Rolling noise reduction through GA-based wheel shape optimization techniques

Proceedings of the YIC 2021 - VI ECCOMAS Young Investigators Conference Pub Date : 2021-07-07 DOI:10.4995/yic2021.2021.12577

X. Garcia-Andrés, Jorge Gutiérrez-Gil, V. Andrés, J. Martínez-Casas, F. Denia

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Abstract

Railway rolling noise is nowadays a major source of acoustic pollution in urban areas, with nearly up to 12 million people daily affected in Europe by this phenomenon [1]. Hence, the search for ways of decreasing such noise radiation has become a highly active and significant research field. Following this approach, a Genetic Algorithms-based shape optimization of the railway wheel [2] is developed with the aim of minimizing rolling noise. Different approaches are considered to address the problem, such as directly minimizing radiated Sound poWer Level (SWL) or using the maximization of the natural frequencies if computational efficiency is especially critical. A parametric Finite Element model is implemented for the wheel based on the most relevant geometric parameters in rolling noise radiation. For the acoustic calculation, the sound radiation models used in the TWINS software [3] are adopted, which also accounts for the whole dynamics of the wheel/rail system. Furthermore, for every candidate wheel proposed, a structural analysis is computed in order to check design feasibility in accordance with the corresponding standard [4]. In all cases, new geometries for the wheel cross section are achieved that reduce the radiated rolling noise. REFERENCES [1] WHO European Centre for Environment and Health, “Burden of disease from environmental noise”, WHO, Tech. Rep., 2011 [2] X. Garcia-Andrés, J. Gutiérrez-Gil, J. Martínez-Casas and F. D. Denia, “Wheel shape optimization approaches to reduce railway rolling noise”, Struct. Multidiscipl. Optim., Vol. 62, pp. 2555-2570, (2020). [3] D. J. Thompson, B. Hemsworth and N. Vincent, “Experimental validation of the TWINS prediction program for rolling noise, part 1: Description of the model and method”, J. Sound Vib., Vol. 193 (1), pp. 123–135, (1996). [4] UNE, “Railway applications. Wheelsets and bogies. Monobloc wheels. Technical approval procedure. Part 1: Forged and rolled wheels. UNE-EN-13979-1:2006”, Asociación Española de Normalización (UNE), Technical Standard, 2011.

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基于遗传算法的车轮形状优化技术降低滚动噪声

如今，铁路滚动噪音是城市地区声污染的主要来源，在欧洲，每天有近1200万人受到这一现象的影响。因此，寻找降低噪声辐射的方法已成为一个非常活跃和重要的研究领域。在此基础上，以最小化滚动噪声为目标，提出了基于遗传算法的铁路车轮[2]形状优化方法。不同的方法被考虑来解决这个问题，如直接最小化辐射声功率级(SWL)或使用最大的固有频率，如果计算效率特别重要。基于滚动噪声辐射中最相关的几何参数，建立了车轮的参数化有限元模型。声学计算采用TWINS软件[3]中使用的声辐射模型，该模型也考虑了轮轨系统的整体动力学。对提出的每个候选车轮进行结构分析，按照相应的标准[4]进行结构分析，以验证设计的可行性。在所有情况下，新的几何形状的车轮横截面实现，减少辐射滚动噪声。参考文献[1]世卫组织欧洲环境与健康中心，“环境噪声造成的疾病负担”，世卫组织，技术代表，2011年bbbx . garcia - andr， J. guti， J. Martínez-Casas和F. D. Denia，“减少铁路滚动噪声的车轮形状优化方法”，Struct。Multidiscipl。Optim。， Vol. 62, pp. 2555-2570，(2020)。[10]邓杰·汤普森，B.海姆斯沃斯和N. Vincent，“滚动噪声的TWINS预测程序的实验验证，第1部分:模型和方法的描述”，J. Sound Vib。，第193卷(1)，第123-135页，(1996)。“铁路应用。”轮对和转向架。实心轮子。技术审批程序。第一部分:锻造和轧制车轮。UNE- en -13979-1:2006”，Asociación Española de Normalización (UNE)，技术标准，2011。

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Proceedings of the YIC 2021 - VI ECCOMAS Young Investigators Conference

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