Methodology to optimize engine mounts design in order to minimize inertial unbalances vibration propagation

Cheli, Federico; Pezzola, M.; Agostoni, S.; Giombini, M.

doi:10.1109/med.2011.5983210

Cited by 2 publications

(2 citation statements)

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“…Nariman-Zadeh et al [11] used multi-objective optimization using genetic algorithms (MOGA) on a five-degree-of-freedom vehicle vibration model, and the optimization results clearly improved vibration isolation performance. Cheli F., et al [12] developed a technique for statistically forecasting inertial engine unbalances induced by the crank mechanism and, ultimately, the countershaft, lowering the consequent propagating vibrations transmitted to the frame by optimizing the engine mount structure. Design issues included the quantity of the engine mounts, their optimal positions, and their viscous elasticity qualities.…”

Section: Introductionmentioning

confidence: 99%

Optimal Motorcycle Engine Mount Design Parameter Identification Using Robust Optimization Algorithms

2022

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Mechanical vibrations have a significant impact on ride comfort; the driver is constantly distracted as a result. Volumetric engine inertial unbalances and road profile irregularities create mechanical vibrations. The purpose of this study is to employ optimization algorithms to identify structural elements that contribute to vibration propagation and to provide optimal solutions for reducing structural vibrations induced by engine unbalance and/or road abnormalities in a motorcycle. The powertrain assembly, swing-arm assembly, and vibration-isolating mounts make up the vibration-isolating system. Engine mounts are used to restrict transferred forces to the motorbike frame owing to engine shaking or road irregularities. Two 12-degree-of-freedom (DOF) powertrain motorcycle engine systems (PMS) were modeled and examined for design optimization in this study. The first model was used to compute engine mount parameters by reducing the transmitted load through the mounts while only considering shaking loads, whereas the second model considered both shaking and road bump loads. In both configurations, the frame is infinitely stiff. The mount stiffness, location, and orientation are considered to be the design parameters. The purpose of this study is to employ computational methods to minimize the loads induced by shaking forces. To continue the optimization process, Grey Wolf Optimizer (GWO), a meta-heuristic swarm intelligence optimization algorithm inspired by grey wolves in nature, was utilized. To demonstrate GWO’s superior performance in PMS, other optimization methods such as a Genetic Algorithm (GA) and Sequential Quadratic Programming (SQP) were used for comparison. To minimize the engine’s transmitted force, GWO was employed to determine the optimal mounting design parameters. The cost and constraint functions were formulated and optimized, and promising results were obtained and documented. The vibration modes due to shaking and road loads were decoupled for a smooth ride.

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Section: Introductionmentioning

confidence: 99%

Optimal Motorcycle Engine Mount Design Parameter Identification Using Robust Optimization Algorithms

2022

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“…The main issue for conventional elastomeric mount is, it damping and stiffness can't be tuned (fix). Thus, the stiffness and damping properties of elastomer need to be chosen correctly in order to obtain the optimum vibration suppression (Cheli et al, 2011). Moreover, it can only isolate single frequency vibrations and effective only in limited range of excitation frequencies (Wijaya et (Hosseini, 2010) Hydraulic Engine Mounts (HEMs) are the next generation of engine mounts which can be classified into three types namely hydraulic mount with simple orifice, hydraulic mount with inertia track and hydraulic mount with inertia track and decoupler (Yu et al, 2011).…”

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confidence: 99%

Modelling and verification of three dof engine mount system

Yusoff

Hudha

Kadir

et al. 2018

J. Fundam and Appl Sci.

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This paper presents the modelling and validation of three degree of freedom of engine mount system. The engine mounting system successful to isolate the driver and passenger from the noise and vibration, but there is a need to improve the performance of engine mount system due to current modern car design which required lighter car body, higher speed and lar power-intensive engine. The passive rubber has been modelled as spring and damper in parallel. Based on Newton's Second Law, the mathematical equation has been derived out and implemented into MATLAB Simulink for the validation purposes. A real experim from engine mount system has been used as the benchmark in this study. The response of the acceleration from the real system has been compared with the simulation result. Pe difference of 3.9 to 5% has been obtained for the simulated mod experimental result. This paper presents the modelling and validation of three degree of freedom of engine mount engine mounting system successful to isolate the driver and passenger from the there is a need to improve the performance of engine mount system due to current modern car design which required lighter car body, higher speed and lar intensive engine. The passive rubber has been modelled as spring and damper in parallel. Based on Newton's Second Law, the mathematical equation has been derived out and Simulink for the validation purposes. A real experim from engine mount system has been used as the benchmark in this study. The response of the acceleration from the real system has been compared with the simulation result. Pe has been obtained for the simulated model as compared to the real validation; three degree of freedom.

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Methodology to optimize engine mounts design in order to minimize inertial unbalances vibration propagation

Cited by 2 publications

References 1 publication

Optimal Motorcycle Engine Mount Design Parameter Identification Using Robust Optimization Algorithms

Optimal Motorcycle Engine Mount Design Parameter Identification Using Robust Optimization Algorithms

Modelling and verification of three dof engine mount system

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