FORM 160.82-EG1 (408) Model CYK Compound Centrifugal Liquid Chillers Design Level G 700 Through 2400 TONS (2500 Through 8440 kW) Utilizing HFC-134a Table of Contents
FORM 160.82-EG1 (408) ..........................................................................................................................................1 Introduction..............................................................................................................................................................3 Mechanical Specifications ......................................................................................................................................5 Accessories and Modifications ............................................................................................................................ 11 Application Data ....................................................................................................................................................12 Overall Chiller Arrangement .................................................................................................................................21 Compact Nozzle Arrangements ...........................................................................................................................22 Marine Nozzle Arrangements ...............................................................................................................................28 Guide Specifications .............................................................................................................................................32 SI Metric Conversion .............................................................................................................................................38 NOMENCLATURE 2 JOHNSON CONTROLS Introduction
The YORK Compound YK Chiller is a design using two centrifugal compressors arranged in series to handle radiator-cooled, brine-chilling, and heat-pump applications at conditions outside the range of typical centrifugal chillers. These custom units use HFC-134a refrigerant and are available in a wide range of capacities: · For air-cooled applications, (air-cooled radiators) 700 to 2,400 tons at 45°F LWT and up to 155°F LCWT (2,500 to 8,440 kWR at 7°C LWT and up to 68.3°C LCWT). · For brine chilling, 400 to 2,000 tons at 20°F LBT and 95°F LCWT (1,410 to 7,030 kWR at -7°C LBT and 35°C LCWT). Brine temperatures as low as 0°F (-17.8°C) can be achieved. · For heat pump applications, 11,000 to 40,000 MBH (3,200 to 11,700 kWR) heat rejection. STANDARD COMPONENTS Each compound chiller employs common parts instead of a one-of-a-kind design. The compressors and heat exchangers use standard technology proven in the successful YORK packaged chiller line. Each compressor is driven by a standard, open-drive electric motor. COMPACT FOOTPRINT Compressors and motors are mounted above the shells to assure the smallest footprint for this type of chiller. GREATER ADAPTABILITY With the compound chiller, the impeller diameter, width and speed can be optimized for each stage of compression based on operating conditions. SUPERIOR PART-LOAD PERFORMANCE Using a compound arrangement allows the use of pre-rotation-vane (PRV) capacity control for the centrifugal impellers of both compressors. Pre-rotation vanes act like a throttle on the suction side of the compressor to control compressor load. With PRV control on both compressors, the result is better part-load performance than for typical multistage compressors. HANDLES VARYING CONDENSING CONDITIONS Since chillers most often operate at off-design conditions, off-design performance is a major factor in the energy saving equation. A compound chiller can operate with a wider range of condensing water temperatures than typical chillers. The compound unit allows one compressor to be shut off, so the chiller can run on just one compressor during low head conditions. This practice not only ensures system stability, it allows the chiller to run more efficiently and takes advantage of cooling water temperatures well below design.
JOHNSON CONTROLS FORM 160.82-EG1 (408) LOWER INRUSH CURRENT Instead of starting a single, large motor, the compound chiller stagger-starts the motors in sequence. Consequently, peak inrush current is reduced to about 58% compared to starting a motor for a single large compressor. LOWER SOUND LEVELS Acoustically, with compound compressors sharing the workload, compressor RPMs are lower than in standard centrifugal designs -- and lower RPMs help lower sound levels. GRAPHIC CONTROL A powerful, graphic control panel makes chiller operation easy. Startup is handled by a push of the button; there is no need for manual intervention in the staggered-start sequence of the compressors. A color graphical operator interface means operating parameters, set-points and alarms are clearly visible, ensuring proper reading and response. FLASH ECONOMIzER (INTERCOOLER) The Compound YK Chiller includes a flash economizer (intercooler) that results in better efficiency during two stage operation. The Compound YK can be purchased without the economizer but the efficiency will be lower. OPEN DRIVE DESIGN Hermetic-motor burnout can cause catastrophic damage to a chiller. The entire chiller must be cleaned, and the refrigerant replaced. YORK centrifugal chillers eliminate this risk by using air-cooled motors. Refrigerant never comes in contact with the motor, preventing contamination of the rest of the chiller. Insurance companies that offer policies on large air conditioning equipment often consider air-cooled motors a significant advantage over hermetic refrigerant-cooled units. HIGH-EFFICIENCY HEAT EXCHANGERS The chiller heat exchangers offer the latest technology in heat transfer surface design to give you maximum efficiency and compact design. Waterside and refrigerant-side design enhancements minimize both energy consumption and tube fouling. SINGLE-STAGE COMPRESSOR DESIGN AND EFFICIENCY PROVEN IN THE MOST DEMANDING APPLICATIONS Designed to be the most reliable chillers we've ever made, YORK centrifugal chillers incorporate singlestage compressor design. With fewer moving parts and straightforward, efficient engineering, YORK single-stage 3 Introduction - continued
