Internformat: Microscale combustion and power generation /

Microscale combustion and power generation /:

Recent advances in microfabrication technologies have enabled the development of entirely new classes of small-scale devices with applications in fields ranging from biomedicine (portable defibrillators, drug delivery systems, etc.), to wireless communication and computing (cell phones, laptop compu...

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Hauptverfasser:	Ju, Yiguang (VerfasserIn), Cadou, Christopher P., 1965- (VerfasserIn), Maruta, Kaoru (VerfasserIn)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	New York, [New York] (222 East 46th Street, New York, NY 10017) : Momentum Press, 2015.
Schriftenreihe:	Engineering collection.
Schlagworte:	Internal combustion engines > Combustion. Combustion > Industrial applications. Microfabrication. Moteurs à combustion interne > Combustion. Combustion > Applications industrielles. TECHNOLOGY & ENGINEERING / Mechanical Internal combustion engines > Combustion Microfabrication microscale combustion flameless combustion combustion limits combustion instability excess enthalpy combustion small-scale liquid film combustors micro-tubes and porous combustors Swiss-roll combustors catalytic reactors micro-heat engines micro-reactors micro-power generators micro-thrusters model aircraft engines 2-stroke engines piston engines heterogeneous combustion catalytic combustion conjugate heat transfer scale-effects on combustion thermoelectric power generation micro gas turbine engine micro-rotary engine micro-rockets microfabrication MEMS
Online-Zugang:	Volltext
Zusammenfassung:	Recent advances in microfabrication technologies have enabled the development of entirely new classes of small-scale devices with applications in fields ranging from biomedicine (portable defibrillators, drug delivery systems, etc.), to wireless communication and computing (cell phones, laptop computers, etc.), to reconnaissance (unmanned air vehicles, microsatellites etc.), and to augmentation of human function (exoskeletons etc.). In many cases, however, what these devices can actually accomplish is limited by the low energy density of their energy storage and conversion systems. This breakthrough book brings together in one place the information necessary to develop the high energy density combustion-based power sources that will enable many of these devices to realize their full potentials.
Beschreibung:	1 online resource (1 PDF (xlvii, 512 pages) :) illustrations.
Bibliographie:	Includes bibliographical references and index.
ISBN:	9781606503089 1606503081 1606503065 9781606503065

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100	1		\|a Ju, Yiguang., \|e author.
245	1	0	\|a Microscale combustion and power generation / \|c Yiguang Ju, Christopher Cadou and Kaoru Maruta.
264		1	\|a New York, [New York] (222 East 46th Street, New York, NY 10017) : \|b Momentum Press, \|c 2015.
300			\|a 1 online resource (1 PDF (xlvii, 512 pages) :) \|b illustrations.
336			\|a text \|2 rdacontent
337			\|a computer \|2 rdamedia
338			\|a online resource \|2 rdacarrier
490	1		\|a Engineering collection
588			\|a Title from PDF title page (viewed on February 21, 2015).
504			\|a Includes bibliographical references and index.
