CH4/NH3 Flame Structure and Extinction Limit under Flame–Flame Interactions
Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH4/NH3 flame was lit by applying a double-nozzle burner to gain insight into the structure, and the laminar diffusion flame structure, CH*/OH* intensity maximum...
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| Published in | ACS omega Vol. 9; no. 13; pp. 14997 - 15014 |
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| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
American Chemical Society
02.04.2024
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| Online Access | Get full text |
| ISSN | 2470-1343 2470-1343 |
| DOI | 10.1021/acsomega.3c09073 |
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| Abstract | Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH4/NH3 flame was lit by applying a double-nozzle burner to gain insight into the structure, and the laminar diffusion flame structure, CH*/OH* intensity maximum, and flame size were analyzed by an ICCD camera. In addition, the extinction limit (lower limit) of the CH4/NH3 flame under different conditions was also studied. The results showed that with the increase of burner pitch, the two diffusion flames showed four states of merged flames, merging flames, inclining separated flames, and independent flames in turn. In the process of flame separation, the continuous pitch between merging flames was short. At this point, higher syngas flow could help increase the continuous pitch to keep merging form. The paper investigated the flame structure and found that the flame size would decrease when the NH3 content in the fuel was high. The flame stability also decreased with an increase of the NH3 content in the fuel. These findings provided experimental proof and a theoretical basis for future studies on the stability of CH4/NH3 co-firing. |
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| AbstractList | Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH4/NH3 flame was lit by applying a double-nozzle burner to gain insight into the structure, and the laminar diffusion flame structure, CH*/OH* intensity maximum, and flame size were analyzed by an ICCD camera. In addition, the extinction limit (lower limit) of the CH4/NH3 flame under different conditions was also studied. The results showed that with the increase of burner pitch, the two diffusion flames showed four states of merged flames, merging flames, inclining separated flames, and independent flames in turn. In the process of flame separation, the continuous pitch between merging flames was short. At this point, higher syngas flow could help increase the continuous pitch to keep merging form. The paper investigated the flame structure and found that the flame size would decrease when the NH3 content in the fuel was high. The flame stability also decreased with an increase of the NH3 content in the fuel. These findings provided experimental proof and a theoretical basis for future studies on the stability of CH4/NH3 co-firing.Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH4/NH3 flame was lit by applying a double-nozzle burner to gain insight into the structure, and the laminar diffusion flame structure, CH*/OH* intensity maximum, and flame size were analyzed by an ICCD camera. In addition, the extinction limit (lower limit) of the CH4/NH3 flame under different conditions was also studied. The results showed that with the increase of burner pitch, the two diffusion flames showed four states of merged flames, merging flames, inclining separated flames, and independent flames in turn. In the process of flame separation, the continuous pitch between merging flames was short. At this point, higher syngas flow could help increase the continuous pitch to keep merging form. The paper investigated the flame structure and found that the flame size would decrease when the NH3 content in the fuel was high. The flame stability also decreased with an increase of the NH3 content in the fuel. These findings provided experimental proof and a theoretical basis for future studies on the stability of CH4/NH3 co-firing. Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH4/NH3 flame was lit by applying a double-nozzle burner to gain insight into the structure, and the laminar diffusion flame structure, CH*/OH* intensity maximum, and flame size were analyzed by an ICCD camera. In addition, the extinction limit (lower limit) of the CH4/NH3 flame under different conditions was also studied. The results showed that with the increase of burner pitch, the two diffusion flames showed four states of merged flames, merging flames, inclining separated flames, and independent flames in turn. In the process of flame separation, the continuous pitch between merging flames was short. At this point, higher syngas flow could help increase the continuous pitch to keep merging form. The paper investigated the flame structure and found that the flame size would decrease when the NH3 content in the fuel was high. The flame stability also decreased with an increase of the NH3 content in the fuel. These findings provided experimental proof and a theoretical basis for future studies on the stability of CH4/NH3 co-firing. Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH 4 /NH 3 flame was lit by applying a double-nozzle burner to gain insight into the structure, and the laminar diffusion flame structure, CH*/OH* intensity maximum, and flame size were analyzed by an ICCD camera. In addition, the extinction limit (lower limit) of the CH 4 /NH 3 flame under different conditions was also studied. The results showed that with the increase of burner pitch, the two diffusion flames showed four states of merged flames, merging flames, inclining separated flames, and independent flames in turn. In the process of flame separation, the continuous pitch between merging flames was short. At this point, higher syngas flow could help increase the continuous pitch to keep merging form. The paper investigated the flame structure and found that the flame size would decrease when the NH 3 content in the fuel was high. The flame stability also decreased with an increase of the NH 3 content in the fuel. These findings provided experimental proof and a theoretical basis for future studies on the stability of CH 4 /NH 3 co-firing. |
| Author | Meng, Fanxing Ren, Xiaohan Zheng, Bingbing Chen, Quanwang |
| AuthorAffiliation | Institute of Thermal Science and Technology Shandong Institute for Product Quality Inspection Shandong University Institute for Advanced Technology |
| AuthorAffiliation_xml | – name: Shandong Institute for Product Quality Inspection – name: Shandong University – name: Institute of Thermal Science and Technology – name: Institute for Advanced Technology |
| Author_xml | – sequence: 1 givenname: Fanxing surname: Meng fullname: Meng, Fanxing organization: Shandong University – sequence: 2 givenname: Quanwang surname: Chen fullname: Chen, Quanwang organization: Shandong Institute for Product Quality Inspection – sequence: 3 givenname: Bingbing surname: Zheng fullname: Zheng, Bingbing organization: Shandong University – sequence: 4 givenname: Xiaohan orcidid: 0009-0005-3142-5436 surname: Ren fullname: Ren, Xiaohan email: renxh@sdu.edu.cn organization: Institute of Thermal Science and Technology |
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| Snippet | Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH4/NH3 flame was... Ammonia is considered to play an important role in replacing traditional fossil fuels in future energy systems. In the experimental study, CH 4 /NH 3 flame was... |
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| Title | CH4/NH3 Flame Structure and Extinction Limit under Flame–Flame Interactions |
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