Graduate Final Project
CAD/CAM THEORY AND APPLICATIONS
(Design of a Multi-Element Wing)
- Rishabh Verma
PURDUE SCHOOL OF ENGINEERING AND TECHNOLOGY
INDIANA UNIVERSITY PURDUE UNIVERSITY INDIANAPOLIS
Objective-
To model a rear wing for a race car, with modification to a Multi-Element wing profile with
and without a Gurney flap; on a CAD modelling software. Specific analysis on the
downforce, angle of attack and drag force created by the various airfoil configurations.
Theory of Airfoils -
A fixed-wing aircraft's wings, horizontal, and vertical stabilizers are built with airfoil-shaped
cross sections, as are helicopter rotor blades. Airfoils are also found in propellers, fans,
compressors and turbines. Sails are also airfoils, and the underwater surfaces of sailboats,
such as the centerboard and keel, are similar in cross-section and operate on the same
principles as airfoils. Swimming and flying creatures and even many plants and sessile
organisms employ airfoils/hydrofoils: common examples being bird wings, the bodies of
fish, and the shape of sand dollars. An airfoil-shaped wing can create downforce on an
automobile or other motor vehicle, improving traction.
Any object with an angle of attack in a moving fluid, such as a flat plate, a building, or the
deck of a bridge, will generate an aerodynamic force (called lift) perpendicular to the flow.
Airfoils are more efficient lifting shapes, able to generate more lift (up to a point), and to
generate lift with less drag.
A lift and drag curve obtained in wind tunnel testing is shown on the right. The curve
represents an airfoil with a positive camber so some lift is produced at zero angle of attack.
With increased angle of attack, lift increases in a roughly linear relation, called the slope of
the lift curve. At about 18 degrees this airfoil stalls, and lift falls off quickly beyond that. The
drop in lift can be explained by the action of the upper-surface boundary layer, which
separates and greatly thickens over the upper surface at and past the stall angle. The
thickened boundary layer's displacement thickness changes the airfoil's effective shape, in
particular it reduces its effective camber, which modifies the overall flow field so as to
reduce the circulation and the lift. The thicker boundary layer also causes a large increase in
pressure drag, so that the overall drag increases sharply near and past the stall point.
Airfoil design is a major facet of aerodynamics. Various airfoils serve different flight
regimes. Asymmetric airfoils can generate lift at zero angle of attack, while a symmetric
airfoil may better suit frequent inverted flight as in an aerobatic airplane. In the region of
the ailerons and near a wingtip a symmetric airfoil can be used to increase the range of
angles of attack to avoid spin–stall. Thus a large range of angles can be used without
boundary layer separation. Subsonic airfoils have a round leading edge, which is naturally
insensitive to the angle of attack. The cross section is not strictly circular, however: the
radius of curvature is increased before the wing achieves maximum thickness to minimize
the chance of boundary layer separation. This elongates the wing and moves the point of
maximum thickness back from the leading edge.
Supersonic airfoils are much more angular in shape and can have a very sharp leading edge,
which is very sensitive to angle of attack. A supercritical airfoil has its maximum thickness
close to the leading edge to have a lot of length to slowly shock the supersonic flow back to
subsonic speeds. Generally such transonic airfoils and also the supersonic airfoils have a
low camber to reduce drag divergence. Modern aircraft wings may have different airfoil
sections along the wing span, each one optimized for the conditions in each section of the
wing.
Movable high-lift devices, flaps and sometimes slats, are fitted to airfoils on almost every
aircraft. A trailing edge flap acts similarly to an aileron; however, it, as opposed to an
aileron, can be retracted partially into the wing if not used.
