Production of hydrogen by simple impingement of a turbulent jet of steam upon a high temperature zirconia surface
Identifieur interne : 000132 ( Istex/Corpus ); précédent : 000131; suivant : 000133Production of hydrogen by simple impingement of a turbulent jet of steam upon a high temperature zirconia surface
Auteurs : J. Lede ; J. Villermaux ; R. Ouzane ; M. A. Hossain ; R. OuahesSource :
- International Journal of Hydrogen Energy [ 0360-3199 ] ; 1987.
English descriptors
- KwdEn :
- Atmospheric pressure, Boundary layer, Collision efficiency, Cooling rate, Cylindrical cavity, Dissociation, Dissociation reactor, Experimental device, First approach, Flat surface, Flow rate, Heat transfer, Heat transfer coefficient, High temperature, High temperature zone, Hollow target, Hydrogen energy, Hydrogen production, Image furnace, Incident radiation, Lapicque, Lede, Mass flow rate, Maximum production, Nozzle, Nozzle exit, Nusselt number, Prandtl number, Present case, Present paper, Present work, Pure steam, Pyrex, Pyrex vessel, Pyrex walls, Quenching, Quenching device, Quenching devices, Rapid cooling, Reaction temperature, Recombination, Reynolds number, Reynolds numbers, Round nozzle, Same surface, Simple device, Simple impingement, Simplified flow model, Solid target, Stagnation, Stagnation flow region, Stagnation zone, Steam, Steam flow rate, Surface area, Target temperature, Temperature increase, Thermodynamic equilibrium, Thermolysis, Total flow rate, Villermaux, Volumetric flow rate, Wall dissociation, Wall temperature, Water input, Water thermolysis, Xenon lamp, Zirconia, Zirconia surface.
- Teeft :
- Atmospheric pressure, Boundary layer, Collision efficiency, Cooling rate, Cylindrical cavity, Dissociation, Dissociation reactor, Experimental device, First approach, Flat surface, Flow rate, Heat transfer, Heat transfer coefficient, High temperature, High temperature zone, Hollow target, Hydrogen energy, Hydrogen production, Image furnace, Incident radiation, Lapicque, Lede, Mass flow rate, Maximum production, Nozzle, Nozzle exit, Nusselt number, Prandtl number, Present case, Present paper, Present work, Pure steam, Pyrex, Pyrex vessel, Pyrex walls, Quenching, Quenching device, Quenching devices, Rapid cooling, Reaction temperature, Recombination, Reynolds number, Reynolds numbers, Round nozzle, Same surface, Simple device, Simple impingement, Simplified flow model, Solid target, Stagnation, Stagnation flow region, Stagnation zone, Steam, Steam flow rate, Surface area, Target temperature, Temperature increase, Thermodynamic equilibrium, Thermolysis, Total flow rate, Villermaux, Volumetric flow rate, Wall dissociation, Wall temperature, Water input, Water thermolysis, Xenon lamp, Zirconia, Zirconia surface.
Abstract
Abstract: The present paper describes the first results of experiments for the production of hydrogen by simple impingement of a turbulent jet of steam on a zirconia surface heated at the focus of an image furnace. Experiments were made by varying the target temperature (2200–2500 K), the steam flow rate and the nozzle to target distance. The reaction is likely to occur in a thin thermal boundary layer close to the surface or by a partially heterogeneous wall dissociation. The results compare favorably with those of other methods using secondary cold turbulent jets of gas for quenching: less steam is wasted (no quenching device) and the available energy for heating the reactants is better used (thermal boundary layer concept).
