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Pressure gauges are used for a variety of industrial and application-specific pressure monitoring applications. Mechanical, or analog, pressure gauges have an analog face which displays the pressure reading using a dial. Pressure gauges can be used for visual monitoring of air and gas pressure for compressors, vacuum equipment, process lines and specialty tank applications such as medical gas cylinders and fire extinguishers. In addition to visual indication, some pressure gauges are configured to provide electrical output of indicated pressure and monitoring of other variables such as temperature.
Types of Mechanical Pressure Gauges
For more detailed information on types of pressure gauges visit Pressure Sensors Selection Guide on GlobalSpec.
- Absolute pressure sensors measure the pressure of a system relative to a perfect vacuum. The measurement is done in pounds per square inch absolute (psia).
- Differential pressure is measured by reading the difference between the inputs of two or more pressure levels. The sensor must have two separate pressure ports; the higher of the two pressures is applied through the high port and the lower through the low port. It is commonly measured in units of pounds per square inch (psi).
- Gauge sensors are the most common type of pressure sensors. The pressure is measured relative to ambient pressure which is the atmospheric pressure at a given location. The average atmospheric pressure at sea level is 1013.25 mbar but changes in weather and altitude directly influence the output of the pressure sensor. In this device, the input pressure is applied through the high port and the ambient pressure is applied through the open low port.
- Vacuum sensors are gauge sensors used to measure the pressure lower than the localized atmospheric pressure. A vacuum is a volume of space that is essentially empty of matter. Vacuum sensors are divided into different ranges of low, high and ultra-high vacuum.
- Sealed gauged sensors measure pressure relative to one atmosphere at sea level (14.7 psi) regardless of local atmospheric pressure.
The same sensor can be used for all three types of pressure measurement; only the references differ.
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- Compound pressure gauges can display positive and negative pressure readings.
Liquid Filled- Liquid filled gauges are filled with a liquid such as glycerin or silicone oil to protect the gauge from the harmful effects of vibration and pulsation. They are best used when a system will be under positive and negative pressure (requires a compound pressure gauge) because a dry gauge will wear out more quickly under the stress and when the system is exposed to a lot of vibration. There are several advantages to choosing a liquid filled gauge; liquid steadies the pointer so the gauge is easier to read and it lubricates the internal parts of the gauge so they last longer.
Pressure Gauge Specifications
- Working pressure range is the maximum allowable pressure at which a system or piece of equipment is designed to operate safely. The extremes of this range should be determined in accordance with the expected pressure range the device must operate within.
- Dial diameter is the diameter of the gauge. The dial size is usually determined by the readability requirements; larger for remote reading and smaller where the gauge is close to the operator. Generally, a requirement for higher accuracy dictates a larger dial size for display of readable small pressure scale increments.
Various dial diameters. Image Credit: neptechinc.com
- Pressure connection size is the size of the pressure connection. 1/4" NPT would be represented as .25 inches.
- Accuracy is defined as the difference (error) between the true value and the indicated value expressed as a percent of the span. It includes the combined deviations resulting from the method, observer, apparatus and environment. Since gauge accuracy is closely related to price, consider the application to determine the accuracy needed. Applications requiring less accurate readings, like in a backyard pool, can use an accuracy of "3-2-3", which means the gauges are accurate to plus or minus 3% in the bottom third and top third of their range, and within 2% in the middle third. Gauge levels can be as accurate as 0.25%.
- Vacuum range is the span of pressures from the lowest vacuum pressure to the highest vacuum pressure (e.g., from 0 to 30 inches of mercury VAC).
Operating temperature is important to consider. Buyers should be aware of the ambient and media temperatures in the environment of the sensor. If the sensor is not compensated correctly the reading can change drastically.
The mount location on the gauge can vary depending on the type of gauge. Selecting the type of mount depends on the application and environment in which the gauge will be used.
Bottom- This is sometimes called a stem mount, and the mount connection is on the bottom of the gauge.
- Back- Back mounting can be found in the center or lower back of the gauge. The mount connection will protrude from the back of the gauge.
Flange- The pressure gauge is mounted by a flange around the face or back of the gauge
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Scale Specifications Criteria
The scale is located on the face of the analog pressure gauge. Scale can help determine accuracy, with smaller scales leading to more accurate readings. The face of the gauge can have a single or dual scale.
Single scale pressure gauges have one scale (one set of units) on their faces.
Dual scale pressure gauges have two scales (two sets of units) on their faces. This is commonly seen in compound pressure gauges.
For more detailed information on sensor technologies vist the Pressure Sensor Selection Guide on GlobalSpec.
Mechanical deflection uses an elastic or flexible element to mechanically deflect with a change in pressure, for example a diaphragm, Bourdon tube, or bellows.
- Piston technology uses a sealed piston/cylinder to measure changes in pressure.
Strain gauges (strain-sensitive variable resistors) are bonded to parts of the structure that deform as the pressure changes. Strain gauges are rugged, accurate, and stable, they can operate in severe shock and vibration environments as well as in a variety of pressure media.
Piezoelectric pressure sensors measure dynamic and quasi-static pressures. They are capable of converting stress into an electric potential and vice versa. The sensors can only be used for varying pressures. They are very rugged but require amplification circuitry and are susceptible to shock and vibration.
Semiconductor piezoelectric sensors are based on semiconductor technology. The change in resistance is not only because of a change in the length and width (as it is with strain gage) but because of a shift of electrical charges within the resistor. These are very sensitive devices.
Variable capacitance pressure instruments use the capacitance change results from the movement of a diaphragm element to measure pressure. Depending on the type of pressure, the capacitive transducer can be either an absolute, gauge, or differential pressure transducer. The device uses a thin diaphragm as one plate of a capacitor. The applied pressure causes the diaphragm to deflect and the capacitance to change. The deflection of the diaphragm causes a change in capacitance that is detected by a bridge circuit.
Analog pressure gauges should be selected considering the media and ambient operating conditions. Gauge selection should take into consideration the corrosive environment in which it is to operate. The media being measured must be compatible with the wetted parts of the pressure instrument. Improper application can damage the analog pressure gauge, causing failure or personal injury and property damage. Diaphragm seals (also called gauge isolators) can be added to the system to protect the gauge from corrosive attack, and prevent viscous or dirty media from clogging Bourdon tube analog pressure gauges.
Related Products & Services
Digital Pressure Gauges
Digital pressure gauges use electronic components to convert applied pressure into usable signals. The gauge readout has a digital numerical display.
Pressure gauges are used for a variety of industrial and application-specific pressure monitoring applications. Uses include visual monitoring of air and gas pressure for compressors, vacuum equipment, process lines and specialty tank applications such as medical gas cylinders and fire extinguishers.
Pressure instruments are used to measure, monitor, record, transmit or control pressure.
Pressure sensors include all sensors, transducers and elements that produce an electrical signal proportional to pressure or changes in pressure.
Pressure switches are actuated by a change in the pressure of a liquid or gas. They activate electromechanical or solid-state switches upon reaching a specific pressure level.
Pressure transmitters translate the low level output of a sensor or transducer to a higher level signal suitable for transmission to a site where it can be further processed. These devices include pressure sensors, transducers, elements, and instruments.
Vacuum sensors are devices for measuring vacuum or sub-atmospheric pressures.