Engineering Noise Control
Theory and Practice, Fourth Edition
4th Edition
Published on 24. June 2009
Book
Hardback
748 pages
978-0-415-48706-1 (ISBN)
Description
The practice of engineering noise control demands a solid understanding of the fundamentals of acoustics, the practical application of current noise control technology and the underlying theoretical concepts. This fully revised and updated fourth edition provides a comprehensive explanation of these key areas clearly, yet without oversimplification. Written by experts in their field, the practical focus echoes advances in the discipline, reflected in the fourth edition's new material, including:
completely updated coverage of sound transmission loss, mufflers and exhaust stack directivity
a new chapter on practical numerical acoustics
thorough explanation of the latest instruments for measurements and analysis.
Essential reading for advanced students or those already well versed in the art and science of noise control, this distinctive text can be used to solve real world problems encountered by noise and vibration consultants as well as engineers and occupational hygienists.
completely updated coverage of sound transmission loss, mufflers and exhaust stack directivity
a new chapter on practical numerical acoustics
thorough explanation of the latest instruments for measurements and analysis.
Essential reading for advanced students or those already well versed in the art and science of noise control, this distinctive text can be used to solve real world problems encountered by noise and vibration consultants as well as engineers and occupational hygienists.
Reviews / Votes
If you don't already have Bies and Hansen and you work in the field of noise control then this should be high on your list of purchases.-Noise Control Engineering Journal
More details
Edition
4th New edition
Language
English
Place of publication
London
United Kingdom
Target group
College/higher education
Edition type
New edition
Product notice
Paper over boards
Illustrations
230 s/w Zeichnungen
230 Line drawings, black and white
Dimensions
Height: 235 mm
Width: 159 mm
Weight
1293 gr
ISBN-13
978-0-415-48706-1 (9780415487061)
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Classification
Other editions
Additional editions
E-Book
12/2017
4th Edition
CRC Press
€61.49
Available for download
E-Book
12/2017
4th Edition
CRC Press
€61.49
Available for download
Other
06/2009
4th Edition
CRC Press
€154.20
Article exhausted; check different version
Book
06/2009
4th Edition
Taylor & Francis
€81.89
Article exhausted; check different version
Previous edition
Book
07/2003
3rd Edition
Spon Press
€191.64
Article exhausted; check for reprint
Persons
David A. Bies is now retired having served as a Reader and then Visiting Research Fellow at the University of Adelaide's School of Mechanical Engineering. He is an expert and widely published acoustics physicist who has also worked as a senior consultant in industry.
Colin H. Hansen is Professor and Head of the School of Mechanical Engineering at the University of Adelaide. With a wealth of experience in consulting, research and teaching in acoustics, he has authored numerous books, journal articles and conference proceedings on the topic.
Colin H. Hansen is Professor and Head of the School of Mechanical Engineering at the University of Adelaide. With a wealth of experience in consulting, research and teaching in acoustics, he has authored numerous books, journal articles and conference proceedings on the topic.
Content
Fundamentals and Basic Terminology
Introduction
Noise-Control Strategies
Acoustic Field Variables
Wave Equations
Mean Square Quantities
Energy Density
Sound Density
Sound Power
Units
Spectra
Combining Sound Pressures
Impedance
Flow Resistance
The Human Ear
Brief Description of the Ear
Mechanical Properties of the Central Partition
Noise Induced Hearing Loss
Subjective Response to Sound Pressure Level
Instrumentation for Noise Measurement and Analysis
Microphones
Weighting Networks
Sound Level Meters
Classes of Sound Level Meter
Sound Level Meter Calibration
Noise Measurements Using Sound Level Meters
Time-Varying Sound
Noise Level Measurement
Data Loggers
Personal Sound Exposure Meter
Recording of Noise
Spectrum Analysers
Intensity Meter
Energy Density Sensors
Sound Source Localization
Criteria
Introduction
Hearing Loss
Hearing Damage Risk
Hearing Damage Risk Criteria
Implementing a Hearing Conservation Program
Speech Interference Criteria
Psychological Effects of Noise
Ambient Noise Level Specification
Environmental Noise Level Criteria
Environmental Noise Level Surveys
Sound Sources and Outdoor Sound Propagation
Introduction
Simple Source
Dipole Source
Quadruple Source (Far-Field Approximation)
Line Source
Piston in an Infinite Baffle
Incoherent Plane Radiator
Directivity
Reflection Effects
Reflection and Transmission at a Plane/Two Media Interface