505	0		\|a 1. Meso- and microscale combustion and flammability limits -- 1.1 Premixed flames in meso- and microscale combustion -- 1.2 Flammability limit and quenching diameter -- 1.3 Heat recirculation -- 1.4 Flame and wall structure coupling in microscale combustion -- 1.5 Weak flame regimes with temperature gradients -- 1.6 Coupling of thermal and kinetic quenching in microscale combustion -- 1.7 Non-equilibrium combustion -- References --
505	8		\|a 2. Boundary-accelerated flames in microchannels -- 2.1 Physical and numerical models -- 2.2 The boundary-layer accelerated flame -- 2.3 Effects of varying channel dimensions -- 2.4 Outflow acceleration and propulsion characteristics -- 2.5 Effects of wall temperature -- 2.6 Laminar-flame transition to detonation in long channels -- 2.7 Discussion -- References --
505	8		\|a 3. Flame instability in microscale combustion -- 3.1 Repetitive extinction and re-ignition instability -- 3.2 Spinning instability -- 3.3 Spiral flames and pattern formations -- References --
505	8		\|a 4. Microscale combustion modeling -- 4.1 Introduction -- 4.2 Microreactor thermal management -- 4.3 Heterogeneous and homogeneous chemistry modeling -- 4.4 Models used in microreactor research -- 4.5 Zero-dimensional models -- 4.6 One-dimensional channel-flow models -- 4.7 Multidimensional microreactor models -- 4.8 Applications of multidimensional models -- 4.9 Turbulent microreactor combustion -- 4.10 Non-continuum flows in microreactors -- 4.11 Conclusion and future work -- References --
505	8		\|a 5. Non-premixed micro combustion -- 5.1 Microjet diffusion flames -- 5.2 Basic microflame structure -- 5.3 Methodology -- 5.4 Characteristics of microjet methane diffusion flames -- 5.5 Flame structure and stabilization mechanism -- 5.6 Conclusion and future work -- References --
505	8		\|a 6. Diffusion flame instability and cell formation in meso- and microscale combustion -- 6.1 Cell flame formation in a microscale diffusion flame reactor -- 6.2 Flame streets and unsteady flame propagation in mesoscale diffusion flames -- 6.3 Conclusion and future work -- References --
505	8		\|a 7. Micro-combustion in non-catalytic narrow ducts -- 7.1 Overview of the state of the art -- 7.2 Structure of the tubular micro-reactive flow -- 7.3 Thermoacoustics -- 7.4 Outer wall temperature -- 7.5 Conclusion and future work -- References --
505	8		\|a 8. Fundamentals of microscale catalytic combustion -- 8.1 Introduction -- 8.2 Methodology -- 8.3 Characteristics of microscale catalytic combustion -- 8.4 Enhancement of microscale combustion by catalyst segmentation -- 8.5 Conclusion and future work -- References --
505	8		\|a 9. Miniature liquid fuel combustion -- 9.1 Overview -- 9.2 Brief review of mesoscale liquid fuel combustors -- 9.3 Liquid film combustor fundamentals -- 9.4 Combustor design evaluation -- 9.5 Liquid film combustion-driven TPV power system -- 9.6 Conclusion and future work -- References --
505	8		\|a 10. Heat-recirculating combustors -- 10.1 Introduction -- 10.2 Simplified analysis -- 10.3 Scaling -- 10.4 Practical perspectives -- 10.5 Conclusion and future work -- References --
505	8		\|a 11. Catalytic reactors: power generation and fuel processing -- 11.1 Introduction to catalytic combustion -- 11.2 Catalytic microreactors -- 11.3 Basic theory of catalytic combustion -- 11.4 Operation of microreactors for power generation -- References --
505	8		\|a 12. Microreactor with a temperature gradient -- 12.1 Weak flame in a temperature gradient -- 12.2 Multistage oxidation study using weak flame in a temperature gradient -- References --
505	8		\|a 13. Chemical micropropulsion -- 13.1 Micropropulsion and scaling -- 13.2 Materials, fabrication, and system integration -- 13.3 Solid propellant thrusters -- 13.4 Liquid propellant thrusters -- 13.5 Gaseous propellant thrusters -- 13.6 Conclusion and future work -- References --
505	8		\|a 14. Micro-rotary engine power system -- 14.1 Introduction -- 14.2 Meso-scale "mini-rotary" engine -- 14.3 MEMS-scale "micro-rotary" engine -- 14.4 Conclusion and future work -- References --
505	8		\|a 15. Small-scale reciprocating engines -- 15.1 Survey of miniature research engines -- 15.2 Miniature commercial engines -- 15.3 Quantifying engine performance -- 15.4 Performance measurements -- 15.5 Fuels -- 15.6 Sample performance data from three miniature engines -- 15.7 Scaling of engine performance -- 15.8 Small two-stroke piston engine combustion -- 15.9 Conclusion and future work -- References --
505	8		\|a 16. Combustors for microgas turbine engines -- 16.1 Introduction -- 16.2 Microgas turbine engines -- 16.3 Basic combustion concepts -- 16.4 Challenges of microgas turbine combustors -- 16.5 Homogeneous gas-phase microcombustors -- 16.6 Heterogeneous (catalytic) microcombustors -- 16.7 Conclusion and future work -- References -- Index.
