In a thermal power plant, a horizontal copper pipe of "D" diameter, "L" length and thickness 1.7 cm enters into the boiler that has the thermal conductivity as 0.36 W/mk. The boiler is maintained at 104°C and temperature of the water that flows inside the pipe is at 31°C. If the energy transfer (Q) is 117126 kJ in 6 hours. Determine the Heat transfer rate, Surface area of the pipe and Diameter & Length of the pipe, if D = 0.017 L (Please Solve the problem in a paper and upload in the separate submission link provided and also fill the answers without the unit in the box below) Change in Temperature (in K) Heat Transfer Rate (in W) Surface Area of the Pipe (m)

In a thermal power plant, a horizontal copper pipe of "D" diameter, "L" length and thickness 1.7 cm enters into the boiler that has the thermal conductivity as 0.36 W/mk. The boiler is maintained at 104°C and temperature of the water that flows inside the pipe is at 31°C. If the energy transfer (Q) is 117126 kJ in 6 hours. Determine the Heat transfer rate, Surface area of the pipe and Diameter & Length of the pipe, if D = 0.017 L (Please Solve the problem in a paper and upload in the separate submission link provided and also fill the answers without the unit in the box below) Change in Temperature (in K) Heat Transfer Rate (in W) Surface Area of the Pipe (m)

Principles of Heat Transfer (Activate Learning with these NEW titles from Engineering!)

8th Edition

ISBN:9781305387102

Author:Kreith, Frank; Manglik, Raj M.

Publisher:Kreith, Frank; Manglik, Raj M.

Chapter7: Forced Convection Inside Tubes And Ducts

Section: Chapter Questions

Problem 7.4P

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