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Reduction of radiative heat transfer in thermal insulations by use of dielectric coated fibers
0735-1933/89 $3.00 + .00 PrintedintheUnited States
INT. COMM. HEAT MASS TRANSFER Vol. 16, pp. 851-860, 1989 ©Pergamon Press pie
R E D U C T I O N OF R A D I A T I V E H E A T T R A N S F E R IN T H E R M A L I N S U L A T I O N S BY USE OF D I E L E C T R I C C O A T E D F I B E R S
Department
T. W. Tong and P. S. Swathi of M e c h a n i c a l and A e r o s p a c e E n g i n e e r i n g A r i z o n a State U n i v e r s i t y Tempe, AZ 85287 G. R. C u n n i n g t o n , Jr. Palo Alto R e s e a r c h L a b o r a t o r y Palo Alto, CA 94304
Lockheed
(Communicated by J.P. Hartnett and W.l. Minkowycz) ABSTRACT This paper reports an analysis on using c o a t e d silica fibers to reduce r a d i a t i v e heat t r a n s f e r t h r o u g h thermal insulations. C o n s i d e r a t i o n s were given to s i l i c a fibers of d i a m e t e r s 2, 5, and I0 ~m. They were c o a t e d w i t h either a 0.2 #m silicon c o a t i n g or a 0.2 ~m silicon inner c o a t i n g and a 0.I ~m s i l i c a outer coating. Calculations were p e r f o r m e d to d e t e r m i n e the ratio of r a d i a t i v e heat flux for c o a t e d fibers to that for u n c o a t e d fibers, The c a l c u l a t i o n s were made for b o t h constant fiber number d e n s i t y and c o n s t a n t bulk density. It was found that k e e p i n g the fiber number d e n s i t y c o n s t a n t r e s u l t e d in larger r e d u c t i o n s in r a d i a t i v e heat flow. For the test c o n d i t i o n s examined, r e d u c t i o n as high as 75 percent was shown to be possible.
Introduction An earlier
investigation
had on the r a d i a t i v e potential transfer been
for using in s i l i c a
extended
properties silicon
thermal
for m u l t i p l e
of s i l i c a
coatings
coatings
of the r a d i a t i v e
present
presents
851
fibers
[i].
to permit
properties
an analysis,
dielectric
to reduce
insulations
tai]orability paper
of the effect
coatings
indicated
radiative
The study
high
heat
[l] has
broader
of the fibers
w h i c h makes
[2].
use of the
The
852
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
findings through
in Refs. silica
I and 2,
on r e d u c i n g
insulations
for
Vol. 16, No. 6
radiative
temperatures
heat
ranging
transfer
from
1000
to
1600 K.
Because widely work
of
used
their
in many
considers
low b u l k thermal
insulations
or I0 ~m
in diameter.
coating.
To p r e v e n t
temperatures, also
made
Silicon oxidation
an outer
density,
silica
insulation
coating
of silica
parent
of 0.2 ~m thick of silicon made
fibers
have
applications.
been
The present
fibers
of 2, 5
is chosen
as the
at e l e v a t e d
of 0.I ~m thick
silica
is
considered. Analysis
Radiative
Properties
Figure The f i b e r coating
1 depicts is
assumed
thicknesses
The e x p r e s s i o n s
scattering
the to
fiber
geometry
be c i r c u l a r
are
uniform
and extinction
consideration.
and
infinitely
and the
incidence
for the r a d i a t i v e
(Osca)
under
properties,
(Oext)
i I
i
long. is
namely,
efficiencies,
the
and
I
COATINGS~
I FIBER---------
I
I
r
r
i i i INCIDENT WAVE
~
FIG l Geometry of fiber.
The
unpolarized.
the
Vol. 16, No. 6
RADIATIVE TRANSFER IN THERMAL INSULATIONS
back--scattered scattering These
fraction
albedo
radiative
incidence fiber,
(w)
(¢),
as the ratio
of incidence
of the coatings, and coatings
from all directions,
averaged
according
in Ref.
can be c o m p u t e d
the w a v e l e n g t h
of the fiber
are o b t a i n e d
can be found
is defined
properties
thicknesses
indexes
(bf)
2.
of Q s c a
to Qext"
the angle
(x),
the radius
and the complex
values
The single
once
are specified. for the
853
of of the
refractive
For
incidence
radiative
properties
to
r~/2 z=
21
(i)
z d¢ o0
where
z stands
scattered
for either
fraction
The a v e r a g e
0
sca or Qext" is given by
back-
2• IO sca bf de b-
:
f
(2)
6 sea
Radiative
Transfer
Heat
The analysis is o p t i c a l l y local
thick
radiative
approximated difference radiative
is c o n d u c t e d and
heat
the fibers
flux
between
are
process.
