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Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
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Searching... | 30000010203727 | QC320.36 S54 2010 | Open Access Book | Book | Searching... |
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Summary
Summary
Two-phase nano- and micro-thermal control device research is now proving relevant to a growing range of modern applications, including those in cryogenics, thermal engineering, MEMS, and aerospace engineering. Until now, researchers have lacked a definitive resource that provides a complete review of micro- and nano-scale evaporative heat and mass transfer in capillaries-porous structures.
Transport Phenomena in Capillary-Porous Structures and Heat Pipes covers the latest experiemental research efforts in two-phase thermal control technology research and development. The book covers vaporization heat transfer and hydrodynamic processes occurring in capillary channels and porous structures--paying particular attention to the physical mechanisms of these phenomena. Extensive experimental research activities on unique film and photo materials of boiling inside slits, capillaries, and capillary-porous structures are reviewed.
By providing a complete record of research in the field, this volume gives researchers, engineers, and practitioners working on vaporization heat transfer and hydrodynamic processes the findings needed to avoid unnecessary experimental efforts, and will help further the development of this dynamic area of research.Author Notes
Smirnov, Henry
Table of Contents
Foreword | p. xi |
Preface | p. xiii |
Introduction | p. xv |
Nomenclature | p. xix |
Chapter 1 Hydrodynamics and Heat Transfer at Single-Phase Flow in Capillary and Slit Channels | p. 1 |
1.1 Hydrodynamics and Heat Transfer of Steady Single-Phase Flow in Capillaries and Slits | p. 1 |
1.2 Hydrodynamics and Heat Transfer of Nonsteady Single-Phase Laminar Flow | p. 9 |
1.3 Hydrodynamics and Heat Transfer of Single-Phase Turbulent Flow in Capillaries and Slits | p. 12 |
Chapter 2 Hydrodynamics and Heat Transfer at Single-Phase Flow through Porous Media | p. 17 |
2.1 Physical Fundamentals, Models, and Equations of Momentum and Heat Transfer at Single-Flow through Porous Media | p. 17 |
2.2 Effective Thermal Conductivity of Porous Structures | p. 20 |
2.3 Internal Heat Transfer in Porous Media | p. 28 |
2.4 Heat Transfer on the Porous Structure External Surface | p. 33 |
Chapter 3 Thermohydrodynamics at Vaporization inside Capillary-Porous Structures | p. 41 |
3.1 Vaporization Conditions in Capillaries and Capillary-Porous Structures | p. 41 |
3.2 Hydrodynamics at Vaporization in Capillary-Porous Structures | p. 45 |
3.3 Fundamental Principle of "Irreversibility Minimum" in Two-Phase Filtration Modeling | p. 55 |
3.4 Investigations of Vaporization in Porous Structures with Internal Heat Generation | p. 63 |
3.5 Experimental Investigations of Internal Characteristics and Mechanisms of Thermohydrodynamic Phenomena | p. 71 |
Chapter 4 Thermohydrodynamics at Vaporization in Slit and Capillary Channels | p. 93 |
4.1 Experimental Studies on Heat Transfer at Boiling in Slits and Capillary Channels | p. 93 |
4.2 Hydrodynamic Phenomena and Vaporization in Slit and Capillary Channels | p. 115 |
4.3 Experimental Studies of Vaporization Mechanism in Plain Slits and Annular Channels | p. 121 |
4.4 Physical Imaginations and Theoretical Models for Heat Transfer at Vaporization in Vertical Slits and Capillaries | p. 147 |
4.5 Physical Imaginations and Theoretical Models for Heat Transfer at Vaporization in Horizontal and Short Slits and Capillaries | p. 153 |
Chapter 5 Heat and Mass Transfer at Vaporization on Surfaces with Capillary-Porous Coverings | p. 163 |
5.1 Experimental Investigations of Vaporization Heat Transfer on Surfaces with Porous Coatings | p. 163 |
5.1.1 Experimental Investigations of Boiling Heat Transfer on Coated Surfaces in Subcritical Thermal Regimes | p. 163 |
5.1.2 Experimental Investigations of Boiling Heat Transfer on Surfaces Covered by Screen Wicks | p. 168 |
5.1.3 Experimental Investigations of Vaporization Heat Transfer on Fiber-Metal Surfaces | p. 182 |
5.1.4 Experimental Investigations of Vaporization Heat Transfer on Surfaces Covered by Corrugated Structures | p. 189 |
5.1.5 Experimental Investigations of Heat Transfer inside Evaporators of Loop Heat Pipes | p. 194 |
5.1.6 Experimental Investigations of Boiling Heat Transfer on Surfaces Covered by Sintered and Gas-Sprayed Coatings | p. 201 |
5.2 Experiments on Heat Transfer at Vaporization on Surfaces with Sintered Coatings: The Malyshenko Phenomenological Theory of Boiling | p. 214 |
5.3 Physical Imaginations and Models of Vaporization on Surfaces with Porous Coatings | p. 226 |
5.4 General Model of Vaporization Processes on the Coated Surfaces (the Third Stage) | p. 260 |
5.5 Heat Transfer at Vaporization on Surfaces Covered by Movable Capillary Structures | p. 271 |
5.6 Models of Heat Transfer inside Evaporators of LHP and Capillary Pumped Loops | p. 291 |
Chapter 6 Heat Transfer Crises at Vaporization Inside Slits, Capillaries, and on Surfaces Covered by Capillary-Porous Structures | p. 299 |
6.1 Physical Explanations and Semiempirical Models of Boiling Heat Transfer Crisis | p. 299 |
6.2 Modified Hydrodynamic Theory of Boiling Crises in Restricted Spaces | p. 303 |
6.3 Experiments on Boiling Heat Transfer Crisis at Forced Liquid Flow in Slits and Capillary Tubes | p. 305 |
6.3.1 Boiling Crisis at Forced Flow in Capillaries | p. 306 |
6.3.2 Boiling Heat Transfer Crisis at Low-Velocity Flow inside Annular Capillary Channels | p. 318 |
6.3.3 Experimental Investigation of the CHF at Forced Flow in Capillaries: Modified Hydrodynamic Theory of Boiling Heat Transfer Crisis | p. 319 |
6.3.4 CHF in Narrow Annular Channels (Experimental Data and Semiempirical Models) | p. 326 |
6.4 Experimental Research on the CHF at Pool Boiling in Slits, Capillaries, and Corrugated Capillary Channels | p. 330 |
6.5 Experimental Research on Heat Transfer Crisis at Boiling on Surfaces with Porous Coverings | p. 338 |
6.6 Maximum Heat Fluxes Inside Heat Pipes | p. 347 |
References | p. 355 |
Index | p. 371 |