Exergy losses in premixed flames of dimethyl ether and hydrogen blends

Tongbin ZHAO, Jiabo ZHANG, Dehao JU, Zhen HUANG, Dong HAN

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Front. Energy ›› 2019, Vol. 13 ›› Issue (4) : 658-666. DOI: 10.1007/s11708-019-0645-8
RESEARCH ARTICLE
RESEARCH ARTICLE

Exergy losses in premixed flames of dimethyl ether and hydrogen blends

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Abstract

A second-law thermodynamic analysis was conducted for stoichiometric premixed dimethyl ether (DME)/hydrogen (H2)/air flames at atmospheric pressure. The exergy losses from the irreversibility sources, i.e., chemical reaction, heat conduction and species diffusion, and those from partial combustion products were analyzed in the flames with changed fuel blends. It is observed that, regardless of the fuel blends, chemical reaction contributes most to the exergy losses, followed by incomplete combustion, and heat conduction, while mass diffusion has the least contribution to exergy loss. The results also indicate that increased H2 substitution decreases the exergy losses from reactions, conduction, and diffusion, primarily because of the flame thickness reduction at elevated H2 substitution. The decreases in exergy losses by chemical reactions and heat conduction are higher, but the exergy loss reduction by diffusion is slight. However, the exergy losses from incomplete combustion increase with H2 substitution, because the fractions of the unburned fuels and combustion intermediates, e.g., H2 and OH radical, increase. The overall exergy losses in the DME/H2 flames decrease by about 5% with increased H2 substitution from 0% to 100%.

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second law analysis / flame / dimethyl ether (DME) / hydrogen / binary fuels

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Tongbin ZHAO, Jiabo ZHANG, Dehao JU, Zhen HUANG, Dong HAN. Exergy losses in premixed flames of dimethyl ether and hydrogen blends. Front. Energy, 2019, 13(4): 658‒666 https://doi.org/10.1007/s11708-019-0645-8

