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Model-based evaluation of an integrated autothermal biomass gasification and solid oxide fuel cell combined heat and power system
Numerical analysis of combined heat and power plant consisting of a solid oxide fuel cell and autothermal gasification system has been made for several cases of different composition of fuel relevant to air and steam blown biomass gasification process. Wet wood is fed to the fixed-bed downdraft gasi...
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| Published in: | Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science Journal of mechanical engineering science, 2017-02, Vol.231 (4), p.672-694 |
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| container_title | Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science |
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| creator | Borji, Mehdi Atashkari, Kazem Ghorbani, Saba Nariman-Zadeh, Nader |
| description | Numerical analysis of combined heat and power plant consisting of a solid oxide fuel cell and autothermal gasification system has been made for several cases of different composition of fuel relevant to air and steam blown biomass gasification process. Wet wood is fed to the fixed-bed downdraft gasifier and gaseous fuel is produced then after gas cleaning and conditioning can be used in solid oxide fuel cells. The integrated plant is investigated by thermodynamic modeling combining a one-dimensional model of direct internal intermediate planar type solid oxide fuel cell which allows monitoring the temperature gradients along the cell length in different operating conditions and a zero-dimensional autothermal gasifier. The solid oxide fuel cell mathematical model is developed based on gas species mass balances, energy balance, and an electrochemical model beside the kinetics describing internal reforming and water-gas shift reactions. Such a model can be integrated with adiabatic gasification modeling which includes atom balance conservation for assumed gas species and a modified thermodynamic equilibrium analysis. Both gasifier and solid oxide fuel cell models are verified against experimental and previous numerical data available in the literature. Two main parameters, namely modified equivalence ratio and air-to-steam ratio are investigated and the most important cycle parameters such as power, electric and combined heat and power efficiencies, temperature gradients along the cell length, and mole fractions of gaseous species of the produced fuel are analyzed. It has been revealed that any increase in air-to-steam ratio at fixed modified equivalence ratio leads to penalty on cold gas efficiency of the gasifier and both solid oxide fuel cell and combined heat and power plant electric efficiencies. Increased air-to-steam ratio at constant modified equivalence ratio produces a mixture with lower low heating value, higher steam-to-carbon ratio, rich in CO and lower in CH4 content. Under this condition the operating temperature of the cycle and solid oxide fuel cell increases and consequently improves the operating voltage of the cell and combined heat and power efficiency of the plant. On the other hand, results show that gasification with increased modified equivalence ratio at constant air-to-steam ratio produces mixtures richer in CH4 and CO, poorer in H2 with higher low heating value and cold gas efficiency, and lower steam-to-carbon ratio. Such conditio |
| doi_str_mv | 10.1177/0954406215621338 |
| format | article |
| fullrecord | <record><control><sourceid>proquest_cross</sourceid><recordid>TN_cdi_proquest_journals_2425838767</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sage_id>10.1177_0954406215621338</sage_id><sourcerecordid>2425838767</sourcerecordid><originalsourceid>FETCH-LOGICAL-c346t-98ce5d4c38e0f6788a5bc15b1ec013242274479d28ac68ff2495e0f875eea5193</originalsourceid><addsrcrecordid>eNp1kMtLxDAQxoMouD7uHgOeq0matOlRFl-w4kXPZZpO10jbrEnq4-h_btYKguDAzBy-3_cNDCEnnJ1xXpbnrFJSskJwlTrP9Q5ZCCZ5Jiqd75LFVs62-j45COGZpRKFWpDPO9dinzUQsKX4Cv0E0bqRuo7CSO0Yce0hJg2m6OIT-gF62lg3QAh0DcF21swOGFsaXG9b6t5ti7SbsKcG-zTc0NgxZTwhxG9u497Q0_ARIg5HZK-DPuDxzz4kj1eXD8ubbHV_fbu8WGUml0XMKm1QtdLkGllXlFqDagxXDUfDeC6kEKWUZdUKDabQXSdkpRKpS4UIilf5ITmdczfevUwYYv3sJj-mk3VyK53rsigTxWbKeBeCx67eeDuA_6g5q7ePrv8-Olmy2RJgjb-h__JftIR-rQ</addsrcrecordid><sourcetype>Aggregation Database</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype><pqid>2425838767</pqid></control><display><type>article</type><title>Model-based evaluation of an integrated autothermal biomass gasification and solid oxide fuel cell combined heat and power system</title><source>IMechE_英国机械工程师协会期刊</source><source>Sage Journals Online</source><creator>Borji, Mehdi ; Atashkari, Kazem ; Ghorbani, Saba ; Nariman-Zadeh, Nader</creator><creatorcontrib>Borji, Mehdi ; Atashkari, Kazem ; Ghorbani, Saba ; Nariman-Zadeh, Nader</creatorcontrib><description>Numerical analysis of combined heat and power plant consisting of a solid oxide fuel cell and autothermal gasification system has been made for several