Talk:von Mises yield criterion

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It may be more accurate to delete or change

"because the stress tensor has six independent components"

The stress tensor must be positive-definite, so the components are related and only five can be independent.

Tibbits (talk) 17:19, 2 December 2013 (UTC)[reply]

Currently the links take you to the stress page; however, the deviatoric stress invariants aren't defined their. They're defined on the Cauchy stress tensor page. Should they be included on the stress page, or should we simply redirect that link to the Cauchy stress tensor subsection? Jdc2179 (talk) 12:11, 7 June 2013 (UTC)[reply]

I changed all wiki links about the stress tensor to the Cauchy stress tensor page. sanpaz (talk) 15:06, 7 June 2013 (UTC)[reply]

I think that two important details should be mentioned in the article: Firstly the fact that we are looking at a /projection/ here from an (at least) 6-dimensional space to a 3-dimensional space. Obviously, during this projection, some information of the Cauchy stress tensor gets lost... And secondly the fact that the /position/ of the stress point inside the yield surface does not have any physical meaning - except that it shows the proximity to possible yielding by its shortest distance to the surface (which in fact could more easily be shown in a one-dimensional plot). Any comments on that? Kassbohm (talk) 04:56, 18 February 2010 (UTC)[reply]

I believe your sentence, "It is most applicable to ductile materials where the ratio of the yield and ultimate strengths is near 0.577." should better read " It is most applicable to ductile materials where the ratio of the shear yield to tensile yield strengths is appx. 0.577, or 1 over the square root of 3.

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You are right, this was my mistake.

-samba6566

Since the third term is squared, it does not matter whether the sigma(x) or the sigma(z) come first (mathematically). The mathematical convention, however, is that the terms are presented in order, x then y then z with there complimentary terms following each. —The preceding unsigned comment was added by Samba6566 (talk • contribs) 23:17, 2 March 2007 (UTC).[reply]

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Was this supposed to say sigma_v over square root of 3? Readertonight 01:23, 17 August 2007 (UTC)[reply]

• You are absolutely right! Thanks! Alex Bakharev 04:09, 17 August 2007 (UTC)[reply]

I started improving the section on the Yield Criterion, and then realized that both sections within this article are redundant. Which made me think that this article needs to be re-organized and include the following: 1- what the von Mises yield criterion states (definition and assumptions) 2- equations and figures for the yield function and yield surface 3- equations for the different stress conditions (triaxial, biaxial, uniaxial, and pure shear) 4- The Flow Rule Associated with the von Mises Yield Function I will try to re-organize this article according to these suggestions. Please comment Sanpaz 00:39, 1 December 2007 (UTC)[reply]

I just posted the new version of the article. I know it is a huge change, but I saw necessary to add more content and re-organize the article. There is still more to be added. I apologize for the big change. Please comment Sanpaz 02:39, 4 December 2007 (UTC)[reply]

It needs an introductory paragraph and those horizontal lines ought to be removed in favor of sections... I'll get to it later but for now I'll add the page to Wikipedia:WikiProject Engineering. --Explodicle 19:10, 4 December 2007 (UTC)[reply]

These changes deviate the intent of the article. The article is about the overall yield criterion, not solely about the interpretation of, or the use of it(von vises stress). However, the concept of von mises stress needs to be included. Sanpaz (talk) 18:36, 19 January 2008 (UTC)[reply]

I reintroduced the concept of Equivalent stress or von Mises stress into the article, but into its correct spot within the context of the article (i.e. in the uniaxial stress condition section ). Sanpaz (talk) 20:06, 19 January 2008 (UTC)[reply]

I found a much more succinct and usefully answer on yahoo answers.

"What is Von Mises Stress in layman terms?

Good question. Von Mises Stress is actually a misnomer. It refers to a theory called the "Von Mises - Hencky criterion for ductile failure".

In an elastic body that is subject to a system of loads in 3 dimensions, a complex 3 dimensional system of stresses is developed (as you might imagine). That is, at any point within the body there are stresses acting in different directions, and the direction and magnitude of stresses changes from point to point. The Von Mises criterion is a formula for calculating whether the stress combination at a given point will cause failure.

There are three "Principal Stresses" that can be calculated at any point, acting in the x, y, and z directions. (The x,y, and z directions are the "principal axes" for the point and their orientation changes from point to point, but that is a technical issue.)

Von Mises found that, even though none of the principal stresses exceeds the yield stress of the material, it is possible for yielding to result from the combination of stresses. The Von Mises criteria is a formula for combining these 3 stresses into an equivalent stress, which is then compared to the yield stress of the material. (The yield stress is a known property of the material, and is usually considered to be the failure stress.)

