentially hazardous process which is the main processing plant. Stores for maintenance and operating supplies was placed near to the administration buildings so that the staff will have easy access to the service. There is a bottom expansion just below the main process plant and near to the waste treatment plant. This free space is provided to be used for the placement of new equipment and pipes in the future just in case the plant needs to be expanded. The waste treatment plant will enable the direct transport of waste stream produced by the separation units. There is also a pond that is placed next to the waste treatment plant. Waste treatment plant, utilities plant and tank farm were placed near to the main process plant. This placement also reduces the distance and length of supply pipes used in the transporting process of raw materials, waste, and utilities to or from the plant area, making it cost effective. Beside it, it should be beside a road which will make it easier for loading and unloading of materials. Control room was placed near to the main processing plant so that easier for the operators to monitor the operation of the plant because if the is malfunction in any of the operating process, troops can be send to the site immediately. Maintenance workshops and others that did not link to process materials should be located together at the safe area and within easy access to process units. Direct access should be provided for traffic purposes, which if possible should not pass through any process area. There is also a loading area placed for transport of goods and raw materials where only the lorries and other form of transport to transfer these materials allowed entering the area. Canteen and surau (prayer room) are also provided for the convenience of the staffs and were placed near to the administration and maintenance workshop buildings because it is one of the most used workplace and it is a must to have easy access to these places. These buildings
should be located in a safe area within a short distance of the main concentration of workers. The surrounding should be attractive and relaxing for workers to release some stress from hectic workloads. For quality control of products, a plant needs a laboratory to inspect the products produced. Work laboratories should be located at a safe area near the administration building where most facilities are completed. Clinic is placed next to the laboratory to handle any emergency case caused by chemicals. Fire house to handle emergency cases for example fire or explosion of the plant is built near to the main processing plant. Sufficient car parks facilities also provided for the convenience of the staff and personnel or visitors to park their vehicles. Car parks are placed near to the main entrance to prevent any unwanted hazard to the properties. Guard houses or security post were placed at both entrances to the plant to monitor the flow of in and out to the plant itself. There were three assembly point placed near to every section of the plant so that in case of emergency, all the people in the site can be evacuated at faster rate to these safer places. Other than those mentioned above, free lands also available at the plant layout for future needs. Trees also will be planted in the site to absorb the emission of carbon dioxide gases and also to make the site pleasant to the eye. There is no smoking area provided in this plant layout since chlorobenzene is volatile and explosive to ignition of fire, thus for safety of the plant and all personnel, smoking in the plant area are strictly prohibited. Access road will be needed to each building for construction and for operation and maintenance. General Safety Procedures For a new plant, it is very important to have sufficient site medical, fire and security services. For ensuring safety, health and welfare of all workers at the plant, Occupational Safety and Health Act (OSHA) was enacted. All contractors, employees and agents must tolerate and understand the Site Safety Rules & Regulations before starting any work. Work cannot begin until a complete site safety induction has been carried out. Safety is the most pressing issue when being evaluated in a chemical plant. It must be made the highest priority as compared to other factors such as profit. Prevention wills the best means of containing risk and danger. The plant risk reduction must be followed as strictly as possible to ensure all precautions are taken.
Some general manuals that should be followed to ensure the safety in work field and work force are listed below: 1. Each employee is expected to know and observe all plant safety procedure. All injuries, no matter how light, must be reported to the immediate Supervisor. This is to ensure the protection of each worker and assure that proper records of the accidents are made. 2. All employees are responsible for their colleagues and of their own. Broken equipment, unsafe conditions and unsafe practices must be reported to Supervisor as soon as discovered. 3. There shall be no smoking at any time within the plant area since most of the chemicals are volatile. Matches or lighters shall not be carried into the plant and must be left in locker rooms. 4. It is mandatory that all workers at the plant area to wear hard hats and safety glasses all the time. In some plant area, other protection may be required such as hearing protection. Person who do not wear this safety equipment are prohibited to enter the plant area. 5. Possession or use of liquor and illegal drugs is not permitted on the plant premises. Anyone under the influenced of either will is strictly prohibited from entering the premises. 6. Visitor must apply permission at the main office or at the security post, sign a release, and be instructed of plant safety rules before they are allowed to enter the plant. Visitor will not be taken into the plant areas that are experiencing production problems. Any visitors who do not possess the temporary entering pass cannot be around the plant site. 7. All workers must know how to use all types of fire extinguishers, fire hoses, fire blankets, and other personal protective equipment. (e.g. water must not be used on fires around the electrical equipment since water is a conductor that may result an electrocution of people).
