Energy and exergy analyses of hydrogen production by coal gasification

International Journal of Hydrogen Energy

Volumn 42, Issue 4, 2017, Pages 2592-2600

  Seyitoglu, S S ^a   Dincer, I ^b   Kilicarslan, A ^a  

^a HITIT UNIVERSITY   (Turkey)

^b UNIVERSITY OF ONTARIO INSTITUTE OF TECHNOLOGY   (Canada)

Author keywords

Coal gasification; Efficiency; Energy; Exergy; Hydrogen production

Indexed keywords

ABSORPTION COOLING; AIR CLEANERS; BRAYTON CYCLE; COAL; COAL GASIFICATION; COMPUTER SOFTWARE; EFFICIENCY; EXERGY; GAS GENERATORS; RANKINE CYCLE;

AIR SEPARATION UNIT; ENERGY; ENERGY AND EXERGY ANALYSIS; ENERGY AND EXERGY EFFICIENCY; ENGINEERING EQUATION SOLVERS; HIGH TEMPERATURE ELECTROLYZER; ORGANIC RANKINE CYCLE(ORC); PRESSURE SWING ABSORPTION;

HYDROGEN PRODUCTION;

EID: 85005842225     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2016.08.228     Document Type: Article

References (36)

1. [1] World Energy Outlook. Website: http://www.worldenergyoutlook.org. [Accessed: 10.01.2016].
2. [2] Ghosh, S., De, S., Thermodynamic performance study of an integrated gasification fuel cell combined cycle-an energy analysis. J Power Energy 217:2 (2003), 137–147.
3. [3] World Coal Association. Website: http://www.worldcoal.org/coal. [Accessed 15.02.2016].
4. [4] Higman, C., Burgt, M.V.D., Gasification. 2nd ed., 2008, Elsevier Inc.
5. [5] Acar, C., Dincer, I., Comparative assessment of hydrogen production methods from renewable and non-renewable sources. Int J Hydrogen Energy 39 (2014), 1–12.
6. [6] Miller, B.G., Coal energy systems. 2005, Elsevier Inc.
7. [7] Balta, M.T., Dincer, I., Hepbasli, A., Thermodynamic assessment of geothermal energy use in hydrogen production. Int J Hydrogen Energy 34 (2009), 2925–2939.
8. [8] Mansilla, C., Sigurvinsson, J., Bentemps, A., Marechal, A., Werkoff, F., Heat management for hydrogen production by high temperature steam electrolysis. Energy 32 (2007), 423–430.
9. [9] Sigurvinsson, J., Mansilla, C., Lovera, P., Werkoff, F., Can high temperature steam electrolysis function with geothermal heat. Int J Hydrogen Energy 32 (2007), 1174–1182.
10. [10] Fujiwara, S., Kasai, S., Yamauchi, H., Yamada, K., Makino, S., Matsunaga, K., et al. Hydrogen production by high temperature electrolysis with nuclear reactor. Prog Nucl Energy 50 (2008), 422–426.
11. [11] Mingyi, L., Bo, Y., Jingming, X., Jing, C., Thermodynamic analysis of the efficiency of high-temperature steam electrolysis system for hydrogen production. J Power Sources 177:2 (2008), 493–499.
12. [12] Herring, J.S., O'Brien, J.E., Stoots, C.M., Hawkes, G.L., Hartvigsen, J.J., Shahnam, M., Progress in high-temperature electrolysis for hydrogen production using planar SOFC technology. Int J Hydrogen Energy 32:4 (2007), 440–450.
13. [13] Prabu, V., Jayanti, S., Integration of underground coal gasification with a solid oxide fuel cell system for clean coal utilization. Int J Hydrogen Energy 37:2 (2012), 1677–1688.
14. [14] Khalid, F., Dincer, I., Rosen, M.A., Energy and exergy analyses of a solar-biomass integrated cycle for multigeneration. Sol Energy 112 (2015), 290–299.
15. [15] Ozcan, H., Dincer, I., Thermodynamic analysis of a combined chemical looping based trigeneration system. Energy Convers Manag 85 (2014), 477–487.
16. [16] Herdem, M.S., Farhad, S., Dincer, I., Hamdullahpur, F., Thermodynamic modelling and assessment of a coal gasification and alkaline water electrolysis system for hydrogen production. Int J Hydrogen Energy 39:7 (2014), 3061–3071.