cases of different composition of fuel relevant to air and steam blown biomass gasification process. Wet wood is fed to the fixed-bed downdraft gasifier and gaseous fuel is produced then after gas cleaning and conditioning can be used in solid oxide fuel cells. The integrated plant is investigated by thermodynamic modeling combining a one-dimensional model of direct internal intermediate planar type solid oxide fuel cell which allows monitoring the temperature gradients along the cell length in different operating conditions and a zero-dimensional autothermal gasifier. The solid oxide fuel cell mathematical model is developed based on gas species mass balances, energy balance, and an electrochemical model beside the kinetics describing internal reforming and water-gas shift reactions. Such a model can be integrated with adiabatic gasification modeling which includes atom balance conservation for assumed gas species and a modified thermodynamic equilibrium analysis. Both gasifier and solid oxide fuel cell models are verified against experimental and previous numerical data available in the literature. Two main parameters, namely modified equivalence ratio and air-to-steam ratio are investigated and the most important cycle parameters such as power, electric and combined heat and power efficiencies, temperature gradients along the cell length, and mole fractions of gaseous species of the produced fuel are analyzed. It has been revealed that any increase in air-to-steam ratio at fixed modified equivalence ratio leads to penalty on cold gas efficiency of the gasifier and both solid oxide fuel cell and combined heat and power plant electric efficiencies. Increased air-to-steam ratio at constant modified equivalence ratio produces a mixture with lower low heating value, higher steam-to-carbon ratio, rich in CO and lower in CH4 content. Under this condition the operating temperature of the cycle and solid oxide fuel cell increases and consequently improves the operating voltage of the cell and combined heat and power efficiency of the plant. On the other hand, results show that gasification with increased modified equivalence ratio at constant air-to-steam ratio produces mixtures richer in CH4 and CO, poorer in H2 with higher low heating value and cold gas efficiency, and lower steam-to-carbon ratio. Such condition improves the electric efficiency of the solid oxide fuel cell and the integrated plant, but the combined heat and power efficiency of the cycle decreases due to decreased operating temperature of the solid oxide fuel cell and the cycle.</description><identifier>ISSN: 0954-4062</identifier><identifier>EISSN: 2041-2983</identifier><identifier>DOI: 10.1177/0954406215621338</identifier><language>eng</language><publisher>London, England: SAGE Publications</publisher><subject>Biomass ; Calorific value ; Carbon monoxide ; Chemical reactions ; Cogeneration ; Cold gas ; Downdraft ; Efficiency ; Electric power systems ; Equilibrium analysis ; Equivalence ratio ; Gaseous fuels ; Gasification ; Heat ; Internal reforming ; Methane ; Numerical analysis ; One dimensional models ; Operating temperature ; Parameter modification ; Power efficiency ; Power plants ; Reaction kinetics ; Solid oxide fuel cells ; Temperature gradients ; Thermodynamic equilibrium ; Wildlife conservation</subject><ispartof>Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science, 2017-02, Vol.231 (4), p.672-694</ispartof><rights>IMechE 2015</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c346t-98ce5d4c38e0f6788a5bc15b1ec013242274479d28ac68ff2495e0f875eea5193</citedby><cites>FETCH-LOGICAL-c346t-98ce5d4c38e0f6788a5bc15b1ec013242274479d28ac68ff2495e0f875eea5193</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://journals.sagepub.com/doi/pdf/10.1177/0954406215621338$$EPDF$$P50$$Gsage$$H</linktopdf><linktohtml>$$Uhttps://journals.sagepub.com/doi/10.1177/0954406215621338$$EHTML$$P50$$Gsage$$H</linktohtml><link.rule.ids>314,780,784,21913,27924,27925,45059,45447,79364</link.rule.ids></links><search><creatorcontrib>Borji, Mehdi</creatorcontrib><creatorcontrib>Atashkari, Kazem</creatorcontrib><creatorcontrib>Ghorbani, Saba</creatorcontrib><creatorcontrib>Nariman-Zadeh, Nader</creatorcontrib><title>Model-based evaluation of an integrated autothermal biomass gasification and solid oxide fuel cell combined heat and power system</title><title>Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science</title><description>Numerical analysis of combined heat and power plant consisting of a solid oxide fuel cell and autothermal gasification system has been made for several cases of different composition of fuel relevant to air and steam blown biomass gasification process. Wet wood is fed to the fixed-bed downdraft gasifier and gaseous fuel is produced then after gas cleaning and conditioning can be used in solid oxide fuel cells. The integrated plant is investigated by thermodynamic modeling combining a one-dimensional model of direct internal intermediate planar type solid oxide fuel cell which allows monitoring the temperature gradients