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Problem 6.127 Network Flow Scott Jewett BIEN 301 January 30, 2007.

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Presentation on theme: "Problem 6.127 Network Flow Scott Jewett BIEN 301 January 30, 2007."— Presentation transcript:

1 Problem 6.127 Network Flow Scott Jewett BIEN 301 January 30, 2007

2 Problem Diagram Horizontal Pipe Network A C B D 2 ft 3 /s D=6 in D=8 in D=3 in D=9 in 4000 ft 3000 ft f =.025 P A = 120 psi T= 20°C

3 Required 1.Determine the flow rate and direction in all the pipes 2.Determine the pressures at points B, C, and D.

4 Assumptions Liquid Incompressible Steady Viscous

5 Assumptions (cont.) Flow directions Loop directions A C B D Q ac Q cd Q bd Q ab Q bc L1L1 L2L2

6 Nodal Equations Solve nodal equations Flow out - Flow in = 0 Node A: Node C: Node B: A C B D Q ac Q cd Q bd Q ab Q bc L1L1 L2L2 2ft 3 /s

7 Use equation 6.10 to obtain head loss as a function of flow rate for each pipe Head loss

8 Obtain five equations relating flow rate to head loss

9 Loop Equations Set up loop equations: Sum of head losses around loop = 0 Loop 1: Loop 2: If the flow is opposite the loop, then the head loss is negative. A C B D Q ac Q cd Q bd Q ab Q cb L1L1 L2L2

10 System of equations Five equations, Five unknowns

11 Solution Solve using Mathcad or similar tool Q ab = 1.187 ft 3 /s Q ac =.813 ft 3 /s Q cb =.99 ft 3 /s Q cd = 1.803 ft 3 /s Q bd =.197 ft 3 /s

12 Pressure Solution Equation 6.8 relates pressure to head loss h f = ( P a - P b )/(ρg)

13 Pressure solution P b = P a - ρgh f(ab) P b = 120 psi - ρg(19.116*(Q ab ) 2 ) P b = 108 psi P c = P b - ρgh f(cb) P c = 102 psi P d = P c - ρgh f(cd) P d = 74 psi

14 Biomedical Application Blood flow –Your body consists of blood vessels with varying: Diameter Friction Height –All of these affect flow rate and pressure.

15 Questions?

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