A Semi-Mechanistic Model for Predicting the Service Life of Composite Coatings on VW63Z Magnesium Alloy

doi:10.1007/s40195-024-01698-w

Abstract

Abstract:

The application of Mg alloys is always accompanied by various coating technology, but a reliable model predicting the service life of coatings on Mg alloys is lacking but urgent. In this work, a semi-mechanistic model was proposed to predict the service life of plasma electrolytic oxidation (PEO) coating/electrophoretic coatings on a VW63Z Mg alloy; the model was decomposed into three parts: a first part depicting the degradation time of organic coating (L₁) and the diffusion time of electrolyte in the inorganic coating (L₂), respectively; a second part interpreting the breakdown of coatings due to the corrosion process (L₃); a final part establishing an algorithm converting the accelerated tests into the real service environment (α); the effect of structural stress and dissimilar metal joints on the service life of coatings was also considered. Based on the ongoing accelerated experiments, the semi-mechanistic model could be able to predict the service life of both PEO coatings and composite coatings on VW63Z Mg alloy with a satisfiable precision.

Key words: Magnesium alloy, Service life prediction, Plasma electrolytic oxidation, Electrophoretic coating, Corrosion resistance

Xiaoxue Wang, Jingjing Guo, Zihao Zeng, Peng Zhou, Rongqiao Wang, Xiuchun Liu, Kai Gao, Jingli Sun, Yong Yuan, Fuhui Wang. A Semi-Mechanistic Model for Predicting the Service Life of Composite Coatings on VW63Z Magnesium Alloy[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(7): 1161-1176.

Figures/Tables 15

Fig. 1 Schematic diagram of the breakdown process of coatings on Mg alloys

Fig. 2 Schematic diagram interpreting the breakdown of coatings on Mg alloys

Fig. 3 Schematic diagram of the four-point flexural test a and the real image of the loader b

Table 1 Test conditions for determining the diffusion kinetics of corrosive electrolyte

Parameters	Test conditions
Temperature (℃)	20/40
NaCl concentration (ppm)	0	50	70	90	110	130	35,000

Fig. 4 Schematic diagram of the dissimilar joints

Fig. 5 Schematic diagram of closely-arrayed electrodes a and the picture of real electrodes demonstrating the formation of an electrolyte water bridge on the surface b

Fig. 6 Surface and cross-sectional morphologies of PEO coatings prior to a and d, after b and e micro-creep loading, and the surface and cross-sectional observations of composite coatings c and f

Fig. 7 Impedance spectra of PEO coated Mg alloy in a 70 ppm NaCl electrolyte with a temperature of 20 ℃ a and b; the linear c and logarithmic plot d of the calculated Rp values as a function of immersion time

Fig. 8 Calculated ${{L}}_{2}$ values for the diffusion kinetic models: the relationship of ${{L}}_{2}$ value as a function of Cl− concentration at 20 ℃ prior to a and after c micro-creep loading, and the relationship of ${{L}}_{2}$ value as a function of Cl− concentration at 40 ℃ prior to b and after d micro-creep loading

Fig. 9 Degradation of adhesive force of PEO coating a and composite coating b as a function of immersion time in NaCl electrolyte

Fig. 10 Measured (dots) and predicted (dash lines) values of hydrogen evolution volume (HEV) as a function of time for bare Mg alloys a and b and dissimilar joints c and d

Fig. 11 Calculated breakdown time of PEO coating a and composite coatings b

Fig. 12 Measured surface resistance changes as a function of time a and the calculated factor under various relative humidity b

Fig. 13 Comparison of the measured and predicted results for PEO coatings and composite coatings in a 110 ppm NaCl electrolyte and the PEO coatings in an accelerated test

Fig. 14 Weibull probability distribution for the PEO coating and the composite coating, respectively

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