16. In the pipe shown, is the pressure higher at point 2, where the fluid flows...
use
Bernoulli law to find the difference
6. Make a prediction. In the pipe shown in Figure below is the pressure higher at point 2 where the fluid flows fastest, or at point 1? The fluid in the pipe flows from left to right. #2 Use Bernoulli law to find out the difference.
Water flows through a pipe shaped as shown here. The pressure at the lower end of the pipe is 296 kPa and the fluid velocity is 5.00 m/s. The upper end of the pipe is 0.600 m higher and the cross-sectional area is 1/3 of the area at the lower end. Calculate the velocity at the upper end of the pipe. 15 m/s Calculate the pressure at the upper end of the pipe.
Fluid shown in (Figure 1) flows through the curved
pipe such that fluid particles move along the center streamline
with the velocity of V=(14s^2 + 1000t^3/2 +4)m/s, where s is in
meters and t is in seconds
Part A
Determine the magnitude of the acceleration of a particle at point
A, where s= 0.3m, if it arrives t = 0.02s
a=
Fundamental Problem 3.8 Fluid shown in (Figure 1) flows through the curved pipe Y Pa such that fluid particles...
Water can be considered as a non-viscous incompressible fluid of density p. A laboratory set-up is such that water flows through a pipe, exhibiting a laminar and steady-state flow. At the top end of the pipe, the flow tube has a cross-sectional area A and point 1 (located on the central streamline) is exposed to the ambient environment. The pipe drops through a A vertical distance h7 while its area decreases to when it reaches point 2 (also on the...
Water flows in the horizontal pipe shown in the figure.
At point A the area is 26.0 cm2 and the
speed of the water is 2.20 m/s. At B the area is 15.0
cm2. The fluid in the manometer is mercury, which has a
density of 13,600 kg/m3. We can treat water as an ideal
fluid having a density of 1000 kg/m3. What is the
manometer reading h?
Question 10 (1 point) Water flows in the horizontal pipe shown in...
Water flows through a pipe as shown in the figure. The pressure at points 1 and 2 respectively is 1.80 x 105 Pa and 1.20 x 105 Pa. The radius of the pipe at points 1 and 2 respectively is 3.50 cm and 1.20 cm. If the vertical distance between points 1 and 2 is 2.75 m, determine the following. (a) speed of flow at point 1 m/s (b) speed of flow at point 2 cm/s (c) volume flow rate...
3. Oil flows in the pipe shown. The orifice in the pipe has a coefficient of discharge of 0.64. Compute the discharge of the oil in the pipe CE311 Fluid Mechanics Winter 2019, Assignment 5, Due March 1 4. Water flows steadily through the funnel shown in the figure below. Throughout most of the funnel the flow is approximately radial (along rays from O) with a velocity of V- cr where r is the radial coordinate and c is a...
Water flows at a rate of 22 L/min through a horizontal 7.0-cm-diameter pipe under a pressure of 17.0 Pa . At one point, calcium deposits reduce the cross-sectional area of the pipe to 21 cm2 . What is the pressure at this point? (Consider the water to be an ideal fluid.) Express your answer using two significant figures.
Water flows at a rate of 21 L/min through a horizontal 8.0-cm-diameter pipe under a pressure of 3.8 Pa . At one point, calcium deposits reduce the cross-sectional area of the pipe to 39 cm2 . What is the pressure at this point? (Consider the water to be an ideal fluid.) Express your answer using two significant figures. p= Pa
(Fluid mechanics)
2 of 3 Water, assumed inviscid and incompressible, flows steadily out of a large tank as shown in the adjacent figure. Above the water there is a 2-m layer of oil of specific gravity SG = 0.81 and the water outlet is located 0.7 m below the oil-water interface. Take the elevation reference (z = 0) at the outlet level. Determine: Oil, SG = 0.81 0.7 m Water 50 mm diameter a) Are the validity conditions of Bernoulli's...