Lagged Pipe 242y6l
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HEAT TRANSFER LAB Presentation
Jadavpur University Power Engineering Dept
Created by : ** PRASUN CHOWDHURY (000911501001) **KISHORE MANDI (000911501002) **SUBEDIT DAS (000911501005)
TOPIC : To determine the thermal conductivity of insulation for a LAGGED PIPE.
INTRODUCTION
Lagging of pipes is required to prevent LEAKAGES of heat. The apparatus is designed to study the lagging phenomenon. In Lagged Pipe apparatus, three concentric pipes are arranged between two s.The gap between the pipes are filled compactly by two different insulating materials and heater is provided at the centre of inner pipe. Temperature at various points are measured with thermocouples. Heat input is measured by voltmeter and ammeter readngs.
APPARATUS USED voltmeter
ammeter
Temperature indicator
knob
SECTIONAL VIEW OF THE APPARATUS
ASSUMPTIONS
There is no heat loss from the two ends of the pipe.
Insulations No heat lossoo preventing the heat to come out axially
There is one dimensional radial heat conduction through the insulator.
The other assumptions are: We assume steady state heat conduction. We have to assume the length of the pipe and the length of the heater to be the same.
OBSERVATION TABLE Run No.
Voltage Current (I) (V)
1
40
2
50
3
70
Ta (K)
Tb (K)
Tc (K)
Td (K)
R1=25
R2=38
R3=50
R4=62
0.18 62. 41. 35. 26 7 3 7 0.22 74 46. 38. 28 7 7 0.31 10 59. 47. 31 2 3 7
CALCULATIONS(experimental) The rate of heat generation is given by q̇=Vi…….(1) Where V=applied voltage i=current through the heater At the steady state condition, the above heat is dissipated radially. From the governing equation of heat transfer by conduction we get q̇=-kA(dT/dr) Now A=2πrL, So q̇=-k(2πrL)dT/dr……………………(2) So equating (1) and (2) we get the following equation k=Vi/(2πrLdT/dr) This is the value of k obtained experimentally.
CALCULATIONS(theoretical) T1 -T12 are the temperatures of 12 thermocouples. Ta=(T1 + T2 + T3 )/3 Tb=(T4 + T5 + T6)/3 Tc=(T7 + T8 + T9 )/3 Td=(T10 + T11 + T12 )/3 The theoretical working equation is q̇=( Ta - Td)/[ln(R4/R1)/2πkL] where k=thermal conductivity L=length of the pipe k= q̇ ln(R4/R1)/ [2πL(Ta - Td)] This is the value of k obtained theoretically.
RESULTS RUN no.
Ktheo
Kexpt
(W/mK)
(W/(mK)
1
0.244
0.298
18
2
0.25
0.36
38
3
0.31
0.45
32
% Error
Temperature vs Radial length graph 300 250 200 t3 t2 t1
150 100 50 0 25
38
50
62
ACKNOWLEDGEMEN T We are very much grateful to the following teachers,without them this expt would not have been possible.
Prof. Amitava Dutta Prof. A. K. Satra Sri Bireshwar Paul Sri Atish Nandi
THANK YOU
Jadavpur University Power Engineering Dept
Created by : ** PRASUN CHOWDHURY (000911501001) **KISHORE MANDI (000911501002) **SUBEDIT DAS (000911501005)
TOPIC : To determine the thermal conductivity of insulation for a LAGGED PIPE.
INTRODUCTION
Lagging of pipes is required to prevent LEAKAGES of heat. The apparatus is designed to study the lagging phenomenon. In Lagged Pipe apparatus, three concentric pipes are arranged between two s.The gap between the pipes are filled compactly by two different insulating materials and heater is provided at the centre of inner pipe. Temperature at various points are measured with thermocouples. Heat input is measured by voltmeter and ammeter readngs.
APPARATUS USED voltmeter
ammeter
Temperature indicator
knob
SECTIONAL VIEW OF THE APPARATUS
ASSUMPTIONS
There is no heat loss from the two ends of the pipe.
Insulations No heat lossoo preventing the heat to come out axially
There is one dimensional radial heat conduction through the insulator.
The other assumptions are: We assume steady state heat conduction. We have to assume the length of the pipe and the length of the heater to be the same.
OBSERVATION TABLE Run No.
Voltage Current (I) (V)
1
40
2
50
3
70
Ta (K)
Tb (K)
Tc (K)
Td (K)
R1=25
R2=38
R3=50
R4=62
0.18 62. 41. 35. 26 7 3 7 0.22 74 46. 38. 28 7 7 0.31 10 59. 47. 31 2 3 7
CALCULATIONS(experimental) The rate of heat generation is given by q̇=Vi…….(1) Where V=applied voltage i=current through the heater At the steady state condition, the above heat is dissipated radially. From the governing equation of heat transfer by conduction we get q̇=-kA(dT/dr) Now A=2πrL, So q̇=-k(2πrL)dT/dr……………………(2) So equating (1) and (2) we get the following equation k=Vi/(2πrLdT/dr) This is the value of k obtained experimentally.
CALCULATIONS(theoretical) T1 -T12 are the temperatures of 12 thermocouples. Ta=(T1 + T2 + T3 )/3 Tb=(T4 + T5 + T6)/3 Tc=(T7 + T8 + T9 )/3 Td=(T10 + T11 + T12 )/3 The theoretical working equation is q̇=( Ta - Td)/[ln(R4/R1)/2πkL] where k=thermal conductivity L=length of the pipe k= q̇ ln(R4/R1)/ [2πL(Ta - Td)] This is the value of k obtained theoretically.
RESULTS RUN no.
Ktheo
Kexpt
(W/mK)
(W/(mK)
1
0.244
0.298
18
2
0.25
0.36
38
3
0.31
0.45
32
% Error
Temperature vs Radial length graph 300 250 200 t3 t2 t1
150 100 50 0 25
38
50
62
ACKNOWLEDGEMEN T We are very much grateful to the following teachers,without them this expt would not have been possible.
Prof. Amitava Dutta Prof. A. K. Satra Sri Bireshwar Paul Sri Atish Nandi
THANK YOU
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