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Which of the following is the most appropriate theory of failure for mild steel?
- a)Maximum principal stress theory
- b)Maximum principal strain theory
- c)Maximum shear stress theory
- d)Maximum shear strain energy theory
Correct answer is option 'D'. Can you explain this answer?
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Which of the following is the most appropriate theory of failure for m...
Maximum principal stress theory (Rankine’s theory)
According to this theory, permanent set takes place under a state of complex stress, when the value of maximum principal stress is equal to that of yield point stress as found in a simple tensile test.
For design criterion, the maximum principal stress (σ1) must not exceed the working stress ‘σy’ for the material.
Note: For no shear failure τ ≤ 0.57 σy
Note: For no shear failure τ ≤ 0.57 σy
Graphical representation
For brittle material, which do not fail by yielding but fail by brittle fracture, this theory gives satisfactory result.
The graph is always square even for different values of σ1 and σ2.
Maximum principal strain theory (ST. Venant’s theory)
According to this theory, a ductile material begins to yield when the maximum principal strain reaches the strain at which yielding occurs in simple tension.
For no failure in uni – axial loading.
For no failure in tri – axial loading.
For design, Here, ϵ = Principal strainσ1, σ2 and σ3 = Principal stresses
Graphical Representation
This story over estimate the elastic strength of ductile material.
Maximum shear stress theory
(Guest & Tresca’s Theory)
According to this theory, failure of specimen subjected to any combination of load when the maximum shearing stress at any point reaches the failure value equal to that developed at the yielding in an axial tensile or compressive test of the same material.
Graphical Representation
σ1 and σ2 are maximum and minimum principal stress respectively.
σ1 and σ2 are maximum and minimum principal stress respectively.
Here, τmax = Maximum shear stress
σy = permissible stress
This theory gives satisfactory result for ductile material.
Maximum strain energy theory (Haigh’s theory)
According to this theory, a body complex stress fails when the total strain energy at elastic limit in simple tension.
Graphical Representation.
This theory does not apply to brittle material for which elastic limit stress in tension and in compression are quite different.
This theory does not apply to brittle material for which elastic limit stress in tension and in compression are quite different.
Maximum shear strain energy / Distortion energy theory / Mises – Henky theory.
It states that inelastic action at any point in body, under any combination of stress begging, when the strain energy of distortion per unit volume absorbed at the point is equal to the strain energy of distortion absorbed per unit volume at any point in a bar stressed to the elastic limit under the state of uniaxial stress as occurs in a simple tension / compression test.
It gives very good result in ductile material.
It cannot be applied for material under hydrostatic pressure.
All theories will give same results if loading is uniaxial.
Most Upvoted Answer
Which of the following is the most appropriate theory of failure for m...
I think , the failure of mild steel is essentially due to cup and cone formation unlike HYSD bars . and cup and cone failure happens coz of shear strain.
correct me If I am wrong .
correct me If I am wrong .
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Which of the following is the most appropriate theory of failure for m...
Maximum shear strain energy theory
The most appropriate theory of failure for mild steel is the Maximum shear strain energy theory. This theory is also known as the Distortion Energy theory or Von Mises-Hencky theory.
Explanation:
Mild steel is a ductile material, which means it can undergo significant plastic deformation before failure. Therefore, the theory of failure for mild steel should be based on its ductile behavior rather than its brittle behavior.
The Maximum shear strain energy theory states that failure will occur when the total strain energy per unit volume in a material reaches a critical value. This critical value is related to the yield strength of the material.
Key points:
- The theory assumes that failure occurs when the distortion energy per unit volume reaches a critical value, regardless of the principal stresses acting on the material.
- It is based on the assumption that the total strain energy per unit volume is proportional to the total shear strain energy per unit volume.
- The theory takes into account both normal and shear stresses, but it gives more weightage to shear stresses.
- The theory is applicable to isotropic materials, such as mild steel, where the yield strength in tension and compression is the same.
