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Transcript
Acoustics and Noise Physics of Sound • • • • • Sound is a response to pressure waves = c = 344 m/s @ 20° C in air Amplitude: Pressure [N/m2] Intensity: Amplitude squared I = P2 [Watts] Fourier Theorem Anatomy of the human ear • External Ear – Pinna – Auditory Canal • Middle Ear – Tympanic Membrane (eardrum) – Hammer (Malleus) – Anvil (Incus) – Stirrup (Stapes) – Round Window Membrane Anatomy of the human ear (cont’d) • Inner Ear – Semicircular canal – Cochlea and Basilar Membrane – Auditory Nerves Anatomy of the human ear (cont’d) Psychophysics of Sound • We have a non-linear perceptual response to sound pressure waves • Intensity Level [Bels]: IL = log10(I/Iref), where Iref is least audible (usually use 10-12 W) • But this is too large, so we use decibels (dB): 10 log10(I/Iref) • Since I = P2, Sound Pressure Level in dB is SPL = 20log10(P/Pref) • Pref generally 0.00002 N/m2 (threshold of hearing) Frequency Components • Sound is made up of a combination of frequency components (Fourier Theorem) • Pitch is perceptual response to frequency • Human hearing is not uniformly responsive to all frequencies Adding dBs from Sound Sources • E.g.: To combine 80 & 75 dB, difference (5 dB) intercepts curve at 1.2 dB, so sum is 81.2 dB Sample Problem • A jet engine produces 80 dB SPL as heard at 50 feet. What is the heard SPL as each engine is turned on? – – – – 1 engine: 80 dB 2 engines: 80 - 80 = 0, so combination is 83 dB 3 engines: 83 - 80 = 3, so combination is 84.8 dB 4 engines: 84.8 - 80 = 4.8 dB, so combo is 86 dB Computational Sound Addition N Li /10 SPLtotal 10 log 10 i 1 • Previous Example: – SPL = 10 log(1080/10 + 1080/10 + 1080/10 + 1080/10) – SPL = 10 log(4*108) – SPL = 86 dB • More precise, and easy to use for arbitrary numbers and values of sound sources Noise: Unwanted Sound Loudness • Noise measured in terms of “equal loudness” • Compared to a reference of 1000 Hz tone: – If 65 dB SPL tone at 50 Hz is equally loud as 40 dB 1000 Hz tone, then it has loudness level of 40 phons • Can draw equal loudness contours as f() Equal Loudness Contours Sound Levels • We measure sound levels with reference to equal loudness contours corresponding to three scales: A: from 40 phon contour B: from 70 phon contour C: essentially flat response • Report results in dB(A), dB(B), dB(C) Effects of noise • Psychological – startle, annoy – disrupt concentration, sleep, relaxation • Interference – disrupts speech communication, safety • Physiological – hearing loss – aural pain Health Effects • Acute damage to eardrum through very loud, sudden noises • Chronic damage to inner ear (hair cells of cochlea): – Threshold shift in impacted frequencies – Temporary or Permanent Audiograms • Any graph of auditory sensitivity as a function of frequency • By convention, increasing intensity of threshold (decreasing sensitivity) is plotted downwards • Hearing Level (HL): Correcting minimum SPL for reference as a function of frequency – e.g. if 0-ref level for 1000 Hz is 7 dB, then 0 dB HL is 7 dB SPL • So in HL, a “normal” audiogram is flat Permanent Threshold Shift in Textile Workers OSHA Maximum Permissible Industrial Noise Levels • Protection required when sound levels on A scale of SLM at slow response exceed: 8 hrs 6 4 3 2 1.5 1 0.5 0.25 90 dB(A) 92 95 97 100 102 105 110 115 Hearing Conservation Programs • 8-hour PEL TWA is 90 dBA, but • If 8-hour TWA exceeds 85 dBA, a Hearing Conservation Program must be implemented: – – – – – Noise monitoring Audiometric testing Hearing protection Employee training and tracking Recordkeeping (2 years req’d - more is prudent) Dose Calculation • Mixed exposure based on linear equation: Cn C1 C2 Em ... T1 T2 Tn where Cn = amount of time exposed at a level, & Tn=amount of time allowed at that level • If Em> 1, an over exposure has occurred Dose Example • Suppose an employee is exposed to – – – – 85 dB(A) for 3.75 hours 90 dB(A) for 2 hours 95 dB(A) for 2 hours 110 dB(A) for 0.25 hours • Then 2 2 0.25 Em 0 1.25 8 4 0.50 • So the worker was over exposed Transient Noise • Report % of time an SL is exceeded e.g. L10 = 70 dB(A) means that 10% of the time the noise exceeded 70 dB on the A scale • Noise Pollution Level: NPL L50 + (L10 - L90) + (L10 + L90)2/60 Transient Noise Survey Sources of Noise • • • • Vibrating machinery Combustion processes Movement of air Collision of materials Noise Measurements • Sound Level Meter – Area, grab – Used for noise surveys (typically annual) • Noise Dosimeter – Personal, continuous (integrated) Sound Level Meters • Mike Amp Freq. Filters Meter • Measure immediate sound level • Noise dosimeter: variation to permit sound measurement over work period Engineering Controls • Maintenance of machinery to eliminate vibration due to worn parts • Lubrication • Fluid damping • Fan blade redesign • Room design and layout • Barriers Administrative Controls • Limited exposure time • Training in use of engineering controls • Regular hearing tests for exposed individuals Personal Protective Equipment • Earplugs • Earmuffs • Enormous employee resistance due to discomfort • Safety concerns (e.g. inability to hear approaching forklift)
