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Shearing Stress01:18

Shearing Stress

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.
Stress: General Loading Conditions01:15

Stress: General Loading Conditions

To grasp the intricacy of real-world conditions where multiple loads are applied simultaneously to a structure, one might visualize a section passing through a specific point within a body, aligned parallel to the xy plane. This section is subjected to various forces, including original loads, normal forces, and shearing forces.
The shearing force, possessing potential directionality within the plane of the section, is simplified into two component forces running parallel to the x and y axes.
Transformation of Plane Stress01:18

Transformation of Plane Stress

Studying stress transformation is essential in understanding how stress components within a material, like a cube under plane stress, change with rotation. This change is analyzed by considering a prismatic element within the cube. As the element rotates, the stress components acting on it—both normal and shearing stresses—change in magnitude and orientation. This change is quantified using trigonometric functions of the rotation angle, relating the forces acting on the rotated element's faces...
Shearing Strain01:20

Shearing Strain

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...
Principal Stresses01:24

Principal Stresses

The graphical depiction of normal and shearing stress equations is represented by a circle, demonstrating the interplay between these stresses under different angular conditions. The center of this circle C, located on the vertical axis, represents the average normal stress, while its radius shows the range of stress variations. At points A and B, where the circle intersects the horizontal axis, the maximum and minimum normal stresses are observed, occurring without shearing stress. These...
Components of Stress01:23

Components of Stress

Stress analysis under multiple loading conditions is intricate, necessitating a comprehensive grasp of normal and shearing stresses. Consider a small cube at point O, subjected to stress on all six faces, visible or not. Normal stress components σx, σy, σz act perpendicularly to the x, y, and z axes. Shearing stress components τxy and τxz are exerted on faces perpendicular to these axes.
Interestingly, the hidden cube faces also experience these stresses, equal and opposite to those on the...

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Updated: Jun 15, 2026

Optical Coherence Tomography Based Biomechanical Fluid-Structure Interaction Analysis of Coronary Atherosclerosis Progression
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Optical Coherence Tomography Based Biomechanical Fluid-Structure Interaction Analysis of Coronary Atherosclerosis Progression

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Local shear stress transduction.

Chanyut Kolitawong1, A Jeffrey Giacomin, Leann M Johnson

  • 1Department of Mechanical Engineering, King Mongkut's University of Technology North Bangkok, 1518 Piboolsongkram Rd., Bangkok 10800, Thailand.

The Review of Scientific Instruments
|March 3, 2010
PubMed
Summary
This summary is machine-generated.

This review classifies and analyzes over 80 local direct measurement shear stress transducers. It identifies key error sources, including misalignment and temperature gradients, crucial for accurate shear stress measurements.

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Area of Science:

  • Engineering
  • Measurement Science

Background:

  • Shear stress measurement is critical in various engineering applications.
  • Direct measurement transducers offer precise localized data.
  • A systematic review of existing shear stress transducers is needed.

Purpose of the Study:

  • To comprehensively review and classify local direct measurement shear stress transducers.
  • To analyze the primary sources of error associated with these transducers.

Main Methods:

  • Classification of transducers based on movement, measuring mode, and mechanism.
  • Subclassification into active/passive movement, static/dynamic mode, and rotational/translational mechanisms.
  • Review and tabulation of over 80 shear stress transducers.

Main Results:

  • Transducers categorized into distinct groups based on operational principles.
  • Identification of key error sources: misalignment, material ingress, surface roughness, and temperature gradients.
  • Tabulated data for over 80 different shear stress transducers.

Conclusions:

  • Accurate shear stress measurement requires careful consideration of transducer selection and potential error sources.
  • Understanding transducer classification aids in choosing appropriate devices.
  • Mitigation of identified error sources is essential for reliable data acquisition.