H11x2Figure 3, for task 4.a) Calculate the outlet velocity V2 and the gage pressure P1,gage at the flange in section 1.b) Find the reaction force, FR, in the flange connection (the force acting on the nozzle to holdthis in place). Task 4 - conservation of momentumA curved nozzle with fresh water (use sealed 1000 kg/m3 for fresh water) in stationary flow has a vertical inlet andoutlet forming an angle ÿ = 30° with the horizontal plane, see Error!Reference source not found.. The inlet has diameter D1 = 80 mm and the outlet, to the atmosphere, has diameter D2 =25 mm. The inlet velocity V1 = 2 m/s. The nozzle weighs 20 kg (mD = 20 kg) whenit is empty, and it (the nozzle) holds 2.5 liters (VD = 2.5 liters). The height difference (H) betweenthe flange connection and outlet is 500 mm, as illustrated in Figure 3

Answered: Image /qna-images/answer/7a578401-dd2d-4cbe-8098-4eded95184f2.jpg

Answered: H 11 x 2 Figure 3, for task 4. a)…

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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Can someone please help me to solve the following question showing all work. R-in = 5cm R-out = 15cm
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In a certain hydraulic turbomachine, the following data apply:Inlet blade velocity is 20 m/s. Vu1=21 m/s; Vr1=10 m/s.At the exit, V2 is purely axial and has a value of 14 m/s, and blade speed is9 m/s. Is this power absorbing or power producing? Find E and the changes instatic and stagnation pressures. Would this machine be classified as a purelyradial, purely axial, or mixed flow type?Ans: E=420 J/kg; Δpstag=420 kPa; Δpstat=247.4 kPa
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