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Ammonia–water bottoming cycles: a comparison between gas engines and gas diesel engines as prime movers

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  • Jonsson, Maria
  • Yan, Jinyue

Abstract

Ammonia–water cycles can produce more power than steam Rankine cycles in several applications. One of these applications is as a bottoming cycle to internal combustion engines. In the present study, ammonia–water bottoming cycle configurations for spark-ignition gas engines and compression-ignition gas diesel engines have been compared. Single-pressure Rankine cycles have been used as a basis for the comparison. Low heat source temperatures should increase the difference in power output between the ammonia–water cycle and the Rankine cycle. However, in this study, the results of the simulations show different trends. In most cases, the ammonia–water bottoming cycles with gas engines as prime movers generate more power compared to a Rankine cycle than when gas diesel engines are the prime movers. The temperature of the most important waste heat source, the exhaust gas, is approximately 100°C higher for the gas engines than for the gas diesel engines. Therefore, for the gas engines, most of the waste heat available to a bottoming cycle is in the form of relatively high-temperature exhaust gas, while for the gas diesel engines more of the waste heat is in the form of relatively low-temperature heat sources.

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  • Jonsson, Maria & Yan, Jinyue, 2001. "Ammonia–water bottoming cycles: a comparison between gas engines and gas diesel engines as prime movers," Energy, Elsevier, vol. 26(1), pages 31-44.
    • Handle: RePEc:eee:energy:v:26:y:2001:i:1:p:31-44
    DOI: 10.1016/S0360-5442(00)00043-8
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    1. Chen, Yaping & Guo, Zhanwei & Wu, Jiafeng & Zhang, Zhi & Hua, Junye, 2015. "Energy and exergy analysis of integrated system of ammonia–water Kalina–Rankine cycle," Energy, Elsevier, vol. 90(P2), pages 2028-2037.
    2. Kiani, Behdad & Akisawa, Atsushi & Kashiwagi, Takao, 2008. "Thermodynamic analysis of load-leveling hyper energy converting and utilization system," Energy, Elsevier, vol. 33(3), pages 400-409.
    3. Wang, Jiangfeng & Dai, Yiping & Gao, Lin, 2009. "Exergy analyses and parametric optimizations for different cogeneration power plants in cement industry," Applied Energy, Elsevier, vol. 86(6), pages 941-948, June.
    4. Sarabchi, N. & Khoshbakhti Saray, R. & Mahmoudi, S.M.S., 2013. "Utilization of waste heat from a HCCI (homogeneous charge compression ignition) engine in a tri-generation system," Energy, Elsevier, vol. 55(C), pages 965-976.
    5. Nguyen, Tuong-Van & Knudsen, Thomas & Larsen, Ulrik & Haglind, Fredrik, 2014. "Thermodynamic evaluation of the Kalina split-cycle concepts for waste heat recovery applications," Energy, Elsevier, vol. 71(C), pages 277-288.
    6. Bahlouli, K. & Khoshbakhti Saray, R. & Sarabchi, N., 2015. "Parametric investigation and thermo-economic multi-objective optimization of an ammonia–water power/cooling cycle coupled with an HCCI (homogeneous charge compression ignition) engine," Energy, Elsevier, vol. 86(C), pages 672-684.
    7. Yue, Chen & Han, Dong & Pu, Wenhao & He, Weifeng, 2016. "Parametric analysis of a vehicle power and cooling/heating cogeneration system," Energy, Elsevier, vol. 115(P1), pages 800-810.
    8. Yue, Chen & Han, Dong & Pu, Wenhao & He, Weifeng, 2015. "Energetic analysis of a novel vehicle power and cooling/heating cogeneration energy system using cascade cycles," Energy, Elsevier, vol. 82(C), pages 242-255.
    9. Querol, E. & Gonzalez-Regueral, B. & García-Torrent, J. & Ramos, Alberto, 2011. "Available power generation cycles to be coupled with the liquid natural gas (LNG) vaporization process in a Spanish LNG terminal," Applied Energy, Elsevier, vol. 88(7), pages 2382-2390, July.
    10. Larsen, Ulrik & Sigthorsson, Oskar & Haglind, Fredrik, 2014. "A comparison of advanced heat recovery power cycles in a combined cycle for large ships," Energy, Elsevier, vol. 74(C), pages 260-268.
    11. Yu, Zeting & Han, Jitian & Liu, Hai & Zhao, Hongxia, 2014. "Theoretical study on a novel ammonia–water cogeneration system with adjustable cooling to power ratios," Applied Energy, Elsevier, vol. 122(C), pages 53-61.
    12. Zhang, Xinxin & He, Maogang & Zhang, Ying, 2012. "A review of research on the Kalina cycle," Renewable and Sustainable Energy Reviews, Elsevier, vol. 16(7), pages 5309-5318.
    13. Zhu, Zilong & Zhang, Zhi & Chen, Yaping & Wu, Jiafeng, 2016. "Parameter optimization of dual-pressure vaporization Kalina cycle with second evaporator parallel to economizer," Energy, Elsevier, vol. 112(C), pages 420-429.
    14. Kim, Kyoung Hoon & Ko, Hyung Jong & Kim, Kyoungjin, 2014. "Assessment of pinch point characteristics in heat exchangers and condensers of ammonia–water based power cycles," Applied Energy, Elsevier, vol. 113(C), pages 970-981.
    15. Zhang, Ye-Qiang & Wu, Yu-Ting & Xia, Guo-Dong & Ma, Chong-Fang & Ji, Wei-Ning & Liu, Shan-Wei & Yang, Kai & Yang, Fu-Bin, 2014. "Development and experimental study on organic Rankine cycle system with single-screw expander for waste heat recovery from exhaust of diesel engine," Energy, Elsevier, vol. 77(C), pages 499-508.
    16. Wang, Jiangfeng & Yan, Zhequan & Wang, Man & Dai, Yiping, 2013. "Thermodynamic analysis and optimization of an ammonia-water power system with LNG (liquefied natural gas) as its heat sink," Energy, Elsevier, vol. 50(C), pages 513-522.

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