Advantages of the Maximum shear strain energy theory:
1. The theory gives good correlation with experimental results for ductile materials like mild steel.
2. It provides a conservative estimate of failure, ensuring that the material is not overstressed.
3. The theory is relatively simple to apply and does not require the calculation of principal stresses or strains.
4. It is widely used in engineering design and analysis.
Limitations of the Maximum shear strain energy theory:
1. The theory is not applicable to materials that exhibit significant anisotropy or non-linear behavior.
2. It does not take into account the effects of hydrostatic stress, which can be important in some situations.
3. The theory assumes that failure occurs when the distortion energy reaches a critical value, but it does not provide any information about the mode or location of failure.
In conclusion, the Maximum shear strain energy theory is the most appropriate theory of failure for mild steel due to its ductile behavior and good correlation with experimental results.
The most appropriate theory of failure for mild steel is the Maximum shear strain energy theory. This theory is also known as the Distortion Energy theory or Von Mises-Hencky theory.
Explanation:
Mild steel is a ductile material, which means it can undergo significant plastic deformation before failure. Therefore, the theory of failure for mild steel should be based on its ductile behavior rather than its brittle behavior.
The Maximum shear strain energy theory states that failure will occur when the total strain energy per unit volume in a material reaches a critical value. This critical value is related to the yield strength of the material.
Key points:
- The theory assumes that failure occurs when the distortion energy per unit volume reaches a critical value, regardless of the principal stresses acting on the material.
- It is based on the assumption that the total strain energy per unit volume is proportional to the total shear strain energy per unit volume.
- The theory takes into account both normal and shear stresses, but it gives more weightage to shear stresses.
- The theory is applicable to isotropic materials, such as mild steel, where the yield strength in tension and compression is the same.
Advantages of the Maximum shear strain energy theory:
1. The theory gives good correlation with experimental results for ductile materials like mild steel.
2. It provides a conservative estimate of failure, ensuring that the material is not overstressed.
3. The theory is relatively simple to apply and does not require the calculation of principal stresses or strains.
4. It is widely used in engineering design and analysis.
Limitations of the Maximum shear strain energy theory:
1. The theory is not applicable to materials that exhibit significant anisotropy or non-linear behavior.
2. It does not take into account the effects of hydrostatic stress, which can be important in some situations.
3. The theory assumes that failure occurs when the distortion energy reaches a critical value, but it does not provide any information about the mode or location of failure.
In conclusion, the Maximum shear strain energy theory is the most appropriate theory of failure for mild steel due to its ductile behavior and good correlation with experimental results.
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Which of the following is the most appropriate theory of failure for mild steel?a)Maximum principal stress theoryb)Maximum principal strain theoryc)Maximum shear stress theoryd)Maximum shear strain energy theoryCorrect answer is option 'D'. Can you explain this answer?
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Which of the following is the most appropriate theory of failure for mild steel?a)Maximum principal stress theoryb)Maximum principal strain theoryc)Maximum shear stress theoryd)Maximum shear strain energy theoryCorrect answer is option 'D'. Can you explain this answer? for Civil Engineering (CE) 2024 is part of Civil Engineering (CE) preparation. The Question and answers have been prepared according to the Civil Engineering (CE) exam syllabus. Information about Which of the following is the most appropriate theory of failure for mild steel?a)Maximum principal stress theoryb)Maximum principal strain theoryc)Maximum shear stress theoryd)Maximum shear strain energy theoryCorrect answer is option 'D'. Can you explain this answer? covers all topics & solutions for Civil Engineering (CE) 2024 Exam. Find important definitions, questions, meanings, examples, exercises and tests below for Which of the following is the most appropriate theory of failure for mild steel?a)Maximum principal stress theoryb)Maximum principal strain theoryc)Maximum shear stress theoryd)Maximum shear strain energy theoryCorrect answer is option 'D'. Can you explain this answer?.
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