compressors have proven durability records in hospitals, chemical plants, gas processing plants, the U.S. Navy, and in other applications where minimal downtime is a crucial concern. In thousands of installations worldwide, YORK single stage compressors are working to reduce energy costs. High strength aluminum-alloy compressor impellers feature backward-curved vanes for high efficiency. Airfoil shaped pre-rotation vanes minimize flow disruption for the most efficient part load performance. Precisely positioned and tightly fitted, they allow the compressor to unload smoothly from 100% to minimum load for excellent operation in all applications. PRECISION CONTROL OF COMPRESSOR OIL PRESSURE Using our expertise in variable speed drive technology and applications, Johnson Controls has moved beyond the fixed head and bypass approach of oil pressure control. The old approach only assures oil pressure at the outlet of the pump rather than at the compressor, and allows no adjustment during chiller operation. The Compound chillers feature two variable speed drive oil pumps, monitoring and providing the right amount of oil flow to each compressor on a continuous basis. This design also provides sophisticated electronic monitoring and protection of the oil pump electrical supply, ensuring long life and reliable operation of the oil pump motor. Variable speed drive technology reduces oil pump power consumption, running only at the speed required, rather than at full head with a pressure regulating bypass valve. FACTORY PACKAGING REDUCES FIELD LABOR COSTS YORK centrifugal chillers are designed to keep installation costs low. Where installation access is not a problem, the unit can be shipped completely or partially packaged, requiring minimal piping and wiring to complete the installation. The flash economizer (intercooler) ships separately for assembly to the chiller at time of installation. All piping between the economizer and the chiller is prefabricated so no welding is required for installation. TAKE ADVANTAGE OF COLDER COOLING TOWER WATER TEMPERATURES YORK centrifugal chillers have been designed to take full advantage of colder cooling tower water temperatures, which are naturally available during most operating hours. Considerable energy savings are available by letting tower water temperature drop, rather than artificially holding it above 75°F (23.9°C), Especially at low load, as some chillers require. HEAT PUMP The Compound YK is ideal for use in heat pump applications supplying up to 155°F (68.3°C) leaving condenser water temperature. In this application the CYK can provide Coefficients of performance over 4 times greater than water heaters. More information on heat pump applications can be found in Johnson Controls Form 160.00-PM31. COMPUTERIzED PERFORMANCE RATINGS Each chiller is custom-matched to meet the individual building load and energy requirements. Standard heat exchanger tube bundle sizes and pass arrangements, are available to provide the best possible match. It is not practical to provide tabulated performance for each combination, as the energy requirements at both full and part load vary significantly with each heat exchanger and pass arrangement. Computerized ratings are available through each Johnson Controls sales office. These ratings can be tailored to specific job requirements. 4 JOHNSON CONTROLS Mechanical Specifications
GENERAL The YORK CYK Compound Centrifugal Liquid Chillers are factory-packaged including the evaporator, condenser, compressor, motor, lubrication system, control center, and interconnecting unit piping and wiring. The flash economizer (intercooler) ships loose for assembly to the chiller at time of installation. All piping between the economizer and the chillers is prefabricated in the factory so no welding is required in the field. The initial charge of refrigerant and oil is supplied for each chiller. Actual shipping procedures will depend on a number of project-specific details. The services of a Johnson Controls factory-trained, field service representative are incurred to supervise or perform the final leak testing, charging, the initial start-up, and concurrent operator instructions. COMPRESSOR Each compressor is a single-stage centrifugal type powered by an open-drive electric motor. The casing is fully accessible with vertical circular joints and fabricated of close-grain cast iron. The complete operating assembly is removable from the compressor and scroll housing. The rotor assembly consists of a heat-treated alloy steel drive shaft and impeller shaft with a high strength, cast aluminum alloy, fully shrouded impeller. The impeller is designed for balanced thrust and is dynamically balanced and overspeed tested for smooth, vibration free operation. The insert-type journal and thrust bearings are fabricated of aluminum alloy and are precision bored and axially grooved. The specially engineered, single helical gears with crowned teeth are designed so that more than one tooth is in contact at all times to provide even distribution of compressor load and quiet operation. Gears are integrally assembled in the compressor rotor support and are film lubricated. Each gear is individually mounted in its own journal and thrust bearings to isolate it from impeller and motor forces. FLASH ECONOMIzER (INTERCOOLER) Single stage type, consisting of a vertical pressure vessel with internally mounted mesh eliminators and liquid spray pipe, an externally mounted (field installed) level transmitter located with a liquid level pipe assembly and an external control valve mounted in the liquid outlet to the evaporator. Refrigerant from the condenser, after expanding through the condenser subcooler level control valve, enters through the internal spray pipe, where flash gas is removed and channeled through the mesh eliminator,
