How to calculate Stress Intensity Factor?

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Discussion Overview

The discussion revolves around calculating the stress intensity factor (SIF) for a flat circular disc with a central point load and a crack on its bottom surface. Participants explore the implications of the crack's depth and location, as well as the appropriate methodologies for deriving the stress field and SIF in the context of fracture mechanics.

Discussion Character

  • Technical explanation
  • Exploratory
  • Debate/contested

Main Points Raised

  • One participant describes a scenario involving a brittle circular disc with a central point load and a crack, seeking guidance on the forces experienced by the crack and the calculation of the SIF.
  • Another participant suggests referencing a book on glass and ceramic fracture mechanics, indicating its relevance to the problem of a simply supported disc.
  • A different participant proposes deriving the stress field equations from first principles for a simply supported circular plate under a point load, recommending specific texts for further understanding.
  • It is noted that if the crack runs along the major diameter, it will experience bending forces that may tend to open the crack.
  • Participants discuss the significance of the crack's depth, with one stating that if the crack is trivial in depth compared to the plate dimensions, the stresses can be approximated using solid plate analysis.
  • Another participant provides a formula for calculating the stress intensity factor, emphasizing the importance of knowing the critical stress intensity factor for the material in question.

Areas of Agreement / Disagreement

Participants express varying approaches to the problem, with no consensus on a single method for calculating the stress intensity factor. Some agree on the relevance of certain texts and methodologies, while others highlight the complexity of the equations involved and the conditions under which they apply.

Contextual Notes

Participants mention limitations related to the depth of the crack and the assumptions required for different analytical approaches. The discussion reflects a range of mathematical functions that may or may not apply depending on the specific characteristics of the crack.

Who May Find This Useful

This discussion may be useful for graduate students and researchers in fracture mechanics, particularly those dealing with stress intensity factors in brittle materials and circular geometries.

saurabh anand
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Hello everyone,
I am currently doing my masters research project on fracture mechanics. My problem is such that I have a flat circular disc(brittle) which is simply supported around its circumference. The top surface of the disc is subjected to a point load at its centre. the bottom surface has a crack of a given length and a depth of less that half the thickness of the plate ( part through crack). This crack passes through the centre of the plate. What kind of forces will the crack experience? and how can I calculate the stress intensity factor at any point on this crack. There has been a lot of work previously carried out for plates with remote tensile and bending loads on the edges of the plate. I am not sure which category my problem falls into because I am applying a local force at the centre. thanks in advance. Any help will be deeply appreciated.
 
Thank you for the information. I will look into it.
 
I am not very sure how to derive the mathematical equation for the stress field. But the way I would follow is to first look at and understand how the equations for simple supported circular plate with point load at the center are derived from first principles. What this will do is to give you a better perspective of the problem to be solved. I liked the book "Stresses in Plates and shells" by Ugural. You can perhaps look into that. Also Fracture Mechanics notes by Alan Zehnder from Cornell can be looked into. Then in the same problem without crack introduce a crack which is represented by zero traction boundary conditions.Try to solve for the stress function and solve with the s.s. plate with point load BC's.
Then may be you can solve the original problem using Ansys/Abaqus and look at the results.
 
If crack runs along major diameter then it will experience bending forces tending to hinge open the crack .

If crack is of trivial depth compared to plate dimensions then stresses can be approximated using analysis of a solid plate and then treating crack as a stress raiser .

If crack is of significant depth then an analytic solution is only possible if shape and size of crack can be described by a limited range of mathematical functions .

Apart from a few trivial cases solving the resulting equations is very difficult indeed .
 
Thankyou Koolraj09 the approach you suggested is exactly how I am going about it. thanks for the reference book. I will look into it.
 
Nidum thanks for the reply. the crack in my case is of trivial depth.
 
saurabh anand said:
Hello everyone,
I am currently doing my masters research project on fracture mechanics. My problem is such that I have a flat circular disc(brittle) which is simply supported around its circumference. The top surface of the disc is subjected to a point load at its centre. the bottom surface has a crack of a given length and a depth of less that half the thickness of the plate ( part through crack). This crack passes through the centre of the plate. What kind of forces will the crack experience? and how can I calculate the stress intensity factor at any point on this crack. There has been a lot of work previously carried out for plates with remote tensile and bending loads on the edges of the plate. I am not sure which category my problem falls into because I am applying a local force at the centre. thanks in advance. Any help will be deeply appreciated.
Here is what you need to do. Calculate the stress under point load with no crack- use a book like ROARK for this. The stress intensity is given as
stress = Ki/(y) (SQRT(C) where c is flaw depth and Y = 1.26, for penny crack. Thus Ki = (max stress without crack)(y)( sqrt(C)). If stress intensity is less than critical stress intensity factor, Kic. then it will not fail. Kic = inherent property of material which you need to know. For britle materials like glass Kic = about 1MPa (m^1/2). The stress is in Mpa and the flaw depth is in meters. Note that stress must be in tension for failure to occur.
Edit: I corrected the equations as now noted above.
 
Last edited:

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