Plantwide control and operating strategy for air separation unit in oxy-combustion power plants

Energy Conversion and Management

Volumn 106, Issue , 2015, Pages 782-792

  Jin, Bo ^a   Su, Mingze ^a   Zhao, Haibo ^a   Zheng, Chuguang ^a  

^a HUAZHONG UNIVERSITY OF SCIENCE AND TECHNOLOGY   (China)

Author keywords

Air separation unit; Dynamic simulation; Flexible operations; Oxy combustion; Plantwide control

Indexed keywords

COMBUSTION; COMPUTER SIMULATION; ENERGY CONSERVATION; LIQUEFIED GASES; SEPARATION;

AIR SEPARATION UNIT; CONTROL STRUCTURE; FLEXIBLE OPERATION; INTEGRATED PATTERN; OPERATING FLEXIBILITY; OPERATING STRATEGY; OXY COMBUSTIONS; PLANTWIDE CONTROL;

QUALITY CONTROL;

EID: 84944743377     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2015.09.077     Document Type: Article

References (38)

1. J. Xiong, H. Zhao, and C. Zheng Exergy analysis of a 600 MWe oxy-combustion pulverized-coal-fired power plant Energy Fuels 25 2011 3854 3864
2. B. Jin, H. Zhao, C. Zou, and C. Zheng Comprehensive investigation of process characteristics for oxy-steam combustion power plants Energ Convers Manage 99 2015 92 101
3. A. Smith, and J. Klosek A review of air separation technologies and their integration with energy conversion processes Fuel Process Technol 70 2001 115 134
4. A. Darde, R. Prabhakar, J.-P. Tranier, and N. Perrin Air separation and flue gas compression and purification units for oxy-coal combustion systems Energy Proc 1 2009 527 534
5. J.-P. Tranier, R. Dubettier, A. Darde, and N. Perrin Air separation, flue gas compression and purification units for oxy-coal combustion systems Energy Proc 4 2011 966 971
6. Dimitri G. Oxygen production for oxyfuel power plant-state of development. Workshop on oxyfuel-FBC technology; 2012.
7. J.A. Mandler Modelling for control analysis and design in complex industrial separation and liquefaction processes J Process Contr 10 2000 167 175
8. B. Jin, H. Zhao, and C. Zheng Dynamic modeling and control for pulverized-coal-fired oxy-combustion boiler island Int J Greenh Gas Control 30 2014 97 117
9. B. Jin, H. Zhao, and C. Zheng Dynamic simulation for mode switching strategy in a conceptual 600 MWe oxy-combustion pulverized-coal-fired boiler Fuel 137 2014 135 144
10. Y. Hu, X. Li, H. Li, and J. Yan Peak and off-peak operations of the air separation unit in oxy-coal combustion power generation systems Appl Energ 112 2013 747 754
11. N. Perrin, R. Dubettier, F. Lockwood, J. Tranier, C. Bourthy-Weber, and M. Devaux Oxycombustion for carbon capture on coal power plants and industrial processes: advantages, innovative solutions and key projects Energy Proc 37 2013 1389 1404
12. B. Roffel, B. Betlem, and J. De Ruijter First principles dynamic modeling and multivariable control of a cryogenic distillation process Comput Chem Eng 24 2000 111 123
13. R. Cornelissen, and G. Hirs Exergy analysis of cryogenic air separation Energ Convers Manage 39 1998 1821 1826
14. J.O. Trierweiler, and S. Engell A case study for control structure selection: air separation plant J Process Contr 10 2000 237 243
15. D.R. Vinson Air separation control technology Comput Chem Eng 30 2006 1436 1446
16. Z. Xu, J. Zhao, X. Chen, Z. Shao, J. Qian, L. Zhu, and et al. Automatic load change system of cryogenic air separation process Sep Purif Technol 81 2011 451 465
17. 2 capture Fuel Process Technol 92 2011 1685 1695
18. L. Van der Ham, and S. Kjelstrup Exergy analysis of two cryogenic air separation processes Energy 35 2010 4731 4739
19. L. Van der Ham Improving the exergy efficiency of a cryogenic air separation unit as part of an integrated gasification combined cycle Energ Convers Manage 61 2012 31 42
20. P. Mahapatra, and B.W. Bequette Design and control of an elevated-pressure air separations unit for IGCC power plants in a process simulator environment Ind Eng Chem Res 52 2012 3178 3191
21. Mahapatra P, Zitney SE, Bequette BW. Dynamic maximization of oxygen yield in an elevated-pressure air separation unit using multiple model predictive control. In: Proc of 10th IFAC international symposium on dynamics and control of process systems (DYCOPS 2013), Mumbai, India; 2013.
22. K. Roh, and J.H. Lee Control structure selection for the elevated-pressure air separation unit in an IGCC power plant: self-optimizing control structure for economical operation Ind Eng Chem Res 53 2014 7479 7488
23. 2 capture Int J Greenh Gas Control 5 2011 S194 S203
24. C. Fu, and T. Gundersen Recuperative vapor recompression heat pumps in cryogenic air separation processes Energy 59 2013 708 718
25. C. Fu, and T. Gundersen Using exergy analysis to reduce power consumption in air separation units for oxy-combustion processes Energy 44 2012 60 68
26. 2 capture Chem Eng Trans 29 2012
27. M.B. Toftegaard, J. Brix, P.A. Jensen, P. Glarborg, and A.D. Jensen Oxy-fuel combustion of solid fuels Prog Energ Combust Sci 36 2010 581 625
28. Stone BB, McDonald DK, Zadiraka AJ. Oxy-combustion coal fired boiler and method of transitioning between air and oxygen firing. Google patents; 2009.
29. Pourchot T, Granier F, Goloubevb D, Alekseev A. Oxy-combustion: an ASU integration option and improved operation flexibility. In: 3rd Oxyfuel combustion conference; 2013.
30. 2 capture from power plant. IEA greenhouse gas R&D programme; 2005.
31. 2 capture Energy Proc 4 2011 637 644
32. Dimitri G, Alexander A, Thierry P, François G. Integration of ASU in process of power generation. In: 3rd Oxyfuel Combustion conference; 2013.
33. 2 compression and purification unit in oxy-combustion power plants Energy 83 2015 416 430
34. Aspen Technology Inc. Aspen dynamics™ 11.1 user guide; 2001.
35. W.L. Luyben Plantwide dynamic simulators in chemical processing and control 2002 CRC Press
36. S. Skogestad Control structure design for complete chemical plants Comput Chem Eng 28 2004 219 234
37. M.L. Luyben, B.D. Tyreus, and W.L. Luyben Plantwide control design procedure AIChE J 43 1997 3161 3174
38. Beysel G. Enhanced cryogenic air separation: a prove process applied to oxyfuel future prospects. In: 1st Oxyfuel combustion conference; 2009.