The equivalent stress is often called the "Von Mises Stress" as a shorthand description. It is not really a stress, but a number that is used as an index. If the "Von Mises Stress" exceeds the yield stress, then the material is considered to be at the failure condition.

The formula is actually pretty simple, if you want to know it: (S1-S2)^2 + (S2-S3)^2 + (S3-S1)^2 = 2Se^2 Where S1, S2 and S3 are the principal stresses and Se is the equivalent stress, or "Von Mises Stress". Finding the principal stresses at any point in the body is the tricky part."

I find this a lot with engineering articles, they are all written at graduate student level. But if you think about it, someone of that level, wouldn't need to look this up. Try to write these kinds of articles in such a way that someone can be like "wait, what is von mises stress anyways", and then they can come here and figure it out. Not many people ask "wait, what was the mathematical approximation you used to find this von mises stress" —Preceding unsigned comment added by 75.162.56.142 (talk) 23:43, 9 March 2008 (UTC)[reply]

I have shad more light on the meaning of the yield strength with respect to the yield criterion. IMHO, it makes best sense to describe the yield condition such that it is met when the von Mises stress reaches the yield strength. The previous version, though formally a correct alternative, did not show this. It used a critical stress k that was related but not equal to the yield strength. This is neither instructive nor common practice, at least not in my surrounding.

Unfortunately, my changes induce many consistency changes, namely the factor 3, when the squared alternative of the yield criterion was used. I am afraid, I might have missed some instances, when screening the text. I will check more often the consistency of this article in the coming days and try to eliminate all errors that I might have introduced. However, I would deeply appreciate your assistance with that.

I hope everyone agrees that the yield criterion: influence - resistance = 0 is better stated with the yield strength being the resistance. I am sorry for the amount of work this conceptual change induces. Tomeasy (talk) 09:03, 23 April 2008 (UTC)[reply]

I have to review closely what you just changed. My first impression is that the changes you made are not consistent with what most plasticity books present. The subsection you added about Arbitrary load is not really an arbitrary load. This topic was already covered in the "Uniaxial Stress" subsection (Von Mises criterion is just a simplification from Uniaxial to triaxial load). So this subsection you created should be deleted. Any comments?Sanpaz (talk) 15:13, 23 April 2008 (UTC)[reply]

You are right, there are probably still inconsistencies with the remainder of the earlier version and I am sorry that. As I said, I am not yet done and I would appreciate your help.

The clue about the arbitrary load section is that, in deed, it holds for all loading cases, so even the triaxial one you mentioned. The only assumption is the symmetry of the stress tensor (which, I think, we should actually mention somewhere. As you probably know, many theories exist where this assumption is not made). The uniaxial stress, however, is much more special in that it has only one principal stress unequal zero. As you can see from my formula, it states (correctly) the dependence on three arbitrary principal stresses, which is a prerequisite if one wants to capture triaxial loading cases. Remains only the question as to whether the formula is correct. I can give you my word that it is and I am working on metal plasticity every day. This statement is of course not sufficient, but there are sources given below. Anyway, since you seem to like what has been in the article before, please observe that my formula is and has been used (underwater) in the section mathematical formulation. I guess you agree that the yield function as it is introduced there is valid for any loading case.

What do you think about my main point, that is to state the yield criterion as a comparisson of the yield strength and the von Mises stress. Actually this is the only thing I changed. Besides this I did not change a single assumption or concept. What was before compared the von Mises stress divided by sqrt(3) to the yield strength divided by sqrt(3). Qualitatively, this is the same, because one is interested in the sign of this function rather than it's value. However, it is uncommon and most important for Wikipedia by far less instructive. As you explained the yield strength is determined in a simple uniaxial loading experiment and we can assume that relatively many people are familiar with that and the result: the yield strength of the material. Therefore, it makes sense to formulate the criterion on basis of this popular quantity.

You mentioned sources. Since the topic is quite basic there are abundant. I have not found any that formulates according to the earlier state of the article. However, I do not doubt it exists, since it is also correct. I give you two text book references from the most famous people who are doing research in my field, that is Computational Mechanics. Both compare the equivalent stress (the von Mises stress) to the yield strength:

* Simo JC and Hughes TJR (1998) Computational Inelasticity, Springer-Verlag, New York.

* Belytschko T, Wing KL, and Moran B (2000) Nonlinear Finite Elements for Continua and Structures, Wiley, Chichester.

