Abstract
The paper considers the main scientific activities of the doctor of Technical Science, Professor Lev Aleksandrovich Rokhter, such as optimizing the shape of gas-air flow paths of thermal power plants, protecting the environment from harmful emissions, and identifying stack failures, which are currently being developed by his followers. For a systematic study of gas-air flow path components, L.A. Richter applied a technique based on the theory of complex variable and conformal mapping, which makes it possible to find optimal aerodynamic configuration of the gas-air flow path components. By means of the methodology developed by him, gas-air flow path research is currently carried out using Solid Works and Flow Vision application packages. Examples of optimizing the design of flue gas ducts with allowance for aerodynamic forces are given. The professor formulated the reasons and described the mechanism of structural collapse of reinforced concrete and brick stack constructions based on a theory of the occurrence of static pressures in the gas exhaust duct under certain conditions, which contribute to the penetration of aggressive substances of flue gas to the outer structural surface. In the last decade, works that additionally consider the flue gas mass transfer effect on the stack have become widespread. L.A. Richter proved that the problem of estimating the concentrations of impurities in TPP stack emissions is much more complicated under real conditions. This is due to the need to take into account the actual state of the atmosphere and its heterogeneous turbulent structure as well as the obligatory allowance for the rise of the stack plume over the stack mouth. Studies of his followers have shown that the scattering region of harmful substances is significantly reduced when a selfenvelopment phenomenon occurs under certain conditions. The professor’s contribution to the development of the methodology for finding economically optimal rates in various gas-air flow path components, as well as the creation of new structural components of electrostatic precipitators, which are currently widely used in practice, is also shown.
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References
L. A. Rikhter, Gas-Air Ducts of Thermal Power Plants, 2nd ed. (Energoizdat, Moscow, 1984) [in Russian].
N. A. Zroichikov, V. B. Prokhorov, and A. M. Arkhipov, “Reduction of aerodynamic drag of the gas duct of the TGMP-314 boilers at CHPP “TETs-23” of PJSC Mosenergo,” in Proc. All-Russ. Sci.-Pract. Conf. Improving the Reliability and Efficiency of Operation of Power Plants and Power Systems, Moscow, June 1–3, 2010 (Mosk. Energ. Inst., Moscow, 2010).
V. B. Prokhorov, M. V. Fomenko, and I. V. Grigor’ev, “Aerodynamic improvement of the assembly through which gas conduits are taken into a smoke stack by simulating gas flow on a computer,” Therm. Eng. 59, 457–461 (2012).
I. V. Grigor’ev, V. B. Prokhorov, and M. V. Fomenko, “Optimization of the gas duct of the 300 MW unit of Troitskaya GRES,” Vestn. Mosk. Energ. Inst., No. 5, 27–33 (2013).
L. A. Rikhter, D. P. Elizarov, and V. M. Lavygin, Auxiliary Equipment of Thermal Power Plants: Study Aid for Higher Schools (Energoatomizdat, Moscow, 1987) [in Russian].
E. P. Volkov, Selected Works, Vol. 2: Flue Pipes of Thermal and Nuclear Power Plants (Mosk. Energ. Inst., Moscow, 2014) [in Russian].
V. I. Maneev and A. P. Terekhov, Aerodynamics and Heat Transfer of Chimneys (Nauchn. Obozr., Moscow, 2017) [in Russian].
L. A. Rikhter, E. P. Volkov, and V. N. Pokrovskii, Protection of Water Basins and Air Sheds from Emissions of Thermal Power Plants (Energoizdat, Moscow, 1981) [in Russian].
Ecology of Power Generation: Study Aid, Ed. by V. Ya. Putilov (Mosk. Energ. Inst., Moscow, 2003) [in Russian].
V. V. Abramov, V. S. Agababov, and S. N. Anichkov, Modern Environmental Technologies in Electric Energy Generation: Informative Digest, Ed. by V. Ya. Putilov (Mosk. Energ. Inst., Moscow, 2007) [in Russian].
L. A. Rikhter, Thermal Power Plants and Atmosphere Protection (Energiya, Moscow, 1975) [in Russian].
E. P. Volkov, Selected Works, Vol. 1: Protection of Airshed from Emissions of Thermal Power Plants (Mosk. Energ. Inst., Moscow, 2014) [in Russian].
RD 52.04.212-86. A Method for Calculation of the Concentrations in the Atmosphere of Hazardous Substances Contained in Emissions of Enterprises. All-Union Normative Document, Ed. by M. Ya. Berlyand, N. K. Gasilinaya, E. L. Genikhovich, R. I. Onikul, and V. A. Glukharev (Gidrometeoizdat, Leningrad, 1987) [in Russian].
L. A. Rikhter, E. I. Gavrilov, and V. B. Prokhorov, “The causes and conditions of the process of self-enveloping of chimneys,” Teploenergetika, No. 11, 15–18 (1980).
A. M. Gribkov, N. A. Zroichikov, and V. B. Prokhorov, “Plume trajectory formation under stack tip self-enveloping,” Therm. Eng. 64, 745–752 (2017). doi 10.1134/S0040601517100032
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Original Russian Text © V.B. Prokhorov, S.L. Chernov, B.G. Tuval’baev, 2018, published in Teploenergetika.
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Prokhorov, V.B., Chernov, S.L. & Tuval’baev, B.G. Solutions for Gas-Air Flow Paths and Environmental Protection from Harmful Power-Plant Emissions in the Framework of the Scientific School Created by L. A. Rikhter [On the Centenary of the Birth of L. A. Rikhter]. Therm. Eng. 65, 927–933 (2018). https://doi.org/10.1134/S004060151812008X
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DOI: https://doi.org/10.1134/S004060151812008X