17. [17] Bicer, Y., Dincer, I., Energy and exergy analyses of an integrated underground coal gasification with SOFC fuel cell system for multigeneration including hydrogen production. Int J Hydrogen Energy 40:39 (2015), 13323–13337.
18. [18] Gnanapragasam, N.V., Reddy, B.V., Rosen, M.A., Hydrogen production from coal gasification for effective downstream CO2capture. Int J Hydrogen Energy 35:10 (2010), 4933–4943.
19. [19] El-Emam, R.S., Dincer, I., Naterer, G.F., Energy and exergy analyses of an integrated SOFC and coal gasification system. Int J Hydrogen Energy 37:2 (2012), 1689–1697.
20. [20] Martelli, E., Kreutz, T., Consonni, S., Comparison of coal IGCC with and without CO2capture and storage:shell gasification with standard vs. partial water quench. Energy Proc 1:1 (2009), 607–614.
21. [21] Xu, T., Zang, G., Chen, H., Dou, B., Tan, C., Co-production of hydrogen and electricity based on coal partial gasification with CO2capture. Int J Hydrogen Energy 37 (2012), 11805–11814.
22. [22] Ghosh, S., De, S., Exergy analysis of a cogeneration plant using coal gasification and solid oxide fuel cell. Int J Energy Res 30 (2006), 647–658.
23. [23] Duan, L., Sun, S., Yue, L., Qu, W., Yang, Y., Study on a new IGCC (integrated gasification combined cycle) system with CO2capture by integrating MCFC (molten carbonate fuel cell). Energy 87 (2015), 490–503.
24. [24] Adams, T.A., Barton, P.I., High efficiency power production from coal with carbon capture. AIChE J 50:12 (2010), 3120–3136.
25. [25] Seyitoglu, S.S., Dincer, I., Kilicarslan, A., Assessment of an IGCC based trigeneration system for power, hydrogen and synthesis fuel production. Int J Hydrogen Energy 41 (2016), 8168–8175.
26. [26] Ozcan, H., Dincer, I., Performance evaluation of an SOFC based trigeneration system using various gaseous fuels from biomass gasification. Int J Hydrogen Energy 40:24 (2015), 7798–7807.
27. [27] Karaca, H., Ceylan, K., Olcay, A., Catalytic dissolution of two Turkish lignites in tetralin under nitrogen atmosphere: effects of the extraction parameters on the conversion. Fuel 80 (2001), 559–564.
28. [28] Yagmur, E., Simsek, E.H., Aktas, Z., Togrul, T., Effect of demineralization process on the liquefaction of Turkish coals in tetralin with microwave energy: determination of particle size distribution and surface area. Fuel 84 (2005), 2316–2323.
29. [29] Bilgen, S., Kaygusuz, K., Sarı, A., Second law analysis of various types of coal and woody biomass in Turkey. Energy Sources 26 (2004), 1083–1094.
30. [30] Demirbas, A., Relationships proximate analysis results and higher heating values of lignites. Energy Sources Part A 30 (2008), 1876–1883.
31. [31] General Directorate of mineral research and exploration. Website: www.mta.gov.tr. [Accessed: 09.04.2015].
32. [32] U.S Department of energy, reportMajor environmental aspects of gasification-based power generation technologies final report, www.netl.gov. [Accessed: 23.11.2015].
33. [33] Salkuyeh, Y.K., Adams, T.A., Combining coal gasification, natural gas reforming, and external carbonless heat for efficient production of gasoline and diesel with CO2capture and sequestration. Energy Convers Manag 74 (2013), 492–504.
34. [34] Frey, H.C., Akunuri, N., Development and application of optimal design capability for coal gasification systems: performance, emissions, and cost of Texaco gasifier e based systems using Aspen. Technical report., 2001, Carnegie Mellon University.
35. [35] Dincer, I., Rosen, M.A., Exergy, energy, environment and sustainable development. 2007, Elsevier, Oxford.
36. [36] Kotas, T.J., The exergy method of thermal plant analysis. 1995, Krieger, Florida.