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Анотація
It has been proposed the application of an optimization criterion based on properties of target functions, taken from the elements of technical, economic and thermodynamic analyses. Marginal costs indicators of energy for different energy products have also been identified. Target function of the power plant optimization was proposed, that considers energy expenditure in the presented plant and in plants closing the energy sources generation and consumption balance.
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Як цитувати
MaksymovаO., Maksymov, M., Silina, V., & Orischenko, A. (2017). DEVELOPMENT OF THE METHOD OF DETERMINING THE TARGET FUNCTION OF OPTIMIZATION OF POWER PLANT. Automation of Technological and Business Processes, 9(2). https://doi.org/10.15673/atbp.v9i2.559
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ПИТАННЯ ТЕОРІЇ, МЕТОДИ ТА АЛГОРИТМИ ЕФЕКТИВНОГО АВТОМАТИЧНОГО УПРАВЛІННЯ ОБ’ЄКТАМИ ХІМІКО-ТЕХНОЛОГІЧНОГО ТИПУ
Посилання
[1] Hong-jie Song, Wei Zhang, Ya-qi Li, Zheng-wei Yang, An-bo Ming. (2017) Exergy analysis and parameter optimization of heat pipe receiver with integrated latent heat thermal energy storage for space station in charging process. Applied Thermal Engineering, 119, 304-311.
[2] Ravinder Kumar. (2017). A critical review on energy, exergy, exergoeconomic and econo mic (4-E) analysis of thermal power plants. Engineering Science and Technology, an International Journal, 20, 283–292.
[3] Mehmet Melikoglua. (2016). The role of renewables and nuclear energy in Turkey׳s Vision 2023 energy targets: Economic and technical scrutiny. Renewable and Sustainable Energy Reviews, 62, 1-12.
[4] Verkhivker G.P.(1986) About thermodynamic comparison and analysis of schemes of energy technological installations. - Izvestiya high schools. Ser.: Power Engineering, 11, 90-93.
[5] Caputo A., Pelagagge P., Salini P. (2011). Joint economic optimization of heat exchanger design and maintenance policy.. Applied Thermal Engineering, 31, 1381-1392.
[6] Strzalka R., Erhart T., Eicker U. (2013). Analysis and optimization of a cogeneration system based on biomass combustion. Applied Thermal Engineering, 50, 1418-1426.
[7] Quijera J., Alriols M., Labidi J. (2014). Integration of a solar thermal system in canned fish factory.Applied Thermal Engineering, 70, 1062-1072.
[8] Pelykh, S.N., Maksimov M.V., Parks G.T. (2013). A method for VVER-1000 fuel rearrangement optimization taking into account both fuel cladding durability and burnup.Nuclear Engineering and Design, 257, 53–60.
[9] Maksimova O.B., Davydov V.O., Babych S.V. (2014). Control of Heat Supply System with Structural Changeable Hardware. Journal of Automation and Information Sciences, v46, i6, 37-48.
[10] Maksimova O.B., Davydov V.O., Babych S.V. (2016). zptimization of Control of Heat Supply Systems of Urban Districts. Journal of Automation and Information Sciences, v48, i4, 69-89.
[2] Ravinder Kumar. (2017). A critical review on energy, exergy, exergoeconomic and econo mic (4-E) analysis of thermal power plants. Engineering Science and Technology, an International Journal, 20, 283–292.
[3] Mehmet Melikoglua. (2016). The role of renewables and nuclear energy in Turkey׳s Vision 2023 energy targets: Economic and technical scrutiny. Renewable and Sustainable Energy Reviews, 62, 1-12.
[4] Verkhivker G.P.(1986) About thermodynamic comparison and analysis of schemes of energy technological installations. - Izvestiya high schools. Ser.: Power Engineering, 11, 90-93.
[5] Caputo A., Pelagagge P., Salini P. (2011). Joint economic optimization of heat exchanger design and maintenance policy.. Applied Thermal Engineering, 31, 1381-1392.
[6] Strzalka R., Erhart T., Eicker U. (2013). Analysis and optimization of a cogeneration system based on biomass combustion. Applied Thermal Engineering, 50, 1418-1426.
[7] Quijera J., Alriols M., Labidi J. (2014). Integration of a solar thermal system in canned fish factory.Applied Thermal Engineering, 70, 1062-1072.
[8] Pelykh, S.N., Maksimov M.V., Parks G.T. (2013). A method for VVER-1000 fuel rearrangement optimization taking into account both fuel cladding durability and burnup.Nuclear Engineering and Design, 257, 53–60.
[9] Maksimova O.B., Davydov V.O., Babych S.V. (2014). Control of Heat Supply System with Structural Changeable Hardware. Journal of Automation and Information Sciences, v46, i6, 37-48.
[10] Maksimova O.B., Davydov V.O., Babych S.V. (2016). zptimization of Control of Heat Supply Systems of Urban Districts. Journal of Automation and Information Sciences, v48, i4, 69-89.