the b o u n d i n g conductivity
that
randomly
in an o p t i c a l l y
as a d i f f u s i o n
thermal
on the basis
surfaces
insulation
oriented.
thick
If the
the
medium
The
may be
temperature
is not
too
may be a p p r o x i m a t e d
large, as
a
[3,4]
3
4¢T m
(3)
[(I - ~ + 2~bf)oext] m where
T
m
is
temperatures, averaged
~ext
the
arithmetic
o is
extinction
=
the
mean of
bounding
Stefan-Boltzmann
coefficient
Oext d*N =
the
40extWf p~d
is
given
constant,
surface and the
by
(4)
854
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
where
d, • and p are
individual fibers
fibers,
the diameter,
respectively,
and Wf is the bulk
denominator
of the right
wavelength-averaged function
(ebx)
length
hand
and density
and N is the number
density
quantity
Vol. 16, No. 6
of the
side
density
insulation.
of Eq.
weighted
of the
(3)
against
of
The
is a the Planck's
at T m = I
~
ebk(Tm) dx
[(I
Making
use of Eqs.
between
uT:
~ + 2wbf)~ext] m
-
a coated
expression
(3) and
(4),
qr~coated
assuming
and an u n c o a t e d
for the r a d i a t i v e
• and N to be the same
insulation,
heat
flux
one can obtain
ratio
coated
[ x I (I - ~ + 2~bf)Qext d
constant,
the bulk
one obtains
the
density
of the
following
ratio:
qr,coated =
[RHS of Eq.
qr, u n c o a t e d Note
that
limits
for
the purpose
of the
integral
the
as
= [ x I (I - ~ + 2~bf)Oext d
For the case where
(5)
(I - ~ + 2~bf)qex t
(6)
uncoated insulation
is held
(Pd2)coated (6)](pdZ)uncoate d
of c o m p u t a t i o n
have been
the
replaced
(7)
lower
by
and upper
x I and
x 2,
respectively. Results Radiative
Properties for Qext'
Computations
the complex
-
refractive
and Friese
silicon.
The densities
g/cc,
a weighted
The w e i g h t e d silica
based
average
because
, and w have been -
reported
[6] for silica
respectively average
gf
index
Champtier
2.328
and D i s c u s s i o n
of silica [8].
by M a l i t s o n
the silicon
The density
is just
coating
[5]
and by Driscoll
and silicon
on the densities
density
carried
out using
and
[7]
for
are 2.2 g/cc
of the coated of silica
slightly
is thin,
higher
only
and
fiber
is
and silicon. than
0.2 pm as
that
of
Vol. 16, No. 6
mentioned
RADIATIVE TRANSFER IN THERMAL INSULATIONS
earlier.
to be 2, 5, and obtained
for
a silicon and
three
obtained,
the r a d i a t i v e
X 2 were
wavelength
chosen
range
at I000
wavelength 0.5 am
results fibers
range.
very
desirable
because
prevent
the fibers This,
oxidation.
substantially
the 2 ~m parent
fiber,
in the shorter
3.5,
there 6.5,
respectively. 1 for
x less
when
fiber.
coating,
are added,
fiber).
coatings
is in general
but
than 4 ~m for all
cases.
to
Qext
(3 to 8 pm
are added.
region
fiber
However,
is less
than
the
As far as bf is
an increase
scattering
to alter
At the shorter
region.
and 8 pm for the 2, 5, and
The
out to be
not added
wavelengths
wavelength
wavelength
The single
was
the
the coated
5 to 8 pm for the 5 pm parent
decreases
longer
coatings
From
~ is
and two coatings
turned
coating
longer
10 ~m parent
the d e c r e a s e
in the
has
of silica
that
one coatiug
2-4.
than 4 pm,
the parent
of the silicon When
Qext
than
outer
at the
wavelengths,
concerned,
with
than
were
7 to 8 ~m
by silica.
it is clear
in a way,
the silica
and 6 to 8 pm for the
increase
2-4,
properties
ratio
K.
characteristic shorter
over
rule with
in Figs.
in the
of low absorption
characteristics
it from
increases
a dip
At w a v e l e n g t h s
radiant
flux
to 1600
and bf are shewn
limits
integration
heat
to
This
trapezoidal
of i000
displays
in Figs.
small.
radiative
~'
different
between
range
is a typical
[9].
illustrated have
is r e l a t i v e l y
for
This
using
(7)
integration
The
for the radiative
Qext
to 1 b e c a u s e
difference
the
performed
1 degree
(6) and
of the b l a c k b o d y K.