520	3		\|a Recent advances in microfabrication technologies have enabled the development of entirely new classes of small-scale devices with applications in fields ranging from biomedicine (portable defibrillators, drug delivery systems, etc.), to wireless communication and computing (cell phones, laptop computers, etc.), to reconnaissance (unmanned air vehicles, microsatellites etc.), and to augmentation of human function (exoskeletons etc.). In many cases, however, what these devices can actually accomplish is limited by the low energy density of their energy storage and conversion systems. This breakthrough book brings together in one place the information necessary to develop the high energy density combustion-based power sources that will enable many of these devices to realize their full potentials.
650		0	\|a Internal combustion engines \|x Combustion. \|0 http://id.loc.gov/authorities/subjects/sh85067316
650		0	\|a Combustion \|x Industrial applications.
650		0	\|a Microfabrication. \|0 http://id.loc.gov/authorities/subjects/sh96011316
650		4	\|a Combustion \|x Industrial applications.
650		4	\|a Internal combustion engines \|x Combustion.
650		4	\|a Microfabrication.
650		6	\|a Moteurs à combustion interne \|x Combustion.
650		6	\|a Combustion \|x Applications industrielles.
650		6	\|a Microfabrication.
650		7	\|a TECHNOLOGY & ENGINEERING / Mechanical \|2 bisacsh
650		7	\|a Internal combustion engines \|x Combustion \|2 fast
650		7	\|a Microfabrication \|2 fast
653			\|a microscale combustion
653			\|a flameless combustion
653			\|a combustion limits
653			\|a combustion instability
653			\|a excess enthalpy combustion
653			\|a small-scale liquid film combustors
653			\|a micro-tubes and porous combustors
653			\|a Swiss-roll combustors
653			\|a catalytic reactors
653			\|a micro-heat engines
653			\|a micro-reactors
653			\|a micro-power generators
653			\|a micro-thrusters
653			\|a model aircraft engines
653			\|a 2-stroke engines
653			\|a piston engines
653			\|a heterogeneous combustion
653			\|a catalytic combustion
653			\|a conjugate heat transfer
653			\|a scale-effects on combustion
653			\|a thermoelectric power generation
653			\|a micro gas turbine engine
653			\|a micro-rotary engine
653			\|a micro-rockets
653			\|a microfabrication
653			\|a MEMS
700	1		\|a Cadou, Christopher P., \|d 1965- \|e author. \|1 https://id.oclc.org/worldcat/entity/E39PCjMhtjghchd464DkhkWr4m \|0 http://id.loc.gov/authorities/names/no97020989
700	1		\|a Maruta, Kaoru., \|e author.
776	0	8	\|i Print version: \|z 9781606503065
830		0	\|a Engineering collection.
