THERMAL SCIENCE

International Scientific Journal

THREE-DIMENSIONAL SIMULATION OF CONTROLLED COOLING OF ELECTRONIC COMPONENT BY NATURAL AND MIXED CONVECTION

ABSTRACT
The present study is the 3-D simulation of cooling control of electronic component, by natural convection and mixed convection in a cubical enclosure, filled with air. The heating square portion similar to the integrated electronic device and releasing a constant flux is placed on the right vertical wall of the enclosure. The same wall has, in its upper part, an extractor, while the rest of the considered wall is adiabatic. Its opposite wall has an opening maintained at a cold temperature. For low temperatures, the cooling of the component is provided by natural convection, however, in the case of strong temperature gradients, the extractor, operating at variable velocity, allows the evacuation of the dissipated heat. The cooling control of the component, the temperature distribution as well as the flow of fluid in the cavity is studied according to the governing parameters, namely the Rayleigh and Reynolds numbers. The obtained results show that the control cooling of the electronic components has a great industrial interest compared to the continuous cooling (ventilation), by an optimal choice of the governing parameters and the material constituting the components.
KEYWORDS
PAPER SUBMITTED: 2019-05-08
PAPER REVISED: 2020-05-22
PAPER ACCEPTED: 2020-05-24
PUBLISHED ONLINE: 2020-06-07
DOI REFERENCE: https://doi.org/10.2298/TSCI190508181B
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2021, VOLUME 25, ISSUE Issue 4, PAGES [2565 - 2577]
REFERENCES
  1. Bejan, A. , and Kraus, A. D , Heat Transfer Handbook, John Wiley, New York, USA, 2003
  2. Goldstein, R.J. , et al. , A review of 2003 literature, Int. J. of Heat and Mass Transfer. , 49 (2006), pp. 451-534
  3. Sharif, M.A.R. , and Mohammad, T.R. , Natural convection in cavities with constant flux heating at the bottom wall and isothermal cooling from the sidewalls, Int. J. Therm. Sci. , 44 (2005), pp. 865-878
  4. Ben Cheikh, N. , Ben Beya, B. , and Lili, T. ,Influence of thermal boundary conditions on natural convection in a square enclosure partially heated from below, Int. J. Heat and Mass Transfer, 34 (2007), pp. 369-379.
  5. Ben-Cheikh, N. , Campo, A. , Ouertatani, N. , and Lili, T. ,Three-dimensional study of heat and fluid flow of air and dielectric liquids filling containers partially heated from below and entirely cooled from above, Int. J. Heat Transfer., 37 (2010), pp. 449-456.
  6. Fusegi, T. , Hyun, J.M. , Kuwahara, K. , and Farouk, B. ,A numerical study of three-dimensional natural-convection in a differentially heated cubical enclosure, Int. J. Heat Mass Transfer., 34 (1991), pp 1543-1557.
  7. Frederick, R.L. , and Quiroz, F. ,On the transition from conduction to convection regime in a cubical enclosure with a partially heated wall, Int. J. Heat Transfer, 44 (2001), pp 1699-1709.
  8. Papanicolaou, E., Jaluria, Y., Mixed convection from a localized heat source in a cavity with conducting walls: a numerical study, Numerical Heat Transfer, Part A Applications, 23 (4) (1993), pp 463-484.
  9. Yücel, C. , Hasnaoui, M.. , Robillard, L. , and Bilgen, E. , Mixed convection heat transfer in open ended inclined channels with discrete isothermal heating, Numerical Heat Transfer, Part A, 24 (1993), pp 109-126.
  10. Shuja, S.Z., Yilbas, B.S., and Iqbal M.O. , Mixed convection in a square cavity due to heat generating rectangular body: Effect of cavity exit port locations, International Journal of Numerical Methods for Heat & Fluid Flow, 10 (8) (2000), pp 824-841,
  11. Manca, O., Nardini, S. ,Khanafer, K. , and Vafai, K. , Effect of heated wall position on mixed convection in a channel with an open cavity, Numer Heat Transfer, Part A, 43 ,3 (2003), pp 259-282
  12. Bahlaoui, A., Raji, A. and Hasnaoui, M. , Coupling between mixed convection and radiation in an inclined channel locally heated, J Mech Eng., 55 (2005), pp 45-57.
