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Rotor Performance Enhancement Using Slats on the Inner Part of a 10MW Rotor Mac Gaunaa, Frederik Zahle, Niels N. Sørensen, Christian Bak, Pierre- Elouan.

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Presentation on theme: "Rotor Performance Enhancement Using Slats on the Inner Part of a 10MW Rotor Mac Gaunaa, Frederik Zahle, Niels N. Sørensen, Christian Bak, Pierre- Elouan."— Presentation transcript:

1 Rotor Performance Enhancement Using Slats on the Inner Part of a 10MW Rotor Mac Gaunaa, Frederik Zahle, Niels N. Sørensen, Christian Bak, Pierre- Elouan Réthoré Wind Energy Department, DTU Wind Energy, DK-4000 Roskilde, Denmark

2 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Outline  Introduction & Motivation  Methods used in this work  Reference rotor  Results & Discussion  Conclusions & Outlook Feb. 4th2EWEA 2013 Vienna

3 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Introduction & motivation  Conventional Blade Element Momentum based design methods result in too lightly loaded inner part of rotors for maximum energy capture  The inner part of wind turbine blades have a high relative thickness due to structural/load/cost constraints  This results in poor aerodynamic performance on the inner part of the rotors  Earlier findings have shown that it is possible to increase the performance of (very) thick 2D airfoils drastically using leading edge slats  What if we try to tap into this unused power production potential using leading edge slats?  How do we do that?  What could be gained from it? Feb. 4th3EWEA 2013 Vienna

4 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Flow behavior for a ”thick” main airfoil alone Introduction Feb. 4th4EWEA 2013 Vienna

5 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Flow behavior example: α=2 0 Pressures and streamlines Re=1*10 6 Introduction Feb. 4th5EWEA 2013 Vienna

6 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Flow behavior example: α=8 0 Pressures and streamlines Re=1*10 6 Introduction Feb. 4th6EWEA 2013 Vienna

7 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Flow behavior example: α=14 0 Pressures and streamlines Re=1*10 6 Introduction Feb. 4th7EWEA 2013 Vienna

8 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Flow behavior example: α=24 0 Pressures and streamlines Re=1*10 6 Introduction Feb. 4th8EWEA 2013 Vienna

9 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” An example of lift and drag c s /c=0.3, results from Torque 2010, Gaunaa et.al. Introduction Feb. 4th9EWEA 2013 Vienna

10 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Outline  Introduction & Motivation  Methods used in this work  Reference rotor  Results & Discussion  Conclusions & Outlook Feb. 4th10EWEA 2013 Vienna

11 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Methods & Tools  Rotor design  Based on Lifting Line free wake method results  Specified  (r)  dF/dr(r) and flow angle  2D optimization framework  A coupling of  Optimization: OpenMDAO  Airfoil representation using Bezier splines  2D CFD  -Cost= K opt C l /C d (  *-  ) /A + (1-K opt )C l (  *)/B  17 design variables:  *(1), slat TE pos(2), slat angle(1) & slat shape(13)  CFD solver EllipSys2D/3D  Used for optimization (2D) and evaluation of the design (3D)  Incompressible RANS solver using structured curvilinear grids  k-  SST turbulence model, Overset method used in 3D for the slats  Validated performance with multi element airfoils in 2D for the AGARD test case Feb. 4th11EWEA 2013 Vienna

12 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Outline  Introduction & Motivation  Methods used in this work  Reference rotor  Results & Discussion  Conclusions & Outlook Feb. 4th12EWEA 2013 Vienna

13 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Reference rotor and setup  DTU 10MW reference rotor (Light Rotor, Inn Wind)  State of the art, “realistic rotor”, based on FFA-W3-XXX airfoils  3 bladed PRVS rotor, 10MW  R=89.16M  Rated wind speed 11.5 m/s  Optimal Tip Speed Ratio is =7.5  We allow a retwisting of the radial locations where the slats are located, but otherwise do not change the reference blade  Slats are designed for 0.1  r/R  0.3 0.08  r/R  0.32  Chordlength ratios and main airfoil thickness ratios are given below Feb. 4th13EWEA 2013 Vienna r/R0.10.150.1750.20.250.3 c slat /c main 0.540.520.500.350.20 t/c main 0.940.770.670.580.450.38

14 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Outline  Introduction & Motivation  Methods used in this work  Reference rotor  Results & Discussion  Conclusions & Outlook Feb. 4th14EWEA 2013 Vienna

15 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Rotor design results from lifting line free wake method Feb. 4th15EWEA 2013 Vienna Lift coefficient versus r/RFlow angle versus r/R

16 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Slat design (2D CFD) to obtain 2D crossectional shape of slats r/R=0.15 t main /c main =0.77 c slat /c main =0.52 C l,max >3.5 Feb. 4th16EWEA 2013 Vienna  =20

17 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Slat design 2D airfoil performances. C l versus  Feb. 4th17EWEA 2013 Vienna

18 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Lifting line and 2D CFD results combined to get the 3D layout Feb. 4th18EWEA 2013 Vienna

19 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Performance evaluation using 3D CFD: Surface streamlines Feb. 4th19EWEA 2013 Vienna

20 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Performance evaluation using 3D CFD Vorticity magnitude without and with slats Feb. 4th20EWEA 2013 Vienna r/R=0.15 r/R=0.25 Without slats With slats

21 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Performance evaluation using 3D CFD  Local thrust coefficient C t Feb. 4th21EWEA 2013 Vienna ?? C T /C T,ref =2%

22 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Performance evaluation using 3D CFD Local power coefficient C p Feb. 4th22EWEA 2013 Vienna C P /C P,ref =1.1% !!

23 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Results & Discussion  Performance evaluation using 3D CFD Cumulative thrust and power coefficients Feb. 4th23EWEA 2013 Vienna ”Interesting” result: Quite a large part of the power gained at the slatted radii (~1/3) is lost on the outer part of the blade! This behavior is not captured in BEM results

24 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Outline  Introduction & Motivation  Methods used in this work  Reference rotor  Results & Discussion  Conclusions & Outlook Feb. 4th24EWEA 2013 Vienna

25 DTU Wind Energy, Technical University of Denmark Add Presentation Title in Footer via ”Insert”; ”Header & Footer” Conclusions & Outlook  A one-point rotor/slat design method, based on lifting line free wake method in combination with 2D CFD optimization, was presented  A new optimization framework for slatted airfoils using 2D CFD has been demonstrated  A set of multi-element airfoils were designed for the DTU 10 MW reference rotor for 0.1<r/R<0.3  For the first time, a 3D design of a rotor with slats is evaluated using CFD  Due to a disagreement on the definition of profile coordinate systems, no definitive answer for the increase in C P or AEP by the use of slats.  However:  C P /C P,ref =1.1% for this non-optimal case.  Interesting 3D effects on the outer part of the blade resulting in a significant power loss On the to-do list:  Get agreement on all geometry definitions, and run the intended case  Evaluate increase in C P and AEP, and investigate C T “cost”  Evaluate how close LL/BEM computational tools get to the CFD result  Is a final tweaking using 3D CFD needed in the design loop?  3D corrections for the slatted sections... Feb. 4th25EWEA 2013 Vienna

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