Figure 1: Plant Layout
Economic Analysis Estimation of Capital Cost Generally, capital cost estimating has five classifications: 1. 2. 3. 4. 5.
Order of magnitude Estimate also known as Ratio or Feasibility Study Estimate, also known as Major equipment or Factored Preliminary Design Estimate, also known as Scope Definitive Estimate, also known as Project Control Detailed Estimate, also known as Firm or Contractor’s
This five classifications roughly correspond to the five classes of estimate defined in the AACE Recommended Practice No. 17R-97[4]. This part will discuss on Preliminary Design Estimate which is Class 3. For the cost estimation of a chemical plant, a Class 3 estimate is typically +10% to -40% accurate. This means by doing such an estimate, the true cost of building the plant would likely be in the range of 0.1 higher than and 0.4 lower than the estimated price. If greater accuracy is required in the capital cost estimate, then more money and time must be expended in conducting the estimate.
Estimation Of Purchased Equipment Costs The purchased cost and an attribute of the equipment are the most common simple relationship related to units of capacity and it is given by (
)
Where: A = Equipment cost attribute C = Purchased cost N = Cost exponent Subscripts : a refers to equipment with the required attribute b refers to equipment with the base attribute
Effect of Time on Purchased Equipment Cost The cost of equipments are depend on past records or published correlations for price information, it is essential to be able to update these costs to take into account changing economic conditions(inflation). This can be achieved by using the following expression: C2 = C1( ) Where: C= Purchased cost I =Cost Index Subcripts: 1 refers to base time when cost is known 2 refers to time when cost is desired Calculation for Cost of Equipments log10 Cp0= K1 + K2 log10 A + K3 (log10 A)2 The value of K1,K2, and K3 can be obtained from Table A.1 and A is the capacity of the equipment.
FBM= B1 + B2FMFP B1 and B2 can be obtained from Table A.4 FM can be obtained by referring the Table A.3 for the identification number for the material and then refer the material factor at Figure A.8 FP can be obtained by two methods which are 1. For process vessel, FP,vessel =
[
]
⁄
2. For other equipment Log10 FP = C1 + C2log10P + C3(log10P)2 Value of C1,C2, and C3 can be obtained from the Table A.2 and P is the unit pressure of bar gauge or barg. CBM = CPOFBM
Sample of Calculations Calculations for heater: Characteristics:
2 units of heater with different types H1 Duty = 1307 kW H2 Duty = 1501 kW Type = H1 - Steam boiler heater and H2 - Hot water heater Type = Carbon Steel Identification Number = 53
Based on the Figure A.4,
= 196 $/kW and
= 48.2$/kW
Based on Figure A.19, FBMH1 = FBMH2 = 2.1 Hence, CBMH1 =
FBMH1
= (196 $/kW)(1307 kW)(2.1) = $538120 CBMH2 =
