Experimental Analysis of Whistle Noise in a Particle Agglomeration Pipe

ASME 2018 Noise Control and Acoustics Division Session presented at INTERNOISE 2018 Pub Date : 2018-08-26 DOI:10.1115/NCAD2018-6116

Zhe Zhang, H. Tiikoja, M. Åbom, H. Bodén

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引用次数: 2

Abstract

A self-sustained sound, more usually known as a whistle, refers to a distinct tonal noise created due to the interaction between the sound and flow field. When a positive feedback loop is formed between the two fields, the energy in the mean flow will be transferred into the sound wave, thus giving rise to a whistle. In engineering practice, whistles are destructive as they can produce high sound and vibration levels and may result in risk for mechanical failures. In this work, a flow-related high level tonal noise was found during a measurement on a particle agglomeration pipe, which is a quasi-periodic corrugated structure designed for the exhaust system of heavy-duty trucks. The purpose of the pipe is to enhance particle agglomeration to increase the size of exhaust gas particles. To investigate the origin of the detected tonal noise additional measurements were carried out. Based on the measurement result, the aero-acoustic coupling in the agglomeration pipe was analyzed, revealing that the pipe has a large potentiality to amplify the incident sound power in the presence of a mean flow. Furthermore, the Nyquist stability criterion was applied to confirm the existence of exponentially growing modes in the system at certain conditions.

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颗粒凝聚管中哨子噪声的实验分析

自我持续的声音，通常被称为哨子，是指由于声音和流场之间的相互作用而产生的独特音调噪音。当两个场之间形成正反馈回路时，平均流中的能量将被转移到声波中，从而产生哨子。在工程实践中，哨子具有破坏性，因为它们可以产生很高的声音和振动水平，并可能导致机械故障的风险。本文对重型卡车排气系统的准周期波纹结构颗粒集聚管进行了测量，发现了与流动相关的高阶音调噪声。该管道的目的是增强颗粒团聚，以增加废气颗粒的大小。为了研究检测到的音调噪声的来源，进行了额外的测量。在此基础上，分析了集聚管内的气声耦合，发现在平均流存在的情况下，集聚管对入射声功率有较大的放大潜力。利用Nyquist稳定性判据证实了系统在一定条件下存在指数增长模态。

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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ASME 2018 Noise Control and Acoustics Division Session presented at INTERNOISE 2018

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