4.6 Article

Damage Mechanism of Trivalent Chromium Coatings under Tensile Stress

Journal

COATINGS
Volume 13, Issue 7, Pages -

Publisher

MDPI
DOI: 10.3390/coatings13071194

Keywords

coatings; trivalent chromium bath; hard chromium; tensile stress; adherence

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Due to new environmental regulations, the use of hexavalent chromium electrolytes for chromium plating is no longer allowed. Trivalent chromium electrolytes have been developed as an alternative. This paper proposes a study on the adhesion of Cr-III coatings using numerical models and experimental scenarios. Two types of cracking, transverse cracking and delamination, were investigated. Microtensile tests and numerical simulations were conducted to analyze the damage initiation threshold and complete delamination of the coating.
Due to new environmental regulations, hexavalent chromium electrolytes can no longer be used for thick, hard chromium plating. In response to this industrial and environmental challenge, trivalent chromium electrolyte plating has been developed. In this paper, we propose a study of the adhesion of Cr-III coatings based on the implementation of numerical models in comparison with an identified experimental scenario. The aim is to dissociate the influence of coating and substrate behaviours from the adhesion work by describing the intrinsic damage of the chromium layer and the coating-substrate interface. Two types of cracking were studied: transverse cracking and delamination. For the former, the crack density was higher for Cr-III than for Cr-VI and increased with deformation and coating thickness. Microtensile tests with scanning electron microscopy (SEM) observations allowed us to highlight the cracking process in the coating (transverse cracking) and at the coating-substrate interface (delamination). The numerical simulation of the test allowed us to estimate a damage-initiation threshold normal stress of 1900 MPa, which occurred at an average applied strain of 2.5%. Delamination of the coating was complete at an average strain of 13.6% and an interfacial normal stress of 2600 MPa.

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