AIRFOILS AT LOW SPEEDS Airfoils at Low Speeds Copyright © 1989 by Selig, Donovan, and Fraser All rights reserved H. A. Stokely, publisher 1504 North Horseshoe Circle Virginia Beach, Virginia 23451 USA Airfoils at Low Speeds v FOREWORD AND ACKNOWLEDGEMENTS The history of this experimental program on low-speed airfoils is extensive. In August 1986, work toward testing model sailplane airfoils in a wind tunnel at Princeton University began on an ambitious scale. The initial plan was to test 30 airfoils: 15 existing airfoils and 15 new airfoils to be designed concurrently with the tests. As news of the project caught the attention of radio control (RC) model soaring enthusiasts, the project grew far beyond the original goals and expectations, thanks to their generosity. When the experimental apparatus was finally dismantled in January 1989, almost two and a half years later, over 60 models were tested and over 130 airfoil polars were generated. It is our hope that the results of this work will be valuable to modelers and researchers for many years to come. A word is in order to explain the role each of us played in this effort. The initial impetus for the project, its organization and day-to-day management, as well as the wind tunnel testing and data reduction were done by Selig and Donovan. They also designed all of the new airfoils except for the DF- series by Fraser. The custom measurement apparatus was built jointly by Selig and Donovan at Princet.on University and by Fraser at Fraser-Volpe Corporation. The digitizing of the models was done at Fraser-Volpe Corporation by Fraser, who also wrote the computer programs for reducing this part of the data. All three of us shared in the writing and editing of this book. We would also like to mention that everything from the data collection to the writing of this book was done by computer. There is not a single number anywhere in any part of the data thiJ.t was generated, computed, reduced, copied, averaged, printed, graphed, or manipulated by hand. Aside from the speed and convenience of this approach, the principal advantage is the complete elimination of several types of errors that may otherwise occur. 5i All of the airfoil polar data is available on 3~ or inch IBM compatible diskette from Fraser. Sincere thanks go to Prof. Smits of the Princeton University Gas Dynamics Laboratory for his enduring support while this extracurricular project began to grow and consume seemingly endless hours of time away from the first two au thors' regular thesis research. The gracious support of Prof. Lam and Prof. Cur tiss of Princeton University, and the helpful discussions of Prof. Maughmer of The Pennsylvania State University are appreciated. Thanks also go to Lou Piz zarello who provided us with an air conditioner and new air intake filters for the tunnel. We are indebted to Ray Olsen for his many contributions at times when we needed them most. vi Airfoils at Low Speeds For