Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry

© 2015 International Energy Initiative. The objective of this research is to substitute compressed biomethane gas (CBG) for liquefied petroleum gas (LPG) for use in industrial ceramic kilns. This is for both environmental and economic reasons. In Thailand, the ceramic industry employs directly and i...

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Main Authors: Watit Puttapoun, James Moran, Pruk Aggarangsi, Asira Bunkham
Format: Journal
Published: 2018
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http://cmuir.cmu.ac.th/jspui/handle/6653943832/54456
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-544562018-09-04T10:26:57Z Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry Watit Puttapoun James Moran Pruk Aggarangsi Asira Bunkham Energy Environmental Science Social Sciences © 2015 International Energy Initiative. The objective of this research is to substitute compressed biomethane gas (CBG) for liquefied petroleum gas (LPG) for use in industrial ceramic kilns. This is for both environmental and economic reasons. In Thailand, the ceramic industry employs directly and indirectly over 75,000 people mostly in Saraburi and Nakhon Lampang. It generates annual exports in excess of 30,000 million baht (approximately $910 million US). In 2014, it used 577,000. tons of LPG a fossil fuel. Thailand has the potential to produce renewable biomethane, from agricultural waste, in quantities to meet this demand.Small-scale ceramic kilns use two types of burners, a rocket type and a shower type. A mixing nozzle injects the fuel into the burner. This creates a natural draft which entrains the combustion air and both air and fuel exit at the burner head where ignition occurs. It is not possible to directly substitute CBG for LPG without making physical changes to these nozzles and adjusting the flow parameters. This research outlines a methodology for adapting the burners for CBG and experimentally verifying the predictions. Flame stability, temperature, emissions, and efficiency were measured and were equivalent to the LPG flames. Finally, the modified burners were tested inside a 0.1m3shuttle ceramic kiln and used to fire greenware. It is estimated that a cost savings of up to 30% can be obtained using CBG, with a payback period of a little over three and a half years, factoring in the cost of the changeover. 2018-09-04T10:13:54Z 2018-09-04T10:13:54Z 2015-10-01 Journal 23524669 09730826 2-s2.0-84941269970 10.1016/j.esd.2015.08.001 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84941269970&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/54456
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Energy
Environmental Science
Social Sciences
spellingShingle Energy
Environmental Science
Social Sciences
Watit Puttapoun
James Moran
Pruk Aggarangsi
Asira Bunkham
Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry
description © 2015 International Energy Initiative. The objective of this research is to substitute compressed biomethane gas (CBG) for liquefied petroleum gas (LPG) for use in industrial ceramic kilns. This is for both environmental and economic reasons. In Thailand, the ceramic industry employs directly and indirectly over 75,000 people mostly in Saraburi and Nakhon Lampang. It generates annual exports in excess of 30,000 million baht (approximately $910 million US). In 2014, it used 577,000. tons of LPG a fossil fuel. Thailand has the potential to produce renewable biomethane, from agricultural waste, in quantities to meet this demand.Small-scale ceramic kilns use two types of burners, a rocket type and a shower type. A mixing nozzle injects the fuel into the burner. This creates a natural draft which entrains the combustion air and both air and fuel exit at the burner head where ignition occurs. It is not possible to directly substitute CBG for LPG without making physical changes to these nozzles and adjusting the flow parameters. This research outlines a methodology for adapting the burners for CBG and experimentally verifying the predictions. Flame stability, temperature, emissions, and efficiency were measured and were equivalent to the LPG flames. Finally, the modified burners were tested inside a 0.1m3shuttle ceramic kiln and used to fire greenware. It is estimated that a cost savings of up to 30% can be obtained using CBG, with a payback period of a little over three and a half years, factoring in the cost of the changeover.
format Journal
author Watit Puttapoun
James Moran
Pruk Aggarangsi
Asira Bunkham
author_facet Watit Puttapoun
James Moran
Pruk Aggarangsi
Asira Bunkham
author_sort Watit Puttapoun
title Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry
title_short Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry
title_full Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry
title_fullStr Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry
title_full_unstemmed Powering shuttle kilns with compressed biomethane gas for the Thai ceramic industry
title_sort powering shuttle kilns with compressed biomethane gas for the thai ceramic industry
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84941269970&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/54456
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