(4)
the radiative
respectively.
at 1600
with
coating
at
Once
The
fiber
(3) and
properties
in Eqs.
chosen
were
inner
in Eqs.
ratios.
i0 pm,
silica
rule.
used
91 percent
for Oext'
insulations
close
radiative
were
results
a silicon
integrals
flux
1 and
for the t e m p e r a t u r e
wavelength
fiber;
trapezoidal
heat
as
(5) was
any coatings,
fibrous
the
Results
The results Without
The
diameters
purposes
with
they were
contains
in Eq.
fiber
silica
fiber
K and 95 percent
intervals.
obtained
very
coating.
by c o m p u t i n g
were
determine
energy
parent
and silica
of @ and a p p l y i n g
properties
silica
For c o m p a r i s o n
cases:
outer
evaluated
intervals
k I and
I0 pm.
coating;
a silica
were
The parent
855
at w a v e l e n g t h s
shorter
10 pm fibers,
albedo This
~ stays
very
is b e c a u s e
close
both
to
856
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
Vol. 16, No. 6
10
0.5Base Fbe, 2#m
---
:goofed Fiber '
---
F;ooled ;ibe, ' a,~r
"i,
~]i'er
0.4-
/:,\ /..-,:\ ,x I':' ,k./,'
IC~
2-
"A
/% /-,:,i,' "" (\I':.' ,7,,.
i! !,
"
/
r\
i
3
/;
:i,I,
0.3-
-0.6
0.2-
-OA
0.I
-I).2
b~
15
"2
0.0 2
0,8
4
6
5
7
g
I 2
I 3
I 4
I 5
I 6
I 7
I 8
I 9
0,0
10
x O•m) (a)
(b)
Radiative
FIG 2 p r o p e r t i e s for the 2 ~m s i l i c a and the c o a t e d fibers.
fiber
4 --
~ ; e ibur [:gm
--
C:~te¢ ~<,er I (bet
- - - C,:~ted Fiber :! [over
0.4-
0.8
0.3"
0.6
0.2"
-0.4
3-
,.<:.-..
I::3 •
':-'I',
-0.2
0
I 2
r 5
I 4
I 5
F 6
I ?
[ 8
0.0
[ 9
~ l l l J I I I 2 Z 4 5 6 7 8
(a)
Radiative
0.0 9
1
D
(b)
properties
and
the
FIG for
coated
3 the 5 #m s i l i c a
fibers.
fiber
Vol. 16, No. 6
RADIATIVE TRANSFER IN THERMAL INSULATIONS
857
0.5 --
~se Fiber ]0# Cooled Fiber I-boyer
1
Cooled ribel 2 Loyer
---
t
0.4-
- 0.8
0.3-
- 0.6
13
I,C::~ 0.2-
ol I 2
1
-0.2
0.0
I
l
I
3
4
,5
I 6
I 7
and
Radiative
The
results
number
for 63
the
less
the
and
except
that
in Figure
the
this
changes
in
number in
the
K.
insulation
is
66
smaller energy where
lower 6 shows
higher contained
I 8
I
9
10
fiber
results
61 are
mean
and
(7).
in
Fig.
5.
for
in
increase
region heat
and
For 63
flux
the
percent
the
percent.
The the
wavelengths Qext
occurs.
are
smaller
2 pm f i b e r .
ratio
for
at for
10 pm
because
reductions for
75
reduction
longer in
The
from
temperatures the
constant
applied.
percent. 64
for
(6)
corresponding
the
radiative
flux
are
is
applied,
the
Eqs.
ranges
The and
radiative
shown
heat
substantial
temperature the
are
coatings
reductions at
coating
density
in
insulation
1600
the
examining
defined
radiative
when
2 #m f i b e r
by
as
at
is
outer
the
ratio
achieved
radiant
silica
in
illustrated
flux
percent
are
blackbody
a
of
corresponding
reductions
I
7
spectrum.
nonabsorbing
best
is
5 pm f i b e r
fiber,
I
6
are
reduction
K to
I
,5
silica
constant
density
1000 the
be
for
reduction
I
4
FIG 4 p r o p e r t i e s for the I0 ~m and the c o a t e d fibers.
