Hydrodynamics and heat exchange in processes of cooling of a magnetic plate in a magnetic liquid in the magnetic field

The effect of the magnetic field on heat transfer processes of a magnetized steel plate cooled in a magnetic fluid is experimentally studied. Thermocouples were installed at six points on the surface of the plate along its length. The plots of temperature versus time are obtained in the absence of a magnetic field and in magnetic fields of different intensity. It is found that the intensity of heat exchange depends to a large extent on the magnitude of the magnetic field and on the location of points on the surface of the plate. In a magnetic field, cooling of the central part of the plate occurs with the same intensity as in the absence of a magnetic field and with a lower intensity in comparison with other points on the surface of the plate. Near the plate ends, the cooling rate of the surface is much greater in the magnetic ield than in the absence of it. With increasing magnetic field strength, the cooling rate of points in the central part of the plate decreases and is less than in the absence of a magnetic field. The dependence of heat transfer on the magnitude of the magnetic ield is explained by the distribution of the magnetic forces acting on the liquid surrounding the plate and the nature of the vapor-air cavities formed near its surface. Experiments on simulation of formation and the shape of vapor-air cavities in a liquid surrounding a magnetizing plate are described.

магнитная жидкость, теплообмен, гидродинамика, стальная пластина, магнитное поле, magnetic fluid, heat transfer, hydrodynamics, steel plate, magnetic ield

1. Гогосов В. В., Симоновский А. Я. О локально-неоднородном охлаждении при закалке в магнитной жидкости // Изв. АН СССР Механика жидкости и газа. 1989. № 2. С. 3.

2. Gogosov V. V., Simonovskii A. Ya., Smolkin R. D. Quenching and separation in magnetic fluids // JMMM. 1990. V. 85. №. 1-3.P. 227.

3. Mirkin L.I., Shesterikov S.A., Simonovski A.Y. Equipment and method for quenching steels in a magnetic liquid // 1993. V.U.Z. Mashinostr. V.6 P. 1.

4. Bashtovoi V.G., G. Challant, Volkova O.Yu. Boiling Heat Transfer in Magnetic Fluids// Journal of Magnetism and Magnetic Materials. 1993. V. 122. P. 305.

5. Junhong L., Jianming G., Zhiwei L. Experiments and mechanism analysis of pool boiling heat transfer enhancement with water-based magnetic fluid // Int J Heat Mass Transf. 2004. V. 41. P. 170.

6. Кобозев М.А., Симоновский А.Я. Метод измерения, экспериментальная установка и результаты измерения частоты образования пузырьков пара при кипении магнитной жидкости на одиночном центре парообразования // ЖТФ. 2007. Т. 77 №11. С. 31.

7. Симоновский А.Я., Яновский А.А. Влияние однородного магнитного поля на теплообмен при кипении магнитной жидкости на неограниченной поверхности // Вестник Ставропольского государственного университета. 2011.

8. Syam S.L.; Singh M.K., Sousa A. Investigation of thermal conductivity and viscosity of Fe3O4 nanofluid for heat transfer applications // International Communications in Heat and Mass Transfer. 2013. V. 44 P. 7-14.

9. Yanovskii A.A., Simonovskii A.Ya., Klimenko E.M. On the Inluence of the Magnetic Field upon Hydrogasdynamic Processes in a Boiling Magnetic Fluid // Surface Engineering and Applied Electrochemistry. 2014. V. 50. № 3. P. 260.

10. Yanovskiy A.A., Simonovsky A.Ya., Kholopov V.L., Chuenkova I.Yu. Heat Transfer in Boiling Magnetic Fluid in a Magnetic Field // Solid State Phenomena. 2015. № 233-234. P. 339.

11. Khoshmehr H.H., Saboonchi A., Shafii M.B., Jahani N. The study of magnetic field implementation on cylinder quenched in boiling ferro-fluid // Applied Thermal Engineering. 2014. V. 64. № 1-2. P. 331.

12. Zupan J., Renjo M.M. Thermal and rheological properties of water-based ferroluids and their applicability as quenching media // 20th International Conference on Magnetism. Conf. Proc. ICM 2015. V. 75. P. 1458.

13. Abdollahi A. Salimpour M.R., Etesami N. Experimental analysis of magnetic ield effect on the pool boiling heat transfer of a ferro-fluid // Applied Thermal Engineering. 2017. V.111. P.1101.