Tomeasy (talk) 16:57, 23 April 2008 (UTC)[reply]

To clarify: ${\displaystyle \sigma ^{dev}=s_{ij}(\mathbf {e} _{i}\otimes \mathbf {e} _{j})={\boldsymbol {\sigma }}-{\frac {1}{3}}\left({\boldsymbol {\sigma }}\cdot \mathbf {I} \right)\mathbf {I} }$. This concept is already in the subsection Uniaxial Stress. The convention on how is written is different, though. I just undid the deletion of the subsection. I will try to understand well your point first.Sanpaz (talk) 17:16, 23 April 2008 (UTC)[reply]

Thanks for your efforts. Again you are right, the deviatoric stress is defined twice and we should eliminate one. I allowed myself to correct your formula, since a tensor basis is formed by the dyadic product of two basis vectors and not just one. This way they are in deed identical. Tomeasy (talk) 17:31, 23 April 2008 (UTC)[reply]

Thanks for the correction in sij Sanpaz (talk) 17:37, 23 April 2008 (UTC)[reply]

I understand what you are suggesting now. Pretty much, we are talking about different ways of showing or expressing the Von Mises Criterion. You are suggesting to express the criterion as a function of ${\displaystyle \ \sigma _{v}}$. However, the original formulation by Von mises,(see [1], says that yielding occurs when ${\displaystyle \ J_{2}}$ reaches a critical value ${\displaystyle \ k}$. However, the Von mises stress ${\displaystyle \ \sigma _{v}}$ is a concept derived or obtained from this formulation. It is an interpretation of the formulation. This interpretation is that to obtain the yield strength of material loaded triaxially (3-D) one needs only the yield strength of the material obtained from uniaxial tests. This uniaxial strength is the Von Mises Stress ${\displaystyle \ \sigma _{v}}$. So, my suggestion is to be general in the formulation, and later talk about the interpretations given to the formulation, which is what the article had before.Sanpaz (talk) 19:40, 23 April 2008 (UTC)[reply]

Hill is a perfect reference, but so are mine.

The formulation that I advocate is by no means less general than the one you prefer. In fact, they are equivalent. So please, do not claim otherwise or give a basis to your claim.

As I already explained, the yield strength is the most instructive critical value. Please react on this claim of mine. I find instructiveness is an important point when editing Wikipedia.

to obtain the yield strength of material loaded triaxially (3-D) one needs only the yield strength of the material obtained from uniaxial tests. There is only one yield strength! No triaxial strength, uniaxial strength, etc.

This uniaxial strength is the Von Mises Stress ${\displaystyle \ \sigma _{v}}$. No. Again there is no uniaxial strength. The rest is just wrong. The von Mises stress in not the strength. The strength is a material constant, while the von Mises stress depends on the loading. In the special case of an unloaded material it is simply zero.

OK, with the last two points it may be that I just explained you what you had already known. If so, then my apologies but also please try to formulate more precisely. Tomeasy (talk) 20:09, 23 April 2008 (UTC)[reply]

• "The formulation that I advocate is by no means less general than the one you prefer. In fact, they are equivalent.":

I have not disagreed with that. That's why I said that we are just talking about different ways of expressing the criterion.

• "There is only one yield strength! No triaxial strength, uniaxial strength, etc."

I should have written: to obtain the yield strength of material loaded from any direction (3-D) one needs only the stress at yield of the material obtained from uniaxial tests. And, there are such things as uniaxial strength, shear strength, biaxial strength...

• "No. Again there is no uniaxial strength. The rest is just wrong. The von Mises stress in not the strength. The strength is a material constant, while the von Mises stress depends on the loading. In the special case of an unloaded material it is simply zero."'

I won't argue that. What I was trying to state was that the uniaxial stress at yield is the same Von Mises Stress ${\displaystyle \ \sigma _{v}}$.

• I still think the criterion should be stated based on J2 and not ${\displaystyle \ \sigma _{v}}$. I prefer the idea of starting the formulation with J2 and then later coming to the definition of the von mises stress ${\displaystyle \ \sigma _{v}}$. I still see ${\displaystyle \ \sigma _{v}}$ as a conclusion or interpretation of the criterion, and not the original thinking of the criterion. See [2] Perhaps there in a better way to emphasizes your point about ${\displaystyle \ \sigma _{v}}$ is some other way without changing the general formulation.
• I know what is the intent of the Arbitrary Loading Condition section. Before, this condition was addressed in the general explanation for the criterion, it was implied in the Mathematical Formulation, as it was presented as a general state of stresses, and it was not particularly included in the section about Different Stress Conditions (this section was for particular stress cases such as uniaxial, pure shear, etc). I think that is fine that you have included the general condition.

