Model-Based Quality Control System for Error Reduction in the Thermoforming Process

Richard Vocke; Johannes Stempin; Patrick Schiebel; Axel Herrmann; Andreas Fischer

doi:10.4028/www.scientific.net/KEM.809.598

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 809Model-Based Quality Control System for Error...

Model-Based Quality Control System for Error Reduction in the Thermoforming Process

Abstract:

Model-based quality control has the potential to reduce the reject rate in the production of fiber-reinforced plastics (FRP) components. After all the cross-market establishment of FRP, undesirable quality deviations often occur with new materials or component shapes. The quality control uses the component quality (e.g. component angle, crystallinity, fiber orientation, pore content) as the control variable. As a key component of the control, a process model is developed to link the process parameters (press pressure, press duration and tool temperature) with the quality parameters. Knowledge of the process-determining cause-effect relationships is necessary to ensure that different quality parameters are in the target value at the same time. Based on experimental tests, these interrelationships are determined using methods of statistical test planning and serve as the basis for model-based quality control. As a result, it has been shown that the targeted control of the component angle is possible in a range of about ±1° by using the control parameters, tool temperature and pressure, which have a significant influence on the quality. In the next step, further quality characteristics are included in the control system in order to demonstrate the ability to control the quality of complex component specifications. Model-based quality control is particularly promising for the reduction of the process run-in phase and thus for the reduction of the reject rate.

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Periodical:

Key Engineering Materials (Volume 809)

Pages:

598-603

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.809.598

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Online since:

June 2019

Authors:

Richard Vocke*, Johannes Stempin, Patrick Schiebel, Axel Herrmann, Andreas Fischer

Keywords:

CFRTP, Clip, Fiber Reinforced Thermoplastic, PPS, Quality Control, Spring-In, Stamp-Forming, Thermoforming

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References

[1] E. Witten, A. Schuster. Composites-Marktbericht 2018: Der Composites-Markt Europa: Marktentwicklungen, Herausforderungen und Chancen. Carbon Composites. (2018).

Google Scholar

[2] R. Gaitzsch, M. Koerdt, A.S. Herrmann. Suitable Coupon Design for Assessment of Interface Strength in Overmoulded Structures Made from Fibre Reinforced High-performance Thermoplastics, 4th ITHEC Conf., Bremen (2018).

Google Scholar

[3] S. Wijskamp. Shape distortions in composites forming, PhD thesis, University of Twente, Enschede (NL), (2005).

Google Scholar

[4] R. Vocke, J. Stempin. Development of a model-based quality control system for zero-error,-production of flexible batch sizes in the thermoforming-process. MAPEX Symposium, Bremen. (2018).

Google Scholar

[5] A. Miaris, K. Edelmann, S. Sperling: Thermoplastic Matrix Composites: Xtra complex, Xtra Quick, Xtra Efficient-Manufacturing advanced composites for the A350 XWB and beyond, 20th ICCM Copenhagen, (2015).

Google Scholar

[6] O. Focke, A. Miene, M. Koerdt, J. F. Evers, A. S. Herrmann: Automated quality inspection in a continuous preforming process for Non Crimped Fabrics (NCF). The 11th International Symposium of Measurement Technology and Intelligent Instruments (ISMTII), Aachen, July 1-5, (2013).

Google Scholar