Water is to be heated from 20°C to 64°C by flowing through a 5 cm diameter circular pipe as shown in the figure (not scaled) with a mass flow rate of 0.01 kg/s. i- Determine the pipe length if the pipe is heated with a constant surface heat flux of 300 W/m? Calculate the surface temperature of the pipe at the outlet (x=L) and at the half length (x=L/2). hint: assume fully developed flow, then check your assumption If the pipe surface has a constant surface temperature 90°C (instead of a constant surface heat flux constant surface heat flux (i&ii) or temperature ii- (iii) water D= 5cm i11- 20°C 0.01kg/s 64°C boundary condition), determine the pipe length
Water is to be heated from 20°C to 64°C by flowing through a 5 cm diameter circular pipe as shown in the figure (not scaled) with a mass flow rate of 0.01 kg/s. i- Determine the pipe length if the pipe is heated with a constant surface heat flux of 300 W/m? Calculate the surface temperature of the pipe at the outlet (x=L) and at the half length (x=L/2). hint: assume fully developed flow, then check your assumption If the pipe surface has a constant surface temperature 90°C (instead of a constant surface heat flux constant surface heat flux (i&ii) or temperature ii- (iii) water D= 5cm i11- 20°C 0.01kg/s 64°C boundary condition), determine the pipe length
Principles of Heat Transfer (Activate Learning with these NEW titles from Engineering!)
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ISBN:9781305387102
Author:Kreith, Frank; Manglik, Raj M.
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Chapter7: Forced Convection Inside Tubes And Ducts
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Heat Transfer
Question is image
part iii) ?
![Water is to be heated from 20°C to 64°C by flowing through a 5 cm diameter circular pipe as
shown in the figure (not scaled) with a mass flow rate of 0.01 kg/s.
i-
Determine the pipe length if the pipe is heated with a constant surface heat flux of
300 W/m2
Calculate the surface temperature
of the pipe at the outlet (x=L) and
at the half length (x=L/2). hint:
assume fully developed flow, then
check your assumption
If the pipe surface has a constant
surface temperature 90°C (instead
of a constant surface heat flux
boundary condition), determine the
pipe length
constant surface
ii-
heat flux (i&ii)
or temperature
(iii)
water
D= 5cm
iii-
20°C
0.01kg/s
64°C
L](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fc636a00a-110d-40e2-abc5-260e49660b5b%2F0cd652f8-5a38-4364-bbea-76e437b69093%2F7toc8p_processed.png&w=3840&q=75)
Transcribed Image Text:Water is to be heated from 20°C to 64°C by flowing through a 5 cm diameter circular pipe as
shown in the figure (not scaled) with a mass flow rate of 0.01 kg/s.
i-
Determine the pipe length if the pipe is heated with a constant surface heat flux of
300 W/m2
Calculate the surface temperature
of the pipe at the outlet (x=L) and
at the half length (x=L/2). hint:
assume fully developed flow, then
check your assumption
If the pipe surface has a constant
surface temperature 90°C (instead
of a constant surface heat flux
boundary condition), determine the
pipe length
constant surface
ii-
heat flux (i&ii)
or temperature
(iii)
water
D= 5cm
iii-
20°C
0.01kg/s
64°C
L
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