Wind Energy Handbook. Michael Barton Graham

Wind Energy Handbook - Michael Barton Graham


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drag‐free situation. However, the departure of the axial flow distribution from uniformity is not great, even when the lift/drag ratio is low, provided the flow around a blade remains attached.

      From the torque/angular momentum Eq. (3.52), the blade geometry parameter becomes

      (3.76)StartFraction italic upper B c lamda Over 2 pi upper R EndFraction upper C Subscript l Baseline equals StartStartFraction 4 lamda squared mu squared a prime left-parenthesis 1 minus a right-parenthesis OverOver StartFraction upper W Over upper U Subscript infinity Baseline EndFraction left-bracket left-parenthesis 1 minus a right-parenthesis minus StartFraction upper C Subscript d Baseline Over upper C Subscript l Baseline EndFraction lamda mu left-parenthesis 1 plus a prime right-parenthesis right-bracket EndEndFraction

Graphs depict the radial variation of the flow induction factors with and without drag. Graph depicts Spanwise variation of the blade geometry parameter with and without drag. Graph depicts the variation of inflow angle with local speed ratio with and without drag. Graph depicts the variation of maximum CP with design λ for various lift/drag ratios.

      As far as blade design for optimal operation is concerned, drag can be ignored, greatly simplifying the process.

      3.8.5 Optimal blade design for constant‐speed operation

      If the rotational speed of a turbine is maintained at a constant level, then the tip speed ratio is continuously changing, and a blade optimised for a fixed tip speed ratio would not be appropriate. Closed‐form solutions have been derived for optimum wind turbines; see Peters and Modarres (2013) and Jamieson (2018).

      No simple technique is available for the optimal design of a blade operating at constant rotational speed. Non‐linear (numerical) optimisation techniques may be used to solve the problem of maximising energy capture at a given site incorporating the data on its specific wind speed distribution. Alternatively, a design tip speed ratio can be chosen corresponding to the wind speed at the specified site that contains the most energy, or, more practically, the pitch angle for the whole blade can be adjusted to maximise energy capture.

      3.9.1 Introduction

      The analysis described in all prior sections assumes that the rotor has an infinite number of blades of infinitesimal chord so that every fluid particle passing through the rotor disc passes close to a blade through a region of strong interaction, i.e. that the loss of momentum in any annulus is uniform with respect to azimuth angle θ. With a finite (usually small, two or three) number of blades, some fluid particles will interact more strongly with the blades and some less strongly. The immediate loss of (kinetic) momentum by a particle will depend on the distance between its streamline and the blade as the particle passes through the rotor disc. These differences are subsequently reduced but not eliminated by the action of pressure forces between the adjacent curved streamlines and eventually by mixing. The axial induced velocity will therefore vary around the disc, the average value determining the overall axial momentum of the flow. What is also relevant is the incident velocity (relative angle and speed) that each blade section senses, i.e. to which it responds, as it rotates. When as here the incident flow is not uniform, a blade section senses a weighted average of the flow induced in the region occupied by the section in the absence of its own self‐generated flow field. This is usually evaluated as the velocity at the quarter chord of the section (cf. lifting line theory). For a rotor for which the product σλ of solidity and tip speed ratio is not too small, as is usual, it is found that the combination of incident wind, average axial induced velocity, and blade rotation speed gives a very good approximation to this incident velocity except close to the tip and root ends of the blade, where the sectional approximation breaks down.

Schematic illustration of the Helical trailing tip vortices <hr><noindex><a href=Скачать книгу