A laminar flow wing has a maximum thickness in the middle camber line. Analyzing the
Navier–Stokes equations in the linear regime shows that a negative pressure gradient along
the flow has the same effect as reducing the speed. So with the maximum camber in the
middle, maintaining a laminar flow over a larger percentage of the wing at a higher cruising
speed is possible. However, some surface contamination will disrupt the laminar flow,
making it turbulent. For example, with rain on the wing, the flow will be turbulent. Under
certain conditions, insect debris on the wing will cause the loss of small regions of laminar
flow as well. Before NASA's research in the 1970s and 1980s the aircraft design community
understood from application attempts in the WW II era that laminar flow wing designs were
not practical using common manufacturing tolerances and surface imperfections. That
belief changed after new manufacturing methods were developed with composite
materials (e.g., graphite fiber) and machined metal methods were introduced. NASA's
research in the 1980s revealed the practicality and usefulness of laminar flow wing designs
and opened the way for laminar flow applications on modern practical aircraft surfaces,
from subsonic general aviation aircraft to transonic large transport aircraft, to supersonic
designs.
Gurney Flaps - The Gurney Flap is a small tab projecting from the trailing edge of a wing.
Typically it is set at a right angle to the pressure side surface of the airfoil, and projects 1%
to 2% of the wing chord. This trailing edge device can improve the performance of a simple
airfoil to nearly the same level as a complex high-performance design.
The device operates by increasing pressure on the pressure side, decreasing pressure on
the suction side, and helping the boundary layer flow stay attached all the way to the
trailing edge on the suction side of the airfoil. Common applications occur in auto racing,
helicopter horizontal stabilizers, and aircraft where high lift is essential, such as banner-
towing airplanes.
Modelling Software Used – SolidWorks –
SolidWorks is a solid modeler, and utilizes a parametric feature-based approach to create
models and assemblies. The software is written on Parasolid-kernel.
Parameters refer to constraints whose values determine the shape or geometry of the
model or assembly. Parameters can be either numeric parameters, such as line lengths or
circle diameters, or geometric parameters, such as tangent, parallel, concentric, horizontal
or vertical, etc. Numeric parameters can be associated with each other through the use of
relations, which allows them to capture design intent.
Design intent is how the creator of the part wants it to respond to changes and updates.
For example, you would want the hole at the top of a beverage can to stay at the top
surface, regardless of the height or size of the can. SolidWorks allows the user to specify
that the hole is a feature on the top surface, and will then honor their design intent no
matter what height they later assign to the can.
Features refer to the building blocks of the part. They are the shapes and operations that
construct the part. Shape-based features typically begin with a 2D or 3D sketch of shapes
such as bosses, holes, slots, etc. This shape is then extruded or cut to add or remove
material from the part. Operation-based features are not sketch-based, and include
features such as fillets, chamfers, shells, applying draft to the faces of a part, etc.
Building a model in SolidWorks usually starts with a 2D sketch (although 3D sketches are
available for power users). The sketch consists of geometry such as points, lines, arcs,
conics (except the hyperbola), and splines. Dimensions are added to the sketch to define
the size and location of the geometry. Relations are used to define attributes such as
tangency, parallelism, perpendicularity, and concentricity. The parametric nature of
SolidWorks means that the dimensions and relations drive the geometry, not the other way
around. The dimensions in the sketch can be controlled independently, or by relationships
to other parameters inside or outside of the sketch.
In an assembly, the analog to sketch relations are mates. Just as sketch relations define
conditions such as tangency, parallelism, and concentricity with respect to sketch
geometry, assembly mates define equivalent relations with respect to the individual parts
or components, allowing the easy construction of assemblies. SolidWorks also includes
additional advanced mating features such as gear and cam follower mates, which allow
modeled gear assemblies to accurately reproduce the rotational movement of an actual
gear train.
Analysis Software – OpenFOAM-
OpenFOAM (for "Open source Field Operation and Manipulation") is a C++ toolbox for the
development of customized numerical solvers, and pre-/post-processing utilities for the
solution of continuum mechanics problems, including computational fluid dynamics (CFD).
OpenFOAM solvers include:
Simulation of burning Methane.
Basic CFD solvers
Incompressible flow with RANS and LES capabilities
Compressible flow solvers with RANS and LES capabilities
Buoyancy-driven flow solvers
DNS and LES
Multiphase flow solvers
Particle-tracking solvers
Solvers for combustion problems
Solvers for conjugate heat transfer
Molecular dynamics solvers
Direct Simulation Monte Carlo solvers
Electromagnetics solvers
Solid dynamics solvers
In addition to the standard solvers, OpenFOAM's syntax lends itself to the easy
creation of custom solvers.