effect
heat
Significant
I
3
Transfer
can
radiative
I 2
(b)
combined
the
10
(a)
silicon
properties
I 9
x(~m)
Heat
The
[ 0
(.m)
Radiative
silica
-0.4
constant
is When
858
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
Vol. 16, No. 6
0.45
0.40
""""""..•" 21" ..*.'*'~"
Base Fiber l O/~m
0.35 s
•
• ,o
" Fiber 5Nm 0.30
•
,
,f
.,•../
~
m
'f/
Cooted Fiber 1-Loyer
---Coa(ed Fiber 2-Layer
f -"'" Base Fiber 2#m
0.25
0.20
1000
I
I
I
I
I
1I00
1200
1300
1400
1500
1600
To (K) Radiative
bulk
heat
density.
weight
of
This
the
reduction
in
that
observed
fact
that
maintain
FIG 5 for c o n s t a n t
situation
corresponds
insulation radiative for
there the
ratio
flux
heat
constant
are
same
fewer
bulk
properties
for
one
different,
the
radiative
consistently 60,
and
61
respectively.
the
be
transfer
fibers and flux
5,
and
to
is
in
the
tw o ratio
the
two is
reductions
that
the
not
coatings at
with at
than
due in
the
to
the
order
to
radiative
are
for
10 pm f i b e r s
The c o r r e s p o n d i n g
is
insulation
reduction
where
significant This
coatings
density.
case
Note
less
density.
number
the
fixed.
Although
The b e s t 2,
kept
number
density.
coating
higher. for
must
fiber
lO00 one 1600
significantly is K,
about
83,
coating, K are
46,
54,
Vol. 16, No. 6
RADIATIVE TRANSFER IN THERMAL INSULATIONS
025
I
I
I
I
I II
II
l
I
859
I
m . Cooted Fiber 1-Loyer ---Cooted Fiber 2-Loyer osss °~S
0.65
oS s# S s# SS
0.55
Bose Fiber 5#m~,.., ,*"
,,'
ssoss SS~' Base Fiber 2#m
, o.."- \
0,45-
-'°J
I
,./
ol /
..I__ ....
~.'..'~
Z'~'~'°''"
Bose Fiber lO#m~.__._
P
0.35
! 1000
"1
11O0
1200
I
I
I
1300
1400
1500
1600
To (K) Radiative
heat
and 60 percent. reductions fibers,
of 58,
flux
FIG 6 ratio for constant
The a d d i t i o n 57,
respectively,
of an outer
and 59 p e r c e n t
bulk
density.
coating
produced
for the 2, 5, and
at I000 K, and,
28,
I0 # m
45 and 52 p e r c e n t
at
1600 K. Conclusions It has been substantially applying
coated silicon
radiative
coatings
I0 #m fibers
were
by e i t h e r inner
demonstrated heat
that
transfer
to the fibers. considered. a 0.2 #m thick
coating
it is p o s s i b l e in s i l i c a
Insulations
The fibers silicon
coating
and a 0.I ~m s i l i c a
insulations
made
were
outer
to reduce
of 2, 5,
considered
and
to be
or a 0.2 ~m coating.
by
In
860
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
general,
smaller
t h e a d d i t i o n of a s i l i c a
reductions.
reduction density,
obtained
outer coating resulted
For the c o n d i t i o n s was
75 percent
and 63 percent
Vol. 16, No. 6
considered,
for constant
for constant
bulk
in
the
fiber
largest
number
density.
References i.
T. W. Tong, P. S. Swathi and G. R. C u n n i n g t o n , Thermal Insulation, ll, 7 (1987).
2.
P. S.
Swathi,
3.
T. W.
Tong,
Ph.D.
Q.
Thesis,
Arizona
S. Yang and C.
Jr.,
J.
State U n i v e r s i t y
L. Tien,
J.
Heat
(1989).
Transfer,
105,
76 ( 1 9 8 3 ) . 4.
K. Y. Wang, S. Kumar and C. Transfer, i, 289 ( 1 9 8 7 ) .
5.
I. H. Malitson,
J. Opt.
6.
R. J. C h a m p t i e r
and G. J.
7.
W. G. Driscoll, York (1987).
ed.,
8.
R. C. Weast,
J. Astle
M.
Soc.
T. W.
Tong and C.
Am.,
Friese,
Handbook
of C h e m i s t r y and Physics, 9.
L. Tien,
55,
J.
Thermophys.
1205
Heat
(1965).
Report
SAMSO-TR-202
(1974).
of Optics,
McGraw-Hill,
New
and W. H. Beyer, eds., CRC H a n d b o o k CRC Press, Baton Rouge (1986).