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Datensatz im Suchindex

DE-BY-FWS_katkey	ZDB-4-EBA-ocn903905189
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author	Ju, Yiguang Cadou, Christopher P., 1965- Maruta, Kaoru
author_GND	http://id.loc.gov/authorities/names/no97020989
author_facet	Ju, Yiguang Cadou, Christopher P., 1965- Maruta, Kaoru
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callnumber-sort	TJ 3759 J85 42015
callnumber-subject	TJ - Mechanical Engineering and Machinery
collection	ZDB-4-EBA
contents	1. Meso- and microscale combustion and flammability limits -- 1.1 Premixed flames in meso- and microscale combustion -- 1.2 Flammability limit and quenching diameter -- 1.3 Heat recirculation -- 1.4 Flame and wall structure coupling in microscale combustion -- 1.5 Weak flame regimes with temperature gradients -- 1.6 Coupling of thermal and kinetic quenching in microscale combustion -- 1.7 Non-equilibrium combustion -- References -- 2. Boundary-accelerated flames in microchannels -- 2.1 Physical and numerical models -- 2.2 The boundary-layer accelerated flame -- 2.3 Effects of varying channel dimensions -- 2.4 Outflow acceleration and propulsion characteristics -- 2.5 Effects of wall temperature -- 2.6 Laminar-flame transition to detonation in long channels -- 2.7 Discussion -- References -- 3. Flame instability in microscale combustion -- 3.1 Repetitive extinction and re-ignition instability -- 3.2 Spinning instability -- 3.3 Spiral flames and pattern formations -- References -- 4. Microscale combustion modeling -- 4.1 Introduction -- 4.2 Microreactor thermal management -- 4.3 Heterogeneous and homogeneous chemistry modeling -- 4.4 Models used in microreactor research -- 4.5 Zero-dimensional models -- 4.6 One-dimensional channel-flow models -- 4.7 Multidimensional microreactor models -- 4.8 Applications of multidimensional models -- 4.9 Turbulent microreactor combustion -- 4.10 Non-continuum flows in microreactors -- 4.11 Conclusion and future work -- References -- 5. Non-premixed micro combustion -- 5.1 Microjet diffusion flames -- 5.2 Basic microflame structure -- 5.3 Methodology -- 5.4 Characteristics of microjet methane diffusion flames -- 5.5 Flame structure and stabilization mechanism -- 5.6 Conclusion and future work -- References -- 6. Diffusion flame instability and cell formation in meso- and microscale combustion -- 6.1 Cell flame formation in a microscale diffusion flame reactor -- 6.2 Flame streets and unsteady flame propagation in mesoscale diffusion flames -- 6.3 Conclusion and future work -- References -- 7. Micro-combustion in non-catalytic narrow ducts -- 7.1 Overview of the state of the art -- 7.2 Structure of the tubular micro-reactive flow -- 7.3 Thermoacoustics -- 7.4 Outer wall temperature -- 7.5 Conclusion and future work -- References -- 8. Fundamentals of microscale catalytic combustion -- 8.1 Introduction -- 8.2 Methodology -- 8.3 Characteristics of microscale catalytic combustion -- 8.4 Enhancement of microscale combustion by catalyst segmentation -- 8.5 Conclusion and future work -- References -- 9. Miniature liquid fuel combustion -- 9.1 Overview -- 9.2 Brief review of mesoscale liquid fuel combustors -- 9.3 Liquid film combustor fundamentals -- 9.4 Combustor design evaluation -- 9.5 Liquid film combustion-driven TPV power system -- 9.6 Conclusion and future work -- References -- 10. Heat-recirculating combustors -- 10.1 Introduction -- 10.2 Simplified analysis -- 10.3 Scaling -- 10.4 Practical perspectives -- 10.5 Conclusion and future work -- References -- 11. Catalytic reactors: power generation and fuel processing -- 11.1 Introduction to catalytic combustion -- 11.2 Catalytic microreactors -- 11.3 Basic theory of catalytic combustion -- 11.4 Operation of microreactors for power generation -- References -- 12. Microreactor with a temperature gradient -- 12.1 Weak flame in a temperature gradient -- 12.2 Multistage oxidation study using weak flame in a temperature gradient -- References -- 13. Chemical micropropulsion -- 13.1 Micropropulsion and scaling -- 13.2 Materials, fabrication, and system integration -- 13.3 Solid propellant thrusters -- 13.4 Liquid propellant thrusters -- 13.5 Gaseous propellant thrusters -- 13.6 Conclusion and future work -- References -- 14. Micro-rotary engine power system -- 14.1 Introduction -- 14.2 Meso-scale "mini-rotary" engine -- 14.3 MEMS-scale "micro-rotary" engine -- 14.4 Conclusion and future work -- References -- 15. Small-scale reciprocating engines -- 15.1 Survey of miniature research engines -- 15.2 Miniature commercial engines -- 15.3 Quantifying engine performance -- 15.4 Performance measurements -- 15.5 Fuels -- 15.6 Sample performance data from three miniature engines -- 15.7 Scaling of engine performance -- 15.8 Small two-stroke piston engine combustion -- 15.9 Conclusion and future work -- References -- 16. Combustors for microgas turbine engines -- 16.1 Introduction -- 16.2 Microgas turbine engines -- 16.3 Basic combustion concepts -- 16.4 Challenges of microgas turbine combustors -- 16.5 Homogeneous gas-phase microcombustors -- 16.6 Heterogeneous (catalytic) microcombustors -- 16.7 Conclusion and future work -- References -- Index.
