Trane RAUC-C50, RAUC-C30, RAUC-C60 manual System Start-Up, Chilled Water Temperature Controller 6U11

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System Start-Up

Figure 41. W7100A Staging Sequence

Chilled Water Temperature Controller (6U11)

The chilled water temperature controller used with EVP chiller applications is a Honeywell W7100G. This microprocessor controller is designed to maintain an average leaving water temperature using an integrating control band concept that matches the required operating capacity to the chiller load. The integral action, unlike “proportional only” type controllers, minimizes the amount of offset from the control setpoint.

The control band setting is centered on the leaving water setpoint. It is adjustable from 0ºF to 10ºF [0ºC to 6ºC] and is used to stabilize system operation.

The control algorithm used by the W7100G to add stages of cooling is illustrated in Figure 42. As the water temperature rises above the upper control band limit, a stage of mechanical cooling is added, provided the minimum “Off” time has been satisfied (Point A). The minimum “fast response” time and the time delay between staging for the W7100G is set for 60 seconds.

If the water temperature remains above the upper control band limit (Point B), the next available stage of cooling will be energized when the minimum time delay between stages has elapsed.

As the water temperature decreases below the lower control band, the last stage that was turned “On” will be cycled “Off” (Point C) when the minimum “On” time for that stage has elapsed.

As the load on the water increases due to cooling stages being cycled “Off”, the controller will maintain it’s current position, i.e., no staging of cooling “On” or “Off”, as long as the temperature remains inside the control band.

When the temperature increases above the upper control band limit (Point D), mechanical cooling stages will be sequenced “On” in the same manner as before. As a rule, any time the water temperature is above the upper control band limit, a stage of cooling will be “added” and anytime the water temperature decreases below the lower control band limit, a stage of cooling will be “Subtracted”.

Thermostatic Expansion Valve

The reliability and performance of the refrigeration system is heavily dependent upon proper expansion valve adjustment. Therefore, the importance of maintaining the proper superheat cannot be over emphasized. Accurate measurements of superheat will provide the following information.

1.How well the expansion valve is controlling the refrigerant flow.

2.The efficiency of the evaporator coil.

3.The amount of protection the compressor is receiving against flooding or overheating.

The recommended range for superheat is 10 to 16 degrees at the evaporator. Systems operating with less than 10 degrees of superheat:

