Many instrumentation and control managers have adopted torque tube technology for use in liquid applications. However, professionals across many processing industries – including chemical, petroleum refining, power generation, pulp and paper, nuclear power, crude oil processing and natural gas processing – have come to realize that range spring technology is a more reliable level measurement and control solution than torque tubes due to the output stability, structural integrity and ease of use it provides.
The following comparison demonstrates the benefits that range spring technology may provide compared to torque tubes. This comparison uses a linear variable differential transformer (LVDT) transmitter with range spring technology, which is the operating principle used by the Magnetrol® E3 Modulevel® displacer level transmitter, as an example.
- While torque tubes can be overly sensitive, range spring technology dampens the effects of vibration, agitation and turbulence to provide stability in the most challenging applications. In addition, a range spring’s longer travel zone and dampening effect yield an output signal that is 4 times more stable than a torque tube can provide.
- The knife-edge bearings that support a torque tube at each end create points of wear and friction buildup as the tube twists against them. Unlike torque tubes, range spring movement is free of both the threat of wear and the opportunity for friction, which may cause inaccuracy in the measurement.
- Torsion of the torque tube may result in fatigue failure of the enclosing tube, as well as the opportunity for accelerated corrosion due to the shear stresses induced in the tube. However, the static-pressure-retaining enclosing tube of a displacer level transmitter with range spring technology is not susceptible to either of these failure effects.
- Displacer transmitters, which feature a compact, vertical design, are also much easier to install than torque tubes – and make maintenance much easier because you can remove a displacer transmitter head without depressurizing the process or chamber. In contrast, removing a torque tube transmitter requires shutdown of the entire process and costly down time.
- In addition, displacer level transmitters feature a head that is rotatable through 360°, making configuration of right-hand and left-hand mounting and orientation of the display and conduit a snap. By comparison, torque tubes must be factory configured to orient the display to the left or right of the chamber.
- Displacer transmitter technology also gives you versatile access and ease of control, with remote mounting capability that can be up to 400 feet away from the instrument. This provides a significant advantage over torque tubes, which must be mounted within 30 feet of the sensor.
Follow Our Displacer Level Transmitter Technology Discussion
In next week’s post, we’ll discuss LVDT transmitters with range spring technology and their use in interface applications. To learn more about using displacer transmitters for level control, you can also download the MAGNETROL Linear Variable Differential Transformer Technology Guide.