along the cell length in different operating conditions and a zero-dimensional autothermal gasifier. The solid oxide fuel cell mathematical model is developed based on gas species mass balances, energy balance, and an electrochemical model beside the kinetics describing internal reforming and water-gas shift reactions. Such a model can be integrated with adiabatic gasification modeling which includes atom balance conservation for assumed gas species and a modified thermodynamic equilibrium analysis. Both gasifier and solid oxide fuel cell models are verified against experimental and previous numerical data available in the literature. Two main parameters, namely modified equivalence ratio and air-to-steam ratio are investigated and the most important cycle parameters such as power, electric and combined heat and power efficiencies, temperature gradients along the cell length, and mole fractions of gaseous species of the produced fuel are analyzed. It has been revealed that any increase in air-to-steam ratio at fixed modified equivalence ratio leads to penalty on cold gas efficiency of the gasifier and both solid oxide fuel cell and combined heat and power plant electric efficiencies. Increased air-to-steam ratio at constant modified equivalence ratio produces a mixture with lower low heating value, higher steam-to-carbon ratio, rich in CO and lower in CH4 content. Under this condition the operating temperature of the cycle and solid oxide fuel cell increases and consequently improves the operating voltage of the cell and combined heat and power efficiency of the plant. On the other hand, results show that gasification with increased modified equivalence ratio at constant air-to-steam ratio produces mixtures richer in CH4 and CO, poorer in H2 with higher low heating value and cold gas efficiency, and lower steam-to-carbon ratio. Such condition improves the electric efficiency of the solid oxide fuel cell and the integrated plant, but the combined heat and power efficiency of the cycle decreases due to decreased operating temperature of the solid oxide fuel cell and the cycle.</description><subject>Biomass</subject><subject>Calorific value</subject><subject>Carbon monoxide</subject><subject>Chemical reactions</subject><subject>Cogeneration</subject><subject>Cold gas</subject><subject>Downdraft</subject><subject>Efficiency</subject><subject>Electric power systems</subject><subject>Equilibrium analysis</subject><subject>Equivalence ratio</subject><subject>Gaseous fuels</subject><subject>Gasification</subject><subject>Heat</subject><subject>Internal reforming</subject><subject>Methane</subject><subject>Numerical analysis</subject><subject>One dimensional models</subject><subject>Operating temperature</subject><subject>Parameter modification</subject><subject>Power efficiency</subject><subject>Power plants</subject><subject>Reaction kinetics</subject><subject>Solid oxide fuel cells</subject><subject>Temperature gradients</subject><subject>Thermodynamic equilibrium</subject><subject>Wildlife conservation</subject><issn>0954-4062</issn><issn>2041-2983</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNp1kMtLxDAQxoMouD7uHgOeq0matOlRFl-w4kXPZZpO10jbrEnq4-h_btYKguDAzBy-3_cNDCEnnJ1xXpbnrFJSskJwlTrP9Q5ZCCZ5Jiqd75LFVs62-j45COGZpRKFWpDPO9dinzUQsKX4Cv0E0bqRuo7CSO0Yce0hJg2m6OIT-gF62lg3QAh0DcF21swOGFsaXG9b6t5ti7SbsKcG-zTc0NgxZTwhxG9u497Q0_ARIg5HZK-DPuDxzz4kj1eXD8ubbHV_fbu8WGUml0XMKm1QtdLkGllXlFqDagxXDUfDeC6kEKWUZdUKDabQXSdkpRKpS4UIilf5ITmdczfevUwYYv3sJj-mk3VyK53rsigTxWbKeBeCx67eeDuA_6g5q7ePrv8-Olmy2RJgjb-h__JftIR-rQ</recordid><startdate>20170201</startdate><enddate>20170201</enddate><creator>Borji, Mehdi</creator><creator>Atashkari, Kazem</creator><creator>Ghorbani, Saba</creator><creator>Nariman-Zadeh, Nader</creator><general>SAGE Publications</general><general>SAGE PUBLICATIONS, INC</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>F28</scope><scope>FR3</scope></search><sort><creationdate>20170201</creationdate><title>Model-based evaluation of an integrated autothermal biomass gasification and solid oxide fuel cell combined heat and power system</title><author>Borji, Mehdi ; Atashkari, Kazem ; Ghorbani, Saba ; Nariman-Zadeh, Nader</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c346t-98ce5d4c38e0f6788a5bc15b1ec013242274479d28ac68ff2495e0f875eea5193</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Biomass</topic><topic>Calorific value</topic><topic>Carbon monoxide</topic><topic>Chemical reactions</topic><topic>Cogeneration</topic><topic>Cold gas</topic><topic>Downdraft</topic><topic>Efficiency</topic><topic>Electric power systems</topic><topic>Equilibrium analysis</topic><topic>Equivalence ratio</topic><topic>Gaseous fuels</topic><topic>Gasification</topic><topic>Heat</topic><topic>Internal reforming</topic><topic>Methane</topic><topic>Numerical analysis</topic><topic>One dimensional models</topic><topic>Operating temperature</topic><topic>Parameter modification</topic><topic>Power efficiency</topic><topic>Power plants</topic><topic>Reaction kinetics</topic><topic>Solid oxide fuel