A pump delivers water (density equals 1000 kg/m^3) at a steady rate of 1219 L/min as shown in the figure. Just upstream of the pump [section (1)] where the pipe area is 56 cm^2., the pressure is 1 bar. Just downstream of the pump [section (2)] where the pipe area is 14 cm., the pressure is 4 bar. The change in water elevation across the pump is zero. The rise in internal energy of water is 280 J/kg. The pumping process is considered to be adiabatic. The exit velocity in m/s is: Select one: O a. 3.63 Control volume Ob. 14.51 D2 OC. 7.26 Pump Section (2) Section (1) P1
A pump delivers water (density equals 1000 kg/m^3) at a steady rate of 1219 L/min as shown in the figure. Just upstream of the pump [section (1)] where the pipe area is 56 cm^2., the pressure is 1 bar. Just downstream of the pump [section (2)] where the pipe area is 14 cm., the pressure is 4 bar. The change in water elevation across the pump is zero. The rise in internal energy of water is 280 J/kg. The pumping process is considered to be adiabatic. The exit velocity in m/s is: Select one: O a. 3.63 Control volume Ob. 14.51 D2 OC. 7.26 Pump Section (2) Section (1) P1
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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![A pump delivers water (density equals 1000 kg/m^3) at a steady rate of 1219 L/min as shown in the figure. Just upstream of the pump [section (1)] where the pipe area is 56 cm^2., the
pressure is 1 bar. Just downstream of the pump [section (2)] where the pipe area is 14 cm., the pressure is 4 bar. The change in water elevation across the pump is zero. The rise in
internal energy of water is 280 J/kg. The pumping process is considered to be adiabatic. The exit velocity in m/s is:
Select one:
It = ?
Оа. 3.63
Control volume
Ob. 14.51
D2
OC. 7.26
Pump
Section (2)
Section (1)
P1](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fcddd530b-f7e3-4c31-9e95-dc1f4b984d68%2F8d51cace-798b-4fa1-b410-2dd164265901%2Fdw9zyhd_processed.png&w=3840&q=75)
Transcribed Image Text:A pump delivers water (density equals 1000 kg/m^3) at a steady rate of 1219 L/min as shown in the figure. Just upstream of the pump [section (1)] where the pipe area is 56 cm^2., the
pressure is 1 bar. Just downstream of the pump [section (2)] where the pipe area is 14 cm., the pressure is 4 bar. The change in water elevation across the pump is zero. The rise in
internal energy of water is 280 J/kg. The pumping process is considered to be adiabatic. The exit velocity in m/s is:
Select one:
It = ?
Оа. 3.63
Control volume
Ob. 14.51
D2
OC. 7.26
Pump
Section (2)
Section (1)
P1
![A pump delivers water (density equals 1000 kg/m^3) at a steady rate of 1219 L/min as shown in the figure. Just upstream of the pump [section (1)] where the pipe area is 56 cm^2., the
pressure is 1 bar. Just downstream of the pump [section (2)] where the pipe area is 14 cm., the pressure is 4 bar. The change in water elevation across the pump is zero. The rise in
internal energy of water is 280 J/kg. The pumping process is considered to be adiabatic. The inlet velocity in m/s is:
Select one:
Wun = ?
O a. 3.63
Control volume
Ob. 14.51
D2
O. 36279.76
Pump
Section (2)
Section (1)
P1](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fcddd530b-f7e3-4c31-9e95-dc1f4b984d68%2F8d51cace-798b-4fa1-b410-2dd164265901%2Fuso7o2r_processed.png&w=3840&q=75)
Transcribed Image Text:A pump delivers water (density equals 1000 kg/m^3) at a steady rate of 1219 L/min as shown in the figure. Just upstream of the pump [section (1)] where the pipe area is 56 cm^2., the
pressure is 1 bar. Just downstream of the pump [section (2)] where the pipe area is 14 cm., the pressure is 4 bar. The change in water elevation across the pump is zero. The rise in
internal energy of water is 280 J/kg. The pumping process is considered to be adiabatic. The inlet velocity in m/s is:
Select one:
Wun = ?
O a. 3.63
Control volume
Ob. 14.51
D2
O. 36279.76
Pump
Section (2)
Section (1)
P1
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