Open Access
Issue
E3S Web Conf.
Volume 97, 2019
XXII International Scientific Conference “Construction the Formation of Living Environment” (FORM-2019)
Article Number 05030
Number of page(s) 11
Section Hydrotechnical Construction and Melioration
DOI https://doi.org/10.1051/e3sconf/20199705030
Published online 29 May 2019
  1. V.M. Lyather, A.N. Militeev, Numerical modeling of open streams. Water Resources. (1987) .1. C.35-41. [Google Scholar]
  2. A.N. Krutov, Development of the theory and methods of forecasting the spread of pollutants in the surface waters of arid zones. Dis. on the competition scholarly step. Doctor of Technical Sciences, M. (1997), 162 p. [Google Scholar]
  3. A.N. Militeev, Solving problems of hydraulics of small reservoirs and pools of waterworks using numerical methods. Author’s abstract diss. doctors tech. Sciences.M., (1982). 43c [Google Scholar]
  4. F.F. Vasiliev, T.A. Temnoeva, S.M. Shugrin, A numerical method for calculating unsteady currents in open channels. Ed. USSR Academy of Sciences. mechanics, (1965) [Google Scholar]
  5. O. F. Vasiliev, M.T. Gladyshev, On the calculation of discontinuous waves in open channels. Izv. Academy of Sciences of the USSR, ser. Fluid and gas mechanics, (1966) 6. p. 184-189. [Google Scholar]
  6. O. F. Vasiliev, A.F. Voevodin, A.A. Atavin, Methods for calculating unsteady currents in open channel systems and channels. Numerical methods of continuum mechanics, (1975). V. 6. No. 4. p. 21-30. [Google Scholar]
  7. D.V. Kvon, Mathematical modeling of hydrothermal processes in Lake Teletskoye. Author’s abstract dis. on the competition scholarly step. Ph.D. sciences. Barnaul. (1998) 21 p. [Google Scholar]
  8. A.N. Militeev, D.R. Bazarov, A.N. Krutov, Three-dimensional mathematical model for streams with a blurred bottom. Messages in applied mathematics. M., the CC of RAS, (1997) 45 p. [Google Scholar]
  9. V.M. Lyather, A.N. Militeev, Hydraulic investigations by numerical methods. Water resources. (1981) 3. S.60-79. [Google Scholar]
  10. A.N. Militeev, Numerical modeling of pulsation currents and heat and mass transfer in small unstratched water bodies. Hydraulic research in the energy and water sector. M., (1983) P.8-22. [Google Scholar]
  11. M.G. Gladyshev, Numerical modeling of unsteady currents in open channels. Water resources. (1981) 3. C.119-125. [Google Scholar]
  12. O.F. Vasilyev, G.V. Volkova, V.I. Kvon, Numerical calculation of the hydrothermal mode of cooling ponds of thermal power plants and nuclear power plants. Tr. coordinates owls on hydraulic engineering., Energy, L., (1977) 115. C. 59-64. [Google Scholar]
  13. O.F. Vasiliev, M.G. Gladyshev, On the calculation of discontinuous waves in open channels. Izv. Academy of Sciences of the USSR. Fluid and gas mechanics. (1966) 6. C. 53-61. [Google Scholar]
  14. O.F. Vasilyev, M. G. Gladyshev, V. G Sudobicher, Numerical calculation of unsteady water movement in an open channel. The solution of one-dimensional problems of gas dynamics in moving grids. M .: Science, (1970) C. 48-61. [Google Scholar]
  15. M.G. Gladyshev, Numerical modeling of unsteady currents in open channels. Water resources. (1981) 3. C.119-125. [Google Scholar]
  16. V.I. Kvon. Hydrothermal calculation of cooling ponds. Izv. Academy of Sciences of the USSR. Energy and transport. (1979). 5.C.49-60 [Google Scholar]
  17. B.L. Istorik, Numerical research of concretional flows in open channels. Sat scientific Trudov. Hydroproject them. S.Y. Beetle Hydraulics and filtration. M., (1979). C.18-28. [Google Scholar]
  18. B.L. Istorik, V.M. Lyather, Propagation of breakthrough waves in a prismatic channel.Izv. Academy of Sciences of the USSR. MZHG. (1975). 1. P.39-42. [Google Scholar]
  19. A.S. Petrusev, Difference schemes and their analysis: a teaching aid. M.: MIPT, (2004). 89 s. [Google Scholar]
