Chapter 10 Sound in Ducts
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1 Chapter 10 Sound in Ducts Slides to accompany lectures in Vibro-Acoustic Design in Mechanical Systems 01 by D. W. Herrin Department of Mechanical Engineering Lexington, KY Tel:
2 Types of Mufflers 1. Dissipative (absorptive) silencer: Duct or pipe Sound absorbing material (e.g., duct liner) Sound is attenuated due to absorption (conversion to heat)
3 Types of Mufflers. Reactive muffler: Sound is attenuated by reflection and cancellation of sound waves Compressor discharge details 40 mm 3
4 Types of Mufflers 3. Combination reactive and dissipative muffler: Sound absorbing material Perforated tubes Sound is attenuated by reflection and cancellation of sound waves + absorption of sound 4
5 Performance Measures Transmission Loss W i Wr Muffler W t Anechoic Termination Transmission loss (TL) of the muffler: ( ) TL db =10 log10 W W i t 5
6 Performance Measures Insertion Loss SPL 1 Muffler SPL IL (db) = SPL 1 SPL Insertion loss depends on : TL of muffler Lengths of pipes Termination (baffled vs. unbaffled) Source impedance Note: TL is a property of the muffler; IL is a system performance measure. 6
7 Example TL and IL Expansion Chamber Muffler Source Inlet Pipe Outlet Pipe TL and IL (db) Insertion Loss Transmission Loss -50 Frequency (Hz) Pipe resonances 7
8 Acoustic System Components Source Su Su Any acoustic system P (sound pressure reaction) Z t Input or load impedance z = P Su = r + jx Termination impedance z t = P t Su t = r t + jx t 8
9 Summary 1 Dissipative mufflers attenuate sound by converting sound energy to heat via viscosity and flow resistance this process is called sound absorption. Common sound absorbing mechanisms used in dissipative mufflers are porous or fibrous materials or perforated tubes. Reactive mufflers attenuate sound by reflecting a portion of the incident sound waves back toward the source. This process is frequency selective and may result in unwanted resonances. Impedance concepts may be used to interpret reactive muffler behavior. 9
10 The Helmholtz Resonator Named for: Hermann von Helmholtz, , German physicist, physician, anatomist, and physiologist. Major work: Book, On the Sensations of Tone as a Physiological Basis for the Theory of Music, 186. von Helmholtz,
11 Helmholtz Resonator Model V L x K = M ρoc S V B = ρ o S Lʹ B L is the equivalent length of the neck (some air on either end also moves). S B F = PS B M x + Kx = PS B x = jωu B x = u B jω " j ωm K % $ 'u B = PS B ω z B = P " 1 % = j$ S B u B S B ' " ωm K % $ ω ' z B 0 when ω = Damping due to viscosity in the neck are neglected K M = c SB Lʹ V (resonance frequency of the Helmholtz resonator) 11
12 Helmholtz Resonator Example A 1-oz (355 ml) bottle has a cm diameter neck that is 8 cm long. What is the resonance frequency? f f n n c π SB Lʹ V = 18 Hz 343 = π ( 0.0) = π 4 ( )( ) 1
13 Helmholtz Resonator as a Side Branch TL ( db) = 10 log ωlʹ c S B S c ωv Anechoic termination V = m 3 L = 5 mm S B = x 10-4 m S = 8 x 10-4 m f n = 154 Hz TL (db) Frequency (Hz) 35 Hz 13
14 Network Interpretation (any system) z B P z z A V z B z A z = z z B z A + z B A Can we make Z B zero? z z B = P! 1 $ = j S B u B " S B %! ωm K $ " ω % z B 0 when ω = K M = c SB Lʹ V (Produces a short circuit and P is theoretically zero.) 14
15 A Tuned Dynamic Absorber M F M 1 x Original System F K M 1 x Tuned Dynamic Absorber K 1 K 1 x/f tune K M = K 1 M 1 Original system M /M 1 =0.5 Tuned dynamic absorber ω/ω 1 15
