Characterization of fatigue crack growth by cyclic material forces

The study at hand introduces a new approach to characterize fatigue crack growth at small strain elastoplasticity by cyclic material forces, cyclic configurational forces. In the theoretical framework, analyzing cyclic processes, the balance of cyclic energy momentum is derived using the cyclic free energy instead of the free energy. Moreover, the cyclic material forces acting on an inclusion within an elastic homogeneous body are derived using a modified version of ESHELBY'S thought experiment. In the numerical context, cyclic nodal material forces are calculated using the weak form of the balance of cyclic energy momentum. Cyclic crack driving forces and cyclic global material forces are approximated using cyclic nodal material forces. The obtained cyclic global material forces are path-independent and show a linear correlation with the cyclic crack tip opening displacement. It is also able to characterize the effects of a single tensile overload. Finally, the results of the new approach are validated by comparing them to the experimental cyclic J-integral of a compact tension specimen.

Automated summary

This study introduces a new approach to characterize fatigue crack growth at small strain elastoplasticity by cyclic material forces and cyclic configurational forces. The balance of cyclic energy momentum is derived using the cyclic free energy instead of the free energy in the theoretical framework. Numerically, cyclic nodal material forces are calculated using the weak form of the balance of cyclic energy momentum, and the results are validated by comparing them to experimental data.