JOHNSON CONTROLS FORM 160.82-EG1 (408) out the top and on to the high stage compressor section. The remaining liquid feeds out of the economizer through a liquid level control valve to the evaporator. Eight sight glasses are provided, two above and two below the mesh eliminators, two at the liquid spray pipe, and two in the liquid line leaving the economizer. A thermometer well if furnished for checking the liquid temperature. Connections are provided for the Johnson Controls furnished, field installed pressure transmitter and relief valve assemblies. Three support legs of structural steel tubing are provided with mounting brackets for spring type isolators. Refrigerant connections are as follows: high pressure liquid inlet, interstage flash gas top outlet, and low pressure liquid bottom outlet. CAPACITY CONTROL Pre-rotation vanes (PRV) in each compressor modulate chiller capacity from 100% to 15% of design for normal air conditioning applications. Operation is by an external, electric PRV actuator which automatically controls the vane position to maintain a constant leaving chilled liquid temperature (or leaving condenser temperature for a heat pump application). Rugged airfoil shaped cast manganese bronze vanes are precisely positioned by solid vane linkages connected to the electric actuator. Both compressors are normally operated to satisfy the evaporator load (or the condenser load in the case of a heat pump). Should the entering condensing water temperature drop below a preset temperature, a compressor will be taken off line. This allows the remaining compressor to continue operating more efficiently at low entering condensing water temperatures. OPTISOUNDTM CONTROL The YORK® OptiSoundTM Control is a patented combination of centrifugal-chiller hardware and software that reduces operational sound levels, expands the chiller operating range, and improves chiller performance. The OptiSound Control feature continuously monitors the characteristics of the compressor-discharge gas and optimizes the diffuser spacing to minimize gas-flow disruptions from the impeller. This innovative technology improves operating sound levels of the chiller an average of 7 dBA, and up to 13 dBA on the largest models. It can also reduce part-load sound levels below the full-load level. In addition, the OptiSound Control provides the benefit of an expanded operating range. It improves performance and reliability by minimizing diffuser gas stall at off-design operation, particularly conditions of very low load combined with little or no condenser-water relief. The elimination of the gas-stall condition can also result in improved chiller efficiency at off design conditions. 5 Mechanical Specifications - continued
Johnson Controls includes the OptiSound Control for all CYK chillers when it is available on the compressors used. It is not available on all compressors. LUBRICATION SYSTEM Lubrication oil is force-fed to all bearings, gears and rotating surfaces by a variable speed drive pump; which operates prior to startup, and continuously during operation and during coast-down. A gravity-fed oil reservoir is built into the top of each compressor to provide lubrication during coast-down in the event of a power failure. Dual oil reservoirs, separate from the compressors, contain the 2 HP submersible oil pumps and 1500 watt immersion-type oil heaters for each compressor. The oil heaters are thermostatically controlled to remove refrigerant from the oil. A water-cooled oil cooler is provided after each oil pump, with factory installed water piping terminating at the center on the condenser side of the unit. A thermostatically controlled bypass valve maintains the required oil temperature supply from each oil cooler to its compressor. Oil is filtered by externally mounted, 1/2 micron, replaceable cartridge oil filters, equipped with service valves. An automatic oil return system recovers any oil that may have migrated to the evaporator. Oil piping is completely factory installed. MOTOR DRIVELINE The compressor motors are open drip-proof, squirrel cage, induction type constructed to YORK design specifications. 60 hertz motors operate at 3570 rpm. 50 hertz motors operate at 2975 rpm. The open motor is provided with a D-flange, and is factory-mounted to a cast iron adapter mounted on the compressor. This unique design allows the motor to be rigidly coupled to the compressor to provide factory alignment of motor and compressor shafts. Motor drive shaft is directly connected to the compressor shaft with a flexible disc coupling. Coupling has all metal construction with no wearing parts to assure long life, and no lubrication requirements to provide low maintenance. A large, steel terminal box with gasketed front access cover is provided on each motor for field-connected conduit. There are six terminals (three for medium voltage) brought through the motor casing into the terminal box. Jumpers are furnished for three-lead types of starting. Motor terminal lugs are not furnished. HEAT EXCHANGERS Shells Evaporator and condenser shells are fabricated from rolled carbon steel plates with fusion welded seams. Carbon steel tube sheets, drilled and reamed to accommodate the tubes, are welded to the end of each shell. Intermediate tube supports are fabricated from carbon steel plates, drilled and reamed to eliminate sharp edges, and spaced no more than four feet apart. The refrigerant side of each shell is designed, tested, and stamped in accordance with ASME Boiler and Pressure Vessel Code, Section VIII ­ Division I, or other pressure vessel codes as appropriate. Tubes Heat exchanger tubes are state-of-the-art, high-efficiency, externally and internally enhanced type to provide optimum performance. Tubes in both the evaporator and condenser are 3/4" or 1" O.D. copper alloy and utilize the "skip-fin" design, providing a smooth internal and external surface at each intermediate tube support. This provides extra wall thickness (up to twice as thick) and non-work hardened copper at the support location, extending the life of the heat exchangers. Each tube is roller expanded into the tube sheets providing a leakproof seal, and is individually replaceable. Evaporator The evaporator is a shell and tube, flooded type heat exchanger. A distributor trough provides uniform distribution of refrigerant over the entire shell length to yield optimum heat transfer. Mesh eliminators or baffles are located above the tube bundle to prevent liquid refrigerant carryover into the compressor. A 1.5" (38mm) liquid level sight glass is conveniently located on the side of the shell to aid in determining proper refrigerant charge. The evaporator shell contains a dual refrigerant relief valve arrangement set to pressures up to 235 PSIG (1620 kPa). A 1" refrigerant charging valve is provided. Condenser The condenser is a shell and tube type, with discharge gas baffles to prevent direct high velocity impingement on the tubes. The baffles are also used to distribute the refrigerant gas flow properly for most efficient heat transfer. An integral sub-cooler is located at the bottom of the condenser shell providing highly effective liquid refrigerant sub-cooling to provide the highest cycle efficiency. The condenser contains dual refrigerant relief valves that can be set to pressures up to 350 PSIG (2413 kPa).