L. Tien,
J. Reat
Transfer,
56,
70
(1983).
INT. COMM. HEAT MASS TRANSFER Vol. 16, pp. 851-860, 1989 ©Pergamon Press pie
R E D U C T I O N OF R A D I A T I V E H E A T T R A N S F E R IN T H E R M A L I N S U L A T I O N S BY USE OF D I E L E C T R I C C O A T E D F I B E R S
Department
T. W. Tong and P. S. Swathi of M e c h a n i c a l and A e r o s p a c e E n g i n e e r i n g A r i z o n a State U n i v e r s i t y Tempe, AZ 85287 G. R. C u n n i n g t o n , Jr. Palo Alto R e s e a r c h L a b o r a t o r y Palo Alto, CA 94304
Lockheed
(Communicated by J.P. Hartnett and W.l. Minkowycz) ABSTRACT This paper reports an analysis on using c o a t e d silica fibers to reduce r a d i a t i v e heat t r a n s f e r t h r o u g h thermal insulations. C o n s i d e r a t i o n s were given to s i l i c a fibers of d i a m e t e r s 2, 5, and I0 ~m. They were c o a t e d w i t h either a 0.2 #m silicon c o a t i n g or a 0.2 ~m silicon inner c o a t i n g and a 0.I ~m s i l i c a outer coating. Calculations were p e r f o r m e d to d e t e r m i n e the ratio of r a d i a t i v e heat flux for c o a t e d fibers to that for u n c o a t e d fibers, The c a l c u l a t i o n s were made for b o t h constant fiber number d e n s i t y and c o n s t a n t bulk density. It was found that k e e p i n g the fiber number d e n s i t y c o n s t a n t r e s u l t e d in larger r e d u c t i o n s in r a d i a t i v e heat flow. For the test c o n d i t i o n s examined, r e d u c t i o n as high as 75 percent was shown to be possible.
Introduction An earlier
investigation
had on the r a d i a t i v e potential transfer been
for using in s i l i c a
extended
properties silicon
thermal
for m u l t i p l e
of s i l i c a
coatings
coatings
of the r a d i a t i v e
present
presents
851
fibers
[i].
to permit
properties
an analysis,
dielectric
to reduce
insulations
tai]orability paper
of the effect
coatings
indicated
radiative
The study
high
heat
[l] has
broader
of the fibers
w h i c h makes
[2].
use of the
The
852
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
findings through
in Refs. silica
I and 2,
on r e d u c i n g
insulations
for
Vol. 16, No. 6
radiative
temperatures
heat
ranging
transfer
from
1000
to
1600 K.
Because widely work
of
used
their
in many
considers
low b u l k thermal
insulations
or I0 ~m
in diameter.
coating.
To p r e v e n t
temperatures, also
made
Silicon oxidation
an outer
density,
silica
insulation
coating
of silica
parent
of 0.2 ~m thick of silicon made
fibers
have
applications.
been
The present
fibers
of 2, 5
is chosen
as the
at e l e v a t e d
of 0.I ~m thick
silica
is
considered. Analysis
Radiative
Properties
Figure The f i b e r coating
1 depicts is
assumed
thicknesses
The e x p r e s s i o n s
scattering
the to
fiber
geometry
be c i r c u l a r
are
uniform
and extinction
consideration.
and
infinitely
and the
incidence
for the r a d i a t i v e
(Osca)
under
properties,
(Oext)
i I
i
long. is
namely,
efficiencies,
the
and
I
COATINGS~
I FIBER---------
I
I
r
r
i i i INCIDENT WAVE
~
FIG l Geometry of fiber.
The
unpolarized.
the
Vol. 16, No. 6
RADIATIVE TRANSFER IN THERMAL INSULATIONS
back--scattered scattering These
fraction
albedo
radiative
incidence fiber,
(w)
(¢),
as the ratio
of incidence
of the coatings, and coatings
from all directions,
averaged
according
in Ref.
can be c o m p u t e d
the w a v e l e n g t h
of the fiber
are o b t a i n e d
can be found
is defined
properties
thicknesses
indexes
(bf)
2.
of Q s c a
to Qext"
the angle
(x),
the radius
and the complex
values
The single
once
are specified. for the
853
of of the
refractive
For
incidence
radiative
properties
to
r~/2 z=
21
(i)
z d¢ o0
where
z stands
scattered
for either
fraction
The a v e r a g e
0
sca or Qext" is given by
back-
2• IO sca bf de b-
:
f
(2)
6 sea
Radiative
Transfer
Heat
The analysis is o p t i c a l l y local
thick
radiative
approximated difference radiative
is c o n d u c t e d and
heat
the fibers
flux
between
are
process.