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Contents Remote Split System Units JuneGrounding Required Environmental ConcernsResponsible Refrigerant Practices Overview of ManualTable of Contents SS-SVX09A-EN Model Number Description Unit NameplateCompressor Nameplate Unit Description Unit Inspection No Step SurfaceUnit Clearances EVP Chiller ConsiderationsUnit Dimensions & Weight Information InstallationFoundation Installation RAUC-C20 Unit Dimensional Data & Recommended Clearances RAUC-C25 Unit Dimensional Data & Recommended Clearances RAUC-C30 Unit Dimensional Data & Recommended Clearances RAUC-C40 Unit Dimensional Data & Recommended Clearances RAUC-C50 Unit Dimensional Data & Recommended Clearances RAUC-C60 Unit Dimensional Data & Recommended Clearances Bphe 20 Evaporator Chiller Dimensions Bphe 25 Evaporator Chiller Dimensions Bphe 30 Evaporator Chiller Dimensions Bphe 40 Evaporator Chiller Dimensions Bphe 50 Evaporator Chiller Dimensions Bphe 60 Evaporator Chiller Dimensions Typical Unit Weights & Point Loading Data Typical EVP Chiller Weights & General DataRigging Heavy Objects Rigging and Center-of-Gravity DataUnit Isolation Neoprene IsolatorsTypical Neoprene Isolator Selection & Location Installation Spring Isolators Leveling the UnitShipping Fasteners Compressor Shipping HardwareTwo Manifolded Compressors Typical Spring Isolator Selection & LocationGeneral Unit Requirements Refrigerant Piping RequirementsMain Electrical Power Requirements Hazardous Voltage Hazard of ExplosionEVP Chilled Water Piping Requirements Ground Wire Field Installed Control Wiring RequirementsVolt Control Wiring All Units No Controls UnitsEVP Chiller Piping Low Voltage Wiring AC & DC Hazardous Voltage Variable Air Volume VAV UnitsConstant Volume Units Refrigerant Line ComponentsLiquid Line Moisture Indicator Sight Glass Access Valves PortsLiquid Line Solenoid Valves Thermostatic Expansion Valve TEVSolenoid Valve & Sight Glass w/Moisture Indicator Typical Placement of Split System piping ComponentsSuction Line Interconnecting Tubing Refrigerant PipingSuction Line Piping Use Type L refrigerant grade copper tubing onlyLiquid Line Interconnecting Tubing Liquid Line PipingEvaporator Piping Typical Coil Piping For Dual Circuit UnitsHot Gas Bypass for Commercial Comfort-Cooling Applications Optional Pressure GaugesFinal Refrigerant Pipe Connections Brazing Procedures Hazard of Explosion and Deadly Gases Leak Testing Procedure Hazard of Explosion Chilled Water Piping Evaporator Water-Pressure Drop Installation Air Vents Chiller Flow SwitchWater Temperature Sensor Water Pressure GaugesFreezestat Typical Piping RecommendationsOptional Flow Switch Illustration Final Water Piping ConnectionsField Installed Power Wiring Disconnect Switch External Handle Factory Mounted OptionMain Unit Power Wiring Hazardous Voltage Power Wire Sizing and Protection Device Customer Connection Wire RangeEquations Calculation #1 MCA, MOP, and RDEInstallation Calculation #2 Disconnect Switch Sizing DSS Electrical Service Sizing DataField Installed Control Wiring Hazardous Voltage Controls Using 115 VAC Hazardous VoltageEVP Interlocks EVP Flow control 6S58 EVP Circulating Pump InterlockOutside Air Thermostat 5S57 Hot Gas Bypass All control optionsControls using 24 VAC Hazardous Voltage Controls using DC Analog Input/Outputs Hazardous VoltageAC Conductors Economizer Actuator Circuit DC ConductorsTemperature Control Parameters No System ControlEconomizer Actuator Circuit Legend Refer to Wiring Notes on p Installation Variable Air Volume Control Honeywell W7100A Discharge Air Sensor Honeywell 6RT3Suction Line Thermostat Night Setback Hazardous VoltageEVP Chiller Control W7100G Discharge Chilled Water Controller Chilled Water Temperature Sensor Honeywell 6RT2 EVP Chiller Remote PanelOutside Air Thermostat 5S57 Field Provided Refer to Wiring Notes on Page p Constant Volume Control Honeywell Thermostat WiringElectronic Zone Thermostat Honeywell T7067 Thermostat CheckoutT7067 Electronic Zone Thermostat & Q667 Switching Subbase Q667 Switching Subbase Discharge Air Sensor Honeywell 6RT1Refer to Wiring Notes on Page p RT1 Discharge Air Sensor Assembly Compressor Damage EVP Chiller ApplicationsSystem Evacuation Procedures System Pre-Start ProceduresSystem Pre-Start Procedures Standing Vacuum Test Typical Vacuum Pump HookupEvacuation Time vs. Pressure Rise System Pre-Start Procedures W7100A Discharge Air Controller Economizer Actuator Checkout Zone or Discharge Air Temp ControllerOhms 4200 4000 3800 System Pre-Start Procedures W7100G Chilled Water Controller Master Energy Control Checkout Hazardous Voltage Zone Thermostat Checkout Honeywell T7067 Zone Thermostat 6U37 Voltage Output ramps TerminalsOhms Voltage Imbalance Electrical PhasingSequence of Operation VAV W7100A Discharge Air Controller 7U11Economizer Cycle Chilled Water Temperature Controller 6U11 System Start-UpThermostatic Expansion Valve Condenser Fans W7100G Staging SequenceLow Ambient Dampers Compressor Crankcase HeatersPump Down Low Ambient Damper Adjustment Factory or Field Installed Live Electrical ComponentsSystem Start-Up Low Ambient Thermostats Hot Gas Bypass OperationFreezestat Setting EVP Chiller Applications200 300 Air Over Evaporator Application Rotating ComponentsSystem Airflow Measurement Verifying Proper Supply Fan RotationCompressor Start-Up All Systems Compressor Damage Live Electrical Components Subcooling Measuring SubcoolingMeasuring Superheat Pressure Control Switch Settings Minimum starting Ambient TemperatureCompressor Oil Recommended Refrigerant CapacitiesCompressor Sequence Typical Compressor Locations Ton Pressure Curve System Start-Up System Start-Up Ton Pressure Curve per Circuit 100 101 Final System Setup Recommended Operating SetpointsSample Maintenance Log Scroll Compressor Replacement Compressor Operational SoundsAt Shutdown At Low Ambient Start-UpService & Maintenance Compressor Circuit Breaker DataFuse Replacement Data Monthly MaintenanceFuse Replacement Data Air Handling EquipmentCoil Cleaning Condensing UnitHazardous Pressures System operationWarranty and Liability Clause Symbols NumericsIndex 111SS-SVX09A-EN

RAUC-C20, RAUC-C40, RAUC-C25, RAUC-C30, RAUC-C60 specifications

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