This article takes an in depth look at pressure gauges.
You will learn more about topics such as:
A pressure gauge is a tool used to measure the intensity of fluid, gas, water, or steam within a pressure-powered system. It helps monitor for leaks or pressure fluctuations that could impact the system's performance. Pressure systems are designed to function within a specified pressure range, and any deviations from these standards can significantly affect their operation.
Pressure gauges have been in use for over a century, continually evolving to meet the demands of new applications. Their implementation has become essential as pressure systems are increasingly deployed across various industries.
The variations in pressure gauges depend on their intended use, with different sizes, styles, and materials tailored for specific applications. Pressure gauges are categorized and defined in several ways, including by their usage, the type of media they measure, and the method used to gauge pressure.
Pressure is calculated by measuring the perpendicular force applied per unit area of a surface, using various techniques and methods. Accurate pressure measurement depends on the reference point against which the pressure reading is taken. Pressure gauges are classified into two main types: hydrostatic and mechanical.
Mechanical Pressure: Mechanical pressure is measured by a bellows, diaphragm, or Bourdon tube that converts fluid pressure into force.
In the discussion of pressure, it is important to understand some of pressure‘s other dynamics, which are absolute, gauge, differential, and atmospheric. Everyone is familiar with atmospheric pressure; it is discussed as part of weather reports, it is the pressure of the air around us. Absolute, differential, and gauge pressure are methods for measuring pressure.
Absolute pressure gauges measure pressure independently of atmospheric fluctuations by using a reference vacuum that remains constant at zero pressure. This vacuum chamber, isolated from external pressure changes, is separated from the media chamber by a diaphragm. As pressure increases, the diaphragm deforms towards the vacuum chamber. This deformation is then converted into a pressure value.
Unlike other pressure gauges, absolute pressure gauges are unaffected by changes in altitude. This makes them particularly suitable for use in aeronautics, HVAC systems, and distillation processes, where consistent and precise pressure measurements are crucial.
In a bellows pressure gauge, the bellows consists of thin, flexible metal tubes arranged in an accordion-like shape and sealed at one end. When pressure is applied, it acts on the bellows, causing it to expand and create movement. These gauges are highly sensitive and are typically used for measuring low-pressure applications.
Bellows gauges come in two main forms. In one type, pressure applied to the bellows causes deformation, which is counterbalanced by a spring. In the other type, the gauge operates on the differential pressure principle, with the bellows sealed between two chambers that have different pressures.
A Bourdon tube pressure gauge features an elastic, curved tube that is fixed at one end to a socket. When pressure is applied, the tube deflects, with the extent of the deflection being proportional to the pressure. This movement is transmitted to a rotary gear connected to a pointer. The gauge operates on the principle that a curved tube will straighten under pressure, and this change is indicated on a dial or digital display.
Bourdon tube pressure gauges can measure pressures ranging from up to 1000 bar to as low as -1 bar for gases, steam, or fluids. They offer accuracy within ±0.1% to ±2.5% of full scale deflection and are typically constructed from brass, stainless steel, or Monel, a nickel alloy.
A capsule pressure gauge features two thin, concentric corrugated diaphragms sealed together around their edges. One diaphragm has a central hole that allows the medium to enter. When pressure is applied, the diaphragms expand or contract, creating rotary movement that is displayed on the gauge's face. Capsule pressure gauges are designed to measure pressures up to 600 mbar with an accuracy of ±1.6% and are exclusively used for measuring gas pressures.
A diaphragm pressure gauge operates on a similar principle to a Bourdon pressure gauge but uses a diaphragm instead of a flexible tube to measure pressure. The diaphragm, positioned between two flanges, displaces when pressure is applied, determining the difference between the applied pressure and a reference pressure. This type of gauge can measure pressures ranging from up to 40 bar to -1 bar for gases, steam, and fluids. It is primarily used for measuring low-level pressures.
Differential pressure gauges measure the difference between the pressure in two chambers that are separated by an element that moves back and forth according to the changes in pressure. The movement of the element causes a movement in the pointer on the gauge face or provides a digital display reading. One of the ports of the gauge is installed on the high side, while the other is placed on the low side that shows a pressure drop on the gauge.
In some differential pressure gauges, a linear magnetic piston is positioned between the two pressure chambers. This piston interacts with a rotary magnet connected to the gauge pointer or digital display. Differential pressure gauges are favored for their simplicity and effectiveness in measuring the difference between two pressure points.