the b o u n d i n g conductivity
that
randomly
in an o p t i c a l l y
as a d i f f u s i o n
thermal
on the basis
surfaces
insulation
oriented.
thick
If the
the
medium
The
may be
temperature
is not
too
may be a p p r o x i m a t e d
large, as
a
[3,4]
3
4¢T m
(3)
[(I - ~ + 2~bf)oext] m where
T
m
is
temperatures, averaged
~ext
the
arithmetic
o is
extinction
=
the
mean of
bounding
Stefan-Boltzmann
coefficient
Oext d*N =
the
40extWf p~d
is
given
constant,
surface and the
by
(4)
854
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
where
d, • and p are
individual fibers
fibers,
the diameter,
respectively,
and Wf is the bulk
denominator
of the right
wavelength-averaged function
(ebx)
length
hand
and density
and N is the number
density
quantity
Vol. 16, No. 6
of the
side
density
insulation.
of Eq.
weighted
of the
(3)
against
of
The
is a the Planck's
at T m = I
~
ebk(Tm) dx
[(I
Making
use of Eqs.
between
uT:
~ + 2wbf)~ext] m
-
a coated
expression
(3) and
(4),
qr~coated
assuming
and an u n c o a t e d
for the r a d i a t i v e
• and N to be the same
insulation,
heat
flux
one can obtain
ratio
coated
[ x I (I - ~ + 2~bf)Qext d
constant,
the bulk
one obtains
the
density
of the
following
ratio:
qr,coated =
[RHS of Eq.
qr, u n c o a t e d Note
that
limits
for
the purpose
of the
integral
the
as
= [ x I (I - ~ + 2~bf)Oext d
For the case where
(5)
(I - ~ + 2~bf)qex t
(6)
uncoated insulation
is held
(Pd2)coated (6)](pdZ)uncoate d
of c o m p u t a t i o n
have been
the
replaced
(7)
lower
by
and upper
x I and
x 2,
respectively. Results Radiative
Properties for Qext'
Computations
the complex
-
refractive
and Friese
silicon.
The densities
g/cc,
a weighted
The w e i g h t e d silica
based
average
because
, and w have been -
reported
[6] for silica
respectively average
gf
index
Champtier
2.328
and D i s c u s s i o n
of silica [8].
by M a l i t s o n
the silicon
The density
is just
coating
[5]
and by Driscoll
and silicon
on the densities
density
carried
out using
and
[7]
for
are 2.2 g/cc
of the coated of silica
slightly
is thin,
higher
only
and
fiber
is
and silicon. than
0.2 pm as
that
of
Vol. 16, No. 6
mentioned
RADIATIVE TRANSFER IN THERMAL INSULATIONS
earlier.
to be 2, 5, and obtained
for
a silicon and
three
obtained,
the r a d i a t i v e
X 2 were
wavelength
chosen
range
at I000
wavelength 0.5 am
results fibers
range.
very
desirable
because
prevent
the fibers This,
oxidation.
substantially
the 2 ~m parent
fiber,
in the shorter
3.5,
there 6.5,
respectively. 1 for
x less
when
fiber.
coating,
are added,
fiber).
coatings
is in general
but
than 4 ~m for all
cases.
to
Qext
(3 to 8 pm
are added.
region
fiber
However,
is less
than
the
As far as bf is
an increase
scattering
to alter
At the shorter
region.
and 8 pm for the 2, 5, and
The
out to be
not added
wavelengths
wavelength
wavelength
The single
was
the
the coated
5 to 8 pm for the 5 pm parent
decreases
longer
coatings
From
~ is
and two coatings
turned
coating
longer
10 ~m parent
the d e c r e a s e
in the
has
of silica
that
one coatiug
2-4.
than 4 pm,
the parent
of the silicon When
Qext
than
outer
at the
wavelengths,
concerned,
with
than
were
7 to 8 ~m
by silica.
it is clear
in a way,
the silica
and 6 to 8 pm for the
increase
2-4,
properties
ratio
K.
characteristic shorter
over
rule with
in Figs.
in the
of low absorption
characteristics
it from
increases
a dip
At w a v e l e n g t h s
radiant
flux
to 1600
and bf are shewn
limits
integration
heat
to
This
trapezoidal
of i000
displays
in Figs.
small.
radiative
~'
different
between
range
is a typical
[9].
illustrated have
is r e l a t i v e l y
for
This
using
(7)
integration
The
for the radiative
Qext
to 1 b e c a u s e
difference
the
performed
1 degree
(6) and
of the b l a c k b o d y K.
