Experimental investigation of the resistance welding of thermoplastic-matrix composites. Part II: optimum processing window and mechanical performance

Citation
C. Ageorges et al., Experimental investigation of the resistance welding of thermoplastic-matrix composites. Part II: optimum processing window and mechanical performance, COMP SCI T, 60(8), 2000, pp. 1191-1202
Citations number
19
Categorie Soggetti
Material Science & Engineering
Journal title
COMPOSITES SCIENCE AND TECHNOLOGY
ISSN journal
02663538 → ACNP
Volume
60
Issue
8
Year of publication
2000
Pages
1191 - 1202
Database
ISI
SICI code
0266-3538(2000)60:8<1191:EIOTRW>2.0.ZU;2-T
Abstract
An experimental investigation of the resistance welding of carbon-fibre and glass-fibre reinforced polyetherimide laminates is presented, The optimum resistance welding time based on a criterion of maximum lap shear strength was determined. The time required to achieve intimate contact predicted by a three-dimensional transient finite-element model featuring heat transfer and consolidation correlated well with the optimal welding time. The influe nce of the welding pressure on lap shear strength was investigated. and the consolidation quality obtained in the welded joint was related to the proc essing conditions. The extent of flow occurring during welding, or the redu ction of thickness of the welded joints, was shown to be related to lap she ar strength. Four failure mechanisms, leading to different values of lap sh ear strength, were identified including interfacial failure, cohesive failu re of the heating element, tearing of the heating element and tearing of th e laminate. Experimental and numerical processing windows were constructed and correlated well to each other. A comparison between fabric and unidirec tional heating elements, in terms of lap shear strength and the interlamina r fracture toughness, G(1c) was performed. It was demonstrated that large-s cale lap-shear coupons and double cantilever beam specimens can be resistan ce welded providing that current leaking to the laminate is avoided. (C) 20 00 Elsevier Science Ltd. All rights reserved.