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is convenient to consider the drag exerted on 2‐D bodies across a uniform flow, because many general practical bodies are of a configuration that has one long cross‐flow dimension such that the flow varies only gradually in that ‘long’ direction. In such cases, 2‐D flow is a good local approximation to the flow about any section of the body normal to the long axis. These configurations may be termed quasi‐2‐D. Wind turbine blades and towers are examples of such bodies.

      All fluids (with a very few special exceptions, such as liquid helium) have some viscosity, although in the case of two of the most common fluids, air and water, it is relatively small. In the absence of any viscous effect, the flow slips relative to the body at its surface, can be described by a potential function, and is called potential flow. The drag in this case on a 2‐D body in fully subsonic, steady inviscid flow is exactly zero because no wake is generated.

Schematic illustration of the flow past a streamlined body.

      Many practical bodies such as wind turbines or aircraft involve a complex assembly of components that individually belong to the preceding categories. Forces on such bodies are usually calculated by breaking the body down into quasi‐2‐D elements, and interactions between elements are dealt with, when significant, by interference coefficients. In some cases where it is appropriate to consider sectional flow, such as for the blades of a wind turbine, the flow is not exactly in the plane of the section and may contain a non‐zero ‘lengthwise’ or transverse component. It is usual and can be demonstrated that if boundary layer effects are neglected, the pressures and forces on any body section normal to the long axis result from only those flow components that are in the plane of the section and are insensitive to the velocity component parallel to the long axis. This is known as the independence principle and holds quite accurately for real attached viscous flows up to angles of yaw between the flow and the long axis from normal flow (0° of yaw) to about 45° of yaw. This covers the usual range for such elements as wind turbine blades. For larger yaw angles than this the independence principle is increasingly in error, and as the yaw angle approaches 90° the flow becomes more like that of a slender body.

      A3.2 The boundary layer

Graph depicts the boundary layer showing the velocity profile.

      A3.3 Boundary layer separation

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