Heat integration of natural gas combined cycle power plant integrated with post-combustion CO2 capture and compression

Fuel

Volumn 151, Issue , 2015, Pages 110-117

  Luo, Xiaobo ^a   Wang, Meihong ^a   Chen, Jian ^b  

^a UNIVERSITY OF HULL   (United Kingdom)

^b TSINGHUA UNIVERSITY   (China)

Author keywords

CO2 compression; Heat integration; NGCC; Post combustion carbon capture; Process modelling

Indexed keywords

CARBON; CARBON CAPTURE; CLIMATE CHANGE; COMBINED CYCLE POWER PLANTS; COMBUSTION; EFFICIENCY; EXHAUST GAS RECIRCULATION; FOSSIL FUEL POWER PLANTS; INTEGRATION; NATURAL GAS; SHOCK WAVES;

EXHAUST GAS RECIRCULATION (EGR); GLOBAL CLIMATE CHANGES; HEAT INTEGRATION; NATURAL GAS COMBINED CYCLES; NGCC; POST-COMBUSTION CARBON CAPTURES; PROCESS MODELLING; SHOCK WAVE COMPRESSION;

CARBON DIOXIDE;

EID: 84936760045     PISSN: 00162361     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.fuel.2015.01.030     Document Type: Article

References (56)