Sanpaz (talk) 01:30, 24 April 2008 (UTC)[reply]

It's not only the uniaxial stress at yield [that] is the same [as the] von Mises stress. Even at any other point of the uniaxial loading curve the uniaxial stress is equal to the von Mises stress. Reason is, as the article shows, that under uniaxial loading the uniaxial stress is identical to the von Mises stress. Further, at yield (the event that you pointed at) it additionally holds that this unixaial stress cum von Mises stress equals in magnitude also the yield strength and the yield function is zero.

Sorry for being so picky on words, but I think we should try to make correct statements only.

So, my suggestion is to be general in the formulation, that's why reacted a little bit affected. Thanks for your clarification.

OK, one more source. Again a very good one. I do not doubt there are hundreds. Shall I show you more sources that employ my formulation?

Proposition: Let's simply discuss, why giving your or my proposition preference is better.

My main point is (1) instructiveness. But also (2) the physical unit, which is Pa for the von Mises stress, whereas J2 first has to be raised to 0.5 to match it with some critical strength, which is not even the yield strength. Another point is (3) that von Mises plasticity namely applies to metals and their strength is not measured by a shear experiment, which is probably the most simple to measure for soils, but in a uniaxial tensile test. I have not seen similar arguments to your position apart from pointing at (very good) references, which, however, I am equally doing.

Tomeasy (talk) 11:43, 24 April 2008 (UTC)[reply]

I have to be honest with you, I really do not like much the new formulation. Not that it is not correct, but it is not what most books that I am familiar with would explain (a good example is Hill's book which is a very well known book). And if I were new to Wikipedia and I knew about the topic and I saw this formulation as it is now, I would be hesitant about the whole formulation. I already explained a few comments above the reason for my position on the subject, but I would like to state it again: The original formulation by Von Mises stated that yielding occurred when the value of the second deviatoric stress invariant ${\displaystyle J_{2}}$ reaches a certain value. The formulation you are proposing, to me, is just an interpretation which substitutes ${\displaystyle J_{2}}$ as a function of a new stress value called Von Mises stress (I do not know who came up with that term, it would be interesting to know though). Perhaps the fields we worked on treat the criterion differently. I am a civil engineer so I am use to the other formulation.

So, what I would prefer is to state the criterion the classic way (the way it was before), and expand the formulation to account for the Von Mises stress ${\displaystyle \sigma _{v}}$ as you are proposing now. This way, I think it will give more clarity to the article. Think about what I just wrote, you do not need to reply now nor change anything in the article. But consider what I am suggesting. - Sanpaz (talk) 00:25, 28 April 2008 (UTC)[reply]

Ok, you are really challenging my references, claiming their formulation was less classical. Note, that I had appreciated your sources and that my argumentation was so far was not based on whose references are the better. Since you choose not to argue about the points that I find important with respect to wikipedia editing, I turn to the only point that seems to interest you: What is more classical, common, or accepted.

The authors of the text books have according to ISI - web of sience the foolowing h-indices: Belytschko (59), Hughes (57), Simo(50). For sure, Hill (I wasn't able to get his exact number for there are to many R. Hill), as a great scientist, has also a high h-index, but probably lower than the one's I mentioned. At least one can say, according to this most objective numerical measure, it appears inappropriate to deem their way of writing just an interpretation of the original form. Actually we are not talking here about an interpretation as the forms are mathematically identical. I find the term interpretation derogative in this discussion.

Looking what the internet, here google, offers to von Mises yield criterion is also revealing. I just researched the first three non-wikipedia hits. Those were the hits # 2, 3, and 4. Wikipedia was on top :-) Hit #2: Engineering Fundamentals makes the statement as I propose. #3: NASA ditto. #4 University of Cambridge formulates the criterion in a way that is neutral to your and my proposition. When becoming specific, however, they first turn to the uniaxial case and consequently write From above, if, s1 = Y, s2 = s3 = 0, then the constant is given by 2Y2. This is the von Mises Yield Criterion. Your proposition is later attended by the words The von Mises criterion can therefore be expressed as:. I really did not look into more items on google. Therefore, I expect the large majority will follow the formulation that I advocate.

So much to the point that appears of sole significance to you. Nevertheless, I find instructiveness, applicability important points to consider as well. It would be nice, if you attended those concerns as well or give reasons for ignoring this line of thought.

