About Electro-Pneumatic Transducers | Equilibar

About Electro-Pneumatic Transducers

How Electro-Pneumatic Transducers Work


The electro-pneumatic transducer was a workhorse of American industrial automation from the 1950’s through the 1990’s.

These devices were also called:

  • current / pressure transducer
  • I/P transducer
  • voltage / pressure transducer
  • E/P transducer

Newer types of electronic pressure regulators (also called electronic pressure controllers), with improved accuracy and precision, have taken over much of the market for these E/P transducers. This page seeks to explain how the original electro-pneumatic transducers worked.

How I/P and E/P Transducers Work

As the names indicate, these devices converted either electrical current (typically 4 – 20 mA) or voltage (typically 0 – 5 VDC or 0 – 10 VDC) into pressure. They worked by creating a force imbalance on a piloted diaphragm by means of a magnetic coil of wire (similar to a speaker coil). Other than the coil, there are no electronic features to control the pressure output. The device works as a simple force mechanical balance with adjustable spring biases for the zero and span.

These devices typically contain a second flow-boosting stage, which uses a force balanced diaphragm and valve seat to generate higher flow rates at the outlet port than would be possible from the smaller first stage valve.

These devices work quite well if properly maintained and frequently calibrated. Indeed, these devices were the basis for the golden age of pneumatic control in the post World War II era, actuating countless control valves and pneumatic cylinders in factories worldwide.

Control technicians were carefully trained to adjust the zero and span screws to obtain the required accuracy and repeatability. Bellofram’s Type 1000 is a classic example of the electro-pneumatic transducer, still available today, with a specified 1% linearity, 1% hysteresis, and 0.5% repeatability. The 3 – 15 psig / .2 – 1 bar(g) output range was a common standard, and most models did not offer output pressures above 40 psig / 2.8 bar(g).

Though these devices are still available, most modern American industries have upgraded to devices with electronic feedback offering higher precision, more repeatability, and less hysteresis.

Pressure Transducers with electronic controllers

During the late 20th century, new types of electronic pressure devices were introduced, sometimes also referred to as “pressure transducers”. These devices used internal pressure sensors to evaluate and correct the output pressure using PID or other algorithms. Some of these devices used new mechanisms such as piezo valves instead of speaker coils to create the internal pilot pressures. As with the original style of pressure transducers, diaphragm based flow boosters were used to increase the flow volume.

These new devices offers significantly improved performance with accuracy approaching that of available pressure sensors (0.1 to 0.25% Full Scale). Hysteresis and impact of supply pressure were also significantly improved.

Modern Servo Technology
Electronic Pressure Regulators

A subset of these electronic pressure controllers using servo or solenoid valves has gained in popularity in recent years due to their flexibility, robustness, and reliability. These devices will be referred to as electronic pressure regulators on this website.

Learn more about how high precision electronic pressure regulators work

See our selection of high precision electronic pressure regulators

 


 

Equilibar EPC electronic pressure controller

Equilibar EPC electronic pressure controller
The EPC converts electronic input signal to output pressure

 

Visit our electronic pressure regulator page or contact us for more information about our electronic pressure controllers.
Equilibar News
stainless steel valve with schematic

Equilibar for electrolysis: emergency shutdown valves

Electrolysis is the chemical process of using electricity to divide a molecule into its component parts. It plays a key role in hydrogen and other renewable energy technologies, which has led to increased exploration and activity in the field. Many electrolysis applications require extremely precise fluid control that can respond to changes almost immediately. The Read More

Read More