Design of hole-clinching process for joining of dissimilar materials – Al6061-T4 alloy with DP780 steel, hot-pressed 22MnB5 steel, and carbon fiber reinforced plastic

• Published in: Journal of materials processing technology Vol. 214; no. 10; pp. 2169 - 2178
• Main Authors: Lee, Chan-Joo, Lee, Jung-Min, Ryu, Ho-Yeon, Lee, Kyung-Hun, Kim, Byung-Min, Ko, Dae-Cheol
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.10.2014
• Subjects: 22MnB5 steel; Advanced high-strength steel; Alloy steels; Aluminum base alloys; Carbon fiber reinforced plastic; Carbon fiber reinforced plastics; Dissimilar materials; High strength steels; Hole clinching; Joining; Mathematical analysis; Multi-material design; Strength; Structural steels; Carbon fiber reinforced plastic; Advanced high-strength steel; 22MnB5 steel; Hole clinching; Multi-material design
• ISSN: 0924-0136
• DOI: 10.1016/j.jmatprotec.2014.03.032

The mechanical joining of dissimilar materials is a key technology in the automotive industry as it enables the realization of car bodies that incorporate multiple materials. However, it remains difficult to join materials such as aluminum alloy to high-strength/low-ductility materials such as advanced high-strength steel, hot-pressed steel, and carbon fiber reinforced plastic by using joining methods that are based on forming technology. The purpose of this study is to develop a new joining process, called “hole clinching,” for these material combinations. In the hole-clinching process, the ductile material is positioned uppermost and the brittle material—into which a hole is formed—is positioned below that. The upper sheet is indented into a die cavity through the hole in the lower sheet and spread so that the two sheets interlock geometrically. In this study, hole-clinching tools were designed based on the geometrical relationship between the forming volume and the joint strength. Finite element analysis and practical experiments were performed to verify the practicality of the hole-clinching process. The cross-sections of the hole-clinched joints formed in our experiments were in good agreement with the results of the finite element analysis. Then, a single-lap shear test was performed to evaluate the joint strength. The hole-clinched joints, regardless of the material combinations, provided a joint strength in excess of the desired 2.5kN. These results point to the applicability of the hole-clinching process to the joining of dissimilar materials.