Pressure Switch

What is a pressure switch and how it works?

It is the switch that detects the presence of fluid pressure. It uses diaphragms or bellows as the pressure-sensing element and its motion actuates one or more switch contacts.

When the pressure switch senses minimum pressure, it will be referred to as in its “normal” status. Any fluid pressure below the trip threshold of the switch is referred to as the “normal” status of the pressure switch.

Two pressure switches as shown in the below photograph sensing the same fluid pressure:

A special design of pressure switch uses a bourdon tube as the pressure-sensing element, and a glass bulb partially filled with mercury as the electrical switching element. When the pressure is applied to the bourdon tube to flex sufficiently, the glass bulb tilts to cause the mercury to fall against a pair of electrodes, thus completing an electrical circuit.

Below the photograph is a close-up view of one of these pressure switches. The bourdon tube is grey in color inside the case, and almost as wide in diameter as the circular switch housing. Yellow-colored plastic caps covering up their external electrical contacts are mercury tilt switch bottles.

The next set of photographs shows a mercury tilt switch removed from the switch mechanism, the switch in two different states (contact open on the left and closed on the right).

The mercury tilt switches include immunity to switch contact degradation from harmful atmospheres (oil mist, dirt, dust, corrosion) as well as safety in explosive atmospheres (since a spark contained within a hermetically sealed glass bulb cannot touch off an explosion in the surrounding atmosphere) is its advantage. Including the possibility of intermittent electrical contact resulting from mechanical vibration, as well as sensitivity to mounting angle (i.e., you would not want to use this kind of switch aboard a moving vehicle!) is its disadvantage.

The below photograph shows a pressure switch manufactured by the Danfoss corporation:

The force generated by a pressure-sensing element against mechanical spring balances by the pressure switch. Tension on the spring and the trip point of this switch is adjustable.

There is one setting known as the dead band or differential pressure setting shown in the lower window on the switch. After the switch tripped, we have to reset the setting which determines the amount of pressure change required to bring it normal state.

List of Prominent Manufacturers: Afrisco, Aircom, Aircomp, Airlogic, Airpress, Airtec, Airwork, Ashcroft, Aventics, Barksdale, BCM Sensor, BD Sensor, Bieri Hydraulics, Cameron, Comitronic, Comus, Danfoss, Delta-Mobrey, Doepke, DropsA, Dwyer, Eaton, Elettrotec, Engler, Festo, FineTek, Fratelli Ghiotto, Gems, Georigin, GHM Group, Herga, HK Instruments, Honeywell, Huba Control, Hydac, Hydropa, Indumart, Inelta, Jiucheny, Keller, Layher, Leeg Sensor, Lefoo, Leybold, Mico, Neo-Dyn, New-Flow, Nivelco, Norgren, Noshok, Pascal, PCI Instruments, Piezus, Prisma Instruments, Rexroth, Riels, Roemheld, Rototherm, Sauermann, Sauter, Schischeck, Schmalz, Selco, Sensata, Setra, SMC, United Electric Controls, Telemechanique, Trafag, Val.co, Wasinsx, WIKA, Yuanben

Follow to get new posts and updates about the blog. Appreciate your feedback!

Pressure Switch Basics

 

Basically, the pressure switch is a device that operates an electrical contact (open or closes a respective switch contact) when the preset fluid pressure is reached. The switch is designed in such a way that it makes contact either on pressure rise or on pressure fall corresponds to a certain preset pressure level.

Types: Depending on the nature of the requirement, it is mechanical or electronic models.

Mechanical pressure switch

A mechanical pressure switch consists of a spring and a diaphragm to control at what pressure the micro-switch is triggered. The spring acts as an opposing force to the inlet pressure and preset pressure or pretension is adjusted with a set screw or knob. The spring’s pretension depends on the pressure at which the switch makes contact. The switch comes/resets to its original state when the pressure drops.

  

When the preset pressure is reached and the switch is actuated, it will send an electrical signal for which no auxiliary power is needed. The difference between the switch point and reset point is called hysteresis and expressed as a percentage of the switch point value.

There are three different types of contacts in these pressure switches: normally open (NO), normally closed (NC), and changeover (SPDT) contacts. For both NO and NC operation changeover contacts were used.

The mechanical pressure switch is better than an electronic pressure switch suited for handling high voltages. For an increase or decrease in pressure, it should be used to make a contact change.

