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Continental Oil Company Engineering Department P<pica City, Oklahoma DTH 000096928 OPERATING MANUAL D-7QO PVC REACTORS ABERDEEN. MISSISSIPPI September 23, 1977 OMaJ- (Lk Work by: Albert R. Peck Process Engineer Chemicals Division Process Engineering Department David L. Hester Process Engineer Chemicals Division Process Engineering Department Approved by: ^J. Robert Rolfes Senior Process Engineer Chemicals Division Process Engineering Department DTH 000096929 TABLE OF CONTENTS OPERATING MANUAL D-700 PVC REACTORS ABERDEEN. MISSISSIPPI I. INTRODUCTION A. Operator Responsibilities . . . B. Process Information ....................... 1. Evacuation 2. Charge 3. Initiator 4. Polymerization 5. Recovery and Steam Stripping 6. Dumping II. GENERAL PROCESS DESCRIPTION A. Evacuation ......................................... B. Charge ................................................. 1. Precharge Preparations 2. Reactor Charge C. Polymerization ................................ D. Recovery and Steam Stripping . 1. Recovery 2. Steam Stripping 3. Hydroquinone Injection 4. Recovery of Blowdown Tank E. Reactor Dump and Rinse .... F. Chem Wash and Rinse ...................... G. Water Swirl ... ........................... H. Blowdown Collection System . . III. OPERATING PROCEDURES A. Reactor Evacuation ....................... B. Reactor Precharge ........................... 1. Lead Operator Duties 2. "A" Operator Duties Page No. 1 3 5 5 9 12 16 17 18 19 21 25 DTH 000096930 Table of Contents Operating Manual D-700 PVC Reactors Page 2 III. OPERATING PROCEDURES (CONTINUED) Page No. C. Reactor Charge.............................................................................................. 29 D. Polymerization......................................................... 1. Lead Operator Duties 2. "A" Operator Duties 3. Emergency Shutdown 34 E. Recovery and Steam Stripping............................................................... 1. "A" Operator Duties 2. Lead Operator Duties 3. Recovery System Troubleshooting 40 F. Reactor Dump and Rinse ............................................................................ 1. "A" Operator Duties 2. Lead Operator Duties 47 G. Chem Wash and Rinse............................................ 49 H. Full and Partial Swirl............................................................................ 1. Full Swirl 2. Partial Swirl 53 I. Colloid Solution Makeup ........................................................................ 1. Lead Operator Duties 2. "A" Operator Duties 54 J. Hydroquinone Solution Makeup ............................................................... 1. Lead Operator Duties 2. "A" Operator Duties 3. Safety Precautions 59 K. Used Chem Wash Solution Disposal...................................................... 62 L. Initiator Handling and Storage .......................................................... 1. Safety Precautions In Handling 2. Physical Characteristics 3. Initiator Storage Freezers 4. Design and Operational Functions 5. Daily Operational Checks 6. Emergency Procedure for Catalyst Freezers 7. Circle Chart Responsibility and Change Schedule 64 DTH 000096931 Table of Contents Operating Manual D-700 PVC Reactors Page 3 III. OPERATING PROCEDURES (CONTINUED) Page No. M. Reactor Pressure Check ............................................................................ 72 N. Reactor Cleaning and Entry ................................................................... 1. Reactor Manhead Opening Procedures 2. Reactor Cleaning and Entry 74 O. Housekeeping Guidelines.............................. 78 IV. EQUIPMENT INDEX.............................................................................................. . 80 V. INSTRUMENT INDEX......................................................................................................... 114 VI. ALARMS AND SAFETY EQUIPMENT A. Continuous Flow Fresh Air System........................................................... 120 B. Alarms and Switches......................................................................................122 C. Firewater System..................................................... 1. Fire Monitors 2. Hydrocarbon Analyzers 3. Deluge System 130 D. Fixed Point Monitors ................................................................................. 131 VII. EQUIPMENT OPENING PROCEDURES ......................................................................... 132 VIII. APPENDIX A. Equipment List B. Instrument List C. VCM Emergency Plant D. P&I Diagrams DTH 000096932 DTH 000096933 OPERATING MANUAL D-700 PVC REACTORS ABERDEEN. MISSISSIPPI I. INTRODUCTION A. Operator Responsibilities The purpose of this plant is to safely and economically convert vinyl chloride monomer (VCM) Into a useable form of poly vinyl chloride (PVC). This is accomplished by a batch process in which VCM, water, initiator and colloid solution are charged into the reactor and under carefully controlled conditions, PVC with the desired physical properties is produced. This chemical reaction, which changes VCM to PVC, is called polymerization. The operator helps fulfill the plant's purpose by making sure that quality production is obtained from his equipment without endangering his fellow workers or his equipment. The operator is able to attain his goals in safety, job performance and efficient operation through a training period and on the job experience. The operator fulfills his responsibilities by: 1. Understanding how his equipment functions. 2. Understanding what role each piece of equipment plays in the process. 3. Keeping a close and regular check on equipment. 4. Knowing how to spot malfunctions and correct them. 5. Keeping his area of responsibility safe and clean. 6. Keeping complete and accurate records. DTH 000096934 Operating Manual D-700 PVC Reactors Page 2 I. INTRODUCTION (CONTINUED) A. Operator Responsibilities (Continued) The operating Manual will cover the normal responsibilities and duties of the Lead Operator and the Reactor "A" Operator. Each phase in the production method will be covered. In addition to normal operating methods, it will also discuss operations under abnormal and emergency conditions. The operator must be prepared to meet these situations with temporary measures until the abnormal condition is corrected or the emergency crisis ceases to exist. Safety takes second place to no plant activity. The safety of the plant personnel and equipment is to be carefully considered before any job is started. The Conoco safety slogan, "our work is never so urgent or inqportant that we cannot take time to do it safely", is an idea that can help make the work area safer for everyone when it is put into practice. Good housekeeping is also an Important responsibility of the operators. It requires careful attention for safety reasons and to maintain good working conditions. Cleaning up after job completion is the responsibility of the person doing the job. A job should not be considered complete until all materials are picked up and properly stored. DTH 000096935 Operating Manual D-700 PVC Reactors Page 3 I. INTRODUCTION (CONTINUED) B. Process Information Several types of resins are produced. Resin type is determined by a set of physical properties such as particle size and viscosity. Each type of resin produced requires that a certain set of operating conditions be closely followed so that the desired resin properties are obtained. Minor changes in formulas or operating conditions can cause major differences in the physical properties of the resin. Some factors in determining resin properties are reaction temperature, which helps determine viscosity, colloid, which influences particle size, and the amount of recovered VCM charged, which also effects particle sice. The phases of reactor operation and a brief description of each follows: 1. Evacuation This step removes all air possible by steam eductors. Too much air left in a reactor will alter particle size. Evacuation should require about five minutes. 2. Charge Water, Colloid and VCM are charged to the reactor simultaneously through a timed sequence system. The temperature of the reactor contents at the end of charging is determined by the charge water temperature. The reactor will be below run temperature at the end of the charge and jacket steam will be used to raise the temperature t-o the desired level. Charge should take about nine minutes. DTH 000096936 Operating Manual D-700 PVC Reactors Page 4 I. INTRODUCTION (CONTINUED) B. Process Information (Continued^ 3. Initiator Hie Initiator is manually loaded into the initiator injection pot and charged into the reactor after reactor charge is complete. 4. Polymerisation This is the time from the initiator addition until most of the VCM has been converted to resin. The reaction generates heat continuously as liquid VCM becomes PVC resin. Heat that is generated is removed by cooling water on the reactor jacket and condenser. Reaction times varies, but generally requires five to six hours. 5. Recovery and Steam Stripping Recovery and steam stripping removes most of the un-reacted VCM from the reactor via a compressor-vacuum pump system. Steam is added to the bottom of the reactor and rises through the PVC and water slurry to help remove unreacted VCM. Recovery and steam stripping takes about 40 minutes. 6. Dumping The PVC resin, after reaction is complete, is in a slurry form. The slurry is dumped to a strainer and dump tank and is pumped to blend tanks in the Dryer Room for drying. Dump requires about 25 minutes. DTH 000096937 DTH 000096938 Operating Manual D-700 PVC Reactors Page 5 II. GENERAL PROCESS DESCRIPTION A. Evacuation Before charging, the inerts present in the polymerization reactor are removed by evacuation. The interlock selector switch is placed on "evacuation" position. The main condenser valve is opened and the evacuation valve is opened, which automatically starts the reactor steam ejector. Any condensate in the steam to the ejector is removed by a cyclone separator. The emergency cooling water supply valve to the reactor is then opened. When the reactor pressure reaches 28.5 inches of mercury vacuum, as indicated by the pressure Indicator in the control room and at the reactor, evacuation is complete. This portion of the cycle requires about five minutes. ' B. Charge 1. Precharge Preparations After evacuation, the reactor is ready to be charged. In preparation for charge, adequate quantities of VCM, hot water, colloid solution, and Initiator are made ready for the charge sequence. Prior to charge, fresh VCM is transferred from the VCM storage sphere to the fresh VCM storage tank. This transfer of VCM begins automatically when the VCM liquid level falls below a certain level. When the high liquid level is regained, the transfer process shuts down automatically. Two 200 gpm VCM transfer pumps are used to transfer the VCM from the VCM storage sphere. t DTH 000096939 Operating Manual D-700 PVC Reactors Page 6 II. GENERAL PROCESS DESCRIPTION (CONTINUED) B. Charge (Continued) 1. Precharge Preparations (Continued) Process water is automatically supplied to the hot water tank when the water level drops below a certain point. The water is filtered by the process water filter, and is heated in the hot water preheater, enroute to the hot water tank. The hot water tank temperature is maintained by the external steam coils on the hot water tank. The colloid solution, previously madeup, remains in the makeup tank until there is less than one reactor charge remaining in the colloid storage tank. The colloid is then pushed from the makeup tank through the colloid transfer filter to the colloid storage tank. While this transfer takes place, the colloid circulation pump is used to mix the new colloid with the colloid remaining in the storage tank. When the solution is transferred the pumps are shut down and a sample is taken to the laboratory for analysis. After each reactor charge, colloid is transferred at 50 gpm from the storage tank to the colloid charge tank by the colloid circulation pump. When the storage tank contains less than one charge, the full charge tank will contain sufficient colloid to charge seven reactors. The colloid charge tank can be emptied to less than one charge irtiile the new colloid solution is being transferred and analyzed. DTH 000096940 Operating Manual D-700 PVC Reactors Page 7 II. GENERAL PROCESS DESCRIPTION (CONTINUED) B. Charge (Continued) 1. Precharge Preparations (Continued) Immediately before the reactor is to be charged, the initiator injection system is made ready for charge in the following manner. First, the initiator injection pot is drained to the sewer. Enough water is manually added from the board so that the pot will be full after the initiator has been added. The initiator is then manually added to the initiator injection pot. The pot is then blocked in and pressurized with high pressure service water to at least 180 psig. The initiator injection system is now ready for the next reactor charge. 2. Reactor Charge After evacuation is completed, the interlock selector switch is moved to the "charge" position. If the following precharge conditions are met, the charge sequence is ready to begin: a. Levels in the fresh VCM storage tank, the hot water tank, and the colloid charge tank are adequate for a complete reactor charge. b. There is sufficient pressure in the Initiator Injection pot and in the high pressure service water header. c. The charge meters are reset to the charge quantities. Steam is usually applied to the reactor jacket at the start of charge by manually opening the steam valve from the Control Room. DTH 000096941 Operating Manual D-700 FVC Reactors Page 8 II. GENERAL PROCESS DESCRIPTION (CONTINUED) B. Charge (Continued) 2. Reactor Charge (Continued) This aids in heating the reaction mass to the desired temperature during and immediately following charge. The automatic charge sequence begins with the hot water charge. The hot water is pumped from the hot water tank, to the reactor by the hot water charge pump. After a predetermined quantity of hot water has been charged, the colloid charge pumps and the second hot water charge punq> start. The next step in the charge sequence begins with the fresh and recovered VCM charges. The fresh VCM is pumped to the reactor from the fresh VCM storage tank, by one of the two VCM charge pumps. The recover ed VCM is punqied from one of two recovered VCM storage tanks by the recovered VCM charge pump into the suction of the VCM charge pump. The recovered VCM is filtered in the recovered VCM filter and the total VCM charge is filtered enroute to the reactor by the VCM charge filter. Shortly after the beginning of the VCM charge, one of the hot water charge pumps shuts down until the VCM charge is com pleted and then restarts. This insures that there will be an adequate amount of water charge remaining to flush out the charge line. Both hot water charge pumps continue to run until charge is completed. DTH 000096942 Operating Manual D-700 PVC Reactors Page 9 II. GENERAL PROCESS DESCRIPTION (CONTINUED) B. Charge (Continued) 2. Reactor Charge (Continued) When the VCM, water and colloid charge Is complete, the Initiator Is charged by opening the Initiator charge valve from the Control Room. Loading the Initiator and preparation of the Initiator charge pot was discussed In the precharge preparations section. C. Polymerisation After charge Is completed, the reactor Interlock selector switch Is placed In the "polymerisation" position, and the reactor temperature controller is placed on automatic. When the reaction mass reaches the desired temperature the steam is turned off. The reaction mass temperature Is automatically controlled by varying the amount of cooling water that is passed through the top-mounted knockback condenser and the reactor jacket. The reaction mass is continually mixed and kept in suspension by the bottom-mounted single speed agitator. The agitator mechanical seals are lubricated and cooled by seal oil from a seal oil pressure unit. During polymerisation, mechanical seal purge water is injected into the reactor through che reactor cleaning nossle and Inboard of the agitator mechanical seal. The water is added to keep the reactor DTH 000096943 Operating Manual D-700 PVC Reactors Page 10 II. GENERAL PROCESS DESCRIPTION (CONTINUED) C. Polymeriaation (Continued) cleaning nozzle and agitator mechanical seals clean. The purge water flow for each service is indicated with a rotameter and manually adjusted. The inerts present in the reactor during polymerization accumulate in the reactor condenser head space. These inerts are vented to the recovery system to prevent inert blanketing. Approximately one and one~half hour after the beginning of each polymerization cycle, a sample of resin is taken. The sample is checked for unusual resin conglomerates which indicate a potentially bad batch. If these resin conglomerates occur, several more samples are taken. Depending on the severity of the problem, the batch may be killed early or the resin may be Isolated after recovery. Before the sample is taken, the blowdown tank is recovered if it is not already under vacuum. To take a resin sample, the one-hour resin sampler is attached to the appropriate reactor sampling line and the valve opened until the sampling pressure gauge reads 60 psig. The sampling system lines are cleared of VCM vapors and resin by evacuating to the blowdown tank and flushing with water. The sampling system lines are then vented to the atmosphere and the sampler disconnected. The resin is removed from the sampler by removing the screen insert. DTH 000096944 Operating Manual D-700 PVC Reactors Page 11 II. GENERAL PROCESS DESCRIPTION (CONTINUED) C. Polymerization (Continued) When the desired degree of polymerization is reached and the reactor pressure has dropped to the desired pressure, the reaction is stopped by manually adding a mixture of AMS, BHT and OMS (the short stop solution) to the reactor. High pressure service water is used to pressure the short stop solution from the AMS short stop charge pot into the reactor through the same piping as the agitator mechanical seal purge water. The AMS short stop charge pot is then blocked in and refilled with the short stop solution. This system is also used to "kill" runaway reactions. A nitric oxide (NO) short stop addition system is provided to inject NO into the reactors in the event of power failure, major VCM re leases, fires, or other emergencies. The system is activated either locally or from the control room. NO is supplied from the emergency NO short stop bottles and is injected into the reactor through the same piping as the agitator mechanical seal purge water. D. Recovery and Steam Stripping 1. Recovery When reaction is completed, the interlock selector switch is moved to the "recovery and steam stripping" position. The following sequence then occurs. The recovery compressor seal water systems, the water recirculation systems for the recovery knockout drums, and two of the three recovery compressors are DTH 000096945 ' Operating Manual D-700 PVC Reactors Page 12 II. GENERAL PROCESS DESCRIPTION (CONTINUED') D. Recovery and Steam Stripping (Continued) 1. Recovery (Continued) manually started from the board. Cooling water to the re covered VCM condenser and the water recirculation cooler starts automatically with the compressors, and the hydroquinone e injection system starts with the compressor seal water systems. The vapor from the reactor flows through a pressure control valve to two resin knockout drums in series which remove carryover resin. The pressure control valve prevents excessive carryover of resin from the reactor by limiting the pressure to the recovery system to about 35 pslg. Each of the knockout drums have an internal water spray system and a recirculation pump. Both knockout drums have an on-off level control system which, on high liquid level, diverts the discharge of the water re circulation punq>s to the blowdown tank. A water recirculation - cooler, (the function of which is explained in the steam stripping portion of the recovery system process description), is provided and can be used in the water recirculation loop of either scrubbing stage. The VCM vapors from the knockout drums are compressed by the recovery compressors. DTH 000096946 Operating Manual D-700 PVC Reactors Page 13 II. GENERAL PROCESS DESCRIPTION (CONTINUED) D. Recovery and Steam Stripping (Continued) 1. Recovery (Continued) The recovery compressors are constant volume liquid ring compressors with a water seal. The discharge streams from the compressors flow to two parallel seal water recirculation systems which operate as follows. Seal water is separated from the VCM vapors in the seal water separators, filtered by the seal water filters, cooled by the seal water coolers, and pumped back to the compressors by the seal water pumps. The flow of seal water to each compressor is controlled at 50 gpm. The seal water temperature is controlled just above the VCM condensation temperature (95-105F). Automatic draining of the seal water separators to the blowdown tank is provided to maintain the correct water level. The VCM vapors from the seal water system are condensed in two recovered VCM condensers. The condensed VCM is collected in the recovered VCM collect tank which is on automatic on-off level control. VCM is transferred to the recovered VCM storage tanks by the recovered VCM transfer pump when there is high liquid level in the VCM collect tank. Inerts are bled from the collect tank to the V-ll area blow down tank. DTH 000096947 Operating Manual D-700 PVC Reactors Page 14 II. GENERAL PROCESS DESCRIPTION (CONTINUED) D. Recovery and Steam Stripping (Continued) 1. Recovery (Continued) When the reactor pressure drops to 7 psig, the two recovery vacuum pumps automatically start. The VCM flow from the recovery knockout drums and the seal water flow are both diverted to the vacuum pumps which discharge into the suction of the compressors. 2. Steam Stripping In order to reduce residual VCM in the slurry, the slurry in the reactor is heated and stripped with steam. At the start of a normal recovery, steam addition to the reactor is manually started from the control room and the slurry mass is heated. When the temperature of the reactor has risen to the desired temperature, the steam stripping operation is completed. As recovery proceeds, less and less VCM is recovered from the reactor. To supply sufficient VCM vapor to the recovery vacuum pimps and compressors, a VCM backpressure system is used. This is done to prevent cavitation and overheating of the vacuum pumps and compressors. Before entering the recovery knockout drums, the steam and VCM from the reactor are combined with a bleed stream of VCM from the recovered VCM storage tanks. The amount of VCM bled into the recovery system is adjusted by the backpressure control valve such that a set supply pressure to the vacuum pumps is maintained. 000096948 dth Operating Manual D-700 PVC Reactors Page 15 II. GENERAL PROCESS DESCRIPTION (CONTINUED) D. Recovery and Steam Stripping (Continued) 2. Steam Stripping (Continued) The majority of the steam is condensed in the first knockout drum described in the normal recovery process description. The first stage of the scrubbing system consists of a recovery knockout drum with an internal water spray system, a water recirculation pump and the water recirculation cooler. The ^ water cooler reduces the water temperature sufficiently to allow the internal spray system in the knockout drum to cool the VCM and condense much of the steam in the vapor stream. After leaving the first stage of the water scrubbing system, the VCM vapor flows to the second stage of the scrubbing system and then to the rest of the recovery system in the same manner as during normal recovery. 