Sound Propagation Outdoors, General Concepts
Sound Power, its Use and Measurement
Introduction
Radiation Impedance
Relation between Sound Power and Sound Pressure
Radiation Field of a Sound Source
Determination of Sound Power Using Intensity Measurements
Determination of Sound Power Using Surface Vibration Measurements
Some Uses of Sound Power Information
Sound in Enclosed Spaces
Introduction
Low Frequencies
Bound between Low-Frequency and High-Frequency Behavior
High Frequencies, Statistical Analysis
Transit Response
Porous Sound Absorbers
Panel Sound Absorbers
Flat and Long Rooms
Applications of Sound Absorption
Auditorium Design
Partitions, Enclosures and Barriers
Introduction
Sound Transmission through Partitions
Noise Reduction vs Transmission Loss
Enclosures
Barriers
Pipe Lagging
Muffling Devices
Introduction
Measures of Performance
Diffusers as Muffling Devices
Classification of Muffling Devices
Acoustic Impedance
Lumped Element Devices
Reactive Devices
Lined Ducts
Duct Bends or Elbows
Unlined Ducts
Effect of Duct End Reflections
Duct Break-Out Noise
Line Plenum Attenuator
Water Injection
Directivity of Exhaust Duct
Vibration Control
Introduction
Vibration Isolation
Types of Isolators
Vibration Absorbers
Vibration Neutralizers
Vibration Measurement
Damping of Vibrating Surfaces
Measurement of Damping
Sound Power and Sound Pressure Level Estimation Procedures
Introduction
Fan Noise
Air Compressors
Compressors for Chillers and Refrigeration Units
Cooling Towers
Pumps
Jets
Control Valves
Pipe Flow
Boilers
Turbines
Diesel and Gas-Driven Engines
Furnace Noise
Electric Motors
Generators
Transformers
Gears
Transportation Noise
Practical Numerical Acoustics
Introduction
Low-Frequency Region
High-Frequency Region: Statistical Energy ANalysis
Introduction
Noise-Control Strategies
Acoustic Field Variables
Wave Equations
Mean Square Quantities
Energy Density
Sound Density
Sound Power
Units
Spectra
Combining Sound Pressures
Impedance
Flow Resistance
The Human Ear
Brief Description of the Ear
Mechanical Properties of the Central Partition
Noise Induced Hearing Loss
Subjective Response to Sound Pressure Level
Instrumentation for Noise Measurement and Analysis
Microphones
Weighting Networks
Sound Level Meters
Classes of Sound Level Meter
Sound Level Meter Calibration
Noise Measurements Using Sound Level Meters
Time-Varying Sound
Noise Level Measurement
Data Loggers
Personal Sound Exposure Meter
Recording of Noise
Spectrum Analysers
Intensity Meter
Energy Density Sensors
Sound Source Localization
Criteria
Introduction
Hearing Loss
Hearing Damage Risk
Hearing Damage Risk Criteria
Implementing a Hearing Conservation Program
Speech Interference Criteria
Psychological Effects of Noise
Ambient Noise Level Specification
Environmental Noise Level Criteria
Environmental Noise Level Surveys
Sound Sources and Outdoor Sound Propagation
Introduction
Simple Source
Dipole Source
Quadruple Source (Far-Field Approximation)
Line Source
Piston in an Infinite Baffle
Incoherent Plane Radiator
Directivity
Reflection Effects
Reflection and Transmission at a Plane/Two Media Interface
Sound Propagation Outdoors, General Concepts
Sound Power, its Use and Measurement
Introduction
Radiation Impedance
Relation between Sound Power and Sound Pressure
Radiation Field of a Sound Source
Determination of Sound Power Using Intensity Measurements
Determination of Sound Power Using Surface Vibration Measurements
Some Uses of Sound Power Information
Sound in Enclosed Spaces
Introduction
Low Frequencies
Bound between Low-Frequency and High-Frequency Behavior
High Frequencies, Statistical Analysis
Transit Response
Porous Sound Absorbers
Panel Sound Absorbers
Flat and Long Rooms
Applications of Sound Absorption
Auditorium Design
Partitions, Enclosures and Barriers
Introduction
Sound Transmission through Partitions
Noise Reduction vs Transmission Loss
Enclosures
Barriers
Pipe Lagging
Muffling Devices
Introduction
Measures of Performance
Diffusers as Muffling Devices
Classification of Muffling Devices
Acoustic Impedance
Lumped Element Devices
Reactive Devices
Lined Ducts
Duct Bends or Elbows
Unlined Ducts
Effect of Duct End Reflections
Duct Break-Out Noise
Line Plenum Attenuator
Water Injection
Directivity of Exhaust Duct
Vibration Control
Introduction
Vibration Isolation
Types of Isolators
Vibration Absorbers
Vibration Neutralizers
Vibration Measurement
Damping of Vibrating Surfaces
Measurement of Damping
Sound Power and Sound Pressure Level Estimation Procedures
Introduction
Fan Noise
Air Compressors
Compressors for Chillers and Refrigeration Units
Cooling Towers
Pumps
Jets
Control Valves
Pipe Flow
Boilers
Turbines
Diesel and Gas-Driven Engines
Furnace Noise
Electric Motors
Generators
Transformers
Gears
Transportation Noise
Practical Numerical Acoustics
Introduction
Low-Frequency Region
High-Frequency Region: Statistical Energy ANalysis