Preliminary experimental study of post-combustion carbon capture integrated with solar thermal collectors

Applied Energy

Volumn 185, Issue , 2017, Pages 1471-1480

  Wang, Fu ^a,b   Zhao, Jun ^a   Li, Hailong ^b,c   Deng, Shuai ^a   Yan, Jinyue ^a,c,d  

^a TIANJIN UNIVERSITY   (China)

^b Ningbo RX New Materials Tech Co   (China)

^c MÄLARDALEN UNIVERSITY   (Sweden)

^d ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

Author keywords

Dynamic response; Linear Fresnel reflector; Parabolic trough collector; Post combustion CO2 capture; Solar thermal energy

Indexed keywords

CARBON; CARBON DIOXIDE; COMBUSTION; DYNAMIC RESPONSE; REFLECTION; SOLAR COLLECTORS; SOLAR ENERGY; STEAM TURBINES; THERMAL ENERGY;

AMINE-BASED CHEMICAL ABSORPTIONS; LINEAR FRESNEL REFLECTOR (LFR); PARABOLIC TROUGH COLLECTORS; POST-COMBUSTION CARBON CAPTURES; POST-COMBUSTION CO; SOLAR THERMAL COLLECTOR; SOLAR THERMAL ENERGY; SOLAR THERMAL ENERGY COLLECTORS;

SOLAR HEATING;

ABSORPTION; CARBON DIOXIDE; CARBON SEQUESTRATION; COMBUSTION; EXPERIMENTAL STUDY; PERFORMANCE ASSESSMENT; SOLAR POWER; SOLAR RADIATION; SOLVENT; THERMAL POWER; TURBINE;

EID: 85003869014     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2016.02.040     Document Type: Article

References (35)

1. [1] IEA. World Energy Outlook, 2012. Paris: OECD/IEA.
2. [2] Yan, J., Carbon capture and storage (CCS). Appl Energy 148 (2015), A1–A6.
3. 2-capture options. Int J Green Energy 6:5 (2009), 512–526.
4. 2 capture options. Appl Energy 89:1 (2012), 303–314.
5. 2 capture. Appl Energy 90:1 (2012), 113–121.
6. 2 capture using reactive solvents in large pilot and demonstration plants. Int J Greenhouse Gas Control 40 (2015), 6–25.
7. 2 into enzyme accelerated solvents: from laboratory to pilot scale. Appl Energy 156 (2015), 676–685.
8. 2 capture in Huaneng Beijing coal-fired power station. Appl Energy 87 (2010), 3347–3354.
9. 2 capture technology. Energy Procedia 4 (2011), 1411–1418.
10. [10] Li, H., Ditaranto, M., Yan, J., Carbon capture with low energy penalty: supplementary fired natural gas combined cycles. Appl Energy 97 (2012), 164–169.
11. [11] Ying, Y., Hu, E.J., Thermodynamic advantages of using solar energy in the regenerative Rankine power plant. Appl Therm Eng 19 (1999), 1173–1180.
12. [12] Zhu, Y., Zhai, R., Zhao, M., et al. Evaluation methods of solar contribution in solar aided coal-fired power generation system. Energy Convers Manage 102 (2015), 209–216.
13. 2 capture using solar thermal energy. U.S. Patent Application 12/374,017. 2007-7-17.
14. [14] Parvareh, F., Sharma, M., Qadir, A., Milani, D., Khalilpour, R., Chiesa, M., et al. Integration of solar energy in coal-fired power plants retrofitted with carbon capture: a review. Renew Sustain Energy Rev 38 (2014), 1029–1044.
15. 2 capture. J Energy Power Eng 5 (2011), 195–208.
16. [16] Qadir, A., Mokhtar, M., Khalilpour, R., Milani, D., Vassallo, A., Chiesa, M., et al. Potential for solar-assisted post-combustion carbon capture in Australia. Appl Energy 111 (2013), 175–185.
17. [17] Mokhtar, M., Ali, M.T., Khalilpour, R., Abbas, A., Shah, N., Hajaj, A.A., et al. Solar-assisted post-combustion carbon capture feasibility study. Appl Energy 92 (2012), 668–676.
18. 2 capture. Int J Greenhouse Gas Control 9 (2012), 272–280.
19. 2-capture in a coal-fired power plant. Sol Energy 86:11 (2012), 3196–3204.
20. [20] Sharma, M., Parvareh, F., Abbas, A., Highly integrated post-combustion carbon capture process in a coal-fired power plant with solar repowering. Int J Energy Res 39:12 (2015), 1623–1635.
21. [21] Parvareh, F., Milani, D., Sharma, M., et al. Solar repowering of PCC-retrofitted power plants; solar thermal plant dynamic modelling and control strategies. Sol Energy 119 (2015), 507–530.
22. [22] Qadir, A., Sharma, M., Parvareh, F., et al. Flexible dynamic operation of solar-integrated power plant with solvent based post-combustion carbon capture (PCC) process. Energy Convers Manage 97 (2015), 7–19.
23. [23] Wang, F., Li, H., Zhao, J., Deng, S., Yan, J., Technical and economic analysis of integrating low-medium temperature solar energy into power plant. Energy Convers Manage, 2016, 10.1016/j.enconman.2016.01.037.
24. [24] Wang, F., Zhao, J., Li, H., Zhao, L., Yan, J., Experimental study of solar assisted post-combustion carbon capture. Energy Procedia 75 (2015), 2246–2252.
25. [25] Hilliard MD. A predictive thermodynamic model for an aqueous blend of potassium carbonate, piperazine, and monoethanolamine for carbon dioxide capture from flue gas [Ph.D. thesis]. The University of Texas at Austin; 2008.
26. [26] Fischer, S., Muller-Steinhagen, H., Collector test method under quasi-dynamic conditions according to the European Standard EN 12975-2. Sol Energy 76:1 (2004), 117–123.
27. [27] Rabensteiner, M., Kinger, G., Koller, M., Gronald, G., Hochenauer, C., Pilot plant study of ethylenediamine as a solvent for post combustion carbon dioxide capture and comparison to monoethanolamine. Int J Greenhouse Gas Control 27 (2014), 1–14.
28. [28] Mangalapally, H.P., Hasse, H., Pilot plant experiments for post combustion carbon dioxide capture by reactive absorption with novel solvents. Energy Procedia 4 (2011), 1–8.
29. 2 capture solvent and improvement using ion exchange resins. Int J Greenhouse Gas Control 37 (2015), 38–45.
30. 2 desorption from diethylenetriamine (DETA) solution in a stripper column packed with Dixon ring random packing. Fuel 136 (2014), 261–267.
31. [31] Chiu, L.F., Li, M.H., Heat capacity of alkanolamine aqueous solutions. J Chem Eng Data 44:6 (1999), 1396–1401.
32. 2 capture. Chem Eng J 264 (2015), 230–240.
33. 2 absorption in aqueous MEA solution with electrolyte NRTL model. Fluid Phase Equilib 311 (2011), 67–75.
34. 2 capture by reactive absorption: pilot plant description and results of systematic studies with MEA. Int J Greenhouse Gas Control 6 (2012), 84–112.
35. 2 Abscheidung aus Kohlekraftwerksrauchgasen (Master thesis). Vienna University of Technology; 2013.