JOHNSON CONTROLS 6 FORM 160.82-EG1 (408) WATER BOXES The removable water boxes are fabricated of steel. The design working pressure is 150 PSIG (1034 kPa) and the boxes are tested at 225 PSIG (1551 kPa). Integral steel water baffles are located and welded within the water box to provide the required pass arrangements. Stub-out water nozzle connections with ANSI/AWWA C-606 grooves are welded to the water boxes. These nozzle connections are suitable for ANSI/AWWA C606 couplings, welding or flanges, and are capped for shipment. Plugged 3/4" drain and vent connections are provided in each water box. WATER FLOW SWITCHES Thermal type water flow switches are factory mounted in the chilled and condenser water nozzles, and are factory wired to the control panel. These solid state flow sensors have a small internal heating element. They use the cooling effect of the flowing fluid to sense when an adequate flow rate has been established. The sealed sensor probe is 316 stainless steel, which is suited to very high working pressures. zERO LOAD HOT GAS BYPASS Sized for operation to 0% evaporator load to prevent nuisance shutdowns due to low load conditions, and critical industrial and process applications. LOW INLET CONDENSER WATER CAPABILITY The CYK Compound chiller incorporates a control strategy that allows a compressor to shut down automatically when two-compressor operation is no longer required. This allows the chiller to take advantage of low-inlet condenser water temperatures to reduce energy consumption. CONTROL CENTER The chiller is controlled by a stand-alone PLC based control center. The chiller control center provides all the necessary controls and control logic to provide automatic start-up, automatic operation, capacity control and safety protection of the chiller. Control Panel The control panel includes a 10.4" color active matrix display with integral keypad for operator interface. The control panel is a factory wired, unit mounted, NEMA 12, gasketed enclosure. The panel is fabricated of 10 gauge steel and includes full height front access doors. The panel enclosure is painted to match the chiller color on the outside, and gloss white on interior surfaces. All controls are arranged for easy access and internally wired to clearly marked terminal strips or pre-wired PLC interface modules for external wiring connections. Wiring is color-coded black (control), white (neutral), and green (ground), with each wire numerically identified at both ends with heat shrinkable wire markers. Wiring enclosed in shielded cables and pre-wired cables are color coded per the wiring diagram. The screen details all operations and parameters, using a graphical representation of the chiller and its components. Graphic screens are provided for: a. Chiller Overview b. c. d. e. f. g. h. Evaporator Condenser Low stage compressor High stage compressor Motors Capacity control diagram Manual/Auto stations for all control outputs The operator interface is programmed to provide display of all major operating parameters in both graphical and list type screen displays. PID control loop set points, and Manual/Auto functions are also accomplished by the operator interface. Alarm indicators on the graphic display screen provide annunciation, and an alarm history screen is provided which shows the most recent alarms, with the time and date of occurrence. Trip status screens are provided which show the values of all analog inputs at the time of the last five chiller safety shutdowns. The time and date of the shutdown are also shown. Separate push buttons are provided on the face of the control panel for Chiller Start, Stop, Reset and Emergency Stop. Capacity Controls System The Capacity Control philosophy of the York CYK chiller control system allows efficient, fully automated control, without need for operator intervention. This control system also monitors and displays all safety aspects of the chiller and provides alarms and a shutdown if safety limits are exceeded. If operator intervention is required, manual controls are provided on the electronic operator interface, for all electric actuators. JOHNSON CONTROLS 7 Mechanical Specifications - continued
The capacity controls algorithm automatically seeks out the most efficient operation of the CYK chiller. The prerotation vanes are automated to obey the temperature controller to maintain chilled water production. In cases of low load, the pre-rotation vanes automatically throttle and are limited to a minimum anti-surge position. To provide light duty operation, the hot gas recycle valve is seamlessly throttled open according to temperature demands. This keeps the centrifugal compressor out of surge and maintains chilled water production. In cases of high load, which exceeds the motor kilowatt (or current) usage, the capacity controls algorithm automatically unloads the system to maintain a restriction on power consumption. In the same way, conditions of high discharge pressure or low suction pressure override the production of chilled water in the interests of keeping the chiller system online. In cases of light load and low head, the high compressor is dropped offline, the intercooler (if provided) bypassed, and the unit will be run with the low stage compressor like a normal single compressor chiller. Analog Input List: 1. Low Stage Motor Current (% FLA) 2. High Stage Motor Current (% FLA) 3. Sub-cooler Refrigerant Liquid Level 4. Low Stage Oil Reservoir Oil Level (Brine Units) 5. High Stage Oil Reservoir Oil Level (Brine Units) 6. Evaporator Refrigerant Pressure 7. Condenser Refrigerant Pressure 8. Low Stage Compressor Low Oil Pressure 9. High Stage Compressor Low Oil Pressure 10. Low Stage Compressor High Oil Pressure 11. High Stage Compressor High Oil Pressure 12. Chilled Water-Out Temperature. 13. Chilled Water-In Temperature. 