These illustrations of Noise and Vibration Control Principles and Application
were developed by Stig Ingemansson, Ingemansson Technology, Gothenburg,
Sweden. After his death, his company released the illustrations to the public
domain to benefit noise control goals in the larger community.
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A1
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Sound Behavior - Causes of sound production
Changes in force, pressure, or speed produce noise
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A2
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Sound Behavior - Causes of sound production
Airborne sound is usually produced by vibration in solids and fluids
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A3
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Sound Behavior - Causes of sound production
Structureborne sound travels great distances
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A4
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Sound Behavior - Low and high frequencies
The rate of change determines the amount of high frequency noise
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A5
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Sound Behavior - Low and high frequencies
The slower the repetitions, the lower the frequencies of the noise
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A6
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Sound Behavior - Low and high frequencies
High frequency sound is highly directional and easy to reflect
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A7
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Sound Behavior - Reduction in air
High frequency sound is greatly reduced by passing through air
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A8
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Sound Behavior - How disturbing?
Low frequency noise is less disturbing
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B1
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Sound from vibrating plates - Size and thickness
Make vibrating surfaces as small as possible
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B2
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Sound from vibrating plates - Size and thickness
Densely perforated plates produce less noise
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B3
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Sound from vibrating plates - Size and thickness
A long, narrow plate produces less sound than a square one
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B4
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Sound from vibrating plates - Size and thickness
Plates with free edges produce less low frequency noise
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B5
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Sound from vibrating plates - Size and thickness
Light objects and low speed produce the least impact noise
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B6
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Sound from vibrating plates - Size and thickness
A damped surface produces less sound
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B7
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Sound from vibrating plates - Resonance
Resonance amplifies noise but it can be damped
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B8
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Sound from vibrating plates - Resonance
Resonance shifted to higher frequency is more easily damped
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C1
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Sound production in air or gases - Wind tones
Wind tones can be eliminated
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C2
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Sound production in air or gases - Wind tones
Air flow past hollow openings should be avoided
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C3
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Sound production in air or gases - Ducts
Ducts without obstructions produce the least amount of noise from turbulence
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C4
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Sound production in air or gases - Ducts
Undisturbed flow produces the least amount of exit noise
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C5
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Sound production in air or gases - Ducts
Jet noise can be reduced by using an extra air stream
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C6
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Sound production in air or gases - Ducts
Low frequency jet noise is easier to reduce if converted to high frequency
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C7
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Sound production in air or gases - Fans
Fans make less noise if placed in smooth, undisturbed flow streams
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D1
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Sound production in flowing liquids - Pipe systems
Abrupt changes in area produce noise
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D2
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Sound production in flowing liquids - Pipe systems
Large and rapid changes in pressure produce cavitation noise
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E1
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Sound propagation indoors - Placement of sound source
Sound sources should not be placed near corners
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E2
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Sound propagation indoors - Absorption
Thick, porous layers absorb both high and low frequency sound
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E3
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Sound propagations indoors - Absorption
Cover layers with large perforations may be used without reducing absorption
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E4
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Sound propagations indoors - Absorption
Panels on studs absorb low frequencies
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E5
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Sound propagations indoors - Absorption
Sound barriers may be combined with sound absorptive ceilings
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F1
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Sound propagation in ducts - Reactive mufflers
All duct changes reduce sound transmission
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F2
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Sound propagations in ducts - Reactive mufflers
Expansion chambers are useful for reducing low-frequency noise
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F3
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Sound propagations in ducts - Dissipative mufflers
Dissipative mufflers are effective over a broad range of frequencies
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F4
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Sound propagation in ducts - Reactive mufflers
Reactive mufflers are effective in narrow frequency ranges
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F5
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Sound propagation in ducts - Reactive mufflers
Pure tomes can be eliminated by canceling sound
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F6
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Sound propagation in ducts - Dissipative mufflers
Unused spaces can be absorption chambers
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G1
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Sound from vibrating machines - Machine mounting
Machines which vibrate should be mounted on heavy, rigid bases
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G2
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Sound from vibrating machines - Machine mounting
Machines can be vibrations isolated with flexible elements
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G3
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Sound from vibrating machines - Machine mounting
Improperly selected isolators can increase vibrations
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G4
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Sound from vibrating machines - Machine mounting
Heavy machines producing low frequency vibrations require a rigid floor
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G5
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Sound from vibrating machines - Machine mounting
A separate foundation provides the best solidborne sound barrier
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G6
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Sound from vibrating machines - Machine mounting
Sound through connections must be blocked
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H1
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Sound reduction of walls - TL
The TL of a single wall is estimated from its surface weight
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H2
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Sound reduction of walls - TL
A single wall provides poor sound insulation around a certain frequency
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H3
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Sound reduction of walls - TL
Rigidity and weight are both important in thick walls
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H4
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Sound reduction of walls - TL
Light double walls provide good isolation
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H5
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Sound reduction of walls - TL
Double walls should have few connections
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