In the figure below, this "double" nozzle discharges water (at 10°C, density= 1000 kg/m3) into the atmosphere at a rate of 0.50 m3/s. The pressure at the inlet is to be 315612 Pa. If the nozzle is lying in a horizontal plane. Jet A is 10 cm in diameter, jet B is 12 cm in diameter, and the pipe (1) is 30 cm in diameter. The x-component of force (Rx) acting through the flange bolts is required to hold the nozzle in place is: Patm V=26.1 m/s Pam VA=26.1 m/s Rx P=315612 Pa V,=7.07 m/s Select one: O a. 12.2 kN O b. 18.2 kN O c. 15.2 kN O d. 19.2 kN

In the figure below, this "double" nozzle discharges water (at 10°C, density= 1000 kg/m3) into the atmosphere at a rate of 0.50 m3/s. The pressure at the inlet is to be 315612 Pa. If the nozzle is lying in a horizontal plane. Jet A is 10 cm in diameter, jet B is 12 cm in diameter, and the pipe (1) is 30 cm in diameter. The x-component of force (Rx) acting through the flange bolts is required to hold the nozzle in place is: Patm V=26.1 m/s Pam VA=26.1 m/s Rx P=315612 Pa V,=7.07 m/s Select one: O a. 12.2 kN O b. 18.2 kN O c. 15.2 kN O d. 19.2 kN

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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Question

In the figure below, this "double" nozzle discharges water (at 10°C, density= 1000 kg/m3) into the atmosphere at a rate of
0.50 m3/s. The pressure at the inlet is to be 315612 Pa. If the nozzle is lying in a horizontal plane. Jet A is 10 cm in
diameter, jet B is 12 cm in diameter, and the pipe (1) is 30 cm in diameter. The x-component of force (Rx) acting through
the flange bolts is required to hold the nozzle in place is:
Patm
V3=26.1 m/s
Patm
VA=26.1 m/s
Rx
P=315612 Pa
V,=7.07 m/s
Select one:
O a. 12.2 kN
O b. 18.2 kN
O c. 15.2 kN
O d. 19.2 kN
e 0E = 0

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