D- Water 12 2. In this system, d = 6 in., D = 6 ft, and =z2 = 12 ft. The water in the system is 13 cfs. machine a pump or a turbine? pressures at points A and B? losses. Pump 1. The discharge in the siphon is 2.80 cfs, D = 10 in., L1= 3 ft, and L2 = 3 ft. Determine the head loss between the reservoir surface and point C. Determine the pressure at point B if three-quarters of the head loss (as found above) occurs between the reservoir surface and point B. 1m Water T-10°C Energy Equation Water Same elevation- Machine Elevation = 40 m -Elevation=20m _Elevation = 10 m 300 m- -300 m- 4. Assume that the head loss in the pipe is given by hl= 0.014(L/D)(V2/2g), where L is the length of pipe and AF2 Ar 3. A water discharge of 10 m3/s is to flow through this horizontal pipe, which is 1 m in diameter. If the head loss is given as 7V2/2g (V is velocity in the pipe), how much power will have to be supplied to the flow by the pump to produce this discharge? Elevation = 100 m L = 100 m D= 60 cm - Elevation = 95 m Water T= 10°C 12 in., =z1 = discharge of Is the What are the Neglect head D is the pipe diameter. a. Determine the discharge of water through this system. b. Draw the HGL and the EGL for the system. c. Locate the point of maximum pressure. d. Locate the point of minimum pressure. e. Calculate the maximum and minimum pressures in the system. - Elevation = 100 m L = 400 m D = 60 cm Elevation - 30 m - Nozzle 30 cm-diameter jet
D- Water 12 2. In this system, d = 6 in., D = 6 ft, and =z2 = 12 ft. The water in the system is 13 cfs. machine a pump or a turbine? pressures at points A and B? losses. Pump 1. The discharge in the siphon is 2.80 cfs, D = 10 in., L1= 3 ft, and L2 = 3 ft. Determine the head loss between the reservoir surface and point C. Determine the pressure at point B if three-quarters of the head loss (as found above) occurs between the reservoir surface and point B. 1m Water T-10°C Energy Equation Water Same elevation- Machine Elevation = 40 m -Elevation=20m _Elevation = 10 m 300 m- -300 m- 4. Assume that the head loss in the pipe is given by hl= 0.014(L/D)(V2/2g), where L is the length of pipe and AF2 Ar 3. A water discharge of 10 m3/s is to flow through this horizontal pipe, which is 1 m in diameter. If the head loss is given as 7V2/2g (V is velocity in the pipe), how much power will have to be supplied to the flow by the pump to produce this discharge? Elevation = 100 m L = 100 m D= 60 cm - Elevation = 95 m Water T= 10°C 12 in., =z1 = discharge of Is the What are the Neglect head D is the pipe diameter. a. Determine the discharge of water through this system. b. Draw the HGL and the EGL for the system. c. Locate the point of maximum pressure. d. Locate the point of minimum pressure. e. Calculate the maximum and minimum pressures in the system. - Elevation = 100 m L = 400 m D = 60 cm Elevation - 30 m - Nozzle 30 cm-diameter jet
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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