3. Hydroquinone Injection The VCM removed from the reactor during recovery still contains a small amount of initiator. As a result, the VCM will continue to polymerize, resulting in plugged recovery lines, charge lines, and recovered VCM storage tanks. Polymerization is significantly reduced by the addition of an inhibitor such as hydroquinone to the VCM stream as it is being recovered. A 4.6 percent solution of hydroquinone in water is prepared in the hydroquinone storage tank. DTH 000096949 Operating Manual D-700 PVC Reactors Page 16 II. GENERAL PROCESS DESCRIPTION (CONTINUED) D. Recovery and Steam Stripping (Continued) 3. Hydroquinone Injection (Continued) The hydroquinone solution is pumped by the hydroquinone injection pump into the suction of the recovery seal water pumps. The injection pump starts and stops automatically with the seal water pumps. The metering pump has a variable stroke which can be adjusted manually to maintain the preset hydro quinone injection rate. 4. Recovery of Blowdown Tank The blowdown tank is to collect the various steam and water streams containing VCM from the four-reactor module. The recovery system is used to recover VCM vapor. The tank can be recovered during the steam stripping portion of a reactor recovery or during a period between reactor recoveries. When the pressure of the tank drops below the desired pressure, recovery of the tank is stopped. E. Reactor Dump and Rinse After the reactor is recovered and steam stripped, the reactor interlock selector switch is moved to the "dump" position. The appropriate dump valves are opened from the control room and the slurry flows by gravity to the dump system. The slurry passes through an enclosed vibrating slurry strainer where the PVC culls are collected until dump is completed. The slurry then flows to the slurry dump tank. The slurry transfer pumps transfer the slurry to the blend tanks. The dump tank level is automatically controlled. DTH 000096950 Operating Manual D-700 PVC Reactors Page 17 II. GENERAL PROCESS DESCRIPTION (CONTINUED) E. Reactor Dump and Rinse (Continued) Near the end of dunq>, the reactor condenser Is flushed with water by turning on the condenser rinse system from the board. Hot water is pumped from the hot water tank by the hot water charge pumps through the cleaning nozsle in the reactor condenser. The rinse water mixes with any remaining slurry and is pumped with the slurry to the blend tanks flushing out the slurry transfer lines. Hie slurry strainer and the slurry dunq> tank are equipped with a water wash system to remove resin from the equipment between production of different types of resin. F. Chem Wash and Rinse If it has been determined that the reactor needs cleaning, the reactor interlock selector switch is moved to the "clean and rinse" position after the dump and rinse is completed. The chem wash solution is a caustic solution. The cleaning solution pump or spare pumps the solution at 500 gpm from the cleaning solu tion tank through the cleaning solution heater to the reactor condenser spray nossle. Steam to the cleaning solution heater is automatically adjusted such that the exit temperature of the chem wash solution is 190F. When the level in the reactor is above the agitator blades (approximately 5,000 gallons) as determined by the level change in the cleaning solution tank, no more solution DTH 000096951 Operating Manual D-700 PVC Reactors Page 18 II. GENERAL PROCESS DESCRIPTION (CONTINUED') F. Cham Wash and Rinse (Continued) is added to the system. Recirculation is then started with chem wash solution being punned from the reactor at approximately 250 gpm and back to the reactor through the reactor cleaning nozzle. Large PVC particles picked up in the reactor cleaning process are removed from the cleaning solution in the cleaning solution strainer before entering the suction of the cleaning solution pump. When chem wash has ended, the solution is pumped back to the cleaning solution tank at 500 gpm by the cleaning solution pump. The process requires ten minutes to fill the reactor through the condenser, five minutes to wash the reactor, and ten minutes to empty the reactor, for a total of twenty-five mintues. After the chem wash is completed, the reactor is rinsed with hot water from the hot water tank. The hot water is pumped by the hot water charge pumps to the reactor. The water first enters through the condenser cleaning nozzle and then the reactor cleaning nozzle. The chem wash and rinse system is manually controlled from the control room. G. Water Swirl If the resin formula calls for a water swirl, the reactor interlock selector switch is placed in the "swirl" position after the chem wash rinse is completed. Cold or hot water enters the suction of the hot water charge pumps, and is pumped through the reactor DTH 000096952 Operating Manual D-700 PVC Reactors Page 19 II. GENERAL PROCESS DESCRIPTION (CONTINUED) G. Water Swirl (Continued) charge line into the reactor. When the water charge reaches a preset amount, the water charge system is automatically shut down. The reactor agitator is then used to swirl the water for approximately 25 minutes. The lead operator then drains the water to the sewer. This completes one reaction cycle; the reactor is now ready for evacuation. H. Blowdown Collection System Various waste water streams from the process must be collected in an enclosed system for treatment. Water streams containing PVC and VCM from the recovery system, the VCM storage tanks, line and vessel purges, and miscellaneous flush and seal waters are intermittently sent to the blowdown tank. When the liquid in the blowdown tank reaches a level 22 inches from the top of the tank, a high level alarm sounds in the control room. At the discretion of the operator, the water in the blowdown tank is stem stripped at 175? and 16 Inches Hg vacuum, using the reactor recovery system. The vapors from the blowdown tank are recovered in the manner previously described in the recovery section of the process description. Due to the operating pressures of streams collected in the tank, the pressure in the blowdown tank should be minimized. 000096953 dth Operating Manual D-700 PVC Reactors Page 20 II. GENERAL PROCESS DESCRIPTION (CONTINUED) H. Blowdown Collection System (Continued) When the recovery and stripping of the blowdown tank Is completed, the lead operator activates the blowdown tank pump. The water is strained of PVC particles and is sent to the sewer. During drain ing, steam is used to maintain enough pressure in the tank to allow operation of the blowdown tank pump. When the liquid level drops to 12 inches from the bottom of the tank, the draining process is automatically stopped. DTH 000096954 DTH 000096955 Operating Manual D-700 PVC Reactors Page 21 III. OPERATING PROCEDURES A. Reactor Evacuation Evacuation of the reactor is required prior to charging in order to remove as much of the air as possible. Air is introduced into the reactor during previous phases of the reactor batch cycle since dump, rinse, and chem wash require that the reactor be vented to the atmosphere. Air in the reactor during reaction causes poor temperature control during polymerization and may alter the parti cle size of the resin. Evacuation is accomplished using a two-stage steam jet ejector system. Evacuation is controlled by the lead operator from the board. The "A" operator must confirm that all process equipment is operating correctly during evacuation. Procedure 1. If the reactor has been opened, follow procedure given in the "Reactor Cleaning and Entry" section on how to close the reactor manhead. 2. The lead operator puts the interlock mode selector on "evacuation." 3. The lead operator checks to see that all valves are closed. 4. The lead operator then opens the condenser recovery valve and the evacuation reactor valve, which automatically starts the reactor evacuation steam jet used to evacuate the reactor. He then opens the emergency cooling water valve, which supplies cooling water to the reactor condenser. DTH 000096956 Operating Manual D-700 PVC Reactors Page 22 III. OPERATING PROCEDURES (CONTINUED) A. Reactor Evacuation (Continued) Note: In the following steps, 5-10, the operators prepare the initiator for charge while evacuation is in progress. 5. The "A" operator will go to the initiator freezer and bring the specified amount of initiator to the initiator injection pot. Extreme caution must be exercised by the "A" operator to be sure that no VCM is allowed to get back into the initi ator injection pot. When a small amount of VCM is mixed with a large amount of initiator, an extremely fast reaction takes place giving off heat and pressure. To guard against this situation, the operator must know that he has an adequate water supply and pressure. The reactor initiator injection valve must never be opened unless the bomb is fully pressurized with the inlet water valve open. Note: The following precautions must be taken when handling Initiator. a. Full face shield and plastic gloves must be worn while handling initiator. b. If any initiator is spilled on skin or clothing, immedi ately flush with water. c. Should any initiator remain in the containers, return it to storage. d. Take all empty containers to trash and split side of all containers. STH 000096957 Operating Manual D-700 PVC Reactors Page 23 III. OPERATING PROCEDURES CCONTINUBD) A. Reactor Evacuation (Continued) 6. The "A" operator must check the injection bomb to be sure that it is empty. Close the drain valve. Open the initiator addition valve. 7. The lead operator will manually open the HPSW inlet valve, CV-879, until the initiator water totalizer, FQI-703, shows that 55 counts of water are in the initiator injection pot. 8. The "A" operator will now add the initiator to the injection pot. 9. The "A" operator will now close the initiator addition valve and inform the lead operator that the initiator loading is complete and the bomb is ready to be pressurized. 10. The lead operator will now open CV-879, which supplies high pressure service water to the initiator injection pot. This should activate the high pressure light for the injection pot on the panel. 11. When a 25-inch Hg vacuum is reached in the reactor, an indicator on the board will light. 12. The lead operator will stop evacuation when a vacuum of 28.5 Inches Hg is attained. The reactor pressure is double checked by the "A" operator at the reactor with a mercury manometer. The lead operator stops evacuation by closing the condenser DTH 000096958 Operating Hanual D-700 PVC Reactors Page 24 III. OPERATING PROCEDURES (CONTINUED) A. Reactor Evacuation (Continued) 12. recovery valve and the evacuation reactor valve This automatically shuts off the evacuation steam jets, He then closes the emergency cooling water valves. 13. Evacuation is now complete. DTH 000096959 Operating Manual D-700 PVC Reactors Page 25 III. OPERATING PROCEPURES (CONTINUED) B. Reactor Precharge The reactor precharge procedure includes a series of precharge checks and precautions that must be carried out by the lead and "A" operators. If the necessary precharge conditions are not met, the modlcon (a small computer which controls the automatic charge sequence) will not allow the automatic charge sequence to begin. It is the responsibility of the lead operator to see that all pre charge checks and precautions are carried out. He should also read the log book at the start of the shift, covering the period since he was last on the job. This will alert him to any changes in formula, mechanical, or operational procedures that may not have been passed on verbally. 1. Lead Operator Duties a. Check level in fresh VCM receiver to see that it is ade quate for charge. This is a level of at least 247 inches on the sight glass. b. Drain water in the recovered VCM receiver to the blowdown tank. Valves from the recovered receiver are manually opened from the board until pressure rise in the blowdown tank indicates all the water is out and VCM is being trans ferred. Valves are then manually shut from the board. c. Fill out the reactor charge sheet. d. Check the hot water tank level and temperature. DTH 000096960 Operating Manual D-700 PVC Reactors Page 26 III. OPERATING PROCEDURES (CONTINUED) B. Reactor Precharge (Continued) 1. Lead Operator Duties (.Continued) e. Check to see that all valves on the reactor are closed. f. Have the "A" operator make a precharge check and reading of the following: (1) Dura-Beal* oil level and pressure. (2) Mechanical seal purge water pressure and rate to the reactor agitator seal. (3) Colloid charge tank level and temperature. g. Record the readings on the charge sheet as they are trans mitted by the "A" operator. 2. "A" Operator Duties a. Check Dura-Seal* level and pressure. There are two DuraSeal* units. One supplies seal oil pressure to all four reactor agitator mechanical seals and the other is a spare and starts automatically when the operating unit has low seal oil level or discharge pressure. If both units fail, an emergency supply of seal oil is provided by the emergency seal oil drum that is nitrogen pressurized. Valves must be opened manually at the unit if the emergency seal oil system is used. *Registered Trademark DTH 000096961 Operating Manual D-700 PVC Reactors Page 27 III. OPERATING PROCEDURES (CONTINUED) B. Reactor Precharge (.Continued) 2. "A" Operator Duties (Continued) NOTE: When the primary and spare Dura-Seal* oil units are down and the emergency system is in operation, reactors are not to be charged until at least one of the DuraSeal* oil units is operating. The emergency system is designed to be a backup system that should be used short term only. When one of the Dura-Seal* oil units is not in operating condition. Inform the lead operator so that repairs can be made. The seal oil level should be checked in both units. The discharge pressure should be checked and be in the range of 205-250 psig. If the pressure falls below 205 psig, the spare unit will automatically start up and the primary unit shut down. The spare unit will also automatically start up and the primary unit shut down when a low seal oil level is detected in the primary unit. Report the seal oil pressure to the lead operator. *Registered Trademark DTH 000096962 Operating Manual D-700 PVC Reactors Page 28 III. OPERATING PROCEDURES (CONTINUED) B. Reactor Precharge (Continued) 2. "A" Operator Duties (Continued) b. Check the mechanical seal purge water pressure and rate of flow to the agitator mechanical seal. Pressure should be 180-220 psig. Adjust the water flow rate to that given in the formula. Report the seal water pressure and flow rate to the lead l operator. c. Check the colloid charge tank level to be certain enough is in the tank to complete a charge. Notify the lead operator of the level present. A level of at least 26 inches should be shown on the sight glass before charge is started. d. Inform the lead operator when checks are completed and the reactor is ready for charge. DTH 000096963 Operating Manual D-700 PVC Reactors Page 29 III. OPERATING PROCEDURES (CONTINUED) C. Reactor Charge This section includes vacuum break and reactor charge. The reactor charge is one of the most critical operations in terms of product quality. Care must be taken to assure that all the raw materials are added in the proper order and in the proper amount. Procedure 1. When evacuation and precharge checks are complete, the lead operator can move the interlock mode selector to "charge." 2. The lead operator should take the following steps and see that the following conditions are met before charge: a. VCM transfer should be in auto. b. Recovered VCM charge should be in auto with either the primary or spare pump selected for charge. c. Fresh VCM charge should be in auto with either the primary or spare pump selected for charge. d. Hot water charge should be in auto. e. Initiator charge should be in auto with high pressure light on. f. Colloid charge should be in auto with either the primary or spare pump selected for charge. g. Select recipe to be charged by dialing recipe number on the recipe selector on the board, h. Push meter reset button, which resets all charge meters. DTH 000096964 Operating Manual D-700 PVC Reactors Page 30 III. OPERATING PROCEDURES (CONTINUED) C. Reactor Charge (Continued) Procedure (Continued) i. The charge light will now come on if all the following conditions are met: (1) The fresh VCM storage tank, hot water tank, and colloid charge tank all have a level adequate for one complete charge. (2) One reactor is in charge mode. (3) The high pressure service water header is at least ISO psig. r^- (4) The reactor being charged has at least 25 inches Hg vacuum. (5) The initiator injection pot is at least 180 psig. 3. When a charge light is obtained on the panel, the lead operator will inform the "A" operator to stand by for breaking vacuum. The lead operator will break vacuum by: a. Manually opening the reactor VCM charge valve from the board. b. Manually opening the reactor charge valve from the board. c. Turbine meters will start counting as VCM flows into the reactor. d. As soon as a positive pressure is indicated in the reactor, close the VCM charge valve. DTH 000096965 \ Operating Manual D-700 PVC Reactors Page 31 III. OPERATING PROCEDURES (CONTINUED) C. Reactor Charge (Continued) Procedure (Continued) 4. The "A" operator will then watch the pressure gauge at the top of the reactor. When the pressure rises above zero, start checking the following: a. Inspect manhead visually and by moving hands around Lenape* lid feeling for escaping vapor. b. Check safety disc gauges for pressure. Any pressure indi cates a leaking or ruptured disc. c. Turn flush water (injection water) on sprayhead. The purpose is to keep heads free of resin. Set rate according to recipe. d. If all checks okay, notify lead operator. If not, notify lead to hold on charge until problem can be corrected. 5. The lead operator can now push the charge button. In rapid sequence, the following occurs: a. Reactor water charge valve opens. b. "A" hot water pump starts, valves open, and water starts into the reactor. c. The valves from the fresh VCM receiver, 45-745, to the VCM charge pump and discharge valve open. d. At set point No. 1 on water meters: Registered Trademark DTH 000096966 Operating Manual D-700 PVC Reactors Page 32 III. OPERATING PROCEDURES (CONTINUED) C. Reactor Charge (Continued) Procedure (Continued) (1) "B" hot water pump starts and discharge valve opens. (2) The colloid charge pump discharge valve will open and pump will start. The preset amount of colloid will be pumped into the reactor. When the colloid meter set point is reached, the colloid charge pump will cut off and the discharge valve and reactor colloid charge valve will close. NOTE: The lead operator will turn on reactor jacket steam during colloid and water charge to assist reactor heatup. e. At set point No. 2 on water meter, the reactor VCM charge valve opens and the VCM and recovered VCM charge pumps start. f. At set point No. 3 on the water meter, "B" hot water pump stops and discharge valve closes. This allows time for all VCM to be charged to the reactor before the water charge is completed. NOTE: A partially plugged filter pack can cause slow VCM flow, and it may be necessary to cut off "A" hot water pump also. If this should happen, be sure to have a minimum of 50 counts left on water charge meter. This is enough to clean lines and manifold of VCM. When the VCM is within ten counts of being complete, put "A" and "B" hot water pumps back on automatic and complete the charge. DTH 000096967 Operating Manual D-700 PVC Reactors Page 33 III. OPERATING PROCEDURES CCONTINUED) C. Reactor Charge (Continued) Procedure (Continued) NOTE: When a filter is known to be fouled, isolate and switch to the spare unit. If you continue to try to force VCM through fouled filters, the high pressure will cause the filter elements to collapse and greatly increase the time taken to change them out. g. When VCM meters reach the set point (two meters running in tandem, first to reach the set point cuts pump off and closes valve), the VCM pimp, outlet valve, inlet and discharge valve to VCM charge pump, and reactor VCM valve close. This action also starts "B" hot 1^0 pump and opens discharge valve. h. At set point No. 4 on the water meters, "A" and "B" hot water pumps stop and discharge valves close. Also, the reactor water charge valve and main dump valve close. 6. When the automatic charge sequence has been completed, it is safe to charge the initiator. 7. The lead operator charges the initiator by opening the initiator reactor charge valve. 8. When a preset amount of water has been charged through the initi ator charge pot, the reactor initiator charge valve and the HPSW inlet valve are automatically closed. 9. The lead operator will now record the final reactor temperature. r^ Adjust reactor temperature set point to setting called for in the formula and put temperature controller in "auto" position. DTH 000096968 Operating Manual D-700 PVC Reactors Page 34 III. OPERATING PROCEDURES (CONTINUED) D. PolymerlzatIon Polymerization is the phase of the reactor cycle in which liquid VCM is converted into solid PVC. This portion of the reactor cycle is mainly accomplished by accurate instrumentation. The primary area of responsibility for the lead operator is coordination of the activities of the "A" operator. The "A" operator is required to sample the reactor and kill the reaction when polymerization has progressed to the point that product quality is satisfactory. 1. Lead Operator Duties a. Change the interlock mode selector to "polymerization." Monitor the temperature and pressure closely until the reactor reaches the desired set point and lines out. b. Cut off steam valve to jacket at two to four degrees below set point, depending on the rate of temperature rise. c. After 1 1/2 hours at run temperature, have "A" operator obtain slurry sample with reactor sample bomb. d. Examine the resin. At this stage of the reaction, the resin should be formed into individual, separate particles. Resin forms you would suspect as irregular are: (1) Stringers--Several particles of resin stringing together. (2) Conglomerates--Clusters of resin stuck together in little balls. DTH 000096969 Operating Manual D-700 PVC Reactors Page 35 III. OPERATING PROCEDURES (CONTINUED) D. Polymerization (Continued) 1. Lead Operator Duties (Continued) If either of the above conditions are observed, have the "A" operator take samples every fifteen minutes until a definite trend can be established. If this irregularity clears up, continue the run; but if the condition worsens, notify the shift supervisor who will make the decision as to what corrective action should be taken. e. It may become necessary to remove the inerts. Inerts in the condenser will cause the reactor pressure to rise as they blanket the condenser and do not allow VCM vapor to be condensed. Under these conditions, less heat can be removed even though the condenser water flow will be full open. Vent the inerts through the main condenser valve to the recovery system. Open the valve from the board. As soon as the "Valve Open" light comes on, push the "valve Close" button. One time should be enough; but if the reactor pressure does not stay at the set point, it may be necessary to vent twice. f. Irregularities during polymerization: (1) Slow Heatup--May be caused by weak or no initiator. Slow heatup can also be caused by no steam on reactor jacket or the cooling water valves may be open. Contact the shift supervisor if this condition persists. DTH 000096970 Operating Manual D-700 PVC Reactors Page 36 III. OPERATING PROCEDURES (CONTINUED) D. Polymerization (Continued) 1. Lead Operator Duties (Continued) (2) Excessively Long Run--Caused by low initial initiator charge or a buildup of inhibitor or chem wash solution (caustic) in batch. If there is only slow reaction and the resin checks okay, the shift supervisor will give word on what to do. If caustic is in the reactor, the batch will turn slightly yellow and coarsen. If this is found to be true, kill immediately with the amount of short stop solution speci fied in the formula. (3) Simultaneous Temperature and Pressure Rise--Check cooling water temperature and valves. The reactor is producing more heat than the cooling water can remove. Also could be an overcharge of initiator. Notify shift supervisor for instructions. (4) Simultaneous Temperature and Pressure Drop--The cooling water valves are probably wide open. This happens more often in freezing weather when relays freeze up. Throttle manual valves until malfunction is found and corrected. (5) Agitator Kicks Out or Power Failure--Most power failures are of short duration (seconds to two minutes), and the reactor pressure does not have time to build to a dangerous level. If outage is prolonged, the pressure will build. DTH 000096971 Operating Manual D-700 PVC Reactors Page 37 III. OPERATING PROCEDURES (CONTINUED) D. Polymerization (Continued) 1. Lead Operator Duties (Continued) If this situation occurs, follow the procedure in Section III.D.3, which outlines action to be taken during emergency shutdown (such as during a power failure). 