Tomeasy (talk) 00:28, 29 April 2008 (UTC)[reply]

It is not a discussion of who has the best reference. It is a discussion of what is the best way to present the criterion. Von Mises did not formulate his criterion thinking about a Von Mises Stress. Some body else came up with that term later. He simply stated that yielding occurred when ${\displaystyle \ J_{2}}$ reached a certain numerical value. He just formulated his criterion on mathematical grounds. Knowing that the formulation is ${\displaystyle \ f(J_{2})={\sqrt {J_{2}}}-Constant=0}$, one can deduce from the case of pure shear that the Constant is the yield stress in pure shear, ${\displaystyle \ k}$. Later, in the case of uniaxial stress conditions, one can deduce that ${\displaystyle \ k={\frac {\sigma _{y}}{\sqrt {3}}}}$, where ${\displaystyle \ \sigma _{y}}$ is the yield stress in uniaxial tension, which you called ${\displaystyle \ {\bar {\sigma }}}$ in your formulation. And that is the logical order in which the article should present the information. Your formulation simply jumps straight away into formulating the criterion as a function of the yield stress in uniaxial tension, ${\displaystyle \ {\bar {\sigma }}}$, and modifies the first term of the criterion into the von Mises stress by multiplying the original formulation by ${\displaystyle \ {\sqrt {3}}}$

${\displaystyle \ {\begin{aligned}f(J_{2})&={\sqrt {3}}\left({\sqrt {J_{2}}}-k\right)=0\\f(J_{2})&={\sqrt {3J_{2}}}-{\bar {\sigma }}=\sigma _{v}-{\bar {\sigma }}=0\end{aligned}}}$

and that is why you obtain your formulation, which is correct, but is not how the criterion was formulated.

Maybe that is the conclusion to our discussion: Just to formulate the criterion in that order.

And that is it. That is my reasoning which I think is correct. I don't have anymore to say about the subject. I cannot be more clear than that. This discussion was good to make things more clear about the subject, but I don't see the point of going on and on about it. Cheers - Sanpaz (talk) 00:22, 1 May 2008 (UTC)[reply]

I am unable to comprehend what is said about the maximum octahedral shear stress. Especially I have a problem with the second part of this equation

${\displaystyle \tau _{oct}={\sqrt {{\frac {2}{3}}J_{2}}}={\sqrt {\frac {2}{3}}}k}$.

The first part simply states the shear stress acting on the octahedron, but where does the second part come from. It is important to mention that the equation stated above is still based on a formulation of the yield criterion that compares the square root of ${\displaystyle J_{2}}$ to a critical value, which is equal to the shear stress at the onset of yielding in a pure shear experiment. Please note, that at present the remainder of the article is based on a yield formulation that compares the von Mises stress to the yield strength, which is equal to the tensile stress at at the onset of yielding in a uniaxial tensile experiment.

While trying to adjust this section to the latter formulation, I am in trouble, because I do not understand the second part of the equation in the first place. According to my naive thinking the shear stress on the octahedron at at the onset of yielding should (with the first formulation of the yield criterion in mind) simply equal the critical value k, and not ${\displaystyle {\sqrt {\frac {2}{3}}}k}$. I probably miss a point here, perhaps some geometric reason. Can anyone help me out so that a consistent version can finally be established?

Independent from this, I acknowledge that it is not yet decided which formulation should stand in the end. However, my question to the above formula exist even if the yield criterion is stated as in the earlier version. Moreover, I am trying to establish a consistent version of the yield strength based formulation, so that in the end we can simply choose between the two, both being formally OK. This section is the last piece that lacks this consistency. Tomeasy (talk) 08:34, 25 April 2008 (UTC)[reply]

With the previous formulation, the value of the octahedral shear stress is

${\displaystyle \tau _{oct}={\sqrt {{\frac {2}{3}}J_{2}}}={\sqrt {\frac {2}{3}}}k}$, which is obtained by replacing the von mises criterion equation ${\displaystyle \ J_{2}=k^{2}}$ with k being the yield stress in pure shear. But with the new formulation that you are proposing you have to change the value of k for ${\displaystyle \ {\bar {\sigma }}}$ - Sanpaz (talk) 00:25, 28 April 2008 (UTC)[reply]

I was afraid it is. Well then we should delete this whole paragraph, since it does not state anything else then what the octahedral shear stress is. One might argue to leave that, even though one can find it also on the respective page. Definitely misleading is the conclusionthat anything reduces here to the yield criterion, as if the yield criterion was derived her. That's how I erroneously understood it. What is actually done here, as you explain, is that the yield criterion is inserted in the formula for the octahedral shear stress, nothing more. Any further claim is a short circuit. Of course, the formula will then contain this information. Note, this thread is independent from the discussion on how to formulate the criterion. Even with the criterion being based on the yield strength, the reduced to formulation is senseless. Tomeasy (talk) 17:24, 28 April 2008 (UTC)[reply]

