Strain rate dependent deformation and damage behaviour of textile-reinforced thermoplastic composites

Research output: Contribution to book/Conference proceedings/Anthology/ReportConference contributionContributedpeer-review

Contributors

Abstract

The present work focuses on the detailed characterisation and modelling of the strain rate dependent deformation and damage behaviour of a continuous fibre-reinforced thermoplastic composite (TPC) with multi-layered flat bed weft-knitted reinforcement. For this purpose, a novel experimental testing procedure is developed in the first part of this work. A so-called stepwise loading and reloading with stress relaxation and strain retardation phases enables the determination of the elastic, inelastic and viscoelastic portions with only one experimental test. Additionally, microscopic diagnostic is employed to investigate the complex deformation and damage behaviour and its provoking phenomenological damage mechanism like inter fibre failure and inelastic deformation. After the detailed experimental characterisation, an adapted viscoelastic-plastic damage model is developed in the second part of this work. This model on lamina level is based on a modified damage-plasticity model proposed by LADEVÈZE and uses an additional spring-dashpot system for describing the viscoelastic overstress. This model is implemented as a user-defined material (VUMAT) in the FE program ABAQUS for realising a model validation and structure application.

Details

Original languageEnglish
Title of host publicationECCM17 - 17th European Conference on Composite Materials
ISBN (electronic)978-3-00-053387-7
Publication statusPublished - 2016
Peer-reviewedYes

Conference

Title17th European Conference on Composite Materials
Abbreviated titleECCM 17
Conference number17
Duration26 - 30 June 2016
Degree of recognitionInternational event
CityMünchen
CountryGermany

External IDs

Scopus 85018572103
ORCID /0000-0003-1370-064X/work/142243609

Keywords

Keywords

  • Continuous fibre-reinforced thermoplastics, Damage evolution, Inelastic strain, Strain rate dependent behaviour, Viscoelastic-plastic damage model