2. "A" Operator Duties a. When charge is complete, recheck water injection rates through the cleaning nozzle and seal flush. b. On Instruction from the lead operator, resin samples will be taken from the reactor. This normally occurs 1 1/2 hours after Initiator injection. If the first sample shows forma tion of undesirable resin particles, additional samples may be called for every fifteen minutes until a decision is made about what should be done with the batch. Before the sample is taken, the blowdown tank, 45-319, is recovered if it is not already under vacuum. To take a resin sample, the sampler is attached to the appropriate reactor sampling line and the reactor sampling ram valve opened until the sampling pressure gauge reads 60 psig. The reactor sampling system lines are cleared of VCM vapors and resin by evacuating to the blowdown tank and flushing with water. The sampling system lines are then vented to the atmosphere and sampler 45-770 disconnected. The resin is removed from the sampler by removing the screen insert. DTH 000096972 Operating Manual D-700 PVC Reactors Page 38 III. OPERATING PROCEDURES (CONTINUED) D. Polymerization (Continued) 2. "A" Operator Duties (Continued) c. When the lead operator instructs the "A" operator to do so, the batch is killed by adding short stop solution to the reactor. High pressure service water is used to pressure the short stop solution from the AMS short stop charge pot into the reactor through the same piping as the agitator mechanical seal purge water Inboard seal flush. 3. Emergency Shutdown The following steps are to be taken during emergency shutdown: a. Use the nitric oxide (NO) short stop system for killing each reactor. There are six cylinders of NO that can be released for each reactor. The NO system can be activated either at the reactors by manually opening the correct valves or from the control room. b. Use nitrogen to pressurize the Dura-Seal* unit emergency seal oil drum and the mechanical seal purge water surge drum. The valves connecting the emergency seal oil and seal water drums with their respective systems must be opened manually. c. There will be sufficient air in the air system surge tank to operate valves for approximately fifteen minutes. It will be necessary to use the nitrogen backup system to Registered Trademark dth 000096973 Operating Manual D-700 PVC Reactors Page 39 III. OPERATING PROCEDURES CCOWTINUBD) D. Polymerization (Continued) 3. Emergency Shutdown (Continued) operate valves after fifteen minutes. The surge tank should be valved off before the backup nitrogen system is activated. d. Monitor each reactor for pressure rise. If the pressure continues to rise, the following steps are to be taken: (1) Equalize the reactor with any other empty or killed reactor of the same type product. (2) If the pressure still continues to rise, vent through r' the main condenser valve to the recovery system and the recovered VCM receiver. (3) If this will not relieve the pressure buildup, then equalize the reactor with a reactor of different type resin. (4) When 1, 2, and 3 alone fail to relieve the reactor pressure, then manually vent at 170 psig as often as needed to maintain control. NOTE: Step (4) is to be the last resort. Under the new EPA law, any venting must be reported and could result in a fine. r' dth 00096974 Operating Manual D-700 PVC Reactors Page 40 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping The reactor Is ready for recovery when certain conditions are reached in the reaction process. The conditions under which recovery will start are: Pressure Drop---There la not enought unreacted VCM left in the reactor to maintain run pressure. A pressure drop is accompanied by a drop in the cooling water flow to the reactor jacket and con denser. Runaway--Reaction has increased to the point that it has outrun the capabilities of the cooling water to control. Temperature and pressure will both rise when this occurs. Follow instructions on each product formula as to the exact conditions at which the reaction is killed. Temperature Rise--Pressure Drop--This is the ideal recovery situation and indicated proper initiator loading. The reaction will peak and slightly outrun the capabilities of the'cooling water. This situation gives the best recovery conditions since there is less VCM to be recovered and more converted to resin. Quick-Kill--A reactor is sometimes killed on specific products to meet certain customer specifications--lower dry time (higher plasti cizer absorbtlon). The reactor is killed with a specified amount of the short stop solution at a specified set of conditions. The short stop solution mixture stops the reaction chain. dth 000096975 Operating Manual D-700 PVC Reactors Page 41 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping (Continued) On a quick-kill batch, it is very important to guard against resin carryover to the recovery system. An injection of defoamer will help to control foaming. A fast recovery is also important and will affect the dry time. 1. "A" Operator Duties When notified by the lead operator that the recovery conditions specified in the formula are met, the "A" operator will take the following steps: a. Check the hydroquinone injection system to make sure that the proper valves are open and the hydroquinone level is adequate. b. Check the blowdown tank level and pressure. Level and pressure must be low to allow the automatic drain on the water recirculation pump to operate. c. Check the water levels in the seal water separators and knockout drums. These- levels are controlled automatically but should be checked before startup. Knockout drum level should be at or below the mid-point of the inlet to the vessel. The seal water separator level should be at or below the mid-point of the inlet to the vessel. d. Check the backflow pressure controller. It should be set at three inches Hg vacuum. DTH 000096976 Operating Manual D-700 PVC Reactors Page 42 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping (Continued) 1. "A" Operator Duties (Continued) e. Check to see that the flush to the knockout drum and seal water separator level gauges are on and set at 1 gpm. These are FI-726, FI-727, FI-741, and FI-742. f. Notify the lead operator that the recovery system Is ready to startup. g. Steam header pressure should be greater than 100 psig. h. Reactor steam line should be checked and reactor steam valves should be checked to make sure they are opening correctly. 2. Lead Operator Duties a. When the "A" operator has checked the recovery system, the lead operator can change reactor interlock mode to "recovery." b. Start the water recirculation pumps, 72-889 and 72-890. c. Start the seal water pumps, 72-891 and 72-892. This auto matically starts hydroqulnone Injection pump 72-895. d. Two recovery compressors, 72-903, 72-904, or 72-905, are placed in auto. The automatic recovery start switch is then pushed. This starts two compressors and opens the valves associated with compressor startup. e. The vacuum pumps will automatically come on when the suction pressure of the compressor is 7 psig. The necessary valve changes are also automatically made. 000096977 Operating Manual D-700 PVC Reactors Page 43 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping (Continued) 2. Lead Operator Duties (.Continued) . When the reactor reaches the pressure specified in the product formula, the lead operator will move the reactor temperature set point to the specified stripping tempera ture and begin steam stripping. g. Watch the temperature of the reactor condenser. h. When stripping conditions specified in the formula are met, steam stripping is complete. i. When steam stripping and recovery is complete, the recovery system is shut down as follows: (1) Push stop buttons for the recovery compressors 72-903, 72-904, or 72-905. This also stops the vacuum pumps. (2) Push stop buttons for seal water pumps 72-891 and 72-892. This also stops hydroquinone injection pump. (3) Push stop buttoms for the water recirculation pumps, 72-889 and 72-890. 3. Recovery System Troubleshooting a. High Compressor Outlet Temperature Probable cause is poor or no water recirculation in the recovery knockout drum, 45-760. Check VCM backflow controller setting. Controller setting should be at 3 inches Hg. 000096978 dth <*N Operating Manual D-700 PVC Reactors Page 44 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping (Continued) b. High Compressor Discharge Pressure High pressure can be caused by: (1) Plugged Condenser--Have lead operator report problem to the shift supervisor. (2) Plug in the Line from the Condenser to the VCM Collect Tank--Line will have to be pulled and cleaned. (3) High Level in the VCM Collect Tank (a) Switch transfer pump to manual. (b) Check level of the recovered VCM receiver-east or west. (4) No Cooling Water to Condenser--Check inlet and outlet water valves. (5) High Seal Water Temperature--This temperature should be 110 + 10. Check seal water pump for flow and pressure and check filter pack. c. If the compressor is not compressing the VCM vapor and does not have a 50 to 70 psi discharge pressure: (1) Check seal water flow. (2) Check seal water separator water level and adjust as necessary. (3) Check seal water temperature--below 80F water will condenser the VCM vapor and cause displacement of the water seal around the compressor cone. DTH 000096979 Operating Manual D-700 PVC Reactors Page 45 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping (Continued) 3. Recovery System Troubleshooting (Continued) d. Recirculation water pump 72-889 goes out (mechanical- electrical) . (1) Under normal operation, recirculation water pump 72-889 circulates water through the water recircu lation cooler and into recovery knockout drum 45-760. Crossover piping is provided so that, if recirculation water pump 72-889 fails, recirculation water pump 72-890 will be valved to circulate through the recir culation water cooler and into recovery knockout dmm 45-761. Note: Normal operating temperatures for the recovery system during stripping are: (a) Reactor Condenser - 215-225F (Peak Temperature) (b) 45-760 Knockout Drum Outlet - 122-128F (c) 45-761 Knockout Drum Outlet ~ 90-115F (d) Compressor Outlet - 130-140F The lead operator must monitor these temperatures on the multipoint recorder and have the "A" operator check out and correct deviations. e. Reactor Foaming (carryover)--When foaming is detected, the "A" operator will: DTH 000096980 Operating Manual D-700 PVC Reactors Page 46 III. OPERATING PROCEDURES (CONTINUED) E. Recovery and Steam Stripping (.Continued) 3. Recovery System Troubleshooting (Continued) (1) Inject defoamer into the reactor to reduce slurry surface tension and lower the reactor slurry level. It may become necessary for the lead operator to shut down one compressor to slow the recovery. If exces sive foaming occurs, shut down recovery and thoroughly flush the entire system with water until clear. DTH 000096981 O O Operating Manual D-700 PVC Reactors Page 47 III. OPERATING PROCEDURES (CONTINUED) F. Reactor Dump and Rinse When the recovery of the reactor has been completed, the slurry is ready to be dumped to the slurry blend tank(s) that has been designated by the shift supervisor. 1. "A" Operator Duties a. Check the selected blend tank or tanks to make sure it will hold the batch. b. Set up the dump line to the selected blend tanks. Check to see that the blend tank sewer valve Is closed and the agitator Is on. c. Check the slurry transfer pump valving to make sure the flow will be going to the correct line. d. Place the coarse overflow collector Into position. Inform the lead operator that the dump can begin. e. Monitor the dump tank level until the flow to the pump and discharge from the reactor have leveled out to a steady rate. f. Add calcium stearate to the dump tank as directed by the shift supervisor (except with 5425, 5465, and 5446 resins). g. If instructed by the lead operator, open the reactor manhead to inspect the reactor internals. Follow opening procedure in "Reactor Cleaning and Entry" section. O' DTH 000096982 Operating Manual D-700 PVC Reactors Page 48 III. OPERATING PROCEDURES (.CONTINUED) F. Reactor Dump and Rinse (Continued) 2. Lead Operator Duties a. Check the sewer valve on the reactor to be sure it is closed. b. Turn on the Sweco* strainer. c. Check the Sweco* exhauster to be sure it is running. It should be running continuously. d. Turn the Interlock node selector switch to the "dump" position. e. After the "A" operator Informs lead operator that dump can begin, place the slurry transfer pumps, 72-896 and/or 72-897, in the "run" position. This opens the slurry transfer pumps' seal water supply valves, CV-864 and/or CV-866, before the pumps start. The level in slurry dump tank 45-766 is automatically controlled. f. Five minutes after the start of dump, open the reactor vent to the atmosphere. g. When there is no slurry flow through FI-747, the reactor is rinsed according to formula instructions. h. When dump and rinse are complete, place the slurry transfer pumps in the stop position. This shuts down the pumps, 72--896 and/or 72--897, and then closes the slurry transfer pump seal flush water valve, CV-864 and/or CV-866. *Registered Trademark DTH 000096983 Operating Manual D-700 FVC Reactors Page 49 IH. OPERATING PROCEDURES (CONTINUED) G. Chem Wash and Rinse Chem wash and rinse is not done as a matter of routine on all reactors; however, if it has been determined that chem wash is needed, the shift supervisor will Inform the lead operator to do so. After the reactor has been rinsed during the dump cycle, it is ready to be chem washed. The chem wash cycle is necessary to remove polymer buildup from the reactor condenser, walls, baffles, and agitator. If polymer buildup is allowed to remain in the reactor, it continues to grow with each successive charge. Buildups will contribute to high gel, low quality resin, and will make reactor dumping very difficult it they get large enough to break off and plug dump valves and lines. Operators must exercise caution during chem wash due to the caustic in the solution. If any solution should get on an opeator, flush Immediately with water. Caustic feels slick to the touch and will start burning the skin just a few seconds after contact. If the solution should spray over the body, immediately get under a safety shower and remove your clothing. If any should get in the eyes, flush eyes for at least fifteen minutes but until all burning stops and report to your supervisor. DTH 000096984 Operating Manual D-700 PVC Reactors Page 50 III. OPERATING PROCEDURES CCONTINUED) G. Chem Wash and Rinse (Continued) Procedure 1. The lead operator will check and make sure the reactor sewer valve is closed. 2. The lead operator will then place the interlock mode selector switch to "clean and rinse." 3. The lead operator then checks to see that the cleaning solution tank, 45-767, is at least 85 percent full. 4. The lead operator then opens the valves from the cleaning solution pumps, 72-989 or 72-899, to the reactor condenser cleaning nozzle. The atmospheric vent on the reactor should be open. All other reactor valves are closed. 5. The lead operator then opens the suction valves, CV-873, for the cleaning solution pumps, 72-898 or 72-899. 6. The lead operator will check to see that the cleaning solution heater temperature controller is set at 190F. 7. The lead operator will then turn on one cleaning solution pump 72-898 or 72-899. 8. When 5,000 gallons have been flushed through the reactor con denser (this is a change of about 85 percent in the cleaning solution tank level), the lead operator will: a. Stop the cleaning solution pump. b. Close pump suction valve CV-873 from the cleaning solution tank. DTH 000096985 I Operating Manual D-700 PVC Reactors Page 51 III. OPERATING PROCEDURES (CONTINUED) G. Chem Wash and Rinse (Continued) Procedure (Continued) c. Open chem wash return valve on reactor. d. Open cleaning solution pump suction valve CV-874 from the reactor. e. Close valves to the condenser cleaning nozzle. f. Open valves to the reactor cleaning nozzle. g. Restart the cleaning solution pump. The chem wash solution should now be circulating from the bottom of the reactor back to the reactor cleaning nozzle. h. The reactor agitator remains on. 9. The lead operator will recirculate the chem wash solution through the reactor for five minutes and will then pump the chem wash solution back to the cleaning solution tank by: a. Opening CV-872. b. Closing CV-871. This sends the cleaning solution pump discharge to the cleaning solution tank. 10. The "A" operator should monitor the cleaning solution pump and notify the lead operator when it loses suction (check pressure gauge on pump discharge). 11. The lead operator will now shut off the cleaning solution pump. DTH 000096986 Operating Manual D-700 PVC Reactors Page 52 III. OPERATING PROCEDURES (CONTINUED) G. Chen Wash and Rinse (Continued) Procedure (Continued) 12. The lead operator will then check the cleaning solution tank level Indicator to see If all the chem wash solution has returned. If any solution is lost or accidentally dumped to the sewer, notify the utilities supervisor. The spilled solution must be neutralized to avoid upsetting the chemical balance in the lagoons. 13. The lead operator will now close the reactor cleaning valves and open the condenser cleaning valve and the reactor sewer valve. 14. The lead operator will cut on both hot water charge pumps and flush through the condenser to the sewer for ten minutes. 15. The lead operator will then close the condenser cleaning valve, open the reactor cleaning valve, and flush the reactor to the sewer for ten minutes. 16. The lead operator will now close the reactor sewer valve. 17. Because of water dilution and resin accumulation, chem wash solution must be disposed of and fresh caustic pumped to the cleaning solution tank once per week. Follow the procedure outlined under "Used Chem Wash Solution Disposal." DTH 000096987 Operating Manual D-700 PVC Reactors Page 53 III. OPERATING PROCEDURES (CONTINUED) H. Full and Partial Swirl To assist in the production of quality resin, particularly low gel. It has been found that, by filling the reactor with water and agitating, the gel count is markedly lower. Swirl is performed when specified in the formula. 1. Full Swirl In this swirl, the reactor is almost completely filled with water. Lead Operator Duties a. Has "A" operator open manhead (refer to reactor manhead opening procedures). b. Turn the Interlock mode selector switch to the "swirl" position. c. Opens the reactor main charge valve and water charge valve. d. Starts both hot water charge pumps. e. Adds 2,000 counts of water to reactor (20,000 gallons). f. Cuts off pumps and closes valves. g. Agitates for ten minutes. h. Opens sewer valve and dumps. 2. Partial Swirl This swirl procedure Is the same as the full swirl except for the amount of water used. Charge 440 counts (4,400 gallons) and follow the same procedure as the full swirl. DTH 000096988 Operating Manual D-700 PVC Reactors Page 54 III. OPERATING PROCEDURES (CONTINUED) I. Colloid Solution Makeup The properties of polyvinyl chloride (PVC) are strongly dependent upon the type and quality of the colloid solution used. The colloid solution must be made very accurately and consistently every time it is prepared. The colloid solution is a 1 1/2 percent solution of Dow F-50 Methocel* powder in water. There is a local instrument panel located near the colloid makeup tank on the second floor of the recovery building. These instru ments are to aid the operator in making the colloid solution in a consistent manner. 1. Lead Operator Duties As soon as the lead operator is notified by the "A" operator that the colloid storage tank level is below the straight wall, he will schedule the "A" operator to make up colloid solution as follows: a. With the "A" operator at the colloid tanks, open the makeup tank outlet valve (CV-857) and start the colloid transfer pump to transfer the colloid solution to the storage tank. b. To mix any remaining heel in the storage tank with the new colloid solution, open the storage tank inlet valve (CV-858) ^Registered Trademark DTH 000096989 Operating Manual D-700 PVC Reactors Page 55 III. OPERATING PROCEDURES (CONTINUED) I. Colloid Solution Makeup (Continued) 1. Lead Operator Duties (Continued) and circulation pump inlet valve (CV-859) and start the colloid circulation pump. The charge tank inlet valve (CV-861) must be closed. c. When the "A" operator indicates that the makeup tank is empty, close the makeup tank outlet valve (CV-857) and turn off the transfer pump. d. With the circulation pump still running, notify the "A" operator to catch a colloid solution sample and take it to the laboratory for analysis. e. Close the storage tank Inlet valve (CV-858) and circulation pump inlet valve (CV-859) and turn off the circulation pump. f. Schedule the "A" operator to makeup a new batch of colloid solution as soon as possible. g. During the first part of the colloid makeup procedure when notified by the "A" operator, the lead operator will open the hot water charge valve (CV-706) and will start one hot water charge pump and the discharge valve associated with the charge pump to transfer hot water to the colloid makeup tank. The colloid makeup tank water meter will close the valves and shut down the hot water pump automatically when it reaches its set point. DTH 000096990 Operating Manual D-700 PVC Reactors Page 56 III. OPERATING PROCEDURES (CONTINUED) I. Colloid Solution Makeup (Continued) 2. "A" Operator Duties The "A" operator aids in colloid solution transfer by notifying the lead operator when the colloid storage tank needs to be refilled. After transfer, the "A" operator notifies the lead operator that the makeup tank is empty and then catches a sample of the colloid solution in the storage tank and takes it to the laboratory. When notified by the lead operator, the "A" operator makes up a new batch of colloid solution by the following procedure: a. Bring eight bags of Dow F-50 Methocel* powder (50 pounds per bag) to the top of the colloid makeup tank. b. Rinse the colloid makeup tank with water to the sewer until it is clean. c. Reset the colloid makeup water meter to 538 gallons, open the colloid tank inlet valve (CV-856), and notify the lead operator to open the hot water charge valve (CV-706), start a hot water charge pump, and open the discharge valve associ ated with the pump selected. The water meter will stop the pump and close the actuated valves that were opened when the set point is reached. Check to see that the agitator blades are covered. Registered Trademark DTH 000096991 Operating Manual D-700 PVC Reactors Page 57 III. OPERATING PROCEDURES (CONTINUED) I. Colloid Solution Makeup (Continued) 2. "A" Operator Duties (Continued) d. Start the colloid tank heater and the tank agitator. The temperature controller will close the steam valve when the water in the tank reaches 200F. e. When the heater is off, add the methocel powder very slowly with the agitator still on. Each bag should take about one minute to add. If the powder is added too quickly, it will form lumps and not dissolve properly. Carry the empty bags to a trash container. f. Allow about thirty minutes to let the agitator thoroughly mix the powder into the hot water. Check the mixture for lumps and continue to mix if lumps are present. g. When the mixture contains no lumps, reset the colloid makeup water meter to 2,623 gallons and open the colloid tank inlet valve (CV-856) and the colloid tank water valve (CV-828) to add cold water. The water meter will close the actuated valves that were opened when the set point is reached. Measure the outage on the colloid makeup tank to check the accuracy of the water meter. The straight wall por tion of the tank contains 14.8 gallons per inch. 000096992 DTH Operating Manual D-700 PVC Reactors Page 58 III. OPERATING PROCEDURES (CONTINUED) I. Colloid Solution Makeup (Continued) 2. "A" Operator Duties (Continued) h. Start the colloid tank cooler. The temperature controller will close the cooling jacket valve when the colloid solu tion reaches 85F. Check the cooling water temperature. If it is 80*P or above, the solution will cool very slowly; so close the manual cooling water valves and open the process water valves to the jacket. i. Check the temperature after four hours of cooling. If the temperature is 85F and the temperature controller has closed the cooling jacket valve, turn off the agitator. If the tank is still cooling, leave the agitator on until the tank has reached 85F. It is very important to cool the colloid solution completely each time to produce a good quality colloid solution. DTH 000096993 rN n Operating Manual D-700 PVC Reactors Page 59 III. OPERATING PROCEDURES (CONTINUED) J. Hydroquinone Solution Makeup Hydroquinone is injected into the recovery system to short stop the chain reaction and polymerization of vinyl chloride. If the hot VCM gases are allowed to flow through the recovery lines with out any inhibitor, they continue the reaction that was started in the reactor and rapidly fill and plug the recovery lines. Plugged lines in the recovery system are very time consuming to pull and clean and cause considerable amounts of downtime. Adequate and accurate injection of hydroquinone eliminates this problem. Hydroquinone (commercial name Tecquinol*) comes in a powder form and must be put into a solution with water for our use. When the hydroquinone solution level is low, as determined by the low level alarm LA-733 in the control room and/or by the hydro quinone storage tank sight glass, a new batch is to be made on the next day shift. Each batch should last approximately one month. 