Pipe line sizing
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The document outlines 11 steps for sizing a pipe line to carry water at 100 m3/hr, including: calculating the internal pipe diameter, selecting the nearest available pipe size, determining the fluid velocity, calculating the Reynolds number and friction factor, determining equivalent length, calculating pressure drop, and comparing the available and calculated pressure drops. The goal is to select a pipe size that ensures the available pressure drop is greater than the calculated pressure drop.
![Koncept Learning Center
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Pipe Line Sizing
Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp)
Step-1 : Assume Fluid Velocity
Step-2 : Calculate Internal Pipe Line Diameter
Step-3 : Select Nearest Available Pipe Size
Step-4 : Find Pipe Internal Diameter
Step-5 : Calculate Fluid Velocityfor selected pipe size
Step-6 : Calculate Reynolds Number
Step-7 : Find Friction Factor
Step-8 : Determine Equivalent Length
Step-9 : Calculate Pressure Drop, Say Δp calculated
P = --------------- x [----- ]f x L x V2
D x 10000 2 g](https://image.slidesharecdn.com/pipelinesizing-130815043127-phpapp02/85/Pipe-line-sizing-10-320.jpg)
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Pipe line sizing
- 1. Koncept Learning Center [email protected] Pipe Line Sizing
- 2. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity
- 3. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter
- 4. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size
- 5. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter
- 6. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocity for selected pipe size
- 7. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocity for selected pipe size Step-6 : Calculate Reynolds Number Nre = D v ρ / μ
- 8. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocity for selected pipe size Step-6 : Calculate Reynolds Number Step-7 : Find Friction Factor
- 9. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocity for selected pipe size Step-6 : Calculate Reynolds Number Step-7 : Find Friction Factor Step-8 : Determine Equivalent Length
- 10. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocityfor selected pipe size Step-6 : Calculate Reynolds Number Step-7 : Find Friction Factor Step-8 : Determine Equivalent Length Step-9 : Calculate Pressure Drop, Say Δp calculated P = --------------- x [----- ]f x L x V2 D x 10000 2 g
- 11. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocity for selected pipe size Step-6 : Calculate Reynolds Number Step-7 : Find Friction Factor Step-8 : Determine Equivalent Length Step-9 : Calculate Pressure Drop, Say Δp calculated Step-10 : Determine Available Pressure Drop, Say Δp available
- 12. Koncept Learning Center [email protected] Pipe Line Sizing Sizing Pipe Line carrying Water @ 100 m3/hr (ρ = 1000 kg/m3 , μ = 1 cp) Step-1 : Assume Fluid Velocity Step-2 : Calculate Internal Pipe Line Diameter Step-3 : Select Nearest Available Pipe Size Step-4 : Find Pipe Internal Diameter Step-5 : Calculate Fluid Velocity for selected pipe size Step-6 : Calculate Reynolds Number Step-7 : Find Friction Factor Step-8 : Determine Equivalent Length Step-9 : Calculate Pressure Drop, Say Δp calculated Step-10 : Determine Available Pressure Drop, Say Δp available Step-11 : Compare Δp available & Δp calculated Δp available > Δp calculated
- 13. Koncept Learning Center [email protected] For Training Workshop Write us at : [email protected] Pipe Line Sizing