OpenFOAM utilities are subdivided into:
Mesh utilities
Mesh generation: they generate computational grids starting either
from an input file (blockMesh), or from a generic geometry specified as
STL file, which is meshed automatically with hex-dominant grids
(snappyHexMesh)
Mesh conversion: they convert grids generated using other tools to the
OpenFOAM format
Mesh manipulation: they perform specific operations on the mesh such
as localized refinement, definition of regions, and others
Parallel processing utilities: they provide tools to decompose,
reconstruct and re-distribute the computational case to perform
parallel calculations
Pre-processing utilities: tools to prepare the simulation cases
Post-processing utilities: tools to process the results of simulation
cases, including a plugin to interface OpenFOAM and ParaView.
Surface utilities
Thermophysical utilities
Advantages-
Friendly syntax for partial differential equations.
Fully documented source code.
Unstructured polyhedral grid capabilities.
Automatic parallelization of applications written using OpenFOAM high-level syntax.
Wide range of applications and models ready to use.
Commercial support and training provided by the developers.
No license costs.
Modelling – (SolidWorks Coordinates for Basic Airfoil modelling)
-Attached STL Files
Coordinates for Airfoil
No. X - Y- Z-
1 203.2736 0 -0.24526 2 202.9728 0 -0.3812
3 202.0718 0 -0.78638 4 200.5747 0 -1.45288
5 198.4882 0 -2.36789 6 195.8222 0 -3.51373
7 192.5891 0 -4.86847 8 188.8047 0 -6.40669 9 184.4877 0 -8.09935
10 179.6597 0 -9.91575 11 174.3456 0 -11.8226
12 168.5739 0 -13.7857 13 162.3755 0 -15.7704
14 155.7847 0 -17.7422 15 148.8389 0 -19.6669
16 141.5784 0 -21.5118 17 134.0458 0 -23.2453
18 126.2864 0 -24.8386 19 118.3484 0 -26.2648 20 110.2813 0 -27.5001
21 102.1373 0 -28.524 22 93.96943 0 -29.3201
23 85.8327 0 -29.8757 24 77.65796 0 -30.1634
25 69.4629 0 -30.0313 26 61.47308 0 -29.4624
27 53.75453 0 -28.4836 28 46.37085 0 -27.1307
29 39.38158 0 -25.449 30 32.84139 0 -23.4905 31 26.79924 0 -21.3124
32 21.29719 0 -18.9754 33 16.37142 0 -16.5417
34 12.05118 0 -14.0722 35 8.359648 0 -11.6261
36 5.313883 0 -9.25779 37 2.925064 0 -7.01609
38 1.199693 0 -4.94162 39 0.139395 0 -3.0673
40 -0.25847 0 -1.41569 41 0 0 0 42 0.884733 0 1.134466
43 2.362403 0 1.95011 44 4.414723 0 2.45872
45 7.020357 0 2.677566
No. X - Y- Z- 46 10.1539 0 2.628595
47 13.78773 0 2.338629 48 17.89217 0 1.838554
49 22.43633 0 1.16271 50 27.38831 0 0.347675
51 32.71683 0 -0.56693 52 38.39058 0 -1.54087
53 44.3803 0 -2.53289 54 50.65735 0 -3.50134
55 57.1945 0 -4.40578 56 63.96573 0 -5.20619
57 70.94484 0 -5.86557 58 78.10602 0 -6.34878 59 85.57971 0 -6.65216
60 93.2877 0 -6.88076 61 101.0627 0 -7.036
62 108.8616 0 -7.10651 63 116.6392 0 -7.08437
64 124.3497 0 -6.96529 65 131.9465 0 -6.74949
66 139.383 0 -6.44042 67 146.6118 0 -6.0454
68 153.5871 0 -5.575 69 160.2626 0 -5.04221 70 166.5939 0 -4.46268