14. Condenser Water In Temperature 15. Condenser Water Out Temperature 16. Evaporator Refrigerant Liquid Temp. 17. Low Stage Compressor Refrigerant Discharge Temperature 18. High Stage Compressor Refrigerant Discharge Temperature 19. Sub-cooled Refrigerant Liquid Temperature 20. Low Stage Compressor Oil Temperature 21. High Stage Compressor Oil Temperature 22. Low Stage PRV Position 23. High Stage PRV Position 8 24. Low Stage Compressor high stage thrust Bearing Probe Gap 25. High Stage Compressor thrust bearing Probe gap 26. Flash Economizer Pressure Digital Inputs: 1 . Chilled Water Low Flow Switch 2. Condenser Water Low Flow Switch 3. Low Stage Motor Starter Full Voltage (Run) Auxiliary Contact 4. High Stage Motor Starter Full Voltage (Run) Auxiliary Contact 5. Low Stage Motor Starter Safety Fault Lockout Relay 6. High Stage Motor Starter Safety Fault Lockout Relay 7. Condenser Refrigerant High Pressure Cutout 8. Low Stage Compressor Oil Heater Thermostat 9. High Stage Compressor Oil Heater Thermostat 10. Low Stage PRV Closed Limit Switch 11. High Stage PRV Closed Limit Switch 12. Low Stage Compressor V.S. Oil Pump Drive Faulted Contact 13. High Stage Compressor V.S. Oil Pump Drive Faulted Contact 14. Chiller Start 15. Chiller Stop 16. System Reset 17. Emergency Stop Analog Output List 1. Hot Gas Bypass Valve 2. Low Stage Compressor, V.S. Oil Pump Drive Control 3. High Stage Compressor, V.S. Oil Pump Drive Control 4. Variable Orifice Valve 5. Inter-stage Valve 6. Bypass Level Control valve output LCV-117 Digital Output List 1. Low Stage Liquid Line Solenoid Valve 2. High Stage Liquid Line Solenoid Valve 3. High Stage Oil Return Solenoid JOHNSON CONTROLS FORM 160.82-EG1 (408) Digital Output List - cont'd 4. 5. 6. 7. Low Stage Oil Return Solenoid Valve Low Stage Compressor Oil Heater Contactor High Stage Compressor Oil Heater Contactor Low Stage Compressor Motor Start/Stop Control Relay 8. High Stage Compressor Motor Start/Stop Control Relay 9. Low Stage Compressor Oil Pump Start/Stop Relay Available Network Protocols
Media Cat-5 twisted pair RS-232 RS-232 Protocol Ethernet Industrial Protocol www.ethernet-ip.org Allen-Bradley DF1 Full Duplex Modbus RTU Slave Any protocol/media requirements not listed here must be called out on the factory order form. Available protocols will be implemented with a Johnson Controls eLink module* or Prolinx gateway** where applicable: · · · · · · · · Modbus RTU over RS-485** Modbus over TCP/IP** BACnet MS/TP* BACnet/IP* LONworks* Profibus** ControlNet Allen-Bradley DH-485 Check appropriate protocol and include this document attached to the Factory Order Form. All communication interface wiring and hardware, which is required external to the chiller control panel, will be supplied and installed by the electrical installation contractor under another contract. CODES AND STANDARDS · ASME Boiler and Pressure Vessel Code ­ Section Vlll Division 1. · ARI Standard 550/590 (When applicable) · ASHRAE 15 ­ Safety Code for Mechanical Refrigeration · ASHRAE Guideline 3 ­ Reducing Emission of Halogenated Refrigerants in Refrigeration and AirConditioning Equipment and Systems · N.E.C. ­ National Electrical Code · OSHA ­ Occupational Safety and Health Act ISOLATION MOUNTING The unit is provided with four vibration isolation mounts consisting of 1" (25.4 mm) thick neoprene isolation pads for field mounting under the steel mounting pads located on the tube sheets and three pads for the flash economizer (intercooler). 10. High Stage Compressor Oil Pump Start/Stop Relay 11. Oil Level Control Pump Start/Stop Relay 12. Start-up Bypass Valve Open/Close Relay 13. Open Low Stage PRV 14. Open High Stage PRV 15. Close Low Stage PRV 16. Close High Stage PRV Security Security access to prevent unauthorized change of setpoints, to allow local or remote control of the chiller, and to allow manual operation of the pre-rotation vanes and oil pump. Access is through ID and password recognition, which is defined by three different levels of user competence: operator, service and programming. Over-Current Protection A fused connection through a transformer on the Variable Speed Oil Pump Panel to provide individual overcurrent protected power for all controls. PLANT MANAGEMENT/CONTROL SYSTEM INTERFACE: Ethernet I/P (Ethernet Industrial Protocol) is the preferred LAN (Local Area Network) between Local Chiller Control Panels. Ethernet I/P allows full management of the Allen-Bradley system from a central location. All required analog and discrete data for communications will be arranged in blocks of IEEE Floating Point and 16-bit words within the Logix processor's data tables. All data is available remotely as read only values. The following write-able control signals are available. Remote Start, Remote Stop, Remote Leaving Chilled Water Setpoint, and Remote Demand Limit Setpoint. JOHNSON CONTROLS Mechanical Specifications - continued
REFRIGERANT CONTAINMENT The standard unit has been designed as a complete and compact factory-packaged chiller except for the flash economizer. The piping between the economizer and the main chiller is all prefabricated in the factory with strategically placed flanges. No field welding is necessary to attach the economizer. As such, it has minimum joints from which refrigerant can leak. The entire assembly has been thoroughly leak tested at the factory prior to shipment. The YORK chiller includes service valves, conveniently located to facilitate transfer of refrigerant to a remote refrigerant storage/recycling system. PAINT Exterior surfaces are protected with one coat of Caribbean blue, durable alkyd-modified, vinyl enamel, machinery paint. SHIPMENT Protective covering is furnished on the motor, Control Center and unit-mounted controls. Water nozzles are capped with fitted plastic enclosures. Entire unit is protected with industrial-grade, reinforced shrink-wrapped covering. The flash economizer (intercooler) is removed for shipment. Flanged joints are provided and all piping is prefabricated. 10 JOHNSON CONTROLS Accessories and Modifications
