Skip to main content

Novel method for composite production with injection compression moulding

We demonstrate the feasibility and relevance of a novel composite production method, thermoplastic compression resin transfer moulding (TP-CRTM) coupled with injection compression moulding.

Spritzprägeimprägnierverfahren-process-ikt-ht-fhnw.jpg

Figure 1: Schematic representation of the direct thermoplastic melt impregnation with variothermal injection compression moulding.

Technologies

  • Fibre-reinforced plastics
  • Variothermal injection compression moulding
  • TP-CRTM
  • FEA

Background

Using fibre reinforced thermoplastics in the mobility sector can considerably reduce weight and therefore fuel consumption. Their manufacture is as of today mainly based on expensive semi-finished materials, preventing their broad use such as in the automotive industry. Alternative manufacturing routes are therefore sought to reduce the costs and enable a broader use of these composites. One promising technology is thermoplastic compression resin transfer moulding coupled with injection compression moulding and low-viscosity thermoplastics. However, its implementation at an industrial scale remains challenging mainly because of difficult cavity sealing.

Goals

    The main goal of the project is to design and build a mould specifically designed to overcome the difficulties of cavity sealing in a variothermal environment. Appropriate process parameters are experimentally defined to produce a fully consolidated composite with short processing times. Finally, the produced parts are mechanically characterized to prove the relevance of the process. Guidelines on how to define robust process parameters are presented.

    Result

      A novel tool with a variothermal sealing was designed and successfully implemented. Finite-Element analysis (FEA) was performed to define appropriate process parameters and to ensure sealing. Figure 3 shows the plates that were produced with the novel tooling with a diameter of 100mm and 2mm thickness. They display an elevated fibre volume fraction, advantageous mechanical properties and could be manufactured with a cycle time shorter than 10 minutes.


      Projekt information

      Execution

      FHNW Institute of Polymer Engineering

      Duration

      4 years

      Funding

      SCCER (Swiss Competence Center for Energy Research)

      15916.1 PKOEN; Efficient Technologies and Systems tor Mobility, 2013-2020.
      Project teamChristian Rytka (lead), Halime Philipp, Yara Khalaf, Vincent Werlen, Daniel Zürcher, Oskar Häfeli, Stephanie Wegmann