Manometer pressure gauges measure pressure by comparing two columns of fluid. This simple gauge consists of a transparent "U"-shaped tube partially filled with a manometric fluid, such as mercury. One end of the tube is connected to the pressure source, while the other end is open to the atmosphere, allowing the difference in fluid levels to indicate the pressure.
A piezometer is a type of manometer used to measure the pressure of liquids within a medium pressure range. It consists of a simple glass tube open at both ends. One end of the tube is connected to the pipeline where the fluid's pressure is to be measured, while the other end is exposed to the atmosphere. The tube is mounted vertically, allowing the liquid to rise into the tube. The pressure reading is indicated by the height of the fluid within the tube.
Pressure gauges are commonly used to monitor pressure in pipelines and ensure the safe operation of gases, fluids, and steam. They are essential for evaluating the performance of pumps, conveying systems, and various types of spray nozzles.
The primary purpose of pressure gauges is to provide crucial information about the status of a system, helping to prevent equipment damage and leaks. Investing in a high-quality pressure gauge, regardless of its cost, can save time and reduce expenses by ensuring accurate and reliable monitoring.
Given the wide variety of pressure gauges, it's impractical to cover the construction of each type in detail. For brevity, this discussion will focus on the construction of the Bourdon pressure gauge.
The cases for pressure gauges are made of plastic, steel, brass, or, most commonly, stainless steel. The complexity and type of case is a good indication of how expensive the gauge is. Phenolic, a resin made from phenols and aldehydes, cases are used in aggressive and harmful environments such as those for chemical and petrochemical production.
Cases of pressure gauges can be filled with glycerin or silicone to prevent condensation and protect against corrosive environments that could damage the internal mechanism. Additionally, rubber gauge covers are available to shield the gauge’s case from impact damage.
The socket is the first part of the pressure gauge to come into contact with the pressurized fluid. Inexpensive gauges typically have a simple hole drilled at the outlet connection, whereas more costly gauges feature a threaded hole for a restrictor orifice. The restrictor orifice helps prevent particles from entering the gauge and potentially jamming it.
One end of the Bourdon tube is welded to the linkage in Bourdon pressure gauges. In less expensive models, the linkage is often attached using stamping or a mechanical device.
Pointer types vary based on the adjustments they allow and their complexity. More advanced pointers offer features for fine-tuning adjustments to account for altitude changes, wear from pulsations, and vibrations.
Pressure gauge readings can be displayed in either an analog dial format or as a digital readout. The type of display varies based on the gauge’s design and function. A pressure gauge’s dial scale is calibrated to match its specific design and type; for instance, the dial on a Bourdon tube gauge is calibrated to correspond with the Bourdon tube's measurements.
The scale on a pressure gauge is often divided into three sections: the first and third sections are less accurate, while the middle section is the most accurate. When choosing an analog pressure gauge, it’s ideal for the normal pressure range to fall within the middle section of the dial for optimal accuracy.
While the middle of the dial generally provides the most accurate pressure readings, some pressure gauges offer high accuracy across the entire dial scale, achieving accuracy within 1%.
A digital pressure gauge displays pressure readings on an LCD screen and utilizes a transducer to convert the pressure value into an electrical signal. Digital pressure gauges come in various designs and styles, including portable models for field testing and fixed models for installation on pipelines.
Digital pressure gauges require a power source, typically a battery, to operate. In contrast, analog pressure gauges function mechanically and do not need an external power source.
The front or face of a pressure gauge, known as the window, protects the gauge from environmental factors and shields the internal mechanism. It can be made from glass, tempered glass, or plastic. Soft plastic windows offer flexibility for thermal compensation and accommodate the expansion of glycerin or silicone fills without leakage. The window acts as a clear membrane, allowing users to view and read the gauge’s dial.
The three basic types of gauge windows are safety glass, polycarbonate, and acrylic. Safety glass can be either tempered or laminated, making it hardened and durable to resist breakage. Polycarbonate is 250 times stronger than glass and 30 times stronger than acrylic, capable of withstanding significant impact. Acrylic, while not as strong as polycarbonate, is still stronger than glass, exceptionally resistant to stress, and does not shatter.
Pressure is a physical and measurable force per unit area exerted against an object by a substance, material, or gas in contact with it. For liquids and gases, the pressure increases as the quantity or weight of the substance increases.