(4)
the radiative
respectively.
at 1600
with
coating
at
Once
The
fiber
(3) and
properties
in Eqs.
chosen
were
inner
in Eqs.
ratios.
i0 pm,
silica
rule.
used
91 percent
for Oext'
insulations
close
radiative
were
results
a silicon
integrals
flux
1 and
for the t e m p e r a t u r e
wavelength
fiber;
trapezoidal
heat
as
(5) was
any coatings,
fibrous
the
Results
The results Without
The
diameters
purposes
with
they were
contains
in Eq.
fiber
silica
fiber
K and 95 percent
intervals.
obtained
very
coating.
by c o m p u t i n g
were
determine
energy
parent
and silica
of @ and a p p l y i n g
properties
silica
For c o m p a r i s o n
cases:
outer
evaluated
intervals
k I and
I0 pm.
coating;
a silica
were
The parent
855
at w a v e l e n g t h s
shorter
10 pm fibers,
albedo This
~ stays
very
is b e c a u s e
close
both
to
856
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
Vol. 16, No. 6
10
0.5Base Fbe, 2#m
---
:goofed Fiber '
---
F;ooled ;ibe, ' a,~r
"i,
~]i'er
0.4-
/:,\ /..-,:\ ,x I':' ,k./,'
IC~
2-
"A
/% /-,:,i,' "" (\I':.' ,7,,.
i! !,
"
/
r\
i
3
/;
:i,I,
0.3-
-0.6
0.2-
-OA
0.I
-I).2
b~
15
"2
0.0 2
0,8
4
6
5
7
g
I 2
I 3
I 4
I 5
I 6
I 7
I 8
I 9
0,0
10
x O•m) (a)
(b)
Radiative
FIG 2 p r o p e r t i e s for the 2 ~m s i l i c a and the c o a t e d fibers.
fiber
4 --
~ ; e ibur [:gm
--
C:~te¢ ~<,er I (bet
- - - C,:~ted Fiber :! [over
0.4-
0.8
0.3"
0.6
0.2"
-0.4
3-
,.<:.-..
I::3 •
':-'I',
-0.2
0
I 2
r 5
I 4
I 5
F 6
I ?
[ 8
0.0
[ 9
~ l l l J I I I 2 Z 4 5 6 7 8
(a)
Radiative
0.0 9
1
D
(b)
properties
and
the
FIG for
coated
3 the 5 #m s i l i c a
fibers.
fiber
Vol. 16, No. 6
RADIATIVE TRANSFER IN THERMAL INSULATIONS
857
0.5 --
~se Fiber ]0# Cooled Fiber I-boyer
1
Cooled ribel 2 Loyer
---
t
0.4-
- 0.8
0.3-
- 0.6
13
I,C::~ 0.2-
ol I 2
1
-0.2
0.0
I
l
I
3
4
,5
I 6
I 7
and
Radiative
The
results
number
for 63
the
less
the
and
except
that
in Figure
the
this
changes
in
number in
the
K.
insulation
is
66
smaller energy where
lower 6 shows
higher contained
I 8
I
9
10
fiber
results
61 are
mean
and
(7).
in
Fig.
5.
for
in
increase
region heat
and
For 63
flux
the
percent
the
percent.
The the
wavelengths Qext
occurs.
are
smaller
2 pm f i b e r .
ratio
for
at for
10 pm
because
reductions for
75
reduction
longer in
The
from
temperatures the
constant
applied.
percent. 64
for
(6)
corresponding
the
radiative
flux
are
is
applied,
the
Eqs.
ranges
The and
radiative
shown
heat
substantial
temperature the
are
coatings
reductions at
coating
density
in
insulation
1600
the
examining
defined
radiative
when
2 #m f i b e r
by
as
at
is
outer
the
ratio
achieved
radiant
silica
in
illustrated
flux
percent
are
blackbody
a
of
corresponding
reductions
I
7
spectrum.
nonabsorbing
best
is
5 pm f i b e r
fiber,
I
6
are
reduction
K to
I
,5
silica
constant
density
1000 the
be
for
reduction
I
4
FIG 4 p r o p e r t i e s for the I0 ~m and the c o a t e d fibers.