Another thing: The precedent text states: yielding begins when the octahedral shear stress reaches a critical value k. And then it is stated \tau_{oct} =...= \sqrt{2/3} k. To say the least this is very confusing. You have explained that therein the yield criterion is used. This is admitted if the stated formula applies to the state at the onset of yielding, which is also implied by the text. So the text and the formula should in deed harmonize, which they don't. Hence, it's not only confusing, but also wromg somewhere. Btw, nothing to do with k being the yield strength or the root of J2. Tomeasy (talk) 17:49, 28 April 2008 (UTC)[reply]

For reference, Elastic and Inelastic Stress Analysis by Shames and Cozzarelli first describe the Tresca yield criterion, then the Mises yield criterion in the classic ${\displaystyle J_{2}}$ way. Then they describe the maximum distortion strain-energy theory and the octahedral stress theory and then shows those two to be the same as the Mises theory. It gives a footnote:

"The physical interpretation of the Mises yield criterion via the maximum distortion energy theory was suggested by H. Hencky in 1924. The interpretation based on the octahedral stress concept was proposed by A. Nadai in 1937. Other interpretations have also been proposed. See R. Hill, The Mathematical Theory of Plasticity (New York: Oxford University Press, 1950), Chap. 2."

—Ben FrantzDale (talk) 01:30, 29 April 2008 (UTC)[reply]

I have set up a new article for the von Mises stress. I think can take a little bit the pressure away as to how formulate things on this page. Actually, one could delete now the equations stated in the subsection arbitrary loading conditions as they are double now on the new page. I will leave this deletion to other users, since I am not disturbed by this redundancy. Tomeasy (talk) 06:01, 27 April 2008 (UTC)[reply]

I don't think there is a need to create another article about this, if it is already in this article. I would delete that article.Sanpaz (talk) 23:34, 27 April 2008 (UTC)[reply]

I have substituted the value k by the fracture strength, as can be done if the yield criterion is stated the way it currently is. This simplifies the whole article enormously. That's why I chose to do so. However, should we decide in the future to step back to the generic critical value (the one that equals the square root of J2) than we will also revert these edits. Please, comment on what you prefer. Tomeasy (talk) 06:05, 27 April 2008 (UTC)[reply]

I appreciate this description of Von Mises yield criterion as a graduate-level discussion of the concept. However, when I imagined that my undergraduate students might look up "von Mises stress" on wikipedia, I felt that they would be confused by this article.

The context in which the average person would be searching wikipedia for "von Mises" is its connection to the maximum distortion energy failure theory. I was surprised to discover that there is no article describing the maximum distortion energy failure theory as referenced by this article.

I admit that precedence may be an issue. One undergraduate text, Shigley's Mechanical Design, gives precedence to von Mises, but a similar text, Juvinal and Marshek, attributes several others as potential originators of the max distortion theory concept.

In any case, would it be a good idea for someone to create a distortion energy entry for the benefit of people who require a pedestrian understanding of this topic?

Thanks, Deltapapamike (talk) 04:53, 8 June 2009 (UTC)[reply]

In the equation → (sigma1)^2-sigma1*sigma2+(sigma2)^2=3k^2=sigmaY^2 ...sigmaY above refers to the yield strength. This equation does not equal yield strength. This equation should equal Sigma_e (Von Mises stress in my mech. design book) or Sigma_v as denoted in this article. Someone take a look at this and fix if this is indeed incorrect. It could be confusing to someone if it is equaling the yield strength instead of the Von Mises stress. I realize that for the Von Mises failure criterion sigma_e=Sy÷n where n is the safety factor and if it is 1, Sy can = Sigma_e but this is not always the case pbviously. So this formula should be changed. 192.91.173.36 (talk) 21:20, 17 December 2009 (UTC)[reply]

The formula is correct. One reference to confirm it Plasticity for Structural Engineers page 78sanpaz (talk) 17:30, 18 December 2009 (UTC)[reply]

I believe tau13 should be tau12 in the conditions column. I'm not involved in this article. Someone please change it, it's really bugging me. Thanks.--67.59.60.122 (talk) 12:37, 14 December 2011 (UTC)[reply]

Fixed sanpaz (talk) 16:28, 14 December 2011 (UTC)[reply]

