Tubular Combustion:
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Momentum Press
2013
|
| Schlagworte: | |
| Online-Zugang: | FAW01 FAW02 |
| Beschreibung: | Tubular combustors are cylindrical tubes where flame ignition and propagation occur in a spatially confined, highly controlled environment, in a nearly flat, elongated geometry. This allows for some unique advantages where extremely even heat dispersion is required over a large surface while still maintaining fuel efficiency. Tubular combustors also allow for easy flexibility in type of fuel source, allowing for quick changeover to meet various needs and changing fuel pricing. This new addition to the MP sustainable energy series will provide the most up-to-date research on tubular combustion- 1. Introduction / Satoru Ishizuka -- 1.1 Background of tubular flame studies -- 1.1.1 Aerodynamic straining -- 1.1.2 Flame curvature -- 1.1.3 Rotation -- 1.1.4 Tubular flames -- 1.2 Notable tubular flame characteristics -- 1.2.1 Thermal advantage -- 1.2.2 Aerodynamic advantage -- 1.2.3 Lewis number effects -- 1.3 Tubular flame studies -- 1.3.1 Theoretical studies -- 1.3.2 Computational simulations -- 1.3.3 Experimental studies -- 1.4 Relevant studies -- 1.4.1 Tubular non-premixed, diffusion flame studies -- 1.4.2 Miniature liquid-film combustors -- 1.5 Practical application -- 1.5.1 Prototype tubular flame burners -- 1.5.2 Rapidly mixed tubular flame combustion -- References 2. Theory of tubular flames / Tadao Takeno and Makihito Nishioka -- 2.1 Introduction -- 2.2 Theoretical formulation -- 2.2.1 Model and assumptions -- 2.2.2 Fundamental equations -- 2.3 Similarity solution -- 2.3.1 Introduction -- 2.3.2 Equations to be solved -- 2.4 Simplified model with one-step kinetics and simple transport properties -- 2.4.1 Formulation -- 2.4.2 Nondimensional system -- 2.4.3 Incompressible flow system -- 2.4.4 Flow field -- 2.4.5 Concentration and temperature field -- 2.4.6 Simplification for Le = 1 -- 2.4.7 Results for simplified model -- 2.4.8 Discussions on results for simplified model -- 2.5 Effects of variable density -- 2.5.1 Model and assumptions -- 2.5.2 Comparison with incompressible solutions -- 2.5.3 Effects of injection velocity -- 2.5.4 Effects of lewis number -- 2.5.5 Discussions on the effects of variable density -- 2.6 Asymptotic analysis -- 2.6.1 Model and assumptions -- 2.6.2 Nondimensional system -- 2.6.3 Asymptotic analysis -- 2.6.4 Approximate solutions -- 2.6.5 Response curves -- 2.6.6 Extinction conditions -- 2.6.7 Numerical example -- 2.6.8 Discussions -- 2.6.9 Some concluding remarks -- 2.7 Numerical study with full kinetics and exact transport properties -- 2.7.1 Introduction -- 2.7.2 Model and equations -- 2.7.3 Reaction mechanism and transport properties -- 2.7.4 Results and discussions -- 2.7.5 Concluding remarks -- 2.8 Final conclusions -- References 3. Mathematical formulation and computational simulation of tubular flames / Yuyin Zhang, Huayang Zhu, Robert J. Kee -- 3.1 Introduction -- 3.2 Literature overview -- 3.3 Mathematical formulation -- 3.3.1 Similarity form -- 3.3.2 Radial injection -- 3.3.3 Tangential injection -- 3.3.4 Practical considerations -- 3.3.5 Computational procedure -- 3.4 Model validation -- 3.4.1 Tubular flame with a radial inlet flow -- 3.4.2 Swirling tubular flame with a single inlet slot -- 3.5 Flame structure and pressure diffusion -- 3.5.1 Premixed propane-air flames -- 3.5.2 Premixed methane-air flames -- 3.5.3 Summary of pressure diffusion -- 3.6 Potential technology applications -- 3.7 Summary and conclusions -- References 4. Raman spectroscopic measurements of tubular flames / Robert