Study of integration of cryogenic air energy storage and coal oxy-fuel combustion through modelling and simulation

Computer Aided Chemical Engineering

Volumn 33, Issue , 2014, Pages 1537-1542

  Pacheco, Kelvin André ^a   Li, Yongliang ^b   Wang, Meihong ^a  

^a UNIVERSITY OF HULL   (United Kingdom)

^b UNIVERSITY OF LEEDS   (United Kingdom)

Author keywords

Carbon Capture; Coal Oxy fuel Combustion; Cryogenic Energy Storage; Process Integration; Process Simulation; Thermal Energy Storage

Indexed keywords

EID: 84902998037     PISSN: 15707946     EISSN: None     Source Type: Book Series    
DOI: 10.1016/B978-0-444-63455-9.50091-X     Document Type: Chapter

References (12)

1. 2 capture 2009, Cranfield University, UK, MSc Dissertation.
2. Smith A.R., Klosek J. A review of air separation technologies and their integration with energy conversion processes. Fuel Processing Technology 2001, 70:115-134.
3. Aspentech Aspen Plus Tutorial: Getting started modelling process with solids 2009, Aspentech Plc, USA, Version Number: V7.1.
4. Ameel B., T'Joen C., De Kerpel K., De Jaeger P., Huisseune H., Van Belleghem M., De Paepe M. Thermodynamic analysis of energy storage with a liquid air Rankine cycle. Applied Thermal Engineering 2013, 52:130-140.
5. Dubar C., Forcey T., Humphreys V., Schmidt H. A competitive offshore LNG scheme utilising a gravity base structure and improved nitrogen cycles 1998, Institute of Gas Technology, Perth, WA, Australia.
6. DTI Meeting the Energy Challenge: a White Paper on Energy 2007, The Stationery Office, UK Government.
7. Chen H., Cong T.N., Yang W., Tan C., Li Y., Ding Y. Progress in electrical energy storage system: a critical review. Progress in Natural Science 2009, 19:291-312.
8. Chen H., Ding Y., Peters T., Berger F. Energy Storage and Generation 2009, US Patent 2009/0282840 A1.
9. Hu Y. CO2 capture from oxy-fuel combustion power plants, Licentiate dissertation, Stockholm 2011, KTH Royal Institute of Technology, Sweden.
10. Li Y., Chen H., Zhang X., Tan C., Ding Y. Renewable energy carriers: Hydrogen or liquid air/nitrogen?. Applied Thermal Energy 2010, 30:1985-1990.
11. Li Y., Cheng H., Ding Y. Fundamentals and applications of cryogen as a thermal energy carrier: A critical assessment. International Journal of Themal Sciences 2010, 49:941-949.
12. Li Y., Wang X., Ding Y. An optimal design methodology for large-scale gas liquefaction. Applied Energy 2012, 99:484-490.