A horizontal pipe is shown in the figure below. At the inlet (Point 1), the radius...
A horizontal pipe is shown in the figure below. At the inlet (Point 1), the radius of the pipe is 4 cm and the velocity profile is given by: 16-y2 cm/s. At the outlet (Point 2), the radius is 2 cm and the velocity changes to a uniform profile, as shown in the figure. If the viscosity of the liquid inside the pipe is 0.08 [Pa 8) and its density is 990 kg/m3, calculate: U= y y= 16 - y2...
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A horizontal pipe is shown in the figure below. At the inlet (Point 1), the radius of the pipe is 4 cm and the velocity profile is given by: V = 16- y2 cm/s. At the outlet (Point 2), the radius is 2 cm and the velocity changes to a uniform profile, as shown in the figure. If the viscosity of the liquid inside the pipe is 0.07 [Pa s] and its density is 1030 kg/m3,...
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A horizontal pipe is shown in the figure below. At the inlet (Point 1), the radius of the pipe is 4 cm and the velocity profile is given by: v = 16- y2 cm/s. At the outlet (Point 2), the radius is 2 cm and the velocity changes to a uniform profile, as shown in the figure. If the viscosity of the liquid inside the pipe is 0.01 [Pa s) and its density is 900...
2:50 PM Sat Apr 27 2. A pipe with an elbow is shown in the figure. The entrance is connected to another pipe with a flange The inlet and exit areas are 0.02 mi and 0.01 m respectively. The inlet pressure and velocity are 10 Pa andO 5 m/s respectively. (a) Determine the anchoring force. b) If the velocity varies linearly in the last gne meter of the pipe, determine the acceleration of the luid at the exit (25 points)...
Water moves through a constricted pipe in steady, ideal flow. At the lower point shown in the figure below, the pressure is 1.65 ✕ 105 Pa and the pipe radius is 2.50 cm. At the higher point located at y = 2.50 m, the pressure is 1.30 ✕ 105 Pa and the pipe radius is 1.20 cm.
Water moves through a constricted pipe in steady, ideal flow. At the lower point shown in the figure below, the pressure is 1.65 ✕ 105 Pa and the pipe radius is 2.50 cm. At the higher point located at y = 2.50 m, the pressure is 1.22 ✕ 105 Pa and the pipe radius is 1.20 cm (a) Find the speed of flow in the lower section. (b) Find the speed of flow in the upper section. (c) Find the...
2. In the figure below a cylindrical pipe with radius R and length L is shown. A liquid with constant physical properties is pumped upward in Z-direction, opposing the gravity. Flow is steady state, laminar and incompressible. Tube length is sufficiently Targe that the velocity varies only with respect to r. The pressure at z=0 is Po and z=L is P a. Obtain the velocity profile of the flowing water by using shell balance. (V, (PCOSGOR? (Po-PUR2 A AHL b....
The fluid domain shown in Figure A6 has a gap width of into the paper. If the general form of the velocity profile is given by 1 u(y) = Op2 2ur Then a) Show that the specific profile is given by Uy + Op 2 u(y) [5 marks] b) Find the shear stress if the fluid is Newtonian [5 marks] c) Evaluate the average velocity. [5 marks d) Sketch the velocity profile in the domain when the pressure gradient is...
(a) A horizontal pipe of diameter 10 cm carries crude oil from A
to C as shown in Figure 4. At a point B, midway between A and C,
oil leaks at a volume flow rate of QL . The pressure
drop per unit length along AB is 640 Pa/m and along BC is 600 Pa/m.
Determine the leakage flow rate QL . The density of oil
is 800 kg/m3 and its dynamic viscosity is 0.1 N.s/
m2 . You...
Water moves through a constricted pipe in steady, ideal flow. At the lower point shown in the figure below, the pressure is 1.70 x 105 Pa and the pipe radius is 2.60 cm. At the higher point located at y = 2.50 m, the pressure is 1.24 x 10 Pa and the pipe radius is 1.70 cm. (a) Find the speed of flow in the lower section. m/s (b) Find the speed of flow in the upper section. m/s (c)...