Biomass District Energy Trigeneration Systems: Emissions Reduction and Financial Impact
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Biomass cogeneration is widely used for district heating applications in central and northern Europe. Biomass trigeneration on the other hand, constitutes an innovative renewable energy application. In this work, an approved United Nations Framework Convention on Climate Change baseline methodology has been extended to allow the examination of biomass trigeneration applications. The methodology is applied to a case study in Greece to investigate various environmental and financial aspects of this type of applications. The results suggest that trigeneration may lead to significant emissions reduction compared to using fossil fuels or even biomass cogeneration and electricity generation. The emissions reduction achieved may be materialized into a considerable revenue stream for the project, if traded through a trading mechanism such as the European Union Greenhouse Gas Emission Trading Scheme. A sensitivity analysis has been performed to compensate for the high volatility of the emission allowances’ value and the immaturity of the EU Trading Scheme, which prevent a reliable estimation of the related revenue. The work concludes that emission allowances trading may develop into one of the major revenue streams of biomass trigeneration projects, significantly increasing their financial yield and attractiveness. The impact on the yield is significant even for low future values of emission allowances and could become the main income revenue source of such projects, if emission allowances increase their value substantially. The application of trigeneration for district energy proves to lead to increased environmental and financial benefits compared to the cogeneration or electricity generation cases.
KeywordsTrigeneration Emissions trading Greenhouse gases Biomass District energy Economic analysis
- IPCC. (1996). IPCC guidelines for national greenhouse gas inventories: reference manual, table 1–32: estimated emission factors for US heavy duty diesel vehicles (p. 1.75). Retrieved April 28, 2006, from http://www.ipcc-nggip.iges.or.jp/public/gl/guidelin/ch1ref4.pdf.
- IPCC/TEAP. (2005). IPCC/TEAP special report: safeguarding the ozone layer and the global climate system—summary for policymakers (p. 194). Retrieved December 20, 2007, from http://www.mnp.nl/ipcc/docs/full-reports/SROC-FullVolumev2.pdf.
- Rentizelas, A. (2007) Supply chain optimization models: application in the case of energy exploitation of multiple biomass sources. Ph.D. Thesis, National Technical University of Athens.Google Scholar
- Rentizelas, A., Tolis, A. & Tatsiopoulos, I. P. (2006). Effect of greenhouse gas emissions trading on investment decisions for biomass-to-energy production. Paper presented at the Environmental Economics 2006 Conference, Mykonos, Greece.Google Scholar
- UNFCCC. (2006). Revision to the approved consolidated baseline methodology ACM0006: consolidated baseline methodology for grid-connected electricity generation from biomass residues. UN Framework Convention on Climate Change—CDM executive board, version 2 03, March 2006.Google Scholar
- Zhang, Z. (2000). Estimating the size of the potential market for the Kyoto flexibility mechanisms. Review of World Economics, 136, 491–521.Google Scholar