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@PHDTHESIS{vanderVelden:998601,
author = {van der Velden, Tim},
othercontributors = {Reese, Stefanie and Wulfinghoff, Stephan},
title = {{M}ultiphysics modeling of manufacturing and failure
processes},
school = {Rheinisch-Westfälische Technische Hochschule Aachen},
type = {Dissertation},
address = {Aachen},
publisher = {RWTH Aachen University},
reportid = {RWTH-2024-11476},
pages = {1 Online-Ressource : Illustrationen},
year = {2024},
note = {Veröffentlicht auf dem Publikationsserver der RWTH Aachen
University 2025; Dissertation, Rheinisch-Westfälische
Technische Hochschule Aachen, 2024},
abstract = {The development of modern technical devices demands a
resource saving design for the manufacturing process in
conjunction with optimal device performance during the
application. The realization of these complex requirements
necessitates an integrated evaluation approach that
considers the manufacturing process plus the entire lifespan
up to the potential failure of the device. The object's
transfer into its digital twin allows for its numerical
simulation and digital analysis at arbitrary time and length
scales, which offer precious and experimentally hard to
access process insights. This cumulative dissertation may
provide a valuable contribution to the systemic product
development process and, thus, addresses the digital
modeling of multiphysical manufacturing and failure
processes based on the finite element method. The works
comprise the model development of an efficient modeling
approach for material dissolution and moving boundary value
problems in electrochemical machining and, for the product
application, the modeling and regularization of anisotropic
damage at finite strains. The first three articles deal with
the efficient modeling of the manufacturing process of
electrochemical machining. In the first article, a novel
methodology for modeling material dissolution based on
effective material parameters is developed that resolves the
fundamental issue of computationally expensive remeshing
during the simulation of dissolution processes of the
workpiece. The second article features the application of
effective material parameter modeling for the simulation of
the tool and, thereby, enables the entire process simulation
of the moving boundary value problem without mesh
adaptation. The third article extends the isotropic rules of
mixture for the identification of the effective material by
an anisotropic formulation, which is based on the
orientation of the electric current density. The subsequent
four articles cover the gradient-extended modeling of
anisotropic damage. In the fourth and fifth article, two
energy formulations, which fulfill a physical stiffness
reduction according to the damage growth criterion, are
employed to develop an efficient and universal
gradient-extension for inelastic processes with
tensor-valued internal variables. A novel
volumetric-deviatoric gradient-extension of the damage
tensor using two micromorphic degrees of freedom yields an
effective regularization capability to obtain mesh
independent results. Further structural simulations in the
sixth and seventh article confirm the performance of the
developed regularization methodologies.},
cin = {311510},
ddc = {624},
cid = {$I:(DE-82)311510_20140620$},
typ = {PUB:(DE-HGF)11},
doi = {10.18154/RWTH-2024-11476},
url = {https://publications.rwth-aachen.de/record/998601},
}
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