Inverse Design Based on Nonlinear Thermoelastic Material Models Applied to Injection Molding

This paper describes an inverse shape design method for thermoelastic bodies. With a known equilibrium shape as input, the focus of this paper is the determination of the corresponding initial shape of a body undergoing thermal expansion or contraction, as well as nonlinear elastic deformations. A d...

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Bibliographic Details
Published in:arXiv.org 2019-08
Main Authors: Zwicke, Florian, Elgeti, Stefanie
Format: Article
Language:English
Subjects:
Computer simulation
Elastic deformation
Finite element method
Initial stresses
Injection molding
Inverse design
Iterative methods
Nonlinear differential equations
Nonlinear equations
Nonlinear programming
Partial differential equations
Stress distribution
Temperature distribution
Thermal expansion
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Summary:This paper describes an inverse shape design method for thermoelastic bodies. With a known equilibrium shape as input, the focus of this paper is the determination of the corresponding initial shape of a body undergoing thermal expansion or contraction, as well as nonlinear elastic deformations. A distinguishing feature of the described method lies in its capability to approximately prescribe an initial heterogeneous temperature distribution as well as an initial stress field even though the initial shape is unknown. At the core of the method, there is a system of nonlinear partial differential equations. They are discretized and solved with the finite element method or isogeometric analysis. In order to better integrate the method with application-oriented simulations, an iterative procedure is described that allows fine-tuning of the results. The method was motivated by an inverse cavity design problem in injection molding applications. Its use in this field is specifically highlighted, but the general description is kept independent of the application to simplify its adaptation to a wider range of use cases.
ISSN:2331-8422
DOI:10.48550/arxiv.1905.05448