I like to use ${\displaystyle \tau }$ (tau) for shear stress, to help make it obviously different from normal stress. All my engineering books use tau for shear. I realize that some/older books use sigma for both kinds of stress. I know of one asme code that uses it both ways. Is there and advantage to using sigma for shear stress? Is tau typically used for something else? --Zojj tc 19:20, 25 February 2012 (UTC)[reply]

In many textbooks stresses are denoted by ${\displaystyle \sigma _{ij}}$ where i and j indicate the direction of the surface normal and stress, respectively. Hence, ${\displaystyle \sigma _{11}}$ is the normal stress acting on the surface "1" and ${\displaystyle \sigma _{12}}$ is the component of the shear stress on the same surface acting in the "2" direction, et c. I guess it makes for more compact writing using tensor notation and stuff. Baxtrom (talk) 16:31, 29 February 2012 (UTC)[reply]

I agree, it should be ${\displaystyle \tau }$. I'm a mechanical engineer, and without exception, none of any of my textbooks used ${\displaystyle \sigma }$ for shear. All of them used ${\displaystyle \tau }$. Also, since the Wikipedia article about Shear uses ${\displaystyle \tau }$, consistency dictates this article should too. Xiph1980 (talk) 10:35, 9 May 2016 (UTC)[reply]

I don't understand the formula for the deviatoric stress matrix as specified in the article,

${\displaystyle {\boldsymbol {\sigma }}^{dev}={\boldsymbol {\sigma }}-{\frac {1}{3}}\left({\boldsymbol {\sigma }}\cdot \mathbf {I} \right)\mathbf {I} }$

shouldn't it be something like

${\displaystyle {\boldsymbol {\sigma }}^{dev}={\boldsymbol {\sigma }}-{\frac {1}{3}}{\mbox{tr}}({\boldsymbol {\sigma }})\mathbf {I} }$

cheers / Baxtrom (talk) 12:41, 29 February 2012 (UTC)[reply]

Thanks for pointing that out. It is better like this

${\displaystyle {\boldsymbol {\sigma }}^{dev}={\boldsymbol {\sigma }}-{\frac {1}{3}}\left({\mbox{tr}}\ {\boldsymbol {\sigma }}\right)\mathbf {I} }$

sanpaz (talk) 17:23, 29 February 2012 (UTC)[reply]

Why is there no hint about the physical reasoning that lead to the development of the von Mises yield criterion in the first place? It was well known that shear stress is what drives ductile yielding. This is the reason the Tresca (max shear) criterion was developed. But in multi-axial loading (more than just pure shear and simple tension/compression), it was noted that Tresca led to incorrect (conservative) predictions of yield, and that indeed there was need for terms in the failure criterion that coupled stresses in different directions. So, von Mises proposed that the stress components be decomposed into a hydrostatic (average normal stress) component, and whatever was left over to get the original stress state back (the deviatoric component). He then proposed that the hydrostatic component (because it involves no shear) be ignored, and worked only with the deviatoric component. Using the generalized Hooke's law, he calculated the strain energy density of only the deviatoric component for general 3-D loading.

He then proposed calculating the deviatoric strain energy density for any specific loading under consideration, and comparing it to the deviatoric strain energy density of a specimen in simple tension or compression at yield. When the two are equal, the specimen will yield. This leads to the conclusion that when the von Mises stress reaches the tensile yield strength of the material, yield occurs.

So, the statement at the end of the section "This implies that the yield condition is independent of hydrostatic stresses" is misleading. That the yield condition is independent of hydrostatic loading is not implied by the von Mises criterion. It was explicitly assumed from the start. — Preceding unsigned comment added by 157.201.95.254 (talk) 22:11, 21 October 2013 (UTC)[reply]

The lede is

"The von Mises yield criterion [1] suggests that the yielding of materials begins when the second deviatoric stress invariant J_2 reaches a critical value.

Does the Wikipedia community wish to limit its audience to those who understand all of that introductory sentence? So for example, does Wikipedia want to exclude every reader who doesn't understand the term "second deviatoric stress"? — Preceding unsigned comment added by Mcamp@cinci.rr.com (talk • contribs) 00:20, 15 May 2015 (UTC)[reply]

That is always a problem with technical articles (try to explain the EPR paradox in simple words! and that is arguably only the beginning of "serious" quantum physics…). In that very case though, aren't the blue links to Yield (engineering) and Cauchy_stress_tensor#Stress_deviator_tensor enough? Mcamp@cinci.rr.com, feel free to change it if you have a better idea, of course. Tigraan (talk) 09:47, 15 May 2015 (UTC)[reply]

