Principal Stress, VonMises Stress , Fatigue

In summary: M notes that in a ductile material, the crack's growth is governed by the direction of the principal stress and whether this principal stress is tensile or compressive. So, for example, in fatigue for weldings, you should verify which principal stress vector is more perpendicular to the path of the growing crack, and whether its fluctuation is tensile or compressive, as only the tensile stress cycle will make the crack grow. Sometimes, the design rules do not allow you to apply von Mises stress (or the Principal stress components) for fatigue analysis, and you have to stick with one or the other.
  • #1
harsunra
10
0
1. I didnt understand why some people extracting Principal stress for aluminum material

which is subjected to dynamic loads(acceleration).Why not Von Mises?

2. Which has more advantages in predicting Fatigue Life and how?

3. How will you distinguish between tensile and compressive stress, when extracting

Principal & Von Mises.
 
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  • #2
Sorry if this is stating things that you already know.

The difference (from the way I understand it) is under what conditions the analyst thinks the part will fail. I don't think it changes just because it is a fatigue study.

For ductile materials Von Mises is usually used (in school we used this for fatigue) and for brittle materials Principal stresses are normally used.

If you think the part will fail when the tensile (or compressive) stress goes above the materials yield stress then you would look at the Principal stresses. You would use Von Mises if you think the part will fail when the strain energy goes above the yield stress of the material.

I don't know a way of extracting the Principal stresses if you only have the resulting Von Mises.

HTH,
Dan
 
  • #3
Choosing which stress vector will be applied is not only a matter of ductility-brittleness. In ductile materials fatigue, the crack's growth is governed by the direction of the principal stress and whether this principal stress is tensile or compressive. So, for example, in fatigue for weldings, you should verify which principal stress vector is more perpendicular to the path of the growing crack, and whether its fluctuation is tensile or compressive, as only the tensile stress cycle will make the crack grow.

Sometimes, the design rules do not allow you to apply von Mises stress (or the Principal stress components) for fatigue analysis, and you have to stick with one or the other. This is more for safety reasons than to be cost effective.

Compressive or tensile information is not kept after computing the von Mises equivalent stress, as it is always positive.
 

Related to Principal Stress, VonMises Stress , Fatigue

What is Principal Stress?

Principal stress refers to the maximum and minimum stresses at a specific point in a material. These stresses are perpendicular to each other and represent the extreme values of stress that the material experiences.

What is VonMises Stress?

VonMises stress is a measure of the overall stress on a material, taking into account both the magnitude and direction of the stresses. It is commonly used in the study of materials to determine their strength and ability to withstand external forces.

What is Fatigue?

Fatigue is the weakening of a material over time due to repeated loading and unloading cycles. This can lead to failure of the material, even if the individual loads are below the material's ultimate strength. Fatigue is an important consideration in engineering design to ensure the longevity and safety of structures and machines.

How are Principal Stress and VonMises Stress related?

Principal stress and VonMises stress are related through the VonMises yield criterion, which states that the material will yield and deform plastically when the VonMises stress at a point exceeds a certain value. This relationship allows engineers to determine the potential failure of a material by comparing the VonMises stress to its yield strength.

How can fatigue be prevented?

Fatigue can be prevented by using materials with high fatigue strength, designing structures and machines with appropriate stress concentrations, and implementing regular inspections and maintenance to detect and address any potential fatigue-related issues. Additionally, careful consideration of loading conditions and the use of fatigue analysis techniques can help prevent fatigue failure.

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