Sage Journals: Discover world-class research

Abstract

Automobile subframe is key chassis component that connect the suspension to the car body, requiring high stiffness, strength, and vibration resistance under lightweight constraints. This study proposes a novel skeleton-type rear subframe design framework inspired by natural skeletal structures, incorporating multi-stage optimization strategy to balance structural performance and weight reduction. First, to obtain boundary conditions for optimization, a rigid–flexible coupled multi-body dynamic model of the rear suspension is established to obtain the loads acting at the key connection points under different load conditions. An efficient multi-load condition topology optimization model is then employed to minimize the subframe’s mass, bridging the gap between the initial design and target weight. Optimization control parameters are systematically analyzed and selected to ensure convergence toward an ideal topology. Subsequently, a multi-objective topology optimization (MOTO) approach is implemented to simultaneously minimize compliance and maximize the first-order natural frequency, with weighting coefficients for different load conditions determined objectively using gray relational analysis (GRA). The optimized steel subframe has a mass of 22.5 kg and the first-order modal frequency of 232.7 Hz, meeting both the lightweighting and requirement and multi-performance requirements. The proposed method provides an effective framework for designing lightweight, high-performance, and cost-efficient automotive subframes.

Keywords

skeleton subframe lightweight design natural frequency multi-load condition topology optimization multi-objective topology optimization

Get full access to this article

View all access options for this article.

References

Kastensson

. Developing lightweight concepts in the automotive industry: taking on the environmental challenge with the SåNätt project. J Clean Prod 2014; 66: 337–346.

Khaple

Golla

Prasad

. A review on the current status of Fe–Al based ferritic lightweight steel. Def Technol 2023; 26(8): 1–22.

Fan

Yin

, et al. Two-stage surrogate-based optimization of an automobile composite subframe with modified fast flexible space-filling designs. Mech Adv Mater Struct 2023; 30(4): 724–737.

Wang

Xue

Wei

, et al. Multi-condition and multi-objective conceptual optimization design of automotive front subframe. Proc Inst Mech Eng D J Automob Eng 2024; 239(13): 46.

Xue

Wang

Wei

, et al. Analysis and optimization of the front subframe of vehicle. Adv Mech Eng 2024; 16(11): 1–12.

Zhang

, et al. Topology optimization-based lightweight design of a certain tubular beam subframe. J Mech Sci Technol 2024; 38(11): 6253–6265.

Ryu

Hwang

Park

, et al. Body reinforcement design of suspension mounting point under dynamic loads using multi-objective topology optimization. Struct Multidiscip Optim 2022; 5(10): 1–15.

Bendsøe

Kikuchi

. Generating optimal topologies in structural design using a homogenization method. Comput Methods Appl Mech Eng 1988; 71(2): 197–224.

Bendsøe

Sigmund

. Material interpolation schemes in topology optimization. Arch Appl Mech 1999; 69: 635–654.

10.

Zhou

Rozvany

GIN

. The COC algorithm, part II: topological, geometry and generalized shape optimization. Comput Methods Appl Mech Eng 1991; 89(1–3): 309–336.

11.

Chen

. Variational level set method for topology optimization of origami fold patterns. J Mech Des 2022; 144(8): 081702.

12.

Xie

Steven

. A simple evolutionary procedure for structural optimization. Comput Struct 1993; 49(5): 885–896.

13.

Guo

Zhang

, et al. Explicit structural topology optimization based on moving morphable components (MMC) with curved skeletons. Comput Methods Appl Mech Eng 2016; 310: 711–748.

14.

Zhao

, et al. A method for topology optimization of structures under harmonic excitations. Struct Multidiscip Optim 2018; 58(2): 475–487.

15.

Wang

, et al. Lightweight design of turnover frame of bridge detection automobile using topology and thickness optimization. Struct Multidiscip Optim 2019; 59(3): 1007–1019.

16.

Zhang

Shan

Liu

, et al. An integrated multi-objective topology optimization method for automobile wheels made of lightweight materials. Struct Multidiscip Optim 2021; 64(3): 1585–1605.

17.

Fan

, et al. Structural multi-objective topology optimization and application based on the criteria importance through intercriteria correlation method. Eng Optim 2022; 54(5): 830–846.

18.

Cui

Cheng

, et al. A novel multi-objective topology–size integrated design strategy. Eng Optim 2024; 56(2): 293–317.

19.

Lee

Kim

, et al. Multi-scale design of composite material structures for maximizing fundamental natural frequency. Comput Methods Appl Mech Eng 2024; 425: 116928.

20.

Collet

Bruggi

Duysinx

. Topology optimization for minimum weight with compliance and simplified nominal stress constraints for fatigue resistance. Struct Multidiscip Optim 2017; 55(3): 839–855.

21.

Marler

Arora

. Survey of multi-objective optimization methods for engineering. Struct Multidiscip Optim 2004; 26(6): 369–395.

22.

Ramayee

Supradeepan

Sreejith

, et al. Multi-objective optimization of lobed enclosure for wind turbine applications using gray relation analysis. J Energy Resour Technol 2022; 144(11): 111302.

23.

Park

Sutradhar

Shah

, et al. Design of complex bone internal structure using topology optimization with perimeter control. Comput Biol Med 2018; 94: 78–84.

24.

Sigmund

. Morphology-based black and white filters for topology optimization. Struct Multidiscip Optim 2007; 33: 401–424.

25.

Bruns

Tortorelli

. Topology optimization of non-linear elastic structures and compliant mechanisms. Comput Methods Appl Mech Eng 2001; 190(26–27): 3443–3459.

26.

Zhou

Shyy

Thomas

. Checkerboard and minimum member size control in topology optimization. Struct Multidiscip Optim 2001; 21(2): 152–158.

A novel skeleton structure using topology optimization design for automobile rear subframe

Abstract

Keywords

Get full access to this article

References