monetary contributions which made possible the purchase of important el ements essential to this work we thank Rolf Girsberger, H.A. Stokely, Jerry Jack son, Armin Saxer, Charles Griswald, C. Haverlan, H.J. Rogers, Preben Norholm, Brian Smith, Thomas Yamokoski, and Trey Wood. The expertise of many skilled model builders made the lengthy set-up stage all worthwhile. In this respect we very deeply appreciate the work of Bob Champine, Ron Wagner, Stan Watson, Mark Allen, Michael Bame, Tony Beck, Woody Blanchard, Charles Fox, Peter Illick, Harley Michaelis, Forrest Miller, Ted Off, Mike Reed, Tyson Sawyer, Chuck Anderson, Norman Anderson, Jerry Arana, Bruce Baker, Ken Bates, David Batey Jr., Rich Border, John Boren, Mike Chiddick, Doug Dorton, Roger Egginton, Dale Folkening, Harlan Halsey, John Hohensee, Dave Jones, Stan Koch, Terry Luckenbach, Carl Mohs, Lee Mur ray, Mark Nankivil, R.J. Ostrander, Jef Raskin, Les Rogers, Joe Ruminski, and Karl Widiner. Prof. Mark Drela of M.I.T. is gratefully acknowledged for making his ISES computer code available to aid in the analysis of the new airfoil designs. Finally, MKS Instruments, Inc. and Scientific Solutions, Inc. are acknowledged for their valuable contributions of instrumentation. Airfoils at Low Speeds vii TABLE OF CONTENTS Foreword and Acknowledgements . . v List of Polars and Lift Plots viii List of Symbols and Abbreviations xii 1 Introduction . . . . . . . . 1 2 Experimental Facility and Measurement Technique 5 2.1 Flow Quality . . . . 5 2.2 Wind Tunnel Models 6 2.2.1 Digitized Profiles 7 2.2.2 Digitizing Procedure 7 2.2.3 Digitizer Res1,1lts 9 2.3 Force Measurement Technique and Instrumentation 11 2.4 Comparison with Other Facilities 16 3 Low Reynolds Number Terminology 41 3.1 Laminar Separation Bubbles 41 3.2 Trips and Bubble Ramps . . . 42 3.3 Airfoil Hysteresis . . . . . . 42 4 Project Design Methods and Goals 45 5 Comments on Airfoils 51 5 .1 Airfoil Discussions 53 5.2 Stall Behavior 88 5.3 Trips and Surface Roughness 89 5.4 Trailing Edge Thickness 90 5.5 Surface Waviness and Contour Accuracy 90 6 References . . . . 101 7 Airfoil Coordinates 103 7.1 Nominal 103 7.2 Actual .... 129 8 Predicted Moment Data 147 9 Airfoil Thickness and Camber 149 10 Digitizer Plots . . . . . 153 11 Airfoil Comparison Plots 187 12 Airfoil Polars and Lift Plots 193 13 Tabulated Polar Data 359 14 Addresses . . . . . . . . 397 viii Airfoils at Low Speeds LIST OF POLARS AND LIFT PLOTS Figure 12.1 AQUILA-PT 193 12.2 AQUILA-PT lift data 194 12.3 CLARK-Y-PT ·. . . 195 12.4 CLARK-Y-PT lift data 196 12.5 DAE51-PT 197 12.6 DAE51-PT thickened trailing edge 198 12.7 DAE51-PT lift data 199 12.8 DF101-PT 200 12.9 DF102-PT 201 12.10 DF103-PT 202 12.11 E193-PT . 203 12.12 E193MOD-PT 204 12.13 E205A-PT . . 205 12.14 E205B-PT . . 206 12.15 E205B-PT lift data 207 12.16 E214A-PT . . . 208 12.17 E214B-PT . . . 