Sage Journals: Discover world-class research

Abstract

A systematic comparative examination of different single-chamber and double-chamber muffler geometries, comprised of various baffle geometry and size, number of chambers, and inlet-outlet positioning was conducted to determine the most suitable geometry for size-efficient mufflers which can meet size-limitations of automotive applications, confirming enhanced transmission loss (TL). First, we considered a reference model for validation of the simulation method. Then, we objectively studied the effects of circular and rectangular baffles of different sizes on the TL of single-chamber mufflers. Next, double- and single-chamber models were compared. Consequently, to better analyze the performance of the representative benchmark double-chamber muffler, the effects of different layouts of the outlet were studied and the corresponding TL was derived, while the inlet and baffle type and size were fixed. Finally, the effect of inlet layout, considering given outlet position, baffle type, and size, was studied on the noise control performance of the muffler. Results indicate that the 75% circular baffle has a wide frequency range and high TL of 58 dB, where the 75% rectangular plate baffle has a transmission loss of 67 dB. The double-chamber muffler has a wider frequency range and a higher TL of 78 dB compared to the single-chamber muffler. Moreover, changes in the inlet-outlet of the silencer significantly affect TL. As the inlet-outlet positioning of the silencer greatly contributes to the space constraints and packaging of the vehicle components, therefore, the variations of the inlet-outlet position of the silencer in the limited space available in vehicles need to be considered as an important design parameter, considering packaging limitations and noise control performance, which can significantly affect tailpipe radiated noise.

Keywords

Automotive baffle exhaust inlet-outlet muffler noise transmission loss vehicle

Get full access to this article

View all access options for this article.

References

Reddy

KPK

Fatima

Mohanty

AR.

A new sound quality metric for the design of engine exhaust mufflers. Proc IMechE, Part D: J Automobile Engineering 2018; 232(2): 254–263.

Shinde

Gavali

Barawade

, et al. A review on muffler design for exhaust noise attenuation. Int J Eng Technol 2017; 9(3S): 428–431.

Yan

Xiao

Liu

, et al. Study on the order target of the sporty sound quality of the vehicle exhaust noise under acceleration. Proc IMechE, Part D: J Automobile Engineering 2019; 233(8): 2085–2095.

Sagar

Munjal

ML.

Design and analysis of a novel muffler for wide-band transmission loss, low back pressure and reduced flow-induced noise. Noise Control Eng J 2016; 64(2): 208–216.

Parlar

Ari

Yilmaz

, et al. Acoustic and flow field analysis of a perforated muffler design. Int J Mech Mechatron Eng, 2013; 7(3), 447–451.

Shojaeifard

Ebrahimi-Nejad

Kamarkhani

Optimization of exhaust system hangers for reduction of vehicle cabin vibrations. Int J Automot Eng 2017;7(1): 2314–2324

Munjal

. Acoustics of ducts and mufflers. 2nd Ed. John Wiley & Sons, Chichester, 2014.

Selamet

Denia

Besa

Acoustic behavior of circular dual-chamber mufflers. J Sound Vib 2003; 265(5): 967–985.

Davies

Holland

IC engine intake and exhaust noise assessment. J Sound Vib 1999; 223(3): 425–444.

10.

Talbot

D-IJ

Nezan

PDS

. Engine performance optimization through exhaust system simulation and testing. MTZ worldwide 2009; 70(9): 48–56.

11.

Ramu

Srinivasan

Somasundaram

, et al. Design of exhaust silencer muffler for transmission losses with the performance of a four stroke diesel engine with and without muffler section. Technology 2017; 8(1): 139–145.ã

12.

Zhu

ZL.

Transmission loss prediction of reactive silencers using 3-D time-domain CFD approach and plane wave decomposition technique. Appl Acoust 2016; 112: 25–31.

13.

Binois

Dauchez

Ville

, et al. Modeling of cylindrical baffle mufflers for low frequency sound propagation. In: Acoustics 2012, Nantes, FR, 2012. Societe Francaise d’Acoustique.

14.

Selamet

. Acoustic attenuation performance of circular expansion chambers with offset inlet/outlet: I. Analytical approach. J Sound Vib 1998; 213(4): 601–617.

15.