The conversion chart below helps convert between different pressure units and provides an understanding of each type.
| Pressure Unit Conversion Chart | ||||||
|---|---|---|---|---|---|---|
| Pascal (Pa) | Bar (bar) | Pounds per Square Inch (psi) | Technical Atmosphere (at) | Standard Atmosphere (atm) | Torr (Torr) | |
| 1 Pa | = N / m² | 10-5 | 1.450377 x 10-4 | 1.0197 x 10-5 | 9.8692 x 10-5 | 7.5006 x 10-3 |
| 1 bar | 105 | = 100kPa | 14.50377 | 1.0197 | 0.98692 | 750.06 |
| 1 psi | 6.8948 x 103 | 6.8948 x 10-2 |
= 1 lbf / in² | 7.03069 x 10-2 | 6.8046 x 10-2 | 51.71493 |
| 1 at | 9.80665 x 104 | 0.980665 | 14.22334 | = 1 kp / cm² | 0.9678411 | 735.5592 |
| 1 atm | 1.01325 x 105 | 1.01325 | 14.69595 | 1.0332 | 1 | = 760 |
| 1 Torr | 133.3224 | 133.3224 x 10-3 | 1.933978 10-2 | 1.359551 x 10-3 | ≈1.315789 x 10-3 | ≈1mm Hg |
Pressure gauges are crucial instruments used in industry to measure system pressure, serving as a quality control measure and ensuring product consistency. For safety reasons, they monitor fluids, gases, and steam to detect leaks or pressure buildup in a system.
The design, style, type, and configuration of a pressure gauge are tailored to its specific application or industry. Pressure gauges are versatile tools used in a wide range of scenarios, from monitoring pressure in a swimming pool pump to measuring pressure in hydraulic lines for manufacturing equipment.
When discussing pressure gauges for a car, the first thing that comes to mind is the air pressure gauge for the tires. Though an air pressure gauge is important, there are several other pressure gauges that monitor various car systems, such as the air conditioning, oil, and engine coolant. Modern cars have gauges and meters on almost every critical component.
A variety of instruments provide pilots with information about an aircraft's condition and pressure variations. Pressure sensing devices are integral to both the flight group and engine group, playing a crucial role in maintaining the safe operation of the aircraft. Each type of pressure gauge is specifically designed for its intended application.
Aeronautical pressure gauges come in several types, including Bourdon tube, bellows, and diaphragm gauges.
In the oil industry, flow lines, separators, and stock tanks are all under some form of pressure. Every aspect of an oil operation, from the wellhead to the tank, is monitored and overseen by a pressure gauge. All gauges for the oil industry have safety measures built into them for the protection of workers since they can blow out when the pressure gets too high.
Pressure gauges used in the food industry must meet stringent hygiene standards and are typically made from stainless steel grade 316, which is safe for direct contact with food media.
Food-grade pressure gauges are designed to endure the rigorous cleaning processes essential for food preparation, ensuring they maintain hygiene and functionality.
For safety and sanitary reasons, food processing pressure gauges must have an exceptionally smooth surface to prevent contaminants, bacteria, and residue from becoming trapped.
Pressure gauges used in the chemical industry are specially designed to handle various mediums and highly aggressive environments. These gauges often require frequent repair and replacement. To protect the instrument, they are coated with materials such as Tantalum, Halar, or Polytetrafluoroethylene (PTFE), which offer exceptional corrosion resistance.
A hydraulic pressure gauge is crucial for the operation of hydraulic systems. Inaccurate gauges can negatively impact system performance and disrupt manufacturing processes. Detectable pressure changes may signal leaks or damage to hydraulic components. Therefore, hydraulic pressure gauges must be highly accurate and durable, capable of operating effectively in harsh and hazardous conditions.
Pressure gauges are extensively used across various industries to monitor and calibrate pressure functions and applications. They are typically designed, configured, and manufactured to meet the specific needs of each industry, ensuring accurate and precise data.
Despite their widespread use, it is crucial to carefully evaluate all factors when choosing a pressure gauge for installation. Selecting the appropriate gauge for precise measurement can help prevent issues related to pressure gauge malfunctions and ensure the smooth operation of the process.
AAccording to the American Society of Mechanical Engineers (ASME), pressure gauge accuracy is classified from 4A to D, as detailed in ASME B40.1. For mechanical pressure gauges, accuracy is measured as a percentage of the full scale or span. Generally, higher accuracy comes with a higher price.
The required accuracy of a pressure gauge depends on its function, ranging from simple testing to complex industrial monitoring. Typically, testing gauges should have an accuracy of 0.25% to 0.10% of the full scale, while critical processes require an accuracy of 0.5%. For less critical applications, an accuracy of 2% may be sufficient.
