Emerson PN 51-1055pHC/rev.K instruction manual Definitions conductivity/resistivity

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MODEL SOLU COMP II

SECTION 5.0

 

PROGRAMMING THE ANALYZER

5.5.3 Definitions — conductivity/resistivity

1.NEUTRAL SALT CORRECTION. Neutral salt temperature correction is appropriate for most applications involving natural and treated waters in which neutral salts are primarily responsible for the conductivity. It is NOT suitable if the sample is a dilute acid or base. The neutral salt correction programmed into the Solu Comp II takes into account the contribution of water to the overall conductivity (or resistivity). Therefore, the neutral salt works for high purity water as well as for waters having higher conductivity. The correction algo- rithm assumes the salt is sodium chloride. Because the change in the conductivity of sodium chloride solutions with temperature is similar to most other aqueous salt solutions, the correction is suitable for most applications. The correction applies between 0 and 100°C, and the reference temperature is 25°C.

2.LINEAR TEMPERATURE COEFFICIENT OR TEMPERATURE SLOPE. The change in the conductivity of most electrolyte solutions having conductivity greater than about 5 µS/cm at 25°C can be expressed by the

the following equation:

Ct

C25 = 1+ a(t - 25)

In the equation, C25 is the conductivity at 25°C, Ct is the conductivity at t°C, and a is the linear temperature coefficient. The linear temperature coefficient, or temperature slope, has units of %/°C. In the equation, the temperature coefficient is expressed as a decimal fraction. The linear temperature coefficient depends to some extent on both the temperature and concentration of the salt solution. The temperature coefficient also varies from salt to salt.

For maximum accuracy, the temperature coefficient must be appropriate for the salt or salts in solution, their concentration, and the temperature. Frequently, the relationship must be determined by experiment. Fortunately, for most dilute neutral electrolyte solutions, a linear temperature coefficient of 2.00%/°C (0.0200) is appropriate. The table gives typical ranges for different dilute electrolyte solutions.

 

Slope (%/°C)

 

 

 

Neutral salts

1.8 - 2.2

 

 

 

 

Acids and acid salts

1.0 - 1.6

 

 

 

 

Bases and basic salts

1.6 - 3.0

 

 

 

 

High purity water

Use neutral salt correction

 

 

 

3.CATION TEMPERATURE CORRECTION. Cation conductivity, sometimes called acid conductance, is used in steam power plants to measure salt contamination in boiler feedwater and steam. The Solu Comp II automat- ically corrects for the variation in the conductivity of extremely dilute hydrochloric acid with temperature and displays the conductivity at 25°C. The correction is valid to 100°C, so the Solu Comp II can be used for degassed cation conductivity measurements. Cation conductivity temperature correction also applies to semi- conductor etch rinse baths, which contain trace amounts of acids.

4.RAW. Raw conductivity is the conductivity of the sample at the measurement temperature.

5.TDS. TDS is total dissolved solids. The Solu Comp II calculates TDS (in ppm) by multiplying the conductivity (corrected to 25°C using a temperature coefficient of 2%/°C) by 0.65.