W. Pitz -- 4.1 Introduction -- 4.2 Raman scattering technique -- 4.3 Tubular flame burner -- 4.4 Raman scattering measurements in tubular flames -- 4.4.1 Hydrogen-air tubular flames -- 4.4.2 Methane-air tubular flames -- 4.4.3 Propane-air tubular flames -- 4.5 Cellular tubular flames -- 4.5.1 Instabilities in tubular flames -- 4.5.2 Raman scattering measurements in cellular tubular flames -- References 5. Non-premixed tubular flames / Robert W. Pitz -- 5.1 Introduction -- 5.2 Numerical study of the non-premixed tubular flames -- 5.3 Non-premixed opposed-flow tubular burner -- 5.4 Raman scattering measurements in non-premixed tubular flames -- 5.4.1 Hydrogen/air non-premixed tubular flames -- 5.4.2 Hydrocarbon-air non-premixed tubular flames -- 5.5 Cellular instabilities in non-premixed tubular flames -- 5.5.1 Cellular instabilities in diffusion flames -- 5.5.2 Cellular formation and extinction in non-premixed tubular flames -- References 6. Tubular flame characteristics of miniature liquid film combustors / Derek Dunn-Rankin -- 6.1 Introduction -- 6.2 Brief review of some key features of a tubular flame -- 6.3 Review of the key features of a fuel film combustor flame -- 6.4 Examples of tubular flame behaviors in a fuel film combustor -- 6.4.1 Original design -- 6.4.2 Secondary air injection -- 6.4.3 Swirler design and tubular flame -- 6.5 Concluding remarks -- References 7. Small-scale applications / Daisuke Shimokuri -- 7.1. Introduction -- 7.2. Flame quenching in a narrow channel -- 7.2.1 Flame quenching in a nonrotating flow field -- 7.2.2 Advantages using small-scale tubular flame burners -- 7.2.3 Tubular flame in a small-diameter tube -- 7.2.4 Effects of tube size on the tubular flame -- 7.2.5 Critical tube diameter for a rotating flow field -- 7.3 Development of small power sources using a tubular flame -- References 8. Large-scale applications / Satoru Ishizuka -- 8.1 Introduction -- 8.1.1 Classification -- 8.1.2 Flame diameter and length -- 8.1.3 Rapidly mixed tubular flame combustion -- 8.2 Wide flammable range -- 8.2.1 BFG burners -- 8.3 Fuel diversity -- 8.3.1 Gaseous fuels -- 8.3.2 Liquid fuels -- 8.3.3 Solid fuels -- 8.4 Compactness -- 8.4.1 Fuel-processing system for polymer electrolyte fuel cell -- 8.4.2 Hollow fastening bolt -- 8.4.3 Superheated steam generator -- 8.5 Geometry -- 8.5.1 Flame stabilization -- 8.5.2 Heating process -- 8.5.3 Stirling engine -- References -- Index Includes bibliographical references and index |
| ISBN: | 1306124549 9781306124546 9781606503058 1606503057 1606503030 9781606503034 |
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| 500 | |a Tubular combustors are cylindrical tubes where flame ignition and propagation occur in a spatially confined, highly controlled environment, in a nearly flat, elongated geometry. This allows for some unique advantages where extremely even heat dispersion is required over a large surface while still maintaining fuel efficiency. Tubular combustors also allow for easy flexibility in type of fuel source, allowing for quick changeover to meet various needs and changing fuel pricing. This new addition to the MP sustainable energy series will provide the most up-to-date research on tubular combustion- | ||
| 500 | |a 1. Introduction / Satoru Ishizuka -- 1.1 Background of tubular flame studies -- 1.1.1 Aerodynamic straining -- 1.1.2 Flame curvature -- 1.1.3 Rotation -- 1.1.4 Tubular flames -- 1.2 Notable tubular flame characteristics -- 1.2.1 Thermal advantage -- 1.2.2 Aerodynamic advantage -- 1.2.3 Lewis number effects -- 1.3 Tubular flame studies -- 1.3.1 Theoretical studies -- 1.3.2 Computational simulations -- 1.3.3 Experimental studies -- 1.4 Relevant studies -- 1.4.1 Tubular non-premixed, diffusion flame studies -- 1.4.2 Miniature liquid-film combustors -- 1.5 Practical application -- 1.5.1 Prototype tubular flame burners -- 1.5.2 Rapidly mixed tubular flame combustion -- References | ||
