Binary alloys separation in thin capillaries

Authors

  • Vitaliy Anatol’yevich Demin Perm State National Research University, Perm, Russian Federation
  • Aleksey Ivanovich Mizev Institute of Continuous Media Mechanics UB RAS, Perm, Russian Federation
  • Maksim Ivanovich Petukhov Perm State National Research University, Perm, Russian Federation

DOI:

https://doi.org/10.7242/1999-6691/2018.11.2.10

Keywords:

solutal convection, binary alloy’s interface, separation of binary alloys, adsorption and desorption processes

Abstract

Direct numerical simulation of the process of binary alloy separation in a thin non-uniformly heated circular capillary is carried out. The key point of the process under consideration is the assumption of the existence of a thin gas layer between the melt and the capillary wall due to non-wetting condition. Equations of interfacial hydrodynamics are used to describe the effect of separation, which allows us to develop a phenomenological model of the processes at the melt - solid boundary interface for mixtures of liquid metals. The finite difference method in combination with the explicit scheme is used for solving the problem. The calculations have been carried out on the supercomputer “PSU-Kepler” of the Scientific and Educational Center “Parallel and Distributed Calculations” in Perm State National Research University. Velocity and temperature fields, as well as the concentration of melt components in the volume and on the surface, are determined through numerical simulations. The dynamics of the separation process is described in detail. It has been found that the longitudinal temperature gradient and the non-wetting condition on the lateral capillary side generate a downward movement along the external boundary, which, together with adsorption and desorption effects, lead to the formation of volume concentration non-uniformity along the capillary. The temporal evolution of the volume concentrations difference along the capillary observed in experiments is reproduced numerically. The distributions of volume concentrations and the surface phase are studied as a function of both Marangoni number and adsorption-desorption coefficients. Concentration differences for alloy components are studied in relation to the capillary length. It has been shown that an increase in the capillary length leads to the strengthening of the separation effect. The qualitative and quantitative comparison of most characteristics demonstrates that the calculated data are in good agreement with the numerical results of the plane problem considered earlier and with the available experimental data. Numerical experiments show that the movement in the surface layer is quite intensive. The heavy component is transported by the convection flow towards the lower part of the capillary so that its concentration increases by the order of magnitude on the 1/8 part of the capillary surface.

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References

Zalkin V.M. O stroenii rasplavov v binarnyh metallicheskih sistemah s evtekticheskimi diagrammami sostoyaniya [On the structure of melts in binary metallic systems with eutectic phase diagrams]. Phiz. Khimii – Journal of Physical Chemistry, 1972, vol. 46, no 1, pp. 8-14.

Bunin K.P. K voprosu o stroenii metallicheskih evtekticheskih rasplavov [On the structure of metallic eutectic melts]. AN SSSR, OTN, 1942, № 2, pp. 305-310.

Gavrilin I.V. Raspredelenie ugleroda v zhidkom chugune [Carbon distribution in liquid cast iron]. Liteynoe proizvodstvo – Foundry, 1982, no 4, pp. 2-4.

Korsunskiy V.I., Naberuhin Yu.I. O vliyanii centrifugirovaniya na mikrogeterogennoe stroenie metallicheskih rasplavov evtekticheskogo tipa [On the influence of centrifugation on the microheterogeneous structure of metallic melts of the eutectic type]. AN SSSR, Metally, 1973, no 5, pp. 182-187.

Demin V.A. Sedimentation of nanoparticles in a homogeneous carrying fluid in the presence of thermodiffusion. Bulletin of Perm State University. Physics, 2013, 1(23), pp. 20-24.

Glukhov A.F., Demin V.A., Tretyakov A.V. On thermodiffusion influence on the dopant distribution during the freezing of binary liquid column. Bulletin of the Tomsk Polytechnic University. Geo Assets Engineering, 2015, vol. 326, no 11, pp. 118-127.

Gavrilin I.V., Frolova T.B, Zaharov V.P. O likvacii v zhidkih ehvtekticheskih rasplavah [On liquation in liquid eutectic melts]. AN SSSR. Metally, 1984, no 3, pp. 191-193.

Gavrilin I.V. Sedimentacionniy eksperiment pri izuchenii zhidkih splavov [Sedimentation experiment in the study of liquid alloys]. AN SSSR. Metally, 1985, no 2, pp. 66-73.

Demin V.A., Petukhov M.I. On mechanism of large-scale transfer of molten metal components in non-uniformly heated thin capillaries. Bulletin of Perm University. Physics, 2016, 3(34), pp. 65-71. DOI

Demin V.A., Petukhov M.I. Large-scale transfer of molten metal components in thin capillaries. Tomsk State University Journal of Mathematics and Mechanics, 2017, no. 48, pp. 57−69. DOI

Gershuni G.Z., Zhukhovitskii E.M. Convective stability of incompressible fluids, Keter Publishing House, Jerusalem, 1976. 330 p.

De Gennes P.G. Wetting: statics and dynamics. Mod. Phys, 1985, vol. 57, pp. 827-863. DOI

Bratukhin Yu.K., Makarov S.O. Interfacial convection. Perm State University Press, Perm, 1994. 328 p.

Birikh R.V., Briskman V.A., Velarde M., Legros J.-C. Liquid Interfacial Systems: Oscillations and Instability. CRC Press, 2003. 392 p.

Slavtchev S., Hennenberg M., Legros J.-C., Lebon G. Stationary solutal Marangoni instability in a two-layer system. J. Colloid Interface Sci., 1998, vol. 203, no. 2, pp. 354–368. DOI

Birikh R.V. Stability of homogeneous non-stationary surfactant diffusion through a flat interface between liquids. Bulletin of Perm University. Series: Physics, 2016, 1(32), pp. 64-70. DOI

Tarunin E.L. Vychislitel’niy ehksperiment v zadachah svobodnoj konvekcii: ucheb. posobie [Computational experiment in free convection problems: tutorial]. Irkutsk: Irkutsk University, 1990. 228 p.

Tarunin E.L. Dvuhpolevoj metod resheniya zadach gidrodinamiki: uchebnoe posobie po speckursu [Two-field method for solving hydrodynamic problems: a special course manual]. Perm: Perm. univ, 1985. 87 p.

Fisher H.J., Phillips A. Viscosity and density of liquid lead-tin and antimony-cadmium alloys. JOM, 1954, vol. 200, pp. 1060-1070. DOI

Cusco L., Monaghan B.J. Development of a UK national standard for the thermal properties of molten materials: thermal diffusivity of molten copper. High Temp. – High Press., 2002, vol. 34, pp. 281-289. DOI

Alchigarov B.B., Kurshev O.I., Taova T.M. Surface tension of tin and its alloys with lead. Russ. Phys. Chem. A, 2007, vol. 81, no. 8, pp 1281-1284. DOI

Uglev N.P., Dubrovina E.I. Radial’noe raspredelenie komponentov pri rassloenii metallicheskih rasplavov v kapillyarah [Radial distribution of components in the separation of metallic melts in capillaries]. Vestnik PNIPU, Ser. Khimicheskaya tekhnologiya i biotekhnologiya, 2015, no 1, pp. 50-59.

Published

2018-07-23

Issue

Section

Articles

How to Cite

Demin, V. A., Mizev, A. I., & Petukhov, M. I. (2018). Binary alloys separation in thin capillaries. Computational Continuum Mechanics, 11(2), 125-136. https://doi.org/10.7242/1999-6691/2018.11.2.10