Hello,
first time posting on this forum.
I am a junior piping engineer with 3 years of experience, so I know there is a lot out there for me to learn.
My understanding is that the piping code (ASME B31.3) addresses the following failure modes: excessive plastic deformation, plastic instability or incremental collapse, or high-strain-low-cycle fatigue.
Each of these modes of failure is caused by a different kinds of stresses and loading. So it is necessary to place theses stresses into different categories, such as primary or secondary, and set limits to them.
Primary stresses are not self-limiting. They are developed by imposed mechanical loadings such as weight, pressure, etc. A system under primary stress will continue unabated until force equilibrium is achieved, or until failure of the cross section results.
Secondary stresses are self-limiting. They are caused by constraints of displacements of a structure, where displacements are caused by thermal expansion. Distortion of piping system or local yielding relives stresses. That's why the yield stress of secondary stress is twice as high as that of primary stress: repetitively applied load which initially stresses the pipe into plastic yielding will "shake it down" to elastic action.
Sorry for the lengthy introduction, here goes my question.
So primary and secondary stresses are classified into two different categories by the code because their mechanisms are different. So that is why we segregate SUS and EXP and evaluate them separately - not to mention that they have different allowables.
My boss says we also have to look at the overall "energy level" in a piping system in OPE cases, and see how much the operating stresses are compared to material's allowable stress. He sets the stress type of his operating case in the load case to either SUS or OCC in order to compare the operating stresses to the allowables. I have no idea how CAESAR II calculates stresses in OPE cases where we have Weight, Temperature, and Pressure all together though. When the operating stresses are too high, he says extra flexibility needs to be considered even though EXP cases pass.
Anyway, I get his idea but I don't entirely agree with him because by doing so we are mixing two different stresses together, which I believe the code does not allow.
I know this is a sticky topic on this forum but I had no luck finding a thread that truly answers my question.
first time posting on this forum.
I am a junior piping engineer with 3 years of experience, so I know there is a lot out there for me to learn.
My understanding is that the piping code (ASME B31.3) addresses the following failure modes: excessive plastic deformation, plastic instability or incremental collapse, or high-strain-low-cycle fatigue.
Each of these modes of failure is caused by a different kinds of stresses and loading. So it is necessary to place theses stresses into different categories, such as primary or secondary, and set limits to them.
Primary stresses are not self-limiting. They are developed by imposed mechanical loadings such as weight, pressure, etc. A system under primary stress will continue unabated until force equilibrium is achieved, or until failure of the cross section results.
Secondary stresses are self-limiting. They are caused by constraints of displacements of a structure, where displacements are caused by thermal expansion. Distortion of piping system or local yielding relives stresses. That's why the yield stress of secondary stress is twice as high as that of primary stress: repetitively applied load which initially stresses the pipe into plastic yielding will "shake it down" to elastic action.
Sorry for the lengthy introduction, here goes my question.
So primary and secondary stresses are classified into two different categories by the code because their mechanisms are different. So that is why we segregate SUS and EXP and evaluate them separately - not to mention that they have different allowables.
My boss says we also have to look at the overall "energy level" in a piping system in OPE cases, and see how much the operating stresses are compared to material's allowable stress. He sets the stress type of his operating case in the load case to either SUS or OCC in order to compare the operating stresses to the allowables. I have no idea how CAESAR II calculates stresses in OPE cases where we have Weight, Temperature, and Pressure all together though. When the operating stresses are too high, he says extra flexibility needs to be considered even though EXP cases pass.
Anyway, I get his idea but I don't entirely agree with him because by doing so we are mixing two different stresses together, which I believe the code does not allow.
I know this is a sticky topic on this forum but I had no luck finding a thread that truly answers my question.
