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primary design tool was based on the work of Eppler (1990, 1993), who developed a method of determining the nature of the 2‐D viscous flow around an aerofoil of any profile. The Eppler method includes flow separation in the initial stages of stall and has proved to be very successful.

      In addition, several different aerofoil families have been designed for stall‐regulated, variable‐pitch, and variable‐rpm wind turbines.

      For stall‐regulated rotors, improved post‐stall power control is achieved through the design of aerofoils for the outer sections of a blade that limit the maximum lift coefficient. The same aerofoils have a relatively high thickness to chord ratio to accommodate overspeed control devices.

      For variable‐pitch and variable‐speed rotors, outer section aerofoils have a high maximum lift coefficient, allowing low blade solidity.

      Generally, aerofoil cross‐sections with a high thickness to chord ratio give structural designs of high stiffness and strength without causing a large weight penalty, and aerofoils of low thickness result in less drag.

Diameter Type Aerofoil thickness Primary Tip Root
3–10 m Variable speed Variable pitch Thick ‐‐‐ S822 S823
10–20 m Variable speed Variable pitch Thin S802 S802 S803 S804
10–20 m Stall regulated Thin S805 S805A S806 S806A S807 S808
10–20 m Stall regulated Thick S819 S820 S821
20–30 m Stall regulated Thick S809 S812 S810 S813 S811 S814, S815
20–40 m Variable speed S825 S826 S814
Variable pitch S815
30–50 m Stall regulated Thick S816 S817 S818
40–50 m Stall regulated Thick S827 S828 S818
40–50 m Variable speed Variable Pitch Thick S830 S831 S832 S818

      Annual energy capture improvements that are claimed for the NREL airfoil families are of the order of 23–35% for stall‐regulated turbines, 8–20% for variable‐pitch turbines, and 8–10% for variable‐rpm turbines. The improvement for stall‐regulated turbines has been verified in field tests.

      The aerofoil shape coordinates for some of the NREL aerofoils are available on the website of the National Wind Technology Center (NWTC) at Golden, Colorado. Measured aerofoil data for some aerofoils is also available. A licence must be purchased for information about those aerofoils that are restricted.

      3.17.3 The Risø aerofoils

      The Risø National Laboratory in Denmark have also developed families of aerofoil designs for wind turbines with similar objectives to the NREL series (Fugslang and Bak 2004). Although the aerodynamic design techniques of the two laboratories were different, there is, perhaps not surprisingly, a significant similarity about the actual designs.

      The design tools for the Risø aerofoils were the X‐FOIL code developed by Drela (1989), a development of the work of Eppler (1990, 1993), and the Ellipsys‐2D CFD code developed at the Technical University of Denmark by Sørensen (1995).

Schematic illustration of the NREL aerofoil profiles for large blades. Graph depicts the RisØ-A series of aerofoil profiles.
Aerofoil Max t/c % x/c at max t/c y/c at TE Re × 10−6 α ο cl max Design α Design cl Max cl/cd
Risø‐A1‐15 15 0.325 0.0025

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