THERMAL SCIENCE

International Scientific Journal

NEW METHODOLOGICAL APPROACH IN TECHNO-ECONOMIC AND ENVIRONMENTAL OPTIMIZATION OF SUSTAINABLE ENERGY PRODUCTION

ABSTRACT
Among its other objectives and principles, sustainable development concept includes finding the optimal technical solutions that will enable exploitation of the resources of energy with minimal environmental damage. The main goal of this paper is to demonstrate methodological approach by using several operational research methods for selecting the optimal solution for complex, multipurpose power-plants construction concept problem with taking the sustainable development aspects into account. These methods are: ELECTRE I-IV, PROMETHEE I-IV, method of analytic hierarchy process (AHP) and linear programming. The aim of this research was to find out highly efficient, but relatively simple methods of defining environmental-friendly and socio-politically acceptable technical solution. The new methodology is developed and tested by case studies of determining the optimal choice for the construction of thermal and hydropower plants in the areas extremely exposed to conflict of economic, environmental and socio-political interest.
KEYWORDS
PAPER SUBMITTED: 2010-05-10
PAPER REVISED: 2010-08-29
PAPER ACCEPTED: 2010-09-03
DOI REFERENCE: https://doi.org/10.2298/TSCI100510007S
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2010, VOLUME 14, ISSUE Issue 3, PAGES [809 - 819]
REFERENCES
  1. ***, Technology Status of Thermal Power Plants in India and Opportunities in Renovation and Modernization, An OPET International action on ‘Refurbishment of Thermal Power Plants in India', DS Block, India Habitat Centre
  2. Erdem H.H., at al, Comparative Energetic and Exegetic Performance Analyses for Coal-fired Thermals Power Plants in Turkey, International Journal of Thermal Sciences, 48 (2009), pp 2179-2186
  3. ***, Environmental Assessment Report for Antalya - Turkey Power Plant, EN-CEV (Energy and Environmental Investment and Consulting Limited Company), Ankara, Turkey, 2007.
  4. ***, Viet Nam: Mong Duong Thermal Power Project, Summary Environmental Impact Assessment, Project Number: 39595, Prepared by the Government of Viet Nam for the Asian Development Bank (ADB), 2006.
  5. ***, Electricity Generation and Environmental Externalities (Case Studies), EIA - Energy Information Administration, Washington DC, 1995
  6. Wenisch, A., Mraz, G., New Nuclear Power Plant in Lithuania, Expert statement, Environmental Impact Assessment Program, 2008.
  7. Stevović, S., Milajić, A., Conceptual Optimisations in Designing of HPP by Linear Programming Method (in Serbian), Tehnika, 63 (2009), 2, pp. 9-14.
  8. Mesarović, M., Sustainable energy from biomass, Thermal Science, 5 (2001) 2, pp 5-32
  9. ***, Strategy of Development of Energy System in the Republic Serbia up to 2015 (in Serbian), Published by Ministry of Mining and Energy, Belgrade, 2005, Serbian Official Gazette, 44 (2005), Belgrade
  10. ***, Croatia in 21st Century: Energy Sector, Energy Sector Development Strategy of the Republic of Croatia (in Croatian), Official Gazette, 38/02
  11. ***, Power plants - Yesterday, Today, Tomorrow (in Bosnian), Toplane, Sarajevo, 2004
  12. ***, CARDS Project 2005 Facilitating and Implementing the Energy Community in South East Europe, Energy Community Report on Compliance with the Electricity Benchmarks, 2006, www.energy-community.org/pls/portal/docs/69826.PDF
  13. Oka, S., Sedmak A., Djurovic-Petrovic M., Energy Efficiency in Serbia - Research and Development Activity, Thermal Science, 10 (2009), 2, pp 5-32.
  14. ***, Directive 2001/77/EC of European Parliament and of the Council on the promotion of electricity produced from renewable energy sources in the internal electricity market, OJ, L283, September 27, 2003
