A fluid is pumped at a rate of 0.00156 m³/s through a 0.025-m-diameter pipe to fill a water tank as shown in Figure. What is the pressure drop between the inlet (section 1) and the outlet (section 2) accounting for all losses? The density of the fluid is (9.50x10^2) kg/m³ and the dynamic viscosity is 1.12 x 10 - 3 Ns/m2. The following are also known KĻ. elbow = 1.5, KĻ, exit = 1 and surface roughness, e = 0.001 mm. Also take gravity, g = 10 m/s?. The elbows are enlarged for ease of visualisation and the lengths shown are those of the pipes. Answer should be in Pa with three significant figures.
A fluid is pumped at a rate of 0.00156 m³/s through a 0.025-m-diameter pipe to fill a water tank as shown in Figure. What is the pressure drop between the inlet (section 1) and the outlet (section 2) accounting for all losses? The density of the fluid is (9.50x10^2) kg/m³ and the dynamic viscosity is 1.12 x 10 - 3 Ns/m2. The following are also known KĻ. elbow = 1.5, KĻ, exit = 1 and surface roughness, e = 0.001 mm. Also take gravity, g = 10 m/s?. The elbows are enlarged for ease of visualisation and the lengths shown are those of the pipes. Answer should be in Pa with three significant figures.
Chapter2: Loads On Structures
Section: Chapter Questions
Problem 1P
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I7
Transcribed Image Text:15 m
6 m
6 m
2
Elbow
6 m
3 m
1
15 m
Transcribed Image Text:A fluid is pumped at a rate of 0.00156 m³/s through a 0.025-m-diameter pipe to fill a
water tank as shown in Figure. What is the pressure drop between the inlet (section
1) and the outlet (section 2) accounting for all losses?
The density of the fluid is (9.50x10^2) kg/m and the dynamic viscosity
is 1.12 x 10 - 3 Ns/m2. The following are also known KĻ elbow = 1.5, KĻ, exit = 1 and
%3D
surface roughness, e = 0.001 mm. Also take gravity, g =
10 m/s².
The elbows are enlarged for ease of visualisation and the lengths shown are those of
the pipes.
Answer should be in Pa with three significant figures.
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