Design and analysis of automotive lightweight materials suspension based on finite element analysis

Ciampaglia, Alberto; Santini, Adolfo; Belingardi, Giovanni

doi:10.1177/0954406220947457

Cited by 11 publications

(4 citation statements)

References 12 publications

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“…They found the design method of the lightweight gearbox, which provided a basis for the early design of the automobile gearbox. Ciampaglia et al [22] proposed A design method for automobile suspension using lightweight materials and re-optimized the suspension structure using the finite element method to achieve lightweight and ensure structural strength. Mi et al [23] studied the collaborative optimization of the quality and life of the dump truck frame, analyzed and calculated by the kriging model and NSGA-II algorithm, and successfully reduced the dead weight of the frame while ensuring the fatigue life and static strength of the frame.…”

Section: Introducementioning

confidence: 99%

Multi-condition stability analysis and lightweight research of mining wide-body dump truck compartment

Liu,

Tian

et al. 2024

Meas. Sci. Technol.

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This paper proposes a multi-condition optimization method based on single condition optimization and weight. This method analyzes and discusses various working states of the wide-body dump truck and optimize its structure. Firstly, the modal shape and natural frequency of the carriage under modal conditions are analyzed using the finite element method. Combined with the mechanic’s theory, the carriage's force, deformation, and stress are studied under the turning and partial load conditions. This part provides a basis for subsequent stability analysis and lightweight research. According to the filtering white noise method and differential equation method, the f-class road model and the vehicle system dynamics model are established in MATLAB to study the influence of road vibration on the stability of the dump truck during operation. The carriage vibration data prove that the road vibration causes the low order resonance of the carriage and affects the stability of the dump truck. This part provides a basis for the subsequent stability optimization. Based on the above analysis, a multi-objective genetic algorithm (MOGA) based on the response surface is used to optimize the structural parameters of the carriage under partial load conditions, turning conditions and modal conditions, to realize the optimization of stability, mass, stress and deformation of the carriage. Finally, the entropy weight method is used to fuse the optimization results of the three working conditions. The correctness of the comprehensive optimization results is verified, and the wide-body dump truck carriage optimization is realized, proving the feasibility of the proposed method.

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Section: Introducementioning

confidence: 99%

Multi-condition stability analysis and lightweight research of mining wide-body dump truck compartment

Liu,

Tian

et al. 2024

Meas. Sci. Technol.

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“…Some studies focus on optimizing the vehicle suspension system to improve handling, vehicle manoeuvrability, rollover probability and passenger comfort. [19][20][21] Other work proposes to improve traditional suspension systems by using composite materials in the design process, 22 or to substitute the mechanical system with a mechatronic system to better isolate vibrations. 23 In the case of an optimization problem based on a finite element model, the substitution models are privileged to estimate the objective function.…”

Section: Introductionmentioning

confidence: 99%

Optimization of a land vehicle suspension subjected to a buried charge explosion

Titri

Bounab

Louar

et al. 2023

Proceedings of the Institution of Mechanical Engineers, Part C:

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Improvised Explosive Devices (IEDs) represent a serious threat to vehicles. These IEDs can partially or fully damage the vehicle and the onboard equipment and, threaten the lives of its crew. To protect against these devices, modifications to specialized vehicles are made in different parts. Among these latter, the present work focuses on the effects of the suspension system on the dynamic response of the vehicle. The behaviour of a McPherson suspension system of a light vehicle is numerically studied in order to optimize the dimensions of selected components. Three models based on different approaches are developed. The first is based on an Arbitrary Lagrangian Eulerian (ALE) formulation with fluid-structure coupling, which gives a more realistic representation of the blast phenomena. However, it needs significant calculation time and computational power. The second is a simplified, purely Lagrangian, model which requires less computational resources but includes several assumptions. The third model is based on a meta-modelling approach. This latter is used to optimize the dimensions of selected sub-systems of the vehicle suspension via a genetic optimization algorithm.

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“…The new structure reduced the structural weight by 63.3% from the baseline. Although advanced materials such as composites can significantly improve bending and torsion stiffness, the material and manufacturing costs are considerably higher than the conventional materials (Ciampaglia et al, 2021). Optimization methodology to obtain an optimal model in which the structural strength and cost are considered as the objective functions through the design procedure.…”

Section: Introductionmentioning

confidence: 99%

Optimizing stiffness and lightweight design of composite monocoque sandwich structure for electric heavy quadricycle

Homsnit,

Kongwat,

Ruangjirakit

et al. 2023

Lat. Am. j. solids struct.

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The lightweight design of electric heavy quadricycle (L7e) vehicles has contributed to energy savings and sustainable mobility. This study proposes an optimization methodology to design a monocoque sandwich structure under operating conditions for an L7e using a finite element model via HyperWorks. Woven fiberglass fabrics and high-density PVC foam are assigned as the face and core to construct the sandwich structure, respectively. Free-size optimization based on weight minimization is applied to obtain the suitable initial thickness of face and core structures in all components. Multi-objective size optimization is then performed by minimizing both mass and material cost to determine the optimal thickness of each layer. Finally, shuffle optimization is used to modify the stacking sequence for each component to maximize structural stiffness. The results indicate that the core thickness in the passenger compartment is sufficient to maintain stiffness while maintaining the structure's lightweight. However, shuffle optimization is insignificant for the current monocoque model, as the structural stiffness is only marginally improved after the process. Additionally, this study examines the optimized models for structural stiffness and discusses suitable procedures for designing a lightweight and safe electric vehicle.

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Design and analysis of automotive lightweight materials suspension based on finite element analysis

Cited by 11 publications

References 12 publications

Multi-condition stability analysis and lightweight research of mining wide-body dump truck compartment

Multi-condition stability analysis and lightweight research of mining wide-body dump truck compartment

Optimization of a land vehicle suspension subjected to a buried charge explosion

Optimizing stiffness and lightweight design of composite monocoque sandwich structure for electric heavy quadricycle

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