Water flows between two reservoirs, with a 170 meters elevation between them, to a turbine where electricity is generated. The two reservoirs are open to atmosphere. The horizontal distance between the reservoirs is 20 meters, thus, 190 meters of concrete pipe (ε = 1.3 mm) are needed. The water flows at a rate of 0.021 m³/s and the diameter of the pipe is 6.5 centimeters. Minor losses include a well-rounded inlet Ke 0.03) two 901 Flanged benos (K-0.3 sach), and a pipe exit (K₁ = 1.05). The density and viscosity of the water is 1,000 kg/m³ and 0.001 Pa-s, respectively.
Water flows between two reservoirs, with a 170 meters elevation between them, to a turbine where electricity is generated. The two reservoirs are open to atmosphere. The horizontal distance between the reservoirs is 20 meters, thus, 190 meters of concrete pipe (ε = 1.3 mm) are needed. The water flows at a rate of 0.021 m³/s and the diameter of the pipe is 6.5 centimeters. Minor losses include a well-rounded inlet Ke 0.03) two 901 Flanged benos (K-0.3 sach), and a pipe exit (K₁ = 1.05). The density and viscosity of the water is 1,000 kg/m³ and 0.001 Pa-s, respectively.
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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What is the pressure drop in the turbine? Answer: 1176.91 kPa (replace “turbine pressure drop” for “pump pressure increase”)
Transcribed Image Text:4. Water flows between two reservoirs, with a 170 meters elevation between them, to a
turbine where electricity is generated. The two reservoirs are open to atmosphere.
The horizontal distance between the reservoirs is 20 meters, thus, 190 meters of
concrete pipe (ε = 1.3 mm) are needed. The water flows at a rate of 0.021 m³/s and
the diameter of the pipe is 6.5 centimeters. Minor losses include a well-rounded inlet
C.C3
90°
CS Kap 036 two 901 fanged benos (K 10.3 cach), and a pipe exit (K₁ = 1.05). The
density and viscosity of the water is 1,000 kg/m³ and 0.001 Pa-s, respectively.
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