Organized Computational Measurement to Design a High-Performance Muffler

Industrial Metrology Pub Date : 2023-07-14 DOI:10.3390/metrology3030015

Mehran Saadabadi, Mahdieh Samimi, Hassan Hosseinlaghab

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Abstract

Engine noise, as a source of sound pollution for humans and the environment, can be reduced by designing a high-performance muffler. This study presents a novel, organized design process of that muffler for the KTM390 engine as a case study. The acoustic simulation analysis is performed in COMSOL software and aerodynamic analysis is performed in ANSYS Fluent. The features of the muffler considered in this designing process are the overall length of the muffler, the presence of baffles and related parameters (baffle distance, baffle hole diameter, and baffle hole offset), and the effects of extended tubes. In order to evaluate the acoustic performance of the muffler, an objective function has been defined and measured on two frequency ranges, 75–300 Hz and 300–1500 Hz. For evaluating the aerodynamic performance of that, the amount of backpressure is analyzed to achieve a maximum of 3.3 kilopascals for this muffler. The selection of the appropriate parameters includes comparing the resulting transmission loss curves and quantitative evaluation of objective functions (for transmission loss) and backpressure. This organized design process (i.e., tree diagram) leads to an increase in the efficiency of designing mufflers (for example, 41.2% improvement on backpressure).

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组织计算测量设计高性能消声器

发动机噪声作为人类和环境的声音污染源，可以通过设计高性能消声器来降低。本文以KTM390发动机消声器为例，提出了一种新颖的、有组织的消声器设计过程。在COMSOL软件中进行声学仿真分析，在ANSYS Fluent软件中进行气动分析。在本设计过程中考虑的消声器的特点是消声器的总长度，挡板的存在和相关参数(挡板距离，挡板孔直径，挡板孔偏移量)，以及延长管的影响。为了评价消声器的声学性能，定义了一个目标函数，并在75-300 Hz和300-1500 Hz两个频率范围内进行了测量。为了评估该消声器的气动性能，分析了该消声器的背压量，以达到3.3千帕斯卡的最大值。适当参数的选择包括比较得到的传输损失曲线和定量评价目标函数(传输损失)和背压。这种有组织的设计过程(即树形图)提高了消声器的设计效率(例如，在反压方面提高了41.2%)。

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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Industrial Metrology

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