Liebert 3000 manual Physical Connections, Setup, Calibration

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System Performance with Advanced Microprocessor Controls

Physical Connections

Figure 6 shows the 4-20 mA output of LT750 connected to Analog Input #1 (41 and 42) on the exter- nal inputs terminal strip. This strip is provided on units ordered with analog inputs. (If this strip is not installed, there is a field installation kit available from your Liebert representative.)

The 4-20 mA output of the LT750 must be connected to the first analog input, as shown. TB4 is the water detected relay output. It can be connected to any one of the four special alarm inputs. TB5 is the cable fault relay output. It can also be connected to any one of the four special alarm inputs.

Setup

(The following description assumes the wiring connections as shown above.) First, verify that special alarms 1 and 2 are ENABLED to either WARNING or URGENT type. Do this by selecting VIEW/SET ALARMS from the Main Menu. Then, select SETUP ALARMS. Follow the instructions on the display to select the required type for CUSTOM ALARM #1 and CUSTOM ALARM #2 if not already set.

Next, select the alarm message for CUSTOM ALARM #1 and #2. From the Main Menu, select VIEW/ SET ALARMS. Then, select SETUP CUSTOM ALARMS. Then, select SETUP CUSTOM ALARM TEXT. Define CUSTOM ALARM #1 to be CUSTOM 1. (CUSTOM 1 is the default message that will be displayed if a message has never been programmed.) Next, select the text for custom alarm #2 to be WATER UNDER FLOOR. Now, change the message CUSTOM 1 to LT750 CABLE FAULT. This is done by selecting the CHANGE CUSTOM TEXT 1 menu item in the SETUP CUSTOM ALARMS menu. Follow the instructions on the screen to change the message.

The slope and intercept values of Analog Input #1 are used to calculate the location of water. These values should initially be set to zero. The default values are zero, but it may be a good idea to verify those values. They can be viewed by selecting ANALOG/DIGITAL INPUTS from the Main Menu, then SETUP ANALOG INPUTS.

See 3.4.6 - Setup Water Detect Floor Plan for more information.

Calibration

Calibration should not be required for most installations. The accuracy of this display is approxi- mately 1%.

The display is calibrated by the slope and intercept values of Analog Input #1. The position of the water is calculated from the analog output of the LT750 using this formula:

position = analog reading/full scale reading x (measured length + slope) + intercept

position is the distance from the LT750 to the position of the detected water.

measured length is the length of the cable which is calculated automatically when the layout is defined. The units for these values are in floor tiles.

The intercept value read from Analog Input #1 is added to the measured position of a water indication to determine which tile to highlight. For example, if water is displayed under the seventh tile but determined to be under the fifth tile, set the offset value to -2 tiles. Use the intercept value to correct errors close to the start of the cable.

Accuracy errors farther out on the cable should be corrected using Analog Input #1's slope value. This value effectively adjusts the measured length of the cable. Increasing the effective length of cable will increase the distance of the water and move the highlighted tile farther along the cable, and vice versa. Unlike the intercept, which adjusts by the same amount for all locations on the cable, the slope increases its effect for larger distances.

The best procedure to calibrate the cable would be to first simulate water close to the LT750, about five tiles out. Adjust the intercept to get the correct reading. Next, simulate water five tiles from the end. Adjust the slope to get the correct reading.