| 500 | |a 2. Theory of tubular flames / Tadao Takeno and Makihito Nishioka -- 2.1 Introduction -- 2.2 Theoretical formulation -- 2.2.1 Model and assumptions -- 2.2.2 Fundamental equations -- 2.3 Similarity solution -- 2.3.1 Introduction -- 2.3.2 Equations to be solved -- 2.4 Simplified model with one-step kinetics and simple transport properties -- 2.4.1 Formulation -- 2.4.2 Nondimensional system -- 2.4.3 Incompressible flow system -- 2.4.4 Flow field -- 2.4.5 Concentration and temperature field -- 2.4.6 Simplification for Le = 1 -- 2.4.7 Results for simplified model -- 2.4.8 Discussions on results for simplified model -- 2.5 Effects of variable density -- 2.5.1 Model and assumptions -- 2.5.2 Comparison with incompressible solutions -- 2.5.3 Effects of injection velocity -- 2.5.4 Effects of lewis number -- 2.5.5 Discussions on the effects of variable density -- 2.6 Asymptotic analysis -- 2.6.1 Model and assumptions -- 2.6.2 Nondimensional system -- 2.6.3 Asymptotic analysis -- 2.6.4 Approximate solutions -- 2.6.5 Response curves -- 2.6.6 Extinction conditions -- 2.6.7 Numerical example -- 2.6.8 Discussions -- 2.6.9 Some concluding remarks -- 2.7 Numerical study with full kinetics and exact transport properties -- 2.7.1 Introduction -- 2.7.2 Model and equations -- 2.7.3 Reaction mechanism and transport properties -- 2.7.4 Results and discussions -- 2.7.5 Concluding remarks -- 2.8 Final conclusions -- References | ||
| 500 | |a 3. Mathematical formulation and computational simulation of tubular flames / Yuyin Zhang, Huayang Zhu, Robert J. Kee -- 3.1 Introduction -- 3.2 Literature overview -- 3.3 Mathematical formulation -- 3.3.1 Similarity form -- 3.3.2 Radial injection -- 3.3.3 Tangential injection -- 3.3.4 Practical considerations -- 3.3.5 Computational procedure -- 3.4 Model validation -- 3.4.1 Tubular flame with a radial inlet flow -- 3.4.2 Swirling tubular flame with a single inlet slot -- 3.5 Flame structure and pressure diffusion -- 3.5.1 Premixed propane-air flames -- 3.5.2 Premixed methane-air flames -- 3.5.3 Summary of pressure diffusion -- 3.6 Potential technology applications -- 3.7 Summary and conclusions -- References | ||
| 500 | |a 4. Raman spectroscopic measurements of tubular flames / Robert W. Pitz -- 4.1 Introduction -- 4.2 Raman scattering technique -- 4.3 Tubular flame burner -- 4.4 Raman scattering measurements in tubular flames -- 4.4.1 Hydrogen-air tubular flames -- 4.4.2 Methane-air tubular flames -- 4.4.3 Propane-air tubular flames -- 4.5 Cellular tubular flames -- 4.5.1 Instabilities in tubular flames -- 4.5.2 Raman scattering measurements in cellular tubular flames -- References | ||
| 500 | |a 5. Non-premixed tubular flames / Robert W. Pitz -- 5.1 Introduction -- 5.2 Numerical study of the non-premixed tubular flames -- 5.3 Non-premixed opposed-flow tubular burner -- 5.4 Raman scattering measurements in non-premixed tubular flames -- 5.4.1 Hydrogen/air non-premixed tubular flames -- 5.4.2 Hydrocarbon-air non-premixed tubular flames -- 5.5 Cellular instabilities in non-premixed tubular flames -- 5.5.1 Cellular instabilities in diffusion flames -- 5.5.2 Cellular formation and extinction in non-premixed tubular flames -- References | ||
