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Normal and Shear Force01:14

Normal and Shear Force

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When a beam is subjected to different loads, such as weight, pressure, or other external forces, internal forces are generated within the beam. These forces can have a significant impact on the overall stability and strength of the structure. Engineers use various methods to analyze and determine the magnitude and direction of these internal forces. One common technique used to determine internal forces in beams is the method of sections. This method involves considering an imaginary point or...
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Problem Solving on Stress and Strain01:22

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Stress is a quantity that describes the magnitude of a force that causes deformation, generally defined as internal force per unit area. When forces pull on an object and cause its elongation, like the stretching of an elastic band, it is called tensile stress. When forces cause the compression of an object, it is known as compressive stress. When an object is being squeezed uniformly from all sides, like a submarine in the depths of the ocean, we call this kind of stress bulk stress (or volume...
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Shearing Stress01:18

Shearing Stress

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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.
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Stress: General Loading Conditions01:15

Stress: General Loading Conditions

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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....
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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...
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Elastic Strain Energy for Shearing Stresses01:20

Elastic Strain Energy for Shearing Stresses

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As discussed in previous lessons, strain energy in a material is the energy stored when it is elastically deformed, a concept crucial in materials science and mechanical engineering. This energy results from the internal work done against the cohesive forces within the material. When a material undergoes shearing stress and corresponding shearing strain, the strain energy density, which is the energy stored per unit volume, is calculated. Within the elastic limit, where the stress is...
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Related Experiment Video

Updated: Apr 4, 2026

Introducing Shear Stress in the Study of Bacterial Adhesion
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Surface instability of sheared soft tissues.

M Destrade1, M D Gilchrist, D A Prikazchikov

  • 1School of Electrical, Electronic, and Mechanical Engineering, University College Dublin, Belfield, Dublin 4, Ireland.

Journal of Biomechanical Engineering
|December 3, 2008
PubMed
Summary
This summary is machine-generated.

Biological soft tissues wrinkle under shear due to collagen fibers. Adding fibers to elasticity models shows they can either stabilize or destabilize tissue surfaces, depending on fiber orientation and stiffness.

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Area of Science:

  • Biophysics
  • Materials Science
  • Soft Matter Physics

Background:

  • Elastomers maintain flat surfaces under shear, unlike soft biological tissues which exhibit surface buckling.
  • Soft tissues contain oriented collagen fiber bundles embedded in an elastin matrix, influencing their mechanical properties.

Purpose of the Study:

  • To investigate the surface instability of soft tissues under shear.
  • To model the effect of collagen fiber orientation and stiffness on tissue surface buckling.

Main Methods:

  • Utilized the incompressible neo-Hookean model for isotropic nonlinear elasticity.
  • Incorporated a family of parallel fibers into the elasticity model to simulate collagen bundles.
  • Analyzed the influence of fiber angle and stiffness ratio (E/μ) on surface instability.

Main Results:

  • The basic neo-Hookean model predicts surface instability only at very large shear angles (>72°).
  • The presence of fibers significantly alters surface stability, potentially reinforcing or weakening the tissue.
  • Instability is pronounced when shear is applied 'against' the fiber direction.
  • Increased fiber stiffness ratio (E/μ) broadens the range of angles leading to early instability.

Conclusions:

  • Collagen fiber orientation and stiffness are critical factors in soft tissue surface stability under shear.
  • The fiber reinforcement/weakening effect is dependent on the relative angle between fibers and shear direction.
  • Modeling with anisotropic fibers provides crucial insights into the mechanical behavior of biological soft tissues.