LEADER 06417nam 2200685 450 001 9910792224703321 005 20200520144314.0 010 $a1-78242-036-3 010 $a1-78242-028-2 035 $a(CKB)2560000000301471 035 $a(EBL)1875322 035 $a(SSID)ssj0001413421 035 $a(PQKBManifestationID)11841237 035 $a(PQKBTitleCode)TC0001413421 035 $a(PQKBWorkID)11429848 035 $a(PQKB)10210896 035 $a(Au-PeEL)EBL1875322 035 $a(CaPaEBR)ebr10991294 035 $a(CaONFJC)MIL785227 035 $a(OCoLC)897643981 035 $a(CaSebORM)9781782420286 035 $a(MiAaPQ)EBC1875322 035 $a(PPN)224632264 035 $a(EXLCZ)992560000000301471 100 $a20141210h20152015 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 00$aPower ultrasonics $eapplications of high-intensity ultrasound /$fedited by Juan A. Gallego-Juarez, Karl F. Graff 205 $aFirst edition. 210 1$aWaltham, Massachusetts :$cElsevier,$d2015. 210 4$d©2015 215 $a1 online resource (1167 p.) 225 1 $aWoodhead Publishing Series in Electronic and Optical Materials ;$vNumber 66 300 $aDescription based upon print version of record. 320 $aIncludes bibliographical references at the end of each chapters and index. 327 $aFront Cover; Power Ultrasonics: Applications of High-intensity Ultrasound; Copyright; Contents; List of contributors; Woodhead Publishing Series in Electronic and Optical Materials; Chapter 1: Introduction to power ultrasonics; 1.1. Introduction; 1.2. The field of ultrasonics; 1.3. Power ultrasonics; 1.4. Historical notes; 1.5. Coverage of this book; Part One: Fundamentals; Chapter 2: High-intensity ultrasonic waves in fluids: nonlinear propagation and effects; 2.1. Introduction; 2.2. Nonlinear phenomena; 2.2.1. Basic equations: acoustic, entropy, and vorticity modes 327 $a2.2.2. Scope of nonlinear acoustics2.3. Nonlinear interactions within the acoustic mode; 2.3.1. Simple waves; 2.3.2. Quadratic approximation; 2.3.3. Nonlinear distortion and shock formation; 2.3.4. Shock structure; 2.3.5. Intense acoustic fields radiated by finite-aperture sources; 2.3.6. Formation of high-intensity ultrasound fields using focusing; 2.4. Nonlinear interactions between the acoustic and nonacoustic modes; 2.4.1. General remarks; 2.4.2. Acoustic streaming and radiation force; 2.4.3. Medium heating due to absorption of acoustic waves; 2.4.4. Heat release at a shock 327 $a2.5. ConclusionChapter 3: Acoustic cavitation: bubbledynamics in high-powerultrasonic fields; 3.1. Introduction; 3.2. Cavitation thresholds; 3.2.1. Static tension threshold; 3.2.2. Acoustic cavitation threshold; 3.3. Single-bubble dynamics; 3.3.1. Bubble models; 3.3.2. Response curves; 3.3.2.1. Low driving; 3.3.2.2. High driving; 3.3.3. Parameter space diagrams; 3.3.4. Bubble habitat; 3.3.5. Single-bubble dynamics: examples; 3.3.5.1. Sound radiation; 3.3.5.2. Deformation, splitting, and merging; 3.3.5.3. Jet formation; 3.4. Bubble ensemble dynamics; 3.4.1. Bubble clusters 327 $a3.4.2. Bubble filaments3.4.3. Bubble double layers; 3.4.4. Bubble cones; 3.4.5. N-bubble model; 3.4.6. N-bubble simulation examples; 3.5. Acoustic cavitation noise; 3.5.1. Subharmonics and period doubling; 3.5.2. Synchronization; 3.5.3. Bubble splitting; 3.6. Sonoluminescence; 3.7. Conclusions; Chapter 4: High-intensity ultrasonic waves in solids: nonlinear dynamicsand effects; 4.1. Introduction; 4.2. Fundamental nonlinear equations; 4.2.1. Constitutive equations and equation of motion; 4.2.2. Approximate analytical solutions; 4.2.2.1. Applications 327 $a4.2.3. Isotropic solids and wave number modulation4.2.3.1. Applications; 4.3. Nonlinear effects in progressive and stationary waves; 4.3.1. Harmonic balance in progressive waves: dispersion and attenuation; 4.3.2. Frequency mixing; 4.3.2.1. Applications; 4.3.3. Stationary waves: nonlinear sources; 4.3.3.1. Applications; 4.4. Conclusions; Chapter 5: Piezoelectric ceramic materials for power ultrasonic transducers; 5.1. Introduction; 5.2. Fundamentals of ferro-piezoelectric ceramics; 5.2.1. From the ferroelectric single-crystal to the ceramic; 5.2.2. Ferroelectric hysteresis and domains 327 $a5.2.3. The poling process 330 $aThe industrial interest in ultrasonic processing has revived during recent years because ultrasonic technology may represent a flexible ?green” alternative for more energy efficient processes. A challenge in the application of high-intensity ultrasound to industrial processing is the design and development of specific power ultrasonic systems for large scale operation. In the area of ultrasonic processing in fluid and multiphase media the development of a new family of power generators with extensive radiating surfaces has significantly contributed to the implementation at industrial scale of several applications in sectors such as the food industry, environment, and manufacturing. Part one covers fundamentals of nonlinear propagation of ultrasonic waves in fluids and solids. It also discusses the materials and designs of power ultrasonic transducers and devices. Part two looks at applications of high power ultrasound in materials engineering and mechanical engineering, food processing technology, environmental monitoring and remediation and industrial and chemical processing (including pharmaceuticals), medicine and biotechnology. Covers the fundamentals of nonlinear propagation of ultrasonic waves in fluids and solids. Discusses the materials and designs of power ultrasonic transducers and devices. Considers state-of-the-art power sonic applications across a wide range of industries. 410 0$aWoodhead Publishing series in electronic and optical materials ;$vNumber 66. 606 $aUltrasonic waves$xIndustrial applications 606 $aHigh-intensity focused ultrasound 615 0$aUltrasonic waves$xIndustrial applications. 615 0$aHigh-intensity focused ultrasound. 676 $a620.28 702 $aGallego-Juarez$b Juan A. 702 $aGraff$b Karl F. 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910792224703321 996 $aPower ultrasonics$93868961 997 $aUNINA