BAS REMOTE CONTROL Alternate network mediums and protocols may be accomplished with the addition of a protocol translator gateway. These include: Modbus TCP/IP, Profibus, DNP, Remote I/0 and ASCII. Contact the factory for more information. FACTORY INSULATION Factory-applied thermal insulation of the flexible, closed-cell plastic type, 3/4" (19 mm) thick is attached with vapor-proof cement to the evaporator shell, tube sheets, suction connection, and (as necessary) to the auxiliary tubing. The flash economizer (intercooler) may require factory insulation for some operating conditions. For all other projects, optional factory insulation on the economizer is available upon request. Not included is the insulation of compact water boxes and nozzles. This insulation will normally prevent condensation in environments with relative humidities up to 75% and dry bulb temperatures ranging from 50° to 90°F (10° to 32.2°C). 1-1/2" (38 mm) thick insulation is also available for relative humidities up to 90% and dry bulb temperatures ranging from 50° to 90°F (10° to 32.2°C). For heat pump applications the condenser can be ordered with optional factory insulation to minimize heat loss to the atmosphere. WATER FLANGES Four 150 lb. ANSI raised-face flanges for condenser and evaporator water connections, are factory-welded to water nozzles. Companion flanges, bolts, nuts and gaskets are not included. SPRING ISOLATION MOUNTING Spring isolation mounting is available instead of standard isolation mounting pads when desired. Seven vertically restrained level-adjusting, spring-type vibration isolator assemblies with non-skid pads are provided for field-installation. Isolators are designed for one-inch (25 mm) deflection. STARTER ­ FIELD-INSTALLED Field installed, compressor motor starter assemblies are available, selected for proper size and type for job requirements and in accordance with Johnson Controls Engineering Standard (R-1151) for Starters. The starter assemblies have contactors and accessories for controlling the two compressor motors per chiller. MARINE WATER BOXES Marine water boxes allow service access for cleaning of the heat exchanger tubes without the need to break the water piping. Bolted-on covers are arranged for convenient access. ANSI/AWWA C-606 nozzle connections are standard; flanges are optional. Marine water boxes are available for condenser and/or evaporator. Hinged water boxes are available upon request.
JOHNSON CONTROLS FORM 160.82-EG1 (408) KNOCK-DOWN SHIPMENT The chiller can be shipped knocked down into major subassemblies (evaporator, condenser, driveline, etc.) as required to rig into tight spaces. This is particularly convenient for existing buildings where equipment room access does not allow rigging a factory-packaged chiller. REFRIGERANT STORAGE/RECYCLING SYSTEM A refrigerant storage/recycling system is a self-contained package consisting of a refrigerant compressor with oil separator, storage receiver, water-cooled condenser, filter drier and necessary valves and hoses to remove, replace and distill refrigerant. All necessary controls and safety devices are a permanent part of the system. HIGH VOLTAGE MOTORS High voltage induction motors (11 kV to 13.8 kV), special motor enclosures such as TEWAC or WPII, may be substituted. TUBE AND/OR TUBE SHEET MATERIALS AND/OR WATER BOX COATING For condenser and/or evaporator for protection against aggressive water conditions. Alternate cupro-nickel or titanium tubes can be provided in lieu of standard copper. Tube sheets may be of the clad type. Epoxy coating may be applied to water boxes or to tubesheet and water boxes. SACRIFICIAL zINC ANODES With mounting hardware for condenser and/or evaporator corrosion protection. HIGHER WATER CIRCUIT DWP Condenser and/or evaporator water circuit(s) DWP higher than the standard 150 PSIG (1034 kPa) DWP. OUTDOOR AND/OR APPLICATIONS HAzARDOUS DUTY Necessary unit, control and control center modifications for Outdoor (NEMA-3 & 4) application in lieu of standard NEMA-1 construction. Suitable alternate surface preparation and protective coating systems also available. FIELD PERFORMANCE TEST Services of a factory engineer or independent consultant to supervise a field performance test. Various levels of instrumentation can be offered by Johnson Controls. 11 Application Data
The following discussion is a user's guide in the application and installation of CYK chillers to ensure the reliable, trouble-free life for which this equipment was designed. While this guide is directed towards normal, water-chilling applications, the Johnson Controls sales representative can provide complete recommendations on other types of applications. LOCATION CYK chillers are virtually vibration free and may generally be located at any level in a building where the construction will support the total system operating weight. The unit site must be a floor, mounting pad or foundation which is level within 1/4" (6.4 mm) and capable of supporting the operating weight of the unit. Sufficient clearance to permit normal service and maintenance work should be provided all around and above the unit. Additional space should be provided at one end of the unit to permit cleaning of evaporator and condenser tubes as required. A doorway or other properly located opening may be used. The chiller should be installed in an indoor location where temperatures range from 40°F to 104°F (4.4°C to 40°C). WATER CIRCUITS Flow Rate ­ For normal water chilling duty, evaporator and condenser flow rates are permitted at water velocity levels in the heat exchangers tubes of between 3.0 ft/sec (3.3 for condensers) and 12 ft/sec (0.91 m/s and 3.66 m/s). Variable flow applications are possible, and initial chiller selections should be made