Electronic pressure switches

An electronic pressure switch uses an electrical pressure sensor to measure the change in inlet pressure. A display is available in electronic pressure switches where the measured pressure can be read, and it has flexible settings and programming is also possible. 

Other parameters like switch points, output signal, delay time, hysteresis, and many other parameters can be individually adjusted using digital displays to set up the switching function. It can be adjusted by the user according to the requirements.

 

  

These are suitable for automated controlled equipment systems that require programmable function, digital display, flexibility, accuracy, ingress protection, and stability.

Operating principle

The inlet pressure pushes the piston/diaphragm against a spring which has a known resistant force. Then, the piston triggers the micro-switch, moving it between normally closed (NC) and normally open (NO) positions through an operating pin and an insulated trip button.

To set the pressure level at which the micro-switch switches between NC and NO, the trip-setting nut changes the spring pocket depth. To trigger the micro-switch which correlates to a set pressure, depth change allows the spring resistant force to increase or decrease. 

Inlet pressures create force upon the operating piston, generating a force opposing the range spring. When the inlet piston's force is higher than the opposing spring force, it pushes the operating pin into the insulated trip button. The trip button then moves the micro-switch from NC to NO position. 

It breaks the connection, if the pressure decreases below the spring force, the button, pin, and piston move away from the micro-switch. Then connection moves from the NO position to the NC position.

Compare to a mechanical pressure switch, an electric pressure switch is more expensive, but comes with more control over the settings, like pressure setpoint and hysteresis.

Consider the below factors at the time of selection:

Type of media: Housing and seal material should be compatible with the media type. Common media used with pressure switches are Hydraulic oil, Heating oil, Turpentine, Petrol/gasoline, Air, Water.

For the medium containing air and hydraulic/machine oil, nitrile butadiene rubber (NBR) is suitable.

For water medium ethylene propylene diene monomer rubber (EPDM) is suitable.

Pressure: The switch must be able to withstand the maximum working pressure. For vacuum and low-pressure applications, diaphragm design works well, and for high-pressure applications, we use a piston design.

Temperature: The switch must be able to work well within its maximum and minimum temperature range.

Repeatability: It is the ability of the device to accurately switch back to the same set point for every repetition otherwise known as accuracy. The selection of the pressure switch will determine the range of accuracy required for the application. Compare to piston design, diaphragm designs generally provide more accuracy.

Hysteresis: It is the difference between the switch point and the reset point. If the reset point is too large, the switch stays active for a long time. The switch will flip between on/off states frequently if the reset point is too short.

Common applications

Pressure switches are widely used in industrial technical processes to automatically supervise and control systems that use pressurized fluids. Pressure switches are in a wide range of industrial and residential applications like HVAC systems, well pumps, furnaces, HVAC, gas cylinders, air pumps, etc.

List of Prominent Manufacturers: Anderson, ASCO, Barksdale, Barton Instruments, Bristol, Custom Control Sensor, Dresser Instrument, Dwyer Instruments, Honeywell, Mid-West Instrument, SOR Inc., SquareD, United Electric Controls

Follow to get new posts and updates. Appreciate your feedback!

Pressure Transmitter Basics

The device converts the process pressure into a standard electrical signal by using electronic pressure sensors or transducers are generally known as pressure transmitters. The standard electrical signal is useful for indicating and controlling the process.

Pressure Transmitter Types:

• Absolute
• Gauge
• Differential
• Multivariable

Transmitters used a microprocessor, which includes an input circuit, analog-to-digital (A/D) converter that converts the sensor input into a digital signal before it is sent to the microprocessor.

The microprocessor performs manipulation in ranging, linearization, error checking, and either transmit the reading digitally or sends the resulting value to the output digital-to-analog converter (D/A), which converts the signal back to an analog signal of 4–20 mA DC, 0–1 V DC, or 0–10 V DC.

The mechanical signal of the pressure is converted into a current (4-20 mA) electronic signal. Electronic pressure signal has a linear relationship with the magnitude of the voltage or current, which is generally proportional to the corresponding value. Therefore, the voltage or current outputted by the transmitter increases with the increase of the pressure and vice versa.

The transmitter circuit gets power using the signal line (2-wire system). The transmitter quiescent consumption is 3.6 mA; during operation, consumption may be as high as 21 mA, depending on the measurement and sensor status. 4 mA corresponds to 0% of the working range and 20 mA to100% of the working range.

