Design of clinched joints on the basis of binding mechanisms
Research output: Contribution to journal › Research article › Contributed › peer-review
Contributors
Abstract
The work carried out is based on the thesis properties of clinched joints are determined by the proportions of binding mechanisms form-closure, force-closure and material-closure. To describe the acting binding mechanisms and thus to derive the joint properties, detailed knowledge of the local effect of the individual binding mechanisms is necessary to ensure their targeted adjustment by the joining process. The targeted setting of different proportions of the binding mechanisms is achieved firstly via tool geometry and secondly via surface condition of the joined parts. An introduced form-closure component can be quantified by metallographic cross section with subsequent measurement of the quality-determining parameters such as undercut, penetration depth and neck thickness. To qualify the force-closure component, a torsional load can be applied mechanically at rotationally symmetrical clinch joints. This also allows the influence of different surface conditions on the tribological system to be quantified. Measurement of electrical resistance can reveal the binding mechanisms of force- and material-closure. These investigations are carried out on an aluminum joining part combination of the same type. As a result of these investigations, the clinched joints can be designed according to the load occurring in the later life cycle in the form of an optimum and compromise variant with regard to minimum loads to be transmitted mechanically, electrically with regard to low resistance or manufacturing with minimum energy input.
Details
Original language | English |
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Pages (from-to) | 213-222 |
Number of pages | 10 |
Journal | Production engineering |
Volume | 16 |
Issue number | 2-3 |
Publication status | Published - Apr 2022 |
Peer-reviewed | Yes |
Keywords
ASJC Scopus subject areas
Keywords
- Aluminum, Binding mechanism, Clinching, Surface condition, Tool geometry