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Shearing Strain01:20

Shearing Strain

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The shearing strain represents a cubic element's angular change when subjected to shearing stress. This type of stress can transform a cube into an oblique parallelepiped without influencing normal strains. The cubic element experiences a significant transformation when exposed solely to shearing stress. Its shape alters from a perfect cube into a rhomboid, clearly demonstrating the effect of shearing strain. The degree of this strain is considered positive if it reduces the angle between the...
1.6K
Shearing Stress01:18

Shearing Stress

2.3K
Shearing stress, denoted by the Greek letter tau (τ), is stress caused by forces acting transversely on an object. These forces create internal ones within the entity in the plane where the external forces are applied. The resultant of these internal forces is the shear in the section.
The average shearing stress can be calculated by dividing the shear by the area of the cross-section.
2.3K

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Updated: Mar 6, 2026

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Development of a planar shear sensor.

Bruce J P Mortimer, Gary A Zets, Brian J Altenbernd

    Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual International Conference
    |March 9, 2017
    PubMed
    Summary
    This summary is machine-generated.

    This study introduces a wearable sensor for measuring both shear and orthogonal forces. This innovative device can track in-situ foot loading during walking, aiding biomechanical analysis for applications like exoskeletons and rehabilitation.

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    Area of Science:

    • Biomechanics
    • Sensor Technology
    • Wearable Devices

    Background:

    • Accurate measurement of foot loading is crucial for understanding human locomotion.
    • Existing sensors may not capture both shear and orthogonal forces simultaneously.
    • Wearable solutions are needed for in-situ biomechanical analysis.

    Purpose of the Study:

    • To describe the design and calibration of a novel wearable sensor.
    • To enable simultaneous measurement of shear and orthogonal forces.
    • To assess the sensor's utility for in-situ foot loading analysis during ambulation.

    Main Methods:

    • A planar shear sensor utilizing inductive coupling between a target and adjacent coils was developed.
    • The sensor design incorporates geometrically shaped and scaled sense coils.
    • Calibration methods for the wearable sensor were investigated.

    Main Results:

    • The developed sensor successfully measures both shear and orthogonal forces.
    • The sensor's design allows for the detection of lateral movement via changes in inductive coupling.
    • Calibration procedures were established for accurate force measurement.

    Conclusions:

    • The wearable sensor provides a new method for simultaneous shear and orthogonal force measurement.
    • This technology can be applied to measure in-situ foot loading during ambulation.
    • Potential applications include biomechanical analysis, exoskeleton development, and balance rehabilitation.