16 Resonances in an Open Pipe P = 1 Pa source L p = 1 m First mode λ 1 = L p = c f 1 = 343 =171.5 Hz f 1 ( 1) Second Mode λ = L p = c f = 343 = 343 Hz f 1( 1) etc. 16
17 SPL at Pipe Opening No Resonator 17
18 Example HR Used as a Side Branch* TL ( db) = 10 log ωlʹ c S B S c ωv Anechoic termination V = 750 cm 3 L =.5 cm (L = 6.75 cm) D B = 5 cm (S B = 19.6 cm ) D = 10 cm (S = 78.5 cm ) f n = 340 Hz * e.g., engine intake systems 18
19 SPL at Pipe Opening with Resonator 19
20 The Quarter Wave Resonator The Quarter-Wave Resonator has an effect similar to the Helmholtz Resonator: S B z B L S TL ( kl) 4( S S ) ( ) B 4 S SB tan + = 10 log10 z B = jρ o c S B ω n = nπc L f n = nc 4L or cot( ωl c) = 0 when ωl c = nπ n =1,3, 5... L = nc 4 f = n " λ % $ ' 4 0
21 Summary The side-branch resonator is analogous to the tuned dynamic absorber. Resonators used as side branches attenuate sound in the main duct or pipe. The transmission loss is confined over a relatively narrow band of frequencies centered at the natural frequency of the resonator. 1
22 The Simple Expansion Chamber TL = 10 log10 4cos sin kl 4 m ( kl) + m + ( ) where m is the expansion ratio (chamber area/pipe area) = 9 in this example and L is the length of the chamber. 5 TL (db) Frequency (Hz)
23 Quarter Wave Tube + Helmholtz Resonator TL (db) Frequency (Hz) 3
24 Extended Inlet Muffler TL (db) (same for extended outlet) Frequency (Hz) 4
25 Two-Chamber Muffler TL (db) Frequency (Hz) 5
26 Complex System Modeling We would like to predict the sound pressure level at the termination. Quarter-wave resonator Source Engine Pump Compressor (intake or exhaust) Area change Expansion chamber Helmholtz Resonator termination 6
27 The Basic Idea The sound pressure p and the particle velocity v are the acoustic state variables 1 For any passive, linear component: p 1 = Ap + BS u p 1, u 1 any acoustic component! " $ p 1 S 1 u 1 S 1 u 1 = Cp + DS u or % ( A B +! = * -" ' ) C D, $ p S u % ' p, u Transfer, transmission, or four-pole matrix (A, B, C, and D depend on the component) 7
28 The Straight Tube A B L p 1, u 1 p,u (x = 0) (x = L) must have plane waves S Solve for A, B in terms of p 1, u 1 then put into equations for p, u. p( x) = Ae jkx + Be + jkx u( x) = 1 dp jkρ o c dx p( 0) = p 1 = A + B u( 0) = u 1 = A B ρ o c p( L) = p = Ae jkl + Be + jkl u( L) = u = Ae jkl Be + jkl ρ o c p 1 = p cos( kl) + u ( jρ o c)sin( kl) u 1 = p ( j ρ o c)sin( kl) + u cos( kl) ) jρ " $ p cos( kl) o c, + sin( kl). 1 $ S " +. $ ' = %$ S 1 u + 1 ($ js 1 S. + sin( kl) 1 cos( kl).%$ * + ρ o c S -. (note that the determinant A 1 D 1 -B 1 C 1 = 1) p S u $ ' ($ 8
29 9 Combining Component Transfer Matrices [ ] = i i i i i D C B A T Transfer matrix of i th component [ ] [ ] [ ][ ][ ] [ ] = = 1 1 system v p T v p T T T T T v p i n n n [ ] system system system system system = D C B A T
30 Straight Tube with Absorptive Material L k,z c (complex wave number and complex characteristic impedance)! " $ p 1 S 1 u 1 ( % * * = * ' * )* cos( k 'L) js 1 z c sin( k 'L) jz c sin( k 'L) S S 1 cos( k 'L) S + -! - -" -$,- p S u % ' 30
31 Area Change p 1 = p S 1 S S 1 u 1 = S u 1! " $ p 1 S 1 u 1 % ' ( = * 1 0 ) 0 1 +! -", $ p S u % ' 31
32 Expansion Chamber Muffler L S S S straight tube area changes! [ T ] = 1 0 " 0 1! [ T ] = "! $ % " cos( kl) cos( kl) jρ o c sin( kl) S' js' sin( kl) cos( kl) ρ o c jρ o c sin( kl) S' js' sin( kl) cos( kl) ρ o c $ % $! " % $ % 3
33 Expansion Chamber Muffler 18 6 S' S = 9 33
34 Transfer Matrix of a Side Branch S B p 1 = p = p B S Su 1 = S B u B + Su 1 z B = p B S B u B = p S B u B Su 1 = p ( z B ) + Su! " $ p 1 Su 1 % ' ( = * )* z B 1 +! -",- $ p Su % ' 34