71 172.5383 0 -3.85328 72 178.0548 0 -3.2319
73 183.1045 0 -2.6164 74 187.6517 0 -2.02489
75 191.6633 0 -1.47401 76 195.1102 0 -0.97942
77 197.9664 0 -0.55474 78 200.2109 0 -0.21194
79 201.8266 0 0.039624 80 202.8009 0 0.193446 81 203.1264 0 0.245262
Velocity Vs X-direction vector plots for Stall Angle, Basic Airfoil
Design: with & without Gurney Flap
(OpenFoam Result Images)
Results
Run no. Date File Name Airspeed Drag Force Lift Force A A AR Rho Alpha Cd CL L/D
f/s in sq sq ft lb-sec2 / ft 4deg
1 First Run 0 Degree 45 5.25 -197.76 454.15 3.153 5.91 2.38E-03 0.0 0.016 -0.604 37.669
2 AOA -3 degree 45 6.97 -293.23 454.15 3.153 5.91 2.38E-03 -3.0 0.021 -0.895 42.070
3 AOA -5 degree 45 7.72 -340.36 454.15 3.153 5.91 2.38E-03 -5.0 0.024 -1.039 44.088
4 AOA -6 degree 45 10.97 -339.88 454.15 3.153 5.91 2.38E-03 -6.0 0.033 -1.038 30.983
5 AOA -10 degree 45 18.31 -403.05 454.15 3.153 5.91 2.38E-03 -10.0 0.056 -1.230 22.013
6 AOA -11 degree 45 23.60 -370.72 454.15 3.153 5.91 2.38E-03 -11.0 0.072 -1.132 15.708
7 AOA -12 degree 45 23.05 -417.76 454.15 3.153 5.91 2.38E-03 -12.0 0.070 -1.275 18.124
8 AOA -14 degree 45 27.44 -451.47 454.15 3.153 5.91 2.38E-03 -14.0 0.084 -1.378 16.453
9 AOA -15 degree 45 31.56 -398.03 454.15 3.153 5.91 2.38E-03 -15.0 0.096 -1.215 12.612
10 AOA -16 degree 45 33.58 -435.41 454.15 3.153 5.91 2.38E-03 -16.0 0.103 -1.329 12.966
11 AOA -17 degree 45 41.64 -464.96 454.15 3.153 5.91 2.38E-03 -17.0 0.127 -1.419 11.166
12 AOA -17.10 45 38.8 -437.21 454.15 3.153 5.91 2.38E-03 -17.1 0.118 -1.335 11.268
13 AOA -17.25 45 48.51 -392.22 454.15 3.153 5.91 2.38E-03 -17.3 0.148 -1.197 8.085
14 AOA -18 degree 45 47.43 -389.01 454.15 3.153 5.91 2.38E-03 -18.0 0.145 -1.188 8.202
15 AOA -19 degree 45 44.85 -441.67 454.15 3.153 5.91 2.38E-03 -19.0 0.137 -1.348 9.848
16 AOA -21 degree 45 77.20 -336.04 454.15 3.153 5.91 2.38E-03 -21.0 0.236 -1.026 4.353
17 AOA with Gurney -0 45 11.47 -411.6 454.15 3.153 5.91 2.38E-03 0.0 0.035 -1.256 35.885
18 AOA with Gurney -5 45 21.78 -497.17 454.15 3.153 5.91 2.38E-03 -5.0 0.066 -1.518 22.827
19 AOA with Gurney-8 45 32.49 -519.27 454.15 3.153 5.91 2.38E-03 -8.0 0.099 -1.585 15.982
20 AOA with Gurney -10 45 35.02 -553.30 454.15 3.153 5.91 2.38E-03 -10.0 0.107 -1.689 15.800
21 AOA with Gurney -11 45 44.48 -470.28 454.15 3.153 5.91 2.38E-03 -11.0 0.136 -1.436 10.573
22 AOA with Gurney -12 45 44.30 -551.07 454.15 3.153 5.91 2.38E-03 -12.0 0.135 -1.682 12.440
23 AOA with Gurney -13 45 51.0 -571.7 454.15 3.153 5.91 2.38E-03 -13.0 0.156 -1.745 11.207
24 AOA with Gurney -14 45 52.5 -577.3 454.15 3.153 5.91 2.38E-03 -14.0 0.160 -1.762 10.998
25 AOA with Gurney -14.5 45 54.48 -538.57 454.15 3.153 5.91 2.38E-03 -14.5 0.166 -1.644 9.886
26 AOA with Gurney -15.1 45 59.2 -530.9 454.15 3.153 5.91 2.38E-03 -15.1 0.181 -1.621 8.969
27 AOA with Gurney -16 45 62.8 -534.0 454.15 3.153 5.91 2.38E-03 -16 0.192 -1.630 8.508