Calibration of a pressure transmitter includes zero and span adjustment. Exactness includes non-linearity, hysteresis, and repeatability effects and is indicated in % of the calibrated span. 

The pressure value is calculated in percentage taking into consideration the working range provided by the Lower Range Value (LRV) and the Upper Range Value (URV).

The range is the measurement limit that covers from the minimum to the maximum pressure that the transmitter can measure.

Zero is the least pressure at which the transmitter was calibrated.

URV is the highest pressure at which the transmitter was set to measure with respect to the sensor's upper range limit.

LRV is the lowest pressure at which the transmitter was set to measure with respect to the sensor's lower range limit.

Span is the working range where the calibration is done The Span is equal to URV – LRV

“Turndown” is defined as the ratio of maximum allowable span to the minimum allowable span for a particular instrument.

Pressure Trim: The values obtained by Zero Pressure TRIM and Upper-Pressure TRIM may correct here the transmitter for long-term drift or the shift in zero or upper-pressure reading due to installation or overpressure.

Current Trim: The 4 mA TRIM and 20 mA TRIM adjustment is used to make the transmitter current comply with a current standard, should a deviation arise.

Pressure transmitters are manufactured by considering safety measures as it may be installed in hazardous and extremely high-temperature zones. So, it should be approved by different non-profit organizations to comply with the safety standards (explosion-proof, intrinsically safe, ingress protection, etc)

Applications: Used in various industries like powerplant, steel industry, petrochemical, oil and gas, water plants, chemical plants, food industries, etc.

List of Prominent Manufacturers: ABB, Accutech, Ametek, Ashcroft, Barton Instruments, Bristol Babcock, Dresser Instrument, Druck, Dwyer Instruments, Endress+Hauser, Fisher Controls, Flow-Tech, Fuji Electric, The Foxboro Co., Gefran Spa, Honeywell, Measurement Specialties, Moore Products, Mid-West Instrument, MKS Instrument, Nuova-Fima, OCI Instruments, Omega Engineering, Parker, Palmer Instruments, Phonetics, Rosemount, Siemens, Smar International, Winters, Wika, Yokogawa

Follow to get new posts and updates. Appreciate your feedback!

Pressure Gauge Selection Basics

Pressure gauges generally use mechanical sensing elements based on the force balance principle.

We must consider the below factors for right pressure gauge selection because improper selection can cause failure and possible personal injury or property damage.

Accuracy: It ranges from 0.1 to 4 and chose as per the application. For a pointer stop gauge, the accuracy class will cover from 10 % to 100 % of the scale range.

Environment: Consider the environmental condition when selecting a pressure gauge includes ambient temperature, condensation, humidity, water, and chemicals, all of which can affect gauge performance.

Sensing Element: Pressure sensor material depends on the process fluid and should be compatible. Otherwise, it stops working or causes a hazard to personnel, or deviates accuracy.

For sensing elements please visit the below link:

Instrumentation Basics: Mechanical Pressure Sensor Basics I (instrumentbasics.blogspot.com)

Instrumentation Basics: Mechanical Pressure Sensor Basics II (instrumentbasics.blogspot.com)

Material of Construction: Case & ring material, bourdon tube, movement mechanism, dial, pointer, gaskets, blow off disc and window should be manufactured as per process fluid and the environment where it will install.

For example:

Case & ring material      :           AISI 304 SS

Bourdon tube                 :           AISI 316 L SS

Movement mechanism  :           AISI 304 SS

Dial                                :           Aluminum (black graduation on white background)

Pointer                           :           Aluminum, Micro zero adjustable

Gaskets, Blow off disc   :          Neoprene

Window                          :          Shatterproof safety glass

Dial Size: It comes in different sizes and chooses as per the process requirements. It ranges from “1 to 16” diameters.

Range: It depends on the process and has different values as per requirement.

Type of Display: Mainly designed as analog or digital displays. Digital displays are used in certain applications even if analog pressure gauges are the most popular.

Mounting Pattern/Type of mounting: It depends on the location and type of connection. (For example, Direct/wall/surface/panel, Bottom/Back connection)

The factors mentioned above are the key points we need to consider before deciding to select a pressure gauge. Consult with the manufacturer of your gauge for a detailed guide.