ctrlnum	(OCoLC)903905189
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dewey-ones	621 - Applied physics
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id	ZDB-4-EBA-ocn903905189
illustrated	Illustrated
indexdate	2024-11-27T13:26:29Z
institution	BVB
isbn	9781606503089 1606503081 1606503065 9781606503065
language	English
oclc_num	903905189
open_access_boolean
owner	MAIN DE-863 DE-BY-FWS
owner_facet	MAIN DE-863 DE-BY-FWS
physical	1 online resource (1 PDF (xlvii, 512 pages) :) illustrations.
psigel	ZDB-4-EBA
publishDate	2015
publishDateSearch	2015
publishDateSort	2015
publisher	Momentum Press,
record_format	marc
series	Engineering collection.
series2	Engineering collection
spelling	Ju, Yiguang., author. Microscale combustion and power generation / Yiguang Ju, Christopher Cadou and Kaoru Maruta. New York, [New York] (222 East 46th Street, New York, NY 10017) : Momentum Press, 2015. 1 online resource (1 PDF (xlvii, 512 pages) :) illustrations. text rdacontent computer rdamedia online resource rdacarrier Engineering collection Title from PDF title page (viewed on February 21, 2015). Includes bibliographical references and index. 1. Meso- and microscale combustion and flammability limits -- 1.1 Premixed flames in meso- and microscale combustion -- 1.2 Flammability limit and quenching diameter -- 1.3 Heat recirculation -- 1.4 Flame and wall structure coupling in microscale combustion -- 1.5 Weak flame regimes with temperature gradients -- 1.6 Coupling of thermal and kinetic quenching in microscale combustion -- 1.7 Non-equilibrium combustion -- References -- 2. Boundary-accelerated flames in microchannels -- 2.1 Physical and numerical models -- 2.2 The boundary-layer accelerated flame -- 2.3 Effects of varying channel dimensions -- 2.4 Outflow acceleration and propulsion characteristics -- 2.5 Effects of wall temperature -- 2.6 Laminar-flame transition to detonation in long channels -- 2.7 Discussion -- References -- 3. Flame instability in microscale combustion -- 3.1 Repetitive extinction and re-ignition instability -- 3.2 Spinning instability -- 3.3 Spiral flames and pattern formations -- References -- 4. Microscale combustion modeling -- 4.1 Introduction -- 4.2 Microreactor thermal management -- 4.3 Heterogeneous and homogeneous chemistry modeling -- 4.4 Models used in microreactor research -- 4.5 Zero-dimensional models -- 4.6 One-dimensional channel-flow models -- 4.7 Multidimensional microreactor models -- 4.8 Applications of multidimensional models -- 4.9 Turbulent microreactor combustion -- 4.10 Non-continuum flows in microreactors -- 4.11 Conclusion and future work -- References -- 5. Non-premixed micro combustion -- 5.1 Microjet diffusion flames -- 5.2 Basic microflame structure -- 5.3 Methodology -- 5.4 Characteristics of microjet methane diffusion flames -- 5.5 Flame structure and stabilization mechanism -- 5.6 Conclusion and future work -- References -- 6. Diffusion flame instability and cell formation in meso- and microscale combustion -- 6.1 Cell flame formation in a microscale diffusion flame reactor -- 6.2 Flame streets and unsteady flame propagation in mesoscale diffusion flames -- 6.3 Conclusion and future work -- References -- 7. Micro-combustion in non-catalytic narrow ducts -- 7.1 Overview of the state of the art -- 7.2 Structure of the tubular micro-reactive flow -- 7.3 Thermoacoustics -- 7.4 Outer wall temperature -- 7.5 Conclusion and future work -- References -- 8. Fundamentals of microscale catalytic combustion -- 8.1 Introduction -- 8.2 Methodology -- 8.3 Characteristics of microscale catalytic combustion -- 8.4 Enhancement of microscale combustion by catalyst segmentation -- 8.5 Conclusion and future work -- References -- 9. Miniature liquid