Investigation of heat exchange in a blown dense layer of granular materials

Authors

  • Antonina Solodka V. S. Martynovskyi Educational & Scintific Institute of Cold, Cryotechnologies and Environmental Energy of Odessa National Academy of Refrigeration Dvoryanska str., 1/3, Odessa, Ukraine, 65082, Ukraine https://orcid.org/0000-0002-4043-7667
  • Natalya Volgusheva V. S. Martynovskyi Educational & Scintific Institute of Cold, Cryotechnologies and Environmental Energy of Odessa National Academy of Refrigeration Dvoryanska str., 1/3, Odessa, Ukraine, 65082, Ukraine https://orcid.org/0000-0002-9984-6502
  • Irina Boshkova V. S. Martynovskyi Educational & Scintific Institute of Cold, Cryotechnologies and Environmental Energy of Odessa National Academy of Refrigeration Dvoryanska str., 1/3, Odessa, Ukraine, 65082, Ukraine https://orcid.org/0000-0001-5989-9223
  • Alexandr Titlov Odessa National Academy of Food Technologies Kanatna str., 112, Odessa, Ukraine, 65039, Ukraine https://orcid.org/0000-0003-1908-5713
  • Andrey Rozhentsev Odessa National Academy of Food Technologies Kanatna str., 112, Odessa, Ukraine, 65039, Ukraine https://orcid.org/0000-0001-7931-1239

DOI:

https://doi.org/10.15587/1729-4061.2017.112217

Keywords:

heat exchange, granular material, moving layer, stationary, gas flow, temperature curves

Abstract

Experimental studies of heat exchange between a dense layer of granular material and a stream of heated air have been carried out. As a granular material, claydite and gravel were used in a moving and a stationary layer. Temperature curves were obtained for the air flow and the solid component at the inlet and outlet of the installation. The shape of the curves indicates presence of two distinct zones with different heating rates. It was stated that it is expedient to set the heating period in the heat accumulators with a stationary bed within the first period which is characterized by a high heating rate. When calculating duration of the heating period, it is rational to take the value of the final material temperature 10‒15 % lower than the temperature of the heating air at the inlet. It was established that the coefficient of intercomponent heat exchange depends on the gas velocity, the velocity of the bed motion, the gas temperature at the input to the installation and the process duration. It was found that the curves of the dependence of the coefficients of intercomponent heat exchange on the process duration are described by a sigma function.

Intensity of heat transfer for a moving layer in the investigated region was commensurable or somewhat higher than that for a stationary layer. It was shown that claydite is the preferred material for a granular packing. The time to onset of a stationary mode for a moving claydite layer was reduced by 2.4 times in comparison with gravel layer and by 2.2 times for a stationary layer.

Author Biographies

Antonina Solodka, V. S. Martynovskyi Educational & Scintific Institute of Cold, Cryotechnologies and Environmental Energy of Odessa National Academy of Refrigeration Dvoryanska str., 1/3, Odessa, Ukraine, 65082

Postgraduate student

Department of Heat-and-Power Engineering and Fuel Pipeline Transportation

Natalya Volgusheva, V. S. Martynovskyi Educational & Scintific Institute of Cold, Cryotechnologies and Environmental Energy of Odessa National Academy of Refrigeration Dvoryanska str., 1/3, Odessa, Ukraine, 65082

PhD, Associate Professor

Department of Heat-and-Power Engineering and Fuel Pipeline Transportation

Irina Boshkova, V. S. Martynovskyi Educational & Scintific Institute of Cold, Cryotechnologies and Environmental Energy of Odessa National Academy of Refrigeration Dvoryanska str., 1/3, Odessa, Ukraine, 65082

Doctor of Technical Sciences, Associate Professor

Department of Heat-and-Power Engineering and Fuel Pipeline Transportation

Alexandr Titlov, Odessa National Academy of Food Technologies Kanatna str., 112, Odessa, Ukraine, 65039

Doctor of Technical Sciences, Professor, Head Department

Department of Heat-and-Power Engineering and Fuel Pipeline Transportation

Andrey Rozhentsev, Odessa National Academy of Food Technologies Kanatna str., 112, Odessa, Ukraine, 65039

Doctor of Technical Sciences, Professor

Department of Heat-and-Power Engineering and Fuel Pipeline Transportation

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Published

2017-10-30

How to Cite

Solodka, A., Volgusheva, N., Boshkova, I., Titlov, A., & Rozhentsev, A. (2017). Investigation of heat exchange in a blown dense layer of granular materials. Eastern-European Journal of Enterprise Technologies, 5(8 (89), 58–64. https://doi.org/10.15587/1729-4061.2017.112217

Issue

Vol. 5 No. 8 (89) (2017): ENERGY-SAVING TECHNOLOGIES AND EQUIPMENT

Section

Energy-saving technologies and equipment

License

Copyright (c) 2017 Antonina Solodka, Natalya Volgusheva, Irina Boshkova, Alexandr Titlov, Andrey Rozhentsev

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