{"id":2692,"date":"2025-08-07T16:47:25","date_gmt":"2025-08-07T14:47:25","guid":{"rendered":"https:\/\/www.bf-hydraulik.com\/encyclopedia\/hydraulic-radius\/"},"modified":"2026-04-15T11:51:42","modified_gmt":"2026-04-15T09:51:42","slug":"hydraulic-radius","status":"publish","type":"encyclopedia","link":"https:\/\/www.bf-hydraulik.com\/en\/hydraulic-radius\/","title":{"rendered":"Hydraulic radius"},"content":{"rendered":"\t\t
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Hydraulic radius: the formula for calculation<\/h1>

The hydraulic radius<\/a> is a central parameter in hydraulics and fluid mechanics, particularly in describing flows in open channels and closed conduits. It plays an important role in calculating the flow velocity and discharge behavior of fluids, especially water in natural or artificial channels such as rivers, streams, canals, or pipes. However, it can be applied just as effectively to complex hydraulic system<\/a>s. The hydraulic radius<\/a> provides a base value that is combined in a second step with further values, such as flow velocity or the surface roughness of the wetted internal surface. <\/p>

Definition of the hydraulic radius<\/h2>

Mathematically, the hydraulic radius<\/a> R(h) is defined as the ratio of the cross-sectional area of the flow A to the wetted perimeter P:<\/p>

R(h) = A \/ P<\/strong><\/p>

A is the cross-sectional area of the flow region and is specified in a standard unit of area, such as square meters.<\/p>

P is the wetted perimeter, i.e., the part of the perimeter that is in contact with the fluid. The unit of measurement is also a standard unit of length, such as meters. For practical reasons, the area and length measurements should originate from the same system of units. <\/p>

This already shows that the result of the hydraulic radius<\/a> yields a length measurement, which corresponds to the traditional understanding of the term “radius” as the distance of half the circle diameter.<\/p>

In the frequently used application of an open channel (e.g., a stream bed), P corresponds to the perimeter that is actually wetted by water. This is the distance from water surface to water surface, measured along the cross-sectional profile of the submerged area. As an informative value, the hydraulic radius<\/a> can be used as a measure of the efficiency of a cross-section in relation to flow resistance. The smaller the distance P becomes, the larger the hydraulic radius<\/a>, the lower the flow resistance, and the higher the flow velocity. A semi-circular distance P offers the minimum value. <\/p>

Hydraulic radius as a factor for calculating flow velocity<\/h3>

The standard formula for calculating flow velocity is the “Manning equation.” It is used for calculating open channels and is as follows: <\/p>

v = 1\/n (R(h)²\/³ x S1\/²<\/strong><\/p>

v is the average flow velocity (m\/s),<\/em>
n is the roughness coefficient of the wetted surface (according to Manning),<\/em>
S is the slope of the channel.<\/em><\/p>

The larger the hydraulic radius<\/a>, the smaller the influence of friction forces at the wall in relation to the flow area. This increases the efficiency of the flow. Therefore, when designing channels or pipelines, the aim is often to achieve the highest possible hydraulic radius<\/a>, and the aforementioned semi-circular structure is preferred whenever possible. <\/p>

Application of the hydraulic radius<\/h3>

It is by no means the case that a particularly high flow velocity is always sought. Rather, the aim is to adapt the velocity to the respective requirement. The hydraulic radius<\/a> thus offers a simple and quickly implementable aid for modeling the profile of a river or stream bed so that it maintains an optimal flow velocity in every case. <\/p>\t\t\t\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t\t\t\t<\/div>\n\t\t<\/div>\n\t\t\t\t

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