TITLE.PM5

(Ann) #1
HEAT TRANSFER 849

dharm
\M-therm\Th15-4.pm5

Rate of evaporation of liquid air :
The heat flow from the inner sphere surface to outer sphere
surface is given by,


Q
AT T

F

A
A

12 11

4
2
4
1
112

2
2

1
2

111

=

F −
HG

I
KJ

++−
F
HG

I
− KJ

σ
ε
ε

ε
ε

()

=

4
1 1 1

1
2
1
4
2
4
1
1

2
2

12
22

πσ
ε
ε

ε
ε

rT T
r
r

()−
F −
HG

I
KJ

++−
F
HG

I
KJ

=

40 120
100

300
100
1003
003
1 1003
003

0
0

2
44

2

π× × FHG IKJ −FHG IKJ


L
N

M
M

O
Q

P
P
F −
HG

I
KJ++

F −
HG

I
KJ×

F
HG

I
KJ

()

.
.

.
.

.105 5.67

.105
.15

=
0.7855 (2.07 81)
32.33 1 15.84

61.99
49.17


++

=− = – 1.26 W


  • ve sign indicates that heat is gained by the surface 1, means, heat is flowing from outside
    surface to inside surface.


∴ The rate of evaporation =

1.26 3600
209.35 1000

×
× = 0.0217 kg/h. (Ans.)
Example 15.31. Liquid oxygen (boiling temperature = – 182°C) is to be stored in spherical
container of 30 cm diameter. The system is insulated by an evacuated space between inner sphere and
surrounding 45 cm inner diameter concentric sphere. For both spheres ε = 0.03 and temperature of the
outer sphere is 30°C. Estimate the rate of heat flow by radiation to the oxygen in the container.
Solution. Given : T 1 = – 182 + 273 = 91 K, T 2 = 30 + 273 = 303 K, ε 1 = ε 2 = 0.03
d 1 = 30 cm = 0.3 m, d 2 = 45 cm = 0.45 m.
Rate of heat flow, Q 12 :
The heat flow between the two concentric
spheres by radiation is given by


Q 12 =
AT T

F

A
A

114 24
1
112

2
2

1
2

111

σ
ε
ε

ε
ε

()−
− + F −
HG

I
− KJ
For concentric spheres
F 12 − = 1

and A
A


d
d

1
2

1
2

(^22)


F
HG
I
KJ
=F
HG
I
KJ
0.3
0.45
= 0.4444
A 1 = 4π (^) r 12 = 4π ×
03
2
F.^2
HG
I
KJ = 0.283 m
2
Fig. 15.55
Oxygen
1
2
30 Cº
Evacuated
space
–182 Cº
ε= 0.03
Fig. 15.56
T 1
r 1
r 2
T 2

Free download pdf