I agree, this article is terribly over-complicated. I generally have little or no problems following theoretically technical documentation, which I very often need to do for my job, but this article got me confounded. Readability is not helped by the fact that using the ${\displaystyle \sigma }$/${\displaystyle \tau }$ notation, with a Cartesian coordinate system using the ${\displaystyle (x,y,z)}$ axes, or ${\displaystyle ({\hat {i}},{\hat {j}},{\hat {k}})}$ vectors (even often without hat) is more common. Xiph1980 (talk) 10:58, 9 May 2016 (UTC)[reply]

NearlyMad, you reinstated an edit I reverted. Putting aside the "minor" incorrect marking issue, and the possibility of scientific inaccuracy, there are at least concerns:

1. You put a criterion ${\displaystyle {\frac {F_{sy}}{F_{ty}}}={\frac {1}{\sqrt {3}}}=0.577\!}$, when the notations are not defined anywhere. What does it mean? (${\displaystyle {\frac {F_{sy}}{F_{ty}}}}$, sy is shear yield while ty is tension yield.)

1. In any case, that does not belong to the lead (see WP:LEAD).
2. If the edit is supported by a reference which is already present in the article, which one? Please use inline citations.

I know the article is not in great shape and I have done little if any to correct that, but that is not a reason to deteriorate it further. Tigraan^{Click here to contact me} 18:18, 18 October 2016 (UTC)[reply]

When I put that in the article I did include a reference to Nadai. If that has been removed ... But, anyone familiar with this theory understands that the basis depends upon this ratio. It is the definition of Von Mises Yield Criterion just as Fty/Fsy = 0.50 is the definition of Max Shear Stress failure. Joseph L. Moore (talk) 12:06, 9 August 2022 (UTC)[reply]

=[edit]

Trigaan I am trying to make this article a little more useful. I have been providing edits to this page for over ten years (under various usernames). The applicability of any engineering/scientific information must be listed before the information is presented. If you can't see this value within the article I'd have to assume you are not well versed in it and question why you are editing it. As for inline citations, I was not aware of them and as a courtesy you could have added them then told me it should be done.

I have been dealing with von Mises criterion for over thirty years, it's a fascination with me. It is obvious Wikipedia does not need any help from someone with sufficient and adequate knowledge and experience. Good luck, I'll quit watching this page.

Joseph L. Moore Senior Aerospace Engineer NASA

NearlyMad, I do not feel you addressed my concerns.

1. Nowhere in the article is any definition of ${\displaystyle F_{sy}/F_{ty}}$. Maybe it is a notation for the yield stress / Young's modulus or whatever, but it needs to be said.
2. I would have put the inline citations myself if I knew which reference to use, but I have no access to most of the existing references. You come with a claim that one of them supports your information: it seems natural that I ask you which one, rather than go and try to find all of them. If you tell me which one supports which part, I can do the editing for you.
3. Think of the lead as the abstract of a scientific paper. You do not put the full hypotheses in there. Yes, application criteria must be mentioned - but not in the lead.
4. Finally, I will certainly not report you and no administrator should block you over this, but pay attention that "multiple usernames" are subject to WP:SOCK.

Wikipedia does need competent editors, but while competence in a technical subject is useful, competence in encyclopedia writing is better still. Tigraan^{Click here to contact me} 13:53, 19 October 2016 (UTC)[reply]

@NearlyMad, provide a more specific citation on this comment:

"Although the given criterion is based on a yield phenomenon, extensive testing has shown that use of a "von Mises" stress is applicable at ultimate loading "

I have read through the Timoshenko text and I cannot find information that agrees with your statement.

Timoshenko makes reference to R. v. Mises in a footnote on p478 in a discussion about the development of the maximum strain energy theory. He goes on to mention “recent experiments” that showed correlation between maximum strain energy theory and maximum shear theory, and notes that “in most cases the difference between these two theories is not so large as to make it of practical importance”. However, these discussions are focused on defining the yield point for ductile materials, not ultimate failure, so I do not believe it is relevant.

Later, on p482, there is a reference to “very extensive experiments” and a footnote regarding applying the theory to ultimate stresses, but this is explicitly noted in reference to brittle materials.

I should point out that all of my references above are in “Part II” of the text. Your citation notes “Part I”, but I have not been able to locate a reference to von Mises in that portion of the text. 216.243.30.3 (talk) 22:13, 5 January 2024 (UTC)[reply]

After reviewing Timoshenko, I felt it was appropriate to remove the note stating that von Mises was applicable to ultimate loading. If the claim can be substantiated with a more precise citation, the edit can be reversed. NGenEar (talk) 23:55, 5 February 2024 (UTC)[reply]