209 12.18 E214C-PT 3° flap 210 12.19 E214C-PT 0° flap 211 12.20 E214C-PT -3° flap 212 12.21 E214C-PT -6° flap 213 12.22 E214C-PT u.s.t. xjc = 20%,hjc = .17%,w/c = 1.0% 214 12.23 E214C-PT lift data 215 12.24 E374A-PT . . . . . . . . . . . . . . 216 12.25 E374B-PT . . . . . . . . . . . . . . 217 12.26 E374B-PT u.s. bumps xjc =50%, type A 218 12.27 E374B-PT u.s.t. xjc = 20%,hjc = .17%,w/c = 1.0% 219 12.28 E374B-PT u.s. wavy clay, xjc = O% to 15%,h/c = .20% 220 12.29 E374B-PT thickened trailing edge 221 12.30 E374B-PT lift data 222 12.31 E387 A-PT . . . . . . . . . . 223 12.32 E387 A-PT repeated . . . . . . 224 12.33 E387 A-PT u.s.t. xjc = 20%, hjc = 0.17%, wjc = 1.0% 225 12.34 E387 A-PT high turbulence 226 12.35 E387 A-PT lift data 227 12.36 E387B-PT . . . . . 228 12.37 Flat Plate-PT 229 12.38 Flat Plate-PT lift data 230 12.39 FX60-l00-PT . . . . 231 Airfoils at Low Speeds ix 12.40 FX63-137 A-PT 232 12.41 FX63-137B-PT 233 12.42 HQ2/9A-PT 234 12.43 HQ2/9A-PT u.s.t. xjc = 20%,hjc = .17%,wjc = 1.0% 235 12.44 HQ2/9A-PT u.s.t. xjc = 40%, h/c = .17%,wjc = 1.0% 236 12.45 HQ2/9A-PT l.s.t. xjc = 50%,h/c = .17%,wjc = 1.0% 237 12.46 HQ2/9A-PT lift data . . . . . . . . . . . . . . 238 12.47 HQ2/9B-PT . . . . . . . . . . . . . . . . .. 239 12.48 HQ2/9B-PT u.s.t. xjc = 50%,hjc = .17%,wjc = 1.0% 240 12.49 HQ2/9B-PT u.s. blowing xjc =50%, type B 241 12.50 HQ2/9B-PT trips, Rn = 200,000 242 12.51 HQ2/9B-PT lift data 243 12.52 J5012-PT . . . . . . . . . . 244 12.53 MB253515-PT . . . . . . . . 245 12.54 MB253515-PT u.s.t. xjc = 20%,hjc = .17%,w/c = 1.0% 246 12.55 MB253515-PT lift data . . . . . . . . . . 247-249 12.56 M0&-13-128-PT . . . . . . . . . . . . . . . . . . 250 12.57 M0&-13-128-PT u.s. bumps xjc = 31%, type A .... 251 12.58 M0&-13-128-PT misc. u.s. trips, xjc = 31%,Rn = 200,000 252 12.59 M0&-13-128-PT lift data 253 12.60 NACA 0009-PT .... 254 12.61 NACA 0009-PT lift data 255 12.62 NACA 2.5411-PT . . . 256 12.63 NACA 2.5411-PT lift data 257 12.64 NACA 64A010-PT 258 12.65 NACA 64A010-PT lift data 259 12.66 NACA 6409-PT . . . . 260 12.67 NACA 6409-PT lift data . 261 12.68 RG15-PT . . . . . . . 262 12.69 RG15-PT u.s.t. xjc = 20%,hjc = .17%,wjc = 1.0% 263 12.70 RG15-PT u.s.t. x/c = 40%,hjc = .17%,wjc = 1.0% 264 12.71 RG15-PT u.s.t. x/c = 60%,hjc = .17%,wjc = 1.0% 265 12.72 RG15-PT u.s.t. xjc = 70%,h/c = .17%,wjc = 1.0% 266 12.73 RG15-PT lift data 267 12.74 52048-PT . . . . . 268 12.75 52048-PT with trips . 269 12.76 52048-PT misc. trips 270 12.77 52048-PT lift data 271 12.78 52055-PT 272 12.79 52091A-PT ... 273 12.80 52091B-PT . . . 274 12.81 52091B-PT Gurney Flap type A 275 x Airfoils at Low Speeds 12.82 82091B-PT Gurney Flap type B 276 12.83 82091B-PT Gurney Flap type C 277 12.84 82091B-PT lift data 278 12.85 83010-PT 279 12.86 83010-PT lift data 280 12.87 83014-PT 281 12.88 83014-PT lift data 282 12.89 83016-PT 283 12.90 83021A-PT . . . 284 12.91 83021A-PT lift data 285 12.92 83021B-PT 286 12.93 84061A-PT . . . . 287 12.94 84061B-PT . . . . 288 12.95 84061B-PT u.s.t. xfc = 45%,hfc = .17%,w/c = 1.0% 289 12.96 84061B-PT u.s.t. xfc = 45%, Rn = 150,000 .... 