Session: MF-01-02 Application of Fracture Mechanics in Failure Assessment II

Paper Number: 62648

Start Time: Thursday, July 15, 2021, 09:00 AM

62648 - Simulations of Crack Extensions in Small Arc-Shaped Tension Specimens of Uncharged and Hydrogen-Charged 21-6-9 Austenitic Stainless Steels Using Nodal Release Method 

Crack extensions in small side-grooved arc-shaped tension specimens of uncharged and hydrogen-charged conventionally forged 21-6-9 stainless steels are simulated using two-dimensional plane strain finite element analyses with the nodal release method.  The finite element analyses are conducted with the input crack extension-displacement curves from the experiments.  The crack extensions are simulated by releasing the nodal points ahead of the initial crack tips.  The crack extensions follows the experimental results based on the electric potential drop method.  The maximum opening stresses and the separation work rates as functions of the crack extension are then determined for the general trends of the cohesive strength and cohesive energy for the two-dimensional cohesive zone modeling approach.  The evolutions of plastic zone sizes and shapes near the crack tips are also presented as the crack extensions increase.  With the nodal release method for crack extensions, the experimental J-R curves are shown to be significantly higher than the separation work rates and therefore the uses of the experimental J-integral values as guides for the selections of the cohesive energies should be careful for small fracture specimens.  The computational results are useful for identification of the varying cohesive strengths and cohesive energies for the two-dimensional cohesive zone modeling of crack extensions in small fracture specimens.

Presenting Author: Shengjia Wu University of Michigan

Authors:

Shengjia Wu University of Michigan
Shin-Jang Sung University of Michigan
Jwo Pan University of Michigan
Paul Korinko Savannah River National Laboratory