List of Prominent Manufacturers: ABB, Accutech, Ametek, Anderson Instrument, Ashcroft, Barton Instruments, Bristol Babcock, Dresser Instruments, Druck, Dwyer Instruments, Endress+Hauser, Fisher Controls, Flow-Tech, The Foxboro Co., Honeywell, Mid-West Instrument, MKS Instrument, Nuova-Fima, OCI Instruments, Omega Engineering, Smar International, TSI Inc., Trerice, Universal Flow Monitors, Winters, Wika, Yokogawa

Follow to get new posts and updates. Appreciate your feedback!

Pressure Gauge Basics

Pressure Gauge is measuring and indicating instrument without external power that shows the accurate process/fluid pressure by using the mechanical sensing elements like bellow, bourdon, or diaphragm type based on balance working principle.

Components of Pressure Gauge

The main components of a pressure gauge are the dial, pointer, ring/lens gasket, window/glass lens, movement, sensing element, and case.

Case: It is generally known as housing keeps all other materials along with it. The case is made up of aluminum, steel, brass, polypropylene, stainless steel based on the applications and mounting environments. As per mounting style like surface mounting, flush-mounting, or pipeline mounting cases are back flange, front flange, and turret types.

Dial: These are made up of steel, brass, aluminum, plastic, with black marking lines on a white background or in other color combinations. Near major marking lines, the numerals are placed. Sometimes there are two rings of marking lines shown in different units as per the requirement.

Pointer: Generally, it is a bar navigate to show the pressure value by indicating the numerals, fixed with the shaft. Industrial gauges are made with adjustable pointers which adjust by turning the hub while keeping the shaft fixed.

Ring / Lens Gasket: It keeps the window/glass lens fixed. Ring attached to the case in different ways, including snap, friction, slip, threaded, and hinged designs. The look of the gauge can also be affected by ring design variations, including peaked, flat-flared, and beaded gauges.

Window/Glass Lens: It is held against the case front by rings. Material of construction of the lens is available including shatterproof, beveled glass or cellulose acetate, and non-electrostatic plastics, etc.

Movement: The mechanism that connects the sensing element and the pointer to show the deflection is known as a movement in general. It situates in between the dial and the case and protects both (e.g. pinion and socket arrangement).

Sensing Element: Pressure gauges generally use mechanical pressure sensors as sensing elements and deflect the pointer using shaft movement or different types of mechanism arrangements.

To know more about the mechanical pressure sensing element, check the link below: Instrumentation Basics: Mechanical Pressure Sensor Basics I (instrumentbasics.blogspot.com)

Pressure gauge manufactured by considering safety standards which contain at least a blowdown disk that allows the internal pressure to escape. General process connections of pressure gauges are either 1/4in or 1/2in size located either on the back or on the bottom.

List of Prominent Manufacturers: Accutech, Ametek, Ashcroft, Barton Instruments, Bristol Babcock, Dresser Instrument, Druck, Dwyer Instruments, Endress+Hauser, Flow-Tech, TheFoxboro Co., Honeywell, Measurement Specialties, Moore Products, Mid-West Instrument, MKS Instrument, Nuova-Fima, OCI Instruments, Omega Engineering, Parker, Palmer Instruments, Phonetics, Smar International, TSI Inc., Trerice, Winters, Wika, Yokogawa

Follow to get new posts and updates. Appreciate your feedback!

Accessories (Manifold, Snubber, Seal, Siphon, Bracket, Enclosure) Basics

There are different types of accessories or mechanical components to protect the pressure instruments against hazardous process fluids, from high/low temperature, high/low pressure, corrosion, pulsation, etc, or isolate the instrument for removal or maintenance of process line or equipment.

They are mainly: Valve Manifolds, Pulsation Dampeners / Snubbers, Chemical Seals, Water traps and pigtail Siphons, Bleed/Vent Fittings, Mounting Brackets, Heated Enclosure, Impulse Lines, etc.

1. Valve Manifolds

Valve manifolds are generally used to isolate the pressure instruments at the time of calibration or isolate the process connection during instrument replacement on a continuous operation process. Some process fluids may be toxic, corrosive, radioactive, etc, and cause hazards to personnel or the environment, so it is necessary to protect against the release of these fluids during calibration or instrument replacement.