  20. A.N. Militeev, N.V. Ovinova, Method of calculating stratified reservoirs. Inst. ZNIIS. M., (1993) 14 p .Dep. in VNIINTI 03.11.93, 2744-B93. [Google Scholar]
  21. W. Rodi, (1993) Turbulence A state-of-the-art review. IAHR Monograph, Third Edition, A. A. Balkema, Rotterdam, Brookfield. [Google Scholar]
  22. A.N. Militeev, Yu.B. Shpolyansky Numerical Modeling of Pollution Transfer by Design of Water Protection Measures. Optimization of technological processes and improvement of design based on hydraulic research. M., (1989). P.46-52 [Google Scholar]
  23. I.A. Sherenkov, Applied planned problems of the hydraulics of quiet flows .M .: Energy, (1978). 240s [Google Scholar]
  24. I. Shiryak, Investigation of the transport of pollutants in shallow-flowing water bodies by wind currents: Author’s abstract. diss. Cand. tech. Sciences.L., (1978). 23c. [Google Scholar]
  25. A.T. Zinoviev, K.B. Koshelev, K.V. Marusin, E.D. Kosheleva. Mathematical modeling of the channel flow to predict the impact of construction in floodplains on the hydrological regime of large rivers (using the Ob River as an example). Russian Water Management No 2, 2017 Available from: https://www.researchgate.net/publication/318851108 [accessed Mar.22.2019]. [Google Scholar]
  26. Potapov I. I., Snigur KS. Modeling the evolution of the sandy-gravel bottom of the channel in a one-dimensional approximation // Computer Research and Modeling. 2015.T.7 № 2.S.315-329. [Google Scholar]
  27. Belikov V.V., Borisova N.M., Gladkov G.L. Mathematical model of sediment transport for calculating the record of dredging slots and channel open pits. // Bulletin of the State University of Maritime and River Fleet. Admiral S.O. Makarova. Journal of the University of Water Communications. 2010. Issue 2., pp. 105 113. C.F. Scoit, (1994) A numerical study of the interaction of tidal oscillation and nonlinearities in an estuary. Estuarine, Coastal and Shelf Science, 39, pp. 477-496. [Google Scholar]
  28. B.E. Launder, and W.M. Ying, (1973) Prediction of flow and heat transfer in ducts of square cross-section. Proceedings of the Institution of Mechanical Engineers. 187, pp. 455-461. [CrossRef] [Google Scholar]
  29. B. Lin, and K. Shiono, (1992) Prediction of pollutant transport in compound channel flows. Proceedings of the Second International Conference on Hydraulic and Environmental Modelling of Coastal, Estuarine and River Waters, Ashgate Publishing Limited, 2, pp. 373-384. [Google Scholar]
  30. Hydraulic Research Station (1974). The wash water storage scheme numerical model studies of the Great Ouse Estuary. Report DE 11, Wallingford, UK. [Google Scholar]
  31. D. Cokijat, (1991) Mathematical modelling of turbulent flows in two stage channels. Transfer Report, Proceedings of the Hydraulics Division, Department of Civil Engineering, City University, London, UK, pp. 1-78. [Google Scholar]
  32. A.F. Blumberg, (1977) Numerical model of estuarine circulation. Journal of Hydraulics Division, Proceedings of the American Society of Civil Engineers, 103, HY3, pp. 295-310. [Google Scholar]
  33. P.L. Violett, Turbulent mixing in a two layer stratified shear flow. Seond Int. Symposium on stratified flow.Troundheim, Norway. (1980). Pp.315-325. [Google Scholar]
  34. Renato do Nascimento Siqueira, (2002). Transport and mixing processes in stratified flow. Loughborough University Institutional Repository. Retrieved 17.12.2018 from https://dspace.lboro.ac.uk/dspace-jspui/bitstream/2134/34335/1/Thesis-2002-DoNascimentoSiqueira.pdf [Google Scholar]
  35. M.B. Abbot, D.R. Basco, Computational Fluid Dynamics. An Introduction for Engineers. Copublished in the United States with John Wiley and Sons, Inc. New York, (1994), pp.425. [Google Scholar]
  36. W.D. Baines, D.I. Knapp Wind driven water current. J. Hydraulics Division. ASCE. (1965).-91. P.821-836. [Google Scholar]

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