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CHE315 Pressure Drop and Friction Loss 2.10 Design Equations for Laminar and Turbulent Flow in Pipes.

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Presentation on theme: "CHE315 Pressure Drop and Friction Loss 2.10 Design Equations for Laminar and Turbulent Flow in Pipes."— Presentation transcript:

1 CHE315 Pressure Drop and Friction Loss 2.10 Design Equations for Laminar and Turbulent Flow in Pipes

2 CHE315 Pressure Drop and Friction Loss 2.10 Design Equations for Laminar and Turbulent Flow in Pipes

3 CHE315 Pressure Drop and Friction Loss 2.10B PRESSURE DROP AND FRICTION LOSS IN LAMINAR FLOW Example. 2.10-1

4 CHE315 Pressure Drop and Friction Loss Fanning friction factor f for friction loss in laminar flow f is defined as drag force per wetted surface unit area (  s at the surface area) divided by the product of density times the velocity head (  v 2 /2): The drag force The wetted surface unit area

5 CHE315 Pressure Drop and Friction Loss For laminar flow only, combining equations: and Eq (2.10-2) Eq (2.10-5)

6 CHE315 Pressure Drop and Friction Loss f from Figure 2.10-3 Laminar Turbulent

7 CHE315

8 Example 2.10-3 NOTE: If velocity and diameter are both unknown, Solution should be Trial –and-error soln. (or computerized). Pressure Drop and Friction Loss

9 CHE315 Step by step procedure for trial-and error solution 1.Assume an initial value for the velocity (or the diameter) 2.Calculate the Reynolds number (and  /D) 3.From the figure 3.10-3, read the corresponding friction factor f 4.Substitute f into: 5.Compare the obtained value with the initial one 6.If values are different repeat from step2 with the obtained value Pressure Drop and Friction Loss

10 CHE315 Example 2.10-4 Example 2.10.5 Pressure Drop and Friction Loss

11 CHE315 Pressure Drop and Friction Loss For gases, the equation can be rewritten as follows: Pressure drop and friction factor in flow of gas Ideal Gas Law:

12 CHE315 Pressure Drop and Friction Loss How did we arrive to this equation? Using Ideal Gas Law; The following equation can be obtained

13 CHE315 A L A S v L v S Pressure Drop and Friction Loss K f : Turbulent: Table 2.10-1 Laminar: Table 2.10-2

14 CHE315 Pressure Drop and Friction Loss

15 CHE315 Example 2.10.6 Example 2.10.7 Pressure Drop and Friction Loss

16 CHE315 FRICTION LOSSES IN NONCIRCULAR CONDUITS The equivalent diameter D is defined as four times the hydraulic radius r H, defined as the ratio of the cross-sectional area of the channel to the wetted perimeter of the channel.: Pressure Drop and Friction Loss

17 CHE315 Calculate the equivalent diameter? Pressure Drop and Friction Loss

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