O a. 16 N O b. -8 N c. -16 N О с. O d. -5.6 N O e. 5.66 N O f. 8 N O g. ON 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 A, = 30 cm?. 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. Find the horizontal momentum flux in, or in Q,= 6000 cm³/ A2= 30 cm2 Q,= 8000 cm³/s . %3D e = 45° e = 45° A,= 40 cm² %3D A3= 10 cm² Q3= 2000 cm3/s

Elements Of Electromagnetics
7th Edition
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Author:Sadiku, Matthew N. O.
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O a. 16 N
O b. -8 N
c. -16 N
О с.
O d. -5.6 N
O e. 5.66 N
O f. 8 N
O g. ON
Transcribed Image Text:O a. 16 N O b. -8 N c. -16 N О с. O d. -5.6 N O e. 5.66 N O f. 8 N O g. ON
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
A, = 30 cm?. 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.
Find the horizontal momentum flux in, or in
Q,= 6000 cm³/
A2= 30 cm2
Q,= 8000 cm³/s .
%3D
e = 45°
e = 45°
A,= 40 cm²
%3D
A3= 10 cm²
Q3= 2000 cm3/s
Transcribed Image Text: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 A, = 30 cm?. 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. Find the horizontal momentum flux in, or in Q,= 6000 cm³/ A2= 30 cm2 Q,= 8000 cm³/s . %3D e = 45° e = 45° A,= 40 cm² %3D A3= 10 cm² Q3= 2000 cm3/s
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