| 500 | |a 6. Tubular flame characteristics of miniature liquid film combustors / Derek Dunn-Rankin -- 6.1 Introduction -- 6.2 Brief review of some key features of a tubular flame -- 6.3 Review of the key features of a fuel film combustor flame -- 6.4 Examples of tubular flame behaviors in a fuel film combustor -- 6.4.1 Original design -- 6.4.2 Secondary air injection -- 6.4.3 Swirler design and tubular flame -- 6.5 Concluding remarks -- References | ||
| 500 | |a 7. Small-scale applications / Daisuke Shimokuri -- 7.1. Introduction -- 7.2. Flame quenching in a narrow channel -- 7.2.1 Flame quenching in a nonrotating flow field -- 7.2.2 Advantages using small-scale tubular flame burners -- 7.2.3 Tubular flame in a small-diameter tube -- 7.2.4 Effects of tube size on the tubular flame -- 7.2.5 Critical tube diameter for a rotating flow field -- 7.3 Development of small power sources using a tubular flame -- References | ||
| 500 | |a 8. Large-scale applications / Satoru Ishizuka -- 8.1 Introduction -- 8.1.1 Classification -- 8.1.2 Flame diameter and length -- 8.1.3 Rapidly mixed tubular flame combustion -- 8.2 Wide flammable range -- 8.2.1 BFG burners -- 8.3 Fuel diversity -- 8.3.1 Gaseous fuels -- 8.3.2 Liquid fuels -- 8.3.3 Solid fuels -- 8.4 Compactness -- 8.4.1 Fuel-processing system for polymer electrolyte fuel cell -- 8.4.2 Hollow fastening bolt -- 8.4.3 Superheated steam generator -- 8.5 Geometry -- 8.5.1 Flame stabilization -- 8.5.2 Heating process -- 8.5.3 Stirling engine -- References -- Index | ||
| 500 | |a Includes bibliographical references and index | ||
| 650 | 4 | |a Combustion | |
| 650 | 4 | |a Tubes / Thermodynamics | |
| 650 | 7 | |a NATURE / Fossils |2 bisacsh | |
| 650 | 7 | |a Combustion |2 fast | |
| 650 | 7 | |a Tubes / Thermodynamics |2 fast | |
| 650 | 4 | |a Tubes |x Thermodynamics | |
| 650 | 4 | |a Combustion | |
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Datensatz im Suchindex
| _version_ | 1804176604996304896 |
|---|---|
| any_adam_object | |
| author | Ishizuka, Satoru |
| author_facet | Ishizuka, Satoru |
| author_role | aut |
| author_sort | Ishizuka, Satoru |
| author_variant | s i si |
| building | Verbundindex |
| bvnumber | BV043777416 |
| collection | ZDB-4-EBA |
| ctrlnum | (ZDB-4-EBA)ocn863034782 (OCoLC)863034782 (DE-599)BVBBV043777416 |
| dewey-full | 567 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 567 - Fossil cold-blooded vertebrates |
| dewey-raw | 567 |
| dewey-search | 567 |
| dewey-sort | 3567 |
| dewey-tens | 560 - Paleontology |
| discipline | Geologie / Paläontologie |
| format | Electronic eBook |
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Introduction / Satoru Ishizuka -- 1.1 Background of tubular flame studies -- 1.1.1 Aerodynamic straining -- 1.1.2 Flame curvature -- 1.1.3 Rotation -- 1.1.4 Tubular flames -- 1.2 Notable tubular flame characteristics -- 1.2.1 Thermal advantage -- 1.2.2 Aerodynamic advantage -- 1.2.3 Lewis number effects -- 1.3 Tubular flame studies -- 1.3.1 Theoretical studies -- 1.3.2 Computational simulations -- 1.3.3 Experimental studies -- 1.4 Relevant studies -- 1.4.1 Tubular non-premixed, diffusion flame studies -- 1.4.2 Miniature liquid-film combustors -- 1.5 Practical application -- 1.5.1 Prototype tubular flame burners -- 1.5.2 Rapidly mixed tubular flame combustion -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">2. Theory of tubular flames / Tadao Takeno and Makihito Nishioka -- 2.1 Introduction -- 2.2 Theoretical formulation -- 2.2.1 Model and assumptions -- 2.2.2 Fundamental equations -- 2.3 Similarity solution -- 2.3.1 Introduction -- 2.3.2 Equations to be solved -- 2.4 Simplified model with one-step kinetics and simple transport properties -- 2.4.1 Formulation -- 2.4.2 Nondimensional system -- 2.4.3 