Integration and management of renewables into Total Sites with variable supply and demand

Computers and Chemical Engineering

Volumn 35, Issue 9, 2011, Pages 1815-1826

  Varbanov, Petar Sabev ^a   Klemeš, Jiří Jaromír ^a  

^a UNIVERSITY OF PANNONIA   (Hungary)

Author keywords

Energy management; Integration of renewables; Total Site Heat Cascade; Total Site Integration; Varying energy demand; Varying energy supply

Indexed keywords

CARBON FOOTPRINT; ENERGY DEMANDS; ENERGY SUPPLIES; HEAT INTEGRATION; NONISOTHERMAL; PRIMARY ENERGY MIX; PROCESS INTEGRATION; PROCESS SYSTEM ENGINEERING; RENEWABLE ENERGY SOURCE; RENEWABLES; SUPPLY AND DEMAND; TOTAL SITE HEAT CASCADE; TOTAL SITE INTEGRATION;

CARBON DIOXIDE; ENERGY CONVERSION; HEAT STORAGE; SOLAR ENERGY; WASTE HEAT;

ECONOMICS;

EID: 79959635723     PISSN: 00981354     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.compchemeng.2011.02.009     Document Type: Article

References (26)

1. Bance, P. (2008). Residential-scale fuel cell CHP: A better match for domestic loads. Cogeneration & On-Site Power Production, 9(3). Last accessed 04.07.2010. http://www.cospp.com/display_article/330132/122/CRTIS/none/none/1/Residential-scale-fuel-cell-CHP-a-better-match-for-domestic-loads/.
2. Dhole V.R., Linnhoff B. Total site targets for fuel, co-generation, emissions, and cooling. Computers and Chemical Engineering 1993, 17(Suppl.):S101-S109.
3. Foo D.C.Y., Chew Y.H., Lee C.T. Minimum units targeting and network evolution for batch heat exchanger network. Applied Thermal Engineering 2008, 28(16):2089-2099.
4. Friedler F. Process Integration, Modelling and Optimisation for Energy Saving and Pollution Reduction. Chemical Engineering Transactions 2009, 18:1-26.
5. Friedler F. Process Integration, Modelling and Optimisation for Energy Saving and Pollution Reduction. Applied Thermal Engineering 2010, 30(16):2270-2280.
6. Gogenko A.L., Anipko O.B., Arsenyeva O.P., Kapustenko P.O. Accounting for fouling in plate heat exchanger design. Chemical Engineering Transactions 2007, 12:207-212.
7. Hohmann, E. C. (1971). Optimum networks for heat exchange. PhD Thesis, University of Southern California, Los Angeles, United States.
8. Kemp I.C., Deakin A.W. The cascade analysis for energy and process integration of batch processes. Part 1. Calculation of energy targets. Chemical Engineering Research and Design 1989, 67:495-509.
9. Kemp I.C., Deakin A.W. The cascade analysis for energy and process integration of batch processes. Part 3. Network design and process scheduling. Chemical Engineering Research and Design 1989, 67:510-516.
10. Kemp I.C., Deakin A.W. The cascade analysis for energy and process integration of batch processes. Part 3. A case study. Chemical Engineering Research and Design 1989, 67:517-525.
11. Klemeš J., Dhole V.R., Raissi K., Perry S.J., Puigjaner L. Targeting and design methodology for reduction of fuel, power and CO2 on total sites. Applied Thermal Engineering 1997, 7:993-1003.
12. Klemeš J., Friedler F., Bulatov I., Varbanov P. Sustainability in the process industry: Integration and optimization 2010, McGraw Hill Companies Inc., USA.
13. Klemeš J., Linnhoff B., Kotjabasakis E., Zhelev T.K., Gremouti I., Kaliventzeff B., Heyen G., Maréchal F., Lebon M., Puigjaner L., Espuña A., Graells M., Santos G., Prokopakis G.J., Ashton G.J., Murphy N., Paor de A.M., Kemp I.C. Design and operation of energy efficient batch processes. Final report 1994, Commission of the European Communities, Brussels.
14. Linnhoff B., Flower J.R. Synthesis of heat exchanger networks. 1. Systematic generation of energy optimal networks. AIChE Journal 1978, 24(4):633-642.
15. Linnhoff B., Hindmarsh E. The pinch design method for heat exchanger networks. Chemical Engineering Science 1983, 38(5):745-763.
16. Linnhoff B., Mason D.R., Wardle I. Understanding heat exchanger networks. Computers and Chemical Engineering 1979, 3(1-4):295-302.
17. Linnhoff B., Townsend D.W., Boland D., Hewitt G.F., Thomas B.E.A., Guy A.R., Marsland R.H. A user guide to process integration for the efficient use of energy 1982, IChemE, Rugby, UK, Last edition 1994.
18. Linnhoff B., Vredeveld R. Pinch technology has come of age. Chemical Engineering Progress 1984, 80(7):33-40.
19. Masruroh N.A., Li B., Klemeš J. Life cycle analysis of a solar thermal system with thermochemical storage process. Renewable Energy 2006, 31(4):537-548.
20. Matsuda K., Hirochi Y., Tatsumi H., Shire T. Applying heat integration total site based pinch technology to a large industrial area in Japan to further improve performance of highly efficient process plants. Energy 2009, 34(10):1687-1692.
21. Nemet, A., Klemeš, J. J., & Varbanov, P. S. (2011). Methodology for maximising the use of renewables with variable availability. Computer Aided Chemical Engineering, 28.
22. Perry S., Klemeš J., Bulatov I. Integrating waste and renewable energy to reduce the carbon footprint of locally integrated energy sectors. Energy 2008, 33(10):1489-1497.
23. Shang Z., Kokossis A. A transhipment model for the optimisation of steam levels of total site utility system for multiperiod operation. Computers and Chemical Engineering 2004, 28(9):1673-1688.
24. Sharma A., Tyagi V.V., Chen C.R., Buddhi D. Review on thermal energy storage with phase change materials and applications. Renewable and Sustainable Energy Reviews 2009, 13:318-345.
25. Varbanov P., Perry S., Klemeš J., Smith R. Synthesis of industrial utility systems: Cost-effective de-carbonization. Applied Thermal Engineering 2005, 25(7):985-1001.
26. Weber R., Dorer V. Long-term heat storage with NaOH. Vacuum 2008, 82:708-716.