Url:
DOI: 10.1016/0360-3199(87)90120-0
Links to Exploration step
ISTEX:56AE76FFB0A4603366750B196C98F49B909AA4B4Le document en format XML
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rate</term><term>Cylindrical cavity</term><term>Dissociation</term><term>Dissociation reactor</term><term>Experimental device</term><term>First approach</term><term>Flat surface</term><term>Flow rate</term><term>Heat transfer</term><term>Heat transfer coefficient</term><term>High temperature</term><term>High temperature zone</term><term>Hollow target</term><term>Hydrogen energy</term><term>Hydrogen production</term><term>Image furnace</term><term>Incident radiation</term><term>Lapicque</term><term>Lede</term><term>Mass flow rate</term><term>Maximum production</term><term>Nozzle</term><term>Nozzle exit</term><term>Nusselt number</term><term>Prandtl number</term><term>Present case</term><term>Present paper</term><term>Present work</term><term>Pure steam</term><term>Pyrex</term><term>Pyrex vessel</term><term>Pyrex walls</term><term>Quenching</term><term>Quenching device</term><term>Quenching devices</term><term>Rapid cooling</term><term>Reaction temperature</term><term>Recombination</term><term>Reynolds number</term><term>Reynolds numbers</term><term>Round nozzle</term><term>Same surface</term><term>Simple device</term><term>Simple impingement</term><term>Simplified flow model</term><term>Solid target</term><term>Stagnation</term><term>Stagnation flow region</term><term>Stagnation zone</term><term>Steam</term><term>Steam flow rate</term><term>Surface area</term><term>Target temperature</term><term>Temperature increase</term><term>Thermodynamic equilibrium</term><term>Thermolysis</term><term>Total flow rate</term><term>Villermaux</term><term>Volumetric flow rate</term><term>Wall dissociation</term><term>Wall temperature</term><term>Water input</term><term>Water thermolysis</term><term>Xenon lamp</term><term>Zirconia</term><term>Zirconia surface</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Atmospheric pressure</term><term>Boundary layer</term><term>Collision efficiency</term><term>Cooling 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describes the first results of experiments for the production of hydrogen by simple impingement of a turbulent jet of steam on a zirconia surface heated at the focus of an image furnace. Experiments were made by varying the target temperature (2200–2500 K), the steam flow rate and the nozzle to target distance. The reaction is likely to occur in a thin thermal boundary layer close to the surface or by a partially heterogeneous wall dissociation. The results compare favorably with those of other methods using secondary cold turbulent jets of gas for quenching: less steam is wasted (no quenching device) and the available energy for heating the reactants is better used (thermal boundary layer concept).</div></front></TEI><istex><corpusName>elsevier</corpusName><keywords><teeft><json:string>zirconia</json:string><json:string>lede</json:string><json:string>quenching</json:string><json:string>pyrex vessel</json:string><json:string>villermaux</json:string><json:string>nozzle exit</json:string><json:string>flow rate</json:string><json:string>lapicque</json:string><json:string>thermolysis</json:string><json:string>recombination</json:string><json:string>mass flow rate</json:string><json:string>zirconia surface</json:string><json:string>volumetric flow rate</json:string><json:string>boundary layer</json:string><json:string>hydrogen energy</json:string><json:string>hollow target</json:string><json:string>stagnation zone</json:string><json:string>pyrex walls</json:string><json:string>high temperature</json:string><json:string>nusselt number</json:string><json:string>present work</json:string><json:string>hydrogen production</json:string><json:string>quenching devices</json:string><json:string>steam flow rate</json:string><json:string>heat transfer coefficient</json:string><json:string>stagnation</json:string><json:string>quenching device</json:string><json:string>target temperature</json:string><json:string>wall temperature</json:string><json:string>reynolds number</json:string><json:string>reaction temperature</json:string><json:string>total flow rate</json:string><json:string>thermodynamic equilibrium</json:string><json:string>flat surface</json:string><json:string>present paper</json:string><json:string>rapid