The developed auxiliary software serves to simplify, standardize and facilitate the software loading of the structural organization of a complex technological system, as well as its further manipulation within the process of solving the considered technological system. Its help can be especially useful in the case of a complex structural organization of a technological system with a large number of different functional elements grouped into several technological subsystems. This paper presents the results of its application for a special complex technological system related to the reference steam block for the combined production of heat and electricity.
References
[1]
Muhlhauser, H. (1982) Heating Turbines—A Contribution to the Improved Utilization of Primary Energy. Brown Boveri Review, 11, 423-430.
[2]
Schwarzenbach, A. (1990) Parity Factors for Economic Comparisons in Cogeneration Plants. Brown Boveri Review, 3, 166-172.
[3]
Lisin, E., Sobolev, A., Strielkowski, W. and Garanin, I. (2016) Thermal Efficiency of Gogeneration Units with Multy-Stage Reheating for Russian Municipal Heating Systems. Energies, 9, 269. https://doi.org/10.3390/en9040269
[4]
Kasilkov, V.E. and Kholodkov, S.V. (2017) Cogeneration Steam Turbines from Siemens: New Solutions. Thermal Engineering, 64, 184-189. https://doi.org/10.1134/S0040601517030041
[5]
Shibaev, T.L. (2020) A Review of Trends in Development of Cogeneration Steam Turbine Units. Thermal Engineering, 67, 903-908. https://doi.org/10.1134/S0040601520120071
[6]
Savić, B. and Stojaković, M. (1992) Computer Program “TRANSFER” for Analyses of Hot Water Cycle in Cogeneration District-Heating Power Plant. ICHMT 2nd International Forum on Expert Systems and Computer Simulation in Energy Engineering, Erlangen, 17-20 March 1992, 22-3-1, 22-3-6.
[7]
Vasiljević, N., Savić, B., Stojaković, M. and Damnjanović, S. (1993) Energetic Effects of Belgrade District Heating from Power Plant “Nikola Tesla”-A, Feasibility Study 06.14-14/93 for “JKP Belgrade Generating Station”. Faculty of Mechanical Engineering, Belgrade, p. 57. (in Serbian)
[8]
Savić, M.B. (1989) Contribution to the Energy Basis of the Development and Integration of Combined Heat and Electricity Production into the Power System. Ph.D. Thesis, University of Belgrade, Belgrade, p. 166. (in Serbian)
[9]
Savić, B. (1990) Mathematical Modeling and Computer Simulation of Processes in Energy Systems. Hemisphere Publishing Corp, 815-828.
[10]
Savić, B. (1994) Methodology for Thermic Calculations Surface Heat Exchangers Involved in Computer Program TURBOEX for a Steam Turbine Unit Load Calculations. Proceedings of TERMOHIDRAULIKA’94-Termohydraulic Processes in Energetic, Faculty of Mechanical Engineering, Belgrade, 13. and 14. Oktober 1994, D.4-1, 10. (in Serbian)
[11]
Vasiljević, N., Savić, B. and Stojaković, M. (1991) Research of Optimal Design and Operating Conditions of the Condenser Part of Steam Turbine Units. Investigation Study, University of Belgrade, Belgrade, p. 120. (in Serbian)
[12]
Stojaković, M., Vasiljević, N. and Savić, B. (1995) Steam Power Plant Efficiency Enhancement by Means of “Cold-End” Optimization during Exploitation. 57th Annual Meeting, American Power Conference, 57-1, 560-565.
[13]
Kromhout, J., Goudappel, E. and Pechtl, P. (1997) Economic Optimization of the Cooling Water Flow of a 540 MW el Coal Fired Power Plant Using Thermodynamic Simulation. Power-Gen Europe 97, Madrid, May 1997, 204-222.
[14]
Beebe, R. (2003) Condition Monitoring of Steam Turbines by Performance Analyses. Journal of Quality in Maintenance Engineering, 9, 102-112. https://doi.org/10.1108/13552510310482361
[15]
Aronson, K.E., Brodov, Yu.M. and Novoselov, V.B. (2012) Development of a System for Monitoring Technical State of the Equipment of a Cogeneration Steam Turbine Unit. Thermal Engineering, 59, 944-947. https://doi.org/10.1134/S0040601512120026
[16]
Savić, B. and Jovanović, R. (2011) Software System “DIORES” for the Operation Diagnosis of Steam Power Plant Unit. Energy, 36, 1187-1195. https://doi.org/10.1016/j.energy.2010.11.028
