The hydraulic diameter, DH, is a commonly used term when handling flow in non-circular tubes and channels. Using this term, one can calculate many things in the same way as for a round tube. When the cross-section is uniform along the tube or channel length, it is defined as[1][2]

where

A is the cross-sectional area of the flow,
P is the wetted perimeter of the cross-section.

More intuitively, the hydraulic diameter can be understood as a function of the hydraulic radius RH, which is defined as the cross-sectional area of the channel divided by the wetted perimeter. Here, the wetted perimeter includes all surfaces acted upon by shear stress from the fluid.[3]

Note that for the case of a circular pipe,

The need for the hydraulic diameter arises due to the use of a single dimension in the case of a dimensionless quantity such as the Reynolds number, which prefers a single variable for flow analysis rather than the set of variables as listed in the table below. The Manning formula contains a quantity called the hydraulic radius. Despite what the name may suggest, the hydraulic diameter is not twice the hydraulic radius, but four times larger.

Hydraulic diameter is mainly used for calculations involving turbulent flow. Secondary flows can be observed in non-circular ducts as a result of turbulent shear stress in the turbulent flow. Hydraulic diameter is also used in calculation of heat transfer in internal-flow problems.[4]

Non-uniform and non-circular cross-section channels

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In the more general case, channels with non-uniform non-circular cross-sectional area, such as the Tesla valve, the hydraulic diameter is defined as:[5]

 

where

V is the total wetted volume of the channel,
S is the total wetted surface area.

This definition is reduced to   for uniform non-circular cross-section channels, and   for circular pipes.

List of hydraulic diameters

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Geometry Hydraulic diameter Comment
Circular tube   For a circular tube the hydraulic diameter is simply the diameter of the tube.
Annulus  
Square duct   here a represents the length of a side, not the cross sectional area
Rectangular duct (fully filled). The duct is closed so that the wetted perimeter consists of the 4 sides of the duct.   For the limiting case of a very wide duct, i.e. a slot of width b, where ba, then DH = 2a.
Channel of water or partially filled rectangular duct. Open from top by definition so that the wetted perimeter consists of the 3 sides of the duct (2 on the side and the base).   For the limiting case of a very wide duct, i.e. a slot of width b, where ba, and a is the water depth, then DH = 4a.

For a fully filled duct or pipe whose cross-section is a convex regular polygon, the hydraulic diameter is equivalent to the diameter   of a circle inscribed within the wetted perimeter. This can be seen as follows: The  -sided regular polygon is a union of   triangles, each of height   and base  . Each such triangle contributes   to the total area and   to the total perimeter, giving

 

for the hydraulic diameter.

References

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  1. ^ Kudela, Henryk (May 2017). "Viscous flow in pipe" (PDF). p. 3.
  2. ^ "Hydraulic Diameter for Non-Circular Ducts" (PDF). May 2017. p. 2. Archived from the original (PDF) on 2011-06-14.
  3. ^ Frank M. White. Fluid Mechanics. Seventh Ed.
  4. ^ S. G. Kandlikar; Srinivas Garimella; Dongqing Li; Stéphane Colin; Michael R. King (2013). Heat transfer and fluid flow in minichannels and microchannels (2nd ed.). Oxford: Butterworth-Heinemann. doi:10.1016/C2011-0-07521-X. ISBN 978-0-08-098351-6. OCLC 862108729.
  5. ^ Nguyen, Quynh M.; Huang, Dean; Dean, Evan; Romanelli, Genievieve; Meyer, Charlotte; Ristroph, Leif (Oct 2020). "Tesla's fluidic diode and the electronic-hydraulic analogy". American Journal of Physics. 89 (4): 393–402. arXiv:2103.14813. doi:10.1119/10.0003395. S2CID 232401497.

See also

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