cells</topic><topic>Temperature gradients</topic><topic>Thermodynamic equilibrium</topic><topic>Wildlife conservation</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Borji, Mehdi</creatorcontrib><creatorcontrib>Atashkari, Kazem</creatorcontrib><creatorcontrib>Ghorbani, Saba</creatorcontrib><creatorcontrib>Nariman-Zadeh, Nader</creatorcontrib><collection>CrossRef</collection><collection>Mechanical & Transportation Engineering Abstracts</collection><collection>Technology Research Database</collection><collection>ANTE: Abstracts in New Technology & Engineering</collection><collection>Engineering Research Database</collection><jtitle>Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Borji, Mehdi</au><au>Atashkari, Kazem</au><au>Ghorbani, Saba</au><au>Nariman-Zadeh, Nader</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Model-based evaluation of an integrated autothermal biomass gasification and solid oxide fuel cell combined heat and power system</atitle><jtitle>Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science</jtitle><date>2017-02-01</date><risdate>2017</risdate><volume>231</volume><issue>4</issue><spage>672</spage><epage>694</epage><pages>672-694</pages><issn>0954-4062</issn><eissn>2041-2983</eissn><abstract>Numerical analysis of combined heat and power plant consisting of a solid oxide fuel cell and autothermal gasification system has been made for several cases of different composition of fuel relevant to air and steam blown biomass gasification process. Wet wood is fed to the fixed-bed downdraft gasifier and gaseous fuel is produced then after gas cleaning and conditioning can be used in solid oxide fuel cells. The integrated plant is investigated by thermodynamic modeling combining a one-dimensional model of direct internal intermediate planar type solid oxide fuel cell which allows monitoring the temperature gradients along the cell length in different operating conditions and a zero-dimensional autothermal gasifier. The solid oxide fuel cell mathematical model is developed based on gas species mass balances, energy balance, and an electrochemical model beside the kinetics describing internal reforming and water-gas shift reactions. Such a model can be integrated with adiabatic gasification modeling which includes atom balance conservation for assumed gas species and a modified thermodynamic equilibrium analysis. Both gasifier and solid oxide fuel cell models are verified against experimental and previous numerical data available in the literature. Two main parameters, namely modified equivalence ratio and air-to-steam ratio are investigated and the most important cycle parameters such as power, electric and combined heat and power efficiencies, temperature gradients along the cell length, and mole fractions of gaseous species of the produced fuel are analyzed. It has been revealed that any increase in air-to-steam ratio at fixed modified equivalence ratio leads to penalty on cold gas efficiency of the gasifier and both solid oxide fuel cell and combined heat and power plant electric efficiencies. Increased air-to-steam ratio at constant modified equivalence ratio produces a mixture with lower low heating value, higher steam-to-carbon ratio, rich in CO and lower in CH4 content. Under this condition the operating temperature of the cycle and solid oxide fuel cell increases and consequently improves the operating voltage of the cell and combined heat and power efficiency of the plant. On the other hand, results show that gasification with increased modified equivalence ratio at constant air-to-steam ratio produces mixtures richer in CH4 and CO, poorer in H2 with higher low heating value and cold gas efficiency, and lower steam-to-carbon ratio. Such condition improves the electric efficiency of the solid oxide fuel cell and the integrated plant, but the combined heat and power efficiency of the cycle decreases due to decreased operating temperature of the solid oxide fuel cell and the cycle.</abstract><cop>London, England</cop><pub>SAGE Publications</pub><doi>10.1177/0954406215621338</doi><tpages>23</tpages></addata></record> |
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| ispartof | Proceedings of the Institution of Mechanical Engineers. Part C, Journal of mechanical engineering science, 2017-02, Vol.231 (4), p.672-694 |
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| source | IMechE_英国机械工程师协会期刊; Sage Journals Online |
| subjects | Biomass Calorific value Carbon monoxide Chemical reactions Cogeneration Cold gas Downdraft Efficiency Electric power systems Equilibrium analysis Equivalence ratio Gaseous fuels Gasification Heat Internal reforming Methane Numerical analysis One dimensional models Operating temperature Parameter modification Power efficiency Power plants Reaction kinetics Solid oxide fuel cells Temperature gradients Thermodynamic equilibrium Wildlife conservation |
| title | Model-based evaluation of an integrated autothermal biomass gasification and solid oxide fuel cell combined heat and power system |
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