Automatic assembly path planning for wiring harness installations
Artikel i vetenskaplig tidskrift, 2013

The automotive industry of today is becoming more focused on electrified and hybrid solutions, where both conventional combustion engines and battery supplied electrical engines need to fit in an already densely packed vehicle. Many quality problems are related do flexible parts. In particular, the assembly of electric cables and wiring harnesses is difficult due to its concealed routing, multiple branching points, weights and the flexibility in the material. To avoid late detection of assembly problems, the assembly aspect must be considered early during conceptual design and production preparation with respect to both feasibility and ergonomics. Development of automatic path planning methods in virtual manufacturing tools supporting deformable parts is therefore highly motivated. This article presents a novel method for automatically planning and finding a smooth and collision-free mounting of connectors in a wiring harness installation. Automatic path planning for deformable objects in general is widely acknowledged as a very difficult problem. To overcome this challenge, we propose alow-dimensional path planning algorithm that operates in the following way: constraint relaxation, handle path planning, unfolding, path smoothing and handle supplementation. The method has been implemented and successfully applied to an industrial test case.

Automatic path planning

Cosserat rod theory

Deformable parts

Wiring harness

Assembly

Författare

Tomas Hermansson

Stiftelsen Fraunhofer-Chalmers Centrum för Industrimatematik

Robert Bohlin

Stiftelsen Fraunhofer-Chalmers Centrum för Industrimatematik

Johan Carlson

Stiftelsen Fraunhofer-Chalmers Centrum för Industrimatematik

Rikard Söderberg

Chalmers, Produkt- och produktionsutveckling, Produktutveckling

Journal of Manufacturing Systems

0278-6125 (ISSN)

Vol. 32 3 417-422

Ämneskategorier

Maskinteknik

Styrkeområden

Produktion

DOI

10.1016/j.jmsy.2013.04.006

Mer information

Senast uppdaterat

2018-03-20