FBMH2
= (48.2 $/kW)( 1501 kW)(2.1) = $152097 Thus, $H1(2013) = $538120(
⁄
)
= $765431.65 = RM 2,518270.12 $H2(2013) = $152097(
⁄
)
= $216, 345.53 = RM 711, 776.80
Calculations for reactor: Characteristics:
Two reactors with same type
Length = 8 , diameter = 4m
Volume of tower = 100 m3
Type = carbon steel Log10
= 3.4974 + 0.4485log10(100) + 0.1074[log10(100)]2 = $66680.68 $tower(2013) = $66680.68 (
⁄
)
= $94847.80 Based on Table A.4, B1 = 2.25, B2 = 1.82 Fpvessels =
4 [
4 4 ]
= 1.77 FBM = 2.25 + 1.82(1.77)(1) = 5.47 CBM = ($94847.80)(5.47) = $519,450.21 Thus, $REACTOR(2013) = $519,450.21 (
⁄
)
= $738875.40 = RM 2,430,900.00 For two reactors = RM 4,861,800.00
Calculations for separator 3 units Characteristic = Flash distillation Diameter
= 1.8 m
Height
=5m
Volume
= 50.89 m3
log10 Cp
= 3.4974 + 0.4485 (log10 50.89) + 0.1074 (log10 50.89)2 Cp0= $37644.95
Fpvessels =
[
= 0.5021
]
FP = 0.84 Based on Table A.4, B1 = 2.25, B2 = 1.82 and FM = 1.0 (carbon steel) FBM = 2.25 + 1.82(0.84)(1) = 3.779 CBM = ($37644.95)(3.779) = $142252.74 $SEP(2013) = $142252.74(
⁄
)
= $202342.87 = RM 605,708.00
Calculation for storage tank Characteristics: 4 units of different types of storage tanks:
Dimensions for benzene, Length=10 , Diameter= 4.8 For 3 days storage,Volume = 182 m3 Type = floating roof
Log10
= 5.9567 – 0.7587log10(182) + 0.1749[log10(182)]2 = $136571.32 $tower(2013) = $136,571.32 (
⁄
)
= $194,261.52 = RM 639,120.00
Dimension for chlorine, Length =10m , Diameter =4.8m Volume = 182m3 Type = fixed roof
Log10
= 4.8509 – 0.3973log10(182) + 0.1445[log10(182)]2 = $49,098.53 $tower(2013) = $49,098.53 (
⁄
= $69,838.64 = RM 229,769.00
)
Dimesion for chlorobenzene, Dimensions , Diameter = 4.4 m, Length = 10 Volume for storage 3 days of = 150 m3 Type= floating roof
Log10
= 5.9567 – 0.7587log10(150) + 0.1749[log10(150)]2 = $136,118.24 $tower(2013) = $136,118.24 (
⁄
)
= $193,617.05 = RM 637,000.00
Dimension for Dichlorobenzene, Dimensions = , Diameter = 2m, Length = 5 m Volume = 15 m3 Type = floating roof Log10
= 5.9567 – 0.7587log10(15) + 0.1749[log10(15)]2 = $39,810.70 $tower(2013) = $39,810.70 (
⁄
)
= $56,627.49 = RM 186,304.00
Calculation for distillation column One unit of distillation column
Dimensions, Diameter = 3m, Length = 30m
Volume = 212.1 m3 Log10
= 3.4974 + 0.4485log10(212.1) + 0.1074[log10(212.1)]2 = $132500
(2013) = $132500 (564.7/397) = $188,470.40
Based on Table A.4, B1 = 2.25, B2 = 1.82 Fpvessels =
[
]
= 1.26 Hence, FBM = 2.25 + 1.82(1.26)(1) = 4.54 CBM = ($188470.40)(4.54) = $856,258.72 Tray tower area = 7.0686 m3 Log10
= 2.9949 + 0.4465log10(7.0686) + 0.3961[log10(7.0686)]2 = $4570 (2013) = $4570(564.7/397) = $6,500.45
Thus, CBMtray = CpNFBMfq = ($6500.45)(24)(1)(1.0) = $156010.82
CBM,tower + trays = $856,258.72 + $156010.82 = $1,012,269.54
$DC(2013) = $1012269.54(
⁄
)
= $1,439,870.55 = RM4,737,174.00
Equipment identification
No.