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Contents Model Solu Comp Essential Instructions Quick Start Guide ORP Quick Reference Guide Model Solu Comp List of Tables Table of Contents CONT’DIii List of FiguresAbout This Document Section Description and Specifications Ordinary Location -68 only DimensionsTerminal Connections Rating 26-14 AWG wire size Hazardous LocationRange, µS/cm Cell constant, /cm Performance SpecificationsAnalyzer Conductivity Input Recommended Sensors for ConductivityMeasurement Range see table below Toroidal Conductivity Codes -21 and/orRecommended Sensors for ORP Performance Specifications Analyzer ORP InputTemperature Correction none required When used with conductivity -20-32 orRepeatability ±1% Recommended SensorsFrequency Range 0.5 4000 Hz Measurement Range 0-10 ppm mg/L Loop Specifications with a Model 499A OZ SensorRecommended Sensor Input filter 1- 255 samplesModel 1055 Solu Comp II Analyzer Ordering InformationCombination Guide Part Number Description Weight General Information Section InstallationInstallation Unpacking and InspectionPanel Mounting Panel Mount InstallationPipe Mounting Pipe Mount InstallationSurface Mounting Surface Mount InstallationPreparing Conduit Openings Section WiringPOWER, ALARM, OUTPUT, and Sensor Connections Model Solu Comp Section Wiring Model Solu Comp Section Wiring 41055105 41055106 41055107 41055108 41055109 41055110 40105536 40105559 Keypad Section Display and OperationDisplay Programming and Calibrating the Solu Comp II Tutorial Security Using HoldSection Programming the Analyzer Sensors Output Section Default SettingsOutput Dampening Or 4 mA Mode Section Alarm SectionDefault Settings Assigning Outputs 1 DefinitionsChoose Output Range. Choose Output1 or Output2 Choose Output ConfigureChoose Output1 or Output2 Choose 4-20 mA or 0-20 mAAlarm Relays Must be Configured Before Assigning Setpoints Choose Measurement or Temp Choose Alarm ConfigureChoose Alarm Setpoints Definitions pH/ORP Definitions conductivity/resistivity Choose Soln Temp Corr or Sensor Isoptntl Choose MeasurementDefinitions pH OutputsAlarms Measurement Choose Noise Rejection Choose ResetAnalyzer Procedure Changing Screen Contrast Choose Default DisplayProcedure Choosing a Language Introduction Section CalibrationCalibrating Temperature Procedure Calibration Slope and Offset PH at 25C Standards Nominal pHEnter Choose Measurement Choose BufferCalManual Calibration pH S1ManualCal? Choose Measurement Choose Standardize Standardization pHEntering a Known Slope Value pH ORP Calibration Preparation of ORP standard solutionsProcedure-Calibration against a standard meter and cell Calibrating AN IN-SERVICE Sensor ConductivityChoose Measurement Choose InProcess Procedure-Calibration against a standard solution ProgramDisplay Calibrate? Choose Measurement Choose CellConst Placing a NEW Sensor in Service ConductivityCell constant Conductivity µS/cm Resistor k Ω Calibrating the Analyzer ConductivityTo Reset the Factory Resistance CALIBRATION, see Section Model Description See Figure Section MaintenanceReplacement Parts OverviewExploded View of Solu Comp II Panel Mount Version Exploded View of Solu Comp II Pipe/Surface Mount Version Absolute Value of Measured Voltage Exceeds 2500 mV Section TroubleshootingOverview Troubleshooting Using Fault Codes Simulating Inputs Conductivity Simulating TemperatureEeprom Failure PH Sensitive Glass Membrane is BrokenConductivity Sensor Open or Shorted RTD Sense Line for Sensor 1 or Sensor 2 is OpenCalibration Error During Two-Point Calibration Problem See SectionSensor Does Not Respond to Known pH Changes Calibration Error during StandardizationInvalid Input While Manually Entering Slope Model Solu Comp Section Troubleshooting Calibration Error Using Standard Resistors Current Output Too Low Alarm Relays Do Not WorkMeasurement seems wrong Conductivity, µS/cm Cell constant, /cmPreamplifier is in the Sensor Simulating pH input when the preamplifier is in the sensorGeneral Simulating Inputs Conductivity Set the temperature correction to raw SectionThree-Wire RTD Configuration Simulating temperatureChecking for a Poisoned Reference Electrode Measuring Reference VoltageGeneral Warranty RepairNON-WARRANTY Repair Section Return of MaterialWarranty Specifications subject to change without notice

PN 51-1055pHC/rev.K specifications

The Emerson PN 51-1055pHC/rev.K is a highly advanced and reliable component designed for a wide range of applications in industrial automation and control systems. This device is known for its robust performance, exceptional durability, and integration of cutting-edge technologies, making it an ideal choice for demanding operational environments.

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