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Contents Liebert Challenger Page Table of Contents Run Diagnostics Alarm Descriptions Component Operation and MaintenanceHumidifier Figures Page System Descriptions Compressorized SystemsGlycool Chilled Glycol Cooling Systems Chilled Water SystemsStart-Up Procedure Basics Advanced microprocessor control panelAdvanced microprocessor a control for Challenger Main Menu MENU/ESC Status/Alarm DataStatus Display Setpoints/Setup Default setpoints and rangesRun Hours Log Analog SensorsSetup System Setup OperationCalibrate Sensors Show DIP SwitchesSelect Options Setup Alarms Alarm default time delaysDefault Time Alarm Delay secondsStandard Custom Alarm Messages Humidity HUM Control MethodCalibrate Actuator Analog SetupSet Status Display Run Diagnostics Show InputsTest Outputs Test Control BoardChange Passwords Date and TimeControl Circuit Board LCD Display ContrastDIP Switches Non-Volatile MemoryControl Outputs Control output LEDsOperation with Advanced Microprocessor with Graphics Control Advanced microprocessor with graphics control menu View/Set Alarms See 3.7.7 Set Status DisplaySetup Alarms View Water Detect Floor Plan for Optional LTM1000/LT750 Setup Custom AlarmsSetup Water Detect Floor Plan System Setup Cold Start DelayOperating Status View/Set Control SetpointsAuto Restart Delay Default Settings and RangesIR Flush Overfill infrared humidifiers only Chilled Water/Hot Water/Econ-O-Coil FlushCalibrate Valve Actuator Select Control Algorithm Chilled Water and SCR Reheats onlyRun Diagnostics Select Humidity Sensing ModeShow Inputs Modify Plot Scales Setting optionsPlot Graphs Analog/Digital Inputs View Run Hours LogLCD Contrast View 24 Hour Run Time HistoryView Total Run Hours Nonvolatile Memory Temperature Control Cooling/Heating Required, in Percent %Response to Control Types Proportional Control PID Control Chilled Water or SCR Reheats onlyGlycool Cooling Dual Cooling SourceChilled Water Cooling Cooling/dehumidification load status responseHumidity Control Heating Operation Electric ReheatHot Water Reheat SCR Electric Reheat Requires Special Control SoftwareProportional Control Control TypesHumidification Operation System Activation Time between peaks x 5% Load Control Features Additional FeaturesConnecting the Analog Sensors Short Cycle ControlInstallation-LT750 DIP Switch Settings FaultWater Detection Display LT750 Environmental UnitCalibration SetupPhysical Connections Communications Liebert Monitoring Devices and SoftwareStandard Alarms Change FilterCustom Alarms High TemperatureCompressor Overload High Head PressureHigh Temperature and Low Temperature Simultaneously Humidifier Problem Infrared HumidifiersLoss of Power Low TemperatureOptional/Custom Alarms System Testing Firestat Smoke DetectorWater Detection Sensor Liebert unit Recommended Liquitect location Floor drainZone leak detection kit installation scenarios FiltersRemote Shutdown Distance From UnitBlower Package Fan Impellers and BearingsBelt Air DistributionRefrigeration System Suction PressureDischarge Pressure SuperheatHot Gas Bypass Valve Operation AdjustmentThermostatic Expansion Valve Operation Outdoor fan/condenser configuration Air Cooled CondenserValve spring guide Water/Glycol Cooled Condensers Coaxial CondenserRegulating Valve Glycol Solution Maintenance Adjusting Collar NutMechanical Failure Compressor ReplacementCompressor Functional Check Compressor Replacement Procedure Electrical FailureCleaning the Pan HumidifierInfrared Humidifier Removing the PanAutoflush Infrared Humidifier Cleaning System Autoflush OperationAutoflush Controls Steam Generating HumidifierOperation ControlsReplacing the Canister Humidifier canister part numbersPart Capacity Number Voltage Lbs/hr kg/hr 200-460Circuit Board Adjustments Drain Tempering FeatureSymptom Possible Cause Check or Remedy Blower troubleshootingChilled water troubleshooting Compressor and refrigeration system troubleshooting Compressor and refrigeration system troubleshooting Dehumidification troubleshooting Glycol pump troubleshootingInfrared humidifier troubleshooting See 6.4.8 Compressor Functional Check and TableSteam generating humidifier troubleshooting Reheat troubleshooting Filters Steam Generating Humidifier Blower SectionCompressor Air Cooled Condenser if applicableFilters Water/Glycol Condenser if applicableGlycol Pump Electrical PanelSemiannual Maintenance Inspection Checklist Page Ne t ItiTi n That
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3000 specifications

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