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100   $a20100730d2010      uy         0
101 0 $aeng
135   $aurcn|||||||||
181   $ctxt
182   $cc
183   $acr
200 10$aAcoustic cavitation theory and equipment design principles for industrial applications of high-intensity ultrasound /$fAlexey S. Peshkovsky and Sergei L. Peshkovsky
205   $a1st ed.
210   $aNew York $cNova Science Publishers$dc2010
215   $a1 online resource (70 p.)
225  0$aPhysics research and technology
300   $aDescription based upon print version of record.
311 08$a1-61761-093-3 
320   $aIncludes bibliographical references and index.
327   $a""LIBRARY OF CONGRESS CATALOGING-IN-PUBLICATION DATA""; ""CONTENTS""; ""PREFACE""; ""INTRODUCTION""; ""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]""
327   $a""2.5. EXPERIMENTAL SETUP""""2.6. EXPERIMENTAL RESULTS""; ""2.7. SECTION CONCLUSIONS""; ""SELECTION AND DESIGN OF MAIN COMPONENTS OF HIGH-CAPACITY ULTRASONIC SYSTEMS""; ""3.1. ELECTRO MECHANICAL TRANSDUCERS ELECTION 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""; ""ULTRASONIC REACTORCHAMBER GEOMETRY""
327   $a""FINAL REMARKS""""REFERENCES""; ""INDEX""
330   $aA multitude of useful physical and chemical processes promoted by ultrasonic cavitation have been described in laboratory studies. Industrial-scale implementation of the high-intensity ultrasound has, however, been hindered by several technological limitations, making it difficult to directly scale up the ultrasonic systems in order to transfer the results of the laboratory studies to the plant floor. High-capacity flow-through ultrasonic reactor systems required for commercial-scale processing of liquids can only be properly designed if the energy parameters of the cavitation region are correctly evaluated. Conditions which must be fulfilled to ensure an effective and continuous operation of an ultrasonic reactor system are provided in this book.
410  0$aPhysics Research and Technology
606   $aUltrasonic waves$xIndustrial applications
606   $aCavitation
606   $aUltrasonic equipment$xDesign and construction
615  0$aUltrasonic waves$xIndustrial applications.
615  0$aCavitation.
615  0$aUltrasonic equipment$xDesign and construction.
676   $a620.2/8
700   $aPeshkovsky$b Alexey S$01872271
701   $aPeshkovsky$b Sergei L$01872272
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910957998003321
996   $aAcoustic cavitation theory and equipment design principles for industrial applications of high-intensity ultrasound$94481391
997   $aUNINA