cooling</json:string><json:string>image furnace</json:string><json:string>nozzle</json:string><json:string>dissociation</json:string><json:string>reynolds numbers</json:string><json:string>temperature increase</json:string><json:string>simple device</json:string><json:string>collision efficiency</json:string><json:string>solid target</json:string><json:string>xenon lamp</json:string><json:string>water thermolysis</json:string><json:string>high temperature zone</json:string><json:string>incident radiation</json:string><json:string>experimental device</json:string><json:string>surface area</json:string><json:string>water input</json:string><json:string>prandtl number</json:string><json:string>stagnation flow region</json:string><json:string>atmospheric pressure</json:string><json:string>heat transfer</json:string><json:string>first approach</json:string><json:string>simplified flow model</json:string><json:string>same surface</json:string><json:string>present case</json:string><json:string>maximum production</json:string><json:string>round nozzle</json:string><json:string>wall dissociation</json:string><json:string>pure steam</json:string><json:string>dissociation reactor</json:string><json:string>cooling rate</json:string><json:string>cylindrical cavity</json:string><json:string>simple impingement</json:string><json:string>steam</json:string><json:string>pyrex</json:string></teeft></keywords><author><json:item><name>J. Lede</name><affiliations><json:string>LSGC, CNRS-ENSIC, 1 rue Grandville, 54042 Nancy Cedex, France</json:string></affiliations></json:item><json:item><name>J. Villermaux</name><affiliations><json:string>LSGC, CNRS-ENSIC, 1 rue Grandville, 54042 Nancy Cedex, France</json:string></affiliations></json:item><json:item><name>R. Ouzane</name><affiliations><json:string>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</json:string></affiliations></json:item><json:item><name>M.A. Hossain</name><affiliations><json:string>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</json:string></affiliations></json:item><json:item><name>R. Ouahes</name><affiliations><json:string>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</json:string></affiliations></json:item></author><language><json:string>eng</json:string></language><originalGenre><json:string>Full-length article</json:string></originalGenre><abstract>The present paper describes the first results of experiments for the production of hydrogen by simple impingement of a turbulent jet of steam on a zirconia surface heated at the focus of an image furnace. Experiments were made by varying the target temperature (2200–2500 K), the steam flow rate and the nozzle to target distance. The reaction is likely to occur in a thin thermal boundary layer close to the surface or by a partially heterogeneous wall dissociation. The results compare favorably with those of other methods using secondary cold turbulent jets of gas for quenching: less steam is wasted (no quenching device) and the available energy for heating the reactants is better used (thermal boundary layer concept).</abstract><qualityIndicators><score>6.252</score><pdfVersion>1.2</pdfVersion><pdfPageSize>540 x 720 pts</pdfPageSize><refBibsNative>true</refBibsNative><keywordCount>0</keywordCount><abstractCharCount>726</abstractCharCount><pdfWordCount>4836</pdfWordCount><pdfCharCount>25653</pdfCharCount><pdfPageCount>9</pdfPageCount><abstractWordCount>118</abstractWordCount></qualityIndicators><title>Production of hydrogen by simple impingement of a turbulent jet of steam upon a high temperature zirconia surface</title><pii><json:string>0360-3199(87)90120-0</json:string></pii><genre><json:string>research-article</json:string></genre><host><title>International Journal of Hydrogen 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Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</affiliation></author><author xml:id="author-0003"><persName><forename type="first">M.A.</forename><surname>Hossain</surname></persName><affiliation>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</affiliation></author><author xml:id="author-0004"><persName><forename type="first">R.