Computer-aided design tool for typical flexible mechanisms synthesis by means of evolutionary algorithms

Ben Abdallah, Mohamed Amine; Khemili, Imed; Aifaoui, Nizar; Laribi, Med Amine

doi:10.1017/s0263574724000171

Robotica

2024

DOI: 10.1017/s0263574724000171

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Computer-aided design tool for typical flexible mechanisms synthesis by means of evolutionary algorithms

Mohamed Amine Ben Abdallah,

Imed Khemili,

Nizar Aifaoui

et al.

Abstract: Accurate prediction for mechanisms’ dynamic responses has always been a challenging task for designers. For modeling easiness purposes, mechanisms’ synthesis and optimization have been mostly limited to rigid systems, making consequently the designer unable to vow that the manufactured mechanism satisfies the target responses. To address this limitation, flexible mechanism synthesis is aimed in this work. Two benchmark mechanisms being the core of myriad mechanical devices are of scope, mainly, the flexible sl… Show more

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Trajectory-based synthesis of a slider-crank mechanism for applications in inertial vibration exciters

Korendiy,

Vilchynskyi,

Lozynskyy

et al. 2024

Vib. proced.

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Slider-crank mechanisms are widely used in various industrial and technological machines. This paper considers a generalized diagram of a slider-crank mechanism, on the connecting rod of which an imbalanced mass can be fixed. In such a case, the slider-crank mechanism can be employed as an inertial vibration exciter. The aim of this research is to justify the geometric parameters of the mechanism to ensure a predetermined elliptical trajectory of the imbalanced mass motion. The research methodology involves the analytical derivation of the motion equations for a connecting rod point and solving the problem of synthesizing the geometric parameters of the mechanism based on the given trajectory of this point. The obtained results are presented in the form of displacements and trajectories for the connecting rod point of a specific slider-crank mechanism. The major novelty of this research lies in the further development of the theory of slider-crank mechanism synthesis for use in inertial vibration exciters. The derived analytical dependencies can be utilized by designers and engineers in the development of new types of vibration exciters for various industrial and technological vibratory equipment.

show abstract

Trajectory-based synthesis of a slider-crank mechanism for applications in inertial vibration exciters

Korendiy,

Vilchynskyi,

Lozynskyy

et al. 2024

Vib. proced.

View full text Add to dashboard Cite

show abstract

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Computer-aided design tool for typical flexible mechanisms synthesis by means of evolutionary algorithms

Cited by 1 publication

References 63 publications

Trajectory-based synthesis of a slider-crank mechanism for applications in inertial vibration exciters

Trajectory-based synthesis of a slider-crank mechanism for applications in inertial vibration exciters

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