Implementation of heat storage and network water cooler for improvment of energy and economic performance of municipal heating plant with biomass fired cogeneration module
Abstract
Many fossil fuel fired municipal heating plants have been upgraded to cogeneration systems through installation of biomass fired cogeneration modules. This paper shows the effects of installation of the Organic Rankine Cycle (ORC) technology based module in the plant with coal fired water boilers. Current problems related to the operation of the integrated system are presented and discussed. Special attention is given to the volatility of main operational parameters that affects economic performance of the project. In search for improvement an installation of new equipment such as heat storage and district heating water cooler are proposed and examined. Mathematical simulation model and optimization algorithm for thermal energy storage capacity sizing was developed using the commercial software EBSILON® Professional. The model was calibrated and validated with real measurement data from the SCADA system of the plant. Results of simulations revealed potential annual financial benefits related to savings of chemical energy of fuels and selling excess electricity on the balancing market. The results of this simulation prove that proposed modifications of the technological system structure can be a good option for increasing investment profitability at the current level of fuel and energy prices.References
[1] EUROSTAT Statistics Explained. Online publication series. Renewable energy statistics. http://ec.europa.eu/eurostat/statistics-explained/index.php/Renewable_energy_statistics; last access: 04.05.2018
[2] Tartière T.: ORC Market: A World Overview. Web project available at http://orc-world-map.org/analysis.html
[3] Tartière T., Astolfi M.: A World Overview of the Organic Rankine Cycle Market. Proceedings of the IV International Seminar on ORC Power Systems, ORC2017, 13-15 September 2017, Milano, Italy. Energy Procedia 129 (2017), pp. 2–9.
[4] Commission Regulation (EU) No 651/2014 of 17 June 2014 declaring certain categories of aid compatible with the internal market in application of Articles 107 and 108 of the Treaty Text with EEA relevance. https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=celex:32014R0651
[5] Lenz V.: Woody bioenergy in Germany –utilisation and perspectives. Proceedings of the International Bioenergy Conferences in Japan, 24thMay 2017, Nagano.
[6] Obernberger I., Thek G.: Techno-economic evaluation of selected decentralized CHP applications based on biomass combustion in IEA partner countries. Final report. BIOS Bioenergiesysteme GmbH. IEA 32 Task 32 project performed in co-operation with the Institute of Resource Efficient and Sustainable Systems, Graz University of Technology. Graz, March 2004.
[7] Noussan M., Abdin G.C., Poggio A., Roberto R.: Biomass-fired CHP and heat storage system simulations in existing district heating systems. Applied Thermal Engineering 71,2014, pp. 729-735.
[8] Tańczuk M., Ulbrich R.: Implementation of a biomass-fired co-generation plant supplied with an ORC (Organic Rankine Cycle) as a heat source for small scale heat distribution system - A comparative analysis under Polish and German conditions. Energy 62, 2013, pp. 132-141.
[9] Kalina J.: Equipment sizing in a coal-fired municipal heating plant modernisation project with support for renewable energy and cogeneration technologies. Energy Conversion and Management,2014, pp. 1050-1058.
[10] Świerzewski M., Gładysz P.: Biomass-Fired CHP Plants - Energy, Economic And Ecological Assessment - Poland Case Study. Proceedings of the 4th International Conference on Contemporary Problems of Thermal Engineering CPOTE 2016, 14-16 September 2016, Katowice, Poland.
[11] STEAG Energy Services GmbH. Ebsilon Professional software. May, 2018. http://www.steag-systemtechnologies.com/ebsilon_professional.html
[12] www.mpec.bialystok.pl/ nfosigw.gov.pl/bialystok.nasze
[2] Tartière T.: ORC Market: A World Overview. Web project available at http://orc-world-map.org/analysis.html
[3] Tartière T., Astolfi M.: A World Overview of the Organic Rankine Cycle Market. Proceedings of the IV International Seminar on ORC Power Systems, ORC2017, 13-15 September 2017, Milano, Italy. Energy Procedia 129 (2017), pp. 2–9.
[4] Commission Regulation (EU) No 651/2014 of 17 June 2014 declaring certain categories of aid compatible with the internal market in application of Articles 107 and 108 of the Treaty Text with EEA relevance. https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=celex:32014R0651
[5] Lenz V.: Woody bioenergy in Germany –utilisation and perspectives. Proceedings of the International Bioenergy Conferences in Japan, 24thMay 2017, Nagano.
[6] Obernberger I., Thek G.: Techno-economic evaluation of selected decentralized CHP applications based on biomass combustion in IEA partner countries. Final report. BIOS Bioenergiesysteme GmbH. IEA 32 Task 32 project performed in co-operation with the Institute of Resource Efficient and Sustainable Systems, Graz University of Technology. Graz, March 2004.
[7] Noussan M., Abdin G.C., Poggio A., Roberto R.: Biomass-fired CHP and heat storage system simulations in existing district heating systems. Applied Thermal Engineering 71,2014, pp. 729-735.
[8] Tańczuk M., Ulbrich R.: Implementation of a biomass-fired co-generation plant supplied with an ORC (Organic Rankine Cycle) as a heat source for small scale heat distribution system - A comparative analysis under Polish and German conditions. Energy 62, 2013, pp. 132-141.
[9] Kalina J.: Equipment sizing in a coal-fired municipal heating plant modernisation project with support for renewable energy and cogeneration technologies. Energy Conversion and Management,2014, pp. 1050-1058.
[10] Świerzewski M., Gładysz P.: Biomass-Fired CHP Plants - Energy, Economic And Ecological Assessment - Poland Case Study. Proceedings of the 4th International Conference on Contemporary Problems of Thermal Engineering CPOTE 2016, 14-16 September 2016, Katowice, Poland.
[11] STEAG Energy Services GmbH. Ebsilon Professional software. May, 2018. http://www.steag-systemtechnologies.com/ebsilon_professional.html
[12] www.mpec.bialystok.pl/ nfosigw.gov.pl/bialystok.nasze
Published
2019-06-03
How to Cite
ŚWIERZEWSKI, Mateusz; KALINA, Jacek.
Implementation of heat storage and network water cooler for improvment of energy and economic performance of municipal heating plant with biomass fired cogeneration module.
Journal of Power Technologies, [S.l.], v. 99, n. 2, p. 131–141, june 2019.
ISSN 2083-4195.
Available at: <https://papers.itc.pw.edu.pl/index.php/JPT/article/view/1455>. Date accessed: 24 apr. 2024.
Issue
Section
Contemporary Problems of Thermal Engineering 2018 Gliwice
Keywords
ORC;cogeneration;biomass combustion; thermal energy storage; network water cooler
Authors who publish with this journal agree to the following terms:
- Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
- Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).