290 12.97 84061B-PT u.s.t. xfc = 45%, Rn = 150,000 and 300,000 291 12.98 84061B-PT lift data 292 12.99 84062-PT 293 12.100 84180-PT . . . . 294 12.101 84233-PT . . . . 295 12.102 84233-PT u.s.t. xfc = 20%,hfc = .17%,wfc = 1.0% 296 12.103 84233-PT lift data . 297 12.104 8D2030-PT . . . . 298 12.105 8D2030-PT lift data 299 12.106 8D2083-PT . . . . 300 . 12.107 8D5060-PT 301 •' 12.108 8D5060-PT lift data 302 12.109 8D6060-PT . . . . 303 12.110 8D6060-PT u.s.t. xfc = 20%,h/c = .17%,w/c = 1.0% 304 12.111 SD6060-PT u.s.t. xjc = 40%,hjc = .17%,w/c = 1.0% 305 12.112 SD6060-PT lift data . . . . . . . . . . . . . . 306 12.113 8D6080-PT . . . . . . . . . . . . . . . . . . 307 12.114 8D6080-PT u.s.t. xfc = 10%,hjc = .17%,wjc = 1.0% 308 12.115 8D6080-PT u.s.t. xfc = 20%,hjc = .17%,wjc = 1.0% 309 12.116 8D6080-PT u.s.t. xfc = 30%,hjc = .17%,w/c = 1.0% 310 12.117 8D6080-PT thickened trailing edge 311 12.118 8D7003-PT . . . . . . . . . . . . . . . . . . 312 12.119 8D7003-PT repeated . . . . . . . . . . . . . . 313 12.120 8D7003-PT u.s.t. xfc = 60%,hfc = .17%,wfc = 1.0% 314 12.121 8D7003-PT u.s.t. xfc = 70%,hjc = .17%,wfc = 1.0% 315 12.122 8D7003-PT u.s. bumps xfc =50%, type A 316 12.123 SD7003-PT u.s. bumps xfc = 60%, type A .... 317 Airfoils at Low Speeds xi 12.124 SD7003-PT u.s. bumps xjc = 70%, type A 318 12.125 SD7003-PT lift data 319 12.126 SD7032A-PT 320 12.127 SD7032B-PT 321 12.128 SD7032C-PT 6° flap 322 12.129 SD7032C-PT 3° flap 323 12.130 SD7032C-PT 0° flap 324 12.131 SD7032CcPT -3° flap 325 12.132 SD7032C-PT -6° flap 326 12.133 SD7032C-PT lift data 327 12.134 SD7032D-PT . . . . 328 = = 12.135 SD7032D-PT u.s.t. xjc 45%,hjc .17%,wjc = 1.0% 329 12.136 SD7037-PT . . . . . . . . . . . . . . . . . . 330 12.137 SD7037-PT u.s.t. xjc = 30%,hjc = .17%,wjc = 1.0% 331 12.138 SD7043-PT . . . . . . . . . . . . . . . . . . 332 = = = 12.139 SD7043-PT u.s.t. xjc 20%,hjc .17%,w/c 1.0% 333 12.140 SD7043-PT lift data . . . . . . . . . . . . . . 334 12.141 SD7062-PT . . . . . . . . . . . . . . . . . . 335 12.142 SD7062-PT u.s.t. xjc = 15%,hjc = .17%,w/c = 1.0% 336 = = = 12.143 SD7062-PT u.s.t. xj c 15%, h/ c .08%, .17%, w / c 1.0% 337 12.144 SD7080-PT . . . . 338 12.145 SD7080-PT lift data 339 12.146 SD7084-PT . . . . 340 12.147 SD7084-PT lift data 341 12.148 SD7090-PT . . . . 342 12.149 SD7090-PT loose/tight covering, Rn = 300,000 343 12.150 SD7090-PT trips, Rn = 300,000 344 12.151 SD7090-PT lift data . . . . . . . . . . . . 345 12.152 SD8000-PT . . . . . . . . . . . . . . . . 346 12.153 SD8000-PT u.s.t. xjc = 20%,hjc = .17%,w/c = 1.0% 347 12.154 SD8000-PT u.s.t. xjc = 40%,hjc = .17%,w/c = 1.0% 348 12.155 SD8000-PT u.s.t. xjc = 70%,hjc = .17%,w/c = 1.0% 349 12.156 SD8000-PT lift data 350 12.157 SD8020-PT . . . . 351 12.158 SD8020-PT lift data 352 12.159 SD8040-PT 353 12.160 SPICA-PT 354 12.161 SPICA-PT lift data 355 12.162 WB135/35-PT . . 356 12.163 WB135/35-PT lift data 357 12.164 WB140/35/FB-PT . . 358