Modeling of Integrated Energy Supply Systems: Main Principles, Model, and Applications
Publication: Journal of Energy Engineering
Volume 143, Issue 5
Abstract
Energy systems including electricity, heat/cooling, and gas supply systems represent a very important part of the infrastructure in Russia. This paper presents a general framework of integrated energy systems. Elements of the concept of integrated energy systems are suggested. The explanation of the concept elements is given as a three-layer structure of integrated energy systems in three dimensions. The problems of integrated control of electric and heat networks deal with issues of combined calculation of operating conditions of the electric and heat networks integrated in the intelligent energy supply system. A mathematical description of the problems is presented. The results of two illustrative case studies are shown and explained. The first case study represents research on an emergency situation at the supergrid level of the energy system layers after an accident on a pipeline of the gas transportation network. The second case study represents research of interdependency of power and heat supply minigrids in emergency conditions on the example of a city district. Preferable future work is discussed.
Get full access to this article
View all available purchase options and get full access to this article.
References
Almassalkhi, M., and Hiskens, I. (2011). “Optimization framework for the analysis of large-scale networks of energy hubs.” Proc., 17th Power System Computation Conf., Vol. 2, Curran Associates, Inc., Red Hook, NY, 1124–1130.
Arnold, M., and Andersson, G. (2008). “Decomposed electricity and natural gas optimal power flow.” Proc., 16th Power System Computation Conference, Vol. 1, Curran Associates, Inc., Red Hook, NY, 654–660.
Averaynov, V. K., Karasevich, A. M., and Fedyaev, A. V. (2008). “Системы малой энергетики: современное состояние и перспективы развития [Small-scale energy systems: Current state and prospects for expansion].” Strahovoe Revju, Moscow (in Russian).
Basak, P., Choudhury, S., Chowdhury, S. P., and Holder nee Dey, S. (2012). “Automated demand side management (ADSM) strategy of microgrid.” Proc., 2012 IEEE Int. Conf. on Power System Technology (POWERCON 2012), Curran Associates, Inc., Red Hook, NY, 1231–1236.
Chaudry, M., Jenkins, N., and Strbac, G. (2008). “Multi-time period combined gas and electricity network optimization.” Electr. Power Syst. Res., 78(7), 1265–1279.
Chiang, C. L., and Lin, S. Z. (2012). “Improved particle swarm optimization for economic dispatch of combined heat and power systems.” Int. Conf. on Power and Energy Systems. Lecture Notes in Information Technology, Hong Kong.
Costanzo, G. T., Zhu, G., Anjos, M. F., and Savard, G. (2012). “A system architecture for autonomous demand side load management in smart buildings.” IEEE Trans. Smart Grid, 3(4), 2157–2165.
Dolgov, S. I., Ilkevich, N. I., Rabchuk, V. I., Rakitina, G. S., Senderov, S. M., and Slavin, G. B. (2013). “Управление режимами работы потребителей газа при нарушениях газоснабжения [Control of operating conditions of gas consumers in case of gas supply interruption].” Academic Publishing House (GEO), Novosibirsk, Russia (in Russian).
Edelev, A. V., and Beresneva, N. M. (2011). “Software package to study the energy sector development of Russia’s federal entities in terms of energy security.” Proc., 2nd Int. Science Conf. on Sustainable Energy Development, Institute of Energy Science, Hanoi, Vietnam, 49–54.
European Commission. (2006). “European smart grid technology platform: Vision and strategy for Europe’s electricity networks of the future.” Brussels, Belgium.
Geidl, M. (2007). “Optimal power flow of multiple energy carriers.” IEEE Trans. Power Syst., 22(1), 145–155.
Geidl, M., Koeppel, G., Favre-Perrod, P., Kloekl, B., Andersson, G., and Froerhlich, K. (2007). “Energy hubs for the future: A powerful approach for next-generation energy systems.” IEEE Power Energy Mag., 5(1), 24–30.
Gervigni, G., Di Castelmovo, M., Cagnobi, S., Sica, M., and Franceseo, V. (2012). “The policies for the large-scale deployment of smart gas meters in some European countries and draw policy implications, in particular for Italy.” ⟨http://proceedings.wgc2012.com⟩ (Aug. 16, 2016).
Gu, W., et al. (2014). “Modeling, planning and optimal energy management of combined cooling, heating and power microgrid: A review.” Int. J. Electr. Power Energy Syst., 54(1), 26–37.
Haghifam, M. R., and Manbachi, M. (2011). “Reliability and availability modeling of combined heat and power (CHP) systems.” Int. J. Electr. Power Energy Syst., 33(3), 385–393.