28 AOA with Gurney -17 45 62.9 -565.4 454.15 3.153 5.91 2.38E-03 -17 0.192 -1.726 8.991
29 AOA with Gurney -18 45 88.5 -450.1 454.15 3.153 5.91 2.38E-03 -18 0.270 -1.374 5.089
30 AOA with Gurney -19 45 82.8 -490.3 454.15 3.153 5.91 2.38E-03 -19 0.253 -1.497 5.924
31 AOA with Gurney -21 45 116.9 -379.6 454.15 3.153 5.91 2.38E-03 -21 0.357 -1.159 3.247
32 AOA with Gurney -23 45 138.0 -419.5 454.15 3.153 5.91 2.38E-03 -23 0.421 -1.281 3.040
Conclusions –
The original airfoil stalls at 17.25 degrees, and Airfoil with Gurney stalls at 14.5
degree. The cut plots of air velocity vs x- direction, shows the large wake of low
velocity air at the bottom surface of the wing. Also, Drag numbers suddenly increase,
whereas the lift numbers plummet for the specific attack angles.
Velocity Vs X-direction plots for the two wing setup shows the velocity of air around
the airfoil, depicted with different colors. As the wing reaches initial stall, there is a
small green patch at the front and the lower back surface of the airfoil, as the attack
angle increases and the wing reaches full stall, the green wake widens with blue
areas showing even lower velocities. The wing stalls with a wide blue-green wake,
with the wing suffering from induced drag.
As seen from the History Table, as the angle of attack reaches full stall for the wing,
the lift coefficient drops as a result of large adverse pressure gradient in the lower
back part, which in-turn creates a positive Cp at the top surface; the magnitude of lift
seen during stall, is mostly due to the front edge of the wing where the flow is still
attached. Whereas, the drag force on the airfoil suddenly increases during stall due
to the aberrant increase in the induced drag. Due to decrease in the wind velocity
and the sudden change in its direction, a region of suction is formed, which coupled
with friction drag results into a high drag coefficient.
Velocity Vs X-direction vector plots for Stall Angle, Multi-
Element Airfoil Design: with & without Gurney Flap
(OpenFoam Result Images)
Results-
Run no. File Name Airspeed Drag Force Drag Lift Force Lift A A AR Rho Alpha Cd CL L/D
f/s N Lbs N Lbs in sq sq ft lb-sec2 / ft 4 deg
1 AOA 2-Element 0 degree 146.65 9.38 2.10112 -503.08 -112.69 490.98 3.409 4.54 0.002377 0 0.024114 -1.29329 -53.6333
2 AOA 2-Element -5 degree 146.65 16.35 3.6624 -640.25 -143.416 490.98 3.409 4.54 0.002377 -5 0.042032 -1.64591 -39.159
3 AOA 2-Element -9 degree 146.65 39.86 8.92864 -677.62 -151.787 490.98 3.409 4.54 0.002377 -9 0.10247 -1.74198 -17
4 AOA 2-Element -10 degree 146.65 43.16 9.66784 -685.9 -153.642 490.98 3.409 4.54 0.002377 -10 0.110953 -1.76327 -15.892
5 AOA 2-Element -11 degree 146.65 50.29 11.26496 -693.19 -155.275 490.98 3.409 4.54 0.002377 -11 0.129282 -1.78201 -13.7839
6 AOA 2-Element -12 degree 146.65 56.4 12.6336 -698.83 -156.538 490.98 3.409 4.54 0.002377 -12 0.14499 -1.79651 -12.3906
