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Muffler Basics
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Muffler Performance Requirements
Suitable outer geometry. Low pressure drop. Sufficient sound attenuation.
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Reactive (reflective)
MUFFLER BASICS Definition: A device for reducing sound in pipe or duct systems…. Classification Reactive (reflective) Dissipative Area change Resonators Active Porous material Flow constriction
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Measures of damping A number of measures exist. The most common are:
Incident Sound power Transmitted Sound power A number of measures exist. The most common are: - “Transmission Loss (TL)” where a reflection free termination is assumed. The TL only depends on the property of the muffler and is independent of the source.
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- “Insertion Loss (IL)”
For a given source the transmitted sound power (W) is measured downstream for a reference system (e.g. a straight pipe) and with a muffler system. This measure will in particular for low frequencies (plane waves) depend on the properties of the entire system (source + pipe lengths + muffler). - “Noise Reduction (NR)” Here the sound pressure is measured in a cross-section before and after the muffler. This measure depends on the muffler + the termination.
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Insertion Loss Change in Sound Pressure Level at the tail pipe outlet resulting from the insertion of a muffler. IL=SPL1-SPL2
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Noise Reduction Difference between sound pressure levels measured upstream and downstream of muffler NR = SPLu - SPLd
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Area Discontinuity Increase or Decrease
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Reactive mufflers Application: Effective for tones in the low frequency range (plane waves). Area change: Note the position of the maxima depends on the temperature since , where T is the temperature in K.
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Expansion Chamber High Frequency Effects
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Reactive mufflers... Resonators: A reflection factor close to -1 is created when the input impedance (Zin) is zero (resonance condition). TL[dB] fr Zin f [Hz]
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Side Branches Zin f [Hz] TL[dB] fr
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The Quarter wave resonator
Reactive mufflers... TL[dB] fr Zin The Helmholtz-resonator f [Hz] TL[dB] c/4L f [Hz] 3c/4L 5c/4L L Zin The Quarter wave resonator
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Increased length and thickness gives increased damping
Dissipative mufflers Application: Effective for broad-band sounds. The standard types are based on porous materials and are mainly efficient at mid- or high frequencies. Based on porous mtrl. TL[dB] f [Hz] Increased length and thickness gives increased damping Plane wave range
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Dissipative mufflers…
Based on flow constrictions Typically realised via perforated pipes or plates with through flow. Can give damping also at low frequencies… TL[dB] f [Hz] Increasing with flow speed
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Example: Combined reactive-dissipative car muffler
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Measured and simulated TL in the plane wave range (SIDLAB)
Without flow With flow M = 0.15
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Flow generated noise Created at flow constrictions i.e. regions which create flow separation (turbulence) The sound power generated will limit the maximum damping that can be obtained by a muffler The sound power scales as W ~ U a, where a = 4-6. For dissipative mufflers (of porous type) it is also proportionell to the muffler length. Wtr
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Structural by-pass and break-out break–in effects
Sound propagating in ducts and pipes create wall vibrations. These vibrations can propagate as structural waves across a muffler thereby creating an alternative transmission path for the acoustic energy. This is called structural by-pass and will limit the maximum damping. The wall vibrations can also radiate sound to the surrounding air (break-out). This energy can, if reflected from external boundaries, excite pipe wall vibrations after the muffler and induce acoustic waves (break-in). This type of phenomenon is particular important for rectangular pipe and duct sections.
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The plane wave range - 2-ports
pa qa pb qb T qa pb qb a b pa qa qb pb pa Physical system Equivalent circuits
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2-ports – in series and parallell
1 2 M This configuration is best treated using the mobility matrix. Then the T-matrix can be calculated… 1 2
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A single expansion chamber
1 2 3 1 2 3
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Calculate TL using SIDLAB
For a single expansion chamber: f [Hz] c/4L 3c/4L 5c/4L TL(dB) Example: A1= m2, A2=0.025 m2, L=1 m TLmax=14.1 dB.
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Improved performance by adding a l/4 wave resonator…
2 1 3 4 l= ? m 1 3 4 2
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SIDLAB simulation.....
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