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Book cover for Insulation Materials, Testing and Applications
ASTM Selected Technical Papers
Insulation Materials, Testing and Applications
By
DL McElroy
DL McElroy
1
Oak Ridge National Laboratory
,
Oak Ridge, Tennessee
;
editor
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JF Kimpflen
JF Kimpflen
2
Certain-Teed Corporation
,
Valley Forge, Pennsylvania
;
symposium co-chairman and editor
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ISBN-10:
0-8031-1278-5
ISBN:
978-0-8031-1278-0
No. of Pages:
769
DOI:
https://doi.org/10.1520/STP1030-EB
Publisher:
ASTM International
Publication date:
1990
eBook Chapter

Radiant Heat Transfer in Extremely Low Density Fibrous Assemblies

By
RW Dent
RW Dent
1
Albany International Research Company
,
Mansfield, MA 02048-9114
.
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,
J Skelton
J Skelton
1
Albany International Research Company
,
Mansfield, MA 02048-9114
.
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,
JG Donovan
JG Donovan
1
Albany International Research Company
,
Mansfield, MA 02048-9114
.
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Doi:
https://doi.org/10.1520/STP23300S
Page Count:
27
  • Published:
    1990

In very low density insulating assemblies, heat transfer occurs mainly by gas phase conduction, by convention, and by radiation. Many attempts have been made to analyze the parameters that control the radiant component of this heat transfer using electromagnetic theory based on the Maxwell equations. Extensive solutions are available in the literature for spheres but few results have been calculated for cylinders (which would model fibrous insulations), although the relevant equations have been given by Van de Hulst and by Larkin and Churchill. Larkin and Churchill give appropriate values for “real” refractive indices only, with zero absorption.

We have now obtained complete “complex” solutions as functions of fiber diameter and the fiber optical properties of refractive index and absorption coefficient (or dielectric constant). These solutions allow a full understanding of the roles of scattering and absorption in radiant energy transfer and show how these can be optimized for various materials as a function of wave-length (or temperature).

Once the radiant heat transfer is minimized for single isolated cylinders, we consider how this translates to a low density assembly of many such cylinders or fibers. The results show that radiant heat transfer can be minimized by the selection of an optimum fiber diameter and that this optimum differs for each material and for different absorption coefficients (as these affect the real and imaginary parts of the refractive index which determine the heat transfer).

Keywords:
radiant heat transfer, fibrous assemblies, density, insulation, cylinders, fiber diameter, optical properties, refractive index, absorption coefficient

References

1.
Pelanne
,
C. M.
, “
Experiments on the Separation of Heat Transfer Mechanisms in Low Density Fibrous Insulation
,” in
Thermal Conductivity
,
Plenum Press
,
New York
,
1969
, p. 897.
2.
Bomberg
,
M.
 and
Klarsfeld
,
S.
, “
Semi-Empirical Model of Heat Transfer in Dry Mineral Fiber Insulation
,”
Journal of Thermal Insulation
, Vol.
6
, No.
1
,
1983
, p. 156.
3.
Dent
,
R. W.
,
Donovan
,
J. G.
,
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, and
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Development of Synthetic Down Alternatives
,” Natick Report AD,
1984
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4.
Larkin
,
B. K.
 and
Churchill
,
S. W.
, “
Heat Transfer Through Porous Insulations
,”
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5
, No.
4
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1959
, p. 467.
5.
Schuster
,
A.
, “
Radiation Through a Foggy Atmosphere
,”
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, No.
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,
1905
, p. 1.
6.
Hamaker
,
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, “
Radiation and Heat Conduction in Light Scattering Material
,”
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, Vol.
2
,
1947
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7.
Van de Hulst
,
H. C.
,
Light Scattering by Small Particles
,
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,
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,
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.
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Stratton
,
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,
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,
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,
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,
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9.
Mie
,
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, “
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,”
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, Vol.
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, No.
25
,
1908
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10.
Larkin
,
B. K.
 and
Churchill
,
S. W.
, “
Scattering and Absorption of Electromagnetic Radiation by Infinite Cylinders
,”
Journal of the Optical Society of America
 0030-3941, Vol.
49
, No.
2
,
1959
, p. 188.
11.
Aronson
,
J. R.
 et al, “
Infrared Emittance of Fibrous Materials
,”
Applied Optics
 0003-6935, Vol.
18
, No.
15
,
1979
, p. 2622.
12.
Brillouin
,
L.
, “
The Scattering Cross-Section of Spheres for Electromagnetic Waves
,”
Journal of Applied Physics
 0021-8979, Vol.
20
, No.
11
,
1949
, p. 1110.
13.
Borne
,
M.
 and
Wolf
,
E.
,
Principles of Optics
, 4th ed.,
Pergamon Press
,
Oxford
,
1970
.
14.
McKay
,
N. L.
,
Timusk
,
T.
, and
Farnworth
,
B.
, “
Determination of Optical Properties of Fibrous Thermal Insulation
,”
Journal of Applied Physics
 0021-8979, Vol.
55
, No.
11
,
1984
, p. 4064.
15.
Morton
,
W. E.
 and
Hearle
,
J. W. S.
,
Physical Properties of Textile Fibres
,
Butterworths
,
London
,
1962
.
16.
Brandrup
,
I.
 and
Immergut
,
E. H.
,
Polymer Handbook
,
Wiley Interscience
,
New York
,
1975
.
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