35 Helmholtz Resonator Model V L x K = M ρoc S V B = ρ o S Lʹ B L is the equivalent length of the neck (some air on either end also moves). S B F = PS B M x + Kx = PS B x = jωu B x = u B jω " j ωm K % $ 'u B = PS B ω z B = P " 1 % = j$ S B u B S B ' " ωm K % $ ω ' z B 0 when ω = Damping due to viscosity in the neck are neglected K M = c SB Lʹ V (resonance frequency of the Helmholtz resonator) 35
36 Performance Measures Transmission Loss W i Wr A C B D W t Anechoic Termination 1 Transmission loss (TL) of the muffler:! TL =10 log 10 " $ ( ) TL db =10 log10 S in 4S out W W A + S outb ρc + ρcc S in i t + S out S in D % ' 36
37 Derivation Transmission Loss W i Wr A C B D W t Anechoic Termination 1! " $ p 1 S 1 u 1 % ( = * ' ) A C B D +! -", $ p S u % ' Express p 1, p, u 1 and u in terms of incident reflected waves p 1 = p +a + p a u 1 = p +a p a ρc W i = p +a ρc S 1 W t = p +b ρc S p = p +b u = p +b ρc TL =10 log W i W t 37
38 Performance Measures Insertion Loss [ ] = T 0! " A 0 B $ 0 C 0 D 0 % SPL 1 Z S [ T ] =! " A C B D $ % Z T Z S Muffler SPL Z T! IL = 0log 10 " $ A Z S + B Z T Z S + C + D Z T A 0 Z S + B 0 Z T Z S + C 0 + D 0 Z T % ' 38
39 Sound Wave Reflections in Engines Waves leaving engine Waves leaving muffler Muffler Engine Reflected from engine Reflected from muffler Reflected from muffler Reflected from open end Resonances can form in the exhaust and tail pipes as well as within the muffler. 39
40 Source Impedance Acoustic Source Waves Leaving Source Attenuating Element (i.e. Load) Reflected from Source Source Load Reflected from Attenuating Element z s u L p s p L z L p s z s + z L = p L z L 40
41 Transfer Impedance Incident Wave p1 p Reflected Wave u 1 = u Transmitted Wave z tr u p p1 z tr = p 1 p Su 41
42 Source/Load Concept Source z s, p s Load z L, p L L 1 L Muffler z t, p t p s z s p L z L ( ) ( ) IL = f TL, z s, z t p t = f TL, z s, z t, p s 4
43 Insertion Loss Prediction IL (db) Actual source impedance Pressure source (Zs=0) Velocity source (Zs=infinite) Anechoic source (Zs=rho*c) Frequency (Hz) 43
44 Source Impedance Series Impedance Source Load p s z s + z L = p L z L = Su L z s u L p s p L z L p s = Su L z s + p L z s = p s p L Su L 44
45 Source Impedance Parallel Impedance Source Load z Su L z L = Su s z L s u L z s + z L = p L u s z s p L z L z s = p L S( u s u ) L 45
46 Derivation Insertion Loss Z S Muffler 1 Z T SPL! " $ p 1 S 1 u 1 % ( = * ' ) z S = p s p 1 S 1 u 1 A C B D +! -", $ p S u p 1 = p s S 1 u 1 z s z T = p S u S u = p z T % ' p 1 = Ap + B z T p p 1 = p s S 1 u 1 z S " = p s z S Cp + D p % $ ' z T Ap + B " p = p s z S Cp + D p % $ ' z T p p s = 1 A + 1 z T B + z S C + z S z T D z T 46
47 Derivation Insertion Loss [ ] = T 0! " A 0 B 0 C 0 D 0 $ % SPL 1 Z S Z T Determined in same manner as prior slide p p s = 1 A z T B 0 + z S C 0 + z S z T D 0 47
48 Derivation Insertion Loss IL = 0 log p,nomuffler p,muffler p,nomuffler p s = p,muffler p s = 1 A z T B 0 + z S C 0 + z S z T D 0 1 A + 1 z T B + z S C + z S z T D! A Z IL = 0 log S + B Z T Z S + C + D Z T 10 " $ A 0 Z S + B 0 Z T Z S + C 0 + D 0 Z T % ' 48
49 Summary 3 The transfer matrix method is based on plane wave (1-D) acoustic behavior (at component junctions). The transfer matrix method can be used to determine the system behavior from component transfer matrices. Applicability is limited to cascaded (series) components and simple branch components (not applicable to successive branching and parallel systems). 49
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