Cross-process chain influence of process variations in self-piercing riveting with regard to semi-finished product dimensions

Abstract

Semitubular self-piercing riveting is an important and well-established mechanical joining process. A new approach, which involves the use of high strain hardening rivet materials, has the potential advantage of increasing resource efficiency in rivet production by eliminating the normally necessary post-treatment of the rivets by means of heat treatment and coating. However, as the high strain hardening of the rivet materials leads to extraordinarily high tool loads during rivet forming, process fluctuations can be particularly critical. For example, fluctuations in the dimensions of the semi-finished products used can influence the forming process itself, but also the quality of the formed rivets, which in turn can affect the subsequent joining process and the joint formation. An increased reject rate or premature tool failure caused by this is detrimental to the resource efficiency of the entire process chain. Therefore, a fundamental knowledge of the cross-process chain cause-and-effect relationships in conjunction with fluctuating billet dimensions is needed and is acquired within this research work. The investigations show that the forming and the joining process as well as the manufactured components themselves are influenced by the billet dimensions. The forming forces and tool stresses rise with increasing billet volume. Tool failure due to excessive or uneven stress can be the result. As the billet volume increases, the head diameter and the head thickness of the rivets increase. Consequently, the joining process and the joint are also indirectly influenced by the billet volume. With increasing volume, the joining force rises and, due to the increase in the head diameter, so does the joint strength. Knowledge of the detailed relationships is therefore highly relevant for the successful use of high strain hardening rivet materials.