</forename><surname>Ouahes</surname></persName><affiliation>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</affiliation></author><idno type="istex">56AE76FFB0A4603366750B196C98F49B909AA4B4</idno><idno type="DOI">10.1016/0360-3199(87)90120-0</idno><idno type="PII">0360-3199(87)90120-0</idno></analytic><monogr><title level="j">International Journal of Hydrogen Energy</title><title level="j" type="abbrev">HE</title><idno type="pISSN">0360-3199</idno><idno type="PII">S0360-3199(00)X0160-7</idno><imprint><publisher>ELSEVIER</publisher><date type="published" when="1987"></date><biblScope unit="volume">12</biblScope><biblScope unit="issue">1</biblScope><biblScope unit="page" from="3">3</biblScope><biblScope unit="page" to="11">11</biblScope></imprint></monogr></biblStruct></sourceDesc></fileDesc><profileDesc><creation><date>1987</date></creation><langUsage><language ident="en">en</language></langUsage><abstract xml:lang="en"><p>The present paper describes the first results of experiments for the production of hydrogen by simple impingement of a turbulent jet of steam on a zirconia surface heated at the focus of an image furnace. Experiments were made by varying the target temperature (2200–2500 K), the steam flow rate and the nozzle to target distance. The reaction is likely to occur in a thin thermal boundary layer close to the surface or by a partially heterogeneous wall dissociation. The results compare favorably with those of other methods using secondary cold turbulent jets of gas for quenching: less steam is wasted (no quenching device) and the available energy for heating the reactants is better used (thermal boundary layer concept).</p></abstract></profileDesc><revisionDesc><change when="1987">Published</change></revisionDesc></teiHeader></istex:fulltextTEI><json:item><extension>txt</extension><original>false</original><mimetype>text/plain</mimetype><uri>https://api.istex.fr/document/56AE76FFB0A4603366750B196C98F49B909AA4B4/fulltext/txt</uri></json:item></fulltext><metadata><istex:metadataXml wicri:clean="Elsevier, elements deleted: tail"><istex:xmlDeclaration>version="1.0" encoding="utf-8"</istex:xmlDeclaration><istex:docType PUBLIC="-//ES//DTD journal article DTD version 4.5.2//EN//XML" URI="art452.dtd" name="istex:docType"></istex:docType><istex:document><converted-article version="4.5.2" docsubtype="fla"><item-info><jid>HE</jid><aid>87901200</aid><ce:pii>0360-3199(87)90120-0</ce:pii><ce:doi>10.1016/0360-3199(87)90120-0</ce:doi><ce:copyright type="unknown" year="1987"></ce:copyright></item-info><head><ce:title>Production of hydrogen by simple impingement of a turbulent jet of steam upon a high temperature zirconia surface</ce:title><ce:author-group><ce:author><ce:given-name>J.</ce:given-name><ce:surname>Lede</ce:surname><ce:cross-ref refid="AFF1"><ce:sup>∗</ce:sup></ce:cross-ref></ce:author><ce:author><ce:given-name>J.</ce:given-name><ce:surname>Villermaux</ce:surname><ce:cross-ref refid="AFF1"><ce:sup>∗</ce:sup></ce:cross-ref></ce:author><ce:author><ce:given-name>R.</ce:given-name><ce:surname>Ouzane</ce:surname><ce:cross-ref refid="AFF2"><ce:sup>†</ce:sup></ce:cross-ref></ce:author><ce:author><ce:given-name>M.A.</ce:given-name><ce:surname>Hossain</ce:surname><ce:cross-ref refid="AFF2"><ce:sup>†</ce:sup></ce:cross-ref></ce:author><ce:author><ce:given-name>R.</ce:given-name><ce:surname>Ouahes</ce:surname><ce:cross-ref refid="AFF2"><ce:sup>†</ce:sup></ce:cross-ref></ce:author><ce:affiliation id="AFF1"><ce:label>∗</ce:label><ce:textfn>LSGC, CNRS-ENSIC, 1 rue Grandville, 54042 Nancy Cedex, France</ce:textfn></ce:affiliation><ce:affiliation id="AFF2"><ce:label>†</ce:label><ce:textfn>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</ce:textfn></ce:affiliation></ce:author-group><ce:abstract><ce:section-title>Abstract</ce:section-title><ce:abstract-sec><ce:simple-para>The present paper describes the first results of experiments for the production of hydrogen by simple impingement of a turbulent jet of steam on a zirconia surface heated at the focus of an image furnace. Experiments were made by varying the target temperature (2200–2500 K), the steam flow rate and the nozzle to target distance. The reaction is likely to occur in a thin thermal boundary layer close to the surface or by a partially heterogeneous wall dissociation. The results compare favorably with those of other methods using secondary cold turbulent jets of gas for quenching: less steam is wasted (no quenching device) and the available energy for heating the reactants is better used (thermal boundary layer concept).