Substantial electrode life enhancement in resistance spot welding of galvanised steels through nanolayered multi-layer CrN/(Cr,Al)N coating

Malmir, Mahdi; Sheikhi, Mohsen; Mazaheri, Yousef; Elmkhah, Hassan; Usefifar, Gholam Reza

doi:10.1080/02670844.2021.1951512

Cited by 6 publications

(3 citation statements)

References 36 publications

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“…In addition, due to the low deposition rate of ESD, and manual operation makes the composite coating thickness less stable, which limits its application in large-scale industrial production. MALMIR et al [2] used the cathodic arc Physical Vapor Deposition (PVD) process to deposit a nano-multilayer CrN/(Cr,Al)N coating on the electrode surface, which enhanced the wettability, resistance to oxidation and thermal shock of the electrode tips, thereby slowing down the electrode failure rate. However, the coating is easy to fall off, and it also deteriorated the electrical and thermal conductivity of the electrodes.…”

Section: Introductionmentioning

confidence: 99%

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Life and failure of oriented carbon nanotubes composite electrode for resistance spot welding

et al. 2023

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In view of the poor weldability of electrodes in resistance spot welding (RSW) of galvanized steel sheets, the life of oriented multi-walled carbon nanotubes reinforced Cu matrix composites (Cu@MWCNTs/Cu) electrodes was studied, in which Cu coated multi-walled carbon nanotubes (MWCNTs) are arranged along the flow direction of working electric/force. By analyzing the macro/microscopic morphology, microstructure, hardness, texture and composition of the failed composite electrodes and the commercially CuCrZr electrode, the mechanism of the weldability enhancement and failure of electrodes was discussed. The results show that the life of Cu@ MWCNTs/Cu electrodes (2150 welds) is 3 times longer than that of CuCrZr electrode (600 welds), and the degradation rate is much slower. The hardness of Cu@MWCNTs/Cu electrodes is 30-40Hv higher. The content of recrystallized and recovery grains of Cu@MWCNTs/Cu electrodes is less. This is due to the pinning effect of MWCNTs, and straight and long MWCNTs are arranged along the electrical/force direction. These improve the hardness, mechanical properties, conductivity, and resistance to thermal deformation, cracking, and pitting of Cu@MWCNTs/Cu electrodes, which effectively slows down the failure rate and makes the spot welding life of Cu@MWCNTs/Cu electrodes longer. This work provides a new idea for the application of CNTs/Cu composites.

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Section: Introductionmentioning

confidence: 99%

“…Therefore, this method has limited improvement in electrode life. (2) Design the special structure of the electrode tip. CHEN et al [3] designed the electrode end face as a central micro-concave, which effectively improved the connection strength of RSW joints.…”

Section: Introductionmentioning

confidence: 99%

Life and failure of oriented carbon nanotubes composite electrode for resistance spot welding

et al. 2023

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“…However, electrode life plays a significant role in assembling car bodies using the RSW technique. The electrode life is short and needs to be trimmed and updated, resulting in slower production efficiency and higher production costs [19]. However, most of the previous work on BH steel has only addressed welded joint properties such as tensile strength, microhardness, weld geometry, and microstructure.…”

Section: Introductionmentioning

confidence: 99%

Correlating Electrode Degradation with Weldability of Galvanized BH 220 Steel during Electrode Failure Process of Resistance Spot Welding

Zhao¹,

Vdonin²,

Bezgans³

et al. 2022

Preprint

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Electrode degradation in continuous resistance spot welding process of BH 220 steel was evaluated by electrode life test, and weldability tests were conducted by geometry features measurement, mechanical property analysis, and electrode diameter measurement with 88 or 176 weld intervals. The analysis of weld geometry shows that the HAZ width, nugget diameter, and nugget area tend to decrease rapidly, while the nugget height tends to firstly increase with the weld repetitions till the welding heat input becomes too small to form the valid nugget. The peak load shows a rapid downward trend, while failure energy and maximum displacement slightly increase till the 176th weld and then decrease. The cavities and pores in the nugget mainly appear after the 176th spot weld. The electrode diameter increases during welding. The reason for the increase in electrode diameter may be that the contact area between the electrode and BH 220 steel sheets becomes smaller in the welding process, which causes the continuous sticking phenomenon between the electrode and the BH 220 steel sheets. In the absence of alloying, the edge of the electrode is geometrically deformed, while Cu-Zn-Fe alloying occurs in the area in contact with the BH 220 steel sheet.

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Dynamic resistance signal–based wear monitoring of resistance spot welding electrodes

Zhao,

Vdonin,

Slobodyan

et al. 2024

Int J Adv Manuf Technol

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Substantial electrode life enhancement in resistance spot welding of galvanised steels through nanolayered multi-layer CrN/(Cr,Al)N coating

Cited by 6 publications

References 36 publications

Life and failure of oriented carbon nanotubes composite electrode for resistance spot welding

Life and failure of oriented carbon nanotubes composite electrode for resistance spot welding

Correlating Electrode Degradation with Weldability of Galvanized BH 220 Steel during Electrode Failure Process of Resistance Spot Welding

Dynamic resistance signal–based wear monitoring of resistance spot welding electrodes

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