Actual bare module cost, CaBM 00 (RM)
Heater
H1
2,518,270.00
H2
711,776.00
Cooler
CO1
417,463.00
Separator
S1
605,708.00
S2
605,708.00
S3
605,708.00
R1
2,430,900.00
R2
2,430,900.00
Distillation column
D1
4,737174.00
Tank
T1
639,120.00
T2
229,769.00
T3
637,000.00
T4
186,304.00
Reactor
Total bare module cost, CBM (RM)
16,755,800.00
∑
= 1.18 x (RM16,755,800.00)
= RM 19,771,844.00 Grass roof capital cost, (GRC) = RM28,493,713.00 Table: Estimation of fixed and total capital investment cost
Range
Cost (RM)
Purchased equipment cost
12% GRC
3,419,245
Instrumentation and control
6% GRC
1709622.80
Piping (installed)
15% GRC
4274056.95
Electrical and material (installed)
3% GRC
854795.20
Building
8% GRC
2279497.04
Yard improvements
1% GRC
284937.13
Service facilities
5% GRC
1424685.65
Land
2% GRC
569874.26
Direct cost Onsite
Offsite
Total
14,816,714.03
Indirect cost Engineering and supervision
3% GRC
854795.20
Construction expenses
6% GRC
1709622.80
Contractor’s fee
1% GRC
284937.13
Contingency
8% GRC
2279497.04
Total Fixed Capital Investment (FCI)
5,128,852.17 TOTAL + GRC
48,439,279.20
Manufacturing Cost Factors affecting the cost of manufacturing (COM), for a chemical Product Factor 1.Direct cost A. Raw materials
Description of Factor Factors that vary with the rate of production Costs of chemical feed stocks required by the process. Flowrates obtained from the PFD
B. Waste treatment
Cost of waste treatment to protect environment
C. Utilities
Costs of utility streams required by process. Includes but not limited to: a. Fuel gas b. Electric power c. Steam(all pressures) d. Cooling water e. Process water f. Boiler feed water g. Instrument air h. Inert gas (nitrogen) etc. i. Refrigeration
D. Operating labor
Costs of personnel required for plant operations
E.Direct supervisor and clerical labor F.Maintenance and repairs
Cost of administrative/ engineering and support personnel
G. Operating supplies
H. Laboratory charges
Costs of labor and materials associated with the maintenance Costs of miscellaneous supplies that support daily operation not considered to be raw materials. Examples include chart paper, lubricants, miscellaneous chemicals, filters, respirators and protective clothing for operators, etc. Costs of routine and special laboratory tests required for product quality control and troubleshooting. Costs of using patented or licensed technology.
I. Patents and royalties 2. Fixed costs A. Depreciation
B. Local taxes and Insurance
Factors not affected by the level of production Costs associated with the physical plant (buildings, equipment, etc.). Legal operating expense for tax purposes. Costs associated with property taxes and liability insurance. Based on plant location and severity of the process.
C. Plant overhead costs (sometimes referred to as factory expenses)
3. General expenses A. Administration costs
B. Distribution selling costs C. Research and development
and
Catch-all costs associated with operations of auxiliary facilities supporting the manufacturing process. Costs involve payroll and accounting services, fire protection and safety services, medical services, cafeteria and any recreation facilities, payroll overhead and employee benefits, general engineering, etc. Costs associated with management level and administrative activities not directly related to the manufacturing process Costs for administration. Includes salaries, other administration, buildings, and other related activities. Costs of sales and marketing required to sell chemical products. Includes salaries and other miscelleaneous costs. Costs of research activities activities related to the process and product. Includes salaries and funds for research related equipment and supplies, etc.