Hu, M., Chen, Y., Chen, Y., and Chang, Y. (2013). “Optimal operating strategies and management for smart microgrid systems.” J. Energy Eng., .
Huang, S. H., and Lin, P. C. (2013). “A harmony-genetic based heuristic approach toward economic dispatching combined heat and power.” Int. J. Electr. Power Energy Syst., 53(2), 482–487.
Koeppel, G., and Andersson, G. (2006). “The influence of combined power, gas and thermal networks on the reliability of supply.” ⟨https://www.eeh.ee.ethz.ch/uploads/tx_ethpublications/Koeppel_WESC06_2.pdf⟩ (Jun. 17, 2016).
Le Blond, S., Levis, T., and Sooriyabandara, M. (2011). “Towards an integrated approach to building energy efficiency: Drivers and enablers.” Proc., IEEE PES Innovative Smart Grid Technologies Europe Conf., Curran Associates, Inc., Red Hook, NY, 525–532.
Li, Z., Huo, Z., and Yin, H. (2011). “Optimization and analysis of operation strategies for combined cooling, heating and power system.” Proc., IEEE APPEE Conf., Curran Associates, Inc., Red Hook, NY, 2936–2939.
Mancarella, P., Gan, C., and Strbac, G. (2011). “Fractal models for electro-thermal network studies.” Proc., 17th Power System Computation Conf., Vol. 1, Curran Associates, Inc., Red Hook, NY, 699–705.
Marnay, C. (2012). “Worldwide microgrid development: The evolving power supply paradigm.” ⟨http://www.psma.com/sites/default/files/uploads/tech-forums-alternative-energy/presentations/2012-apec-254-worldwide-microgrid-development-evolving-power-supply-paradigm.pdf⟩ (Jun. 17, 2016).
Maroufmashat, A., et al. (2015). “Modeling and optimization of a network of energy hubs to improve economic and emission considerations.” Energy, 93(2), 2546–2558.
Marvasti, A. K., Fu, Y., DorMohammadi, S., and Rais-Rohani, M. (2014). “Optimal operation of active distributed grids: System of systems framework.” IEEE Trans. Power Syst., 5(3), 1228–1237.
Moeini-Aghtaie, M., Abbaspour, A., Fotuhi-Firuzabad, M., and Hajipour, E. (2014). “A decomposed solution to multiple-energy carriers optimal power flow.” IEEE Trans. Power Syst., 29(2), 707–716.
Moghaddam, I. G., Saniei, M., and Mashhour, E. (2016). “A comprehensive model for self-scheduling an energy hub to supply cooling, heating and electrical demands of a building.” Energy, 94, 157–170.
Momoh, J. (2012). Smart grid: Fundamentals of design and analysis, Wiley, New York.
Mueller, U., and Strunz, K. (2012). “Integrated reliability modeling for data center infrastructures: A case study.” Proc., IEEE PES Innovative Smart Grid Technologies Europe Conf., Berlin.
Neeraja, T. P., Sivraj, P., and Sasi, K. K. (2015). “Wide area control systems (WACS) implementation based on sensor network concepts.” Procedia Technol., 21, 303–309.
Notitsky, N. N., et al. (2014). “Трубопроводные системы энергетики: математическое и компьютерное моделированиe [Pipeline energy systems: Mathematical and computer modeling].” Nauka, Novosibirsk, Russia (in Russian).
Ofei-Amoh, R., and Syal, M. (2013). “Installation aspects of smart grid.” Pract. Period. Struct. Des. Constr., 56–66.
Parisio, A., Del Vecchio, C., and Vaccaro, A. (2012). “A robust optimization approach to energy, hub management.” Int. J. Electr. Power Energy Syst., 42(1), 98–104.
Patterson, B. T. (2012). “DC, come home. DC microgrids and the birth of the “Enernet”.” IEEE Power Energy Mag., 10(6), 60–69.
Paudyal, S., Camisares, C. A., and Bhattacharya, K. (2015). “Optimal operation of industrial energy hubs in smart grids.” IEEE Trans. Smart Grid, 6(2), 684–694.
Pionno, M., et al. (2012). “Smart gas meters and middleware for energy efficiency embedded.” ⟨http://proceedings.wgc2012.com⟩ (Aug. 16, 2016).
Prasad, I. (2014). “Smart grid technology: Application and control.” Int. J. Adv. Res. Electr. Electron. Instrum. Eng., 3(3), 9533–9542.
