Water flows over a heated plate as shown below. The plate length is 0.17 m and its boundary condition is set as constant heat flux. Water flow velocity is 2 m/s and uniformly distributed heat flux is 75000 W/m?. Thermophysical properties of water may be approximated as: k = 0.620 W/mk, Pr = 5.2, v = 0.96x10-6 m²/s water V m/s + 20°C Calculate the plate temperature at the trailing edge in °C If the boundary layer is 'tripped' and the flow over the plate is completely turbulent, calculate the plate temperature at the trailing edge in °C 34.9 42.1 51.0 || 59.2 || 64.0 || 75.8 || 82.3
Water flows over a heated plate as shown below. The plate length is 0.17 m and its boundary condition is set as constant heat flux. Water flow velocity is 2 m/s and uniformly distributed heat flux is 75000 W/m?. Thermophysical properties of water may be approximated as: k = 0.620 W/mk, Pr = 5.2, v = 0.96x10-6 m²/s water V m/s + 20°C Calculate the plate temperature at the trailing edge in °C If the boundary layer is 'tripped' and the flow over the plate is completely turbulent, calculate the plate temperature at the trailing edge in °C 34.9 42.1 51.0 || 59.2 || 64.0 || 75.8 || 82.3
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 7.29P
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Water flows over a heated plate as shown below. The plate length is 0.17 m and its boundary condition is set as constant heat flux. Water flow velocity is 2 m/s and uniformly distributed heat flux is 75000 W/m2. Thermophysical properties of water may be approximated as:
k = 0.620 W/mK, Pr = 5.2, ν = 0.96x10-6 m2/s
![Water flows over a heated plate as shown below. The plate length is 0.17 m and its boundary condition is set as constant heat flux.
Water flow velocity is 2 m/s and uniformly distributed heat flux is 75000 W/m?. Thermophysical properties of water may be
approximated as:
k = 0.620 W/mk, Pr = 5.2, v = 0.96x10-6 m²/s
water
V m/s
+ 20°C
Calculate the plate temperature at the trailing edge in °C
If the boundary layer is 'tripped' and the flow over the plate is completely turbulent; calculate the plate temperature at the trailing
edge in C
34.9 42.1 51.0 || 59.2|| 64.0| 75.8 82.3
21.2 24.5 27.3 29.8 |34.0 || 37.1 39.0](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F76abdadb-aea7-4752-8287-45b27fbdd944%2Fcf8ca44d-021c-467d-8b7c-c1fe0eaa7d99%2Fdutl4b_processed.jpeg&w=3840&q=75)
Transcribed Image Text:Water flows over a heated plate as shown below. The plate length is 0.17 m and its boundary condition is set as constant heat flux.
Water flow velocity is 2 m/s and uniformly distributed heat flux is 75000 W/m?. Thermophysical properties of water may be
approximated as:
k = 0.620 W/mk, Pr = 5.2, v = 0.96x10-6 m²/s
water
V m/s
+ 20°C
Calculate the plate temperature at the trailing edge in °C
If the boundary layer is 'tripped' and the flow over the plate is completely turbulent; calculate the plate temperature at the trailing
edge in C
34.9 42.1 51.0 || 59.2|| 64.0| 75.8 82.3
21.2 24.5 27.3 29.8 |34.0 || 37.1 39.0
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