Moody chart

Graph used in fluid dynamics

In engineering, the Moody chart or Moody diagram (also Stanton diagram) is a graph in non-dimensional form that relates the Darcy–Weisbach friction factor f_D, Reynolds number Re, and surface roughness for fully developed flow in a circular pipe. It can be used to predict pressure drop or flow rate down such a pipe.

Moody diagram showing the Darcy–Weisbach friction factor f_D plotted against Reynolds number Re for various relative roughness ε / D

History

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In 1944, Lewis Ferry Moody plotted the Darcy–Weisbach friction factor against Reynolds number Re for various values of relative roughness ε / D.^[1] This chart became commonly known as the Moody chart or Moody diagram. It adapts the work of Hunter Rouse ^[2] but uses the more practical choice of coordinates employed by R. J. S. Pigott,^[3] whose work was based upon an analysis of some 10,000 experiments from various sources.^[4] Measurements of fluid flow in artificially roughened pipes by J. Nikuradse ^[5] were at the time too recent to include in Pigott's chart.

The chart's purpose was to provide a graphical representation of the function of C. F. Colebrook in collaboration with C. M. White,^[6] which provided a practical form of transition curve to bridge the transition zone between smooth and rough pipes, the region of incomplete turbulence.

Description

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Moody's team used the available data (including that of Nikuradse) to show that fluid flow in rough pipes could be described by four dimensionless quantities: Reynolds number, pressure loss coefficient, diameter ratio of the pipe and the relative roughness of the pipe. They then produced a single plot which showed that all of these collapsed onto a series of lines, now known as the Moody chart. This dimensionless chart is used to work out pressure drop, $\Delta p$ {\displaystyle \Delta p} (Pa) (or head loss, $h_{f}$ {\displaystyle h_{f}}(m)) and flow rate through pipes. Head loss can be calculated using the Darcy–Weisbach equation in which the Darcy friction factor $f_{D}$ {\displaystyle f_{D}} appears :

h_{f}=f_{D}{\frac {L}{D}}{\frac {V^{2}}{2,円g}};

{\displaystyle h_{f}=f_{D}{\frac {L}{D}}{\frac {V^{2}}{2,円g}};}

Pressure drop can then be evaluated as:

\Delta p=\rho ,円g,円h_{f}

{\displaystyle \Delta p=\rho ,円g,円h_{f}}

or directly from

\Delta p=f_{D}{\frac {\rho V^{2}}{2}}{\frac {L}{D}},

{\displaystyle \Delta p=f_{D}{\frac {\rho V^{2}}{2}}{\frac {L}{D}},}

where $\rho$ {\displaystyle \rho } is the density of the fluid, $V$ {\displaystyle V} is the average velocity in the pipe, $f_{D}$ {\displaystyle f_{D}} is the friction factor from the Moody chart, $L$ {\displaystyle L} is the length of the pipe and $D$ {\displaystyle D} is the pipe diameter.

The chart plots Darcy–Weisbach friction factor $f_{D}$ {\displaystyle f_{D}} against Reynolds number Re for a variety of relative roughnesses, the ratio of the mean height of roughness of the pipe to the pipe diameter or $\epsilon /D$ {\displaystyle \epsilon /D}.

The Moody chart can be divided into two regimes of flow: laminar and turbulent. For the laminar flow regime ( $Re$ {\displaystyle Re}< ~3000), roughness has no discernible effect, and the Darcy–Weisbach friction factor $f_{D}$ {\displaystyle f_{D}} was determined analytically by Poiseuille:

f_{D}=64/\mathrm {Re} ,{\text{for laminar flow}}.

{\displaystyle f_{D}=64/\mathrm {Re} ,{\text{for laminar flow}}.}

For the turbulent flow regime, the relationship between the friction factor $f_{D}$ {\displaystyle f_{D}} the Reynolds number Re, and the relative roughness $\epsilon /D$ {\displaystyle \epsilon /D} is more complex. One model for this relationship is the Colebrook equation (which is an implicit equation in $f_{D}$ {\displaystyle f_{D}}):

{1 \over {\sqrt {f_{D}}}}=-2.0\log _{10}\left({\frac {\epsilon /D}{3.7}}+{\frac {2.51}{\mathrm {Re} {\sqrt {f_{D}}}}}\right),{\text{for turbulent flow}}.

{\displaystyle {1 \over {\sqrt {f_{D}}}}=-2.0\log _{10}\left({\frac {\epsilon /D}{3.7}}+{\frac {2.51}{\mathrm {Re} {\sqrt {f_{D}}}}}\right),{\text{for turbulent flow}}.}

Fanning friction factor

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This formula must not be confused with the Fanning equation, using the Fanning friction factor $f$ {\displaystyle f}, equal to one fourth the Darcy-Weisbach friction factor $f_{D}$ {\displaystyle f_{D}}. Here the pressure drop is:

\Delta p={\frac {\rho V^{2}}{2}}{\frac {4fL}{D}},

{\displaystyle \Delta p={\frac {\rho V^{2}}{2}}{\frac {4fL}{D}},}

References

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^ Moody, L. F. (1944), "Friction factors for pipe flow" (PDF), Transactions of the ASME, 66 (8): 671–684, archived (PDF) from the original on 2019年11月26日
^ Rouse, H. (1943). Evaluation of Boundary Roughness. Proceedings Second Hydraulic Conference, University of Iowa Bulletin 27.
^ Pigott, R. J. S. (1933). "The Flow of Fluids in Closed Conduits". Mechanical Engineering. 55: 497–501, 515.
^ Kemler, E. (1933). "A Study of the Data on the Flow of Fluid in Pipes". Transactions of the ASME. 55 (Hyd-55-2): 7–32.
^ Nikuradse, J. (1933). "Strömungsgesetze in Rauen Rohren". V. D. I. Forschungsheft. 361. Berlin: 1–22. These show in detail the transition region for pipes with high relative roughness (ε / D > 0.001).
^ Colebrook, C. F. (1938–1939). "Turbulent Flow in Pipes, With Particular Reference to the Transition Region Between the Smooth and Rough Pipe Laws". Journal of the Institution of Civil Engineers. 11 (4). London, England: 133–156. doi:10.1680/ijoti.1939.13150.

History

Description

Fanning friction factor

References

See also