The equation used to evaluate the cost of manufacture using these costs becomes: Costs of Manufactures (COM) = Direct Manufacturing Costs (DMC) + Fixed Manufacturing Costs(FMC) + General Expenses (GE) The cost of manufacturing, COM, can be determined when the following costs are known or can be estimated : 1. Fixed capital investment (FCI) : (CTM or CGR) 2. Cost of operating labor (COL) 3. Cost of utilities (CUT) 4. Cost of waste treatment (CWT) 5. Cost of raw materials (CRM) The table above gives data that are need to calculate to estimate the individual cost items that are identified above. With the exception of the cost of raw materials, waste treatment, utilities, and operating labor all the data need to be calculate by using certain equations. If no other information is avalaible, the midpoint values for each of these ranges is used to estimate the costs involved. Hence, all the summation of the datas for the calculation of manufacturing cost ca be simplified into these equations : DMC = CRM+ CWT + CUT + 1.33COL + 0.069FCI + 0.03COM FMC = 0.708COL + 0.069FCI + depreciation GE = 0.177COL + 0.009FCI + 0.16COM We can obtain the total manufacturing cost by adding these three categories together and solving for the COM and the result is :
COM = 0.280FCI + 2.73COL + 1.23(CRM+ CWT + CUT) The cost of manufacture without depreciation : COMd = 0.180FCI + 2.73COL + 1.23(CRM+ CWT + CUT)
Cost of operating labor, COL The technique used to calculate operating labor requirements is based on data obtained from five chemical companies and correlated by Alkayat and Gerrard. According to this method, the equation for the operating labor requirement for a chemical processing plant is given by: NOL= (6.29 + 3.17P2 + 0.23Nnp)0.5 Where NOL is the number of operators per shift, P is the number of processing step involving the handling of particulate solids, and Nnp is the number of nonparticulate processing steps handling steps includes compression, heating and cooling, mixing, and reaction. Nnp = ∑ Equipment Compressor Tower Reactor Heater Exchanger Total
Quantity 0 1 2 2 3 8
Hence, when Nnp is equal to … , the number of operating labor requirement is NOL= [ NOL =2.85
]0.5
The value of NOL is the number of operators required to run the process unit per shift. A single operator works on the average 49 weeks (3 weeks time off for vacation and sick leave) a year, five 8-hour shift a week. = 49 week/yr
5 shift/week
= 245 shifts per operator/year A chemical plant operates 24 hours per day. This requires (365 days/year 3 shift/day) 1095 operating shifts per year. The number of operators needed to provide this number of shifts is
= 1095 shift/year
245 shifts per operator/year
= 4.5 operators Hence, the operating labor = NOL =2.85
4.5 operators
4.5
= 12.8 The cost of operating labor, COL is equal to the salary given to each of operator yearly which in this case the yearly salary given is RM18,000 COL = RM18,000
13
=RM 234,000.00
Cost Of Utilities Utility Stream
Description Dry saturated a. 8 bar b. 28 bar
Cooling water
Process cooling water: 550C to 200C
Other water
High purity water for process use at 20 0C
Caustic soda solution
5 wt % NaOH at 20 0C
Cost (RM/GJ)
Cost RM/Common Unit
20.003 22.602
41.717/1000kg 45.106/1000kg
1.165
48.69/1000m3 1.03/m3
1414.7/tonnes
Waste treatment and Non-hazardous disposal (water)
118.44/tonnes
Production of waste water = 0.142 kmol /hr x 18 kg/kmol = 2.558 kg/hr = 2.588 kg/hr x 24 hr/day x 365 day/year x 1 tonnes/1000kg = 22.6709 tonnes/year Cost for waste water treatment and disposal = 22.6709 tonnes/year x $36/tonnes = $816.15/year = RM 2,685.15
Raw Material Costs The cost of raw materials can be estimated by using the current price listed in such publications as the Chemical Market Reporter (CMR) at the middle of 2013. Chemical
Cost (RM/kg)
Benzene
1.3681
Typical Shipping Capacity or Basis for Price Barge, Gulf Coast
Chlorine
0.2156
Railroad tank car
Yearly cost for raw materials = (Mass flow rate of raw materials per year) x (cost, RM/kg) Yearly cost for benzene = (2216.76 kg/h x 24 x 330) x (1.3681) = RM 24,019,374.90 Yearly cost for chlorine = (0.6212 kg/h x 24 x 330) x (0.2156) = RM 1060.73 Total cost for raw materials, CRM = RM 24,019,374.90 + RM 1060.73 = RM 24,020,435.63
Yearly Cost and Stream Factor Manufacturing and associated costs are most often reported in terms of RM/yr. The fraction of time that the plant is operating in a year must be known in oreder to calculate the yearly costs of raw materials or utilities. This fraction is known as the Stream Factor(SF), where : Stream Factor (SF) = =
