Question

Water at a gauge pressure of P = 3.4 atm at street level flows into an office building at a speed of 0.64 m/s through a pipe 5.4 cm in diameter. The pipe tapers down to 2.8 cm in diameter by the top floor, 16 m above (Figure 1). Assume no branch pipes and ignore viscosity.

Calculate the flow velocity in the pipe on the top floor.

Calculate the gauge pressure in the pipe on the top floor.

Answer #1

please hit the like button.Thank you

Water at a gauge pressure of P = 3.4 atm at street level flows
into an office building at a speed of 0.86 m/s through a pipe 5.8
cm in diameter. The pipe tapers down to 2.6 cm in diameter by the
top floor, 16 m above (Figure 1). Assume no branch pipes and ignore
viscosity.
Calculate the flow velocity in the pipe on the top floor.
Calculate the gauge pressure in the pipe on the top floor.

Water at a gauge pressure of P = 3.2 atm at street level flows
into an office building at a speed of 0.90 m/s through a pipe 5.2
cm in diameter. The pipe tapers down to 2.6 cm in diameter by the
top floor, 16 m above (Figure 1). Assume no branch pipes and ignore
viscosity.
Part A: Calculate the flow velocity in the pipe on the top
floor. Express your answer to two significant figures and include
the appropriate...

Water at a gauge pressure of PPP = 3.6 atmatm at street level
flows into an office building at a speed of 0.96 m/sm/s through a
pipe 5.6 cmcm in diameter. The pipe tapers down to 2.8 cmcm in
diameter by the top floor, 16 mm above (Figure 1), where the faucet
has been left open. Assume no branch pipes and ignore
viscosity.
a.Calculate the flow velocity.
b.Calculate the gauge pressure in the pipe on the top floor.

Water at a pressure of 3.8 atm at street level flows into an
office building at a speed of 0.60 m/s through a pipe 5.6 cm in
diameter. The pipes taper down to 2.6 cm in diameter by the top
floor, 20m above (Fig. 10-49). Calculate the flow velocity and the
pressure in such a pipe on the top floor. Ignore viscosity.
Pressures are gauge pressures.
flow velocity___ m/s
pressure____ atm

Water at a pressure of 3.50 atm at street level flows into an
office building at a speed of 0.55 m/s through a pipe 6.80 cm in
diameter. The pipes taper down to 3.00 cm in diameter by the top
floor, 26.0 m above. Calculate the water pressure in such a pipe on
the top floor.

Water at a pressure of 3.30 atm at street level flows into an
office building at a speed of 0.80 m/s through a pipe 6.40 cm in
diameter. The pipes taper down to 2.80 cm in diameter by the top
floor, 30.0 m above. Calculate the water pressure in such a pipe on
the top floor.

Water at a pressure of 4.00 atm at street level flows into an
office building at a speed of 0.90 m/s through a pipe 3.60 cm in
diameter. The pipes taper down to 1.60 cm in diameter by the top
floor, 22.0 m above. Calculate the water pressure in such a pipe on
the top floor.

9. Water at a pressure of 4.50 atm at street
level flows into an office building at a speed of 0.80 m/s through
a pipe 6.00 cm in diameter. The pipes taper down to 3.00 cm in
diameter by the top floor, 27.0 m above. Calculate the water
pressure in such a pipe on the top floor.

A bathtub spigot in a top floor apartment lies 20 m above street
level, where water is pumped into the apartment building. The pipe
that leads into the building has an inner radius of 0.57 cm , which
tapers to 0.40 cm at the bathtub spigot opening. The speed of the
water leaving the spigot is 12 m/s . (The density of water is 1000
kg/m 3 .) Assume the water flows without viscosity.
(a) What is the speed of...

Given: The viscosity is negligible. Atmospheric pressure is
101300 Pa. Water flows at speed of 5.9 m/s through a horizontal
pipe of diameter 3.3 cm. The gauge pressure P1 of the water in the
pipe is 1.6 atm. A short segment of the pipe is constricted to a
smaller diameter of 2.4 cm.
What is the gauge pressure of the water flowing through the
constricted segment? Answer in units of atm.

ADVERTISEMENT

Get Answers For Free

Most questions answered within 1 hours.

ADVERTISEMENT

asked 32 minutes ago

asked 1 hour ago

asked 1 hour ago

asked 1 hour ago

asked 1 hour ago

asked 1 hour ago

asked 2 hours ago

asked 2 hours ago

asked 2 hours ago

asked 2 hours ago

asked 2 hours ago

asked 3 hours ago