Incompressible flow system -- 2.4.4 Flow field -- 2.4.5 Concentration and temperature field -- 2.4.6 Simplification for Le = 1 -- 2.4.7 Results for simplified model -- 2.4.8 Discussions on results for simplified model -- 2.5 Effects of variable density -- 2.5.1 Model and assumptions -- 2.5.2 Comparison with incompressible solutions -- 2.5.3 Effects of injection velocity -- 2.5.4 Effects of lewis number -- 2.5.5 Discussions on the effects of variable density -- 2.6 Asymptotic analysis -- 2.6.1 Model and assumptions -- 2.6.2 Nondimensional system -- 2.6.3 Asymptotic analysis -- 2.6.4 Approximate solutions -- 2.6.5 Response curves -- 2.6.6 Extinction conditions -- 2.6.7 Numerical example -- 2.6.8 Discussions -- 2.6.9 Some concluding remarks -- 2.7 Numerical study with full kinetics and exact transport properties -- 2.7.1 Introduction -- 2.7.2 Model and equations -- 2.7.3 Reaction mechanism and transport properties -- 2.7.4 Results and discussions -- 2.7.5 Concluding remarks -- 2.8 Final conclusions -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">3. Mathematical formulation and computational simulation of tubular flames / Yuyin Zhang, Huayang Zhu, Robert J. Kee -- 3.1 Introduction -- 3.2 Literature overview -- 3.3 Mathematical formulation -- 3.3.1 Similarity form -- 3.3.2 Radial injection -- 3.3.3 Tangential injection -- 3.3.4 Practical considerations -- 3.3.5 Computational procedure -- 3.4 Model validation -- 3.4.1 Tubular flame with a radial inlet flow -- 3.4.2 Swirling tubular flame with a single inlet slot -- 3.5 Flame structure and pressure diffusion -- 3.5.1 Premixed propane-air flames -- 3.5.2 Premixed methane-air flames -- 3.5.3 Summary of pressure diffusion -- 3.6 Potential technology applications -- 3.7 Summary and conclusions -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">4. Raman spectroscopic measurements of tubular flames / Robert W. Pitz -- 4.1 Introduction -- 4.2 Raman scattering technique -- 4.3 Tubular flame burner -- 4.4 Raman scattering measurements in tubular flames -- 4.4.1 Hydrogen-air tubular flames -- 4.4.2 Methane-air tubular flames -- 4.4.3 Propane-air tubular flames -- 4.5 Cellular tubular flames -- 4.5.1 Instabilities in tubular flames -- 4.5.2 Raman scattering measurements in cellular tubular flames -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">5. Non-premixed tubular flames / Robert W. Pitz -- 5.1 Introduction -- 5.2 Numerical study of the non-premixed tubular flames -- 5.3 Non-premixed opposed-flow tubular burner -- 5.4 Raman scattering measurements in non-premixed tubular flames -- 5.4.1 Hydrogen/air non-premixed tubular flames -- 5.4.2 Hydrocarbon-air non-premixed tubular flames -- 5.5 Cellular instabilities in non-premixed tubular flames -- 5.5.1 Cellular instabilities in diffusion flames -- 5.5.2 Cellular formation and extinction in non-premixed tubular flames -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">6. Tubular flame characteristics of miniature liquid film combustors / Derek Dunn-Rankin -- 6.1 Introduction -- 6.2 Brief review of some key features of a tubular flame -- 6.3 Review of the key features of a fuel film combustor flame -- 6.4 Examples of tubular flame behaviors in a fuel film combustor -- 6.4.1 Original design -- 6.4.2 Secondary air injection -- 6.4.3 Swirler design and tubular flame -- 6.5 Concluding remarks -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">7. Small-scale applications / Daisuke Shimokuri -- 7.1. Introduction -- 7.2. Flame quenching in a narrow channel -- 7.2.1 Flame quenching in a nonrotating flow field -- 7.2.2 Advantages using small-scale tubular flame burners -- 7.2.3 Tubular