= 0.904
COM = 0.280FCI + 2.73COL + 1.23(CRM+ CWT + CUT) = 0.280(48,439,279.20) + 2.73(234,000.00) +1.23(24,020,435.63 +2,685.15 + 1,738953.39 ) = RM 45,889,169.41 COMd = 0.180FCI + 2.73COL + 1.23(CRM+ CWT + CUT) = 0.180(48,439,279.20) + 2.73(234,000.00) +1.23(24,020,435.63 + 2,685.15 + 1,738953.39) = RM 41,045,241.49
Profitability analysis Assumption Land: RM 17,222,400.00 Salvage value: RM 10,000000 Taxation rate: $45% Plant life: 10 years
Non discounted cash flow Working capital = labor cost + utility cost + raw material cost + waste treatment Working capital = RM 234,000.00 + RM 1,738953.39 + RM 24,020,435.63 +RM 2,685.15 = RM 25,996.074.17
Total fixed capital investment, FCI: RM 48,439,279.20
END OF YEAR (K)
INVESTM ENT RM
RM
R RM
RM
CASH FLOW RM
RM
CUMULA TIVE CASH FLOW RM
RM 0 1 2 3 4 5 6 7 8 9 10 11 12
-17222400 -48439279 -25996074 -9687856 -15500569 -9300342
-48439279 -48439279 -48439279 -38751423 -23250854 -13950512
-5580205 -5580205 -2790102
-8370307 -2790102 0
38912874
1316000000 1316000000 1316000000
41045241 41045241 41045241
45889169 45889169 45889169
694201422 691585701 694375803
-12916800 -48439279 -25996074 694201422 691585701 694375803
1316000000 1316000000 1316000000 1316000000 1316000000 1316000000 1317000000
41045241 41045241 41045241 41045241 41045241 41045241 41045241
45889169 45889169 45889169 45889169 45889169 45889169 45889169
696049865 696049865 697305411 698560957 698560957 698560957 699110957
696049865 696049865 697305411 698560957 698560957 698560957 738023831
Payback period Find the value of $PBP =
in cumulative cash flow 4 4
4
Cumulative cash Position CCP= RM 7012801172 Cumulative cash ratio
-1342.2413 ROROI
-14.3775
4 4
Discounted cash flow END OF YEAR
NON DISCOUNTED CASH FLOW $
0 1 2 3 4 5 6 7 8 9 10 11 12
DISCOUNTED CASH FLOW $
-17222400 -48439279 -25996074 694201422 691585701 694375803 696049865 696049865 697305411 698560957 698560957 698560957 738023831
-17222400 -44035708 -21484359 521563803 472362339 431152742 392902003 357183639 325298120 296258038 269325489 244841354 235157137
Discount rate: 10% p.a Discounted payback period Discounted value of land + working capital
Find the value -
in the cumulative cash flow Discounted payback period
Net present value NPV= RM 3552745510 Present value ratio PVR
-665.68777
CUMULATIVE DISCOUNTED CASH FLOW $ -17222400 -61258108 -82742467 438821336 911183675 1342336417 1735238420 2092422059 2417720179 2713978217 2983303706 3228145060 3463302197
Hazard Analysis Handling and Storage Chlorobenzene need to be stored in a cool, dry, well-ventilated area in tightly sealed containers that are labelled according to the OSHA’s hazard communication standard [29 CFR 1910.1200]. Outside or detached storage is highly preferable; however, if inside storage is to be used, the storage should be in a standard flammable liquids storage room that meet OSHA requirements. The containers used to store chlorobenzene need to be protected from any possible physical damage and should be stored separately form oxidizers, dimethyl sulfoxide, silver perchlorate, other incompatible chemicals, heat, sparks and open flame as cholorobenzene is categorized as rate 3 flammability which is severe fire hazard. All source of ignition must be eliminated. Thus, only non-sparking tools can be used to handle chlorobenzene as static electricity and formation of sparks must be prevented. The optimum temperature condition for the storage of chlorobenzene is between 16°C and 26°C; and it must be stored away from direct sunlight and moisture. The containers should also be grounded and bonded together for transfer in order to prevent static sparks. In addition, the containers previously used to store chlorobenzene need to be handle or disposed appropriately as it may still hold product residues. Health Effect According to Occupational Safety and Health Administration (OSHA), the current permissible exposure limit for chlorobenzene is 75 ppm (350 mg/m3). The routes for the exposure of chlorobenzene mainly occur through inhalation, ingestion, and eye or skin contact. Chlorobenzene also mainly absorbed through the gastrointestinal and respiratory tracts, and dermal absorption. Chlorobenzene is lipophilic and has a tendency to accumulate in lipid-rich tissues in animal and humans. The effect of chlorobenzene to animals is irritation, narcosis, liver and kidney damage. However, fatal effect may occur at high concentration of chlorobenzene. For humans, if chlorobenzene is exposed at the concentration of 200 ppm, eye and nose irritation will occur and at high concentration, central nervous system depression will take place. If liquid chlorobenzene is just briefly in contact with skin, mild irritation occur, however if prolonged or repeated contact happened, burning of the skin will occur. The toxic effects of chlorobenzene on
