The International Scientific Conference „Innovative Materials, Structures and Technologies"

The material presented here demonstrates the experience gained over the past two decades. The emphasis is made on solving the fundamental problems of vortex aerohydromechanics and thermal physics that are related to the construction science. One of the major objectives of this work is to arrange the research directions according to this subject with the intent of showing their inter-discipline character.

Ermishin, А.; Isaev, S., 2003. Control of flow around vortex cell-containing bodies as applied to the aircrafts of integral arrangement (numerical simulation and experimental investigation). Мoscow: MSU Press. 360 p.

Babaskin, V.; Isaev, S.; Меtov, Kh.; Pyshnyi I.; Chepiga, V., 2002. Wind shear as used in aircrafts (warning system). Saint-Petersburg: Academy of Civil Aviation. 146 p.

Babaskin, V. V.; Isaev, S. А.; Меtov, Kh. Т.; Chepiga, V. Е., 2008. Numerical simulation and the warning system of a hazardous orographical wind shear in airports. All-Russian Scientific and Technical Journal “Flight”, 12, pp.27-34.

Baranov, P.; Guvernyuk, S.; Isaev, S.; Kharchenko, V., 2003. Numerical simulation of laminar flow around a cylinder with a co-axial front disc at small and moderate angles of attack using multiblock computational technologies. Aeromechanics and Gasdynamics, 1, pp. 16-27.

Baranov, P.; Isaev, S.; Коrolev, Е.; Usachov, А., 2005. Ventilation computation of open embrasures of road tunnels using the numerical simulation methods. Metro and Tunnels, 6, pp. 13-18.

Belov, I.; Isaev, S.; Коrоbкоv, V., 1989. Tasks and calculation methods of separated incompressible liquid flows. Leningrad: Sudostroyeniye. 256 p.

Bungov, V.; Isaev, S.; Kharchenko, V., 1998. Calculation of the wind action on a cooling tower in the presence of devices for equalizing the ground flow. Journal of Engineering Physics and Thermophysics, 71(5), pp. 852-857. http://dx.doi.org/10.1007/BF02681636

Bystrov, Yu.; Isaev, S.; Кudryavtsev, N.; Leontiev, А., 2005. Numerical simulation of vortex heat transfer enhancement in tube bundles, Saint-Petersburg: Sudostrouyeniye. 398 p.

Castro, I.; Robins, A., 1977. The flow around a surface-mounted cube in uniform and turbulent streams. Journal of Fluid Mechanics, 79(2), pp. 307-335. http://dx.doi.org/10.1017/S0022112077000172

Devnin, S., 1983. Aerohydromechanics of high-drag constructions. Handbook. Leningrad: Sudostroyeniye. 320 p.

Isaev, S.; Zhdanov, V.; Niemann, H.-J., 2002. Numerical study of the bleeding effect on the aerodynamic characteristics of a circular cylinder. Journal of Wind Engineering and Industrial Aerodynamics, 90(11), pp. 1217-1226. http://dx.doi.org/10.1016/S0167-6105(02)00253-2

Isaev, S.; Baranov, P.; Usachov, A.; Mitrofovich, V.; Kolosov, A.; Ponomarev, M., 2003. Numerical modeling of turbulent flow inside a wind-driven plant with allowance for the forces on the impeller. Journal of Engineering Physics and Thermophysics, 76(6), pp. 1246-1250. http://dx.doi.org/10.1023/B:JOEP.0000012025.23698.1d

Isaev, S.; Sudakov, А.; Bаrаnоv, P.; Usachov, А.; Strizhak, S.; Lokhansky, Ya.; Guvernyuk, S., 2009. Development, verification, and application of the multiblock computational technology-based parallel open code VP2/3 for solving fundamental, applied, and maintenance problems of aeromechanics and thermal physics. Bulletin of South Ural State University. Series “Mathematical Modeling and Programming”, 17(3), pp. 59-72.

Isaev, S.; Kornev, N.; Leontiev, A.; Hassel, E., 2010(a). Influence of the Reynolds number and the spherical dimple depth on the turbulent heat transfer and hydraulic loss in a narrow channel. International Journal of Heat and Mass Transfer, 53(1-3), pp. 178-197. http://dx.doi.org/10.1016/j.ijheatmasstransfer.2009.09.042

Isaev, S.; Leontiev, A., 2010(b). Problems of simulating tornado-like heat transfer turbulent flow past a dimpled relief on a narrow channel wall. Journal of Engineering Physics and Thermophysics, 83(4), pp. 783-793. http://dx.doi.org/10.1007/s10891-010-0404-5

Isaev, S.; Vаtin N.; Bаrаnov, P.; Sudakov, А.; Usachov, А.; Еgоrоv, V., 2013(a). Development and verification of multiblock computational technologies for solving unsteady problems of building aerodynamics of high-rise buildings within the URANS approach. Journal of Engineering Physics and Thermophysics, pp. 86(1), pp. 103-109

Isaev, S.; Vatin, N.; Lebiga, V.; Zinoviev, V.; Chang Keh-Chin; Miau, Jiun-Jih., 2013(b). Problems and methods of numerical and experimental investigations of aerodynamics for high-rise constructions in the coastal region "sea-land". Journal of Civil Engineering, 2, pp. 54-61.

Каlinin, E.; Dreitser, G.; Коpp, I.; Мyakochin, А., 1998. Effective heat transfer surfaces. Мoscow: Energoatomizdat. 408 p.

Lawson, T., 2001. Building aerodynamics. London: Imperial College Press. 286 p.

Menter, F., 1993. Zonal two equation turbulence models for aerodynamic flows. AIAA, Paper No 93-2906:21.

Menter, F.; Kuntz, M.; Langtry, R., 2003. Ten years of industrial experience with the SST turbulence model. Turbulence, Heat and Mass Transfer 4. Ed. K.Hajalic, Y.Nogano, M.Tummers. Begell House, Inc.

Usachov, А.; Коlesnikov, А.; Ismail, Siyavoshi, М.; Isaev, S., 2004. Ventilation system and numerical simulation of the propagation of smoke and thermal energy at fire in the Alborz mountain tunnel in Iran. Underground Areas of the World, 1, pp. 49-52.