Find the horizontal force that the fluid exerts on the block, FR.XО а.ONO b. 27.3 NО с.-16 NO d. 11.3 NО е.16 NO f.-11.3 Ng. -27.3 NO h. 4.7 NO i.4.7 N A jet impinges on a splitter block. The incoming jet is horizontal and has a flow rate of Q1 = 8000 cm³/s and a cross-sectional area of A1 = 40 cm?.The block splits the jet in to two smaller jets. One is deflected upward by 45°, and has a flow rate of Q2 = 6000 cm3/s and a cross-sectional area ofA, = 30 cm2. The other jet is deflected downward by 45°, and has a flow rate of Q3 = 2000 cm³/s and a cross-sectional area of A3 = 10 cm2.You may assume that the pressure everywhere is equal to atmospheric pressure, and the density of the fluid is 1000 kg/m³.Q2= 6000 cm³/A,= 30 cm2Q,= 8000 cm³/s%3De = 45°e = 45°A,= 40 cm²A3= 10 cm2Q3= 2000 cm3/s

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A jet impinges on a splitter block. The incoming jet is horizontal and has a flow rate of Q1 = 8000 cm³/s and a cross-sectional area of A1 = 40 cm2. The block splits the jet in to two smaller jets. One is deflected upward by 45°, and has a flow rate of Q2 = 6000 cm³/s and a cross-sectional area of A2 = 30 cm2. The other jet is deflected downward by 45°, and has a flow rate of Q3 = 2000 cm³/s and a cross-sectional area of A3 = 10 cm2. You may assume that the pressure everywhere is equal to atmospheric pressure, and the density of the fluid is 1000 kg/m³. Q2= 6000 cm³/ A,= 30 cm? Q,= 8000 cm³/s e = 45° %D e = 45° A,= 40 cm² A3= 10 cm2 Q3= 2000 cm³/s %3D

A jet impinges on a splitter block. The incoming jet is horizontal and has a flow rate of Q1 = 8000 cm³/s and a cross-sectional area of A1 = 40 cm2. The block splits the jet in to two smaller jets. One is deflected upward by 45°, and has a flow rate of Q2 = 6000 cm³/s and a cross-sectional area of A2 = 30 cm2. The other jet is deflected downward by 45°, and has a flow rate of Q3 = 2000 cm³/s and a cross-sectional area of A3 = 10 cm2. You may assume that the pressure everywhere is equal to atmospheric pressure, and the density of the fluid is 1000 kg/m³. Q2= 6000 cm³/ A,= 30 cm? Q,= 8000 cm³/s e = 45° %D e = 45° A,= 40 cm² A3= 10 cm2 Q3= 2000 cm³/s %3D

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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Fluid Dynamics

The study of the flow of gases and liquids, usually in and around solid surfaces, is known as fluid dynamics in physics and engineering. Fluid dynamics, for example, can be used to evaluate the movement of air through an airplane wing or the surface of a vehicle. It can also be used in ship design to increase the speed at which ships pass through water.

Question

Find the horizontal force that the fluid exerts on the block, FR.X
О а.
ON
O b. 27.3 N
О с.
-16 N
O d. 11.3 N
О е.
16 N
O f.
-11.3 N
g. -27.3 N
O h. 4.7 N
O i.
4.7 N

A jet impinges on a splitter block. The incoming jet is horizontal and has a flow rate of Q1 = 8000 cm³/s and a cross-sectional area of A1 = 40 cm?.
The block splits the jet in to two smaller jets. One is deflected upward by 45°, and has a flow rate of Q2 = 6000 cm3/s and a cross-sectional area of
A, = 30 cm2. The other jet is deflected downward by 45°, and has a flow rate of Q3 = 2000 cm³/s and a cross-sectional area of A3 = 10 cm2.
You may assume that the pressure everywhere is equal to atmospheric pressure, and the density of the fluid is 1000 kg/m³.
Q2= 6000 cm³/
A,= 30 cm2
Q,= 8000 cm³/s
%3D
e = 45°
e = 45°
A,= 40 cm²
A3= 10 cm2
Q3= 2000 cm3/s

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