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Typical Calibration Procedure of Displacer (Buoyancy) Level Transmitter


Operating Principle

The displacer level transmitter (or any other buoyancy level transmitter) uses the effect of buoyancy. When the displacer is immersed in the process fluid, this buoyancy effect will make the displacer lighter than the non immersed displacer. This change of displacer weight is then detected by the sensor (whether use torque tube or LVDT) and then translated as a fluid level.

 

Before we calibrate the displacer level transmitter, we must aware that the transmitter has been set at factory as per process fluid Specific Gravity (SG), while we will use water as the calibration fluid. When the displacer is operated by using actual process fluid, it will show 4 mA at low level (the displacer is not immersed) and 20 mA at high level (the displacer is fully immersed). Thus before we calibrate the transmitter, we need to calculate the equivalence of this buoyancy effect if we use water as the test fluid instead of using actual process fluid (which is in practice are very difficult to get).

 Non-Interface Displacer Level Transmitter Calibration Procedure

 1. Calculate the equivalence water level

 Zero level = displacer not immersed (no need certain adjustment)

 Calculate the high level using this equation:

 (Process Fluid Operating SG / Water SG)*Transmitter Level Range

 2. Set up the Displacer Level Transmitter to column or temporary support as shown in the calibration setup file below.

 3. Fill the level transmitter chamber with water up to the centre of the lower part flange of the LIT cage as a zero level.

 4. By using handheld HART communicator set this level as zero level (see also in the LCD display of the transmitter, it should show zero level).

 5. Read the mA output of the transmitter by using a multimeter. Adjust (if any) through the HART communicator so that the output of the transmitter (on multimeter) is 4 mA.

 6. Fill the level transmitter chamber with water up to the calculated equivalence high level above.

 7. By using handheld HART communicator set this level as high level (see also in the LCD display of the transmitter, it should show high level).

 8. Read the mA output of the transmitter by using a multimeter. Adjust (if any) through the HART communicator so that the output of the transmitter (on multimeter) is 20 mA.

 Interface Displacer Level Transmitter Calibration Procedure

 1. Calculate the equivalence water level

 Calculate zero level using this equation:

 (Lighter Process Fluid Operating SG / Water SG)*Transmitter Level Range

 Calculate the high level using this equation:

 (Heavier Process Fluid Operating SG / Water SG)*Transmitter Level Range

 2. Set up the Displacer Level Transmitter to column or temporary support as shown in the calibration setup file below.

 3. Fill the level transmitter chamber with water up to the calculated equivalence zero level above.

 4. By using handheld HART communicator set this level as zero level (see also in the LCD display of the transmitter, it should show zero level).

 5. Read the mA output of the transmitter by using a multimeter. Adjust (if any) through the HART communicator so that the output of the transmitter (on multimeter) is 4 mA.

 6. Fill the level transmitter chamber with water up to the calculated equivalence high level above.

 7. By using handheld HART communicator set this level as high level (see also in the LCD display of the transmitter, it should show high level).

 8. Read the mA output of the transmitter by using a multimeter. Adjust (if any) through the HART communicator so that the output of the transmitter (on multimeter) is 20 mA.

 Example of equivalence water level calculation:

 Level Transmitter Level Range = 38 inch

 Water SG = 1

 Process Fluid SG = 0.84

 Equivalence high level using water = (0.84/1)*38 = 31.92 inch

 It means the displacer should show 20 mA while we fill the chamber up to 31.92 inch with water fluid as test fluid.

 Interface Application

 Level Transmitter Level Range = 38 inch

 Water SG = 1

 Lighter Process Fluid SG = 0.695

 Heavier Process Fluid SG = 0.994

 Equivalence zero level using water = (0.695/1)*38 = 26.41 inch

 It means the displacer should show 4 mA while we fill the chamber up to 26.41 inch with water fluid as test fluid.

 Equivalence high level using water = (0.994/1)*38 = 37.772 inch

 It means the displacer should show 20 mA while we fill the chamber up to 37.772 inch with water fluid as test fluid.

 Typical tools required:

 1.24 VDC power supply

 2.Multimeter digital

 3.Water Supply Connection

 4.HART communicator

 5.Screwdriver set

 6.Wrench set

 Note: This typical maintenance procedure is just an illustration of how to regularly service a displacer level transmitter for academic purpose only. This typical procedure shall not be used as day to day operation guidance. The vendor specific maintenance manual shall be used in detail.

 

4 comments:

  1. My cousin recommended this blog and she was totally right keep up the fantastic work!




    Torque Calibration

    ReplyDelete
  2. You can find more information on Instrumentation here

    http://www.instrumentationtools.com/

    Thanks
    Bharadwaj

    ReplyDelete
  3. That's very important calibration and it is very clear.
    Thanks a lot.
    I really learned something.

    ReplyDelete