1. Lead Operator Duties As soon as it is determined that the hydroquinone storage tank is low, the day shift lead operator should schedule hydro quinone makeup between reactor recoveries. Registered Trademark DTH 000096994 Operating Manual D-700 PVC Reactors Page 60 III. OPERATING PROCEDURES (CONTINUED) J. Hydroqulnone Solution Makeup (Continued) 2. "A" Operator Duties When notified by the lead operator to make up a new batch of hydroqulnone solution, the "A" operator does the following: a. Weight up twenty pounds of hydroqulnone powder. b. Turn off hydroqulnone metering pump suction valve and, with the nitrogen turned on and the vent closed, drain the remaining heel to the sewer and rinse with water to the sewer. c. Open the vent and add water until the tank is about half full. d. Turn off the nitrogen temporarily and add the hydroqulnone powder through the funnel. e. Turn on the agitator and open the nitrogen line. f. Fill with water to the full mark on the sight glass (fifty gallons). g. Close the vent and mix until the powder is dissolved. h. Make sure the valves are lined up to the hydroquinone metering pump. 3. Safety Precautions Rubber gloves and full face shield must be worn while handling and transferring hydroqulnone dust and liquid. Hydroquinone dust can Irritate and seriously damage the eyes. DTH 000096995 Operating Manual D-700 PVC Reactors Page 61 III. OPERATING PROCEDURES (CONTINUED) J. Hydroquinone Solution Makeup (Continued) 3. Safety Precautions (Continued) First Aid;--In case of contact, immediately flush eyes with water for fifteen (15) minutes. Notify the plant nurse. Flush skin with water and wash clothing before reuse. DTH 000096996 Operating Manual D-700 PVC Reactors Page 62 . III. OPERATING PROCEDURES (CONTINUED) K. Used Chem Nash Solution Disposal A three-inch carbon steel line has been installed from the chem wash header to an existing three-inch carbon steel line connecting to tank 460 at the northwest corner of the plasticizer building, P-1. The purpose of this line is for transfer of spent chem wash solution for neutralization. Transfer of this solution will be done only on the day shift, Monday through Friday, due to the shortage of personnel in P-1 at night and during the weekends. Should it become necessary to transfer during the off-shifts, the shift supervisor will personally check the outage on tank 460 and set up the tank 460 valves. Procedure 1. The shift supervisor must have given instructions to transfer the used chem wash solution and make up a fresh batch. 2. The lead operator will contact the P-1 operator and have him check the outage on tank 460. 3. If there is sufficient outage, the lead operator will instruct the P-1 operator to open the chain valve into 460. There must be at least a 15-foot outage on tank 460 before starting the transfer. NOTE: Do not open the valve to tank 460 if any of the reactors are chem washing. 4. The "A" operator will open the manual valve on the three-inch line to P-1. DTH 000096997 Operating Manual D-700 PVC Reactors Page 63 III. OPERATING PROCEDURES (CONTINUED) K. Used Chem Wash Solution Disposal (Continued) Procedure (Continued) . 5. T The lead operator will close the chem wash inlet valve into the reactor and into the cleaning solution tank. 6. When the P-1 operator has the chain valve on tank 460 open, the lead operator will start the cleaning solution pump and pump all the solution in the cleaning solution tank to tank 460. 7. As soon as the tank is empty of solution, the "A" operator will open the three-inch process water valve to the cleaning solution tank to flush out the transfer line to tank 460 and then close the process water valve. 8. When the flush is complete, the lead operator will call the P-1 operator and Instruct him to close the valve on tank 460. 9. The lead operator will then shut off the cleaning solution pump. 10. The "A" operator will close the valve to tank 460 and open the cleaning solution tank sewer valve. 11. The "A" operator can now flush out residual resin and solution from the cleaning solution tank to the sewer. Make up new batch. NOTE: Notify the utility supervisor that about 100 gallons of caustic solution was dumped to the sewer. DTH 000096998 Operating Manual D-700 PVC Reactors Page 64 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage In the conversion of vinyl chloride monomer to polyvinyl chloride resin, an initiator is needed to start and help sustain the reac tion process. The Aberdeen plant uses peroxide-type initiators. The physical properties of the type resin needed determines the type of initiator to be used. All of these products must be kept in cold storage because of rapid decomposition at room temperatures. The initiator is a skin and eye irritant and must be handled accordingly. Safety precautions for all types of initiator are basically the same, with some differences in handling temperatures and explosive limits. 1. Safety Precautions in Handling Initiator a. Always wear Impervious gloves. b. Wear full face shield when handling an open container. c. Avoid contact with skin or clothing (will bleach out clothes). d. Do not leave initiator unattended when not under refriger ation. e. If initiator is spilled, soak up with absorbent material, such as vermiculite, and spread thinly in an isolated area. f. Dispose of empty containers immediately. Leave cap off and split the side of this container. DTH 0096999 Operating Manual D-700 PVC Reactors Page 65 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) 1. Safety Precautions in Handling Initiator (Continued) g. Bring only what is necessary to the production area. Do not allow the amount in the reactor area freezers to exceed one shift's consumption. h. If a partial or full jug of initiator is found sitting out, it may be water, but always handle and dispose of just as if it were initiator. i. If spilled on skin area, wash with large amounts of water. j. If splashed in the eyes, flush with water for fifteen (15) minutes and notify your supervisor. Do not use oils or salves on the eyes. k. Should any initiator catch on fire, use a dry chemical or foam fire extinguisher. Water will only spread the fire. However, if the fire is spreading and likely to ignite other initiator, get out of the area, since an explosion is very likely. 2. Physical Characteristics The following physical characteristics are given for Lupersol 223-75 and Lup-11 because they are currently in use; however, a different initiator may be used in the future. DTH 000097000 r" Operating Manual D-700 PVC Reactors Page 66 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) 2. Physical Characteristics (Continued) 223-75 Lup-11 Form Freezing Point, F Top Safe Storage, "F Decomposition Temp, F Container Label Liquid -110 20 50 One-Gallon Poly Jug Red* Liquid -2 0-40 160 Five-Gallon Poly Jug Yellow** *Red Label--Liquids with flash point below 80F. **Yellow Label--All liquids and solids with flash point above 80 F. 3. Initiator Storage Freezers Two walk-in freezers and one chest-type freezer have been installed for initiator storage at temperatures ranging down to -30F. Each freezer has two independent refrigeration compressors with one to be held in reserve. This is to insure continuous operation at temperature set points. High tempera ture in any freezer will activate the air horn and beacon flasher alarms. An automatic defrost system controlled by time clocks will provide frost-free operation, a. Operating Conditions (1) Temperature The temperatures are adjustable. They can be set from -30F to +30F. DTH 000097001 Operating Manual D-700 PVC Reactors Page 67 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) a. Operating Conditions (Continued) (2) Alarms Chest and walk-in freezers on high temperature set ting will actuate the red beacon light and air horn. This is common to all initiator freezers in the plant. The present alarm's set point is 17F (+2). (3) Compressors Compressors are numbered 1 through 6. (a) No. 1 and No. 2 compressors serve the east walk-in freezer. (b) No. 3 and No. 4 compressors serve the west walk-in freezer. (c) No. 5 and No. 6 compressors service the chest freezer on the west end. (4) Compressor Shutdown Conditions (Automatic) (a) Temperature of freezer at set point. (b) Low oil level in the compressor. (c) High or low compressor pressure. (5) Circuit Breakers (a) On the Compressor Panel--The compressor breakers in sequence No. 1 through No. 6. (b) Fan Panel--The fans are numbered 2, 3, 5, and 6. (c) The miscellaneous panel has lights, controls, alarms, fans, and clocks. DTH 000097002 n Operating Manual D-700 PVC Reactors Page 68 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) (6) Defrost Cycles--Adjustable In the walk-in freezers, each compressor switches to hot gas bypass every six hours to provide a defrost cycle. This is controlled by a time clock. (7) Freezer Capacity (a) Walk-In Freezers - 550 gallons or 4,200 pounds. (b) New Initiator freezer - 100 gallons or 770 pounds. 4. Design and Operational Functions Each freezer is provided with two refrigeration units which fare capable of maintaining the desired freezer temperature. Both units can be run simultaneously to allow a check on compressor operation. The temperature element in each freezer is connected to a mer cury switch which starts and stops the compressor. These are adjustable and can be set for different temperatures. Each compressor has a timer which activates a solenoid valve in the hot gas line to send hot gas directly to the evaporator to allow for the defrost cycle. The fan normally runs with the compressor but is off during the defrost cycle. The east and west freezers defrost every six hours, and the chest freezer defrosts every eight hours. The water-cooled condensers on each compressor have water bypass to allow continuous flow dth Operating Manual D-700 PVC Reactors Page 69 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) 4. Design and Operational Functions (Continued) and prevent freezeup during cold weather. The condensers also have inlet and outlet valves to allow for acid cleaning. Condenser cooling water is normally supplied by and returned to the cooling tower. During shutdowns and power outages, a bypass valve from the well/city water can be opened to supply water pressure. If the condensers are put on the well water, open the block valve in the manhole at the west end of the cooling tower to divert the water to the sewer. 5. Daily Operational Checks a. Each compressor oil level by maintenance. b. Temperature recorders by "A" operator. c. Frost buildup on freezer coils by "A" operator. NOTE: Manual defrost instructions are on the inside front of each time clock. NOTE: Due to the explosive nature of this initiator, formal approval must be obtained from the operations superin tendent and the mechanical superintendent before any changes are made to this operation. DTH 000097004 Operating Manual D-700 PVC Reactors Page 70 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) 6. Emergency Procedure for Initiator Preezers If the power should go off, do not open the freezers but do the following: a. Find out if the power failure is because of a malfunction in the plant. (1) If trouble is inside the plant, survey the situation and estimate how long the outage will be. Freezers should hold temperature from 3-4 hours, depending on what is in them, the outside temperature, and how many times the door is opened. (2) If trouble is determined to be outside the plant, call Berl Hill at 369-4731, 369-2159, or 369-2019. (a) Keep in touch with the Light Department to deter mine how long the outage will be. (b) If outage is expected to be over three (3) hours, call Jim Barton (369-4755) or Joann Pope (369-4949). They will arrange for purchase of dry ice. b. If a compressor should fail and it is not an electrical problem, get in touch with maintenance as soon as possible. (1) If help is not available from maintenance, get in touch with Dahlem Sales and Service at 369-2165 or residence 369-4435. DTH 000097005 Operating Manual D-700 PVC Reactors Page 71 III. OPERATING PROCEDURES (CONTINUED) L. Initiator Handling and Storage (Continued) 6. Emergency Procedure for Initiator Freezers (Continued) (2) If the problem cannot be fixed, try to move all v initiator to other freezers. If not possible, get dry ice. NOTE: If compressors should go out on a freezer, make sure fans are turned off to that freezer. East freezer 1 and 2 fans, middle freezer 3 and 4 fans, and west freezer 5 and 6 fans. c. Notify the following if an emergency should arise with the initiator freezers: Jim Barton - 369-4755 Ed Kieschnick - 1-328-0350 7. Circle Chart Responsibility and Change Schedule a. The "A" operator on each shift will check the charts to be sure they have ink and are rotating. b. The "A" operator on the 11-7 shift will place new charts in the recorder and turn in the previous day's chart to the shift supervisor. DTH 00097006 Operating Manual D-700 PVC Reactors Page 72 III. OPERATING PROCEDURES (CONTINUED) M. Reactor Pressure Check Prior to the startup of a reactor after an extended outage or following a maintenance outage such as replacing a main dump valve or rodding out the condenser tubes, the reactor must be hydrostatically pressure checked. This is to insure that no leakage occurs at the reactor, either inward or outward. Procedure 1. The lead operator sets up the pressure check as follows: a. Place the reactor mode in "emergency" to gain use of both the charge water valve and the rinse valves. b. Open both hot water charge pump discharge valves CV-849 and CV-829. c. Open the reactor charge water valve. d. Open the main charge valve. e. Open the emergency vent valve. 2. The lead operator then turns on both hot water charge pumps and fills the reactor. 3. The "A" operator stands by to notify the lead operator when water comes out the atmospheric vent, showing that the reactor is full. 4. The lead operator then shuts down the hot water charge pumps and closes all valves. This must be done immediately to avoid overpressuring the reactor and blowing the rupture discs. DTH 000097007 Operating Manual D-700 PVC Reactors Page 73 III. OPERATING PROCEDURES (CONTINUED) M. Reactor Pressure Check (Continued) Procedure (Continued) 5. The "A" operator then increases the reactor pressure by charging water into the reactor through the initiator injec tion system. 6. The lead operator monitors the reactor pressure from the control room and instructs the "A" operator to shut off water addition when the pressure reaches 130 psig. 7. The "A" operator then checks the reactor for leaks at the reactor bottom and top side. If a flange or gasket has been changed, check these very closely. 8. The lead operator then monitors the reactor pressure. If the reactor holds 130 psig for ten minutes, the pressure check is terminated. If the reactor loses pressure, instruct the "A" operator to bring the pressure back up to 130 psig with the high pressure service water and reinspect the reactor for leaks. NOTE: Do not charge a reactor that will not hold pressure. 9. When the pressure check is completed, the lead operator dumps the water in the reactor to the sewer. The reactor is now ready to start evacuation procedure. DTH 000097008 Operating Manual D-700 PVC Reactors Page 74 III. OPERATING PROCEDURES (CONTINUED) N. Reactor Cleaning and Entry 1. Reactor Manhead Opening Procedures One of the most critical parts of the operator's job is the opening of the reactor Lenape* manhead. Following is a list of procedures that must be followed by the "A" operator or anyone else when opening a reactor manhead. Procedure a. Check the pressure gauge and/or bleed valve for pressure or vacuum. b. Put on continuous flow fresh air mask. c. Unlatch Lenape* lock on Lenape* manhead roll-bar and drop down. NOTE: If the reactor has pressure when the roll-bar arm is lifted, the pressure will start escaping. If this should happen, immediately push lift-bar down and notify the lead operator. d. Slowly raise manhead four to six inches and hold in that position. e. Call lead operator and have him Cut on the reactor evacu ation ejector to pull air inward through the manhead. f. Finish raising the manhead. g. Remove continuous flow fresh air mask and process with task. h. Change "0" ring on manhead. Registered Trademark DTH 000097009 n- Operating Manual D-700 PVC Reactors Page 75 III. OPERATING PROCEDURES (CONTINUED) N. Reactor Cleaning and Entry (Continued) 1. Reactor Manhead Opening Procedures (Continued) i. Look at the bottom of rupture discs to determine if they are plugged with resin. j. If the bottom manhead is to be opened, inspect the bottom of the reactor through the open manhead. The reactor should contain no liquids. k. Go to the bottom of the reactor and make sure that the safety chain and jacking bolts are in proper position on the bottom manhead. l. Remove bolts in manhead. m. Carefully open manhead with jacking bolts. 2. Reactor Cleaning and Entry This section will cover precautions taken prior to entry and during entry and cleaning of the reactor. The following is a check list stating conditions which must be met by anyone entering the reactor. Procedure a. The reactor must be empty and flushed with water. b. The C>2 content must be greater than 20 percent. c. The VCM content must be less than 10 ppm. d. The top and bottom manways must be open. e. The nitric oxide (NO) piping must be disconnected. DTH 000097010 Operating Manual D-700 PVC Reactors Page 76 III. OPERATING PROCEDURES (CONTINUED) N. Reactor Cleaning and Entry (Continued) 2. Reactor Cleaning and Entry (Continued) f. The following lines must be blanked: (1) Main eight-inch dump line. (2) Four-inch steam stripping line. (3) Six-inch condenser lines. (4) Four-inch chem wash and rinse line to condenser.* (5) Four-inch chem wash and rinse line to reactor.* (6) One-inch initiator injection line. (7) One-inch inerts vent. C' (8) Three-inch colloid charge line. (9) One-inch sample line. g. Lock out and tag agitator breaker. h. Test agitator switch. i. Special precautions and safety equipment that may be needed are: (1) Impervious suit. (2) Continuous flow fresh air mask. (3) Rubber gloves. (4) Scaffolding for work above bottom level. (5) Two-way radio communication plus manway watch. (6) Safety harness and rope. *When preparing to blank or remove blank in chem wash line, lock out cleaning r solution pump, open chem wash line to reactor, and bleed line at discharge of pump before breaking chem wash flange. DTH 000097011 Operating Manual D-700 PVC Reactors Page 77 III. OPERATING PROCEDURES (CONTINUED) N. Reactor Cleaning and Entry (Continued) 2. Reactor Cleaning and Entry (Continued) j. While cleaning the buildups from the baffles and blade, take extreme care not to scratch the reactor walls. These walls have been polished to eliminate giving the resin being formed during reaction a place to create a buildup. NEVER SCRAPE THE WALLS. k. Around the shaft at the bottom of each reactor is a carbon throttle bushing. The purpose of the throttle bushing is to protect the reactor seal from resin. The seal water flush will not be effective if the throttle bushing or holder is damaged. If there is any buildup in this area, it is the Maintenance Department's responsibility to remove it. Operators are NOT to clean the throttle bushing. Damage to the throttle bushing may cause seal failure. l. If hammer and chisel are required to clean the reactor, be careful of chisel placement to avoid it kicking back out of the buildup and causing personal injury. m. While in the reactor, check the safety discs for buildups, nozzles for plugs, and the bottom of the condenser for plugging. n. When internal job is completed, remove scaffolding from the reactor and store neatly. Remove any loose buildup on the reactor bottom and close the bottom manhead. o. Clean up any debris, rags, etc. The job is never complete until the area is clean. DTH 000097012 Operating Manual D-700 PVC Reactors Page 78 III. OPERATING PROCEDURES (CONTINUED) 0. Housekeeping Guidelines Good housekeeping is a major portion of any task to be undertaken, and no task can be called complete until the work area has been cleaned. Return all tools and materials used to thoir proper place and do not leave lying around to create a safety hazard. The housekeeping of the reactor area is the responsibility of all people working there. This includes supervisors, operators, main tenance, and contractors. Individual areas of housekeeping responsibilities are: 1. Control Room and Reactor Area--To be kept clean by each shift. 2. Food Preparation Area--To be kept clean by each shift. 3. Control Room Refrigerator--To be cleaned and washed by the 7-3 shift each Monday. 4. Storage Shed Area--To be cleaned and straightened by the 7-3 shift each Tuesday. 5. Initiator Storage Area--To be kept orderly by each shift and cleaned thoroughly by the 7-3 shift each Wednesday. All reactor personnel are responsible for the entire reactor area; but certain areas are set up for shift responsibility as to special housekeeping, painting, and general upkeep. These are: 1. 7-3 Shift a. Reactor condenser level. b. Reactor manhead level. 4 c. Reactor bottom level. DTH 000097013 Operating Manual D-700 PVC Reactors Page 79 111. OPERATING PROCEDURES (CONTINUED) 0. Housekeeping Guidelines (.Continued) 2. 3-11 Shift a. Reactor table top level. b. VCM receiver area. c. Initiator freezer area. 3. 