Geometric variation simulation and robust design for flexible cables and hoses
Journal article, 2013

This article presents how to do stability analysis, variation simulation and tolerance envelopes for deformable cables and hoses. In this way, the well-established methods for analyzing and minimizing the propagation of geometric variation are extended from rigid and sheet metal assemblies to large deformations of slender parts. This extension is highly moti- vated, not at least, by the increased amount of cables and hoses in electrified and hybrid solutions in the automotive industry. To secure the geometric correctness of the analysis, we use a nonlinear rod approach in the implementation of a simulation model of flexible cables that accounts for large deformations and supports a wide range of common cable clip types, cable joints and branches. A selection of measures and visualizations that reflect the spatial effects of geo- metric variation in deformable cables is incorporated in established variation analysis techniques. In particular, the con- cept of tolerance envelopes for rigid parts has been extended to also handle system of slender parts such as cables and hoses. This article extends previous research on robust design and variation simulation to cables subject to large defor- mations and has been successfully applied on two typical industrial cases: a wiring harness attached with various types of clips to a static surrounding and a cooler hose subjected to a high-frequency sampled engine motion.

Variation simulation

Monte Carlo simulation

variation envelopes

tolerancing

nonlinear rod theory

Author

Tomas Hermansson

Johan Carlson

Chalmers, Product and Production Development, Product Development

Staffan C Björkenstam

Rikard Söderberg

Chalmers, Product and Production Development, Product Development

Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture

0954-4054 (ISSN) 20412975 (eISSN)

Vol. 226 5 681-689

Subject Categories

Mechanical Engineering

Areas of Advance

Production

DOI

10.1177/0954405413476627

More information

Latest update

4/6/2022 5