Understanding Shear Stress in Tensile Loaded Bodies: Causes and Effects

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Discussion Overview

The discussion revolves around understanding shear stress in bodies subjected to tensile loads, particularly focusing on how shear stresses can arise in such conditions and the implications for material failure. Participants explore concepts related to stress distribution, failure criteria, and the relationship between shear strength and tensile strength.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant questions how a body under pure tensile load can fail by shear and seeks to understand the induction of shear stresses in this scenario.
  • Another participant explains that stress is present throughout the body and that shear stress can arise on planes oriented at angles to the principal stress directions.
  • A participant raises concerns about ensuring that materials fail by pure tension rather than shear, given that shear strength is typically less than tensile strength.
  • Another response discusses failure criteria in terms of stress tensors and suggests that the mathematical expression of these criteria accounts for both normal and shear stresses.
  • One participant requests further clarification on the relationship between stress components and failure criteria, indicating difficulty in understanding the explanation provided.
  • A later reply notes that detailed explanations may require mathematical context and suggests a resource for further reading on the Von Mises yield criterion.

Areas of Agreement / Disagreement

Participants express uncertainty regarding the conditions under which shear stresses are induced in tensile-loaded bodies and how to ensure failure by tension rather than shear. Multiple competing views remain on these topics, and the discussion does not reach a consensus.

Contextual Notes

Participants reference the need for mathematical formulations to fully understand the concepts discussed, indicating that some assumptions and definitions may be necessary for clarity. The discussion also highlights the complexity of stress analysis in materials under different loading conditions.

sriram123
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Hi all,

I'm having problems with visualising shearforce for a body.Let us take a rectangular prism and fix one of its ends.Let the other end be subjected to a tensile force T Newtons.The normal stress acting on the cross section is the tensile force /area of cross section perpendicular to it.The net effect will be to produce elongation in the bar.I know that the shear loads are applied tangentially to the cross section of the body,In that case how does a body loaded by pure tensile load fail by shear ? how are shear stresses induced in this condition?.And why is shear strength for a material less than the tensile strength ?

Thanks in advance
 
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sriram123 said:
Hi all,

I'm having problems with visualising shearforce for a body.Let us take a rectangular prism and fix one of its ends.Let the other end be subjected to a tensile force T Newtons.The normal stress acting on the cross section is the tensile force /area of cross section perpendicular to it.The net effect will be to produce elongation in the bar.I know that the shear loads are applied tangentially to the cross section of the body,In that case how does a body loaded by pure tensile load fail by shear ? how are shear stresses induced in this condition?.And why is shear strength for a material less than the tensile strength ?

Thanks in advance

This is a very good question. Think of a plane crossing through your rectangular prism at an arbitrary angle. The stress in your body is not just at the ends, but it is also present at all locations throughout your body. So there is stress acting on both faces of the plane. The material on one side of the plane exerts a stress on the material on the other side of the plane, and the material on the other side of the plane exerts an equal but opposite stress on the material on the first side of the plane. But, because the plane is oriented at an angle to the axis of the prism, the stress on the plane is not perpendicular to the face of the plane. There is a component of stress tangent to the plane. This is the shear stress on the plane. In general, if you take an arbitrary plane within a body and ask what the stress is that is acting on this plane, unless the plane is perpendicular to one of the principal directions of stress, there will be a shear stress on the plane.
 
@ chestermiller Thanks for you Reply
When we are plotting a stress strain curve for a material in tension ,How do we ensure that the material will fail by pure tension (Necking for ductile materials)?.If shear strength is less than tensile strength won't the material fail by shear first?.Then how can we find yield strength and Ultimate tensile strength ?.I learned that care will be taken that the material will not fail by bending but the shear failure ?How do we ensure that it won't happen?
 
sriram123 said:
@ chestermiller Thanks for you Reply
When we are plotting a stress strain curve for a material in tension ,How do we ensure that the material will fail by pure tension (Necking for ductile materials)?.If shear strength is less than tensile strength won't the material fail by shear first?.Then how can we find yield strength and Ultimate tensile strength ?.I learned that care will be taken that the material will not fail by bending but the shear failure ?How do we ensure that it won't happen?
Another good question. Usually, the failure criterion is expressed in terms of all the components of the stress tensor within a single tensorially correct scalar relationship. When a certain function of the stress components exceeds a critical value (for the material), the material will fail. For simple loadings like tension on a prism, the function takes on a simple form when the axes of the coordinate system are aligned with the principal stress direction. However, the same function will give the correct answer if the axes of the coordinate system are rotated so there are shear stresses. In short, if the failure criterion is properly expressed mathematically, it doesn't matter whether there are only normal stresses present, or whether shear stresses are also present.
 
"For simple loadings like tension on a prism, the function takes on a simple form when the axes of the coordinate system are aligned with the principal stress direction. However, the same function will give the correct answer if the axes of the coordinate system are rotated so there are shear stresses"

I could not follow that can you please explain in more detail?

Thanks in Advance
 

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