Advances in heat transfer. Volume 42 /

Advances in heat transfer. Volume 42 /

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Bibliographic Details
Edition:1st ed.
Imprint:Amsterdam : Elsevier/Academic Press, 2010.
Description:1 online resource (xi, 311 pages) : illustrations.
Language:English
Series:Advances in heat transfer, 0065-2717
Subject:
Heat -- Transmission.
Heat -- Transmission.
Format: E-Resource Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/12378017
Hidden Bibliographic Details
Other authors / contributors:Cho, Young I.
Greene, G. Alanson.
ISBN:9780123786463
0123786460
9780123786456
0123786452
9786612879067
6612879068
1282879065
9781282879065
Notes:Includes bibliographical references and indexes.
English.
Print version record.
Summary:Advances in Heat Transfer fills the information gap between regularly scheduled journals and university-level textbooks by providing in-depth review articles over a broader scope than in journals or texts. The articles, which serve as a broad review for experts in the field, will also be of great interest to non-specialists who need to keep up-to-date with the results of the latest research. This serial is essential reading for all mechanical, chemical and industrial engineers working in the field of heat transfer, graduate schools or industry. Provides an overview of review articles on topics of current interest Bridges the gap between academic researchers and practitioners in industry A long-running and prestigious series.
Other form:Print version: Advances in heat transfer. Vol. 42. Amsterdam Elsevier/Academic Press 2010 9780123786456
Table of Contents:
  • Cover; Advances in Heat Transfer; Copyright; Contents; Contributors; Preface; Acoustic Wave Induced Flows and Heat Transfer in Gasesand Supercritical Fluids; I. Introduction; A. Mechanically Driven Acoustic Waves; B. Thermally Induced Acoustic Waves in Gases; C. Thermoacoustic Waves in Supercritical Fluids; II. Mathematical Model and Numerical Methods; A. Overview; B. Mathematical Model; C. Numerical Methods; III. Mechanically Driven Acoustic Waves in Gas-FilledEnclosures; A. Overview; B. Flows in an Acoustically Driven Rectangular Enclosure
  • C. Flows in an Acoustically Driven Cylindrical EnclosureD. Interactions of Mechanically Driven Acoustic Waves with Heat Transferin a Rectangular Chamber; IV. Numerical Study of Thermally Induced Acoustic Waves inGases; A. Introduction; B. Thermally Induced Acoustic Waves in Atmospheric and High PressureGases; C. Interactions of Thermally Induced Acoustic Waves with BuoyancyInduced Flows: Side-Wall Heated Enclosures; D. Interaction of Thermally Induced Acoustic Waves with BuoyancyInduced Flows: Bottom-Wall Heated Enclosure; V. Experimental Study of Thermally Induced Acoustic Wavesin Gases
  • A. IntroductionB. Experimental Apparatus and Procedure; C. Experimental Results and Discussion; VI. Thermally Induced Acoustic Waves in SupercriticalFluids; A. Introduction; B. Equation of State and Thermodynamic Properties of SupercriticalCarbon Dioxide; C. Numerical Results for Supercritical Carbon Dioxide; VII. Experimental Study of Thermally Induced Acoustic Wavesin Supercritical Fluids; A. Introduction; B. Experimental Apparatus and Procedures; C. Experimental Results and Discussion.; VIII. Summary and Conclusions; References
  • Characterization Methods of High-Intensity FocusedUltrasound-Induced Thermal FieldI. Introduction; A. HIFU Free-Field Characterization in Liquid Medium; B. HIFU Thermal Field Characterization in Tissue Medium; II. HIFU Thermal Field Characterization; A. Invasive Method; B. Nonperturbing Method; C. Noninvasive Method; III. Future Direction; A. Improvement in Calculations: Accounting for Boiling, Cavitation, andNonlinearity; B. Extension of Inverse Heat Transfer Method: Calculation of Intensityand Acoustic Absorptivity; References; Plasma Discharge in Water; I. Introduction
  • A. Needs for Plasma Water TreatmentB. Previous Studies on the Plasma Water Treatment; C. Process of Conventional Electrical Breakdown in Water; II. Underwater Plasma Sources; A. Direct Discharges in Liquid; B. Bubble Discharges in Liquid; III. Dynamics of Non-Equilibrium Plasma in Liquid Water; A. Experiment Setup; B. Results and Discussions; IV. Analysis of Microsecond Streamer Propagation; A. Electrostatic Model; B. Thermal Mechanism; C. Stability Analysis; V. Application of Spark Discharge for Scale Removal on FilterMembranes; A. Experiment Setup; B. Results and Discussion

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