I7 15 m6 m6 m2Elbow6 m3 m115 m A fluid is pumped at a rate of 0.00156 m³/s through a 0.025-m-diameter pipe to fill awater tank as shown in Figure. What is the pressure drop between the inlet (section1) and the outlet (section 2) accounting for all losses?The density of the fluid is (9.50x10^2) kg/m and the dynamic viscosityis 1.12 x 10 - 3 Ns/m2. The following are also known KĻ elbow = 1.5, KĻ, exit = 1 and%3Dsurface 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 ofthe pipes.Answer should be in Pa with three significant figures.

Answered: Image /qna-images/answer/4c63ca52-dee7-436f-bfca-e70bbdb9a56f.jpg

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.

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

See similar textbooks

Similar questions

mater 10
A liquid of specific weight 58 lb/ft3 flows by gravity through a 1-ft tank and a 1-ft capillary tube at a rate of 0.15 ft3/h, as shown in the figure below. Sections 1 and 2 are atmospheric pressure. Neglecting entrance effects, compute the viscosity of the liquid. 1 ft 1 ft d = 0.004 ft Q=0.15 ft³/h O 9.631 x 10-4 Pa-s O 7.654 x 10-4 Pa-s O 2.468 x 10.4 Pa-s ○ 4.567 x 10.4 Pa-s
An illegal connection was detected along a water 400 mm water supply line made with cast iron pipe (n=0.012). before the said illegal connection the difference in pressure for every 100 meters is 1 m and after it the difference in pressure for 100 meter is only 0.7 m compute the decrease in supply due to this connection.PLEASE DRAW FIGURE/DIAGRAM
An illegal connection was detected along a water 400 mm water supply line made with cast iron pipe (n = 0.012). Before the said illegal connection, the difference in pressure for every 100 meters is 1 meter and after it the difference in pressure per 100 meters is only 0.7 m. Compute the decrease in supply due to this connection. *please provide figure tnx
2..
E10
A 25-mm-diameter pipe 35m long is used to convey oil. The oil has a density of 880kg/m³ and a kinematic viscosity of 0.25×10*m³/s. The discharge in the pipe is Q=24x10*m³/min. Given that the pipe is placed horizontally and there are no any minor losses. Determine the pressure drop between the entrance and exit of pipe.
Kindly give me right solution with clear calculations. Please don't copy from chegg answers.
(Multiple pipes) The three tanks shown in the figure below are connected by pipes with friction factors of 0.03 for each pipe. Determine the water velocity in each pipe. Neglect minor losses. Elevation = 857 ft Elevation = 822 ft D = 1.1 ft D = 1.0 ft l = 700 ft l = 800 ft (1) (A) V₁ = i (B) V₂ = i (C) V3 = i (3) D = 1.2 ft € = 600 ft (2) ft/s ft/s ft/s Elevation = 793 ft
If a fluid having viscosity 0.6 Ns/m² and density of 900 kg/m³, flows through a pipe of diameter 40 mm, then find the maximum velocity of fluid (in m/s) inside the pipe for laminar flow. (Critical Reynold's number = 2100) _V D = 40 mm p = 900 Kg/m³ μ = 0.6 Ns/m²
Please solve it correctly asap.
1) The figure shows a conduit made of 1 std type K drawn copper tubing that conveys acetone at a flow rate of 1.33x10 m³/s. All fittings are soldered; the gate valve is fully open. (a) calculate the pressure drop through the system using minor-loss values. (b) Calculate the pressure drop through the system using equivalent length values. Compare the results. The total length of tubing is 9.15 m and the conduit is in a horizontal plane.