1. IEA. Energy Technology Perspectives. Paris: International Energy Agency; 2012.
2. 2 Proc Inst Mech Eng, Part A: J Power Energy 217 1 2003 1 7
3. BP p.l.c. BP Statistical Review of World Energy 2014. [cited 2014 16th September]. < http://www.bp.com/content/dam/bp/pdf/Energy-economics/statistical-review-2014/BP-statistical-review-of-world-energy-2014-full-report.pdf.
4. IEA. Energy Technology Perspectives. Paris: International Energy Agency; 2010.
5. 2 capture with chemical absorption: a state-of-the-art review Chem Eng Res Des 89 9 2011 1609 1624
6. 2 capture at gas fired power plants. International Energy Agency; 2012.
7. DECC of UK. CCS cost reduction task force: final report; 2013 [cited 16.09.14] < https://www.gov.uk/government/publications/ccs-cost-reduction-task-force-final-report >.
8. 2 capture Science 325 5948 2009 1652 1654
9. 2 capture Int J Greenhouse Gas Control 12 0 2013 213 219
10. 2 capture Energy 32 1 2007 10 24
11. 2 capture: an optimisation study using dynamic process models Int J Greenhouse Gas Control 13 2013 44 58
12. 2 capture plant integrated with a commercial scale combined cycle gas turbine (CCGT) power plant Appl Therm Eng 2014 http://dx.doi.org/10.1016/j.applthermaleng.2014.01.014(0)
13. 2 capture from power plants Part I. A parametric study of the technical performance based on monoethanolamine Int J Greenhouse Gas Control 1 1 2007 37 46
14. 2 transport pipeline network Appl Energy 132 2014 610 620
15. 2 sequestration. Thermodynamics and safety problems Energy Convers Manage 76 2013 665 673
16. K. Jordal, P.A.M. Ystad, R. Anantharaman, A. Chikukwa, and O. Bolland Design-point and part-load considerations for natural gas combined cycle plants with post combustion capture Int J Greenhouse Gas Control 11 2012 271 282
17. R. Darby Chemical engineering fluid mechanics 2001 CRC PressI Llc
18. 2 compression using supersonic shock wave technology 2009 Ramgen Power Systems
19. J.P. Ciferno, T.E. Fout, A.P. Jones, and J.T. Murphy Capturing carbon from existing coal-fired power plants Chem Eng Prog 105 4 2009 33 41
20. Company GE. GateCycle Software 2014 [cited 10.09.14]. < http://www.ge-mcs.com/en/bently-nevada-software/320-performance/1831-siweb-pl655.html >.
21. 2 capture integration Int J Greenhouse Gas Control 19 2013 396 405
22. M. Karimi, M. Hillestad, and H.F. Svendsen Natural gas combined cycle power plant integrated to capture plant Energy Fuels 26 3 2012 1805 1813
23. Inc. T. Gas turbine combined cycle design program to create cycle heat balance and physical equipment needed to realize it 2014 [cited 10.09.14]. < http://www.thermoflow.com/combinedcycle-GTP.html >.
24. Aspen Technology I. Optimize chemical process with Aspen Plus® 2014 [10.09.14]. < http://www.aspentech.com/products/aspen-plus.aspx >.
25. 2 capture with aqueous monoethanolamine solution Ind Eng Chem Res 48 20 2009 9233 9246
26. Process Systems Enterprise Limited. gPROMS ModelBuilder; 2014 [cited 10.09.14]. < http://www.psenterprise.com/modelbuilder.html >.
27. 2 chemical absorption process for coal-fired power plants Fuel 89 10 2010 2791 2801
28. 2 capture plant Int J Greenhouse Gas Control 9 2012 428 445
29. 2 capture absorption column Int J Greenhouse Gas Control 12 2013 247 258
30. 2 capture and exhaust gas recirculation Proc Inst Mech Eng, Part E: J Process Mech Eng 227 2 2013 89 105
31. D.Y. Peng, and D.B. Robinson A new two-constant equation of state Ind Eng Chem Fundam 15 1 1976 59 64
32. E. Neau, O. Hernández-Garduza, J. Escandell, C. Nicolas, and I. Raspo The Soave, Twu and Boston-Mathias alpha functions in cubic equations of state: Part I. Theoretical analysis of their variations according to temperature Fluid Phase Equilib 276 2 2009 87 93
33. E. Neau, I. Raspo, J. Escandell, C. Nicolas, and O. Hernández-Garduza The Soave, Twu and Boston-Mathias alpha functions in cubic equations of state. Part II. Modeling of thermodynamic properties of pure compounds Fluid Phase Equilib 276 2 2009 156 164
34. Aspen-Tech Aspen physical property system: physical property methods 2012 Aspen Technology, Inc. Burlington, USA
35. E.Y. Kenig, R. Schneider, and A. Górak Reactive absorption: optimal process design via optimal modelling Chem Eng Sci 56 2 2001 343 350
36. Dugas RE. Pilot plant study of carbon dioxide capture by aqueous monoethanolamine. MSE Thesis, University of Texas at Austin; 2006.
37. C.C. Chen, and Y. Song Generalized electrolyte-NRTL model for mixed-solvent electrolyte systems AIChE J 50 8 2004 1928 1941
38. W.G. Whitman The two film theory of gas absorption Int J Heat Mass Transf 5 5 1962 429 433
39. 2 capture for coal-fired power plants through dynamic modelling and simulation Fuel 101 2012 115 128
40. R.K. Sinnott Chemical engineering design SI ed. 2009 Elsevier
41. Carbon Capture Journal. Internals for carbon capture plants; 2013 [cited 16.09.14]. < http://www.carboncapturejournal.com/news/internals-for-carbon-capture-plants/3349.aspx?Category=featured >.
42. Sulzer Ltd. Putting a chill on global warming; 2014 [cited 16.09.14]. < http://www.sulzer.com/en/-/media/Documents/Cross-Division/STR/2008/2008-3-4-Sulzer-e.pdf >.
43. Koch-Glitsch, LP. Carbon capture; 2014 [cited 16.09.14]. < http://www.koch-glitsch.com/masstransfer/pages/carbon-capture.aspx >.
44. H.M. Kvamsdal, G. Haugen, and H.F. Svendsen Flue-gas cooling in post-combustion capture plants Chem Eng Res Des 89 9 2011 1544 1552
45. 2 capture and wind Energy 36 12 2011 6806 6820
46. 2 capture ready fossil plants with post-combustion capture. Part 1: requirements for supercritical pulverized coal plants using solvent-based flue gas scrubbing Proc Inst Mech Eng, Part A: J Power Energy 223 3 2009 213 226
47. 2 capture J Eng Gas Turbines Power 133 1 2011 011703
48. 2 capture K. Andrzej, T. Ilkka, Computer aided chemical engineering vol. 32 2013 Elsevier 187 192
49. 2-capture; 2003.
50. 2 capture processes Comput Chem Eng 31 5-6 2007 445 455
51. 2 sequestration Energy Convers Manage 47 6 2006 702 715
52. 2 transport technologies for a group of various size industries Int J Greenhouse Gas Control 12 2013 341 350
53. 2 transport pipeline design and operation - case study for the humber region in the UK P.S.V. Jiří Jaromír Klemeš, L. Peng Yen, Computer aided chemical engineering vol. 33 2014 Elsevier 1633 1638
54. 2 compression systems on the compressor power required for a pulverized coal-fired power plant in post-combustion carbon dioxide sequestration Archive Mech. Eng. 59 3 2012 343 360
55. Ramgen Power Systems, LLC. Shock Compression - what is it? 2008 [cited 20.09.14]. < http://www.ramgen.com/tech-shock-compression.html >.
56. R.K. Shah, and D.P. Sekulic Fundamentals of heat exchanger design 2003 John Wiley & Sons