Pressure gauge dials come in a range of sizes, from 1.5 inches to 16 inches, depending on their placement and required accuracy. Larger dials are typically used in less accessible areas, while smaller dials are suitable for easily accessible locations.
For pressure gauges that need frequent and highly accurate readings, it's advisable to choose a gauge with a large dial face. This ensures quick and easy readability.
Environmental factors significantly impact monitoring, calibration, and data gathering devices. Besides the type of medium being measured, factors such as temperature, particulate matter in the medium and atmosphere, condensation, and humidity must be considered.
Temperature is a major environmental factor that can significantly impact pressure gauge readings. Some pressure gauge models are designed to compensate for temperature variations. In cases of extreme temperature fluctuations, it is advisable to isolate the gauge to protect it from potential damage.
In environments with corrosive materials, particulate matter, or high humidity, it's essential to use a weatherproofed, hermetically sealed, and fluid-filled pressure gauge. This type of gauge is designed to withstand harsh conditions and ensure reliable performance.
When selecting a pressure gauge, it is crucial to match it with the media it will monitor and the conditions it will be exposed to. Manufacturers provide a range of gauges designed for corrosive environments, different chemicals and gases, as well as conditions involving impacts, pulsations, or vibrations.
For corrosive environments such as wastewater treatment plants, petrochemical processing, or chemical manufacturing, stainless steel gauges are a popular choice. They offer excellent protection against shocks, vibrations, and temperature extremes.
To protect pressure gauges from hazardous media, various seals can be used, including diaphragm seals that are compatible with any gauge type. Manufacturers also offer custom sealing materials, such as Tantalum and PTFE, to enhance protection against corrosive or extreme conditions.
Choosing the right connection involves evaluating the process pressure, gauge size and weight, available space, and leak integrity. Pressure gauges typically use either a national pipe thread (NPT) or G type connection. The choice between NPT and G connections often depends on the geographical region where the gauge is used. In the United States and Canada, NPT is commonly used, as it adheres to the standards set by the American National Standards Institute (ANSI) and the ASME.
Male NPT connections are tapered, with the thread diameter gradually narrowing from the tip to the socket, which enhances the seal quality.
G connections, used in Europe, Asia, Latin America, and elsewhere except Canada and the United States, follow the British Standard Pipe Parallel (BSPP) pattern and are identified by the letter "G". These straight threads allow for easy installation and removal of gauges without thread damage, though a sealing washer is needed to ensure a tight seal.
Other connection types beyond NPT and BSPP include Deutsches Institut für Normung (DIN), Japanese Industrial Standard (JIS), and SAE.
An important consideration for the connection is its role in attaching the gauge to the application. The design and size of the connection affect its versatility. For instance, a lower mount gauge can be attached to an upward-facing female connection, while a backward-facing connection can make the gauge difficult to read.
The various mounting options include direct stem lower connect, remote surface mount lower connect, panel surface mount back connect, panel hole U clamp flush mount back connect, and panel hole front flange flush mount back connect.
The maximum operating pressure should not exceed 75% of the full-scale range. Choosing a pressure gauge that is pushed beyond this limit can lead to gauge fatigue and potential failure.
Pressure sensor elements are crafted from various metals, including brass, bronze, steel alloys, stainless steel, Monel, and Inconel. The selection of materials depends on the media being monitored. The elements must be compatible with the media and capable of withstanding any harmful or damaging effects that the media may have.
Analog displays have been the preferred choice for many years. However, recent advancements have made digital displays sufficient, leading to a shift in display preferences.
Ultimately, the type of application determines the choice between analog and digital displays. ASME directives 40.1 and 40.7 provide detailed guidance on the use of these display types in pressure gauges.
A mechanical device called an air pressure switch uses pressure to regulate how an electric air compressor operates. The device's air pressure circuit mechanism supplies the motor with electricity. A pressure switch relief valve is a...
Differential pressure is the difference in pressure between two points that is measured using different types of pressure sensing devices. An essential part of differential pressure measurement are gauges and switches that are...
A pressure switch is a mechanical or electronic device activated by the pressure of the process fluid upon reaching a certain threshold or setpoint. A pressure switch can have a bourdon tube, piston, diaphragm, or membrane that moves or...
A pressure transducer is a mechanical device that converts applied pressure, a physical quantity, into a measurable and industry-standard electrical signal which is linearly and proportionally related to the applied pressure...