The nozzle discharges fluid into atmosphere through two identical outlets at the same jet velocity V. The flow is assumed to be steady, inviscid and incompressible with density p =616 kg/m³. The inlet of the nozzle has an average velocity U=5.9 m/s, a cross sectional area A=336 cm² , an unknown gage pressure Pgage > 0, and the momentum flux correction factor ß =1.12. The cross sectional area of each outlet is - A, and the jet flow from the outlets is uniform. If o =50 degree, what is the vertical force component Fy , in N, required to hold the nozzle stationary? Assume the Bernoulli equation is valid and the elevation difference between the inlet and both outlets is negligible.

The nozzle discharges fluid into atmosphere through two identical outlets at the same jet velocity V. The flow is assumed to be steady, inviscid and incompressible with density p =616 kg/m³. The inlet of the nozzle has an average velocity U=5.9 m/s, a cross sectional area A=336 cm² , an unknown gage pressure Pgage > 0, and the momentum flux correction factor ß =1.12. The cross sectional area of each outlet is - A, and the jet flow from the outlets is uniform. If o =50 degree, what is the vertical force component Fy , in N, required to hold the nozzle stationary? Assume the Bernoulli equation is valid and the elevation difference between the inlet and both outlets is negligible.

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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