flame in a small-diameter tube -- 7.2.4 Effects of tube size on the tubular flame -- 7.2.5 Critical tube diameter for a rotating flow field -- 7.3 Development of small power sources using a tubular flame -- References</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">8. Large-scale applications / Satoru Ishizuka -- 8.1 Introduction -- 8.1.1 Classification -- 8.1.2 Flame diameter and length -- 8.1.3 Rapidly mixed tubular flame combustion -- 8.2 Wide flammable range -- 8.2.1 BFG burners -- 8.3 Fuel diversity -- 8.3.1 Gaseous fuels -- 8.3.2 Liquid fuels -- 8.3.3 Solid fuels -- 8.4 Compactness -- 8.4.1 Fuel-processing system for polymer electrolyte fuel cell -- 8.4.2 Hollow fastening bolt -- 8.4.3 Superheated steam generator -- 8.5 Geometry -- 8.5.1 Flame stabilization -- 8.5.2 Heating process -- 8.5.3 Stirling engine -- References -- Index</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">Includes bibliographical references and index</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Combustion</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Tubes / Thermodynamics</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">NATURE / Fossils</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Combustion</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Tubes / Thermodynamics</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Tubes</subfield><subfield code="x">Thermodynamics</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Combustion</subfield></datafield><datafield tag="650" ind1="0" ind2="7"><subfield code="a">Verbrennung</subfield><subfield code="0">(DE-588)4062656-8</subfield><subfield code="2">gnd</subfield><subfield code="9">rswk-swf</subfield></datafield><datafield tag="689" ind1="0" ind2="0"><subfield code="a">Verbrennung</subfield><subfield code="0">(DE-588)4062656-8</subfield><subfield code="D">s</subfield></datafield><datafield tag="689" ind1="0" ind2=" "><subfield code="8">1\p</subfield><subfield code="5">DE-604</subfield></datafield><datafield tag="912" ind1=" " ind2=" "><subfield code="a">ZDB-4-EBA</subfield></datafield><datafield tag="999" ind1=" " ind2=" "><subfield code="a">oai:aleph.bib-bvb.de:BVB01-029188476</subfield></datafield><datafield tag="883" ind1="1" ind2=" "><subfield code="8">1\p</subfield><subfield code="a">cgwrk</subfield><subfield code="d">20201028</subfield><subfield code="q">DE-101</subfield><subfield code="u">https://d-nb.info/provenance/plan#cgwrk</subfield></datafield><datafield tag="966" ind1="e" ind2=" "><subfield code="u">http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=659687</subfield><subfield code="l">FAW01</subfield><subfield code="p">ZDB-4-EBA</subfield><subfield code="q">FAW_PDA_EBA</subfield><subfield code="x">Aggregator</subfield><subfield code="3">Volltext</subfield></datafield><datafield tag="966" ind1="e" ind2=" "><subfield code="u">http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=659687</subfield><subfield code="l">FAW02</subfield><subfield code="p">ZDB-4-EBA</subfield><subfield code="q">FAW_PDA_EBA</subfield><subfield code="x">Aggregator</subfield><subfield code="3">Volltext</subfield></datafield></record></collection> |
| id | DE-604.BV043777416 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:34:50Z |
| institution | BVB |
| isbn | 1306124549 9781306124546 9781606503058 1606503057 1606503030 9781606503034 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-029188476 |
| oclc_num | 863034782 |
| open_access_boolean | |
| owner | DE-1046 DE-1047 |
| owner_facet | DE-1046 DE-1047 |
| psigel | ZDB-4-EBA ZDB-4-EBA FAW_PDA_EBA |
| publishDate | 2013 |
| publishDateSearch | 2013 |
