Analysis of Combined Heat Transfer through the Core Materials of VIPs with Various Scattering Properties
Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33122
Analysis of Combined Heat Transfer through the Core Materials of VIPs with Various Scattering Properties

Authors: Jaehyug Lee, Tae-Ho Song

Abstract:

Vacuum Insulation Panel (VIP) can achieve very low thermal conductivity by evacuating its inner space. Heat transfer in the core materials of highly-evacuated VIP occurs by conduction through the solid structure and radiation through the pore. The effect of various scattering modes in combined conduction-radiation in VIP is investigated through numerical analysis. The discrete ordinates interpolation method (DOIM) incorporated with the commercial code FLUENT® is employed. It is found that backward scattering is more effective in reducing the total heat transfer while isotropic scattering is almost identical with pure absorbing/emitting case of the same optical thickness. For a purely scattering medium, the results agrees well with additive solution with diffusion approximation, while a modified term is added in the effect of optical thickness to backward scattering is employed. For other scattering phase functions, it is also confirmed that backwardly scattering phase function gives a lower effective thermal conductivity. Thus the materials with backward scattering properties, with radiation shields are desirable to lower the thermal conductivity of VIPs.

Keywords: Combined conduction and radiation, discrete ordinates interpolation method, scattering phase function, vacuum insulation panel.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1337631

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 3057

References:


[1] J. Iwaro, A. Mwasha, “A review of building energy regulation and policy for energy conservation in developing countries,” Energy Policy, 38(12), 2010, pp. 7744-7755.
[2] R. Baetens, B.P. Jelle, J.V. Thue, M.J. Tenpierik, S. Grynning, S. Uvsløkk, and A. Gustavsen, “Vacuum insulation panels for building application: A review and beyond,” Energy and Buildings 42 (2), 2010, pp. 147–172.
[3] J.S. Kwon, C.H. Jang, H. Jung, and T.H. Song, “Effective thermal conductivity of various filling materials for vacuum insulation panels,” Int J Heat and Mass Transfer 52, 2009, pp. 5525–5532.
[4] S. Rosseland, Theoretical Astrophysics; Atomic theory and the analysis of stellar atmospherers and envelopes, Clarendon Press, Oxford, 1936.
[5] M.F. Modest, Radiative heat transfer, 3rd edn. Academic Press, 2013.
[6] R. Conquard and D. Baillis, “Modeling of heat transfer in low-density EPS foams,” J. Heat Transfer 28 (6), 2006, pp. 538–549.
[7] J. Kim, C. Jang, T.-H. Song, “Combined heat transfer in multi-layered radiation shields for vacuum insulation panels: Theoretical/numerical analyses and experiment,” Applied Energy 94, 2012, pp. 295-302.
[8] R. Caps, J. Fricke, “Thermal conductivity of opacified powder filler materials for vacuum insulations,” Int J Thermophysics 21, 2000, pp. 445-452.
[9] P. Scheuerpflug, R. Caps, D. Büttner, J. Fricke, “Apparent thermal conductivity of evacuated SiO,-aerogel tiles under variation of radiative boundary conditions,” Int. J. Heat Mass Transfer 28, 1985, pp. 2299-2306.
[10] J. Fricke and R. Caps, “Heat transfer in thermal insulations—recent progress in analysis,” Int. J. Thermophys. 9, 1988, pp. 885–895.
[11] M. Spinnler, E.R.F. Winter, and R. Viskanta, “Studies on high-temperature multilayer thermal insulations,” Int. J. Heat Mass Transfer 47, 2004, pp. 1305–1312.
[12] J. Lee, I. Yeo, W.K. Kang, T-H. Song, “Analysis of combined heat transfer through interstitial materials of VIPs,” Proc. 8th International Symposium on Heating, Ventilation and Air Conditioning. Springer Berlin Heidelberg, 2014.
[13] C. Jang, H. Jung, J. Lee, T-H. Song. (2013). Radiative heat transfer analysis in pure scattering layers to be used in vacuum insulation panels. Applied Energy 112: 703-709.
[14] K.B. Cheong, T.H. Song, “An alternative discrete ordinates method with interpolation and source differencing for two-dimensional radiative transfer problems,” Numerical Heat Transfer Part B 32, 1997, pp. 107-125.
[15] K. Kim, T.H. Song, “Discrete ordinates interpolation method incorporated into a flow and energy solver for solution of combined heat transfer problems,” Journal of Quantitative Spectroscopy and Radiative Transfer 111 (14), 2010, pp. 2070-2083.
[16] C.L. Tien and G.R. Cunnington, “Cryogenic insulation heat transfer,” Adv Heat Transfer, vol. 9, Academic Press, New York, 1973, pp. 349-417.
[17] W.W. Yuen, L.W. Wong, “Heat transfer by conduction and radiation in a one-dimensional absorbing emitting and anisotropically-scattering medium,” ASME J. Heat Transfer 102, 1980, pp. 303–307.
[18] T.K. Kim, H.S. Lee, “Effect of anisotropic scattering on radiative heat transfer in two-dimensional rectangular enclosures,” Int J Heat Mass Transfer 31, 1988, pp. 1711–1721.
[19] R. Viskanta, R.J. Grosh, “Effect of surface emissivity on heat transfer by simultaneous conduction and radiation,” Int. J. Heat Mass Transfer 5, 1962, pp. 729–734.