accordingly to allow proper range of flow while maintaining the minimum velocity noted above. Variable flow in the condenser is not recommended, as it generally raises the energy consumption of the system by keeping the condenser pressure high in the chiller. Additionally, the rate of fouling in the condenser will increase at lower water velocities associated with variable flow, raising system maintenance costs. Cooling towers typically have narrow ranges of operation with respect to flow rates, and will be more effective with full design flow. Contact Johnson Controls Sales for specific flow limits. Water Quality ­ The practical and economical application of liquid chillers requires that the quality of the water supply for the condenser and evaporator be analyzed by a water treatment specialist. Water quality may affect the performance of any chiller through corrosion, deposition of heat-resistant scale, sedimentation or organic growth. These will degrade chiller performance and increase operating and maintenance costs. Normally, performance may be maintained by corrective water treatment and periodic cleaning of tubes. If water conditions exist which cannot be corrected by proper water treatment, it may be necessary to provide a larger allowance for fouling, and/or to specify special materials of construction. General Piping ­ All chilled water and condenser water piping should be designed and installed in accordance with accepted piping practice. Chilled water and condenser water pumps should be located to discharge through the chiller to assure positive pressure and flow through the unit. Piping should include offsets to provide flexibility and should be arranged to prevent drainage of water from the evaporator and condenser when the pumps are shut off. Piping should be adequately supported and braced independently of the chiller to avoid the imposition of strain on chiller components. Hangers must allow for alignment of the pipe. Isolators in the piping and in the hangers are highly desirable in achieving sound and vibration control. Convenience Considerations ­ To facilitate the performance of routine maintenance work, some or all of the following steps may be taken by the purchaser. Evaporator and condenser water boxes are equipped with plugged vent and drain connections. If desired, vent and drain valves may be installed with or without piping to an open drain. Pressure gauges with stop cocks and stop valves may be installed in the inlets and outlets of the condenser and chilled water line as close as possible to the chiller. An overhead monorail or beam may be used to facilitate servicing. Connections ­ The standard chiller is designed for 150 PSIG (1034 kPA) design working pressure in both the chilled water and condenser water circuits. The connections (water nozzles) to these circuits are furnished with grooves for ANSI/AWWA C-606 couplings. Piping should be arranged for ease of disassembly at the unit for tube cleaning. All water piping should be thoroughly cleaned of all dirt and debris before final connections are made to the chiller. Condenser Water Strainer ­ A water strainer of maximum 1/8" (3mm) perforated holes is recommended to be field installed in the refrigerant condenser water inlet line as close as possible to the chiller. If located close enough to the chiller, the condensate water pump may be protected by the same strainer. The loss or severe reduction of water flow due to blockage could seriously impair the chiller's performance. 12 JOHNSON CONTROLS FORM 160.82-EG1 (408) INTENTIONALLY LEFT BLANK JOHNSON CONTROLS 13 Application Data - continued
MULTIPLE UNITS Selection ­ Many applications require multiple units to meet the total capacity requirements as well as to provide flexibility and some degree of protection against equipment shutdown. There are several common unit arrangements for this type of application. The CYK chiller has been designed to be readily adapted to the requirements of these various arrangements. Parallel Arrangement (Refer to Fig. 1) ­ Chillers may be applied in multiples with chilled and condenser water circuits connected in parallel between the units. Fig. 1 represents a parallel arrangement with two chillers. Parallel chiller arrangements may consist of equally or unequally sized units. When multiple units are in operation, they will load and unload at equal percentages of design full load for the chiller. Depending on the number of units and operating characteristics of the units, loading and unloading schemes should be designed to optimize the overall efficiency of the chiller plant. It is recommended to use an evaporator by-pass piping arrangement to bypass fluid around evaporator of any unit which has cycled off at reduced load conditions. It is also recommended to alternate the chiller cycling order to equalize chiller starts and run hours. Series Arrangement (Refer to Fig. 2) ­ Chillers may be applied in pairs with chilled water circuits connected in series and condenser water circuits connected in parallel. All of the chilled water flows through both evaporators with each unit handling approximately one-half of the total load. When the load decreases to a customer selected load value, one of the units will be shut down by a sequence control. Since all water is flowing through the operating unit, that unit will cool the water to the desired temperature. REFRIGERANT RELIEF PIPING Each chiller is equipped with dual pressure relief valves on the condenser, dual relief valves on the evaporator and dual relief valves on the flash economizer (intercooler). The dual relief valves are redundant and allow changing of either valve while the unit is fully charged. The purpose of the relief valves is to quickly relieve excess pressure of the refrigerant charge to the atmosphere, as a safety precaution in the event of an emergency such as fire. They are set to relieve at an internal pressure as noted on the pressure vessel data plate, and are provided in accordance with ASHRAE 15 safety code and ASME or applicable pressure vessel code. Sized to the requirements of applicable codes, a vent line must run from the relief device to the outside of the building. This refrigerant relief piping must include a cleanable, vertical-leg dirt trap to catch vent-stack condensation. Vent piping must be arranged to avoid imposing a strain on the relief connection and should include one flexible connection. COND 1 T EVAP 2 S1 COND 2 S2 EVAP 2 S ­ Temperature Sensor for Chiller Capacity Control T ­ Thermostat for Chiller Capacity Control FIG. 1 ­ PARALLEL EVAPORATORS PARALLEL CONDENSERS 14 FIG. 2 ­ SERIES EVAPORATORS PARALLEL CONDENSERS