The most common type of manifold is the two-valve, three-valve, and five-valve arrangements. Generally, the valves are termed as isolating, block, bleed, equalizing, drain and vent valves.

When the valves and connections are preassembled with manifold, results in time-saving, and the chances for leaks are reduced. Manifolds may be preassembled to the instrument or available loose to bolt directly to standard instruments.

2. Pulsation Dampeners / Snubbers

When the pressure gauge is in service, it affects by pulsation or sudden fluctuation in the pressure of process fluids. It can be avoided by filling viscous liquid like glycerin inside the gauge. The inherent properties to the friction of this fill liquid act as a “shock absorber” which protects the gauge from pulsation or external vibration. It cannot be in the instrument specifically to measure high-frequency pulsations.

A snubber consists of a fluid restriction installed between with pressure sensor and the process to avoid damping pulsations in a pressure instrument.

The simplest example of a snubber is a simple needle valve (an adjustable valve designed for low flow rates) placed in a mid-open position, restricting fluid flow in and out of a pressure gauge.

3. Chemical Seals

Most pressure sensors come with chemical seals or diaphragm protectors. They are using for the following reasons:

1. Use to avoid freezing or settling of the process fluid in the sensor due to temperature variation.

2. Prevent entering hazardous materials into the pressure sensor and slurries from entering, plugging the detector element.

3. Protect the sensing instrument from corrosive or harsh chemicals we use the isolating diaphragm and fill fluid referred to as a chemical seal.

4. Water traps and pigtail Siphons

When sensing elements used in steam service, we must prevent the stream from entering the element, which could cause temperature damage. For this reason, to avoid damage to the sensing element, install a coil pipe siphon between the gauge and the process connection.

For example, in a power plant to check the parameters of the steam at the outlet of the boiler in the main steam line, we use a siphon to avoid damage to the sensing element.

5. Bleed/Vent Fittings

When removing the pressure transmitter from service we have to “bleed” or “vent” stored fluid pressure to the atmosphere, prior to disconnecting the transmitter from the impulse lines. A common accessory for pressure-sensing instruments (transmitters) is the bleed valve fitting or vent valve fitting, installed on the instrument as a passive device that generally comes with ¼ inch male NPT pipe threads.

These bleed valves are used to bleed unwanted fluids from the pressure chamber when directly installed on the flanges of a pressure instrument. To sense compressed air pressure, we bleed condensed water out of an instrument, and to sense water pressure we bleed air bubbles from an instrument.

6. Mounting Brackets

In general, we use a 2-inch pipe mounting bracket to mount transmitters. These brackets are manufactured from heavy sheet metal and equipped with a U-bolt designed to clamp around a 2-inch iron pipe. To provide a mechanical stable of attaching the transmitter, the holes stamped in the bracket match the mounting bolts.

7. Heated Enclosure

When the ambient temperature is too much cold or hot, a protective measure against fluid inside a pressure transmitter is to house the transmitter in an insulated, heated enclosure. Also use an enclosure, to protect all kinds of temperature-sensitive instruments from extreme cold.

8. Impulse Lines

8.1 Purged Impulse Lines

The pressure instrument isolates from direct contact with the process fluid by purging the line with a continuous flow of clean fluid particularly when the impulse line is prone to plugging.

Generally, the purge fluid was clean water. But other than water, Gases such as air, nitrogen, or carbon dioxide are often used in purged systems, for both gas and liquid process applications.

8.2 Heat Traced Impulse Lines

In cold weather conditions, there is a possibility of liquid freezing that we used in impulse lines. To avoid this, we use active heating mediums such as steam and electrical arrangement.

“Steam tracing” consists of a copper tube carrying low-pressure steam, bundled alongside one or more impulse tubes, enclosed in a thermally insulating jacket.

Electrically “tracing” uses a twin-wire cable (heat tape) that acts as a resistive heater. When power is applied, the cable heats up, thus imparting thermal energy to the impulse tubing it is bundled with.

List of Prominent Manufacturers: Ametek, Anderson Greenwood, Dresser Measurements, Dwyer, Honeywell, Mid-West Instruments, MKS Instruments, Noshok, Parker, Rosemount, Siemens Moore, Smar International, Swagelok, Versa Gauge, Wallace & Tiernan, Weiss Instruments

Follow to get new posts and updates. Appreciate your feedback!