fuel combustion -- 9.1 Overview -- 9.2 Brief review of mesoscale liquid fuel combustors -- 9.3 Liquid film combustor fundamentals -- 9.4 Combustor design evaluation -- 9.5 Liquid film combustion-driven TPV power system -- 9.6 Conclusion and future work -- References -- 10. Heat-recirculating combustors -- 10.1 Introduction -- 10.2 Simplified analysis -- 10.3 Scaling -- 10.4 Practical perspectives -- 10.5 Conclusion and future work -- References -- 11. Catalytic reactors: power generation and fuel processing -- 11.1 Introduction to catalytic combustion -- 11.2 Catalytic microreactors -- 11.3 Basic theory of catalytic combustion -- 11.4 Operation of microreactors for power generation -- References -- 12. Microreactor with a temperature gradient -- 12.1 Weak flame in a temperature gradient -- 12.2 Multistage oxidation study using weak flame in a temperature gradient -- References -- 13. Chemical micropropulsion -- 13.1 Micropropulsion and scaling -- 13.2 Materials, fabrication, and system integration -- 13.3 Solid propellant thrusters -- 13.4 Liquid propellant thrusters -- 13.5 Gaseous propellant thrusters -- 13.6 Conclusion and future work -- References -- 14. Micro-rotary engine power system -- 14.1 Introduction -- 14.2 Meso-scale "mini-rotary" engine -- 14.3 MEMS-scale "micro-rotary" engine -- 14.4 Conclusion and future work -- References -- 15. Small-scale reciprocating engines -- 15.1 Survey of miniature research engines -- 15.2 Miniature commercial engines -- 15.3 Quantifying engine performance -- 15.4 Performance measurements -- 15.5 Fuels -- 15.6 Sample performance data from three miniature engines -- 15.7 Scaling of engine performance -- 15.8 Small two-stroke piston engine combustion -- 15.9 Conclusion and future work -- References -- 16. Combustors for microgas turbine engines -- 16.1 Introduction -- 16.2 Microgas turbine engines -- 16.3 Basic combustion concepts -- 16.4 Challenges of microgas turbine combustors -- 16.5 Homogeneous gas-phase microcombustors -- 16.6 Heterogeneous (catalytic) microcombustors -- 16.7 Conclusion and future work -- References -- Index. Recent advances in microfabrication technologies have enabled the development of entirely new classes of small-scale devices with applications in fields ranging from biomedicine (portable defibrillators, drug delivery systems, etc.), to wireless communication and computing (cell phones, laptop computers, etc.), to reconnaissance (unmanned air vehicles, microsatellites etc.), and to augmentation of human function (exoskeletons etc.). In many cases, however, what these devices can actually accomplish is limited by the low energy density of their energy storage and conversion systems. This breakthrough book brings together in one place the information necessary to develop the high energy density combustion-based power sources that will enable many of these devices to realize their full potentials. Internal combustion engines Combustion. http://id.loc.gov/authorities/subjects/sh85067316 Combustion Industrial applications. Microfabrication. http://id.loc.gov/authorities/subjects/sh96011316 Internal combustion engines Combustion. Microfabrication. Moteurs à combustion interne Combustion. Combustion Applications industrielles. TECHNOLOGY & ENGINEERING / Mechanical bisacsh Internal combustion engines Combustion fast Microfabrication fast microscale combustion flameless combustion combustion limits combustion instability excess enthalpy combustion small-scale liquid film combustors micro-tubes and porous combustors Swiss-roll combustors catalytic reactors micro-heat engines micro-reactors micro-power generators micro-thrusters model aircraft engines 2-stroke engines piston engines heterogeneous combustion catalytic combustion conjugate heat transfer scale-effects on combustion thermoelectric power generation micro gas turbine engine micro-rotary engine micro-rockets microfabrication MEMS Cadou, Christopher P., 1965- author. https://id.oclc.org/worldcat/entity/E39PCjMhtjghchd464DkhkWr4m http://id.loc.gov/authorities/names/no97020989 Maruta, Kaoru., author. Print version: 9781606503065 Engineering collection. FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=947933 Volltext
