Multi-Criteria Optimization of an Innovative Suspension System for Race Cars

Țoțu, Vlad; Alexandru, Cătălin

doi:10.3390/app11094167

Cited by 6 publications

(3 citation statements)

References 21 publications

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“…Steering linkage of a bus is optimized using RSM approach [9]. Multi-criteria optimization of a suspension system is realized utilizing the conventional regression models [10]. DOE approach is used for a solid axle of a heavy commercial vehicle on optimizing steering kinematics which used statistical analysis [11].…”

Section: Introductionmentioning

confidence: 99%

Kinematics & Compliance Validation of a Vehicle Suspension and Steering Kinematics Optimization Using Neural Networks

AĞAKİŞİ,

ÖZTÜRK

2023

mech

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Physical and virtual K&C analyses are performed to achieve the vehicle dynamics targets by finding the optimum variables such as the position of hardpoints or stiffnesses of bushings. However, finding appropriate design variables that meet all the aims is challenging. This paper evaluates a hardpoint optimization approach to attain suspension K&C characteristic objectives with the design of experiments, neural networks, and genetic algorithm, based on a reference compact-sized prototype vehicle. The MBD model correlation is provided to optimize the hardpoints to improve the vehicle's steering kinematics concerning Ackerman error and camber angle variation that are out of target in baseline suspension. The results showed that NN based optimization strategy to define the hardpoints has significantly improved targeted characteristics compared to conventional response surface methods in the limited design space.

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Section: Introductionmentioning

confidence: 99%

Kinematics & Compliance Validation of a Vehicle Suspension and Steering Kinematics Optimization Using Neural Networks

AĞAKİŞİ,

ÖZTÜRK

2023

mech

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“…The results showed that the improved algorithm outperformed the traditional multi-objective particle swarm algorithm and the genetic algorithm. Totu and Alexandru [21] presented a comprehensive design method based on the least squares approach for the optimal design of an innovative racing car suspension system. This study used Adams/View and Adams/Insight to build a regression model and carry out the optimization design.…”

Section: Introductionmentioning

confidence: 99%

Optimal Design of Agricultural Mobile Robot Suspension System Based on NSGA-III and TOPSIS

Zhang

et al. 2023

Agriculture

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The stability of vehicles is influenced by the suspension system. At present, there are many studies on the suspension of traditional passenger vehicles, but few are related to agricultural mobile robots. There are structural differences between the suspension system of agricultural mobile robots and passenger vehicles, which requires structural simplification and modelling concerning suspension of agricultural mobile robots. This study investigates the optimal design for an agricultural mobile robot’s suspension system designed based on a double wishbone suspension structure. The dynamics of the quarter suspension system were modelled based on Lagrange’s equation. In our work, the non-dominated sorting genetic algorithm III (NSGA-III) was selected for conducting multi-objective optimization of the suspension design, combined with the Technique for Order Preference by Similarity to the Ideal Solution (TOPSIS) to choose the optimal combination of parameters in the non-dominated solution set obtained by NSGA-III. We compared the performance of NSGA-III with that of other multi-objective evolutionary algorithms (MOEAs). Compared with the second-scoring solution, the score of the optimal solution obtained by NSGA-III increased by 4.92%, indicating that NSGA-III has a significant advantage in terms of the solution quality and robustness for the optimal design of the suspension system. This was verified by simulation in Adams that our method, which utilizes multibody dynamics, NSGA-III and TOPSIS, is feasible to determine the optimal design of a suspension system for an agricultural mobile robot.

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“…Frequently, to simplify the theoretical models, the bushings are modeled by spherical (ball) joints, thus neglecting the linear deformations (which are, however, very small compared to the angular ones) [2][3][4][5][6][7]. In the case of the triangular guidance bars, with double articulation to the chassis and/or wheel carrier, as the case may be, the two afferent spherical connections determine, in fact, a revolute joint.…”

Section: Introductionmentioning

confidence: 99%

A Method for Finding the Static Equilibrium of the Non-Steered Wheel Suspension Systems Used in Passenger Cars

Alexandru

2022

Applied Sciences

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In this work, an analytical method for finding the equilibrium configuration of the suspension systems used for the non-steered (usually rear) wheels of the passenger car is proposed. This study is based on the static model, which takes into account the elastic elements of the suspension (springs, bushings, anti-roll bar, buffers). The external loading of the suspension system comes from the contact forces between the wheels and the ground, depending on the specific operating regime of the vehicle (static or dynamic, by case). An algorithm for analysis of the relative movements in the wheel guiding mechanisms was developed (and further integrated in the general method for finding the equilibrium position) with the purpose of establishing the deformations of the elastic elements. Finally, a computer program was conceived and tested on a particular application.

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Multi-Criteria Optimization of an Innovative Suspension System for Race Cars

Cited by 6 publications

References 21 publications

Kinematics & Compliance Validation of a Vehicle Suspension and Steering Kinematics Optimization Using Neural Networks

Kinematics & Compliance Validation of a Vehicle Suspension and Steering Kinematics Optimization Using Neural Networks

Optimal Design of Agricultural Mobile Robot Suspension System Based on NSGA-III and TOPSIS

A Method for Finding the Static Equilibrium of the Non-Steered Wheel Suspension Systems Used in Passenger Cars

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