</ce:simple-para></ce:abstract-sec></ce:abstract></head></converted-article></istex:document></istex:metadataXml><mods version="3.6"><titleInfo><title>Production of hydrogen by simple impingement of a turbulent jet of steam upon a high temperature zirconia surface</title></titleInfo><titleInfo type="alternative" contentType="CDATA"><title>Production of hydrogen by simple impingement of a turbulent jet of steam upon a high temperature zirconia surface</title></titleInfo><name type="personal"><namePart type="given">J.</namePart><namePart type="family">Lede</namePart><affiliation>LSGC, CNRS-ENSIC, 1 rue Grandville, 54042 Nancy Cedex, France</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">J.</namePart><namePart type="family">Villermaux</namePart><affiliation>LSGC, CNRS-ENSIC, 1 rue Grandville, 54042 Nancy Cedex, France</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">R.</namePart><namePart type="family">Ouzane</namePart><affiliation>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">M.A.</namePart><namePart type="family">Hossain</namePart><affiliation>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">R.</namePart><namePart type="family">Ouahes</namePart><affiliation>Laboratoire de Chimie Solaire, Institut de Chimie, Université des Sciences et Technologie Houari Boumedienne, B.P. 139, Dar-El-Beida, Alger, Algeria</affiliation><role><roleTerm type="text">author</roleTerm></role></name><typeOfResource>text</typeOfResource><genre type="research-article" displayLabel="Full-length article" authority="ISTEX" authorityURI="https://content-type.data.istex.fr" valueURI="https://content-type.data.istex.fr/ark:/67375/XTP-1JC4F85T-7">research-article</genre><originInfo><publisher>ELSEVIER</publisher><dateIssued encoding="w3cdtf">1987</dateIssued><copyrightDate encoding="w3cdtf">1987</copyrightDate></originInfo><language><languageTerm type="code" authority="iso639-2b">eng</languageTerm><languageTerm type="code" authority="rfc3066">en</languageTerm></language><abstract lang="en">Abstract: The present paper describes the first results of experiments for the production of hydrogen by simple impingement of a turbulent jet of steam on a zirconia surface heated at the focus of an image furnace. Experiments were made by varying the target temperature (2200–2500 K), the steam flow rate and the nozzle to target distance. The reaction is likely to occur in a thin thermal boundary layer close to the surface or by a partially heterogeneous wall dissociation. The results compare favorably with those of other methods using secondary cold turbulent jets of gas for quenching: less steam is wasted (no quenching device) and the available energy for heating the reactants is better used (thermal boundary layer concept).</abstract><relatedItem type="host"><titleInfo><title>International Journal of Hydrogen Energy</title></titleInfo><titleInfo type="abbreviated"><title>HE</title></titleInfo><genre type="journal" authority="ISTEX" authorityURI="https://publication-type.data.istex.fr" valueURI="https://publication-type.data.istex.fr/ark:/67375/JMC-0GLKJH51-B">journal</genre><originInfo><publisher>ELSEVIER</publisher><dateIssued encoding="w3cdtf">1987</dateIssued></originInfo><identifier type="ISSN">0360-3199</identifier><identifier type="PII">S0360-3199(00)X0160-7</identifier><part><date>1987</date><detail type="volume"><number>12</number><caption>vol.</caption></detail><detail type="issue"><number>1</number><caption>no.</caption></detail><extent unit="issue-pages"><start>1</start><end>47</end></extent><extent unit="pages"><start>3</start><end>11</end></extent></part></relatedItem><identifier type="istex">56AE76FFB0A4603366750B196C98F49B909AA4B4</identifier><identifier type="ark">ark:/67375/6H6-2MHQKNFZ-X</identifier><identifier type="DOI">10.1016/0360-3199(87)90120-0</identifier><identifier type="PII">0360-3199(87)90120-0</identifier><recordInfo><recordContentSource authority="ISTEX" authorityURI="https://loaded-corpus.data.istex.fr" valueURI="https://loaded-corpus.data.istex.fr/ark:/67375/XBH-HKKZVM7B-M">elsevier</recordContentSource></recordInfo></mods><json:item><extension>json</extension><original>false</original><mimetype>application/json</mimetype><uri>https://api.istex.fr/document/56AE76FFB0A4603366750B196C98F49B909AA4B4/metadata/json</uri></json:item></metadata><serie></serie></istex></record>Pour manipuler ce document sous Unix (Dilib)
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