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]
Han D, Zhai J Q, Duan Y Z, Ju D H, Lin H, Huang Z. Macroscopic and microscopic spray characteristics of fatty acid esters on a common rail injection system. Fuel, 2017, 203: 370–379
CrossRef Google scholar
[2]
Zhu H Y, Bohac S V, Huang Z, Assanis D N. Emissions as functions of fuel oxygen and load from a premixed low-temperature combustion mode. International Journal of Engine Research, 2014, 15(6): 731–740
CrossRef Google scholar
[3]
Zhang J B, Zhai J Q, Ju D H, Huang Z, Han D. Effects of exhaust gas recirculation constituents on methyl decanoate auto-ignition: a kinetic study. Journal of Engineering for Gas Turbines and Power, 2018, 140: 121001
CrossRef Google scholar
[4]
Fan Y C, Duan Y Z, Han D, Qiao X Q, Huang Z. Influences of isomeric butanol addition on anti-knock tendency of primary reference fuel and toluene primary reference fuel gasoline surrogates. International Journal of Engine Research, 2019, doi: 10.1177/1468087419850704
[5]
Pan M Z, Wei H Q, Feng D Q, Pan J Y, Huang R, Liao J Y. Experimental study on combustion characteristics and emission performance of 2-phenylethanol addition in a downsized gasoline engine. Energy, 2018, 163: 894–904
CrossRef Google scholar
[6]
Pan M Z, Huang R, Liao J Y, Ouyang T C, Zheng Z Y, Lv D L, Huang H Z. Effect of EGR dilution on combustion, performance and emission characteristics of a diesel engine fueled with n-pentanol and 2-ethylhexyl nitrate additive. Energy Conversion and Management, 2018, 176: 246–255
CrossRef Google scholar
[7]
Liang X, Zhong A H, Sun Z Y, Han D. Autoignition of n-heptane and butanol isomers blends in a constant volume combustion chamber. Fuel, 2019, 254: 115638
CrossRef Google scholar
[8]
Zhang J B, Huang Z, Han D. Exergy losses in auto-ignition processes of DME and alcohol blends. Fuel, 2018, 229: 116–125
CrossRef Google scholar
[9]
Dai P, Chen Z, Chen S. Ignition of methane with hydrogen and dimethyl ether addition. Fuel, 2014, 118: 1–8
CrossRef Google scholar
[10]
Gerke U, Boulouchos K. Three-dimensional computational fluid dynamics simulation of hydrogen engines using a turbulent flame speed closure combustion model. International Journal of Engine Research, 2012, 13(5): 464–481
CrossRef Google scholar
[11]
Su T, Ji C W, Wang S F, Shi L, Yang J X, Cong X Y. Idle performance of a hydrogen rotary engine at different excess air ratios. International Journal of Hydrogen Energy, 2018, 43(4): 2443–2451
CrossRef Google scholar
[12]
Hairuddin A A, Yusaf T, Wandel A P. A review of hydrogen and natural gas addition in diesel HCCI engines. Renewable & Sustainable Energy Reviews, 2014, 32: 739–761
CrossRef Google scholar
[13]
Salvi B L, Subramanian K A. Sustainable development of road transportation sector using hydrogen energy system. Renewable & Sustainable Energy Reviews, 2015, 51: 1132–1155
CrossRef Google scholar
[14]
Liu J, Yang F Y, Wang H W, Ouyang M G. Numerical study of hydrogen addition to DME/CH4 dual fuel RCCI engine. International Journal of Hydrogen Energy, 2012, 37(10): 8688–8697
CrossRef Google scholar
[15]
Jeon J, Bae C. The effects of hydrogen addition on engine power and emission in DME premixed charge compression ignition engine. International Journal of Hydrogen Energy, 2013, 38(1): 265–273
CrossRef Google scholar
[16]
Shi Z C, Zhang H G, Wu H, Xu Y H. Ignition properties of lean DME/H2 mixtures at low temperatures and elevated pressures. Fuel, 2018, 226: 545–554
CrossRef Google scholar
[17]
Shi Z C, Zhang H G, Lu H T, Liu H, A Y S, Meng F X. Autoignition of DME/H2 mixtures in a rapid compression machine under low-to-medium temperature ranges. Fuel, 2017, 194: 50–62
CrossRef Google scholar
[18]
Wang Y, Liu H, Ke X C, Shen Z X. Kinetic modeling study of homogeneous ignition of dimethyl ether/hydrogen and dimethyl ether/methane. Applied Thermal Engineering, 2017, 119: 373–386
CrossRef Google scholar
[19]
Pan L, Hu E J, Meng X, Zhang Z H, Huang Z H. Kinetic modeling study of hydrogen addition effects on ignition characteristics of dimethyl ether at engine-relevant conditions. International Journal of Hydrogen Energy, 2015, 40(15): 5221–5235
CrossRef Google scholar
[20]
Hu E J, Chen Y Z, Cheng Y, Meng X, Yu H B, Huang Z H. Study on the effect of hydrogen addition to dimethyl ether homogeneous charge compression ignition combustion engine. Journal of Renewable and Sustainable Energy, 2015, 7(6): 063121
CrossRef Google scholar
[21]
Wang Z H, Wang S X, Whiddon R, Han X L, He Y, Cen K F. Effect of hydrogen addition on laminar burning velocity of CH4/DME mixtures by heat flux method and kinetic modeling. Fuel, 2018, 232: 729–742
CrossRef Google scholar
[22]
Liu D. Kinetic analysis of the chemical effects of hydrogen addition on dimethyl ether flames. International Journal of Hydrogen Energy, 2014, 39(24): 13014–13019
CrossRef Google scholar
[23]
Kang Y H, Lu X F, Wang Q H, Gan L, Ji X Y, Wang H, Guo Q, Song D C, Ji P Y. Effect of H2 addition on combustion characteristics of dimethyl ether jet diffusion flame. Energy Conversion and Management, 2015, 89: 735–748
CrossRef Google scholar
[24]
Rakopoulos C D, Giakoumis E G. Second-law analyses applied to internal combustion engines operation. Progress in Energy and Combustion Science, 2006, 32(1): 2–47
CrossRef Google scholar
[25]
Caton J A. Exergy destruction during the combustion process as functions of operating and design parameters for a spark-ignition engine. International Journal of Energy Research, 2012, 36(3): 368–384