effect
heat
Significant
I
3
Transfer
can
radiative
I 2
(b)
combined
the
10
(a)
silicon
properties
I 9
x(~m)
Heat
The
[ 0
(.m)
Radiative
silica
-0.4
constant
is When
858
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
Vol. 16, No. 6
0.45
0.40
""""""..•" 21" ..*.'*'~"
Base Fiber l O/~m
0.35 s
•
• ,o
" Fiber 5Nm 0.30
•
,
,f
.,•../
~
m
'f/
Cooted Fiber 1-Loyer
---Coa(ed Fiber 2-Layer
f -"'" Base Fiber 2#m
0.25
0.20
1000
I
I
I
I
I
1I00
1200
1300
1400
1500
1600
To (K) Radiative
bulk
heat
density.
weight
of
This
the
reduction
in
that
observed
fact
that
maintain
FIG 5 for c o n s t a n t
situation
corresponds
insulation radiative for
there the
ratio
flux
heat
constant
are
same
fewer
bulk
properties
for
one
different,
the
radiative
consistently 60,
and
61
respectively.
the
be
transfer
fibers and flux
5,
and
to
is
in
the
tw o ratio
the
two is
reductions
that
the
not
coatings at
with at
than
due in
the
to
the
order
to
radiative
are
for
10 pm f i b e r s
The c o r r e s p o n d i n g
is
insulation
reduction
where
significant This
coatings
density.
case
Note
less
density.
number
the
fixed.
Although
The b e s t 2,
kept
number
density.
coating
higher. for
must
fiber
lO00 one 1600
significantly is K,
about
83,
coating, K are
46,
54,
Vol. 16, No. 6
RADIATIVE TRANSFER IN THERMAL INSULATIONS
025
I
I
I
I
I II
II
l
I
859
I
m . Cooted Fiber 1-Loyer ---Cooted Fiber 2-Loyer osss °~S
0.65
oS s# S s# SS
0.55
Bose Fiber 5#m~,.., ,*"
,,'
ssoss SS~' Base Fiber 2#m
, o.."- \
0,45-
-'°J
I
,./
ol /
..I__ ....
~.'..'~
Z'~'~'°''"
Bose Fiber lO#m~.__._
P
0.35
! 1000
"1
11O0
1200
I
I
I
1300
1400
1500
1600
To (K) Radiative
heat
and 60 percent. reductions fibers,
of 58,
flux
FIG 6 ratio for constant
The a d d i t i o n 57,
respectively,
of an outer
and 59 p e r c e n t
bulk
density.
coating
produced
for the 2, 5, and
at I000 K, and,
28,
I0 # m
45 and 52 p e r c e n t
at
1600 K. Conclusions It has been substantially applying
coated silicon
radiative
coatings
I0 #m fibers
were
by e i t h e r inner
demonstrated heat
that
transfer
to the fibers. considered. a 0.2 #m thick
coating
it is p o s s i b l e in s i l i c a
Insulations
The fibers silicon
coating
and a 0.I ~m s i l i c a
insulations
made
were
outer
to reduce
of 2, 5,
considered
and
to be
or a 0.2 ~m coating.
by
In
860
T.W. Tong, P.S. Swathi and G.R. Cunnington, Jr.
general,
smaller
t h e a d d i t i o n of a s i l i c a
reductions.
reduction density,
obtained
outer coating resulted
For the c o n d i t i o n s was
75 percent
and 63 percent
Vol. 16, No. 6
considered,
for constant
for constant
bulk
in
the
fiber
largest
number
density.
References i.
T. W. Tong, P. S. Swathi and G. R. C u n n i n g t o n , Thermal Insulation, ll, 7 (1987).
2.
P. S.
Swathi,
3.
T. W.
Tong,
Ph.D.
Q.
Thesis,
Arizona
S. Yang and C.
Jr.,
J.
State U n i v e r s i t y
L. Tien,
J.
Heat
(1989).
Transfer,
105,
76 ( 1 9 8 3 ) . 4.
K. Y. Wang, S. Kumar and C. Transfer, i, 289 ( 1 9 8 7 ) .
5.
I. H. Malitson,
J. Opt.
6.
R. J. C h a m p t i e r
and G. J.
7.
W. G. Driscoll, York (1987).
ed.,
8.
R. C. Weast,
J. Astle
M.
Soc.
T. W.
Tong and C.
Am.,
Friese,
Handbook
of C h e m i s t r y and Physics, 9.
L. Tien,
55,
J.
Thermophys.
1205
Heat
(1965).
Report
SAMSO-TR-202
(1974).
of Optics,
McGraw-Hill,
New
and W. H. Beyer, eds., CRC H a n d b o o k CRC Press, Baton Rouge (1986).
L. Tien,
J. Reat
Transfer,
56,
70
(1983).