Efficient structure crash topology optimization strategy using a model order reduction method combined with equivalent static loads

Ren, Chun Yu; Min, Hao; Ma, Tran; Wang, Fangquan

doi:10.1177/0954407019893841

Cited by 11 publications

(5 citation statements)

References 45 publications

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“…Considering vehicle crash scenario is a dynamic process and the collision force and deformation are non-linear, so traditional gradient-based topology optimization method is not suitable for highly nonlinear dynamic collision load cases. 23 Therefore, equivalent static load (ESL) method is used to describe the dynamic impact force as average impact force. Lee et al 24,25 proposed the equivalent static load (ESL) method to convert the dynamic collision into an average static force equivalently.…”

Section: Methodology and Materialsmentioning

confidence: 99%

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Electric vehicles body frame structure design method: An approach to design electric vehicle body structure based on battery arrangement

Chen

Wang

Zhao

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part D:

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Although the electric vehicles (EVs) have become the main development of the automotive industry, there is still very limited knowledge about the design method of EVs’ body structure. This paper substantially increases this limited knowledge by developing an EV’s aluminum alloy body frame structure design (EVFD) method based on battery arrangements. The main concept of the EVFD approach is the development of the parametric knowledge base to facilitate performance driven design of body structure in concept design stage, including the battery sub-libraries designed by vehicle power performances and the modular body frame structure sub-libraries and cross section of profile sub-libraries designed by structure performances. The layout of vehicle is firstly determined based on battery volume which calculated on the basis of power performance of EVs. And then, the body frame structures are designed by multi-load topology optimization and multi-objective parametric optimization based on the body structure performance, considering the battery layout and its mass distribution. The developed body structure knowledge base is screened through comparing their structural mechanical properties. The feasibility and accuracy of selected EV’s aluminum alloy body frame structure is verified by experiment. In this paper, the case study demonstrates that the proposed EVFD method based on battery arrangement can be effectively used to design aluminum alloy body frame structure of EVs, which provides a reference to other EV’s body structure design. Due to the performance driven design concept employed, the designed body structure for EV meets the requirements of lightweight, dynamic performance, and structural mechanical properties.

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Section: Methodology and Materialsmentioning

confidence: 99%

“…The 100% frontal collision condition is that the vehicle impacts the rigid wall at a certain speed, and the overlap ratio between the vehicle and the rigid wall is 100%, which mainly consider the safety of passenger. 23,37 During the collision, the energy between the vehicle and the rigid wall is converted, as follow:…”

Section: Methodology and Materialsmentioning

confidence: 99%

Electric vehicles body frame structure design method: An approach to design electric vehicle body structure based on battery arrangement

Chen

Wang

Zhao

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part D:

View full text Add to dashboard Cite

show abstract

“…According to the characteristics of the BESO algorithm, Lin et al [35] proposed a dynamic evolution strategy to accelerate convergence in topology optimization. Ren, et al [36] used faster model reduction methods to enhance convergence speed.…”

Section: Introductionmentioning

confidence: 99%

An Eigenfrequency-Constrained Topology Optimization Method with Design Variable Reduction

Liu,

Wu,

Chen

2024

sv-jme

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The dynamic response of structures heavily relies on eigenfrequency, so the optimization of eigenfrequency is valuable in various working conditions. The bi-directional evolutionary structural optimization (BESO) method has been widely applied due to its ability to eliminate grayscale elements. Based upon BESO, this paper introduces a topology optimization method that incorporates eigenfrequency constraints and reduces the number of design variables. In this method, the optimization objective was to minimize compliance. The Lagrange multiplier was used to introduce eigenfrequency constraints, allowing for coordinated control of compliance and eigenfrequency. To prevent oscillation during the optimization process, the sensitivity was normalized. Additionally, to achieve faster convergence, the variables were reduced after meeting volume constraints. The numerical examples demonstrate the effectiveness of this method in increasing the eigenfrequency of the structure and avoiding resonance.

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“…The so-called ReCUR technique was further enriched with a random forest model and the empirical interpolation method (Assou et al 2019;Gstalter et al 2020). Also Fehr et al (2016) analysed andRen et al (2020) optimised crash problems by splitting the domain into linear and non-linear parts, whereby only linear reduction techniques were tested.…”

Section: Introductionmentioning

confidence: 99%

Data-driven models for crashworthiness optimisation: intrusive and non-intrusive model order reduction techniques

Czech

Lesjak

Bach

et al. 2022

Struct Multidisc Optim

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To enable multi-query analyses, such as optimisations of large-scale crashworthiness problems, a numerically efficient model is crucial for the development process. Therefore, data-driven Model Order Reduction (MOR) aims at generating low-fidelity models that approximate the solution while strongly reducing the computational cost. MOR methods for crashworthiness became only available in recent years; a detailed and comparative assessment of their potential is still lacking. Hence, this work evaluates the advantages and drawbacks of intrusive and non-intrusive projection based MOR methods in the framework of non-linear structural transient analysis. Both schemes rely on the collection of full-order training simulations and a subsequent subspace construction via Singular Value Decomposition. The intrusive MOR is based on a Galerkin projection and a consecutive hyper-reduction step. In this work, its inter-and extrapolation abilities are compared to the non-intrusive technique, which combines the subspace approach with machine learning methods. Moreover, an optimisation analysis incorporating the MOR methods is proposed and discussed for a crashworthiness example.

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Efficient structure crash topology optimization strategy using a model order reduction method combined with equivalent static loads

Cited by 11 publications

References 45 publications

Electric vehicles body frame structure design method: An approach to design electric vehicle body structure based on battery arrangement

Electric vehicles body frame structure design method: An approach to design electric vehicle body structure based on battery arrangement

An Eigenfrequency-Constrained Topology Optimization Method with Design Variable Reduction

Data-driven models for crashworthiness optimisation: intrusive and non-intrusive model order reduction techniques

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