  15. Mulavdić, E., Multi-Criteria Optimization of Construction Technology of Residential Building upon the Principles of Sustainable Development, Thermal Science, 9 (2005), 3, pp. 39-52
  16. Oka S., Conditions and measures necessary for biomass use in energy production (in Serbian), Biomass as renewable energy source, editors Oka S., Jovanovic Lj., Society of Thermal Engineers, Belgrade 1997.
  17. Sanaye, S., Hajabdollahi, H., Multi-objective optimization of rotary regenerator using genetic algorithm, International Journal of Thermal Sciences, 48 (2009), pp 1967-1977
  18. Cao, Z. et al, Application of an Effective Strategy for Optimizing the Design of Air Curtains for Open Vertical Refrigerated Display Cases, International Journal of Thermal Sciences, 49 (2010), pp 976-983
  19. Dallaire, J., Gosselin, L., da Silva, A.K., Conceptual Optimization of a Rotary Heat Exchanger With a Porous Core, International Journal of Thermal Sciences, 49 (2010), pp 454-462
  20. ***, The Construction Industry and the Environment, UNEP Industry and Environment Publication, 3, Vol. 19, (1996) pp 3-6, 29-32
  21. Stevović, S., Milajić, A., Simplex Method in the Function of Sustainable Development, Proceedings (Ed. A. Atanasov) 2nd International Conference Research People and Actual Tasks on Multidisciplinary Sciences, 10-12 June 2009, Lozenec, Bulgaria, pp. 196-200
  22. Opricović, S., A Compromise Solution in Water Resources Planning, Springer Netherlands, Water Resources Management, Vol. 23, No. 8/June 2009, pp 1549-1561
  23. Stevović S., Manigoda M., Construction and Exploatation of Hydropowerplants - Ecological Aspects (in Serbian), Proceedings, Conference on Energetics, Teslić, Bosnia, 2001.
  24. Stevović S., Marinković N., Mathematic Modelling of Ecological Aspects in Hydro energy (in Serbian), Proceedings Conference on Energetics, Teslić, Bosnia, 2001.
  25. Stevović S., Ecological Management in Hydroenergetics (in Serbian), Zadužbina Andrejevic, Beograd 2006.
  26. Stevović S., HP Paunci on the River Drina, (in Serbian), Project, Energoprojekt-Hidroinženjering, Beograd, 2000.
  27. Stevović S., Project of HP on the River Drina between towns Srbinje and Gorazde (in Serbian), Energoprojekt-Hidroinženjering, Beograd, 2000.
  28. Stevović S., Optimization and evaluation of Hydro Development, Proceedings, Millenium Congress on Energy and Environment, Clean Energy, Geneve, 2000, January 2000.
  29. Stevović S., Delphi Method in choice of Technical Optimum in Function of the Environmental Quality (in Serbian), Tehnika, Beograd 2008.
  30. Milajić, A., Linear Programming in Optimal Design of Reinforced Concrete Structures (in Serbian), Proceedings (Ed. N. Mladenović, D. Urošević) SYM-OP-IS 2009, 22-25 September 2009, Ivanjica, Serbia, pp. 165-168
  31. Praščević, Ž., Operational Research in Civil Engineering (in Serbian), Faculty of Civil Engineering, University of Belgrade, 1992.
  32. Schrijver, A., Theory of Linear and Integer Programming, John Wiley & Sons, London, 1998.
  33. Miettinen, P.; Hamalainen, R.P.: How to benefit from decision analysis in environmental life cycle assessment (LCA), European Journal of Operational Research, 102(2): 279-294, 1997
  34. Hobbs, B.F.; Meier, P.: Energy Decisions and the Environment: A Guide to the Use of Multicriteria Methods, Kluwer Academic Publishers, Dordrecht, 2000.
  35. ***, Multicriteria Decision Making: Advances in MCDM Models, Algorithm, Theory and Applications (Eds. Gal, T.; Stewart, T.J.; and Hanne, T.), Kluwer Academic Publishers, Dordrecht, 1999
  36. Stevović S., Advance in Energetic Efficiency in Conceptual Solution of Renewable Resources Usage in Function of Sustainable Development (in Serbian), Serbian Ministry of Science, Belgrade, 2008.
  37. Opricović, S., Multicriteria Optimization of Systems in Civil Engineering (in Serbian), Faculty of Civil Engineering, University of Belgrade, 1998.

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence