Strain Gauges Explained

Posted on December 29, 2011 by philgnorris

If you have ever looked at an alarming crack in a house wall after a full structural survey has been undertaken, you may have noticed a number of what looks like pieces of tape across the crack.  this tell-tail piece of material, normally a form of paper, is the simplest form of strain gauge and it is placed there to monitor movement of the crack over time.   If the paper rips apart, the crack is moving.  With a number of these strateigically-placed strain gauges, the structural engineer can obtain quite a lot of information just by inspection.  More sophisticated strain gauges measure the width of the crack and this information can be collected digitally.

For measurement of small changes in length (or strains) where the material is not disrupted as the brick wall was, the change as measured by a strain gauge is not visible to the eye, this is the basis for all force sensors.  To briefly explain the physics, for a homogeneous material such as steel alloy, aluminium, other metals and ceramics, there is a fixed and proportional relationship between stress to which the material is subjected and the strain that occurs.  This is known as Young’s Theorem and the constant for the relationship between stress and strain is known as Young’s Modulus.  Each material has a known Young’s Modulus provided that the material has not been stressed beyond its ‘elastic limit’ which is usually close to but not coincident with its ‘yield point’.

Typical metal foil strain gauge element

Most commercially available force sensors consist of 4 piezo-resistive strain gauges bonded to a specially machined steel billet and arranged in a diamond along the axis of the force to be measured.  These strain gauges are wafer thin and comprise a specially printed circuit that changes it’s electrical resistance and the four gauges are wired as a Wheatstone Bridge to measure the changes in resistance.

Thus the force sensor can be calibrated in force or torque units depending on the design of the steel body.  It can be compressive as in pancake or load cells,  tensile loads as in the ‘Z’ load Cell such as can be found in craneage, or torsion force as can be found in dynamometers; the applications are legion.

 

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Force Sensors In Motorsport

Posted on November 1, 2011 by philgnorris

Motorsport is a testing ground

Motorsport is a very competitive field in which a great deal of research and development takes centre stage.  The competitive edge is usually obtained by paring the last few milligrams of each component and like military aircraft, this process is Continue reading

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Load Sensor Applications

Posted on September 30, 2011 by philgnorris

In recent years, there has been a proliferation of load cell designs based on piezo-resistance strain gauges bonded to a variety of shaped tension and/or compression bodies to suit loadings from a few newtons (N) to hundreds and even thousands of kilo-newtons (kN). The reliability and accuracy of these designs has been proven in many applications, some of which we will be touching on in this article to illustrate the range of applications. Continue reading

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Piezoresistivity In Depth Sensors Explained

Posted on August 5, 2011 by philgnorris

Up to now, we have dealt solely with applied single-axis mechanical force and applied torque only.  That leaves only bending moment and shear force, which we will discuss in a future articles, and pressure, which is the subject of this article.

Depth and level measurement in liquids is a vital requirement in a number of process and utility sectors where industry-standard fieldbus outputs are required  for integration of depth measurement into process control.   This can include wells, boreholes, waste water, lakes, reservoirs, rivers, water and sewage treatment plant as well as other liquids in bulk such as chemicals, fuel and diesel oil. Continue reading

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Force Sensor Electronics

Posted on July 1, 2011 by philgnorris

If you can imagine driving onto a public weighbridge, you will have seen a not only a display at driver height that shows each axle load and a total load.  What’s more, the weights and measures man will give you a ticket showing the same information, along with other information about you and your lorry.  You could also receive an overload warning ticket.  This is a typical application of the integration of a number of force sensor units to give a totallised set of results. Continue reading

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Torque Sensors Explained

Posted on May 23, 2011 by philgnorris

There are many types of force sensor applications used in all industry sectors such as load cells to measure both compressive and tension forces,  shear force and bending force; all of which are necessary to monitor structures and machinery performance.  This time, we introduce the subject of torque sensors also known as the torque transducer.  As any engineer will tell you, torque or turning force is applied tangentially at a distance from an axis.  Thus torque is measured as the product of the force multiplied by the distance from the axis and the units of measurement are commonly in foot-pounds or newton-metres. Continue reading

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Load Cells

Posted on May 23, 2011 by philgnorris

A particular form of force sensor in common use today is the load cell which finds wide application in construction plants, weighbridges, building earthquake monitors and process plant silo batch weighers.  These take many forms and we will be looking at these today.

Mode of operation

The electrical resistance measurement in four strain gauges arranged in a wheatstone bridge circuit is at the heart of the modern load cell or force sensor.   The four strain gauge resistors are firmly set in a vertical plane as four sides of a square.  The wheatstone bridge circuit is powered by a constant 5V,  10V or 18V DC power source and the instrumentation is set to give a digital output signal that is calibrated in weight units. Continue reading

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What Is A Force Sensor?

Posted on May 23, 2011 by philgnorris

Welcome to our new website entirely given over to the ins and outs of force sensors, the types available, applications and what’s coming up.  You will be able to get an unbiased opinion – just the facts and some engineering opinion rather than sales speak – so read on.

The definition of a force sensor (according to Wikipedia) is a device that converts a phyical applied force into another form of energy.   Other words for this are transducer,  strain cell, strain gauge touch sensor or load cell.  The application for force sensors are very wide ranging from compression load cells in structural buildings that measure  dynamic forces of 100′s or even 1,000′s of tonnes, to the force sensitive resistor (FSR) that can detect microscopic strains and is used typically for concealed alarms. Continue reading

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