11-7 Shift a. First floor recovery building. b. Second floor recovery building. DTH 000097014 IV. Equipment Index DTH 000097015 Operating Manual D-700 PVC Reactors Page 80 IV. EQUIPMENT INDEX A. Reactors 1. Polymerization Reactors 45-741, 45-742, 45-743, and 45-744 a. Purpose Vessel used to react VCM to PVC in a water suspension. b. Description Vertical-mounted, bottom-agitated vessel, 12-foot diameter by 22-foot straight wall height (28 feet overall height), jacketed, and with top-mounted condenser. The reactor is stainless steel, and the cooling water and steam jacket is carbon steel. Approximate capacity is 19,000 gallons. c. Normal Operating Conditions The reactor produces various resin types, operating in a pressure range of 28.5 inches Hg vacuum to 150 psig and a temperature range of 80-225F. d. Design Conditions Shell Jacket Temperature, F Pressure, psig 250 200 (and full vacuum) 200 30 B. Heat Exchangers 1. Reactor Condensers 55-328, 55-329, 55-330, and 55-331 a. Purpose To remove the heat of reaction from the polymerization reactor by condensing VCM vapor. DTH 000097016 Operating Manual D-700 PVC Reactors Page 81 IV. EQUIPMENT INDEX (CONTINUED) B. Heat Exchangers (Continued) b. Description Each of the reactor condensers are vertical, mounted on top of the polymerization reactors. Cooling water (shell side) is used to condenser VCM (tube side). Each conden ser has 2,100 square foot surface area provided by 999 tubes which are eight feet long by one-inch diameter. Materials of construction are stainless steel or stainless steel clad for all surfaces in contact with VCM. c. Normal Operating Conditions Condensers operate in a temperature range of 80-225F and pressure range of 28.5 inches Hg vacuum to 150 psig during the reactor cycle. d. Design Conditions Shell Tubes Temperature, F Pressure, psig 200 250 120 200 (and full vacuum) 2. Hot Water Preheater 55-332 a. Purpose To heat process water to 145F before it enters the hot water tank, 45-748. DTH 000097017 Operating Manual D-700 PVC Reactors Page 82 IV. EQUIPMENT INDEX (CONTINUED) B. Heat Exchangers (Continued) b. Description Horizontal shell and tube type exchanger with steam on the shell side and water on the tube side. Surface area of 331 square feet is provided by 64 tubes 20 feet long by one-inch diameter. The tubes are stainless steel, and the shell is carbon steel. c. Normal Operating Conditions Steam temperature and pressure on the shell side will vary. Water on the tube side will be around 50 psig and will enter near 60F and exit at 145F. d. Desgin Conditions Shell Tube Temperature, F Pressure, psig 400 400 175 200 3. Hot Water Tank Heater 55-333 a. Purpose To maintain water temperature in hot water tank 45-748. b. Description External plate coil type heat exchanger that will be clamped outside the hot water tank; stainless steel construction. DTH 000097018 Operating Manual D-700 PVC Reactors Page 83 IV. EQUIPMENT INDEX (CONTINUED) B. Heat Exchangers (Continued) c. Normal Operating Conditions Steam in the coil should be around 341F and 105 psig. Water in the hot water tank should be near 145F. d. Design Conditions 400F and 175 psig 4. Water Recirculation Cooler 55-334 a. Purpose To cool the recirculation water in recovery knockout drum 45-760. b. Description Horizontal mounted, shell and tube type heat exchanger. Cooling water is on the shell side and recirculating water is on the tube side. Surface area of 1,441 square feet is provided by 466 tubes, 16 feet long by 3/4-inch diameter. The tubes are stainless steel and the shell is carbon steel. c. Normal Operating Conditions d. Design Conditions Temperature, F Pressure, psig Shell 450 150 Tube 400 150 DTH 000097019 Operating Manual D-700 PVC Reactors Page 84 IV. EQUIPMENT INDEX (CONTINUED) B. Heat Exchangers (Continued) 5. Seal Water Coolers 55-335 and 55-336 a. Purpose To cool the circulating vacuum pump and compressor seal water. b. Description Horizontal-mounted shell and tube type heat exchanger. Cooling water is on the shell side and recirculating seal water is on the tube side. Surface area of 339 square feet is provided by 182 tubes 10 feet long by 3/4-inch diameter. The tubes are stainless steel and the shell is carbon steel. c. Normal Operating Conditions d. Design Conditions Temperature, F Pressure, psig Shell 200 150 Tube 380 150 6. Recovered VCM Condensers 55-337 and 55-338 a. Purpose To condense VCM vapor during recovery as it is removed from the polymerization reactors. DTH 000097020 Operating Manual D-700 PVC Reactors Page 85 IV. EQUIPMENT INDEX (CONTINUED) B. Heat Exchangers (Continued) b. Description Horizontal-mounted shell and tube type heat exchangers. Cooling water is on the shell side, and VCM is on the tube side. Surface area of 1,030 square feet is provided by 450 tubes 12 feet long by 3/4-inch diameter. The tubes are stainless steel, and the shell is carbon steel. c. Normal Operating Conditions d. Design Conditions Temperature, F Pressure, psig Shell 400 150 Tube 400 150 7. Cleaning Solution Heater 55-339 a. Purpose To heat and maintain chem wash solution temperature during chem wash of the reactors. b. Description Horizontal-mounted shell and tube type heat exchanger. Steam is on the shell side, and chem wash solution (caustic) is on the tube side. Surface area of 214 square feet is provided by 79 tubes 14 feet long by 3/4-inch diameter. The tubes are stainless steel, and the shell is carbon steel. DTH 000097021 Operating Manual D-700 PVC Reactors Page 86 IV. EQUIPMENT INDEX (CONTINUED) B. Heat Exchangers (Continued) c. Normal Operating Conditions Steam temperature and pressure on the shell side will vary. Cleaning solution on the tube side is estimated to enter at 175F and leave at 1906F with a pressure of 125 psig. d. Design Conditions Temperatue, #F Pressure, psig Shell 175 400 Tube 200 400 C. Tanks and Vessels 1. Instrument Air Capacity Tank 45-301 a. Purpose To provide adequate instrument air during periods of high demand and temporarily supply air during instrument air failure. b. Description Vertical-mounted, five-foot nine-inch straight wall height, four-foot diameter, carbon steel construction. c. Normal Operating Conditions 100 psig and 80F d. Design Conditions DTH 000097022 /"""N Operating Manual D-700 PVC Reactors Page 87 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 2. Recovered VCM Storage Tanks 45-317 and 89-520 a. Purpose Storage of recovered VCM and charge tank for recovered VCM. b. Description Vertical-mounted, 18-foot straight wall height, 22-foot overall height, eight-foot diameter with an approximate capacity of 7,200' gallons, carbon steel construction c. Normal Operating Conditions Ambient temperature and 20-70 psig. 3. Blowdown Tank 45-319 a. Purpose To provide for collection and recovery of various VCM con taining vapor vents and waste waters. b. Description Horizontal-mounted, 26-foot straight wall length, six-foot diameter, approximate capacity 5,500 gallons, carbon steel construction. c. Normal Operating Conditions Ambient temperature to 150F and pressure from 10 inches Hg vacuum to 10 psig. d. Design Conditions 350F and full vacuum to 80 psig. DTH 000097023 Operating Manual D-700 PVC Reactors Page 88 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 4. Fresh VCM Storage Tank 45-745 a. Purpose VCM storage tank which holds fresh VCM used in reactor charge. b. Description Vertical-mounted, 22-foot straight wall height, 26-foot overall height, eight-foot diameter with an approximate capacity of 8,700 gallons, carbon steel construction. c. Normal Operating Conditions Ambient temperature and 20-70 psig. d. Design Conditions 150F and full vacuum to 150 psig. 5. Hot Water Tank 45-748 a. Purpose To supply a large volume of hot water for reactor charge and rinse. b. Description Vertical, cone roof, 42-foot straight wall height, 12-foot diameter with an approximate capacity of 35,000 gallons, aluminum construction. c. Normal Operating Conditions Atmospheric pressure and 145F. d. Design Conditions 212F and 1.5 inches of water. DTH 000097024 Operating Manual D-700 PVC Reactors Page 89 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 6. Initiator Injection Pot 45-750 a. Purpose To inject initiator into the reactor during charge. b. Description Vertical-mounted, two-foot straight wall height with one- foot diameter, approximate capacity 12 gallons, stainless steel construction. c. Normal Operating Conditions Temperature near 70F and 180-260 psig. d. Design Conditions 150F and 300 psig 7. Colloid Makeup Tank 45-751 a. Purpose To provide for consistent colloid solution makeup. b. Description Top agitated, vertical-mounted, flat top, 11 1/2-foot straight wall height, seven-foot diameter, approximate capacity 3,300 gallons, bottom jacket for heating, side jacket for cooling, stainless steel construction. c. Normal Operating Conditions Atmospheric pressure and 70-200F. d. Design Conditions 400F and 0 psig DT11 000097025 Operating Manual D-700 PVC Reactors Page 90 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 8. Colloid Storage Tank 45-752 a. Purpose To provide colloid solution storage. b. Description Vertical-mounted, flat top, cone bottom, 12-foot straight wall height, seven-foot diameter, approximate capacity 3,400 gallons, stainless steel construction. c. Normal Operating Conditions Atmospheric pressure and 70-85F. d. Design Conditions 150F and 0 pslg 9. Colloid Charge Tank 45-753 a. Purpose To provide a sufficient quantity of quality colloid solution for charge. b. Description Vertical-mounted, flat top, cone bottom, 14-foot straight wall height, 5 1/2-foot diameter, capacity approximately 2,400 gallons, stainless steel construction. c. Normal Operating Conditions Atmospheric pressure and 70-85F. d. Design Conditions 150F and 0 psig DTH 000097026 Operating Manual D-700 PVC Reactors Page 91 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 10. Seal Oil Storage Drum 45-754 a. Purpose To provide seal oil storage. b. Description Horizontal-mounted, five-foot straight wall length by three-foot diameter, carbon steel construction, approxi mate capacity 270 gallons. c. Normal Operating Conditions Atmospheric pressure, ambient temperature. d. Design Conditions 150F and 0 psig 11. AMS Short Stop Charge Pots 45-755. 45-756, 45-757, and 45-758 a. Purpose To provide a means for injecting short stop solution into any or all of the reactors to stop the reaction. b. Description Vertical-mounted, two-foot straight wall height, six-inch diameter, capacity approximately three gallons, stainless- steel construction. c. Normal Operating Conditions Approximately 70F and 180-260 psig. d. Design Conditions 150F and 300 psig DTH 000097027 Operating Manual D-700 PVC Reactors Page 92 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 12. Mechanical Seal Purge Water Surge Drum 45-759 a. Purpose To provide seal purge water in the event of electrical power failure. b. Description Vertical-mounted, seven-foot straight wall height, 3 I/2-foot diameter, capacity approximately 500 gallons, stainless steel construction. c. Normal Operating Conditions Approximately 70F and 200 psig. d. Design Conditions 150F and 300 psig 13. Recovery Knockout Drums 45-760 and 45-761 a. Purpose To prevent liquid and solids carryover to the recovery vacuum pumps and compressors during reactor recovery. b. Description Vertical-mounted; bottom section has five-foot straight wall height; five-foot diameter; top section has ten-foot straight wall height; three-foot diameter; top section has water spray to help remove carryover; carbon steel construc tion. DTH 000097028 Operating Manual D-700 PVC Reactors Page 93 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) c. Normal Operating Conditions 100-200F and 0-35 psig d. Design Conditions 300F and full vacuum to 150 psig 14. Seal Water Separators 45-762 and 45-763 a. Purpose To separate the circulating vacuum pump and compressor seal water from the recovered VCM vapor. b. Description Vertical-mounted, seven-foot straight wall height, fourfoot diameter, approximate capacity 650 gallons, carbon steel construction. c. Normal Operating Conditions 100-150F and 40-80 psig d. Design Conditions 300F and full vacuum to 150 psig 15. Recovered VCM Collect Tank 45-764 a. Purpose To collect recovered VCM and provide liquid head for VCM transfer pump to allow pumping of recovered VCM to recovered VCM storage tank. DTH 000097029 Operating Manual D-700 PVC Reactors Page 94 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) b. Description Horizontal-mounted, ten-foot straight wall length, threefoot diameter, approximate capacity 520 gallons, carbon steel construction. c. Normal Operating Conditions 70-100F and 35-75 psig d. Design Conditions 160F and full vacuum to 150 psig 16. Hydroquinone Storage Tank 45-765 r^ a. Purpose Provide for hydroquinone storage and makeup. b. Description Top-agitated, vertical-mounted, 2'6" straight wall height, two-foot diameter, approximate capacity 60 gallons, carbon steel construction. c. Normal Operating Conditions Temperature near ambient; pressure about 1 psig. d. Design Conditions 150F and 16 psig 00,00>' 1030 Operating Manual D-700 PVC Reactors Page 95 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 17. Slurry Dump Tank 45-766 a. Purpose To provide sufficient head for the slurry transfer pumps to operate correctly. b. Description Vertical-mounted, flat top, cone bottom, three-foot straight wall height, five-foot diameter, approximate capacity 440 gallons, stainless steel construction. c. Normal Operating Conditions One-inch water vacuum and 150-200F. d. Design Conditions 250F and two-inch water pressure. 18. Cleaning Solution Tank 45-767 a. Purpose To provide an adequate amount of chem wash solution during reactor chem wash. b. Description Vertical-mounted, flat top, cone bottom, ten-foot straight wall height, ten-foot diameter, approximate capacity 5,800 gallons, carbon steel construction. c. Normal Operating Conditions Atmospheric pressure and 60-190F d. Design Conditions r DTH 000097031 250.F and + five-inch water pressure. Operating Manual D-700 PVC Reactors Page 96 IV. EQUIPMENT INDEX (CONTINUED) C. Tanks and Vessels (Continued) 19. Reactor Evacuation Ejector Cyclone Separator 45-768 a. Purpose To remove any condensate present in the motive steam to the reactor evacuation steam ejector. b. Description High efficiency horizontal separator, Anderson type L5-4-175, 10 3/4-inch outside diameter, 26 inches long, carbon steel construction with stainless steel internal baffles. r*\ c. Normal Operating Conditions Steam in is 125 psig and 353F. d. Design Conditions 400F and 175 psig 20. Reactor Sampling Bomb 45-770 a. Purpose To safely obtain a resin sample from the reactor. b. Description 3/4-inch stainless steel pipe, three inches long. One end is capped, and the other is fitted with a coupling. A basket strainer fits inside the sampler for easy resin removal. c. Normal Operating Conditions Slight vacuum to 60 psig and 70-140F. DTH 000097032 Operating Manual D-700 PVC Reactors Page 97 IV. EQUIPMENT INDEX (CONTINUED) D. Filters 1. Process Water Charge Filter 64-716 a. Purpose To remove dirt and scale from the charge water. b. Description Filterite Model 88MS04-316-4FD-C300, cartridge type, stainless steel. c. Normal Operating Conditions t_ 40 psig and 70 F d. Design Conditions 300 psig and 2008F. Particle retention size is ten microns. 2. VCM Charge Filters 64-718 and 64-742 a. Purpose To remove any PVC particles from the VCM charge to the reactor. b. Description Filterite model 906415-001, cartridge type, stainless steel filter with polypropylene filtering element. c. Normal Operating Conditions 150-200 psig and ambient temperature. d. Design Conditions 150F, 300 psig, 1,000 gpm, particle retention size is ten microns. DTH 000097033 Operating Manual D-700 PVC Reactors Page 98 IV. EQUIPMENT INDEX (CONTINUED) D. Filters (Continued) 3* Recovered VCM Filter 64-719 a. Purpose To remove PVC particles from the recovered VCM charge to the reactor. b. Description Filterite Model 909596, cartridge type, stainless steel filter with polypropylene filtering element. c. Normal Operating Conditions 40-130 psig and ambient temperature. d. Design Conditions 150F, 190 psig, 250 gpm, particle retention size ten microns. 4. Process Water Filter 64-720 a. Purpose To remove dirt and scale from process water to the hot water tank. b. Description Dollinger Model LL-122-280, cartridge type, carbon steel filter with polypropylene filtering element. c. Normal Operating Conditions 40 psig and 70F d. Design Conditions 100F, 100 psig, 200 gpm, particle retention size ten microns. DTH 000097034 Operating Manual D-700 PVC Reactors Page 99 IV. EQUIPMENT INDEX (CONTINUED) D. Filters (Continued) 5. Colloid Makeup Water Filter 64-721 a. Purpose To remove dirt and scale from water used in colloid makeup. b. Description Dollinger Model LL-222-180, Series 150, cartridge type, stainless steel filter, cotton filtering element. c. Normal Operating Conditions 40 psig and 70F d. Design Conditions 250F, 250 psig, 125 gpm, particle retention size ten microns. 6. Colloid Transfer Filters 64-722 and 64-723 a. Purpose To remove any undissolved F-50 methocel (the powder that is dissolved in water to make the colloid solution) from the colloid solution. b. Description Dollinger Model LL-222-66, cartridge type, stainless steel filter with polypropylene filtering element. c. Normal Operating Conditions 35 psig and 85F d. Design Conditions 100F, 75 psig, 50 gpm, particle retention size 90 microns. DTH 000097035 Operating Manual D-700 PVC Reactors Page 100 IV. EQUIPMENT INDEX (CONTINUED) D. Filters (Continued) 7. Service Water Filter 64-724 a. Purpose To remove dirt and scale from service water. b. Description Dollinger Model LL-222-280, cartridge type, stainless steel filter with cotton filtering element. c. Normal Operating Conditions 40 psig and 70F d. Design Conditions 100F, 100 psig, 190 gpm, particle retention size ten microns. 8. Seal Oil Supply Filters 64-725 and 64-726 a. Purpose Removes dirt and scale from seal oil. b. Description Dollinger Model LL-222-39, Series 150, cartridge type, stainless steel filter with cotton filtering element. c. Normal Operating Conditions 245 psig and 100F d. Design Conditions 150F, 275 psig, 4 gpm, particle retention size one micron. DTH 000097036 r" Operating Manual D-700 PVC Reactors Page 101 IV. EQUIPMENT INDEX (CONTINUED) D. Filters (Continued) 9. Seal Oil Return Filters 64-727 and 64-728 a. Purpose Removes dirt and scale from seal oil. b. Description Dolllnger Model LL-222-39, Series 150, cartridge type, stainless steel filter with cotton filtering elements. c. Normal Operating Conditions 220 psig and 100F d. Design Conditions 150F, 275 psig, 4 gpm, particle retention size one micron. 10. Seal Water Filters 64-731 and 64-732 a. Purpose To remove PVC resin from the circulating seal water for the recovery vacuum pumps and compressors. b. Description Dolllnger Model LL-122-140, cartridge type, carbon steel filter with polypropylene filtering element. c. Normal Operating Conditions 90-130 psig and 100-150F d. Design Conditions 300F, 150 psig, 160 gpm, particle retention size 100 microns. DTH 000097037 Operating Manual D-700 PVC Reactors Page 102 IV. EQUIPMENT INDEX (CONTINUED) D. Filters (Continued) 11. Slurry Strainer 64-733 a. Purpose To remove large resin particles from the slurry. b. Description Sweco Model LS605 1210, vibrating screen, stainless steel filter and filtering element. c. Normal Operating Conditions One-inch water vacuum and 150-200F d. Design Conditions 250F, two-inch water pressure, 1,000 gpm, particle reten tion on four-mesh screen. 12. Cleaning Solution Strainer 64-734 a. Purpose To remove PVC particles from the cleaning solution. b. Description Ten-inch Elco line strainer, carbon steel construction. c. Normal Operating Conditions 2 psig and 180F d. Design Conditions 200F, 20 psig, 500 gpm, particle retention on four-mesh screen. DTH 000097038 Operating Manual D-700 PVC Reactors Page 103 IV. EQUIPMENT INDEX (CONTINUED) D. Filters (Continued) 13. Breathing Air Filters 64-735, 64-736, 64-737, 64-738, 64-739, 64-740 a. Purpose To remove dirt and scale from the breathing air. b. Description Dollinger Model GP-246-15, cartridge type, stainless steel filter. Nylon 147 filtering element. c. Normal Operating Conditions 70-90 psig and 60-70F d. Design Conditions 100F, 125 psig, 6,000 standard cubic feet per hour (SCFH), particle retention size five microns. 14. Blowdown Tank Drain Strainer 64-741 a. Purpose To remove PVC particles in water dumped to the sewer from the blowdown tank. b. Description Andale type 105 simplex strainer, basket strainer, cast iron with stainless steel filtering element. c. Normal Operating Conditions 8-9 psig and 100-150F d. Design Conditions 200F, 125 psig, 200 gpm, particle retention size 3/8 inch. DTH 000097039 Operating Manual D-700 PVC Reactors Page 10A IV. EQUIPMENT INDEX (CONTINUED) E. Pumps 1. VCM Charge Pumps 72-875 and 72-876 a. Purpose To supply reactors with VCM during charge. b. Description Centrifugal type, Goulds Model 3736, 3X6-13DV, Group L, 150-HP, 3,560 RPM. The casing is carbon steel and the impeller is cast iron. c. Normal Operating Conditions Rated for 800 gpm at 450 feet of differential head. 2. Recovered VCM Charge Pumps 72-877 and 72-878 r' a. Purpose To supply recovered VCM to the suction of the VCM charge pumps during charge. b. Description Centrifugal type, Goulds Model 3196 MT, 2X3-13, 10-HP, 1,750 rpm. The casing is stainless steel and the impeller is cast iron. c. Normal Operating Conditions Rated for 250 gpm at 82 feet of differential head. DTH 000097040 Operating Manual D-700 PVC Reactors Page 105 IV. EQUIPMENT INDEX (CONTINUED) E. Pumps (Continued) 3. Hot Water Charge Pumps 72-879 and 72-880 a. Purpose To supply the reactor with hot water during charge. b. Description Centrifugal type, Goulds Model 3196 LTC, 2X3-13, 100-HP, 3,550 rpm. The casing is stainless steel and the impeller is cast iron. c. Normal Operating Conditions Rated for 450 gpm at 410 feet of differential head. 4. Colloid Batch Transfer Pump 72-881 and Colloid Circulation Pump 72-882_________________________________________ _ a. Purpose The batch transfer pump is used primarily to transfer colloid from the colloid makeup tank to the colloid storage tank. The colloid circulation pump is used primarily to circulate colloid in the storage tank and to transfer col loid from the storage tank to the colloid charge tank. These pumps are piped so they can be used to spare each other. b. Description Centrifugal type, Goulds Model 3196 MT, 1X2-10, 3-HP, 1,750 rpm. The casing and impeller are stainless steel. c. Normal Operating Conditions Rated for 50 gpm at 69 feet differential head. DTH 000097041 r' Operating Manual D-700 PVC Reactors Page 106 IV. EQUIPMENT INDEX (CONTINUED) E. Pumps (Continued) 5. Colloid Charge Pumps 72-883 and 72-884 a. Purpose Used to charge colloid to the reactor. b. Description Centrifugal type, Goulds Model 3736, 1X2-11B, 50-HP, 3,550 rpm. The casing and impeller are stainless steel. c. Normal Operating Conditions Rated for 100 gpm at 470 feet differential head. 6. High Pressure Service Water Pumps 72-885 and 72-886 a. Purpose To provide high pressure water for a variety of uses. b. Description Centrifugal type, Goulds Model 3196 LTC, 2X3-13, 60-HP, 3,550 rpm. The casing and impeller are stainless steel. c. Normal Operating Conditions Rated for 150 gpm at 415 feet of differential head. 7. Mechanical Seal Purge Water Pumps 72-887 and 72-888 a. Purpose To supply high pressure water to the reactor agitator seals and the reactor cleaning nozzle flush. b. Description Centrifugal type, Goulds 3196 MT, 1X2-10, 30-HP, 3,500 rpm. The casing and the impeller are stainless steel. 