Jun

Wei

Yuan

, et al. Modification of exhaust muffler of a diesel engine based on finite element method acoustic analysis. Adv Mech Eng 2015; 7(4): 1–11.

16.

Banerjee

Jacobi

AM.

Analytical prediction of transmission loss in distorted circular chamber mufflers with extended inlet/outlet ports by using a regular perturbation method. J Vib Acoust 2015; 137(6): 061002.

17.

Tan

Khor

Zunaidi

NH.

Development of acoustical simulation model for muffler. Int J GEOMATE 2016; 11(24): 2385–2390.

18.

Allam

Acoustic modelling and testing of advanced exhaust system components for automotive engines. Doctoral Dissertation, Farkost och flyg, 2004.

19.

Fan

Guo

An investigation of acoustic attenuation performance of silencers with mean flow based on three-dimensional numerical simulation. Shock Vib 2016; 2016(2): 1–12.

20.

Jena

Panigrahi

SN.

Numerically estimating acoustic transmission loss of a reactive muffler with and without mean flow. Measurement 2017; 109: 168–186.

21.

Munt

. Acoustic transmission properties of a jet pipe with subsonic jet flow: I. the cold jet reflection coefficient. J Sound Vib 1990; 142(3): 413–436.

22.

Lee

JW.

Optimal topology of reactive muffler achieving target transmission loss values: design and experiment. Appl Acoust 2015; 88: 104–113.

23.

Verma

Munjal

Flow-acoustic analysis of the perforated-baffle three-chamber hybrid muffler configurations. SAE Int J Passenger Cars Mech Syst 2015; 8(1): 370–381.

24.

Ebrahimi-Nejad

Kheybari

Honeycomb locally resonant absorbing acoustic metamaterials with stop band behavior. Mater Res Express 2018; 5(10): 105801.

25.

Ebrahimi-Nejad

Kheybari

Composite locally resonating stop band acoustic metamaterials. Acta Acust United Acust 2019; 105(2): 313–325.

26.

Kheybari

Ebrahimi-Nejad

Locally resonant stop band acoustic metamaterial muffler with tuned resonance frequency range. Mater Res Express 2018; 6(2): 025802.

27.

Alinaghi

Ranjbar

. Noise transmission loss maximization in absorptive muffler with shells. Gazimağusa: North Cyprus/Eastern Mediterranean University, 2015.

28.

Gupta

Transmission loss of cylindrical muffler with different length to diameter ratio by using two load method and simulation tool. Int J Eng Sci Manage Res 2016; 3(4): 27–32.

29.

Xiang

Zuo

, et al. Study of multi-chamber micro-perforated muffler with adjustable transmission loss. Appl Acoust 2017; 122: 35–40.

30.

Elsayed

Bastien

Jones

, et al. Investigation of baffle configuration effect on the performance of exhaust mufflers. Case Stud Therm Eng 2017; 10: 86–94.

31.

Xuan

Liu

Gong

, et al. A time-domain finite volume method for the prediction of water muffler transmission loss considering elastic walls. Adv Mech Eng 2017; 9(2): 1687814017690068.

32.

Hongpu

Zhenlin

Zhuoliang

Influence of perforation and sound-absorbing material filling on acoustic attenuation performance of three-pass perforated mufflers. Adv Mech Eng 2018; 10(1): 1687814017748012.

33.

Williams

Kirby

Hill

, et al. Reducing low frequency tonal noise in large ducts using a hybrid reactive-dissipative silencer. Appl Acoust 2018; 131: 61–69.

34.

Coustyx Software. Muffler transmission loss—double expansion chamber, http://coustyx.com/Products/Coustyx/Validation/Indirect/Muffler/Muffler-2/ (2007, accessed 19 August 2021).

35.

Tao

Seybert

AF.

A review of current techniques for measuring muffler transmission loss. SAE Trans 2003: 2096–2100.

36.

Kheybari

Ebrahimi-Nejad

Dual-target-frequency-range stop-band acoustic metamaterial muffler: acoustic and CFD approach. Eng Res Express 2021; 3(3): 035027.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.78 MB

Effects of inlet-outlet positioning,muffler geometry,and baffle design on vehicle muffler performance for desired sound transmission loss

Abstract

Keywords

Get full access to this article

References

Supplementary Material