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2: Applications in Transport Industry

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  • Page ID
    134597
    • Wikipedia

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    • 2.1: Rotor Stator Interactions
      This page examines aircraft noise reduction, highlighting rotor/stator interactions as a key noise contributor in turbomachinery. It underscores the importance of optimizing blade numbers to mitigate noise levels and frequency, particularly through control of Bessel functions. The discussion includes noise directivity, indicating that reduction strategies should vary by emission direction. Additionally, it recommends further exploration of other noise sources, such as cooling fans.
    • 2.2: Car Mufflers
      This page covers car mufflers' roles in exhaust systems, focusing on their noise reduction, gas expulsion, and emission control functions. It describes two main types: absorber mufflers, which are basic but less effective at low frequencies, and reflector mufflers, which improve noise dampening through sound wave reflection but may increase back pressure.
    • 2.3: Sonic Boom
      This page covers sonic booms, which are produced by shock waves from objects exceeding the speed of sound, especially during supersonic flights. Factors like size and speed influence their intensity, and designs are evolving to minimize noise pollution. It also details the Space Shuttle Columbia's crossing of the sound barrier shortly after launch, marking a key achievement in aerodynamics for human spaceflight.
    • 2.4: Sonar
      This page covers SONAR (Sound Navigation and Ranging), explaining its two types: active, which emits sound pings for detection but can reveal its position, and passive, which listens for sounds and is used mainly by submarines for stealth. The page highlights the historical development of sonar during WWI and its applications in naval warfare and marine ecology, as well as the impact of environmental factors on sound speed in water.
    • 2.5: Interior Sound Transmission
      This page introduces Noise, Vibration, and Harshness (NVH) in ground vehicles, defining noise by frequency, level, and quality. It distinguishes vibration as motion within a frequency range and describes harshness as unpleasant sensations. Sound quality encompasses various sound attributes beyond pitch and loudness. The chapter categorizes NVH and sound quality into powertrain factors, wind noise, road noise, operational sound quality, and issues like squeaks and rattles.

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