000097042 dth Operating Manual D-700 PVC Reactors Page 107 IV. EQUIPMENT INDEX (CONTINUED) E. Pumps (Continued) c. Normal Operating Conditions Rated for 40 gpm at 415 feet of differential head. 8. Water Recirculation Pumps 72-889 and 72-890 a. Purpose To circulate water in the recovery knockout drums. b. Description Centrifugal type, Goulds Model 3196 MT, 2X3-10, 7 1/2 HP, 1,750 rpm. The casing is stainless steel and the impeller is cast iron. c. Normal Operating Conditions Rated for 200 gpm at 68 feet differential head. 9. Seal Water Pumps 72-891 and 72-892 a. Purpose To circulate the seal water used by the recovery vacuum pumps and compressors. b. Description Centrifugal type, Goulds Model 3196 MT, 2X3-10, 10-HP, 1,750 rpm. The casing is stainless steel and the impeller is cast iron. c. Normal Operating Conditions Rated for 160 gpm at 94 feet of differential head. DTH 000097043 Operating Manual D-700 PVC Reactors Page 108 IV. EQUIPMENT INDEX (CONTINUED) E. Pumps (Continued) 10. Recovered VCM Transfer Pumps 72-893 and 72-894 a. Purpose To transfer recovered VCM from the recovered VCM collect tank to a recovered VCM storage tank. b. Description Centrifugal type, Goulds Model 3196 MT, 1X2-10, 3-HP, 1,750 rpm. The casing is stainless steel and the impeller is cast iron. c. Normal Operating Conditions Rated for 50 gpm at 75 feet of differential head. 11. Hydroquinone Injection Pump 72-895 a. Purpose To supply hydroquinone solution for injection into recovery system seal water during reactor recovery. b. Description Reciprocating type, Milton-Roy Model DB-1-30R, 1/4 HP, 1,750 rpm, carbon steel construction. c. Normal Operating Conditions 0.081 gph at approximately 282 feet of differential head. 12. Slurry Transfer Pumps 72-896 and 72-897 a. Purpose To transfer slurry from the reactor to the slurry blend tanks. r DTH 000097044 /'"'s Operating Manual D-700 PVC Reactors Page 109 IV. EQUIPMENT INDEX (CONTINUED) E. Pumps (Continued) b. Description Centrifugal type, Goulds Model 3196 MT, 4X6-13, 40-HP, 1,770 rpm. The casing and impeller are stainless steel. c. Normal Operating Conditions Rated for 600 gpm at 126 feet of differential head. 13. Cleaning Solution Pumps 72-898 and 72-899 a. Purpose To supply chem wash solution to the reactors during chem wash. b. Description Centrifugal type, Durco Model Mark II, Group II, 4X3-10/80, 75-HP, 3,550 rpm, stainless steel casing and impeller. c. Normal Operating Conditions Rated for 500 gpm at 165 feet of differential head. 14. Blowdown Tank Pump 72-900 a. Purpose To pump water which has been stripped of VCM from the blowdown tank to the sewer. b. Description Centrifugal type, Durco Model Mark II, Group II, 4X3-10/84, 7 1/2 HP, 1,750 rpm. The casing is stainless steel and the impeller is cast iron. c. Normal Operating Conditions DTH 000097045 Rated for 200 gpm at 63 feet of differential head. Operating Manual D-700 PVC Reactors Page 110 IV. EQUIPMENT INDEX (CONTINUED) F. Compressors and Fans 1. Recovery Vacuum Pumps 72-901 and 72-902 a. Purpose To recover unreacted VCM from the polymerization reactors. b. Description Bingham Model 4G-M, 75-HP, 1,200 rpm. Constant volume liquid ring with a water seal. The liquid ring is driven by a multivaned impeller in a circular pumpcase. Construc tion is cast iron casing and ductile iron impeller. c. Normal Operating Conditions 24 inches Hg vacuum to 7 psig inlet, 0-10 psig dishcarge, and 100-150F. 2. Recovery Compressors 72-903, 72-904, and 72-905 a. Purpose To recover unreacted VCM from the polymerization reactors. b. Description Nash Model 1256, 150-HP, constant volume liquid ring with water seal. The liquid ring is driven by a multivaned impeller in a circular pumpcase. Construction is cast iron casing and stainless steel impeller. c. Normal Operating Conditions 0-35 psig inlet, 40-80 psig outlet, and 100-150F. DTH 000097046 Operating Manual D-700 PVC Reactors Page 111 IV. EQUIPMENT INDEX (CONTINUED) P. Compressors and Fans (Continued) 3. Slurry Strainer Exhauster 49-368 a. Purpose To keep personnel exposure to VCM vapors to a minimum. b. Description Centrifugal fan, Buffalo Forge Model 365 DL, 3-HP, 1,800 rpm, stainless steel construction. c. Normal Operating Conditions Near atmospheric pressure and 150-200F. G. Agitators 1. Reactor Agitators 51-101, 51-102, 51-103, and 51-104 a. Purpose To keep the colloid, VCM, and water in the reactor well mixed. b. Description Bottom entering, single speed, four blades at 45 angle, 200-HP, 125 rpm, stainless steel construction. c. Normal Operating Conditions 15,000 gallons of liquid or slurry in vertical vessel, 22-foot straight wall by 12-foot diameter, at about 120F and 130 psig. DTH 000097047 Operating Manual D-700 PVC Reactors Page 112 IV. EQUIPMENT INDEX (CONTINUED) G. Agitators (Continued) 2. Colloid Makeup Tank Agitator 51-105 a. Purpose To provide agitation needed to dissolve F-50 methocel in water. b. Description Top entering, single speed, "Lightnin" Model 73-Q-5, 5-HP, 1,750 rpm. Wetted parts are stainless steel. c. Normal Operating Conditions 3,000 gallons of colloid solution; tank is vertical; sevenfoot diameter by 11'6" tall; temperature ranges from 70-250F and atmospheric pressure. 3. Hydroquinone Storage Tank Agitator 51-106 a. Purpose To provide agitation needed to dissolve hydroquinone powder in water. b. Description Top entering, single speed, "Lightnin" Model N33-33, 1/3-HP, 1,750 rpm. c. Normal Operating Conditions Approximately fifty gallons hydroquinone solution in vertical tank 2'6" high by two-foot diameter, 1 psig, and 70"F. DTH 000097048 o Operating Manual D-700 PVC Reactors Page 113 IV. EQUIPMENT INDEX (CONTINUED) H. Package Units 1. Seal Oil Pressure Units 95-299 and 95-300 a. Purpose To supply seal oil to the reactor agitator seals at the required temperature and pressure. b. Description Dura circulator Model SWAR-40-25. c. Normal Operating Conditions 245-250 psig, 100-150F. The seal oil is Di(2-Ethylhexy) phthalate (DOP) which has a viscosity of 35 cp. DTH 000097049 DTH 000097050 Operating Manual D-700 PVC Reactors Page 114 V. INSTRUMENT INDEX A. Plow Controllers Item No. Service Type Set Point FIRC-710 FIRC-711 FIRC-712 FIRC-713 Reactor Cooling Water Flow Controllers Meter run with orifice plate, board-mounted indicators and recorders. Cascade control; the temperature controller of each reactor sets the set point. NOTE: FIRC-710 controls FIRC-711 controls FIRC-712 controls FIRC-713 controls thecooling water to reactor 45-741. thecooling water to reactor 45-742. thecooling water to reactor 45-443. thecooling water to reactor 45-744. FIC-738 Recovery Vacuum Pump Brooks Model 3611 50 gpm FIC-739 and Compressor Seal Rotameter with trans FIC-740 Water Flow Control mitter and a local lers Foxboro flow con troller rN NOTE: FIC-738 controls the seal water to vacuum pump 72-901 and compressor 72-903. FIC-739 controls the seal water to vacuum pump 72-902 and compressor 72-904. FIC-740 controls the seal water to compressor 72-905. FCi-749 FCi-750 FCi-751 FCi-752 Reactor Agitator Mechanical Seal Oil Supply Flow Regulators Kates Model MFA1-1 Flow Regulator 1.0 gpm NOTE: FCi-749 controls the seal oil flow to reactor 45-741 double mechanical seal. FCi-750 controls the seal oil flow to reactor 45-742 double mechanical seal. FCi-751 controls the seal oil flow to reactor 45-743 double mechanical seal. FCi-752 controls the seal oil flow to reactor 45-744 double mechanical seal. 000097051 DIB Operating Manual D-700 PVC Reactors Page 115 V. INSTRUMENT INDEX (CONTINUED) B. Flow Totalizers Item No. Service Type Set Point FQIC-701A VCM Charge Totalizers FQIC-701B Foxboro Turbine Meter, Board-Mounted Read out Determined by specific batch recipe. FQIC-702 Recovered VCM Charge Totalizer Fischer/Porter Vortex Determined by Shedding Meter, Board specific batch Mounted Readout recipe. FQIC-703 Initiator Injection Pot Service Water Flow Totalizer Foxboro Turbine Meter, Board-Mounted Read out Determined by specific batch recipe. FQIC-704 Hot Water Charge Totalizer Foxboro Turbine Meter, Determined by Board-Mounted Read specific batch out recipe. FQIC-705 Colloid Charge Totalizer Brooks Oval Meter, Board-Mounted Read out Determined by specific batch recipe. FQIC-706 Colloid Makeup Water Flow Totalizer Brooks Oval Meter, Local Colloid Board Readout Hot Water, 538 Gallons Cold Water, 2,623 Gallons FQI-708 Reactor Steam Strip ping Flow Total izer Orifice Plate with D/P None; totalizes Cell, Board-Mounted only. Readout FQI-757 Hot Water Charge Totalizer Orifice Plate with D/P None; totalizes Cell, Board-Mounted only. Readout FQI-811 Steam to Reactor Module Flow Totalizer Orifice Plate with D/P None; totalizes Cell, Board-Mounted only. Readout DTH 000097052 Operating Manual D-700 PVC Reactors Page 116 V. INSTRUMENT INDEX (CONTINUED) C. Level Controllers Item No, LC-720 LC-722 Service Seal Water Separator Level Controllers TyPe Displacer, Fisher Model 2500T Set Point 16 Inches from Bottom of Dis placer Float NOTE: LC-720 controls the water level in seal water separator 45-762. LC-722 controls the water level in seal water separator 45-763. LIC-725 Slurry Dump Tank 45-766 Level Controller Displacer, Fisher Model 2500T To be determined in field. D. Pressure Controllers Item No. Service Type Set Point PCi-704 Recovered VCM Storage Tanks 89-520 and 45317 Inert Vent Back pressure Regulator Self-Contained Pressure Regulator 60 psig PCi-706 Steam Stripping Header Steam Supply Backpressure Regu lator Self-Contained Pressure Regulator 100 psig PIC-725 Recovery Knockout Drum 45-760 Inlet Pressure Controller Diaphragm with Foxboro Controller 35 psig PIC-726 VCM Bleed Stream to Recovery System Pressure Controller Vacuum D/P Transmit ter with a Local Foxboro Controller 3" Hg Vacuum PCi-729 Hydroquinone Storage Self-Contained Pres Tank 45-765 Nitrogen sure Regulator Pressure Regulator 1 psig PCi-731 Mechanical Seal Purge Water Surge Drum 45-759 Nitrogen Supply Pressure Regulator Self-Contained Pressure Regulator 180 psig DTH 000097053 Operating Manual r D-700 PVC Reactors Page 117 V. INSTRUMENT INDEX (CONTINUED) D. Pressure Controllers (Continued) Item No. Service Type PCi-739 Seal Oil Pressure Unit Self-Contained Pres95-299 Nitrogen Supply sure Regulator Pressure Regulator Set Point 200 psig PCi-741 Seal Oil Pressure Unit Self-Contained Pres95-300 Nitrogen Supply sure Regulator Pressure Regulator 200 psig PCi-743 PCi-744 PCi-745 PCi-746 PCi-747 PCi-752 Breathing Air Station Supply Pressure Regulator Self-Contained Pressure Regulator 20 psig NOTE: PCi-743 regulates breathing air to the reactor area, ground level, PCi-744 regulates breathing air to the reactor area, second level, PCi-745 regulates breathing air to the recovery building, first floor. PCi-746 regulates breathing air to the recovery building, second floor. PCi-747 regulates breathing air to the charge area. PCi-752 regulates breathing air to the reactor area, third level. PCi-754 PCi-755 PCi-756 PCi-757 NO Short Stop Supply Pressure Regulator Self-Contained Pressure Regulator 200 psig NOTE: PCi-754 regulates NO supply pressure to reactor 45-741. PCi-755 regulates NO supply pressure to reactor 45-742. PCi-756 regulates NO supply pressure to reactor 45-743. PCi-757 regulates NO supply pressure to reactor 45-744. PIC-759 Blowdown Tank 45-319 Pressure Controller Vacuum D/P Transmitter To be Determined with Local Foxboro in Field Controller DTH 000097054 o Operating Manual D-700 PVC Reactors Page 118 V. INSTRUMENT INDEX (CONTINUED) E. Temperature Controllers Item No. Service TIC-701 Hot Water Tank 45-748 Temperature Control ler lZE Resistance Bulb with Board-Mounted Foxboro Controller Set Point 140F TIC-702 Hot Water Preheater 55-332 Discharge Temperature Con troller Filled System with Local Foxboro Con troller 145F TRC-703 Charge Water Temper ature Controller Resistance Bulb with Board-Mounted Fox boro Controller Determined by Specific Batch Recipe TIRC-706 TIRC-707 TIRC-708 TIRC-709 Reactor Polymerization Temperature Controllers Resistance Bulb with Foxboro Controller Determined by Specific Batch Recipe NOTE: TIRC-706 controls reactor 45-741 polymerization temperature. TIRC-707 controls reactor 45-742 polymerization temperature. TIRC-708 controls reactor 45-743 polymerization temperature. TIRC-709 controls reactor 45-744 polymerization temperature. TIRC-710 TIRC-711 TIRC-712 TIRC-713 Reactor Steam Stripping Temperature Controller Resistance Bulb with Board-Mounted Foxboro Controller 225F NOTE: TIRC-710 controls reactor 45-741 steam stripping temperature. TIRC-711 controls reactor 45-742 steam stripping temperature, TIRC-712 controls reactor 45-743 steam stripping temperature, TIRC-713 controls reactor 45-744 steam stripping temperature. TIC-716 TIC-717 Seal Water Temperature Controller Filled System with Local Foxboro Controller To be Determined in Field NOTE: TIC-716 controls seal water cooler 55-335 outlet temperature. TIC-717 controls seal water cooler 55-336 outlet temperature. DTH 000097055 Operating Manual D-700 PVC Reactors Page 119 V. INSTRUMENT INDEX (CONTINUED) E. Temperature Controllers (Continued) Item No. Service Type TIC-718 Cleaning Solution Heater Filled System with 55-339 Outlet Temper- Local Foxboro ature Controller Controller TIC-730 Blowdown Tank 45-319 Temperature Controller Filled System with Local Foxboro Controller Set Point L90F L75F DTH 000097056 r' Switchi < i 000097057 dth Operating Manual D-700 PVC Reactors Page 120 VI. ALARMS AND SAFETY EQUIPMENT A. Continuous Flow Fresh Air System In order to provide personnel protection, a continuous flow fresh air system has been installed. This system consists of personnel fresh air masks and a constant flow breathing air supply. The supply lines are piped to all affected areas of the plant. The individual hookup stations consist of quick connect/disconnecttype fittings. The individual lines to the designated areas are designed to allow a minimum flow of 6 SCFM to each mask at approximately 10-IS psig. An air pressure regulator, shutoff valve, and an air filter are provided at the piping header to each individual area. The air supply system utilizes two Nash compressors supplying 100 SCFM each at a maximum pressure of 80 psig. Each compressor will supply about fifteen masks with air at one time. Th ' com pressors normally are both in operation at the same time, except in cases of mechanical failure. The system is equipped with both visable and audible low pressure alarms which are activated at 50 psig. The revolving Ic.icon light is mounted on a pole to give wider visibility, and the lion is mounted at the compressor. An on-off switch is provided o' each compressor. DTH 000097058 Operating Manual D-700 PVC Reactors Page 121 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) A. Continuous Flow Fresh Air System (Continued) The following job operations will REQUIRE the wearing of a continuous flow fresh air mask supplied through the fresh air lines or a Scott Air Pak: 1. Venting or changing filters in any VCM vessel. NOTE: No vessel or line should be vented unless there is no alternative, such as using pipe or hose to i ransfer VCM into the recovery system or blowdown tank. 2. Entering any vessel that normally contains VCM, such as reactors, blowdown tanks, knockout drums, receivers, etc (except for scaf folding construction). 3. Opening large reactor manhead (wear mask until the manway is partially open and the evacuation jet is moving air through the manway). 4. Opening any line that may possibly contain VCM vapors. 5. At ANY location where the VCM concentration is above the current allowable limit. Anytime VCM is detected by sight or smell, the concentration is well above the limits and precaution is manda tory . DTH 000097059 Operating Manual D-700 PVC Reactors Page 122 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches 1. Amperage Alarms Item No. Service Typ.e AAHL-701 AAHL-702 AAHL-703 AAHL-704 Low or High Amperage to the Reactor Agitator Motor Board-Mounted Alarm Set Point To be determined in tl field. NOTE: AAHL-701 indicates abnormal amperage to reactor 45-741 agitator motor. AAHL-702 indicates abnormal amperage to reactor 45-742 agitator motor. AAHL-703 indicates abnormal amperage to reactor 45-743 agitator motor. AAHL-704 indicates abnormal maperage to reactor 45-744 agitator motor. 2. Flow Alarms and Switches Item No. Service Sot Point FSL-701A Low VCM Flow during and B Charge Switch that Activates Alarm (FAL-701) on Board 400 gpm FAL-701 Low VCM Flow during Charge Board-Mounted Alarm 400 gpm FAL-714 FAL-715 FAL-716 FAL-717 Low Seal Water Flow to the Reactor Agitators Board-Mounted Alarm 2 gpm NOTE: FAL-714 indicates low flow to reactor 45-741 FAL-715 indicates low flow to reactor 45-742 FAL-716 indicates low flow to reactor 45-743 FAL-717 indicates low flow to reactor 45-744 DTH 000097060 Operating Manual D-700 PVC Reactors Page 123 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 3. Level Alarms and Switches Item No. Service Type Set Point LAH-701 High VCM Level in Fresh VCM Storage Tank 45-745 Board-Mounted Alarm '252 Inches above Bottom Tangent LSH-701A High VCM Level in Fresh VCM Storage Tank 45-745 Switch Activates LAH-701 252 Inches above Bottom Tangent LSH-701B High VCM Level in Fresh VCM Storage Tank 45-745 Switch that Serves as Charge Permis sive 252 Inches above Bottom Tangent LSH-701C Level Control of Fresh VCM Receiver 45-745 Switch which Stops 225 Inches Above VCM Transfer Discharge Nozzle LSL-701D Level Control of Fresh VCM Receiver 45-745 Switch which Starts Transfer 219 Inches Above Discharge Nozzle LAH-710 High Level in Col loid Makeup Tank 45-751 Alarm on Colloid Local Board 8 Inches from Top of Tank LSH-711B High Water Level in Hot Water Tank 45-748 Switch that Serves as Charge Permis sive 129 Inches above Discharge Nozzle LSH-711C Hot Water Tank 45-758 Level Control Switch which Stops Water Transfer on High Level 360 Inches above Bottom Tangent LSL-711D Hot Water Tank 45-748 Level Control Switch which Starts Water Transfer 350 Inches above Discharge Nozzle LAH-713 High Level in Col loid Storage Tank 45-752 Board-Mounted Alarm 6 Inches from Top of Tank DTH 000097061 Operating Manual D-700 PVC Reactors Page 124 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 3. Level Alarms and Switches (Continued) Item No. Service LAH-714 High Level in Col loid Charge Tank 45-753 Ty.Pe Board-Mounted Alarm Set Point 8 Inches from Top of Tank LSL-715 Low Level in Col loid Charge Tank 45-753 Switch Serves as Charge Permis sive 24 Inches above Bottom Tangent LSH-716 Level Control of Recovery Knockout Drum 45-760 Switch Opens Valve to Blowdown Tank on High Level 28 Inches above Bottom Tangent LSL-717 Level Control of Recovery Knockout Drum 45-760 Switch Closes Valve to Blow down Tank on Low Level 18 Inches above Bottom Tangent LSH-718 Level Control of Recovery Knockout Drum 45-761 Switch Opens Valve to Blowdown Tank on High Level 28 Inches above Bottom Tangent LSH-719 Level Control of Recovery Knockout Drum 45-761 Switch Closes Valve to Blow down Tank on Low Level 18 Inches Above Bottom Tangent LAH-720 High Level in Seal Water Separator 45-762 Local Alarm 44 Inches above Bottom Tangent LAL-720 Low Level in Seal Water Separator 45-762 Local Alarm 16 Inches above Bottom Tangent LAH-722 High Level in Seal Water Separator 45-763 Local Alarm 44 Inches above Bottom Tangent LAL-722 Low Level in Seal Water Separator 45-763 Local Alarm 16 Inches above Bottom Tangent DTH 000097062 Operating Manual D-700 PVC Reactors Page 125 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 3. Level Alarms and Switches (Continued) Item No. Service LAH-725 High Level in Slurry Dump Tank 45-766 IXPe Board-Mounted Alarm Set Point 6 Inches from Top of Tank LAH-727 High Level in Cleaning Solu tion Tank 45-767 Board-Mounted Alarm 6 Inches from Top of Tank LAL-729 Low Level in Cleaning Solu tion Tank 45-767 Board-Mounted Alarm 6 Inches from Bot tom of Tank LSL-730 Low Level in Seal Oil Reservoir 95-299 Switch Activates LAL-730, Starts Spare Seal Oil Unit 95-300, and Turns Off 95-299 To be Defined by Vendor LAL-730 Low Level in Seal Oil Reservoir 95-299 Board-Mounted Alarm To be Defined by LSL-731 LAL-731 LAL-733 Low Level in Seal Oil Reservoir 95-300 Low Level in Seal Oil Reservoir 95-300 Low Level in Hydroquinone Storage Tank 45-765 Switch Activates LAL-731, Starts Spare Seal Oil Unit 95-299, and Turns Off 95-300 Board-Mounted Alarm Board-Mounted Alarm To be Defined by Vendor To be Defined by Vendor 6 Inches above Bottom Tangent LAH-734 High Level in Cleaning Solution Tank 45-767 Switch Shuts Down 6 Inches from Cleaning Solution Top of Tank Pumps 72-898 and 72-899 and Caustic Transfer Pumps DTH 000097063 LAL-739 Low Level in Col loid Makeup Tank 45-751 Board-Moun ted Alarm One Inch above Bottom Tangent Operating Manual D-700 PVC Reactors Page 126 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 3. Level Alarms and Switches (Continued) Item No. Service LAH-740 High Level in Blow down Tank 45-319 Type Board-Mounted Alarm Set Point 22 Inches from Top of Tank LSL-741 Low Level in Blow down Tank 45-319 Switch will Shut Off Blowdown Tank Pump 72-900 and Close Valves CV-880 and CV-891 12 Inches from Bottom of Tank 4. Pressure Alarms and Switches Item No. Service Type Set Point PSH-703 High Pressure in Initiator Injec tion Pot 45-750 Switch turns on high pressure light on the board and is a precharge condition. 180 psig PSL-707 Low Pressure in Steam Stripping Header Switch closes control valve that supplies steam to the reactor during steam strip ping. 100 psig PSL-712 PSL-713 PSL-714 PSL-715 Low Pressure in Reactor during Recovery Switch prevents opening of reactor dump valve unless pres sure during recovery has been at least as low as set point. 8 psig NOTE: PSL-712 senses pressure in reactor 45-741. PSL-713 senses pressure in reactor 45-742. PSL-714 senses pressure in reactor 45-743. PSL-715 senses pressure in reactor 45-744. DTH 000097064 Operating Manual D-700 PVC Reactors Page 127 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 4. Pressure Alarms and Switches (Continued) Item No . Service Set Point PSL-716 PSL-717 PSL-718 PSL-719 Low Pressure in Reactors during Evacuation Switch keeps charge from starting by preventing main reactor charge valve from open ing unless pres sure is at least as low as set point. 25" Hg Vacuum NOTE: PSL-716 senses pressure in reactor 45-741. PSL-717 senses pressure in reactor 45-742. PSL-718 senses pressure in reactor 45-743. PSL-719 senses pressure in reactor 45-744. PAH-720 PAH-721 PAH-722 PAH-723 High Pressure in Reactors Board-Mounted Alarm 160 psig NOTE: PAH-720 indicates high pressure in reactor 45-741. PAH-721 indicates high pressure in reactor 45-742. PAH-722 indicates high pressure in reactor 45-743. PAH-723 indicates high pressure in reactor 45-744. PSL-727 Low Recovery Com pressor Suction Pressure Switch will start recovery vacuum pumps 72-901 and 72-902 and activate proper valv ing sequence during recovery. 7 psig PDS-728 High Differential Pressure Between Recovery Vacuum Pump Suction and Recovery Compres sor Discharge Switch shuts off recovery compres sors 72-903, 72-904, and 72-905 and vacuum pumps 72-901 and 72-902. 80 psig PSL-732 Low Pressure on High Pressure Service Water System Switch prevents auto matic charge sequence from beginning and activates PAL-732. 150 psig 000097065 DTH Operating Manual D-700 PVC Reactors Page 128 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 4. Pressure Alarms and Switches (Continued) Item No. Service IXEg PAL-732 Low Pressure on High Pressure Service Water System Board-Mounted Alarm PSL-737 Low Pressure on Mechanical Seal Purge Water System (MSPW) Switch activates PAL-737 and turns on spare (MSPW) pump 72-887 or 72-888. PAL-737 Low Pressure on Mechanical Seal Purge Water System Board-Mounted Alarm PSL-738 Low Pressure from Seal Oil Unit 95-299 Switch activates spare seal oil unit 95-300, turns off 95-299, acti vates the necessary valves, and acti vates PAL-738. PAL-738 Low Pressure from Seal Oil Unit 95-299 Board-Mounted Alarm PSL-740 Low Pressure from Seal Oil Unit 95-300 Switch activates spare seal oil unit 95-299, turns off 95-300, activates the necessary valves, and acti vates PAL-740. PAL-740 Low Pressure from Seal Oil Unit 95-300 Board-Mounted Alarm PAH-750 High Pressure on Initiator Injec tion Pot 45-750 Board-Mounted Alarm Set Point 150 psig 180 psig 180 psig 205 psig 205 psig 205 psig 205 psig 225 psig DTH 000097066 Operating Manual D-700 PVC Reactors Page 129 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) B. Alarms and Switches (Continued) 4. Pressure Alarms and Switches (Continued) Item No. Service lap.? PAH-751 High Seal Oil System Board-Mounted Alarm Pressure Set Point 255 psig PAL-753 Low Pressure on NO Short Stop Bottles Board-Mounted Alarm 350 psig PSL-758 Low Pressure on High Pressure Service Water System (HPSW) Switch turns on spare HPSW pump 72-885 or 72-886. 180 psig PAH-760 High Pressure in Blowdown Tank 45-319 Board-Mounted Alarm 10 psig PSL-762 Low Steam Pressure to Blowdown Tank 45-319 Switch closes TCV-730 and PCV-759 and re sets on rising steam pressure of 50 psig. 40 psig PAL-763 Low Instrument Air Pressure Board-Mounted Alarm 85 psig TAH-706 TAH-707 TAH-708 TAH-709 High Temperature in the Reactors Board-Mounted Alarm 160F NOTE: TAH-706 indicates high temperature in reactor 45-741. TAH-707 indicates high temperature in reactor 45-742. TAH-708 indicates high temperature in reactor 45-743. TAH-709 indicates high temperature in reactor 45-744. TAH-715 High Discharge Temperature on the Recovery Compressors Board-Mounted Alarm 150F TAH-719 High Seal Oil Temperature Board-Mounted Alarm 125F TAH-720 High Temperature in Initiator Injec tion Pot 45-750 Board-Mounted Alarm 75F DTH 000097067 Operating Manual D-700 PVC Reactors Page 130 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) C. Firewater System The firewater system consists of a deluge system, combustible hydrocarbon analyzer, and fire monitors with hose connections. 1. Fire Monitors The fire monitors are normally supplied from the city water system. A tie-in with the firewater system allows the fire monitors to operate off either water system. There are six fire monitors located around the perimeter of the recovery building and reactor area. 2. Hydrocarbon Analyzer A continuous combustible hydrocarbon analyzer is used to detect major VCM leaks. When the VCM level at any sample point reaches the set point, the deluge system is activated automatically. 