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Sample Calculation: For Observation No. 5 at 10 Psig Steam Pressure

The document contains sample calculations to determine heat transfer properties in a pipe. It provides characteristics of the inner pipe and condenser area. It then calculates properties like mass flow rates, heat transfer rates, temperatures and coefficients. It determines the steam side and overall heat transfer coefficients, velocity of water flow, and thickness of the condensate film using equations that reference material properties of water.

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Shehabul Hasan Mamun
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135 views5 pages

Sample Calculation: For Observation No. 5 at 10 Psig Steam Pressure

The document contains sample calculations to determine heat transfer properties in a pipe. It provides characteristics of the inner pipe and condenser area. It then calculates properties like mass flow rates, heat transfer rates, temperatures and coefficients. It determines the steam side and overall heat transfer coefficients, velocity of water flow, and thickness of the condensate film using equations that reference material properties of water.

Uploaded by

Shehabul Hasan Mamun
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
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Download as DOCX, PDF, TXT or read online on Scribd
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Sample Calculation

Pipe characteristics:
Outside diameter of the inner pipe, Do = 0.625 inch = 0.01588 m

Inner diameter of the inner pipe, Di = 0.527 inch = 0.01338 m

[Reference: Copper Development Association Inc. (2010), The Copper Tube Handbook (Table-
2a, pp. 21). New York: Madison Avenue.]

Length of the inner pipe, L = 1.6256 m.

Condenser area exposed to cooling water, Ac = πDoL

= 3.14×0.01588×1.6256 m2

= 0.081 m2

For observation no. 5 at 10 psig steam pressure,

Inlet water temperature, T1 = 29.5 °C

Outlet water temperature, T2 = 35.5 °C

T1 +T2 (29.5+35.5)
Mean temperature, TM = = °C= 32.5 °C
2 2

Weight of condensate collected, Wc = 44.7 g

Condensate collection time, tc = 34 sec

Mass flow rate of condensate, Mc = Wc/tc = 44.7/34 = 1.315 g/s

V 1
Volumetric flow rate of water, Vw = = L/s = 0.108 L/s
tw 9.22

Properties at of water at mean temperature (32.5 °C):

Density of water, ρM = 994.93 kg/m3


[Reference: Holman, J. P., & Bhattacharyya, Souvik (2011). Heat Transfer In SI Units (10th ed.,
pp. 609). New Delhi: McGraw-Hill.]

Specific heat of water, CP,M = 4174 J/kg.K


[Reference: Holman, J. P., & Bhattacharyya, Souvik (2011). Heat Transfer In SI Units (10th ed.,
pp. 609). New Delhi: McGraw-Hill.]

Mass flow rate of water, Mw = Vw × ρM = 0.108 × 10−3 × 994.8 kg/s = 0.107 kg/s

Properties of steam at 10 psig:

Saturation temperature of steam at pressure 10 psig, TS = 115.2 °C


[Reference: Felder, Richard M., & Rousseau, Ronald W. (2012). Elementary Principles of
Chemical Processes (3rd ed.). New Delhi: Wiley.]

Latent heat of vaporization of water at saturation temperature, λS = 2215.7 KJ/kg


[Reference: Felder, Richard M., & Rousseau, Ronald W. (2012). Elementary Principles of
Chemical Processes (3rd ed.). New Delhi: Wiley.]

Heat flow calculation:

Rate of heat taken up by water, QW = MWCP,M(T2-T1)

= 0.107 × 4174 × (35.5 − 29.5) W

= 2.70 KW

Rate of heat given up by steam, QC = MCλS

= 1.315 × 10−3 × 2215.7 KW

= 2.91 KW

QW + QC 2.68+2.91
Mean rate of heat flow, Qm = = KW = 2.81 KW
2 2

QC − QW 2.91−2.70
Percent heat loss = × 100% = × 100% = 7.23%
QC 2.91

Calculations for steam side heat transfer coefficient:

Ts +Tm 115.2+32.5
Tube wall temperature on steam side, TW = = = 73.85 °C
2 2

Ts +Tw 115.2+73.85
Film temperature, Tf = = 2
= 94.525 °C
2
Density of water at film temperature, ρf = 962.45 kg/m3
[Reference: Holman, J. P., & Bhattacharyya, Souvik (2011). Heat Transfer In SI Units (10th ed.,
pp. 609). New Delhi: McGraw-Hill.]

Thermal conductivity of water at film temperature, kf = 0.679 W/m.K


[Reference: Holman, J. P., & Bhattacharyya, Souvik (2011). Heat Transfer In SI Units (10th ed.,
pp. 609). New Delhi: McGraw-Hill.]

Coefficient of viscosity of water at film temperature, μf = 3.01 × 10-4 N.s/m2


[Reference: Holman, J. P., & Bhattacharyya, Souvik (2011). Heat Transfer In SI Units (10th ed.,
pp. 609). New Delhi: McGraw-Hill.]

Acceleration due to gravity, g = 9.81 m/s2

0.25
ρ2f gλs k3f
Steam side heat transfer coefficient, h0 = 0.943( )
Lμf (Ts −Tw )

0.25
962.452 ×9.81×2215.7×103 ×0.6793
= 0.943( )
1.6256×3.01×10−4 ×(115.2−73.85)

= 3958.6 W/m2.K

[Reference: Holman, J. P., & Bhattacharyya, Souvik (2011). Heat Transfer In SI Units (10th ed.,
Eqn. 9-10). New Delhi: McGraw-Hill.]

Calculations for velocity of water flow, v:

Volumetric flow rate of water, VW = 0.108 L/s = 0.108×10-3 m3/s

D2i
Cross-sectional flow area of water flow, Ai = π( )
4

0.01342
= 3.1416 × m2
2

= 0.000141 m2

Vw 0.108×10−3
Velocity of water flow, v = = m/s = 0.77 m/s
Ai 0.000141
Calculations for overall heat transfer coefficient, U:

Temperature difference at inlet, ΔT1 = TS-T1 = (115.2-29.5) °C = 85.7 °C

Temperature difference at outlet, ΔT2 = TS-T2 = (115.2-35.5) °C = 79.7 °C

ΔT1−ΔT2 85.7−79.7
Log mean temperature difference, ΔTln = ΔT1 = 85.7 = 82.66 °C
ln( ) ln( )
ΔT2 79.7

Qw 2702.5
Overall heat transfer coefficient, U = = W/m2-K
∆Tln ×Ac 82.66×0.081

= 403.25 W/m2.K

Calculations for thickness of condensate film:

Distance from the top of the column, z = 0.5 m

4μf kf z(Ts −Tf ) 0.25


Fim thickness, yf = ( )
gλs ρf (ρf −ρv )

0.25
4×3.01×10−4 ×0.679×0.5×(115.2−94.525)
=( )
9.81×2215.7×103 ×962.45×(962.45~0)

= 0.00017 m

Average film thickness = (0.000170+0.000171+0.000171+0.000171)/4 m

= 0.000171 m

Calculations for local heat transfer coefficient:

Distance from the top of the column, z = 0.5 m

0.25
ρf (ρf −ρv )gλs k3f
Local heat transfer coefficient, hlocal = ( )
4μf z(Ts −Tw )

0.25
962.452 ×9.81×2215.7×103 ×0.6793
=( )
4×3.01×10−4 ×0.5×(115.2−73.85)

= 3985.9 W/m2.K
Average local heat transfer coefficient = (3971.11+3963.65+3962.1+4055.59) W/m2.K

= 3971.55 W/m2.K

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