Numerical simulation of segmentation cracking in thermal barrier coatings by means of cohesive zone elements

The paper presents comparative experimental and numerical studies of segmentation cracking of thermal barrier coatings (TBCs) during three point bending tests. The finite element simulation of failure development was performed using a cohesive zone approach. Acoustic emission (AE) technique and in situ observations by a charge-coupled device (CCD) camera allowed to determine critical strain values correlated with the damage evolution. Location of crack initiation and crack propagation paths up to macroscopic failure were investigated for as-received and annealed specimens. The results of the numerical simulations and of the experiment were quantitatively similar. The influence of critical energy release rate on crack patterns was examined, resulting in the increase of crack numbers due to decreased value of G I . This explains the good spallation resistance of electron beam-physical vapour deposition (EB-PVD) coatings, where G I is lower than in the case of air plasma sprayed (APS) thermal barrier coatings. Lower value of G I stimulates segmentation cracking and reduces delamination, as observed within electron beam-physical vapour deposition coatings.