Identification of Forming Limits for Unidirectional Carbon Textiles in Reality and Mesoscopic Simulation

Patrick Böhler; Frank Härtel; Peter Middendorf

doi:10.4028/www.scientific.net/KEM.554-557.423

Paper Titles

Two-Scales Kinetic Theory Model of Short-Fibers Aggregates
p.391

Effect of Tow Meander on the Shear Compliance of Woven Engineering Fabrics Measured Using the Biaxial Bias Extension Test
p.402

Simulation of Composite Forming at Meso Scale
p.410

Identification of Fibre Degradation due to Friction during the Weaving Process
p.416

Identification of Forming Limits for Unidirectional Carbon Textiles in Reality and Mesoscopic Simulation
p.423

Forming of a Non-Crimp 3D Orthogonal Weave E-Glass Composite Reinforcement
p.433

Analysis of the Blank Holder Force Effect on the Preforming Process Using a Simple Discrete Approach
p.441

Monolithic Approach of Stokes-Darcy Coupling for LCM Process Modelling
p.447

Experimental Setup to Validate Textile Material Models for Drape Simulation
p.456

HomeKey Engineering MaterialsKey Engineering Materials Vols. 554-557Identification of Forming Limits for...

Identification of Forming Limits for Unidirectional Carbon Textiles in Reality and Mesoscopic Simulation

Abstract:

In several fields of engineering the use of carbon fibre reinforced material (CFRP) is increasing. Minimized weight due to CFRPs could lead to lower consumption of raw materials especially in the automotive area. The goal within the research project TC² is the decrease of costs and production time for composite materials. To achieve better performance to weight ratio and to get acceptable production conditions the draping of dry unidirectional textiles and a following RTM process is investigated. Due to the high degree of complexity of automotive structures the forming process is challenging. Gapping in the textile could appear at corners as well as wrinkling or flexion of the fibres. To be able to define the amount and direction of layers or patches it is necessary to know the limits of forming for unidirectional material and to be able to predict the behaviour of the textile during the forming process. For the definition of the process limits several draping strategies are performed on different corner blend geometries. The goal of that work is to define the critical gradient of the flange to get first failures such as wrinkling or gapping. It is also important to understand the influence of different draping strategies. Parallel to the experimental tests a mesoscopic simulation method using an approach with roving and sewing thread is developed and presented. It is able to predict the material behaviour in critical areas (gapping, wrinkling). Different Young’s moduli and failure criteria can be implemented for the two main directions as well as for the bending of the textile. A validation with the experimental results is performed with the aim to enable the prediction of the textile behaviour using simulation methods.

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Periodical:

Key Engineering Materials (Volumes 554-557)

Pages:

423-432

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.554-557.423

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Online since:

June 2013

Authors:

Patrick Böhler, Frank Härtel, Peter Middendorf

Keywords:

Experimental Forming, Mesoscopic Simulation, Non Crimp Fabric (NCF), Unidirectional Fabric

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