Bilt-in turbulence modelling solution method

THE PURPOSE. The aim of the work is to find a method for mathematical modeling and analysis of inhomogeneous physical fields and the influence of internal structures on these fields. Solutions are sought in areas in which there are subdomains with already known behavior (“embedded” areas and embedded solutions). The goal is to find a modeling method that does not require a change in existing software and is associated only with the modification of the right-hand sides of the equations under consideration. METHODS. The proposed method of mathematical modeling is characterized by the use of characteristic functions for specifying the geometric location and shape of embedded areas, for specifying systems of embedded areas (for example, spherical fillings or turbulent vortices) without specifying them as geometric objects, for modifying the calculated differential equation within the embedded areas. RESULTS. A theorem is formulated and proved (in the form of a statement) that formalizes the essence of the proposed method and gives an algorithm for its application. This algorithm consists in a) representation of the differential equation of the problem in another analytical form; in this form, a term is added to the original differential equation (to its right-hand side), in the presence of which this equation gives a predetermined ("built-in") solution in the necessary regions and b) a representation of the desired solution (using the characteristic function) in the form in which this solution takes the form of either the desired function (in the main area) or the specified functions (in the embedded areas). Examples of calculations from two physical and technical areas - thermal conductivity and hydrodynamics are presented. The result of the work is also the calculation of a turbulent flow in a pipe, in which a system of ball vortices, the speed and direction of rotation of these vortices are specified. CONCLUSION. The proposed method makes it possible to simulate complex physical processes, including turbulence, has been tested, is quite simple and indispensable in cases where embedded structures can be specified only by software.

turbulence, modeling, vortex structures, embedded areas

1. Rodriguez S. Applied Computational Fluid Dynamics and Turbulence Modeling. Springer AG; 2019. doi 10.1007/978-3-030-28691-0.

2. Wilcox DC. Turbulence Modeling for CFD. DCW Industries, Inc; 2006.

3. Melamed LE. Uravnenie turbulentnogo dvizheniya v trubakh. Pis'ma v Zhurnal tekhnicheskoi fiziki. 2015;41(24):23–28. http://journals.ioffe.ru/articles/viewPDF/42592.

4. Melamed LE. Metod lokal'nykh fluktuatsii i modelirovanie neodnorodnykh sred. Pis'ma v Zhurnal tekhnicheskoi fiziki. 2016;42(19):31-37. http://journals.ioffe.ru/articles/viewPDF/43761.

5. Melamed LE, Filippov GA. Modelirovanie turbulentnosti kak «vikhrevoi zasypki». Izvestiya vysshikh uchebnykh zavedenii. Problemy energetiki. 2017;19(9-10):122-132.

6. Gol'dshtik MA. Protsessy perenosa v zernistom sloe. Institut teplofiziki im. S.S. Kutateladze SO RAN, Novosibirsk. 2005.

7. Baumert HZ. Universal equations and constants of turbulent moution. Physica Scripta. 2013;155. :1-12. doi:10.1088/0031-8949/2013/T155/014001.

8. Afanasyev YD, Korabel VN. Starting vortex dipoles in a viscous fluid: Asymptotic theory, numerical simulations, and laboratory experiments. Physics of Fluids. 2004;16(11):3850-3858. doi: 10.1063/1.1790493.

9. Lacaze L, Brancher P, Eiff O, et al. Experimental characterization of the 3D dynamics of a laminar shallow vortex dipole. Experiments in Fluids. 2010;48(2):225-231.

10. Sokolovskiy MA, Cartonb XJ, Filyushkinc BN, et al. Interaction between a surface jet and subsurface vortices in a three-layer quasi-geostrophic model. Geophysical and Astrophysical Fluid Dynamics. 2016;110(3):1-23. http://dx.doi.org/10.1080/03091929.2016.1164148 .

11. Muraki D, Snyder Ch. Vortex Dipoles for Surface Quasigeostrophic Models. Journal of The Atmospheric Sciences. 2007;64:2961-2967. doi:10.1175/JAS3958.1.

12. Kochin NE, Kibel' IA, Roze NV. Teoreticheskaya gidromekhanika. Ch.2. M. Fizmatgiz. 1963.

13. Melamed LE, Filippov GA. Obobshchennaya formula dlya skorosti turbulentnykh i laminarnykh techenii v trubakh. Izvestiya vysshikh uchebnykh zavedenii. Problemy energetiki. 2018;20(7-8):136-146. doi:10.30724/1998-9903-2018-20-7-8-136-146.

14. Zagarola MV, Smits AJ. Mean-flow scaling of turbulent pipe flow. Journal of Fluid Mechanics. 1998;373:33-79.

15. McKeon B J, Li J, Jiang W, et al. Further observations on the mean velocity distribution in fully developed pipe flow. Journal of Fluid Mechanics. 2004;501:135-147.

16. Reichardt H. Vollstandige Darstellung der turbulenten Geschwindigke its verteilung in glatten Leitugen. Zeitschrift fur Angewandte Mathematik und Mechanik. 1951;31(7):208-219.