Iso-Geometric Analysis for Crash Simulation: Study of Anisotropy and Fracture Behaviour in Extruded Aluminium Structures
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Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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Sammanfattning
Achieving reliable crash and impact simulations is essential for improving vehicle
safety, reducing development time, and minimizing costs associated with physical
testing. Although the finite element (FE) method remains the established standard
for crashworthiness analysis in the automotive industry, its dependence on mesh
generation, geometric approximation, and reduced continuity can limit predictive
accuracy and efficiency in complex structural applications.
Isogeometric Analysis (IGA) has emerged as a promising alternative by directly incorporating
computer-aided design (CAD) geometry into numerical simulation through
spline-based basis functions. This framework enables exact geometry representation
and higher-order continuity, offering improved capability for capturing nonlinear
deformation, stress evolution, and damage initiation under crash-relevant loading
conditions.
This study investigates the applicability of IGA to automotive crash simulations, with
particular emphasis on the anisotropic behaviour of extruded aluminium components
and stress triaxiality-dependent ductile fracture. Numerical investigations are carried
out across multiple scales, ranging from material characterisation via tensile testing
to component- and assembly-level crash simulations.
The study includes a systematic evaluation of strain formulations, refinement strategies,
and solid discretisation approaches, motivated by the need to improve correlation
between numerical simulations and physical testing at Volvo Cars.
The results demonstrate that IGA improves geometric fidelity and produces smoother
and more stable solution fields, leading to enhanced prediction of stress distribution,
deformation patterns, and damage evolution compared to conventional FE
formulations. However, challenges remain, including numerical locking phenomena,
sensitivity to discretisation parameters, convergence issues in highly nonlinear
regimes, and limitations in preprocessing workflows and implementation complexity.
Overall, IGA shows strong potential for high-fidelity crash simulation, although
further developments are required to improve robustness and enable efficient largescale
industrial applications.
Beskrivning
Ämne/nyckelord
IGA, FEA, NURBS, GISSMO, Triaxiality, Failure strain, Volumetric locking, Solid elements, Anisotropy
