The Effects of Cold Climates on Pressure Transmitters

Pressure transmitters typically use some form of strain gauges mounted to a diaphragm to measure pressure. These gauges can be applied using glue, thin film deposition, encapsulated in oil, or mounted using a glass firing process. As the diaphragm deflects, the resistance values change. In all cases, the effects of temperature can also change the resistance of this output signal, causing errors in the sensor.

Icing of process media is an indirect result of cold climates. In certain natural gas drilling applications, water can be found in the same pipes as the gas. When the system is shut down and the temperature drops below freezing, the water inside the pipe can freeze and expand, causing an overload on the pressure sensor for a prolonged period of time. The expansion can mirror a pressure spike of 500 PSI (35 bar) to 1,000 PSI (70 bar) of pressure. For a 100 PSI system, the pressure can increase to 1,500 PSI (100 bar). For many sensor technologies, this strain on a lower pressure diaphragm will cause a failure of the strain gauge or rupture of the diaphragm. To protect against sensor failure, the pressure increase must be sustained by the sensing element for a period of time without affecting the accuracy of the sensor after thawing. Special cavity design as well as special proof pressure capability and calibration are the best ways to guarantee that the sensor will not fail from the media freezing in the cavity.

In order to compensate for the changes in temperature electrically, pressure transmitter manufactures test sensors over both pressure and temperature to adjust for the effects of temperature. Because each sensor and strain gauge is unique, it is best practice to test each individual sensor for its specific properties. The traditional method is to trim, or reduce, the raw output signal using resistors to optimize performance over the tested temperature range. The sensor would, then, use a circuit board assembly that amplifies the millivolt signal to the required output signal (ex. 4-20mA). Certain pressure transmitters will offer zero and span adjustability. This function is commonly needed for drifted output signals after diaphragm fatigue. As the cost and size of digital electronics have decreased, there has been an increase in the usage of digital compensation through the use of an ASIC (Application-Specific Integrated Circuit). In cases of low temperature, the ASIC is programmed as the pressure sensor is tested over temperature, with some designs correcting non-linearity, or deviations from the ideal output signal. The temperature of the ASIC can be compensated at the gauges, using a temperature sensor such as a thermistor or at the ASIC itself. The main difference is media temperature. If compensated based on the ASIC temperature, the temperature reading is not as accurate due to its proximity to the media. In cold climates, the ASIC could be reading close to ambient temperature, whereas the media could be a hot liquid or gas. Measuring the temperature of the gauges produces the fastest response and dynamic compensation, optimizing performance.

Another manufacturing advancement related to pressure transmitters is the ability to offer an independent temperature output signal. System integrators can now closely monitor the changes in media temperature from a single device, reducing the cost of installation and the cost of the additional sensor. In the image on the left below, you will observe a one piece, stainless steel sensing element that is machined so there are no welds or internal O-rings. Since there are no welds or joints in this design, fatigue value is much lower over a wide operating temperature. Constructed of very thick diaphragms and state-of-the-art silicon strain gauges, these explosion-proof pressure transmitters offer repeatable results even in the hostile environs of deep well drilling, as shown in the image on the right below. The addition of Alloy 718, 17-4 PH, Alloy C-276 and 316 L SS wetted parts, further extends these pressure transmitters' use in the processing of heavy oil and high sulfidation.