  13. Saha, S., Saha, G., Ali, M,. and Quamrul Islam, M., Combined free and forced convection inside a two-dimensional multiple ventilated rectangular enclosure, ARPN Journal of Engineering and Applied Sciences, 1 (2006), pp 23-35.
  14. Manca, O., Nardini, S., and Vafai, K. , Experimental investigation of mixed convection in a channel with an open cavity, Experimental heat transfer , 19 (1) (2006), pp.53-68.
  15. Raji, A., Hasnaoui, M., and Bahlaoui, A., Numerical study of natural convection dominated hea transfer in a ventilated cavity: Case of forced flow playing simultaneous assisting and opposing roles, International Journal of Heat and Fluid Flow, 29 (4) (2008), pp 1174-1181
  16. Bahlaoui, A., Raji, A.,Hasnaoui, M., Naïmi, M., Makayssi, T., and Lamsaadi, M., Mixed convection cooling combined with surface radiation in a partitioned rectangular cavity, Energy Conversion and Management, 50 (3) (2009), pp 626-635.
  17. Bahlaoui, A., Raji, A., Hasnaoui, M., Ouardi, C., and Makayssi, T., Height partition effect on combined mixed convection and surface radiation in a vented rectangular cavity, Journal of Applied Fluid Mechanics, 4 (2011), pp 89-96.
  18. Gupta, S. K., Chatterjee D., and Mondal, B., Investigation of mixed convection in a ventilated cavity in the presence of a heat conducting circular cylinder, Numer Heat Transfer, Part A, 67 (1) (2015), pp 52-74.
  19. Papanicolaou, E., Jaluria, Y., 'Mixed convection from an isolated heat source in a rectangular enclosure, Numerical Heat Transfer,18 (4) (1991), pp 427-461
  20. Hsu, T. H., et al., Mixed convection in a partially divided rectangular enclosure, Numerical Heat Transfer, Part A Applications, 31 (6) (1991), pp 655-683.
  21. Raji, A., and Hasnaoui, M., Mixed convection heat transfer in a rectangular cavity ventilated and heated from the side, NumericalHeat Transfer, Part A Applications, 33 (5) (1998), pp 533-548.
  22. Raji, A., and Hasnaoui, M., Corrélations en convection mixte dans des cavités ventilées, Revue générale de thermique, 37 (10) (1998), pp 874-884.
  23. Omri., A. and Ben Nasrallah, S., Control volume finite element numerical simulation of mixed convection in an air-cooled cavity, Numer Heat Transfer, Part A,36.(6) (1999), pp 615-637
  24. Raji, A., and Hasnaoui, M., Mixed convection heat transfer in ventilated cavities with opposing and assisting flows, Engineering Computations, 17 (5) (2000), pp 556-572.
  25. Raji, A. and Hasnaoui, M., Combined mixed convection and radiation in ventilated cavities, EngComput: Int J Computer-Aided Eng Software, 18 (7) (2001), pp 922-949
  26. Singh, S., Sharif, M. A. R., Mixed convective cooling of a rectangular cavity with inlet and exit openings on differentially heated side walls, Numerical Heat Transfer: Part A: Applications, 44(3) (2003), pp 233-253
  27. Saha, et al., Mixed convection in an enclosure with different inlet and exit configurations, Journal of Applied Fluid Mechanics, 1 (2008), pp 78-93.
  28. Rahman, el al., Effect of the presence of a heat conducting horizontal square block on mixed convection inside a vented square cavity, Nonlinear Analysis: Modelling and Control, 14(4) (2009), pp 531-548
  29. Stiriba, Y., et al., Numerical study of three-dimensional laminar mixed convection past an open cavity, International Journal of Heat and Mass Transfer, 53 (21) (2010), pp 4797-4808.
  30. Moraga, N. O., Lopez, S. E., Numerical simulation of three-dimensional mixed convection in an air-cooled cavity, Numerical Heat Transfer, Part A: Applications, 45 (8) (2004), pp 811-824
  31. Doghmi, H., Abourida, B., Belarche, L., Sannad, M., and Ouzaouit, M., Effect of the inlet opening on mixed convection inside a 3-D ventilated cavity, Thermal science, 22(6a) (2018), pp 2413-2424.
  32. Doghmi, H., Abourida, B., Belarche, L., Sannad, M., and Ouzaouit, M., Three-dimensional mixed convection heat transfer in a partially heated ventilated cavity, Thermal Science , 35 (2020), 3B,pp 1895-1907
  33. Patankar, S.V., Numerical Heat Transfer and Fluid Flow, McGraw-Hill,. New York., USA, 1980.

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