Dynamic modeling of gears: An innovative hybrid FEM–analytical approach

Q4 Engineering
F. Concli, Concli Gorla
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引用次数: 4

Abstract

Gearboxes are widely used in several applications ranging from the automotive to the industrial and robotic sectors. A planetary gearbox is a special kinematic gear arrangement that, taking advantage of a planet carrier, ensures high reduction ratios together with a very small design. Therefore, they are widely employed for transmissions which require a high power density. There are several fields of applications including, but not limited to, mechatronic, automation and wind power generation. To improve the design of new solutions, for performing monitoring activities on actual gearboxes and for the definition of maintenance schedules, the availability of physical models able to accurately describe the behavior of the system, both in healthy and damaged conditions, would represent a great support. Experimental and numerical studies of the behavior of gearboxes are already available in the literature. Nevertheless, while the experimental approaches are valid only for the specific configuration tested, the numerical techniques show limitations related to the computational effort required. This paper presents an innovative approach for the characterization of the behavior of two different geared transmissions. It is based on a hybrid approach that combines finite elements (FE) with analytical formulations. In detail, the solver computes separately the macro deformation of the bodies (numerical solution based on a coarse grid) and the contacts (solved analytically avoiding the need of mesh refinements). The computational effort is reduced significantly without affecting the accuracy of the results significantly. This approach was used to investigate and understand the vibro-dynamical behavior of a back-to-back test rig (typically used for the characterization of the surface fatigue strength of gears) and of an indus- trial planetary gearbox. The results obtained for the healthy – not damaged – gearboxes were compared with experimental measurements for both configurations in order to validate the hybrid approach. Once the models were validated, the same methodology was eventually used to study the effects of typical gear failures and in specifically surface fatigue (pitting), on the vibrational response. The capability to reproduce the effect of damages with the model of a gearbox represents the first indispensable step of a Structural Health Monitoring strategy. State-of-art and challenges are analyzed and discussed in the paper.
齿轮动力学建模:一种创新的混合有限元分析方法
变速箱广泛应用于从汽车到工业和机器人领域的几个应用中。行星齿轮箱是一种特殊的运动齿轮装置,利用行星载体,确保高减速比和非常小的设计。因此,它们被广泛应用于需要高功率密度的传输。有几个领域的应用,包括但不限于,机电一体化,自动化和风力发电。为了改进新解决方案的设计、对实际齿轮箱执行监测活动以及定义维护计划,能够准确描述系统在健康和损坏状态下行为的物理模型的可用性将是一个很大的支持。实验和数值研究的行为的齿轮箱已经在文献中可用。然而,虽然实验方法仅对测试的特定配置有效,但数值技术显示出与所需计算量相关的局限性。本文提出了一种创新的方法来表征两种不同齿轮传动的行为。它基于将有限元(FE)与解析公式相结合的混合方法。具体来说,求解器分别计算了物体的宏观变形(基于粗网格的数值解)和接触(解析解,避免了网格细化的需要)。在不显著影响结果准确性的情况下,大大减少了计算量。该方法被用于研究和理解背靠背试验台(通常用于表征齿轮表面疲劳强度)和工业行星齿轮箱的振动动力学行为。为了验证混合方法的有效性,将健康非损坏齿轮箱的结果与两种结构的实验测量结果进行了比较。一旦模型得到验证,同样的方法最终被用于研究典型齿轮失效的影响,特别是表面疲劳(点蚀),对振动响应。用齿轮箱模型再现损伤效应的能力是结构健康监测策略不可缺少的第一步。本文对目前的研究现状和面临的挑战进行了分析和讨论。
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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来源期刊
CiteScore
1.10
自引率
0.00%
发文量
24
审稿时长
33 weeks
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