JOHNSON CONTROLS FORM 160.82-EG1 (408) SOUND AND VIBRATION CONSIDERATIONS A YORK CYK chiller is not a source of objectionable sound and vibration in normal air conditioning applications. Neoprene isolation mounts are furnished as standard with each unit. Optional level-adjusting spring isolator assemblies designed for 1" (25 mm) static deflection are available from Johnson Controls. YORK CYK chiller sound pressure level ratings will be furnished on request. Control of sound and vibration transmission must be taken into account in the equipment room construction as well as in the selection and installation of the equipment. THERMAL INSULATION No appreciable operating economy can be achieved by thermally insulating the chiller. However, the chiller's cold surfaces should be insulated with a vapor barrier insulation sufficient to prevent condensation. A chiller can be factory insulated with 3/4" (19 mm) or 1-1/2" (38 mm) thick insulation, as an option. This insulation will normally prevent condensation in environments with dry bulb temperatures of 50°F to 90°F (10°C to 32°C) and relative humidities up to 75% [3/4" (19 mm) thickness] or 90% [1-1/2" (38 mm) thickness]. The insulation is painted and the surface is flexible and reasonably resistant to wear. It is intended for a chiller installed indoors and, therefore, no protective covering of the insulation is usually required. If insulation is applied to the water boxes at the jobsite, it must be removable to permit access to the tubes for routine maintenance. For heat pump applications the condenser can be ordered with optional factory insulation to minimize heat loss to the atmosphere. VENTILATION The ASHRAE Standard 15 Safety Code for Mechanical Refrigeration requires that all machinery rooms be vented to the outdoors using mechanical ventilation by one or more power-driven fans. This standard, plus National Fire Protection Association Standard 90A, state, local and any other related codes should be reviewed for specific requirements. Since the CYK chiller motor is air-cooled, ventilation should allow for the removal of heat from the motor. In addition, the ASHRAE Standard 15 requires a refrigerant vapor detector to be employed for all refrigerants. It is to be located in an area where refrigerant from a leak would be likely to concentrate. An alarm is to be activated and the mechanical ventilation started at a value no greater than the TLV (Threshold Limit Value) of the refrigerant. ELECTRICAL CONSIDERATIONS Motor Voltage ­ Low voltage motors (200 to 600 volts) are furnished with six leads. Medium voltage (2300 to 4160 volts) motors have three leads. Motor circuit conductor size must be in accordance with the National Electrical Code (NEC), or other applicable codes, for the motor full load amperes (FLA). Flexible conduit should be used for the last several feet to the chiller in order to provide vibration isolation. Table 2 lists the allowable variation in voltage supplied to the chiller motor. The unit name plate is stamped with the specific motor voltage, and frequency for the appropriate motor. TABLE 2 ­ MOTOR VOLTAGE VARIATIONS
FREQ. RATED VOLTAGE 200 230 380 416 60 HZ 460 575 2300 3300 4000 346 50 HZ 380 415 3300 NAMEPLATE VOLTAGE 200/208 220/240 380 416 440/460/480 575/600 2300 3300 4000/4160 346 380/400 415 3300 MIN. 180 208 342 375 414 520 2,070 2,970 3,600 311 342 374 2,970 OPERATING VOLTAGE MAX. 220 254 415 457 508 635 2,530 3,630 4,576 381 423 440 3,630 JOHNSON CONTROLS 15 Application Data - continued
Starters ­ Electro-mechanical starters must be furnished in accordance with Johnson Controls Standard Specifications (R-1151). This will ensure that starter components, controls, circuits, and terminal markings will be suitable for required overall system performance. Oil Pump Power Supply ­ A separate 3-phase power supply with a fused disconnect for the factory mounted oil pump variable speed drive is required. Power can also be supplied through an electro-mechanical starter. A 115 volt, single phase, control power transformer is provided in the oil pump drive panel to provide power to the Chiller Control Panel. The variable speed drive oil pump can be selected for the following voltages:
AVAILABLE 3 PHASE VOLTAGES Frequency VOLTAGE 200 208 220 230 240 380 60 416 440 460 480 550** 575** 600** 346 220 50 440 380 400 415 **These voltages require a stepdown transformer to 480 Volts (by others). starter. The capacitors must be sized and installed to meet the National Electrical Code and be verified by Johnson Controls. Ampacity on Load Side of Starter ­ Electrical power wire size to the chiller is based on the minimum unit ampacity. For remote starters, the National Electrical Code defines the calculation of ampacity, as summarized below. More specific information on actual amperage ratings will be supplied with the submittal drawings. · Six-lead type of starting (Star-Delta) Minimum circuit ampacity per conductor (1 of 6): Ampacity = .721 x compressor motor amps. · Three-lead type of starting (Across-the-Line, Autotransformer and Primary Reactor) Minimum circuit ampacity per