humans were exhaustion, nausea, lethargy, headache and irritation to the upper respiratory tract and eye. Chlorobenzene is considered toxic and many studies conducted have found that the toxic effect of chlorobenzene on organisms in the environment includes mortality, immobilization and growth inhibition. The targeted organs for exposure of chlorobenzene are mainly kidneys and liver. Environmental Release Chlorobenzene does not occur naturally. It enters the atmosphere as fugitive emissions from the pesticide industry and from other industries that use it as a solvent (Howard 1989). Release of the chemical also occurs during the disposal of industrial wastes (Howard 1989). Concentrations of chlorobenzene in the atmosphere have typically ranged from < 0.02 ppb for remote areas to 0.8 ppb in cities; the maximum reported value measured was 12 ppb (Howard 1989). Chlorobenzene is volatile (vapor pressure, 11.7 mm Hg) and slightly soluble in water (466.3 mg/L). The most important transport process for chemical from water and soil is evaporation. If chlorobenzene is released to moist soil, it will evaporate to the atmosphere; and if it is released to sandy soil, chlorobenzene will leach into the groundwater. Chlorobenzene will biodegrade very slow and might not degrade at all and remains in the environment. If exposed to the air, the half-life of chlorobenzene is to be about 9 days or sometimes 20 to 40 hours under simulated atmospheric conditions. Usually, the chlorobenzene is removed from the atmosphere through reaction with hydroxyl radicals forming microbiophenyl and photolysis reaction. When exposed to the water, the chlorobenzene will have a half-life about 0.3 days in a river, and about 1 to 12 hours in a rapidly flowing stream. Chlorobenzene is removed from the water through vaporization and biodegradation processes. And if exposed to the soil, it will have a half-life f 0.3 days is exposed to soil at depth 1 cm and 12.6 days at depth 10 cm. Main removal of chlorobenzene from the soil surface is through evaporation. Disposal Since it is possible for chemicals waste to enter the environment if waste incinerated, land filled or just drained, it is important to keep them out of municipal waste stream. Since, chlorobenzene is known as hazardous and toxic chemicals, proper treatment and disposal method need to be
made. The waste disposal facility should be approved by the local authorities; and care should be taken to ensure the disposal meet the regulatory requirements or local environmental laws. Chlorobenzene is listed as a hazardous substance, thus the disposal of it is very strict and is controlled by the federal regulations. Disposal of chlorobenzene into the soil (landfill) is very restricted, except under specific conditions. It is not suitable for disposal by either landfill or via local sewers, drains, natural streams or rivers. Wastes containing chlorobenzene may be disposed by liquid injection, rotary kiln, or fluidized bed incineration. Since chlorobenzene is widely used as a solvent in many chemical processes and it is a volatile compound, most of the waste is released to the atmosphere, few wastes were found in wastewater and land. Thus, the air plays a large role in the environmental transport and degradation of chlorobenzene. For container disposal, the container must be first drained thoroughly. After draining, it should be store in a safe place away from sparks and ignition of fire because the residues of chlorobenzene that still attach to the wall of the container may cause an explosion hazard. Disposal of container and unused contents must be in accordance to local regulatory requirements and environmental laws.
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from
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(2013).
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and
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from
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and
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from
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–
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and
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Appendices