Bellows pressure gauge

Pressure gauge working principle and properties

 23 February 2017

Bellows pressure gauge working principle

Bellows are thin-walled metallic cylinders, with deep convolutions, of which one end is sealed and the other end remains open. The closed end can move freely while the open end is fixed.

When pressure is applied to the closed end, such as in the animation below, the bellows will be compressed. The closed end will move upwards and the link, which is the rod in between the closed end of the bellows and the transmission mechanism, will go up and rotate the pointer.

Bellows pressure gauge
Bellows pressure gauge animation

"Check out other pressure gauge animations:"

Characteristics of bellows

Compared with diaphragm and capsule pressure gauges, bellow gauges have the advantage of a longer stroke length and they generate larger forces.

The number of convolutions can vary between 5 and 20. More convolutions means a longer stroke length and a larger measuring range.

The diameter of the bellows determines the force that can be transmitted to the transmission mechanism. Therefore a larger diameter will be chosen for the measurement of very low pressures in order to have sufficient surface area to which the measured pressure can act.

A larger diameter also means a higher sensitivity and an improvement of the accuracy.

Bellows may be fabricated from different materials. Each of these materials has its own specific stiffness, which is proportional to the Young's modulus of the material, and is inversely proportional to the outside diameter and the number of convolutions of the bellows.

The relationship between the pressure exerted on the bellows, and its deflection is linear and is only disrupted when the elastic limit is reached.

The deflection can be expressed as follows:

formula for deflection of bellows
Where: δ = deflection of the bellows
n = number of convolutions
Ae = effective surface of the bellows
P = pressure
R = average radius of the bellows
E = Young's modulus
t = wall thickness

Bellows are sensitive to temperature changes, work hardening, drift, friction, hysteresis and vibrations.

To compensate for these drawbacks, a bellows is generally used in combination with a calibrated spring.

As an additional advantage, the measuring range can be determined by the choice of the spring. Choosing a strong spring will lead to a large measuring range which makes it possible to measure large pressures with a bellows pressure gauge. For this reason, most bellows gauges are spring-loaded.

The spring also protects the bellows from being completely retracted or stretched beyond the elastic limit and thus extends its lifespan.

datasheets

Measuring range of bellows pressure gauges

The pressure range is determined mainly by the effective area of the bellows and the spring gradient, and to a lesser extent by the material from which the bellows are made. For higher measuring ranges bellows will be used with a smaller diameter.

This kind of pressure gauges can be used to measure different types of pressure but are generally used for the measurement of low pressures, ranging from vacuum to about 3.5 barg.

Differential pressure gauges consisting of 2 opposing bellows with internal heavy range springs can be used at much higher static pressures (up to 750 barg) with a differential pressure measurement range of 69 bar.

Fabrication of bellows

Bellows are usually made from thin-walled seamless tubes pressed hydraulically, or mechanically roll formed.

Wall thicknesses of 0.008 to 0.3 mm are used for instrumentation purposes.

They can be manufactured from beryllium copper, phosphor bronze, Monel, Inconel and stainless steel.

When using phosphor bronze, the bellows will have good hysteresis properties, while beryllium copper provides better dynamic properties. Stainless steel is used when the bellows comes into contact with corrosive media, but it has the disadvantage of being less elastic.

Relative pressure sensors

Bellows may be used both in compression and expansion.

When relatively low pressures are to be measured, the bellows will usually be used in expansion. The process pressure is then introduced to the inside of the bellows and causes the bellows to extend.

If larger pressures are to be measured, it is better if the process pressure acts on the outside of the bellows. In this case, the bellows are compressed.

When measuring larger pressures, the bellows are always equipped with a heavy range spring.

In both illustrations, below, the inside of the bellows is at atmospheric pressure whereas the outer side is subject to the process pressure. Both bellows therefore work in compression. The only difference between the two is the position of the spring. It can be located either on the inside of the bellows or on the outside.

Such sensors may also be used for the measurement of differential pressure. The only thing required is to replace the atmospheric pressure inside the bellows by a second process pressure.

Bellows in compression with internal spring
Bellows in compression with internal spring
Bellows in compression with external spring
Bellows in compression with external spring

Also, a compound pressure gauge can be made with a single bellows when the inside of the bellows is exposed to atmospheric pressure and the process pressure can vary between vacuum and positive pressure. If the pointer rotates to the left, underpressure is measured, to the right means overpressure.

Compound gauge with a single bellows
Compound gauge with a single bellows

Absolute pressure sensors

To measure absolute pressure we need two bellows. The first one is the reference bellows, which is provided with a perfect vacuum on the inside. The second one is the measuring bellows, which is subjected to the process pressure.

Since these absolute pressure sensors are generally used to measure low pressures, the bellows are not equipped with calibrated springs and they are used in expansion. The bellows will stretch with increasing process pressure.

The deflection of the bellows is transferred via the transmission mechanism to the pointer.

A change in the atmospheric pressure has no influence on the measurement in this case, since the influence of this pressure on the two bellows is equally great.

Absolute pressure sensors exist in two different versions. On the one hand, there is the beam balance principle and on the other hand the opposed principle, as in the illustrations shown below.

Beam balance bellows principle
Beam balance bellows principle
Opposed bellows principle
Opposed bellows principle

Differential pressure sensors

Just as differential pressure can be measured with a single bellows, as described above, we can also use dual bellows.

The low process pressure is connected to the first bellows while the high process pressure is connected to the second bellows.

Both of these process pressures will exert a force on the effective area of the bellows upon which they act. The resultant force rotates the pointer.

Differential pressure principle
Differential pressure principle

These measurement devices can be designed for the measurement of differential pressures up to 70 bar or more, with an overpressure limit to 750 barg static pressure on both sides of the device.

At such high pressures, bellows with small diameter are preferred, optionally provided with an internal or external spring. The accuracy will be less because of the need for a small diameter.

At high differential pressures the accuracy is around 1.5% of the measuring range. At lower differential pressures up to 1 bar, accuracies of 0.5% of the measuring range are possible.

Datasheet template

An easy configurable Excel template is available for specifying bellows pressure gauges. This datasheet is designed to define bellows pressure gauges for all kinds of applications.

Datasheet templates for other types of instruments can be found in the datasheet library.

Advertisement
bookmark invitation
close icon

Young's modulus

Young's modulus, also known as the elastic modulus, is a measure of the stiffness of a solid material.

close icon

Elastic limit

The elastic limit or yield point is the point at which a material starts to deform plastically when it is subjected to stress. Below the elastic limit the material will deform elastically and will return to its original shape when the applied stress is removed. A material which is subjected to stress above the elastic limit will experience a permanent, irreversible deformation.

close icon

Drift

Drift is a slow change of the indication or output of a measurement over an extended period of time, during which the actual value of the measured quantity remains the same.

close icon

Hysteresis

Hysteresis of a pressure gaugeHysteresis is the difference in pressure reading between the pressure-up and the pressure-down cycle for the same process pressure. The type of material from which the bellows are made and the wall thickness are important for the amount of hysteresis. Thicker walls will create more hysteresis.