In the branched pipe system below, water is flowing at 0.0142 m³/s in anew, clean DN 100 Schedule 40 pipe (ID = 0.1023 m) at A. The flow splits into twonew, clean DN 50 Schedule 40 pipes (ID = 0.0525 m; A = 0.00216 m³) as shownand then rejoins at B. Call the upper branch "a" and the lower branch "b." Thefriction factor in the upper branch is 0.021, and the friction factor in the lowerbranch is 0.0215. Calculate the flow rate in each of the branches. Include theeffect of all minor losses in the lower branch. The total length of the pipe in thelower branch is 60 m. The elbows are standard.DN 100 Schedule 40DN 100 Schedule 40- 30 mPBDN 50 Schedule 40Angle valvefully open

Solution Given That Water Flowing= 0.0142 m3/s Friction Factor (Upper Branch)=0.021 Friction factor…

Answered: In the branched pipe system below,…

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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Subject water system design Answer the second question
FInd the velocity (Vi) in the 4 inch pipe is 36 ft/sec, the minor head loss due to sudden expansion is 0.25 ft as shown in the plot Determine the following: (a) The total head loss (hu) and the elevation at B. (b) The discharge, in the pipe system (assume steady state conditions), velocity V, in the 6 inch pipe. (C) Complete the EGL-HGL plot by drawing the missing HGL line
1. The total headloss from A to E is 26.2 m. Compute the flow for all pipes B 2 D 3 E Pipe C 5 AB BD DE BC CD f 0.02 0.02 0.02 0.02 0.02 Diameter Length (mm) in (m) 600 500 600 400 450 600 650 700 450 450
From reservoir A water is supplied by a pipe that is 12 inches in diameter and 1000 ft long. At point D it is divided into two branches. One 6 inch-diameter, 2000-ft-long pipe connects to reservoir B and another 12 inch-diameter, 1500-ft- long pipe connects to reservoir C. The surface elevations at A, B, C, and D are 120 ft, 80 ft, 40 ft, and 60 ft respectively. Determine the flow in each pipe. Take f = 0.007 for all pipes and PD/γ is 20.5 ft.
Q4: Assuming f-0.020, determine the discharge in the pipes. Neglect minor losses. Pipe Diameter AB 250 mm 200 mm 400 mm BC BD Length 1200 m 600 m 200 m EL.45m EL 3m. B C EL. 3.0m D EL 0.0m
For the branching pipe system shown, determine the flow in each branch. The fluid in each reservoir is water at 20°C and all pipes are made of cast iron
1. The total headlost from A to E as shown is 20 m. Use n = 0.011 to all pipes Compute for the discharge at line 2 Compute for the discharge at line 1 Compute for the discharge at line 4 (BCD) Pipe Diameter Length in (mm) 600 AB BC CD BD DE 450 450 500 600 Q1 = Q3 Q1 = Q2 + Q4 hfr = hf₁ + hf₂ + hf3 hf₂ = hf Q4 = 0.2974 m³/s Q₁ = 0.7663 m³/s Q3 = 0.7663 m³/s Q2 = 0.4689 m³/s m 600 400 450 600 650 1 B 2 C D 3 E
Determine the discharge for pipe network at each branch 1524 m, 305mm Q = 0.513 m /s A B 915 m, 406mm
the marked choice is the correct answer.
PROBLEM 1 The total discharge in the system below is 15.5 cfs and the head loss from B to Cis 24 ft. Using n = 0.011 for all pipes, determine the following: (a) flow rate Q2 (cfs) through pipe 2, (b) flow rate Qs (cfs) through pipe 3, (c) flow rate Qa (cfs) through pipe 4, 2000 ft 12 in (d) head loss hu (ft) in pipe 1, and (e) head loss his (ft) in pipe 5. 3000 ft 1500 ft 4000 ft 30 in 10 in 24 in A D 2500 ft 15 in
1. A pipe system, connecting two reservoirs whose difference in water surface elevation is 13 meters, consist of 320 meters of 600 mm diameter pipe (pipe 1), branching into 640 meters of 300 mm diameter pipe (pipe 2) and 640 meters of 450 mm diameter pipe (pipe 3) in parallel, which join again to a single 600 mm diameter line 1300 meters long pipe (pipe 3). Assuming f = 0.032 for all pipes. Determine the flow rate in each pipe
PROBLEM 1 The total discharge in the system below is 15.5 cfs and the head loss from B to C is 24 ft. Using n = 0.011 for all pipes, determine the following: (a) flow rate Q2 (cfs) through pipe 2, (b) flow rate Q3 (cfs) through pipe 3, (c) flow rate Qa (cfs) through pipe 4, (d) head loss hu (ft) in pipe 1, and (e) head loss his (ft) in pipe 5. 2000 ft 12 in 3000 ft 1500 ft 4000 ft 30 in 10 in 24 in A B 2500 ft 15 in

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