CrossRef Google scholar
[26]
Zhang J B, Huang Z, Min K D, Han D. Dilution, thermal and chemical effects of carbon dioxide on the exergy destruction in n-heptane and iso-octane auto-ignition processes: a numerical study. Energy & Fuels, 2018, 32(4): 5559–5570
CrossRef Google scholar
[27]
Pan F J, Zhang J B, Han D, Lu T. Numerical study on exergy losses of iso-octane constant-volume combustion with water addition. Fuel, 2019, 248: 127–135
CrossRef Google scholar
[28]
Zhang J B, Huang Z, Han D. Effects of mechanism reduction on the exergy losses analysis in n-heptane auto-ignition processes. International Journal of Engine Research, 2019, doi: 10.1177/1468087419836870
[29]
Zhang J B, Zhong A H, Huang Z, Han D. Second-law thermodynamic analysis in premixed flames of ammonia and hydrogen binary fuels. Journal of Engineering for Gas Turbines and Power, 2019, 141(7): 071007
CrossRef Google scholar
[30]
Zhang J B, Han D, Huang Z. Second-law thermodynamic analysis for premixed hydrogen flames with diluents of argon/nitrogen/carbon dioxide. International Journal of Hydrogen Energy, 2019, 44(10): 5020–5029
CrossRef Google scholar
[31]
Nishida K, Takagi T, Kinoshita S. Analysis of entropy generation and exergy loss during combustion. Proceedings of the Combustion Institute, 2002, 29(1): 869–874
CrossRef Google scholar
[32]
Chen S, Li J, Han H, Liu Z, Zheng C. Effects of hydrogen addition on entropy generation in ultra-lean counter-flow methane-air premixed combustion. International Journal of Hydrogen Energy, 2010, 35(8): 3891–3902
CrossRef Google scholar
[33]
Jiang D, Yang W, Teng J. Entropy generation analysis of fuel lean premixed CO/H2/air flames. International Journal of Hydrogen Energy, 2015, 40(15): 5210–5220
CrossRef Google scholar
[34]
Burke U, Metcalfe W K, Burke S M, Heufer K A, Dagaut P, Curran H J. A detailed chemical kinetic modeling, ignition delay time and jet-stirred reactor study of methanol oxidation. Combustion and Flame, 2016, 165: 125–136
CrossRef Google scholar
[35]
Fischer S L, Dryer F L, Curran H J. The reaction kinetics of dimethyl ether. I: high-temperature pyrolysis and oxidation in flow reactors. International Journal of Chemical Kinetics, 2000, 32(12): 713–740
CrossRef Google scholar
[36]
Wang Z D, Zhang X Y, Xing L L, Zhang L D, Herrmann F, Moshammer K, Qi F, Kohse-Höinghaus K. Experimental and kinetic modeling study of the low- and intermediate-temperature oxidation of dimethyl ether. Combustion and Flame, 2015, 162(4): 1113–1125
CrossRef Google scholar
[37]
Daly C A, Simmie J M, Würmel J, DjebaÏli N, Paillard C. Burning velocities of dimethyl ether and air. Combustion and Flame, 2001, 125(4): 1329–1340
CrossRef Google scholar
[38]
Huang Z H, Chen G, Chen C Y, Miao H Y, Wang X B, Jiang D M. Experimental study on premixed combustion of dimethyl ether–hydrogen–air mixtures. Energy & Fuels, 2008, 22(2): 967–971
CrossRef Google scholar
[39]
Yu H, Hu E, Cheng Y, Yang K, Zhang X, Huang Z. Effects of hydrogen addition on the laminar flame speed and markstein length of premixed dimethyl ether-air flames. Energy & Fuels, 2015, 29(7): 4567–4575
CrossRef Google scholar
[40]
Lamoureux N, Djebaıli-Chaumeix N, Paillard C E. Laminar flame velocity determination for H2–air–He–CO2 mixtures using the spherical bomb method. Experimental Thermal and Fluid Science, 2003, 27(4): 385–393
CrossRef Google scholar
[41]
CHEMKIN-PRO 15141. Reaction Design, San Diego, 2015
[42]
Hirschfelder J, Curtiss C, Bird R. Molecular Theory of Gases and Liquids. New York: Wiley, 1954
[43]
Briones A M, Mukhopadhyay A, Aggarwal S K. Analysis of entropy generation in hydrogen-enriched methane–air propagating triple flames. International Journal of Hydrogen Energy, 2009, 34(2): 1074–1083
CrossRef Google scholar
[44]
Emadi A, Emami M D. Analysis of entropy generation in a hydrogen-enriched turbulent non-premixed flame. International Journal of Hydrogen Energy, 2013, 38(14): 5961–5973
CrossRef Google scholar
[45]
Bejan A. Entropy Generation Through Heat and Fluid Flow. Wiley: New York, 1982
[46]
Saxena S, Dario Bedoya I, Shah N, Phadke A. Understanding loss mechanisms and identifying areas of improvement for HCCI engines using detailed exergy analysis. Journal of Engineering for Gas Turbines and Power, 2013, 135(9): 091505
CrossRef Google scholar
[47]
Yan F, Su W H. Numerical study on exergy losses of n-heptane constant-volume combustion by detailed chemical kinetics. Energy & Fuels, 2014, 28(10): 6635–6643
CrossRef Google scholar
[48]
Mamalis S, Babajimopoulos A, Assanis D, Borgnakke C. A modeling framework for second law analysis of low-temperature combustion engines. International Journal of Engine Research, 2014, 15(6): 641–653
CrossRef Google scholar
[49]
de Vries J, Lowry W B, Serinyel Z, Curran H J, Petersen E L. Laminar flame speed measurements of dimethyl ether in air at pressures up to 10 atm. Fuel, 2011, 90(1): 331–338
CrossRef Google scholar

Acknowledgments

This work was financially supported by the National Natural Science Foundation of China (Grant No. 51776124) and Key Laboratory of Low-Grade Energy Utilization Technologies & Systems of MOE (Grant No. LLEUTS-201803).

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2019 Higher Education Press and Springer-Verlag GmbH Germany, part of Springer Nature
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