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UAA School of Engineering CE 334 - Properties of Materials Lecture # 18 What are Strain Gages? One of several devices that can be used to obtain strains directly. – PowerPoint PPT presentation

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Title: UAA School of Engineering


1
Strain Gage Theory
  • UAA School of Engineering
  • CE 334 - Properties of Materials
  • Lecture 18

2
What are Strain Gages?
  • One of several devices that can be used to obtain
    strains directly.
  • A small device that can be attached directly to
    the item for which strain data is required.
  • The device measures strain at the surface of an
    structural element.
  • A strain gage is a small wire grid whose
    electrical resistance changes as it strains.

3
Basic Principle
  • Professor William Thomson (Lord Kelvin) was the
    first to discover the relationship between
    electrical resistance of wires and induced
    strains.
  • Strains imposed by tensile stresses cause an
    increase in electrical resistance.
  • Strains imposed by compressive
  • stresses cause a decrease in
  • electrical resistance.

4
Uses of Strain Gages
  • Valuable tool for use by stress analysts.
  • Analyze new designs (prototypes)
  • Trouble shooting and correcting old designs.
  • Service load analysis
  • Theoretical investigations
  • Control systems.

5
Wheatstone Bridge
  • Wheatstone bridge (an electrical circuit devised
    by Sir Charles Wheatstone) is most commonly used
    to determine the change of electric resistant.
  • R1 is the active gage and is placed at the
    location where strain is to be measured.
  • R2 is a dummy gage.
  • R4 is a precision variable resistor.
  • Galvanometer is calibrated to read in strain
    units.

6
Measurement of Change in Resistance
  • Resistance changes are small. On the order of
    thousandths of an ohm.
  • Bridge is balance when Ig0
  • I1R1 I2R2 and
  • I1 I4, I2 I3, I1R4 I2R3
  • or I1/I2R2/R1,
  • I1/I2R3/R4, R2/R1 R3/R4
  • ? R1 (R2/R3)R4

7
Gage Factor
  • The gage factor, K, of a strain gage relates the
    change in resistance(?R) to the change in
    length(?L). This is constant for a given strain
    gage.
  • K (?R/R)/(?L/L) (?R/R)/?.
  • Rearrange the terms to get ? (?R/R)/K
  • Once installed, we read the change in resistance
    (?R) and use the above equation to determine the
    strain (?).

8
Points to be considered in selecting a resistance
alloy
  • Gage Factor (The higher the better)
  • Resistance (The higher the better)
  • The effect of temperature
  • Relationship between the change in resistance and
    strain (should be linear)
  • Wire size (small so as to be weaker than adhesive)

9
Temperature Compensation
Temperature Compensation
  • Reasons
  • The resistance of the wires changes with
    temperature.
  • If the temperature coefficient of the strain gage
    differs from that of the specimen, there are some
    temperature effects in the readings.
  • Temperature effects are compensated for by
    attaching the dummy gage R2 to the specimen in
    such a way that it is not strained.
  • R1/R4 R2/R3 at the balance condition.
  • if R1 R2 and ?R1 ?R2 then (R1?R1)/R4
    (R2?R2)/R3

10
Temperature Compensation and Doubling output on a
Bending Member
Temperature Compensation
  • Attach the two active
  • gages on opposite sides.
  • The circuit not only
  • compensates for temperature
  • but also doubles the
  • sensitivity.
  • Because with R1 in
  • compression and R2 in
  • tension, the resistant changes
  • of opposite signs in effect
  • add together.

R1
R2
R4
R3
11
Poisson Arrangement
Temperature Compensation
  • Temperature compensation only.
  • Attach both gages to same side but at one
    perpendicular to the direction of stress.
  • Need to know Poissons Ratio to compensate for
    strain in the dummy gage.

R1
R2
R4
R3
12
Filtering Bending Forces
P
  • R1 and R1 are used as the active gages on
    opposite sides.
  • The strain in R1gtRaxial, in R1ltRaxial.
  • The circuit adds their results and divides by
    two. Errors are canceled out.
  • It gives the true axial strain irrespective of
    any bending.

e
R1
R2
R1
R2
R4
R3
13
Placement on Shaft in Torsion
  • All four gages used.
  • Output is quadrupled.
  • Temperature is compensated.
  • Gages are measuring the principle strains.

R1
R2
R3
R4
14
Multi-element Strain Gages
  • Multi-element strain gages have 2 or more strain
    gages built into them.
  • The orientation of the gages relative to each
    other is fixed.
  • Using Mohrs Circle for strain, the magnitude and
    direction of the principle stresses can be
    computed.

15
45E Rosette
  • For the 45 deg rosette, the magnitudes of
    principle stresses
  • can be determined from basic strain
    relationships

?a
?b
?c
16
60E Rosette
  • The principle stresses and strains can be
    determine from basic relationships.
  • Advantage of the Rosettes is that they make it
    possible to determine the magnitude and direction
    of principle stresses when the direction is not
    obvious or changes with loading.

17
Specialty Gages
  • There are a myriad of specialty gages that have
    been developed for special applications.
  • Gages may vary in types of materials used or in
    configuration to meet the demands of special
    situations.
  • High heat, moist environments, and large strains
    are examples of situations that require special
    gages.

18
Advantages of Strain Gages
  • Ease of Installation
  • Relatively high accuracy
  • Adjustable sensitivity
  • Remote indication
  • Very short gage length
  • Response to dynamic strain.

19
Strain Gage Testing of a Cantilever
20
Strain Gage Testing of a Cantilever
  • Objectives
  • 1. Assist in acquiring strain gage measurements
    from a cantilever beam.
  • 2. Determine the stresses in a cantilever from
    the strain gage measurements.
  • 3. Compare the results with the theoretical
    predictions based on ES-331, the Mechanics of
    Materials course.

21
Strain Gage Testing
Have fun!
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