An alternative definition of the shear stress amplitude based on the Maximum Rectangular Hull method and application to the C‐S (Carpinteri‐Spagnoli) criterion

In the present paper, the fatigue strength estimation capabilities of the modified C-S (Carpinteri-Spagnoli) criterion are improved by employing the Maximum Rectangular Hull (MRH) method proposed by the first author. The C–S criterion is a multiaxial high-cycle fatigue criterion based on the critical plane approach and takes into account both shear stress (Mode II) and normal stress (Mode I) mechanisms to evaluate the orientation of the critical plane. The fatigue damage parameter used is given by a nonlinear combination of the equivalent normal stress amplitude, Na,eq, and the shear stress amplitude, Ca, acting on the critical plane. In the present paper, the shear stress amplitude is evaluated through the MRH method. Some experimental data available in the literature are compared with the theoretical estimations, concluding that the multiaxial fatigue strength evaluations provided by the C–S criterion are improved when Ca is computed applying the MRH method instead of the Minimum Bounding Circle (MBC) method.

[1]  Andrea Carpinteri,et al.  Expected principal stress directions under multiaxial random loading. Part I: theoretical aspects of the weight function method , 1999 .

[2]  M. de Freitas,et al.  A Unified Numerical Approach for Multiaxial Fatigue Limit Evaluation , 2000 .

[3]  Luca Susmel,et al.  Multiaxial notch fatigue , 2009 .

[4]  Andrea Carpinteri,et al.  Multiaxial fatigue life estimation in welded joints using the critical plane approach , 2009 .

[5]  A. Carpinteri,et al.  Structural integrity assessment of metallic components under multiaxial fatigue: the C–S criterion and its evolution , 2012 .

[6]  D. McDiarmid Fatigue Under Out-of-Phase Biaxial Stresses of Different Frequencies , 1985 .

[7]  Andrea Carpinteri,et al.  Multiaxial high-cycle fatigue criterion for hard metals , 2001 .

[8]  E. N. Mamiya,et al.  Using enclosing ellipsoids in multiaxial fatigue strength criteria , 2006 .

[9]  I. Papadopoulos,et al.  Critical plane approaches in high-cycle fatigue : On the definition of the amplitude and mean value of the shear stress acting on the critical plane , 1998 .

[10]  José Alexander Araújo,et al.  On the characterization of the critical plane with a simple and fast alternative measure of the shear stress amplitude in multiaxial fatigue , 2011 .

[11]  Wei-Xing Yao,et al.  Evaluation and comparison of several multiaxial fatigue criteria , 2004 .

[12]  Andrea Bernasconi,et al.  Efficient algorithms for calculation of shear stress amplitude and amplitude of the second invariant of the stress deviator in fatigue criteria applications , 2002 .

[13]  José Alexander Araújo,et al.  Prismatic hull: A new measure of shear stress amplitude in multiaxial high cycle fatigue , 2009 .

[14]  Minoru Kawamoto,et al.  The Strength of Metals under Combined Alternating Bending and Torsion with Phace Difference , 1946 .

[15]  Luis Reis,et al.  Comparative study of multiaxial fatigue damage models for ductile structural steels and brittle materials , 2009 .

[16]  Harald Zenner,et al.  Dauerschwingfestigkeit bei nichtsynchroner mehrachsiger Beanspruchung , 1985 .

[17]  Andrei Kotousov,et al.  Induced out-of-plane mode at the tip of blunt lateral notches and holes under in-plane shear loading , 2012 .

[18]  Andrea Carpinteri,et al.  Multiaxial fatigue assessment using a simplified critical plane-based criterion , 2011 .

[19]  L. Pook A 50‐year retrospective review of three‐dimensional effects at cracks and sharp notches , 2013 .