Plate Heat Exchanger design in excel
PLATE HEAT EXCHAN SIDE-I FLUID: Water Flow Rate in kg/s Properties @ 43.5 C Specific Heat Thermal Conductivity Viscoci
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PLATE HEAT EXCHAN SIDE-I FLUID:
Water
Flow Rate in kg/s Properties @ 43.5 C Specific Heat Thermal Conductivity Viscocity Density
m3/hr
J/Kg-K Watt/mK Ns/m2*(10^-3) Kg/m3
Dirt Coefficient from Coulson and Richardson table 12.9
139.32 38.68 4190 0.586 0.0013 999.564 30000
Thermal Conductivity of Alloy 316 @ 23 C
W/m-K
Temperature In Temperature Out Average Temp for calculating Properties TD1=TI1-TO2 TD2=TO1-TI2
C C
Logarithmic Mean Temp Diff
16.3 49 38 43.5 12.879 8 10.247
No of Transfer Units=(TI1-TO1)/LMTD
1.074
Ft found from fig:12.62 of Ch Engg Design by Coulson and Richardson is 2:2 pass arrangement assumed U(Overall Heat Transfer Coeficient) assumed is from fig 12.2 Mass Flow Rate Heat Duty is HT Area required Plate Length Plate Width Plate thickness Plate Spacing No of Plates per pass Plate (Length * width)
passes
2
W/m2-K Kg/s W m2 m m m m
3088 38.683 1782887 60.92 0.8 0.7 0.0005 0.003 54.5 0.56
m2
Number of Channels/pass
54
No of Plates Required Number of Plates rounded up Channel Cross section area is (width * spacing)
Plates Plates
De or hydraulic mean radius is
m
108.78 109 0.0021 0.006
Calculation for Channel Velocity SIDE-1 Water Channel Velocity (MFR/(D*Channel CS* no of channels/pass) m/s Reynolds Number (Nre)
0.34 1637.36
Prandtl Number Npr
8.94
Heat Transfer Coefficient is
W/m2-K
7488.67
Overall Heat Transfer Coefficient calculated
W/m2-K
3088.3
Pressure Drop Calculation The Plate Pressure drop can be estimated using a form of the equation for flow in the ΔPp= conduit Lp The path Length Gp/ρ
up
Friction Factor
jf=
For this PHE jf= Path Length =
8jf(Lp/de)(ρup2/2)
0.6x Re^(-0.3)
0.065 Plate length x Number of Passes 1.600 m
ΔPp= The Port Pressure drop due to contraction and expansion losses through the ports in the plates must be added to the friction ΔPpt= loss
8089.7 N/m2
1.3Np(ρupt2/2)
The velocity through the ports=w/ρAp, m/s
upt
mass flow through the ports, kg/s
w
Area of the ports, m2
(Πdpt2)/4
Port diameter,m
dpt
Number of Passes
Np
Take Port Diameter as Port Area is Velocity through Port ΔPpt= Total Pressure drop=
125 mm 0.012 m2 3.152 m/s 12912.1 N/m2 21001.8 N/m2 0.2 bar
PLATE HEAT EXCHANGERS SIDE-II FLUID
Water
Flow Rate in kg/s Properties @ 33.8 C Specific Heat Thermal Conductivity Viscocity Density
m3/hr
250.00 69.43
J/Kg-K Watt/mK Ns/m2*(10^-3) Kg/m3
4196 0.583 0.0013 999.75
Dirt Coefficient from Coulson and Richardson table 12.9
Temperature In Temperature Out
30000
C C
Avg Temp for calculating Properties
30 36.1
33.1
0.925
Mass Flow Rate
Kg/s
69.43
SIDE-2 Water Channel Velocity (MFR/(D*Channel CS* no of channels/pass) Reynolds Number (Nre)
m/s
0.61 2766.11
Prandtl Number Npr
9.56
Heat Transfer Coefficient is
W/m2-K
10760.98
Overall Heat Transfer Coefficient Asumed
W/m2-K
3088
sure Drop Calculation The Plate Pressure drop can be estimated using a form of the equation for flow in the conduit
ΔPp=
The path Length Gp/ρ
Lp
Friction Factor
jf=
up
For this PHE jf= Path Length =
0.6x Re^(-0.3)
0.056 Plate length x Number of Passes 1.600 m
ΔPp=
The Port Pressure drop due to contraction and expansion losses through the ports in the plates must be added to the friction loss
8jf(Lp/de)(ρup2/2)
6913.5 N/m2
ΔPpt=
1.3Np(ρupt2/2)
The velocity through the ports=w/ρAp, m/s
upt
mass flow through the ports, kg/s
w
Area of the ports, m2
(Πdpt2)/4
Port diameter,m
dpt
Number of Passes
Np
Take Port Diameter as Port Area is Velocity through Port ΔPpt= Total Pressure drop=
125 mm 0.012 m2 5.657 m/s 41585.4 N/m2 48498.9 N/m2 0.5 bar