| publishDateSort | 2013 |
| publisher | Momentum Press |
| record_format | marc |
| spelling | Ishizuka, Satoru Verfasser aut Tubular Combustion Momentum Press 2013 txt rdacontent c rdamedia cr rdacarrier Tubular combustors are cylindrical tubes where flame ignition and propagation occur in a spatially confined, highly controlled environment, in a nearly flat, elongated geometry. This allows for some unique advantages where extremely even heat dispersion is required over a large surface while still maintaining fuel efficiency. Tubular combustors also allow for easy flexibility in type of fuel source, allowing for quick changeover to meet various needs and changing fuel pricing. This new addition to the MP sustainable energy series will provide the most up-to-date research on tubular combustion- 1. Introduction / Satoru Ishizuka -- 1.1 Background of tubular flame studies -- 1.1.1 Aerodynamic straining -- 1.1.2 Flame curvature -- 1.1.3 Rotation -- 1.1.4 Tubular flames -- 1.2 Notable tubular flame characteristics -- 1.2.1 Thermal advantage -- 1.2.2 Aerodynamic advantage -- 1.2.3 Lewis number effects -- 1.3 Tubular flame studies -- 1.3.1 Theoretical studies -- 1.3.2 Computational simulations -- 1.3.3 Experimental studies -- 1.4 Relevant studies -- 1.4.1 Tubular non-premixed, diffusion flame studies -- 1.4.2 Miniature liquid-film combustors -- 1.5 Practical application -- 1.5.1 Prototype tubular flame burners -- 1.5.2 Rapidly mixed tubular flame combustion -- References 2. Theory of tubular flames / Tadao Takeno and Makihito Nishioka -- 2.1 Introduction -- 2.2 Theoretical formulation -- 2.2.1 Model and assumptions -- 2.2.2 Fundamental equations -- 2.3 Similarity solution -- 2.3.1 Introduction -- 2.3.2 Equations to be solved -- 2.4 Simplified model with one-step kinetics and simple transport properties -- 2.4.1 Formulation -- 2.4.2 Nondimensional system -- 2.4.3 Incompressible flow system -- 2.4.4 Flow field -- 2.4.5 Concentration and temperature field -- 2.4.6 Simplification for Le = 1 -- 2.4.7 Results for simplified model -- 2.4.8 Discussions on results for simplified model -- 2.5 Effects of variable density -- 2.5.1 Model and assumptions -- 2.5.2 Comparison with incompressible solutions -- 2.5.3 Effects of injection velocity -- 2.5.4 Effects of lewis number -- 2.5.5 Discussions on the effects of variable density -- 2.6 Asymptotic analysis -- 2.6.1 Model and assumptions -- 2.6.2 Nondimensional system -- 2.6.3 Asymptotic analysis -- 2.6.4 Approximate solutions -- 2.6.5 Response curves -- 2.6.6 Extinction conditions -- 2.6.7 Numerical example -- 2.6.8 Discussions -- 2.6.9 Some concluding remarks -- 2.7 Numerical study with full kinetics and exact transport properties -- 2.7.1 Introduction -- 2.7.2 Model and equations -- 2.7.3 Reaction mechanism and transport properties -- 2.7.4 Results and discussions -- 2.7.5 Concluding remarks -- 2.8 Final conclusions -- References 3. Mathematical formulation and computational simulation of tubular flames / Yuyin Zhang, Huayang Zhu, Robert J. Kee -- 3.1 Introduction -- 3.2 Literature overview -- 3.3 Mathematical formulation -- 3.3.1 Similarity form -- 3.3.2 Radial injection -- 3.3.3 Tangential injection -- 3.3.4 Practical considerations -- 3.3.5 Computational procedure -- 3.4 Model validation -- 3.4.1 Tubular flame with a radial inlet flow -- 3.4.2 Swirling tubular flame with a single inlet slot -- 3.5 Flame structure and pressure diffusion -- 3.5.1 Premixed propane-air flames -- 3.5.2 Premixed methane-air flames -- 3.5.3 Summary of pressure diffusion -- 3.6 Potential technology applications -- 3.7 Summary and conclusions -- References 4. Raman spectroscopic