MODEL AIDED DESIGN OF TUNED RUBBER TVD

Journal of KONES. Powertrain and Transport Pub Date : 2016-09-06 DOI:10.5604/12314005.1217250

J. Pankiewicz, B. Chilinski, Mariusz Wądołowski

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引用次数: 2

Abstract

The rotation of a crankshaft in piston combustion engines results from the acting of tangential forces on the crank, whose value changes with the change of the angle of shaft rotation. This results in torsional vibrations. These vibrations become especially dangerous when the frequency of changes of any components of tangential force is near or equal to the natural frequency of the shaft. It leads to resonant amplification of vibration amplitude and to exceeding the limit values of the angle of shaft torsion. Most often in such cases, various types of torsional vibration dampers are used. In automotive industry, these are usually rubber vibration dampers. Typical torsional vibration damper is an example of a resonant damper, which is designed for the most dangerous resonant frequency of the crankshaft related to the first form of vibration for which the torsional vibrations usually have the greatest amplitude. The design of such a damper involves choosing the inertia moment of the flywheel and the parameters of viscouselastic element. The article describes the model and the simulation research, which allowed for creating the procedure of designing rubber dampers of torsional vibrations. This procedure can help to reduce the costs of operation tests for the design of optimal torsional vibration damper.

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调谐橡胶TVD的模型辅助设计

活塞式内燃机曲轴的旋转是由于曲轴受到切向力的作用而产生的，切向力的大小随曲轴旋转角度的变化而变化。这就产生了扭转振动。当切向力的任何分量的变化频率接近或等于轴的固有频率时，这些振动变得特别危险。它导致振动幅值共振放大，并超过轴扭角的极限值。在这种情况下，通常使用各种类型的扭转阻尼器。在汽车工业中，这些通常是橡胶减振器。典型扭振减振器是谐振式减振器的一个例子，它是针对与扭振振幅最大的第一种振动形式相关的曲轴最危险的谐振频率而设计的。这种阻尼器的设计涉及飞轮转动惯量和粘弹元件参数的选择。本文描述了该模型和仿真研究，为建立扭转振动橡胶阻尼器的设计程序提供了依据。该方法有助于降低运行试验的成本，从而设计出最优的扭振减振器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of KONES. Powertrain and Transport

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