The Influence of Heat Treatment on the Microstructure, Surface Roughness and Shear Tensile Strength of AISI 304 Clinch Joints

Zeuner, A.; Ewenz, Lars; Kalich, Jan; Schöne, Sebastian; Füssel, Uwe; Zimmermann, Martina

doi:10.3390/met12091514

Cited by 9 publications

(1 citation statement)

References 30 publications

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“…Sia et al [35] studied the behavior and durability of clinch joints at room temperature, 100 • C, and 250 • C. The ultimate tensile-shear strength remained relatively unchanged with a temperature increase, but the stiffness and energy absorption decreased at higher temperatures. Zeuner et al [36] investigated the effect of heat treatment on the forming process and the mechanical properties of clinch joints made from a highly formable sheet material. The study examined the impact of heat treatment, which involves the formation of an oxidation layer on the sheet surface, on the forming process and resulting mechanical properties of the clinch joints.…”

Section: Introductionmentioning

confidence: 99%

Clinching of High-Strength Steel Sheets with Local Preheating

et al. 2023

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Clinching is a manufacturing method of mechanically joining two or more materials without the use of heat or additional components. This process relies on high plastic deformation to create a secure bond. Clinching technology is widely used for joining materials of various grades and thicknesses. Especially in the automotive industry, clinching is an alternative to resistance spot welding. However, the load-bearing capacity of clinched joints is comparatively lower when compared to resistance spot-welded joints. This research aimed to increase the load-carrying capacity of clinched joints. To enhance the load-bearing capacity of the clinched joints, localized modification of the microstructure was carried out, primarily focusing on the neck area of the joint. The alteration of the microstructure within the clinched joint was accomplished through the application of localized heating using the resistance spot welding method. The microstructure distribution in the clinched joint region was analyzed using light and scanning electron microscopy, as well as microhardness measurements. Two material grades, micro-alloyed steel HX420LAD+Z and dual-phase ferritic–martensitic steel HCT600X+Z, were tested. Each grade underwent five groups of ten samples, which were subjected to identical experimental conditions of local heating by resistance spot welding (RSW) and clinching. The utilization of RSW on the clinched joint region resulted in an average enhancement of 17% in the load-carrying capacity for material HCT600X+Z, and an average increase of 25% for material HX420LAD+Z.

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Section: Introductionmentioning

confidence: 99%