spellingShingle	Ju, Yiguang Cadou, Christopher P., 1965- Maruta, Kaoru Microscale combustion and power generation / Engineering collection. 1. Meso- and microscale combustion and flammability limits -- 1.1 Premixed flames in meso- and microscale combustion -- 1.2 Flammability limit and quenching diameter -- 1.3 Heat recirculation -- 1.4 Flame and wall structure coupling in microscale combustion -- 1.5 Weak flame regimes with temperature gradients -- 1.6 Coupling of thermal and kinetic quenching in microscale combustion -- 1.7 Non-equilibrium combustion -- References -- 2. Boundary-accelerated flames in microchannels -- 2.1 Physical and numerical models -- 2.2 The boundary-layer accelerated flame -- 2.3 Effects of varying channel dimensions -- 2.4 Outflow acceleration and propulsion characteristics -- 2.5 Effects of wall temperature -- 2.6 Laminar-flame transition to detonation in long channels -- 2.7 Discussion -- References -- 3. Flame instability in microscale combustion -- 3.1 Repetitive extinction and re-ignition instability -- 3.2 Spinning instability -- 3.3 Spiral flames and pattern formations -- References -- 4. Microscale combustion modeling -- 4.1 Introduction -- 4.2 Microreactor thermal management -- 4.3 Heterogeneous and homogeneous chemistry modeling -- 4.4 Models used in microreactor research -- 4.5 Zero-dimensional models -- 4.6 One-dimensional channel-flow models -- 4.7 Multidimensional microreactor models -- 4.8 Applications of multidimensional models -- 4.9 Turbulent microreactor combustion -- 4.10 Non-continuum flows in microreactors -- 4.11 Conclusion and future work -- References -- 5. Non-premixed micro combustion -- 5.1 Microjet diffusion flames -- 5.2 Basic microflame structure -- 5.3 Methodology -- 5.4 Characteristics of microjet methane diffusion flames -- 5.5 Flame structure and stabilization mechanism -- 5.6 Conclusion and future work -- References -- 6. Diffusion flame instability and cell formation in meso- and microscale combustion -- 6.1 Cell flame formation in a microscale diffusion flame reactor -- 6.2 Flame streets and unsteady flame propagation in mesoscale diffusion flames -- 6.3 Conclusion and future work -- References -- 7. Micro-combustion in non-catalytic narrow ducts -- 7.1 Overview of the state of the art -- 7.2 Structure of the tubular micro-reactive flow -- 7.3 Thermoacoustics -- 7.4 Outer wall temperature -- 7.5 Conclusion and future work -- References -- 8. Fundamentals of microscale catalytic combustion -- 8.1 Introduction -- 8.2 Methodology -- 8.3 Characteristics of microscale catalytic combustion -- 8.4 Enhancement of microscale combustion by catalyst segmentation -- 8.5 Conclusion and future work -- References -- 9. Miniature liquid fuel combustion -- 9.1 Overview -- 9.2 Brief review of mesoscale liquid fuel combustors -- 9.3 Liquid film combustor fundamentals -- 9.4 Combustor design evaluation -- 9.5 Liquid film combustion-driven TPV power system -- 9.6 Conclusion and future work -- References -- 10. Heat-recirculating combustors -- 10.1 Introduction -- 10.2 Simplified analysis -- 10.3 Scaling -- 10.4 Practical perspectives -- 10.5 Conclusion and future work -- References -- 11. Catalytic reactors: power generation and fuel processing -- 11.1 Introduction to catalytic