Finding of the generalized equation of thermal conductivity for porous heat-insulating materials

Authors

DOI:

https://doi.org/10.15587/2312-8372.2016.78688

Keywords:

convection, closed spherical pore, regression analysis, effective thermal conductivity

Abstract

The object of this research is the process of the heat transfer through porous heat insulating materials. The problematic place of research is the absence of a generalized equation of thermal conductivity, which makes unable to predict the effective thermal conductivity of the material at the structure formation stage. The reason of it is lack of complex entrance independent factors of porous structure that influence on the effective thermal conductivity. For determining of this factors the computer simulation was used, it includes three dimensional samples and simulation of thermal process. After it, obtained computer modeling results were confirmed by laboratory experiment with using of the thermal conductivity meter ITP-MH4 of the company «SKB Stroyprybor».

The regression equation of thermal conductivity for porous heat-insulating materials was found by the experimental design method, the analysis of it was showed that the most influence (80 %) on coefficient of effective thermal conductivity have the pore diameter along to the heat flow and the total impact of the pore diameter perpendicular to the heat flow with temperature gradient. The thermal conductivity of initial material without pores λmat in investigated range of 0,05 to 0,95 W/(m·K) isn't a significant factor. The temperature gradient doesn't linear and not directly proportional impact on the thermal conductivity of the final material.

The generalized equation of thermal conductivity and the main factors, which influence on the coefficient of effective thermal conductivity, allow improving the thermal conductivity of new insulation materials and making it possible to develop a complete theory of thermophysical parameters control of porous heat insulating materials by changing the porous structure.

Author Biography

Andrii Cheilytko, Zaporizhia State Engineering Academy, 226 Lenina ave., Zaoporozhia, Ukraine, 69006

Candidate of Technical Sciences, Associate Professor

Department of heating energy

References

  1. Fiedler, T., Pesetskaya, E., Öchsner, A., Gracio, J. (2006, May 15). Calculations of the Thermal Conductivity of Porous Materials. Advanced Materials Forum III, 754–758. doi:10.4028/0-87849-402-2.754
  2. Nakajima, H., Kim, S. Y., Park, J. S. (2009, May 1). Fabrication of porous aluminium with directional pores through thermal decomposition method. Journal of Physics: Conference Series, Vol. 165, 012063. doi:10.1088/1742-6596/165/1/012063
  3. Komissarchuk, O., Xu, Z., Hao, H., Zhang, X., Karpov, V. (2014). Pore structure and mechanical properties of directionally solidified porous aluminum alloys. China Foundry, Vol. 11, 1. Available: https://doaj.org/article/002c72e2e01345db8bf4fef190113057
  4. Misiuriaev, S. A., Tsareva, A. N., Nechaeva, N. N., Yumangulova, A. Yu. (2016). Teploisoliatsionnyi poristyi material. Traditsii i innovatsii v stroitel'stve i arhitekture. Stroitel'nye tehnologii. Samara: Samarskii gosudarstvennyi arhitekturno-stroitel'nyi universitet, 102–106.
  5. Cheilytko, A. O. (2016). Doslidzhennia mozhlyvosti zminy koefitsiientu teploprovidnosti metaliv shliakhom zminy rozmiriv ta roztashuvannia por. Intehrovani tekhnolohii ta enerhozberezhennia, 2, 82–89.
  6. Cheilytko, A. (2013). Study of vesiculation in intumescent material. Technology Audit And Production Reserves, 5(4(13)), 38–40. Available: http://journals.uran.ua/tarp/article/view/18251/16063
  7. Hassan, S., Israr, A., Ali, H., Aslam, W. (2016, February 3). Effective thermal conductivity of multiple-phase transversely isotropic material having coupled thermal system. Proceedings of the International Conference on Advanced Materials and Engineering Structural Technology (ICAMEST 2015), April 25-26, 2015, Qingdao, China. Informa UK Limited, 237–241. doi:10.1201/b20958-52
  8. Tarasov, V. E. (2016, February). Heat transfer in fractal materials. International Journal of Heat and Mass Transfer, Vol. 93, 427–430. doi:10.1016/j.ijheatmasstransfer.2015.09.086
  9. Pia, G., Casnedi, L., Sanna, U. (2016, April). Porosity and pore size distribution influence on thermal conductivity of yttria-stabilized zirconia: Experimental findings and model predictions. Ceramics International, Vol. 42, № 5, 5802–5809. doi:10.1016/j.ceramint.2015.12.122
  10. Li, Y., Wang, Y. (2011, April). Calculation of equivalent thermal conductivity of Gasar porous materials. International Conference on Electric Information and Control Engineering, April 15-17, 2011, Wuhan. Institute of Electrical and Electronics Engineers (IEEE), 4034–4037. doi:10.1109/iceice.2011.5777111
  11. Cheilytko, A. (2013). Investigation influence of pores on the thermal conductivity of the material. Technology Audit And Production Reserves, 2(2(10)), 14–17. Available: http://journals.uran.ua/tarp/article/view/12964/10857
  12. Pabst, W., Gregorova, E. (2014, September). Conductivity of porous materials with spheroidal pores. Journal of the European Ceramic Society, Vol. 34, № 11, 2757–2766. doi:10.1016/j.jeurceramsoc.2013.12.040
  13. Yurkevich, A. A. (2013). Heat transfer in closed air cavity construction materials and products. Mezdunarodnyj naucno-issledovatel'skij zurnal, № 8 (15), Part 2, 78–83. Available: http://research–journal.org/wp–content/uploads/2011/10/8–2–15_d.pdf
  14. Dehghan, M., Valipour, M. S., Keshmiri, A., Saedodin, S., Shokri, N. (2016, January). On the thermally developing forced convection through a porous material under the local thermal non-equilibrium condition: An analytical study. International Journal of Heat and Mass Transfer, Vol. 92, 815–823. doi:10.1016/j.ijheatmasstransfer.2015.08.091
  15. Korepanov, E. V., Didenko, V. N. (2003). Raschet koeffitsienta konvektsii v vosdushchnyh polostiah shchtuchnyh stroitel'nyh isdelii. Materialy Chetvertoi Rossiiskoi nauchno-tehnicheskoi konferentsii «Energosberezhenie v gorodskom hosiaistve, energetike, promyshchlennosti», 24-25 aprelia 2003, Ul'ianovsk, 243–245.

Downloads

Published

2016-09-29

How to Cite

Cheilytko, A. (2016). Finding of the generalized equation of thermal conductivity for porous heat-insulating materials. Technology Audit and Production Reserves, 5(1(31), 4–10. https://doi.org/10.15587/2312-8372.2016.78688

Issue

Vol. 5 No. 1(31) (2016): Mathematical modeling. Mechanical engineering and machine building. Electrical engineering and industrial electronics

Section

Mathematical Modeling: Original Research

License

Copyright (c) 2016 Andrii Cheilytko

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

The consolidation and conditions for the transfer of copyright (identification of authorship) is carried out in the License Agreement. In particular, the authors reserve the right to the authorship of their manuscript and transfer the first publication of this work to the journal under the terms of the Creative Commons CC BY license. At the same time, they have the right to conclude on their own additional agreements concerning the non-exclusive distribution of the work in the form in which it was published by this journal, but provided that the link to the first publication of the article in this journal is preserved.