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Acoustic Cavitation Theory and Equipment Design Principles for Industrial Applications of High-Intensity Ultrasound.

By: Contributor(s): Material type: TextTextSeries: Physics Research and TechnologyPublisher: Hauppauge : Nova Science Publishers, Incorporated, 2010Copyright date: ©2010Edition: 1st edDescription: 1 online resource (70 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781617616471
Subject(s): Genre/Form: Additional physical formats: Print version:: Acoustic Cavitation Theory and Equipment Design Principles for Industrial Applications of High-Intensity UltrasoundDDC classification:
  • 620.28
LOC classification:
  • TA367 -- .P47 2010eb
Online resources:
Contents:
Intro -- ACOUSTIC CAVITATION THEORY AND EQUIPMENT DESIGN PRINCIPLES FOR INDUSTRIAL APPLICATIONS OF HIGH-INTENSITY ULTRASOUND -- ACOUSTIC CAVITATION THEORY AND EQUIPMENT DESIGN PRINCIPLES FOR INDUSTRIAL APPLICATIONS OF HIGH-INTENSITY ULTRASOUND -- CONTENTS -- PREFACE -- Chapter 1 INTRODUCTION -- Chapter 2 SHOCK-WAVE MODEL OF ACOUSTIC CAVITATION -- 2.1. VISUAL OBSERVATIONS OF ACOUSTIC CAVITATION -- 2.2. JUSTIFICATION FOR THE SHOCK-WAVE APPROACH -- 2.3. THEORY -- 2.3.1. Oscillations of a Single Gas Bubble -- 2.3.2. Cavitation Region -- 2.4. SET-UP OF EQUATIONS FOR EXPERIMENTAL VERIFICATION -- 2.4.1. Low Oscillatory Velocities of Acoustic Radiator -- 2.4.2. High Oscillatory Velocities of Acoustic Radiator -- 2.4.3. Interpretation of Experimental Results of Work [26] -- 2.5. EXPERIMENTAL SETUP -- 2.6. EXPERIMENTAL RESULTS -- 2.7. SECTION CONCLUSIONS -- Chapter 3 SELECTION AND DESIGN OF MAIN COMPONENTS OF HIGH-CAPACITY ULTRASONIC SYSTEMS -- 3.1. ELECTROMECHANICAL TRANSDUCER SELECTION CONSIDERATIONS -- 3.2. HIGH POWER ACOUSTIC HORN DESIGN PRINCIPLES -- 3.2.1. Criteria for Matching a Magnetostrictive Transducer to Water at Cavitation -- 3.2.2. Five-Elements Matching Horns -- 3.2.2.1. Design Principles -- 3.2.2.2. Analysis of Five-Element Horns -- 3.2.3. Experimental Results -- 3.3. SECTION CONCLUSIONS -- Chapter 4 ULTRASONIC REACTOR CHAMBER GEOMETRY -- Chapter 5 FINAL REMARKS -- REFERENCES -- INDEX.
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Intro -- ACOUSTIC CAVITATION THEORY AND EQUIPMENT DESIGN PRINCIPLES FOR INDUSTRIAL APPLICATIONS OF HIGH-INTENSITY ULTRASOUND -- ACOUSTIC CAVITATION THEORY AND EQUIPMENT DESIGN PRINCIPLES FOR INDUSTRIAL APPLICATIONS OF HIGH-INTENSITY ULTRASOUND -- CONTENTS -- PREFACE -- Chapter 1 INTRODUCTION -- Chapter 2 SHOCK-WAVE MODEL OF ACOUSTIC CAVITATION -- 2.1. VISUAL OBSERVATIONS OF ACOUSTIC CAVITATION -- 2.2. JUSTIFICATION FOR THE SHOCK-WAVE APPROACH -- 2.3. THEORY -- 2.3.1. Oscillations of a Single Gas Bubble -- 2.3.2. Cavitation Region -- 2.4. SET-UP OF EQUATIONS FOR EXPERIMENTAL VERIFICATION -- 2.4.1. Low Oscillatory Velocities of Acoustic Radiator -- 2.4.2. High Oscillatory Velocities of Acoustic Radiator -- 2.4.3. Interpretation of Experimental Results of Work [26] -- 2.5. EXPERIMENTAL SETUP -- 2.6. EXPERIMENTAL RESULTS -- 2.7. SECTION CONCLUSIONS -- Chapter 3 SELECTION AND DESIGN OF MAIN COMPONENTS OF HIGH-CAPACITY ULTRASONIC SYSTEMS -- 3.1. ELECTROMECHANICAL TRANSDUCER SELECTION CONSIDERATIONS -- 3.2. HIGH POWER ACOUSTIC HORN DESIGN PRINCIPLES -- 3.2.1. Criteria for Matching a Magnetostrictive Transducer to Water at Cavitation -- 3.2.2. Five-Elements Matching Horns -- 3.2.2.1. Design Principles -- 3.2.2.2. Analysis of Five-Element Horns -- 3.2.3. Experimental Results -- 3.3. SECTION CONCLUSIONS -- Chapter 4 ULTRASONIC REACTOR CHAMBER GEOMETRY -- Chapter 5 FINAL REMARKS -- REFERENCES -- INDEX.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.

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