combustion -- 11.2 Catalytic microreactors -- 11.3 Basic theory of catalytic combustion -- 11.4 Operation of microreactors for power generation -- References -- 12. Microreactor with a temperature gradient -- 12.1 Weak flame in a temperature gradient -- 12.2 Multistage oxidation study using weak flame in a temperature gradient -- References -- 13. Chemical micropropulsion -- 13.1 Micropropulsion and scaling -- 13.2 Materials, fabrication, and system integration -- 13.3 Solid propellant thrusters -- 13.4 Liquid propellant thrusters -- 13.5 Gaseous propellant thrusters -- 13.6 Conclusion and future work -- References -- 14. Micro-rotary engine power system -- 14.1 Introduction -- 14.2 Meso-scale "mini-rotary" engine -- 14.3 MEMS-scale "micro-rotary" engine -- 14.4 Conclusion and future work -- References -- 15. Small-scale reciprocating engines -- 15.1 Survey of miniature research engines -- 15.2 Miniature commercial engines -- 15.3 Quantifying engine performance -- 15.4 Performance measurements -- 15.5 Fuels -- 15.6 Sample performance data from three miniature engines -- 15.7 Scaling of engine performance -- 15.8 Small two-stroke piston engine combustion -- 15.9 Conclusion and future work -- References -- 16. Combustors for microgas turbine engines -- 16.1 Introduction -- 16.2 Microgas turbine engines -- 16.3 Basic combustion concepts -- 16.4 Challenges of microgas turbine combustors -- 16.5 Homogeneous gas-phase microcombustors -- 16.6 Heterogeneous (catalytic) microcombustors -- 16.7 Conclusion and future work -- References -- Index. Internal combustion engines Combustion. http://id.loc.gov/authorities/subjects/sh85067316 Combustion Industrial applications. Microfabrication. http://id.loc.gov/authorities/subjects/sh96011316 Internal combustion engines Combustion. Microfabrication. Moteurs à combustion interne Combustion. Combustion Applications industrielles. TECHNOLOGY & ENGINEERING / Mechanical bisacsh Internal combustion engines Combustion fast Microfabrication fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85067316 http://id.loc.gov/authorities/subjects/sh96011316
title	Microscale combustion and power generation /
title_auth	Microscale combustion and power generation /
title_exact_search	Microscale combustion and power generation /
title_full	Microscale combustion and power generation / Yiguang Ju, Christopher Cadou and Kaoru Maruta.
title_fullStr	Microscale combustion and power generation / Yiguang Ju, Christopher Cadou and Kaoru Maruta.
title_full_unstemmed	Microscale combustion and power generation / Yiguang Ju, Christopher Cadou and Kaoru Maruta.
title_short	Microscale combustion and power generation /
title_sort	microscale combustion and power generation
topic	Internal combustion engines Combustion. http://id.loc.gov/authorities/subjects/sh85067316 Combustion Industrial applications. Microfabrication. http://id.loc.gov/authorities/subjects/sh96011316 Internal combustion engines Combustion. Microfabrication. Moteurs à combustion interne Combustion. Combustion Applications industrielles. TECHNOLOGY & ENGINEERING / Mechanical bisacsh Internal combustion engines Combustion fast Microfabrication fast
topic_facet	Internal combustion engines Combustion. Combustion Industrial applications. Microfabrication. Moteurs à combustion interne Combustion. Combustion Applications industrielles. TECHNOLOGY & ENGINEERING / Mechanical Internal combustion engines Combustion Microfabrication
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=947933
work_keys_str_mv	AT juyiguang microscalecombustionandpowergeneration AT cadouchristopherp microscalecombustionandpowergeneration AT marutakaoru microscalecombustionandpowergeneration

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