Document Outline

• PREFACE
• 1. INTRODUCTION AND GENERAL DESCRIPTION
  • 1-1. Instrument check
  • 1-2. Application
• 2. GENERAL SPECIFICATIONS OF EXAxt PH450G
• 3. INSTALLATION AND WIRING
  • 3-1. Installation and dimensions
    • 3-1-1. Installation site
    • 3-1-2. Mounting methods
  • 3-2. Wiring
    • 3-2-1. Preparation
    • 3-2-2. Cables, Terminals and glands
  • 3-3. Wiring the power supply
    • 3-3-1. General precautions
    • 3-3-2. Access to terminal and cable entry
    • 3-3-3. AC power
    • 3-3-4. DC power
    • 3-3-5. Grounding the housing
    • 3-3-6. Switching on the instrument
  • 3-4. Wiring the contact signals
    • 3-4-1. General precautions
    • 3-4-2. Contact outputs.
  • 3-5. Wiring the mA-output signals
    • 3-5-1. General precautions
    • 3-5-2. Analog output signals
  • 3-6. Wiring the sensor system
    • 3-6-1. Impedance measurement jumper settings
  • 3-7. Sensor wiring
    • 3-7-1. Connection cable
    • 3-7-2. Sensor cable connection with special grommet (450G-□-A version)
    • 3-7-3. Sensor cable connections using junction box (BA10) and extension cable (WF10)
• 4. OPERATION OF EXAxt PH450G
  • 4-1. Main display functions
  • 4-2. Trending graphics
  • 4-3. Zoom in on details
    • 4-3-1. Actual mA1 = the current output in mA of the first current output, which is defined as mA1. The range and function of this mA output can be set in Commissioning >> Output setup>> mA1
    • 4-3-2. Actual mA2 = the current output in mA of the second current output, which is defined as mA2. The range and function of this mA output can be set in Commissioning >> output setput >> mA2
    • 4-3-3. Zero = calibrated sensor offset in mV. Theoretically the sensor reads 0 mV in a buffer solution with the same pH value as the Iso­po­ten­tial pH value of the sensor (default 7.00 pH). The ZERO value indicates the condition of the sensor. If the valu
    • 4-3-4. Slope = calibrated efficiency of the sensor unit in percentage of theoretical slope of the sensor unit. The theoretical slope follows the NERNST equation and is 59.16 mV/pH. The SLOPE can be calibrated only after a two-point calibration in buffer so
    • 4-3-5. Sensor mV = the output of the sensor unit prior to calibration and temperature compensation. This value is important for trouble shooting.
    • 4-3-6. Reference impedance = the electrical resistance of the liquid junction. The liquid junction forms the electolytical contact between the reference element and the measuring electrode, so it must be kept clean and filled with conductive electrolyte. O
    • 4-3-7. Last calibrated = the date on which the last sensor calibration is done. The displayed value of the ZERO is the result of this calibration. The displayed value of Slope is not necessarily calibrated on this date: only if the last calibration was a 2
    • 4-3-8. Calibration due = the date when the calibration must be done according to the settings of the maintenance timer. This is based on scheduled maintenance procedures. The maintenance intervals are set in menu: setup>> Commissioning>> measurement setup>
    • 4-3-9. Projected calibration = the date when the predictive maintenance function expects that recalibration of the sensor unit is necessary for good measurement accuracy. The transmitter checks the reference impedance every hour. The user is notified when
    • 4-3-10. Projected replacement = the date when the predictive maintenance function expects that replacement of the sensor is necessary for good measurement accuracy. After each calibration the slope, zero and reference impedance are logged. Aging of the sen
    • 4-3-11. Serial number = serial number of the transmitter
    • 4-3-12. Software revision = the revision level of the software in the instrument
    • 4-3-13. HART Device revision
    • 4-3-14. Logbook
  • 4-4. Information function
  • 4-5. Setup-calibration & commissioning
  • 4-6. Secondary-primary value display switch
  • 4-7. Navigation of the menu structure
  • 4-8. Setup Concentration mode
• 5. MENU STRUCTURE COMMISSIONING
  • 5-1. Sensor setup
  • 5-2. Measurement setup
  • 5-3. Temperature setting
  • 5-4. Temperature compensation
  • 5-5. Calibration settings
  • 5-6. Impedance setting
  • 5-7. mA output setup
  • 5-8. Contact output setput
  • 5-9. Fail
  • 5-10. Simulate
  • 5-11. Error configuration
  • 5-12. Logbook configuration
  • 5-13. Advanced setup
  • 5-14. Display setup
• 6. CALIBRATION
  • 6-1. Calibration check with buffer solutions.
  • 6-2. Manual calibration mode
  • 6-3. Automatic calibration mode
  • 6-4. Sample calibration mode
  • 6-5. Temperature calibration
  • 6-6. ORP & rH calibration
  • 6-7. Operation of hold function during calibration
  • 6-8. Contact output setup
• 7. MAINTENANCE
  • 7-1. Periodic maintenance
  • 7-2. Periodic maintenance of the sensor
  • 7-3. LCD adjustment
• 8. TROUBLESHOOTING
  • 8-1. General
  • 8-2. Calibration check
  • 8-3. Predictive maintenance
  • 8-4. Error displays and actions
• 9. SPARE PARTS
• APPENDICES
  • Appendix 1, Buffer tables
  • Appendix 2, HART HHT (275/375) menu structure
  • Appendix 3, Temperature compensation matrix
• CMPL
• Revision Record