Abstract
The engines of electric and hybrid vehicles cause vibration and noise with complex frequency spectra. This tendency is observed especially for mid-frequency components. Therefore, there are limitations in achieving vibration attenuation using only structural changes, which is the conventional isolation method. A smart structure-based active engine mounting system is a core technology that can continuously improve the noise, vibration, and harshness performance under various operating conditions by continuously controlling the dynamic characteristics of the mount. It can replace the existing mount technology which supports the engine by realizing both static and dynamic stiffness. This study focuses on vibration reduction for a typical mid-frequency excitation. Based on a source–path–receiver structure, a mathematical model for a 3D plate structure with three active paths is proposed. The amplitude and phase of the actuator were calculated for the reduction of given vibrations on the basis of the model. When controlling with the proposed method, it was necessary to perform a large amount of computation and to newly define the modeling according to the structural change. To solve this inconvenience, the NLMS (normalized least mean squares) algorithm was applied, and the results were compared. It is shown that the application of the NLMS algorithm to perform the overall vibration reduction is more effective than the previous method.
Highlights
The downsizing and manufacturing of high-efficiency vehicles are being pursued to produce a lightweight vehicle body and improve engine performance
(2) The NLMS algorithm was applied to the active control and compared to the calculation method of the actuator input
It was shown that applying the NLMS algorithm is effective for overall vibration reduction
Summary
The downsizing and manufacturing of high-efficiency vehicles are being pursued to produce a lightweight vehicle body and improve engine performance. This causes problems of noise, vibration, and harshness (NVH) performance deterioration, furthered by the many restrictions on the existing method of vibration reduction To solve these problems, there is a need for active engine mounting systems. Bartel et al [18,19] proposed a new type of engine mount that isolates engine vibration This was designed to withstand the dynamic forces of the structure, reducing power requirements by using small actuators. Liette et al [20] conducted studies to quantify active path interactions owing to passive system dynamic characteristics in a source–path–receiver system and vibration reduction for structures with path-coupled piezoelectric stack actuators and rubber mounts. This study discusses the following three points: (1) mathematical 3D modeling of structures with three active paths combining piezo stack actuators and rubber mounts; Appl.
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