3. Deluge System The deluge system is normally supplied from the firewater system. It can be operated on process water. The deluge system is a sprinkler system which will cover the reactors, dump system, fresh and recovered VCM storage tanks, and both floors of the recovery building with a water spray. The deluge system is designed to lower VCM concentrations in the reactor and recovery building area in the event of a VCM leak and as a sprinkler system to help put out fires. The deluge system can be acti vated manually, by the combustible hydrocarbon analyzer, or by thermal sensors. DTH 000097068 Operating Manual D-700 PVC Reactors Page 131 VI. ALARMS AND SAFETY EQUIPMENT (CONTINUED) C. Firewater System (Continued) 3. Deluge System (Continued) The revised firewater system contains three new post indicator valves (PIV) and one PIV was relocated. These are valves which have indicators on them to show whether the valve is open or closed. These valves are used to direct water to either the D-700 reactor area or the V-ll area. The valves are located at: 1. The southwest corner of the new cooling water tower. 2. East wall of the V-ll building. 3. Two are located at the northwest corner of the intersec tion of the entrance road and second street. D. Fixed Point VCM Monitor A fixed point VCM monitor is used to detect VCM and record the VCM concentration at various locations in the reactor and recovery building. V II. Equipment Opening Procedure! DTH 000097070 Operating Manual D-700 PVC Reactors Page 132 VII. EQUIPMENT ENTRY PROCEDURE EPA standards for VCM emissions and OSHA regulations on personnel exposure to VCM require that certain operating procedures be followed when there is the possibility of VCM emission to the atmosphere or personnel exposure to VCM. For this reason and to ensure safe working conditions at all times, the "Engineering and Work Practice Control Program for the Reduction of Employee Exposure to Vinyl Chloride" manual should be consulted whenever equipment in the reactor area is opened for any reason. This manual contains a list of detailed procedures as well as safety precautions for equipment opening. DTH 000097071 DTH 000097072 Reactors 45-741 45-742 45-743 45-744 Heat Exchangers 55-328 55-329 55-330 55-331 55-332 55-333 55-334 55-335 55-336 55-337 55-338 55-339 Eductors and Ejectors EE-701 EE-702 EE-703 EE-7 04 EE-705 Tanks and Vessels 45-301 45-317 89-520 45-319 45-745 45-748 45-750 45-751 45-752 45-753 45-754 45-755 45-756 45-757 45-758 APPENDIX A EQUIPMENT LIST Service Polymerization Reactor Polymerization Reactor Polymerization Reactor Polymerization Reactor Reactor 45-741 Condenser Reactor 45-742 Condenser Reactor 45-743 Condenser Reactor 45-744 Condenser Hot Water Preheater Hot Water Tank Heater Water Recirculation Cooler West Seal Water Cooler East Seal Water Cooler West Recovered VCM Condenser East Recovered VCM Condenser Cleaning Solution Heater Reactor 45-741 Jacket Eductor Reactor 45-742 Jacket Eductor Reactor 45-743 Jacket Eductor Reactor 45-744 Jacket Eductor Reactor Evacuation Ejector Instrument Air Capacity Tank East Recovered VCM Storage Tank West Recovered VCM Storage Tank Blowdown Tank Fresh VCM Storage Tank Hot Water Tank Initiator Injection Pot Colloid Makeup Tank Colloid Storage Tank Colloid Charge Tank Seal Oil Storage Drum AMS Short Stop Charge Pot for Reactor 45-741 AMS Short Stop Charge Pot for Reactor 45-742 AMS Short Stop Charge Pot for Reactor 45-743 AMS Short Stop Charge Pot for Reactor 45-744 DTH 000097073 Tanks and Vessels (Continued) 45-759 45-760 45-761 45-762 45-763 45-764 45-765 45-766 45-767 45-768 45-770 Filters 64-716 64-718 64-719 64-720 64-721 64-722 64-723 64-724 64-725 64-726 64-727 64-728 64-731 64-732 64-733 64-734 64-735 64-736 64-737 64-738 64-739 64-740 64-741 64-742 APPENDIX A EQUIPMENT LIST - CONTINUED Service Mechanical Seal Purge Water Surge Drum South Recovery Knockout Drum North Recovery Knockout Drum South Seal Water Separator North Seal Water Separator Recovered VCM Collect Tank Hydroquinone Storage Tank Slurry Dump Tank Cleaning Solution Tank Reactor Evacuation Ejector Cyclone Separator Reactor Sampling Bomb Process Water Charge Filter North VCM Charge Filter Recovered VCM Filter Process Water Filter Colloid Makeup Water Filter North Colloid Transfer Filter South Colloid Transfer Filter Service Water Filter Seal Oil Supply Filter for Seal Oil Pressure Unit 95-299 Seal Oil Supply Filter for Seal Oil Pressure Unit 95-300 Seal Oil Return Filter for Seal Oil Pressure Unit 95-299 Seal Oil Return Filter for Seal Oil Pressure Unit 95-300 South Seal Water Filter North Seal Water Filter Slurry Strainer Cleaning Solution Strainer Breathing Air Filter (Reactors, First Level) Breathing Air Filter (Reactors, Second Level) Breathing Air Filter (Recovery Building First Floor) Breathing Air Filter (Recovery Building, Second Floor) Breathing Air Filter (Charge Area) Breathing Air Filter (Reactors, Third Level) Blowdown Tank Drain Strainer South VCM Charge Filter DTH 000097074 r' APPENDIX A EQUIPMENT LIST - CONTINUED Pumps Motor 72-875 72-876 72-877 72-878 72-879 72-880 72-881 72-882 72-883 72-884 72-885 72-886 72-887 72-888 72-889 72-890 72-891 72-892 72-893 72-884 72-895 72-896 72-897 72-898 72-899 72-900 70-875 70-876 70-877 70-878 70-879 70-880 70-881 70-882 70-883 70-884 70-885 70-886 70-887 70-888 70-889 70-890 70-891 70-892 70-893 70-894 70-895 70-896 70-897 70-898 70-899 70-900 Compressors and Fans Motor 72-901 72-902 72-903 72-904 72-905 49-368 70-901 70-902 70-903 70-904 70-905 70-864 Agitators Motor 51-101 51-102 51-103 51-104 51-105 51-106 70-814 70-815 70-816 70-817 70-818 70-819 Service VCM Charge Pump VCM Charge Pump Recovered VCM Charge Pump Recovered VCM Charge Pump Hot Water Charge Pump Hot Water Charge Pump Colloid Batch Transfer Pump Colloid Circulation Pump Colloid Charge Pump Colloid Charge Pump High Pressure Service Water Pump High Pressure Service Water Pump Mechanical Seal Purge Water Pump Mechanical Seal Purge Water Pump Water Recirculation Pump Water Recirculation Pump Seal Water Pump Seal Water Pump Recovered VCM Transfer Pump Recovered VCM Transfer Pump Hydroquinone Injection Pump Slurry Transfer Pump Slurry Transfer Pump Cleaning Solution Pump Cleaning Solution Pump Blowdown Tank Pump Recovery Vacuum Pump Recovery Vacuum Pump Recovery Compressor Recovery Compressor Recovery Compressor Slurry Strainer Exhauster Reactor 45-741 Agitator Reactor 45-742 Agitator Reactor 45-743 Agitator Reactor 45-744 Agitator Colloid Makeup Tank Agitator Hydroquinone Storage Tank Agitato DTH 000097075 Package Units 95-299 95-300 PA-703 PA-704 PA-705 PA-706 PA-707 PA-708 PA-709 PA-710 PA-711 PA-712 PA-713 PA-714 PA-715 PA-716 PA-717 APPENDIX A EQUIPMENT LIST - CONTINUED Service Seal Oil Pressure Unit Seal Oil Pressure Unit Deluge System Deluge System Combustible Hydrocarbon Analyzer Fire Monitor Fire Monitor Fire Monitor Fire Monitor Fire Monitor Fire Monitor Deleted Fixed Point VCM Monitor Emergency NO Short Stop Bottles Emergency NO Short Stop Bottles Emergency NO Short Stop Bottles Emergency NO Short Stop Bottles Programmable Logic Controller DTH 000097076 APPENDIX B INSTRUMENT LIST Item No. Service Amperage Instruments Al-701 AAHL-701 AI-702 AAHL-702 AI-703 AAHL-703 Al-704 AAHL-704 AI-705 Al-706 AI-707 Al-708 Al-709 Reactor Agitator 51-101 Motor Amperage Indicator Reactor Agitator 51-101 Motor High or Low Amperage Alarm Reactor Agitator 51-102 Motor Amperage Indicator Reactor Agitator 51-102 Motor High or Low Amperage Alarm Reactor Agitator 51-103 Motor Amperage Indicator Reactor Agitator 51-103 Motor High or Low Amperage Alarm Reactor Agitator 51-104 Motor Amperage Indicator Reactor Agitator 51-104 Motor High or Low Amperage Alarm Recovery Vacuum Punqp 72-901 Motor Amperage Recovery Vacuum Pump 72-902 Motor Amperage Recovery Compressor 72-903 Motor Amperage Recovery Compressor 72-904 Motor Amperage Recovery Compressor 72-905 Motor Amperage Control Valves CV-701 CV-702 CV-703 CV-704 CV-705 CV-706 CV-707 CV-708 CV-709 CV-710 CV-711 CV-712 CV-713 CV-714 CV-715 CV-716 CV-717 CV-718 CV-719 CV-720 CV-721 CV-722 CV-723 CV-724 CV-725 CV-726 CV-727 CV-728 Fresh VCM Storage Tank 45-745 Outlet Valve Deleted Recovered VCM Valve to VCM Charge Pumps 72-875 and 72-876 VCM Charge Pump 72-875 Discharge Valve VCM Charge Pump 72-876 Discharge Valve Hot Water Tank 45-748 Outlet Valve Colloid Charge Pump 72-885 Discharge Valve Deleted Hot Water Valve to Colloid Makeup Tank 45-751 Reactor 45-741 Main Charge Valve Reactor 45-741 Colloid Charge Valve Reactor 45-741 Steam Stripping Valve Reactor Condenser 55-328 Cleaning and Rinse Valve Reactor 45-741 Vent Valve Reactor 45-741 Inert Vent Valve Reactor 45-741 Recovery and Evacuation Valve Reactor 45-741 Cleaning and Rinse Valve Deleted Deleted Reactor 45-742 Main Charge Valve Reactor 45-742 Colloid Charge Valve Reactor 45-742 Steam Stripping Valve Reactor Condenser 55-329 Cleaning and Rinse Valve Reactor 45-742 Vent Valve Reactor 45-742 Inert Vent Valve Reactor 45-742 Recovery and Evacuation Valve Reactor 45-742 Cleaning and Rinse Valve Deleted DTH 000097077 rv r r* APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Control Valves (Continued) CV-729 CV-730 CV-731 CV-732 CV-733 CV-734 CV-735 CV-736 CV-737 CV-738 CV-739 CV-740 CV-741 CV-742 CV-743 CV-744 CV-745 CV-746 CV-747 CV-748 CV-749 CV-750 CV-751 CV-752 CV-753 CV-754 CV-755 CV-756 CV-757 CV-758 CV-759 CV-760 CV-761 CV-762 CV-763 CV-764 CV-765 CV-766 CV-767 CV-768 CV-769 CV-770 CV-771 CV-772 Deleted Reactor 45-743 Main Charge Valve Reactor 45-743 Colloid Charge Valve Reactor 45-743 Steam Stripping Valve Reactor Condenser 55-330 Cleaning and Rinse Valve Reactor 45-743 Vent Valve Reactor 45-743 Inert Vent Valve Reactor 45-743 Recovery and Evacuation Valve Reactor 45-743 Cleaning and Rinse Valve Deleted Deleted Reactor 45-744 Main Charge Valve Reactor 45-744 Colloid Charge Valve Reactor 45-744 Steam Stripping Valve Reactor Condenser 55-331 Cleaning and Rinse Valve Reactor 45-744 Vent Valve Reactor 45-744 Inert Vent Valve Reactor 45-744 Recovery and Evacuation Valve Reactor 45-744 Cleaning and Rinse Valve Deleted Deleted Reactor 45-741 Hot Water Rinse Supply Valve Reactor Condenser 45-741 Chem Wash Solution Supply Valve Reactor 45-741 Recovery Valve Reactor 45-741 Initiator Charge Valve Reactor 45-741 VCM Charge Valve Reactor 45-741 Water Charge Valve Deleted Reactor 45-741 Initiator Charge Line Sewer Valve Reactor 45-741 Slurry Dump Valve Reactor 45-741 Sewer Drain Valve Reactor 45-741 Chem Wash Solution Return Valve Deleted Reactor 45-741 Evacuation Valve Reactor 45-741 Initiator Charge Valve Reactor 45-742 Hot Water Rinse Supply Valve Reactor 45-742 Evacuation Valve Reactor 45-742 Chem Wash Solution Supply Valve Reactor 45-742 Recovery Valve Reactor 45-742 Initiator Charge Valve Reactor 45-742 VCM Charge Valve Reactor 45-742 Water Charge Valve Deleted Reactor 45-742 Slurry Dump Valve DTH 000097078 r> r' APPENDIX B INSTRUMENT LIST - CONTINUED Item No Service Control Valves (Continued) CV-773 CV-774 CV-775 CV-776 CV-777 CV-778 CV-779 CV-780 CV-781 CV-782 CV-783 CV-784 CV-785 CV-786 CV-787 CV-788 CV-789 CV-790 CV-791 CV-792 CV-793 CV-794 CV-795 CV-796 CV-797 CV-798 CV-799 CV-800 CV-801 CV-802 CV-803 CV-804 CV-805 CV-806 CV-807 CV-808 CV-809 CV-810 CV-811 CV-812 CV-813 CV-814 Reactor 45-742 Chem Wash Solution Return Valve Reactor 45-742 Sewer Drain Vlave Deleted Reactor 45-742 Initiator Charge Valve Reactor 45-742 Initiator Charge Line Sewer Valve Reactor 45-743 Hot Water Rinse Supply Valve Reactor 45-743 Evacuation Valve Reactor 45-743 Chem Wash Solution Supply Valve Reactor 45-743 Recovery Valve Reactor 45-743 Initiator Charge Valve Reactor 45-743 VCM Charge Valve Reactor 45-743 Water Charge Valve Deleted Reactor 45-743 Slurry Dump Valve Reactor 45-743 Chem Wash Solution Return Valve Reactor 45-743 Sewer Drain Valve Deleted Reactor 45-743 Initiator Charge Valve Reactor 45-743 Initiator Charge Line Sewer Valve Reactor 45-744 Hot Water Rinse Supply Valve Reactor 45-744 Evacuation Valve Reactor 45-744 Chem Wash Solution Supply Valve Reactor 45-744 Initiator Charge Valve Reactor 45-744 VCM Charge Valve Reactor 45-744 Water Charge Valve Deleted Reactor 45-744 Slurry Dump Valve Reactor 45-744 Chem Wash Solution Return Valve Reactor 45-744 Sewer Drain Vlave Deleted Reactor 45-744 Initiator Charge Valve Reactor 45-744 Initiator Charge Line Sewer Valve Reactor 45-744 Recovery Valve Colloid Charge Pump 72-884 Discharge Valve Deleted Cold Water Addition Valve for Swirl Cold Water Addition Valve for Charge Recovery Vacuum Pump 72-901 Suction Valve Recovery Vacuum Pump 72-901 Discharge Valve Recovery Vacuum Pump 72-901 Seal Water Supply Valve Recovery Vacuum Pump 72-901 Mechanical Seal Water Supply Valve Reactor Jacket Eductor EE-701 Steam Valve DTH000097079 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Control Valves (Continued) CV-815 CV-816 CV-817 CV-818 CV-819 CV-820 CV-821 CV-822 CV-823 CV-824 CV-825 CV-826 CV-827 CV-828 CV-829 CV-830 CV-831 CV-832 CV-833 CV-834 CV-835 CV-836 CV-837 CV-838 CV-839 CV-840 CV-841 CV-842 CV-843 CV-844 CV-845 CV-846 CV-847 CV-848 CV-849 CV-850 CV-851 Reactor Jacket Eductor EE-702 Steam Valve Reactor Jacket Eductor EE-703 Steam Valve Reactor Jacket Eductor EE-704 Steam Valve Fresh VCM Storage Tank 45-745 Inlet Valve Hot Water Preheater 55-332 Water Inlet Valve Recovery Vacuum Pump 72-902 Suction Valve Recovery Vacuum Pump 72-902 Discharge Valve Recovery Vacuum Pump 72-902 Seal Water Supply Valve Recovery Vacuum Pump 72-902 Mechanical Seal Water Supply Valve Deleted Deleted Deleted Deleted Colloid Makeup Tank 45-751 Process Water Valve Hot Water Charge Pump 72-880 Discharge Valve Recovery Compressor 72-903 Suction Valve Recovery Compressor 72-903 Discharge Valve Recovery Compressor 72-903 Seal Water Supply Valve Recovery Compressor 72-903 Mechanical Seal Water Supply Valve Deleted Water Recirculation Cooler 55-334 Cooling Water Return Valve Recovery Knockout Drum 45-760 Water Recirculation Inlet Valve Recovery Knockout Drum 45-760 Water Blowdown Valve Recovery Knockout Drum 45-761 Water Recirculation Inlet Valve Recovery Knockout Drum 45-761 Water Blowdown Valve Recovery Compressor 72-904 Suction Valve Recovery Compressor 72-904 Discharge Valve Recovery Compressor 72-904 Seal Water Supply Valve Recovery Coiqpressor 72-904 Mechanical Seal Water Supply Valve Recovered VCM Condensers 55-337 and 55-338 Cooling Water Return Valve Deleted Deleted Reactor Evacuation Ejector EE-706 First Stage Steam Valve Reactor Evacuation Ejector EE-706 Second Stage Steam Valve Hot Water Charge Pump 72-879 Discharge Valve Recovery Compressor 72-905 Suction Valve Recovery Compressor 72-905 Discharge Valve ^ DTH 000097080 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Control Valves (Continued) CV-852 CV-853 CV-854 CV-855 CV-856 CV-857 CV-858 CV-859 CV-860 CV-861 CV-862 CV-863 CV-864 CV-865 CV-866 CV-867 CV-868 CV-869 CV-870 CV-871 CV-872 CV-873 CV-874 CV-875 CV-876 CV-877 CV-878 CV-879 CV-880 CV-881 CV-882 CV-883 CV-884 CV-885 CV-886 CV-887 CV-888 CV-889 CV-890 Recovery Compressor 72-905 Seal Water Supply Valve Recovery Compressor 72-905 Mechanical Seal Water Supply Valve Recovery Vacuum Pumps 72-901 and 72-902 Bypass Valve Recovery Compressors 72-903, 72-904, and 72-905 Bypass Valve Colloid Makeup Tank 45-751 Water Inlet Valve Colloid Makeup Tank 45-751 Colloid Outlet Valve Colloid Recirculation Valve to Colloid Storage Tank 45-752 Colloid Circulation Pump 72-882 Inlet Valve Deleted Colloid Charge Tank 45-753 Inlet Valve Deleted Dump System Water Rinse Valve Slurry Transfer Pump 72-896 Mechanical Seal Water Valve Deleted Slurry Transfer Pump 72-897 Mechanical Seal Water Valve Deleted Deleted Deleted Deleted Cleaning Solution Heater 55-339 Inlet Valve Cleaning Solution Storage Tank 45-767 Top Inlet Valve Cleaning Solution Pumps 72-898 and 72-899 Suction Valve Reactor Cleaning Solution Return Valve to Cleaning Solution Tank 45-767 Seal Oil Pressure Unit 95-300 Seal Oil Return Valve Seal Oil PressureUnit 95-299 Seal Oil Return Valve Seal Oil PressureUnit 95-300 Seal Oil Supply Valve Seal Oil PressureUnit 95-299 Seal Oil Supply Valve Initiator Injection Pot 45-750 Service Water Inlet Valve Blowdown Tank Pump 72-900 Discharge Valve 45-741 Emergency NO Short Stop Three-Way Valve 45-742 Emergency NO Short Stop Three-Way Valve 45-743 Emergency NO Short Stop Three-Way Valve 45-744 Emergency NO Short Stop Three-Way Valve 45-741 Emergency NO Short Stop Valve 45-742 Emergency NO Short Stop Valve 45-743 Emergency NO Short Stop Valve 45-744 Emergency NO Short Stop Valve Recovery Seal Water and VCM Diverter Valve Recovery Seal Water and VCM Diverter Valve DTH 000097081 APPENDIX B INSTRUMENT LIST - CONTINUED Item No Service Control Valves (Continued) CV-891 CV-892 CV-893 CV-894 CV-895 CV-896 CV-897 Steam Valve for Blowdown Tank 45-319 Pressure Regulation Water Drain Valve from Recovered VCM Storage Tank 89-520 to the Blowdown Tank 45-319 Water Drain Valve from Recovered VCM Storage Tank 45-317 to the Blowdown Tank 45-319 VCM Recovery Valve for Blowdown Tank 45-319 VCM Recovery Valve for VCM Storage Tank 45-745, 89-520, and 45-317 Instrument Air Supply Valve to Reactors 45-741, 45-742, 45-743, and 45-744 Hot Water Rinse Header Valve to Reactors 45-741, 45-742, 45-743, and 45-744 Flow Instruments FQIC-701A and B FSL-701A and B FAL-701 FQIC-702 FQIC-703 PQIC-704 PQIC-705 FQIC-706 FI-707 FR-708 FQI-708 FCi-709 FIRC-710 FIRC-711 FIRC-712 FIRC-713 FI-714 FAL-714 FI-715 FAL-715 FI-716 FAL-716 FI-717 FAL-717 FI-718 VCM Charge Totalizers VCM Charge Low Flow Switches VCM Charge Low Flow Alarm Recovered VCM Charge Totalizer Initiator Injection Pot 45-750 Service Water Flow Totalizer Hot Water Charge Totalizer Colloid Charge Totalizer Colloid Makeup Tank 45-751 Makeup Water Flow Totalizer Deleted Reactor Steam Stripping Flow Recorder Reactors Steam Stripping Flow Totalizer Deleted Reactor 45-741 Cooling Water Flow Controller Reactor 45-742 Cooling Water Flow Controller Reactor 45-743 Cooling Water Flow Controller Reactor 45-744 Cooling Water Flow Controller Reactor Agitator 51-101 Inboard Seal Water Flush Rotameter Reactor Agitator 51-101 Seal Water Low Flow Alarm Reactor Agitator 51-102 Inboard Seal Water Flush Rotameter Reactor Agitator 51-102 Seal Water Low Flow Alarm Reactor Agitator 51-103 Inboard Seal Water Flush Rotameter Reactor Agitator 51-103 Seal Water Low Flow Alarm Reactor Agitator 51-104 Inboard Seal Water Flush Rotameter Reactor Agitator 51-104 Seal Water Low Flow Alarm Reactor 45-741 Spray Nozzle Flush Rotameter DTH 000097082 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Flow Instruments (Continued) FI-719 FI-720 FI-721 FI-722 FI-723 FI-724 FI-725 FI-726 FI-727 FI-728 FI-729 FI-730 FI-731 FI-732 FI-733 FI-734 FI-735 FI-736 FI-737 FIC-738 FIC-739 FIC-740 FI-741 FI-742 FIC-743 FI-744 FI-745 FI-746 FI-747 FI-748 FCi-749 Reactor 45-742 Spray Nozzle Flush Rotameter Reactor 45-743 Spray Nozzle Flush Rotameter Reactor 45-744 Spray Nozzle Flush Rotameter Deleted Deleted Deleted Deleted Recovery Knockout Drum Level Controller LC-716 Water Flush Rotameter Recovery Knockout Drum Level Controller LC-718 Water Flush Rotameter Recovery Vacuum Pump 72-901 Double Mechanical Seal Water Rotameter Recovery Vacuum Pump 72-901 Inboard Flush Water Rotameter Recovery Vacuum Pump 72-902 Double Mechanical Seal Water Rotameter Recovery Vacuum Pump 72-902 Inboard Flush Water Rotameter Recovery Compressor 72-903 Double Mechanical Seal Water Rotameter Deleted Recovery Compressor 72-904 Double Mechanical Seal Water Rotameter Deleted Recovery Compressor 72-905 Double Mechanical Seal Water Rotameter Deleted Recovery Vacuum Punp 72-901 and Recovery Compressor 72-903 Seal Water Flow Controller Recovery Vacuum Pump 72-902 and Recovery Compressor 72-904 Seal Water Flow Controller Recovery Compressor 72-905 Seal Water Flow Controller Seal Water Separator Level Controller LC-720 Flush Water Rotameter Seal Water Separator Level Controller LC-722 Flush Water Rotameter Deleted Recovered VCM to Recovery Knockout Drum 45-760 Bullseye Deleted Deleted Slurry Dump to Slurry Strainer FD-717 Bullseye Deleted Reactor Agitator 51-101 Mechanical Seal Oil Supply Flow Regulator DTH 000097083 r-s CN APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Flow Instruments (Continued) FCi-750 FCi-751 FCi-752 FI-753 FI-754 FI-755 FI-756 FQI-757 RO-758 OF-759 OF-760 OF-761 OF-762 FI-763 FI-764 FI-765 FI-766 FI-767 FI-768 FI-769 FI-770 RO-771 RO-772 RO-773 RO-774 Reactor Agitator 51-102 Mechanical Seal Oil Supply Flow Regulator Reactor Agitator 51-103 Mechanical Seal Oil Supply Flow Regulator Reactor Agitator 51-104 Mechanical Seal Oil Supply Flow Regulator Reactor Agitator 51-101 Mechanical Seal Oil Supply Rotameter Reactor Agitator 51-102 Mechanical Seal Oil Supply Rotameter Reactor Agitator 51-103 Mechanical Seal Oil Supply Rotameter Reactor Agitator 51-104 Mechanical Seal Oil Supply Rotameter Hot Water Charge Totalizer Colloid Makeup Water Supply Restriction Orifice Reactor 45-741 Cooling Water System Orifice Flanges Reactor 45-742 Cooling Water System Orifice Flanges Reactor 45-743 Cooling Water System Orifice Flanges Reactor 45-744 Cooling Water System Orifice Flanges Slurry Transfer Pump 72-896 Inboard Seal Flush Water Rotameter Slurry Transfer Pump 72-897 Inboard Seal Flush Water Rotameter Deleted Deleted VCM Charge Pump 72-875 Double Mechanical Seal Water Rotameter VCM Charge Pump 72-876 Double Mechanical Seal Water Rotameter Recovered VCM Charge Pump 72-877 Double Mechanical Seal Rotameter Recovered VCM Charge Pump 72-878 Double Mechanical Seal Rotameter VCM Charge Pump 72-875 Double Mechanical Seal Water Back Pressure Restriction Orifice VCM Charge Pump 72-876 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovered VCM Charge Pump 72-877 Mechanical Seal Water Back Pressure Restriction Orifice Recovered VCM Charge Pump 72-878 Mechanical Seal Water Back Pressure Restriction Orifice DTH 000097084 o _ APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Flow Instruments (Continued) FI-775 FI-776 FI-777 FI-778 FI-779 RO-780 RO-781 RO-782 RO-783 RO-784 RO-785 RO-786 FI-787 FI-788 FI-789 Water Recirculation Pump 72-889 Inboard Seal Flush Water Rotameter Deleted Water Recirculation Pump 72-890 Inboard Seal Flush Water Rotameter Seal Water Pump 72-891 Inboard Seal Flush Water Rotameter Seal Water Pump 72-892 Inboard Seal Flush Water Rotameter Recovery Vacuum Pump 72-901 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Vacuum Pump 72-902 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Compressor 72-903 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Compressor 72-904 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Compressor 72-905 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovered VCM Transfer Pump 72-893 Mechanical Seal Water Back Pressure Restriction Orifice Recovered VCM Transfer Pump 72-894 Mechanical Seal Water Back Pressure Restriction Orifice Recovered VCM Transfer Pump 72-893 Mechanical Seal Water Rotameter Recovered VCM Transfer Pump 72-894 Mechanical Seal Water Rotameter Recovery Vacuum Pump 72-901 Inboard Flush Water Rotameter FI-790 FI-791 FI-792 FI-793 FI-794 FI-795 FI-796 FI-797 FI-798 Recovery Vacuum Pump 72-901 Double Mechanical Seal Water Rotameter Recovery Vacuum Pump 72-902 Inboard Flush Water Rotameter Recovery Vacuum Pump 72-902 Double Mechanical Seal Water Rotameter Deleted Recovery Compressor 72-903 Double Mechanical Seal Water Rotameter Deleted Recovery Conqiressor 72-904 Double Mechanical Seal Water Rotameter Deleted Recovery Conq>ressor 72-905 Double Mechanical Seal Water Rotameter DTH 000097085 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Flow Instruments (Continued) RO-799 RO-800 RO-801 RO-802 R0-803 FI-804 FI-805 FI-806 FI-807 FI-808 FI-809 FI-810 FQI-811 RO-812 RO-813 FI-814 FI-815 RO-816 Recovery Vacuum Pump 72-901 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Vacuum Pump 72-902 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Compressor 72-903 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Compressor 72-904 Double Mechanical Seal Water Back Pressure Restriction Orifice Recovery Compressor 72-905 Double Mechanical Seal Water Back Pressure Restriction Orifice AMS Short Stop Charge Pot 45-755 Water Flush Rotameter AMS Short Stop Charge Pot 45-756 Water Flush Rotameter AMS Short Stop Charge Pot 45-757 Water Flush Rotameter AMS Short Stop Charge Pot 45-758 Water Flush Rotameter Blowdown Tank 45-319 Level Cage Water Flush Rotameter Recovered VCM Sampling System Bullseye Recovered VCM Sampling System Bullseye Steam to Reactor Module Flow Totalizer Deleted Deleted Blowdown Tank