Abstract
In order to assess the economic and ecological effects of inter-company energy supply concepts, an optimising model integrating investment and longterm production planning has been developed. The model represents the energy production of companies on a very disaggregated level taking into account different resources, energy carriers and production processes. This model has been applied to five industrial companies to analyse the economic and ecological implications resulting from investments in inter-company energy supply concepts. Existing technologies as well as possible investment options have been assessed by a techno-economic analysis taking into account company specific circumstances. In addition, the new German combined heat and power law has been modelled in detail, because the supplementary payments legally established in this law may effect energy go supply concepts in a considerable way. Computational results show the installation of a combined cycle power plant adapted to the specific conditions of the case at hand would be the most promising option to fulfil the future energy demand of the companies involved.
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References
Anderson D (1972) Models for determining least-cost investments in electricity supply. Bell Journal of Economics: 3: 267–299
Aspen (1994) Aspen plusTM getting started. Harvard University Press, Cambridge, MA
Ayres RU (1999) The second law, the fourth law, recycling and limits to growth. Ecological Economics 29: 473–483
Bardouille P, Koubsky J (2000) Incorporating sustainable development considerations into the energy sector decision making: Malmö Flintränen district heating facility case study. Energy Policy 28: 689–711
Blok K, de Jager D, Hendriks C (2001) Economie evaluation of sectoral emission reduction objectives for climate change. Study on behalf of the European Commission, http://europa.eu.int/comm/environment/enveco/climate_change/sectoral_objectives.htm
Boeddicker D (1997) Thermodynamische und energiewirtschaftliche Bewertung eines Kombikraftswerks mit integrierter Kohlevergasung und CO2-Rezyklierung. VDI-Verlag, Düsseldorf
Brooke A, Kendrick D, Meeraus A (1988) GAMS — A user’s guide. Scientific Press, Redwood City
Caramanis MC (1983) Electricity generation expansion planning in the eighties: requirements and available analysis tools, energy models and studies, pp 541–562. North-Holland, Amsterdam New York Oxford
Charnes A, Cooper W, Miller H (1959) Application of linear programming to financial budgeting and the costing of funds. The Journal of Business 32: 20–46
Cote RP, Cohen-Rosenthal E (1998) Designing eco-industrial parks: a synthesis of some experiences. Journal of Cleaner Production 6: 181–188
Dantzig GB, Wolfe P (1960) Decomposition principle for linear programme. Operation Research 48: 101–111
Erkman S (1997) Industrial ecology: an historical view. Journal of Cleaner Production 5 (1–2): 1–10
Forum für Energiemodelle und Energiewirtschaftliche Systemanalysen (1999) Energiemodelle zum Klimaschutz in Deutschland: Strukturelle und gesamtwirtschaftliche Auswirkungen aus nationaler Perspektive. Physica-Verlag, Heidelberg
Fichtner W, Frank M, Rentz O (2000) Entwicklung eines Instrumentariums zur Analyse ökonomischer und ökologischer Potentiale bei der Vernetzung von Energieflüssen. In: Fleischmann B, Lasch R, Derigas U, Domschke W, Rieder U (eds) Gesellschaft für Operations Research e.V. (GOR). Operations Research Proceedings 2000, pp 439–444. Springer, Berlin Heidelberg New York
Futterer E, Munsch M (1990) Flow-Sheeting-Programme für die Prozesssimulation. Chem-Ing-Tech 62(1): 9–16
Frank M, Göbelt M, Fichtner W, Rentz O (2001) Optimierende Energie-und Stoffflussmodelle für die strategische Planung von betriebsübergreifenden Energieversorgungssystemen im liberalisierten Energiemarkt. In: VDI-GET (eds) Betriebliches Energiemanagement 2001. VDI-Verlag, Düsseldorf
Garrett D (1989) Chemical engineering economics. Van Nostrand Reinhold, New York
Gately (1970) Investment planning for the electric power industry: an integer programming approach. Research Report 7035, Dept. of Economics, University of Western Ontario
Georgescu-Roegen N (1971) The entropy law and the economic process. Harvard University Press, Cambridge, MA
Göbelt M, Fichtner W, Wietschel M, Rentz O (2000) Development and application of an optimising energy and material flow model for strategic planning of energy utilities. Conference Proceedings of the 5th Conference of Asian-Pacific Operational Research Societies within IFORS, Singapore
Gonzalez-Monroy L, Cordoba A (2002) Financial costs and environment impact optimization of the energy supply systems. International Journal of Energy Research 26 (1): 27–44
Hafkamp WA (1984) Economic-environmental modelling in a national-regional system. North-Holland, Amsterdam New York Oxford
International Atomic Energy Agency et al. (1995) Computer tools for comparative assessment of electricity generation options and strategies. DECADES Project Series Publication, Vienna
Kaluza B, Blecker Th, Bischof Ch (1999) Networks — a cooperative approach to environmental management. University of Klagenfurt, Institute for Economics
Korhonen J, Savolainen I (2001) Cleaner energy production in industrial recycling networks. Eco-Management and Auditing 8 (3): 144–153
Lev B (ed) (1983) Energy models and studies. North-Holland, Amsterdam New York Oxford
Nouweland A, Borm P, Brouwers W, Bruinderink R, Tijs S (1996) A game theoretic approach to problems in telecommunication. Management Science 42 (2): 35–47
Nurminski E, Balabanov T (1983) Decomposition of a large-scale energy model. Large Scale System 4: 295–308
Prekopa A (1995) Stochastic programming. Kluwer, Dordrecht
Song YH (ed) (1999) Modem optimisation techniques in power systems. Kluwer, Dordrecht
Stadtler H, Kilger C (2000) Supply chain management and advanced planning. Springer, Berlin Heidelberg New York
Weinhardt Ch, Zuber P, Göbelt M, Fichtner W, Wietschel M, Rentz O (2000) A competitionmodel for the electricity sector: from an or approach to a multi-agent system. In: Urban Ch (ed) Workshop 2000 — Agent-based simulation, pp 63–68. SCS Europe, Ghent
Wietschel M (2000) Produktion und Energie: Planung und Steuerung industrieller Energie-und Stoffströme. Habilitationsschrift, TH Karlsruhe. Lang, Frankfurt a. M. et al.
World Commission on Environment and Development (1987) Our common future. Oxford University Press, Oxford
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Fichtner, W., Wietschel, M., Rentz, O. (2002). Long term planning of inter-company energy supply concepts. In: Haasis, HD., Spengler, T. (eds) Produktion und Umwelt. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-17036-2_14
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DOI: https://doi.org/10.1007/978-3-642-17036-2_14
Publisher Name: Springer, Berlin, Heidelberg
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