measurements of tubular flames / Robert W. Pitz -- 4.1 Introduction -- 4.2 Raman scattering technique -- 4.3 Tubular flame burner -- 4.4 Raman scattering measurements in tubular flames -- 4.4.1 Hydrogen-air tubular flames -- 4.4.2 Methane-air tubular flames -- 4.4.3 Propane-air tubular flames -- 4.5 Cellular tubular flames -- 4.5.1 Instabilities in tubular flames -- 4.5.2 Raman scattering measurements in cellular tubular flames -- References 5. Non-premixed tubular flames / Robert W. Pitz -- 5.1 Introduction -- 5.2 Numerical study of the non-premixed tubular flames -- 5.3 Non-premixed opposed-flow tubular burner -- 5.4 Raman scattering measurements in non-premixed tubular flames -- 5.4.1 Hydrogen/air non-premixed tubular flames -- 5.4.2 Hydrocarbon-air non-premixed tubular flames -- 5.5 Cellular instabilities in non-premixed tubular flames -- 5.5.1 Cellular instabilities in diffusion flames -- 5.5.2 Cellular formation and extinction in non-premixed tubular flames -- References 6. Tubular flame characteristics of miniature liquid film combustors / Derek Dunn-Rankin -- 6.1 Introduction -- 6.2 Brief review of some key features of a tubular flame -- 6.3 Review of the key features of a fuel film combustor flame -- 6.4 Examples of tubular flame behaviors in a fuel film combustor -- 6.4.1 Original design -- 6.4.2 Secondary air injection -- 6.4.3 Swirler design and tubular flame -- 6.5 Concluding remarks -- References 7. Small-scale applications / Daisuke Shimokuri -- 7.1. Introduction -- 7.2. Flame quenching in a narrow channel -- 7.2.1 Flame quenching in a nonrotating flow field -- 7.2.2 Advantages using small-scale tubular flame burners -- 7.2.3 Tubular flame in a small-diameter tube -- 7.2.4 Effects of tube size on the tubular flame -- 7.2.5 Critical tube diameter for a rotating flow field -- 7.3 Development of small power sources using a tubular flame -- References 8. Large-scale applications / Satoru Ishizuka -- 8.1 Introduction -- 8.1.1 Classification -- 8.1.2 Flame diameter and length -- 8.1.3 Rapidly mixed tubular flame combustion -- 8.2 Wide flammable range -- 8.2.1 BFG burners -- 8.3 Fuel diversity -- 8.3.1 Gaseous fuels -- 8.3.2 Liquid fuels -- 8.3.3 Solid fuels -- 8.4 Compactness -- 8.4.1 Fuel-processing system for polymer electrolyte fuel cell -- 8.4.2 Hollow fastening bolt -- 8.4.3 Superheated steam generator -- 8.5 Geometry -- 8.5.1 Flame stabilization -- 8.5.2 Heating process -- 8.5.3 Stirling engine -- References -- Index Includes bibliographical references and index Combustion Tubes / Thermodynamics NATURE / Fossils bisacsh Combustion fast Tubes / Thermodynamics fast Tubes Thermodynamics Verbrennung (DE-588)4062656-8 gnd rswk-swf Verbrennung (DE-588)4062656-8 s 1\p DE-604 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Ishizuka, Satoru Tubular Combustion Combustion Tubes / Thermodynamics NATURE / Fossils bisacsh Combustion fast Tubes / Thermodynamics fast Tubes Thermodynamics Verbrennung (DE-588)4062656-8 gnd |
| subject_GND | (DE-588)4062656-8 |
| title | Tubular Combustion |
| title_auth | Tubular Combustion |
| title_exact_search | Tubular Combustion |
| title_full | Tubular Combustion |
| title_fullStr | Tubular Combustion |
| title_full_unstemmed | Tubular Combustion |
| title_short | Tubular Combustion |
| title_sort | tubular combustion |
| topic | Combustion Tubes / Thermodynamics NATURE / Fossils bisacsh Combustion fast Tubes / Thermodynamics fast Tubes Thermodynamics Verbrennung (DE-588)4062656-8 gnd |
| topic_facet | Combustion Tubes / Thermodynamics NATURE / Fossils Tubes Thermodynamics Verbrennung |
| work_keys_str_mv | AT ishizukasatoru tubularcombustion |