Pump 72-900 Double Mechanical Seal Water Rotameter Blowdown Tank Pump 72-900 Inboard Seal Water Flush Rotameter Blowdown Tank Pump 72-900 Double Mechanical Seal Water Back Pressure Restriction Orifice Level Gauges LG-701A, B, C, and D LG-702A, B, C and D LG-703A, B, C and D LG-704A, B, C and D LG-705 LG-706A, B, etnd'iC LG-707A, B and C LG-708 LG-709 LG-710 Fresh VCM Storage Tank 45-745 Level Gauge Recovered VCM Storage Tank 89-520 Level Gauge Recovered VCM Storage Tank 45-317 Level Gauge Hot Water Tank 45-748 Level Gauge Deleted Colloid Storage Tank 45-752 Level Gauge Colloid Charge Tank 45-753 Level Gauge Recovery Knockout Drum 45-760 Level Gauge Recovery Knockout Drum 45-761 Level Gauge Hydroquinone Storage Tank 45-765 Level Gauge DTH 000097086 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Level Gauges (Continued) LG-711 LG-712 LG-713 LG-714 LG-715 LG-716 LG-717 Seal Hater Separator 45-762 Level Gauge Seal Water Separator 45-763 Level Gauge Recovered VCM Collect Tank 45-764 Level Gauge Seal Oil Storage Drum 45-754 Level Gauge Deleted Blowdown Tank 45-319 Level Gauge Mechanical Seal Purge Water Surge Drum 45-759 Level Gauge Level Instruments LI-701 Fresh VCM Storage Tank 45-745 Level Indicator LAH-701 Fresh VCM Storage Tank 45-745 High Level Alarm LS-701A, B, Fresh VCM Storage Tank 45-745 Level Switches C and D LA-702 Deleted LA-703 Deleted LI-704 Recovered VCM Storage Tank 89-520 Level Indicator LA-705 Deleted LA-706 Deleted LI-707 Recovered VCM Storage Tank 45-317 Level Indicator LA-708 Deleted LA-709 Deleted LAH-710 Colloid Makeup Tank 45-751 High Level Alarm LI-711 Hot Water Tank 45-748 Level Indicator LS-711A Deleted LA-711B, C, Hot Water Tank 45-748 Level Switches and D LA-712 Deleted LAH-713 Colloid Storage Tank 45-752 High Level Alarm LAH-714 Colloid Charge Tank 45-753 High Level Alarm LSL-715 Colloid Charge Tank 45-753 Low Level Switch LSH-716 Recovery Knockout Drum 45-760 High Level Switch LSL-717 Recovery Knockout Drum 45-760 Low Level Switch LSH-718 Recovery Knockout Drum 45-761 High Level Switch LSL-719 Recovery Knockout Drum 45-761 Low Level Switch LC-720 Seal Water Separator 45-762 Level Controller LAH-720 Seal Water Separator 45-762 High Level Alarm LAL-720 Seal Water Separator 45-762 Low Level Alarm LA-721 Deleted LC-722 Seal Water Separator 45-763 Level Controller LAH-722 Seal Water Separator 45-763 High Level Alarm LAL-722 Seal Water Separator 45-763 Low Level Alarm LA-723 Deleted LC-724 Recovered VCM Collect Tank 45-764 Level Controller f LIC-725 Slurry Dump Tank 45-766 Level Controller LAH-725 Slurry Dump Tank 45-766 High Level Alarm DTH 000097087 \ APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Level Instruments (Continued) LIC-726 LA-726 LAH-727 LI-728 LAL-729 LSL-730 LAL-730 LSL-731 LAL-731 LC-732 LAL-733 LSH-734 LA-735 LA-736 LA-737 LA-738 LAL-739 LAH-740 LSL-741 Deleted Deleted Cleaning Solution Tank 45-767 High Level Alarm Cleaning Solution Tank 45-767 Level Indicator Cleaning Solution Tank 45-767 Low Level Alarm Seal Oil Pressure Unit 95-299 Reservoir Low Level Switch Seal Oil Pressure Unit 95-299 Reservoir Low Level Alarm Seal Oil Pressure Unit 95-300 Reservoir Low Level Switch Seal Oil Pressure Unit 95-300 Reservoir Low Level Alarm Deleted Hydroquinone Storage Tank 45-765 Low Level Alarm Cleaning Solution Tank 45-767 High Level Switch Deleted Deleted Deleted Deleted Colloid Makeup Tank 45-751 Low Level Alarm Blowdown Tank 45-319 High Level Alarm Blowdown Tank 45-319 Low Level Switch Pressure Gauges PG-701 PG-702 PG-703 PG-704 PG-705 PG-706 PG-707 PG-708 PG-709 PG-710 PG-711 PG-712 PG-713 PG-714 PA-715 PG-716 PG-717 PG-718 VCM Charge Pump 72-875 Discharge Pressure Gauge VCM Charge Pump 72-876 Discharge Pressure Gauge Recovered VCM Charge Pump 72-877 Discharge Pressure Gauge Recovered VCM Charge Pump 72-878 Discharge Pressure Gauge Fresh VCM Storage Tank 45-745 Pressure Gauge Recovered VCM Storage Tank 89-520 Pressure Gauge Recovered VCM Storage Tank 45-317 Pressure Gauge Deleted Deleted Deleted Deleted Process Water Filter 64-720 Inlet Pressure Gauge Process Water Filter 64-720 Outlet Pressure Gauge Hot Water Charge Pump 72-879 Discharge Pressure Gauge Hot Water Charge Pump 72-880 Discharge Pressure Gauge Deleted Deleted Deleted DTH 000097088 n- r' APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Pressure Gauges (Continued) PG-719 PG-720 PG-721 PG-722 PG-723 PG-724 PG-725 PG-726 PG-727 PG-728 PG-729 PG-730 PG-731 PG-732 PG-733 PG-734 PG-735 PG-736 PG-737 PG-738 PG-739 PG-740 PG-741 PG-742 PG-743 PG-744 PG-745 PG-746 PG-747 PG-748 PG-749 PG-750 PG-751 PG-752 PG-753 PG-754 PG-755 PG-756 PG-757 PG-758 PG-759 Colloid Makeup Water Filter 64-721 Inlet Pressure Gauge Colloid Makeup Water Filter 64-721 Outlet Pressure Gauge Colloid Batch Transfer Pump 72-881 Discharge Pressure Gauge Colloid Transfer Filter 64-722 Outlet Pressure Gauge Colloid Circulation Pump 72-882 Discharge Pressure Gauge Colloid Transfer Filter 64-723 Outlet Pressure Gauge Colloid Charge Pump 72-883 Discharge Pressure Gauge Colloid Charge Pump 72-884 Discharge Pressure Gauge Steam Stripping Header Pressure Gauge Reactor 45-741 Steam Stripping Line Pressure Gauge Deleted Reactor Condenser 55-328 Pressure Gauge Reactor Agitator 51-101 Seal Oil Return Pressure Gauge Reactor 45-742 Steam Stripping Line Pressure Gauge Reactor Condenser 55-329 Pressure Gauge Deleted Reactor Agitator 51-102 Seal Oil Return Pressure Gauge Reactor 45-743 Steam Stripping Line Pressure Gauge Reactor Condenser 55-330 Pressure Gauge Deleted Reactor Agitator 51-103 Seal Oil Return Pressure Gauge Reactor 45-744 Steam Stripping Line Pressure Gauge Reactor Condenser 55-331 Pressure Gauge Deleted Reactor Agitator 51-104 Seal Oil Return Pressure Gauge Recovery Knockout Drum 45-760 Pressure Gauge Water Recirculation Pump 72-889 Discharge Pressure Gauge Deleted Recovered VCM Bleed Back Line Pressure Gauge Recovery Knockout Drum 45-761 Pressure Gauge Water Recirculation Pump 72-890 Discharge Pressure Gauge Deleted Recovery Vacuum Pump 72-901 Inlet Pressure Gauge Recovery Compressors 72-904 or 72-905 Suction Pressure Gauge Recovery Compressors 72-903, 72-904, and 72-905 Discharge Pressure Gauge Seal Water Separator 45-762 Pressure Gauge Seal Water Separator 45-763 Pressure Gauge Seal Water Pump 72-891 Discharge Pressure Gauge Seal Water Filter 64-731 Outlet Pressure Gauge Seal Water Pump 72-892 Discharge Pressure Gauge Seal Water Filter 64-732 Outlet Pressure Gauge DTH 000097089 /> APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Pressure Gauges (Continued) PG-760 PG-761 PG-762 PG-763 PG-764 PG-765 PG-766 PG-767 PG-768 PG-769 PG-770 PG-771 PG-772 PG-773 PG-774 PG-775 PG-776 PG-777 PG-778 PG-779 PG-780 PG-781 PG-782 PG-783 PG-784 PG-785 PG-786 PG-787 PG-788 PG-789 PG-790 PG-791 PG-792 PG-793 PG-794 PG-795 PG-796 PG-797 Recovered VCM Collect Tank 45-764 Pressure Gauge Recovered VCM Transfer Pumps 72-893 and 72-894 Discharge Pressure Gauge Recovery Knockout Drum 45-760 VCM Inlet Line Pressure Gauge Hydroquinone Storage Tank 45-765 Pressure Gauge Hydroqulnone Injection Pump 72-895 Discharge Pressure Gauge Slurry Transfer Pump 72-896 Discharge Pressure Gauge Deleted Slurry Transfer Pump 72-897 Discharge Pressure Gauge Deleted Caustic Solution Pump 72-898 Discharge Pressure Gauge Caustic Solution Pump 72-899 Discharge Pressure Gauge Cleaning Solution Heater 55-339 Outlet Pressure Gauge Service Water Filter 64-724 Inlet Pressure Gauge Service Water Filter 64-724 Outlet Pressure Gauge Service Water Pumps 72-885 and 72-886 Discharge Pressure Gauge Mechanical Seal Purge Water Pumps 72-887 and 72-888 Discharge Pressure Gauge AMS Short Stop Charge Pot 45-755 Outlet Pressure Gauge AMS Short Stop Charge Pot 45-756 Outlet Pressure Gauge AMS Short Stop Charge Pot 45-757 Outlet Pressure Gauge AMS Short Stop Charge Pot 45-758 Outlet Pressure Gauge Deleted Blowdown Tank Pump 72-900 Discharge Pressure Gauge Blowdown Tank 45-319 Pressure Gauge Seal Oil Return Header Pressure Gauge Seal Oil Pressure Unit 95-299 Pressure Gauge Seal Oil Pressure Unit 95-300 Pressure Gauge Seal Oil Supply Header Pressure Gauge Deleted Deleted Deleted Deleted Reactor Ejector Cyclone Separator 45-768 Outlet Pressure Gauge Breathing Air Header Pressure Gauge Recovery Vacuum Pump 72-902 Suction Pressure Gauge Deleted Initiator Injection Pot 45-750 Pressure Gauge Seal Oil Return Filter 64-727 Outlet Pressure Gauge Seal Oil Return Filter 64-728 Outlet Pressure Gauge DTH OUt n- APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Pressure Gauges (Continued) PG-798 PG-799 PG-800 PG-801 PG-802 PG-803 PG-804 PG-805 PG-806 PG-807 PG-808 PG-809 PG-810 PG-811 Emergency NO Short Stop Bottle PA-713 Pressure Gauge Emergency NO Short Stop Bottle PA-714 Pressure Gauge Emergency NO Short Stop Bottle PA-715 Pressure Gauge Emergency NO Short Stop Bottle PA-716 Pressure Gauge VCM Charge Filter 64-718 and 64-742 Discharge Pressure Gauge Recovered VCM Charge Filter 64-719 Discharge Pressure Gauge Reactor 45-741 Resin Sampling System Pressure Gauge Reactor 45-742 Resin Sampling System Pressure Gauge Reactor 45-743 Resin Sampling System Pressure Gauge Reactor 45-744 Resin Sailing System Pressure Gauge Instrument Air Capacity Tank 45-301 Pressure Gauge Mechanical Seal Purge Water Surge Drum 45-759 Pressure Gauge High Pressure Service Water Header Pressure Gauge (Downstream of PCi-817) Mechanical Seal Purge Water Header Pressure Gauge (Downstream of PCi-818) Pressure Instruments PA-701 PCi-702 PSH-703 PCI-704 PI-705 PCi-706 PSL-707 PCi-708 PCi-709 PCi-710 PCI-711 PSL-712 PSL-713 PSL-714 PSL-715 PSL-716 PSL-717 Deleted Deleted Initiator Injection Pot 45-750 High Pressure Switch Recovered VCM Storage Tanks 89-520 and 45-317 Inert Vent Back Pressure Regulator Reactor Evacuation Header Pressure Indicator Steam Stripping Header Steam Supply Back Pressure Regulator Steam Stripping Header Low Pressure Switch Deleted Deleted Deleted Deleted Reactor 45-741 Pressure Switch (Prevents dump before recovery) Reactor 45-742 Pressure Switch (Prevents dump before recovery) Reactor 45-743 Pressure Switch (Prevents dump before recovery) Reactor 45-744 Pressure Switch (Prevents dump before recovery) Reactor 45-741 Pressure Switch (Prevents charge before evacuation) Reactor 45-742 Pressure Switch (Prevents charge before evacuation) DTH 000097091 r*' APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Pressure Instruments (Continued) PSL-718 PSL-719 PR-720 PAH-720 PR-721 PAH-721 PR-722 PAH-722 PR-723 PAH-723 PI-724 PIC-725 PIC-726 PSL-727 PDS-728 PCi-729 PCi-730 PCi-731 PSL-732 PAL-732 PCi-733 PCi-734 PCi-735 PSL-737A and B PAL-737 PSL-738 PAL-738 PCi-739 PSL-740 PAL-740 PCi-741 PA-742 Reactor 45-743 Pressure Switch (Prevents charge before evacuation) Reactor 45-744 Pressure Switch (Prevents charge before evacuation) Reactor 45-741 Pressure Recorder Reactor 45-741 High Pressure Alarm Reactor 45-742 Pressure Recorder Reactor 45-742 High Pressure Alarm Reactor 45-743 Pressure Recorder Reactor 45-743 High Pressure Alarm Reactor 45-744 Pressure Recorder Reactor 45-744 High Pressure Alarm Reactor Recovery Pressure Indicator Recovery Knockout Drum 45-760 Inlet Pressure Controller VCM Bleed Stream to Recovery System Pressure Controller Recovery Compressors 72-903, 72-904, and 72-905 Suction Low Pressure Switch Recovery Vacuum Pumps 72-901 and 72-902 Suction and Re covery Compressors 72-903, 72-904, and 72-905 Discharge Differential Pressure Switch Hydroquinone Storage Tank 45-765 Nitrogen Pressure Regulator Deleted Mechanical Seal Purge Water Surge Drum 45-759 Nitrogen Supply Pressure Regulator High Pressure Service Water System Low Pressure Switch High Pressure Service Water System Low Pressure Alarm Deleted Deleted Deleted Mechanical Seal Water System Low Pressure Switches Mechanical Seal Water System Low Pressure Alarm Seal Oil Pressure Unit 95-299 Discharge Low Pressure Switch Seal Oil Pressure Unit 95-299 Discharge Low Pressure Alarm Seal Oil Pressure Unit 95-299 Nitrogen Supply Pressure Regulator Seal Oil Pressure Unit 95-300 Discharge Low Pressure Switch Seal Oil Pressure Unit 95-300 Discharge Low Pressure Alarm Seal Oil Pressure Unit 95-300 Nitrogen Supply Pressure Regulator Deleted DTH 000097092 r^ APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Pressure Instruments (Continued) PCi-743 PCi-744 PCi-745 PC1-746 PCi-747 PC1-748 PCI-749 PAH-750 PAH-751 PCi-752 PAL-753 PCI-754 PCi-755 PCI-756 PCi-757 PSL-758 PIC-759 PAH-760 PI-760 PS-761 PSL-762 PAL-763 Breathing Air Station Supply Pressure Regulator (Reactors, Ground Level) Breathing Air Station Supply Pressure Regulator (Reactors, Second Level) Breathing Air Station Supply Pressure Regulator (Recovery Building, First Floor) Breathing Air Station Supply Pressure Regulator (Recovery Building, Second Floor) Breathing Air Station Supply Pressure Regulator (Charge Area) Deleted Deleted Initiator Injection Pot 45-750 High Pressure Alarm Seal Oil Supply High Pressure Alarm Breathing Air Station Supply (Reactors, Third Level) Emergency NO Short Stop Bottles Low Pressure Alarm PA-713 NO Supply Pressure Regulator to Reactor 45-741 PA-714 NO Supply Pressure Regulator to Reactor 45-742 PA-715 NO Supply Pressure Regulator to Reactor 45-743 PA-716 NO Supply Pressure Regulator to Reactor 45-744 High Pressure Service Water Low Pressure Switch Blowdown Tank 45-319 Pressure Controller Blowdown Tank 45-319 High Pressure Alarm Blowdown Tank 45-319 Pressure Indicator Deleted Blowdown Tank 45-319 Stripping Steam Low Pressure Switch Reactor Area Instrument Air Low Pressure Alarm Rupture Discs RD-701 RD-702 RD-703 RD-704 RD-705 RD-706 RD-707 RD-708 RD-709 RD-710 RD-711 RD-712 RD-713 RD-714 Reactor 45-741 Rupture Disc Reactor 45-742 Rupture Disc Reactor 45-743 Rupture Disc Reactor 45-744 Rupture Disc Reactor Condenser 55-328 Rupture Disc Reactor Condenser 55-329 Rupture Disc Reactor Condenser 55-330 Rupture Disc Reactor CblldliN8ar 55-331 Rupture Disc Reactor 45-741 First of Double Rupture Discs Reactor 45-742 First of Double Rupture Discs Reactor 45-743 First of Double Rupture Discs Reactor 45-744 First of Double Rupture Discs Reactor 45-741 Second of Double Rupture Discs Reactor 45-742 Second of Double Rupture Discs DTH 000097093 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Rupture Discs (Continued) RD-715 KD-716 RD-717 RD-718 RD-719 RD-720 RD-721 RD-722 RD-723 RD-724 RD-725 RD-726 RD-727 RD-728 RD-729 RD-730 RD-731 RD-732 RD-733 RD-734 RD-735 RD-736 RD-737 RD-738 RD-739 RD-740 RD-741 RD-742 RD-743 RD-744 RD-745 to KD-759 RD-760 RD-761 RD-762 RD-763 RD-764 RD-765 RD-766 RD-767 Reactor 45-743 Second of Double Rupture Discs Reactor 45-744 Second of Double Rupture Discs Fresh VCM Storage Tank 45-745 Rupture Disc Recovered VCM Storage Tank 89-520 Rupture Disc Recovered VCM Storage Tank 45-317 Rupture Disc Deleted Deleted Deleted Deleted Deleted Deleted Recovery Knockout Drum 45-760 Rupture Disc Recovery Knockout Drum 45-761 Rupture Disc Initiator Injection Pot 45-750 Rupture Disc Deleted Dele ted Recovery Vacuum Pump 72-901 Inlet Rupture Disc Recovery Vacuum Pump 72-902 Inlet Rupture Disc Deleted Deleted Seal Water Separator 45-762 Rupture Disc Seal Water Separator 45-763 Rupture Disc Deleted Deleted Recovered VCM Condenser 55-337 VCM Outlet Rupture Disc Recovered VCM Condenser 55-338 VCM Outlet Rupture Disc Recovered VCM Collect Tank 45-764 Rupture Disc Deleted Deleted Blovdown Tank 45-319 Rupture Disc Deleted Recovered VCM Collect Tank 45-764 Inlet Line Rupture Disc Deleted Deleted Deleted Deleted Slurry Dump Line Rupture Disc Cleaning Solution Strainer 64-734 Inlet Piping Rupture Disc Deleted Safety-Relief Valves SV-701 SV-702 SV-703 Reactor 45-741 Relief Valve Reactor 45-742 Relief Valve Reactor 45-743 Relief Valve DTH 000097094 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Safety-Relief Valves (Continued) SV-704 SV-705 SV-706 SV-707 SV-708 SV-709 SV-710 SV-711 SV-712 SV-713 SV-714 SV-715 SV-716 SV-717 SV-718 SV-719 SV-720 SV-721 SV-722 SV-723 SV-724 SV-725 SV-726 SV-727 SV-728 SV-729 SV-730 SV-731 SV-732 SV-733 SV-734 SV-735 SV-736 SV-737 SV-738 SV-739 SV-740 SV-741 SV-742 SV-743 Reactor 45-744 Relief Valve Reactor Condenser 55-328 Relief Valve Reactor Condenser 55-329 Relief Valve Reactor Condenser 55-330 Relief Valve Reactor Condenser 55-331 Relief Valve Reactor 45-741 Jacket Relief Valve Reactor 45-742 Jacket Relief Valve Reactor 45-743 Jacket Relief Valve Reactor 45-744 Jacket Relief Valve Hot Water Preheater 55-332 Relief Valve Deleted Deleted Deleted Fresh VCM Storage Tank 45-745 Relief Valve Recovered VCM Storage Tank 89-520 Relief Valve Recovered VCM Storage Tank 45-317 Relief Valve VCM Charge Pumps 72-875 and 72-876 Suction Piping Relief Valve Recovered VCM Charge Pumps 72-877 and 72-878 Suction Piping Relief Valve Recovered VCM Charge Filter 64-719 Relief Valve Recovered VCM Charge Pumps 72-877 and 72-878 Discharge Piping Relief Valve VCM Charge Filter 64-718 Relief Valve VCM Charge Line Relief Valve (Down Stream of VCM Charge Totalizers FQ1C-701A and B) Recovery Knockout Drum 45-760 Relief Valve Recovery Knockout Drum 45-761 Relief Valve Deleted Water Recirculation Cooler 55-334 Relief Valve Deleted Recovery Vacuum Pump 72-901 Inlet Relief Valve Recovery Vacuum Pump 72-902 Inlet Relief Valve Hydroquinone Storage Tank 45-765 Relief Valve Hydroquinone Injection Pump 72-895 Discharge Relief Valve Seal Water Separator 45-762 Relief Valve Seal Water Separator 45-763 Relief Valve Seal Water Filter 64-731 Relief Valve Seal Water Filter 64-732 Relief Valve Recovered VCM Condenser 55-337 VCM Outlet Relief Valve Recovered VCM Condenser 55-338 VCM Outlet Relief Valve Recovered VCM Collect Tank 45-764 Relief Valve Cleaning Solution Heater (Tubes) 55-339 Relief Valve Mechanical Seal Purge Water Surge Drum 45-759 Relief Valve DTH 000097095 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Safety-Relief Valves (Continued) SV-744 SV-745 SV-746 SV-747 SV-748 SV-749 SV-750 SV-751 SV-752 SV-753 SV-754 SV-755 SV-756 ^ SV-757 SV-758 SV-759 SV-760 SV-761 SV-762 SV-763 SV-764 SV-765 SV-766 SV-767 SV-768 Blowdown Tank 45-319 Relief Valve Breathing Air Station Supply Piping Relief Valve (Reactors, Ground Level) Breathing Air Station Supply Piping Relief Valve (Reactors, Ground Level) Breathing Air Station Supply Piping Relief Valve (Recovery Building First Floor) Breathing Air Station Supply Piping Relief Valve (Recovery Building Second Floor) Breathing Air Station Supply Piping Relief Valve (Charge Area) AMS Short Stop Charge Pot 45-755 Relief Valve AMS Short Stop Charge Pot 45-756 Relief Valve AMS Short Stop Charge Pot 45-757 Relief Valve AMS Short Stop Charge Pot 45-758 Relief Valve Reactor 45-741 Steam Stripping Line Relief Valve Reactor 45-742 Steam Stripping Line Relief Valve Reactor 45-743 Steam Stripping Line Relief Valve Reactor 45-744 Steam Stripping Line Relief Valve Deleted Deleted Recovered VCM Collect Tank 45-764 Inlet Line Relief Valve Recovered VCM Transfer Pumps 72-893 and 72-894 Discharge Relief Valve Recovered VCM Storage Tanks 89-520 and 45-317 Inlet Line Relief Valve VCM Charge Pumps 72-875 and 72-876 Discharge Relief Valve Breathing Air Station Supply Piping Relief Valve (Reactors, Third Level) Cleaning Solution Filter 64-734 Relief Valve Deleted VCM Charge Filter 64-742 Relief Valve Instrument Air Capacity Tank 45-301 Relief Valve Temperature Gauges TG-701 TG-702 TG-703 TG-704 TG-705 TG-706 TG-707 _ TG-708 Hot Water Preheater 55-332 Outlet Temperature Gauge Recovered VCM Storage Tank 89-520 Temperature Gauge Recovered VCM Storage Tank 45-317 Temperature Gauge Colloid Makeup Tank 45-751 Temperature Gauge Colloid Storage Tank 45-752 Tenperature Gauge Colloid Charge Tank 45-753 Temperature Gauge Reactor Jacket 45-741 Cooling Water Return Temperature Gauge Reactor Condenser 55-328 Cooling Water Return Tempera ture Gauge 000097096 APPENDIX B INSTURMENT LIST - CONTINUED Item No. Service Temperature Gauges (Continued) TG-709 TG-710 TG-711 TG-712 TG-713 TG-714 TG-715 TG-716 TG-717 TG-718 TG-719 TG-720 TG-721 TG-722 TG-723 TG-724 TG-725 TG-726 TG-727 TG-728 TG-729 TG-730 TG-731 TG-732 TG-733 Reactor Jacket 45-742 Cooling Water Return Temperature Gauge Reactor Condenser 55-329 Cooling Water Return Tempera ture Gauge Reactor Jacket 45-743 Cooling Water Return Temperature Gauge Reactor Condenser 55-330 Cooling Water Return Temperature Gauge Reactor Jacket 45-744 Cooling Water Return Temperature Gauge Reactor Condenser 55-331 Cooling Water Return Temperature Gauge Water Recirculation Cooler 55-334 Outlet Temperature Gauge Deleted Water Recirculation Cooler 55-334 Cooling Water Return Temperature Gauge Water Recirculation Cooler 55-334 Inlet Temperature Gauge Seal Water Cooler 55-335 Cooling Water Return Temperature Gauge Seal Water Separator 45-762 Seal Water Outlet Temperature Gauge Deleted Seal Water Cooler 55-336 Cooling Water Return Temperature Gauge Seal Water Separator 45-763 Seal Water Outlet Temperature Gauge Recovered VCM Condenser 55-337 Cooling Water Return Temperature Gauge Recovered VCM Condenser 55-337 VCM Outlet Temperature Gauge Deleted Recovered VCM Condenser 55-338 Cooling Water Return Temperature Gauge Recovered VCM Condenser 55-338 VCM Outlet Temperature Gauge Deleted Cleaning Solution Tank 45-767 Temperature Gauge Seal Oil Return Temperature Gauge Seal Oil Pressure Unit 95-299 Cooling Water Return Temperature Gauge Seal Oil Pressure Unit 95-300 Cooling Water Return Temperature Gauge dtb O' APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Temperature Gauges (Continued) TG-734 TG-735 TG-736 TG-737 TG-738 TG-739 TG-740 Seal Oil Supply Tenperature Gauge Colloid Makeup Tank Jacket 45-751 Cooling Water Return Temperature Gauge Fresh VCM Storage Tank 45-745 Temperature Gauge Process Water Temperature Gauge Hot Water Tank 45-748 Temperature Gauge Initiator Charge Pot 45-750 Temperature Gauge Blowdown Tank 45-319 Tenperature Gauge Temperature Instruments TIC-701 TIC-702 TRC-703 TR-704 TSH-704 TSL-704 TI-705 TIRC-706 TAH-706 TIRC-707 TAH-707 TIRC-708 TAH-708 TIRC-709 TAH-709 TIRC-710 TIRC-711 TIRC-712 TIRC-713 TR-714 TAH-715 TIC-716 TIC-717 TIC-718 TAH-719 TAH-720 TW-721 TW-722 Hot Water Tank 45-748 Temperature Controller Hot Water Preheater 55-332 Discharge Temperature Controller Charge Water Temperature Controller Colloid Makeup Tank 45-751 Temperature Recorder Colloid Makeup Tank 45-751 High Temperature Switch Colloid Makeup Tank 45-751 Low Temperature Switch VCM Charge Temperature Indicator Reactor 45-741 Polymerization Temperature Controller Reactor 45-741 High Temperature Alarm Reactor 45-742 Polymerization Temperature Controller Reactor 45-742 High Temperature Alarm Reactor 45-743 Polymerization Tenperature Controller Reactor 45-743 High Temperature Alarm Reactor 45-744 Polymerization Temperature Controller Reactor 45-744 High Temperature Alarm Reactor 45-741 Steam Stripping Temperature Controller Reactor 45-742 Steam Stripping Temperature Controller Reactor 45-743 Steam Stripping Temperature Controller Reactor 45-744 Steam Stripping Ten^erature Controller Reactor Multipoint Temperature Recorder (For all Four Reactors) Recovery Compressors 72-903, 72-904, and 72-905 Discharge High Tenqperature Alarm Seal Water Cooler 55-335 Outlet Temperature Controller Seal Water Cooler 55-336 Outlet Temperature Controller Cleaning Solution Heater 55-339 Outlet Temperature Controller Seal Oil Pressure Units 95-299 or 95-300 Discharge High Temperature Alarm Initiator Injection Pot 45-750 High Temperature Alarm Cleaning Solution Heater 55-339 Steam Inlet Thermowell Cleaning Solution Heater 55-339 Solution Inlet Thermowell DTH 000097098 APPENDIX B INSTRUMENT LIST - CONTINUED Item No. Service Temperature Instruments (Continued) TW-723 TW-724 TW-725 TR-726 TW-727 TW-728 TW-729 TIC-730 TW-731 TW-732 TW-733 TW-734 Deleted Cleaning Solution Heater 55-339 Solution Outlet Thermowell VCM Charge Filters 64-718 and 64-742 Outlet Piping Thermowell Recovery System Multipoint Temperature Recorder Water Recirculation Cooler 55-334 Cooling Water Supply Thermowell Seal Water Cooler 55-335 Cooling Water Supply Thermowell Recovered VCM Condenser 55-337 Cooling Water Supply Thermowell Blowdown Tank 45-319 Temperature Controller Reactor 45-741 Cooling Water Return Thermowell Reactor 45-742 Cooling Water Return Thermowell Reactor 45-743 Cooling Water Return Thermowell Reactor 45-744 Cooling Water Return Thermowell DTH 000097099
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CUNY - The Graduate CenterColumbia University Mailman School of Public Health - Sociomedical Sciences