Role of multiaxial stress state in the hydrogen-assisted rolling-contact fatigue in bearings for wind turbines

Offshore wind turbines often involve important engineering challenges such as the improvement of hydrogen embrittlement resistance of the turbine bearings. These elements frequently suffer the so-called phenomenon of hydrogen-assisted rolling-contact fatigue (HA-RCF) as a consequence of the synergic action of the surrounding harsh environment (the lubricant) supplying hydrogen to the material and the cyclic multiaxial stress state caused by in-service mechanical loading. Thus the complex phenomenon could be classified as hydrogen-assisted rolling-contact multiaxial fatigue (HA-RC-MF). This paper analyses, from the mechanical and the chemical points of view, the so-called ball-on-rod test, widely used to evaluate the hydrogen embrittlement susceptibility of turbine bearings. Both the stress-strain states and the steady-state hydrogen concentration distribution are studied, so that a better elucidation can be obtained of the potential fracture places where the hydrogen could be more harmful and, consequently, where the turbine bearings could fail during their life in service.

[1]  J. Toribio,et al.  Two-Dimensional Numerical Modelling of Hydrogen Diffusion in Metals Assisted by Both Stress and Strain , 2010 .

[2]  Jesús Toribio,et al.  Hydrogen-Assisted Rolling-Contact Fatigue of Wind Turbines Bearings , 2014 .

[3]  G. T. Hahn,et al.  Rolling contact deformation and microstructural changes in high strength bearing steel , 1989 .

[4]  G. T. Hahn,et al.  Elasto-plastic finite-element analysis of 2-D rolling-plus-sliding contact with temperature-dependent bearing steel material properties , 1993 .

[5]  G. Subhash,et al.  Work hardening response of M50-NiL case hardened bearing steel during shakedown in rolling contact fatigue , 2012 .

[6]  Tim Schmitz,et al.  Formulas For Stress Strain And Structural Matrices , 2016 .

[7]  J. Toribio,et al.  Hydrogen Degradation of Cold-Drawn Wires: A Numerical Analysis of Drawing-Induced Residual Stresses and Strains , 2011 .

[8]  Miguel Lorenzo,et al.  Numerical analysis of hydrogen-assisted rolling-contact fatigue of wind turbine bearings , 2014 .

[9]  Anup S. Pandkar,et al.  Microstructure-sensitive accumulation of plastic strain due to ratcheting in bearing steels subject to Rolling Contact Fatigue , 2014 .

[10]  J. Toribio,et al.  Role of drawing-induced residual stresses and strains in the hydrogen embrittlement susceptibility of prestressing steels , 2011 .

[11]  S. Harvey,et al.  Fatigue and ratcheting interactions , 1995 .

[12]  Douglas Glover,et al.  A Ball-Rod Rolling Contact Fatigue Tester , 1982 .

[13]  Elena Kabo,et al.  Fatigue initiation in railway wheels — a numerical study of the influence of defects , 2002 .

[14]  Elena Kabo,et al.  Material defects in rolling contact fatigue of railway wheels—the influence of defect size , 2005 .

[15]  K. S. Kim,et al.  Ratcheting and fatigue behavior of a copper alloy under uniaxial cyclic loading with mean stress , 2009 .

[16]  Huseyin Sehitoglu,et al.  Three-dimensional elastic-plastic stress analysis of rolling contact , 2002 .

[17]  W. Pilkey Formulas for stress, strain, and structural matrices , 1994 .

[18]  Carol A. Rubin,et al.  A study of subsurface crack initiation produced by rolling contact fatigue , 1993 .

[19]  G. Subhash,et al.  Evolution of subsurface plastic zone due to rolling contact fatigue of M-50 NiL case hardened bearing steel , 2014 .