Rees, M. T., Wu, J., Award, B., Ekanayake, J., and Jenkins, N. (2011). “A modular approach to integrated energy distribution system analysis.” Proc., 17th Power System Computation Conf., Vol. 1, Curran Associates, Inc., Red Hook, NY, 97–103.
Russian Standards and Technical Regulations. (1997). “Loading guide for oil-immersed power transformers.” GOST 14209-97, Moscow.
Sheikhi, A., Rayati, M., Bahrami, S., and Ranjbar, A. M. (2015). “Integrated demand side management game in smart energy hubs.” IEEE Trans. Smart Grid, 6(2), 675–683.
Song, Q., Wang, H., Wen, F., Ledwich, G., and Xue, Y. (2014). “Pressure state response-based method for evaluating social benefits from smart grid development.” J. Energy Eng., .
Stennikov, V. A., Barakhtenko, E. A., Sokolov, D. V., and Oshchepkova, T. B. (2016). “Problems of modeling and optimization of heat supply systems: New methods and software for optimization of heat supply system parameters.” Sustaining power resources through energy optimization and engineering, IGI Global, Hershey, PA.
Styczynski, Z. A., and Voropai, N. I. (2010). “Возобновляемые источники энергии: Теоретические основы, технологии, технические характеристики, экономика [Renewable energy sources: Theoretical framework, technologies, technical features, economics].” OVGU, Irkutsk, Russia (in Russian).
U.S. Department of Energy. (2003). “Grid 2030: A national version for electricity’s second 100 years.” Washington, DC.
Van Beuzekom, I., Gibescu, M., and Slootweg, J. G. (2015). “A review of multi-energy system planning and optimization tools for sustainable urban development.” Proc., 2015 IEEE Power Tech, Curran Associates, Inc., Red Hook, NY, 722–728.
Vasilyev, S. N., et al. (2015). “Теоретические основы, методы и модели управления большими электроэнергетическими системами [Theoretical framework, methods and models for control of large-scale electric power systems].” FSK EES, Moscow, Russia (in Russian).
Voropai, N. I., et al. (2003). “Методы и модели разработки региональных энергетических программ [Methods and models for development of regional energy programs].” Nauka, Novosibirsk, Russia (in Russian).
Voropai, N. I., et al. (2010). “Системные исследования в энергетике: Ретроспектива научных направлений СЭИ-ИСЭМ [System studies in energy: Retrospective view of the research SEI-ISEM].” Nauka, Novosibirsk, Russia (in Russian).
Voropai, N. I., et al. (2015a). “Обоснование развития электроэнергетических систем: Методология, модели, методы, их использование [Expansion planning of electric power systems: Methodology, models, methods and their application].” Nauka, Novosibirsk, Russia (in Russian).
Voropai, N. I., et al. (2015b). “Энергетика XXI века: Инновационное развитие и управление [Energy of XXI century: Innovative development and control].” Nauka, Novosibirsk, Russia (in Russian).
Voropai, N. I., Senderov, S. M., and Edelev, A. V. (2012a). “Detection of” bottlenecks” and ways to overcome emergency situations in gas transportation networks on the example of the European gas pipeline network.” Energy, 42(1), 3–9.
Voropai, N. I., and Stennikov, V. A. (2013). “Integrated smart energy systems—Russian dimension.” ⟨http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6661665&isnumber=6661632⟩ (Jun. 17, 2016).
Voropai, N. I., and Stennikov, V. A. (2014). “Интегрированные интеллектуальные энергетические системы [Integrated smart energy systems].” Izvestiya RAN, Energetika, 1, 64–78 (in Russian).
Voropai, N. I., Suslov, K. V., Sokolnikova, T. V., Styczynski, Z. A., and Lombardi, P. (2012c). “Development of power supply to isolated territories in Russia on the base of microgrid conupt.” Proc., 2012 IEEE PES General Meeting, Curran Associates, Inc., Red Hook, NY, 687–691.
Yuasa, K., and Fujii, Y. (2012). “Developing advanced metering (the ubiquitous metering system).” ⟨http://proceedings.wgc2012.com⟩ (Aug. 16, 2016).
Zhenhua, J., et al. (2009). “A vision of smart transmission grid.” Proc., IEEE PES General Meeting, IEEE, New York.
Information & Authors
Information
Published In
Journal of Energy Engineering
Volume 143 • Issue 5 • October 2017
Copyright
©2017 American Society of Civil Engineers.
History
Received: Aug 23, 2016
Accepted: Dec 6, 2016
Published online: Feb 27, 2017
Discussion open until: Jul 27, 2017
Published in print: Oct 1, 2017
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.