Influence of DC Current on Corrosion Behaviour of Copper-Aluminium Composite Plates

doi:10.1007/s40195-021-01213-5

Abstract

Abstract:

In this study, neutral salt spray accelerated corrosion test of copper-aluminium composite under 0-125A DC current was carried out under 5% concentration. The effect of corrosion behaviour on copper-aluminium composite by DC current was carried out by a scanning electron microscope (SEM) with energy-dispersive spectroscopy (EDS), X-ray diffraction (XRD) patterns, X-ray photoelectron spectroscopy (XPS), weight-loss method and electrochemical analysis. The results show that the current can accelerate the corrosion rate. Meanwhile, the current temperature effect can reduce the corrosion rate. The current caused directional migration of ions resulting in different corrosion products on positive and negative poles of specimen, and the corrosion degree on the positive pole was more serious. The galvanic corrosion mechanism at the copper-aluminium interface is different from the pitting corrosion mechanism far away from the interface, and the latter is more affected by DC current.

Key words: Copper-aluminium composite, Corrosion, DC current, Ionic migration, Temperature effect

Yu-Lin Cheng, Xiao-Jiao Zuo, Xiao-Guang Yuan, Hong-Jun Huang, Yi-Fan Zhang. Influence of DC Current on Corrosion Behaviour of Copper-Aluminium Composite Plates[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(8): 1142-1152.

Figures/Tables 15

Fig. 1 Specimen design drawing

Fig. 2 Salt spray test equipment connection diagram

Table 1 Salt spray test condition

Current value (A)	Exposure time (h)	PH	Temperature (°C)	NaCl (wt%)
0-125	48	6.5-7.2	35	5

Fig. 3 Cross-sectional of SEM image and corrosion rate of specimens corroded for 48 h in salt spray under different currents: a 0 A, b 25 A, c 50 A, d 75 A, e 100 A, f 125 A, g 0 A-, h 50 A-, i corrosion rate

Fig. 4 Surface scanning analysis results of positive and negative poles under 50 A current: a, b positive pole, c, d negative pole

Fig. 5 EDS analysis results of positive and negative specimens under 50 A current: a positive pole, b negative pole

Fig. 6 X-ray powder diffraction patterns of positive and negative poles under 50 A current

Fig. 7 XPS spectra of the corrosion product powder composition under 50 A current: a survey spectrum, b O1s spectrum of the positive pole corrosion product, c O1s spectrum of the negative pole corrosion product

Fig. 8 Electrochemical analysis results of the positive and negative poles under 50 A current in 3.5 wt% NaCl solution: a polarisation curve plots, b Nyquist plots, c Bode-phase angle versus frequency plots and d equivalent circuit of EIS

Table 2 Electrochemical parameters of the positive and negative poles under 50 A DC current value from polarisation curve (Fig. 8a)

Specimen	E_corr (mV)	I_corr (μA)
Positive	- 1187.25	64.07
Negative	- 705.9	20.03

Table 3 Electrochemical parameters of the positive and negative poles under 50 A DC current value from EIS (Fig. 8b-d)

Specimen	R_s (Ω cm²)	Q_pr		R_pr (Ω cm²)	Q_dl		R_ct (Ω cm²)
Specimen	R_s (Ω cm²)	Y_pr (μF/cm²)	n_pr	R_pr (Ω cm²)	Y_dl (μF/cm²)	N_dl	R_ct (Ω cm²)
Positive	5.55	17.49	0.85	285.8	10.51	0.96	445
Negative	8.99	20.29	0.84	121.5	75.16	0.84	1370

Fig. 9 Corrosion mechanism schematic diagram

Fig. 10 Schematic diagram of directional migration of ions is in liquid film under DC current

Fig. 11 Salt film morphology, composition and formation temperature of the surface of specimen under 125 A current: a morphology of salt film on section, b morphology of salt film on the surface, c XRD analysis results of salt film components and d trend of specimen temperature with the current

Fig. 12 Change of salt film thickness with time under 125 A current lapse

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