7 AOA 2-Element -13 degree 146.65 62.53 14.00672 -691.51 -154.898 490.98 3.409 4.54 0.002377 -13 0.160748 -1.77769 -11.0589
8 AOA 2-Element -14 degree 146.65 67.23 15.05952 -658.48 -147.5 490.98 3.409 4.54 0.002377 -14 0.172831 -1.69278 -9.79444
9 AOA 2-Element -15 degree 146.65 76.49 17.13376 -648.33 -145.226 490.98 3.409 4.54 0.002377 -15 0.196636 -1.66669 -8.47601
10 AOA 2-Element -18 degree 146.65 98.96 22.16704 -562.37 -125.971 490.98 3.409 4.54 0.002377 -18 0.2544 -1.44571 -5.6828
11 AOA 2-Element -20 degree 146.65 127.25 28.504 -518.46 -116.135 490.98 3.409 4.54 0.002377 -20 0.327126 -1.33282 -4.07434
12 AOA 2-Element with Gurney 0Deg 146.65 16.23 3.63552 -683.01 -152.994 490.98 3.409 4.54 0.002377 0 0.041723 -1.75584 -42.0832
13 AOA 2-Element with Gurney -2 146.65 21.28 4.76672 -718.13 -160.861 490.98 3.409 4.54 0.002377 -2 0.054705 -1.84612 -33.7467
14 AOA 2-Element with Gurney -5 146.65 42.38 9.49312 -744.9 -166.858 490.98 3.409 4.54 0.002377 -5 0.108948 -1.91494 -17.5767
15 AOA 2-Element with Gurney -6 146.65 48.14 10.78336 -733.69 -164.347 490.98 3.409 4.54 0.002377 -6 0.123755 -1.88612 -15.2408
16 AOA 2-Element with Gurney -7 146.65 54.07 12.11168 -759.53 -170.135 490.98 3.409 4.54 0.002377 -7 0.139 -1.95255 -14.0472
17 AOA 2-Element with Gurney -8 146.65 54.54 12.21696 -780.69 -174.875 490.98 3.409 4.54 0.002377 -8 0.140208 -2.00695 -14.3141
18 AOA 2-Element with Gurney -9 146.65 67.89 15.20736 -789.68 -176.888 490.98 3.409 4.54 0.002377 -9 0.174527 -2.03006 -11.6318
19 AOA 2-Element with Gurney -9.8 146.65 70 15.68 -761.62 -170.603 490.98 3.409 4.54 0.002377 -9.8 0.179952 -1.95792 -10.8803
20 AOA 2-Element with Gurney -10 146.65 69.69 15.61056 -775.09 -173.62 490.98 3.409 4.54 0.002377 -10 0.179155 -1.99255 -11.122
21 AOA 2-Element with Gurney-10.5 146.65 77.74 17.41376 -742.12 -166.235 490.98 3.409 4.54 0.002377 -10.5 0.199849 -1.9078 -9.54618
22 AOA 2-Element with Gurney -12 146.65 89.19 19.97856 -683.6 -153.126 490.98 3.409 4.54 0.002377 -12 0.229284 -1.75736 -7.66454
23 AOA 2-Element with Gurney-15 146.65 124.09 27.79616 -574.79 -128.753 490.98 3.409 4.54 0.002377 -15 0.319003 -1.47763 -4.63204
24 AOA 2-Element with Gurney-20 146.65 219.54 49.17696 -548.22 -122.801 490.98 3.409 4.54 0.002377 -20 0.56438 -1.40933 -2.49713
Conclusion-
The Most Effective Angle of attack for the 2-element airfoil with
downforce of 156.538lbs is -12deg; and a gurney flap modification gives a
downforce of 176.88lbs at -9deg. All the airfoils have a Span of 1.2meters.
There is a significant increase in the downforce numbers from the basic
airfoil to a 2-element wing with a gurney flap.
The drag numbers doesn’t increase significantly, to diminish downforce
improvement. Hence, a two element wing with a gurney flap has been
designed.
Results could be extrapolated according to the specific Aspect Ratio.
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