A Transient Numerical Analysis of a Dissipative Expansion Chamber Muffler

P. Maurerlehner, D. Mayrhofer, M. Mehrgou, Manfred Kaltenbacher, S. Schoder
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Abstract

Expansion chamber mufflers are commonly applied to reduce noise in heating, ventilation, and air-conditioning (HVAC) or exhaust systems. In dissipative mufflers, sound-absorptive materials, such as microperforated plates (MPP), are applied to achieve an enhanced and more broadband mitigation effect. Computational acoustics (CA) analyses of mufflers are usually carried out in the frequency domain, assuming time-harmonic excitation. However, certain applications require time-domain simulations. From a computational point of view, such transient analyses are more challenging. A transformation of the governing equations involving frequency-dependent material parameters into the time domain induces convolution integrals. We apply the recently proposed finite element (FE) formulation of a time-domain equivalent fluid (TDEF) model to simulate the transient response of dissipative acoustic media to arbitrary unsteady excitation. Like most time-domain approaches, the formulation relies on approximating the frequency-dependent equivalent fluid parameters by a sum of rational functions composed of real-valued and complex-conjugated poles. The arising convolution integrals are computed indirectly by solving a set of ordinary auxiliary differential equations (ADE) coupled to the scalar wave equation, according to the ADE method. The numerical study of a dissipative expansion chamber muffler with an MPP reveals that the characteristics of transient excitation fundamentally differ from the known time-harmonic behavior because the characteristic quarter-wavelength resonance cannot evolve. Negligible thermal losses allow the use of a constant, real-valued equivalent bulk modulus. The low rational approximation order of the equivalent density entails an increase of computational degrees of freedom induced by the proposed TDEF approach for the given problem by less than 7% compared to the frequency domain formulation.
耗散式膨胀腔消声器的瞬态数值分析
膨胀腔消声器通常用于降低暖通空调(HVAC)或排气系统的噪音。在耗散型消声器中,应用了吸声材料,如微穿孔板 (MPP),以达到更强、更宽的消声效果。消声器的计算声学(CA)分析通常在频域进行,假定为时谐激励。然而,某些应用需要时域模拟。从计算角度来看,这种瞬态分析更具挑战性。将涉及频率相关材料参数的控制方程转换到时域会产生卷积积分。我们应用最近提出的时域等效流体(TDEF)模型的有限元(FE)公式来模拟耗散声学介质对任意非稳态激励的瞬态响应。与大多数时域方法一样,该公式依赖于通过由实值和复共轭极点组成的有理函数之和来逼近随频率变化的等效流体参数。根据 ADE 方法,通过求解一组与标量波方程耦合的普通辅助微分方程 (ADE),可以间接计算所产生的卷积积分。对带有 MPP 的耗散膨胀腔消声器进行的数值研究表明,瞬态激励的特性与已知的时谐行为有本质区别,因为特征四分之一波长共振无法演化。可忽略的热损失允许使用恒定的实值等效体积模量。由于等效密度的合理近似阶数较低,与频域公式相比,针对给定问题提出的 TDEF 方法增加的计算自由度不到 7%。
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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