Power Technology and Engineering

, Volume 52, Issue 1, pp 74–78 | Cite as

Energy-Efficient Distribution of Heat Between the Boiler Units of Industrial Power Palnts with the Use of Computers

  • A. V. VarganovaEmail author
  • A. V. Malafeev

Methods of increasing the operating efficiency of industrial power plants through the use of novel computer software are considered. By means of these methods the rational boiler load may be determined based on a minimum criterion of the total cost of the steam needed to generate electricity and cover the required thermal load.


power boiler turbine generator power station power supply system optimal regime dynamic programming step-by-step reduction 


Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.


  1. 1.
    A. V. Pazderin, “Solution of problem of energy distribution in electrical networks based on methods of estimation of state,” Élektrichestvo, No. 12, 2 (2004).Google Scholar
  2. 2.
    A. V. Pazderin, “Calculation of technical losses of electricity based on a solution of the problem of energy distribution,” Élektr. Stantsii, No. 12, 44 (2004).Google Scholar
  3. 3.
    A. N. Shemetov and V. K. Oleinikov, “Management of electricity use in sintering production with fuzzy initial information,” Élektrika, No. 5, 24 – 27 (2003).Google Scholar
  4. 4.
    S. A. Eroshenko, A. A. Karpenko, S. E. Kokin, and A. V. Pazderin, “Scientific problems of distributed generation,” Izv. Vuzov. Probl. Énerget., No. 11 – 12, 126 – 133 (2010).Google Scholar
  5. 5.
    D. E. Varganov, A. V. Varganova, and I. I. Barankova, “Use of mathematical economic models of gas piston plants to improve the performance of power centers with sources of distributed generation,” Élektrotekh. Sist. Kompl., No. 4 (33), 29 – 34 (2016).Google Scholar
  6. 6.
    A. L. Malafeev, A. V. Kochkina, and E. A. Panova, “Optimal distribution of capacity between generators of the power plants of an industrial enterprise in long-term phased repair of the equipment of feeder networks,” Vest. Magnitogorsk. Gos. Tekh. Univ. im. G. I. Nosova, No. 4(40), 78 – 81 (2012).Google Scholar
  7. 7.
    O. V. Bulanova, A. V. Malafeev, Yu. N. Rotanova, and V. M. Tarasov, “An analysis of the transients of the electric supply systems of industrial enterprises that include low-power sections,” Promyshl. Énerget., No. 4, 22 – 28 (2010).Google Scholar
  8. 8.
    A. V. Malafeev, O. V. Bulanova, and Yu. N. Rotanova, “Investigation of the dynamic stability of power supply systems of industrial enterprises with internal power plants when separated from the power system as a result of shorting,” Vest. Uzhno-Ural. Gos. Univ. Ser. Kompyut. Tekh. Uprav. Radioélektr., No. 17(117), 72 – 74 (2008).Google Scholar
  9. 9.
    V. A. Venikov, V. G. Zhuravlev, and T. A. Filippova, Optimization of the Regimes of Power Plants and Power Systems [in Russian], Énergoatomizdat, Moscow (1990).Google Scholar
  10. 10.
    V. M. Gornhstein, B. P. Miroshnichenko, and A. V. Ponomarev, Methods for Optimization of the Regimes of Power Systems [in Russian], Énergiya, Moscow (1981).Google Scholar
  11. 11.
    K. Frauendorder, H. Glavitch, and R. Bacher, Optimization in Planning and Operation of Electric Power Systems. Lecture Notes of the SVOR/ASRO Tutorial Thun, Switzerland (1992).Google Scholar
  12. 12.
    N. A. Belyaev, N. V. Korovkin, O. V. Frolov, and V. S. Chudnyi, “Methods for optimization of power-system operation modes,” Russ. Electr. Eng., No. 2, 74 – 80 (2013).CrossRefGoogle Scholar
  13. 13.
    A. V. Pazderin and S. V. Yuferev, Steady-State Calculation of Electrical Power System by the Newton’s Method in Optimization. Presented to 2009 IEEE Bucharest PowerTech: Innovative Ideas Towards the Electrical Grid of the Future, Bucharest (2009).Google Scholar
  14. 14.
    S. Kahourzade, A. Mahmoudi, and H. B. Mokhlis, “A comparative study of multi-objective optimal power flow based on particle swarm, evolutionary programming, and genetic algorithm,” Electr. Eng., No. 97 (2015).Google Scholar
  15. 15.
    A. B. Kochkina, D. Ye. Vargonov, A. D. Kovalev, and A. V. Malafeyev, “Optimization of distribution of active capacities between heterogeneous generating sources in the power supply system of an industrial enterprises,” in: Proc. III International Scientific and Technical Conference, Electrical Power Through the Eyes of the Young, Ural Federal University [in Russian], Yekaterinburg (2012), pp. 280 – 284.Google Scholar
  16. 16.
    A. V. Kochkina, A. L. Malafeyev, N. A. Kurilova, and R. P. Netupskii, “Construction of cost-benefit models of turbogenerators and boiler units of the internal power plants of industrial enterprises,” Élektrotekh. Sist. Kompl., No. 21, 247 – 252 (2013).Google Scholar
  17. 17.
    Rus. Inventor’s Certificate 2013616847, V. A. Igumenshchev, A. V. Malafeyev, O. V. Gazizova, Yu. N. Kondrashova, Ye. A. Panova, A. V. Kochkina, and V. V. Zinov’ev, “Computer Program, KATRAN 7.0 Complex of Computerized Regime Analysis,” Byull. Otkry. Izobret., No. 3 (2013).Google Scholar
  18. 18.
    D. E. Varganov and D. E. Varganova, “Calculation of production cost of fresh steam at large thermal industrial power plants,” Élektrotekh. Sist. Kompl., No. 1(30), 24 – 28 (2016).Google Scholar

Copyright information

© Springer Science+Business Media, LLC, part of Springer Nature 2018

Authors and Affiliations

  1. 1.G. I. Nosov Magnitogorsk State Technical UniversityMagnitogorskRussia

Personalised recommendations