Water at 200∘F enters the radiator at A with an average velocity of 4 ft/s and a pressure of 60 psi. The copper pipe has a diameter of 14in. Take ε=5(10^−6)ft. The radiator is in the vertical plane. ρw = 1.869 slug/ft3 and νw=3.40(10^−6)ft2/s. Use the equation 1/√f = −1.8log[(ε/D/3.7)^1.11 +6.9/Re]. If each 180∘ bend has a minor loss coefficient of KL = 1.03, determine the pressure at the exit B
Water at 200∘F enters the radiator at A with an average velocity of 4 ft/s and a pressure of 60 psi. The copper pipe has a diameter of 14in. Take ε=5(10^−6)ft. The radiator is in the vertical plane. ρw = 1.869 slug/ft3 and νw=3.40(10^−6)ft2/s. Use the equation 1/√f = −1.8log[(ε/D/3.7)^1.11 +6.9/Re]. If each 180∘ bend has a minor loss coefficient of KL = 1.03, determine the pressure at the exit B
Refrigeration and Air Conditioning Technology (MindTap Course List)
8th Edition
ISBN:9781305578296
Author:John Tomczyk, Eugene Silberstein, Bill Whitman, Bill Johnson
Publisher:John Tomczyk, Eugene Silberstein, Bill Whitman, Bill Johnson
Chapter2: Matter And Energy
Section: Chapter Questions
Problem 10RQ: Why does an object weigh less on the moon than on earth?
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Water at 200∘F enters the radiator at A with an average velocity of 4 ft/s and a pressure of 60 psi. The copper pipe has a diameter of 14in. Take ε=5(10^−6)ft. The radiator is in the vertical plane. ρw = 1.869 slug/ft3 and νw=3.40(10^−6)ft2/s. Use the equation 1/√f = −1.8log[(ε/D/3.7)^1.11 +6.9/Re]. If each 180∘ bend has a minor loss coefficient of KL = 1.03, determine the pressure at the exit B
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