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Aerodynamics of Race Cars
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Abstract
Race car performance depends on elements such as the engine, tires, suspension,
road, aerodynamics, and of course the driver. In recent years, however, vehicle aerodynamics
gained increased attention, mainly due to the utilization of the negative
lift (downforce) principle, yielding several important performance improvements.
This review briefly explains the significance of the aerodynamic downforce and how
it improves race car performance. After this short introduction various methods to
generate downforce such as inverted wings, diffusers, and vortex generators are discussed.
Due to the complex geometry of these vehicles, the aerodynamic interaction
between the various body components is significant, resulting in vortex flows and
lifting surface shapes unlike traditional airplane wings. Typical design tools such as
wind tunnel testing, computational fluid dynamics, and track testing, and their relevance
to race car development, are discussed as well. In spite of the tremendous
progress of these design tools (due to better instrumentation, communication, and
computational power), the fluid dynamic phenomenon is still highly nonlinear, and
predicting the effect of a particular modification is not always trouble free. Several
examples covering a wide range of vehicle shapes (e.g., from stock cars to open-wheel
race cars) are presented to demonstrate this nonlinear nature of the flow field.
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INTRODUCTION
Automotive racing must have started at the turn of the twentieth century when the first
two automobiles pulled one beside the other. From that first moment on the sport
consistently grew, not always following the evolutionary trends of the automotive
industry. For example, contemporary race cars have components such as inverted
wings and protruding angular plates, which seem unpractical, and are hence unusable
by the automotive industry. Those involved with the sport insist that motor racing is
a “pure sport” with its own set of rules that need not benefit the general automotive
industry. Such opinions paved the way to numerous forms of racing. In some racing
categories the vehicles resemble production sedans, and in others they look more like
fighter airplanes, not to mention the various tracks that range from paved/unpaved to
straight, oval, or regular road courses. In all forms of racing, however, aerodynamics
eventually surfaced as a significant design parameter, and by the end of the first
100 years of automobiles, all race car designs have some level of aerodynamic element.
Although the foundations of aerodynamics were formulated over the past 200 years,
not all principles were immediately utilized for race car design. Naturally, the desire
for low drag was recognized first and Hucho (1998, p. 14–15) describes one of the
first streamlined race cars (the 1899 Camille Jenatzy) to break the 100 kilometer/hour
(km/h) “barrier.” This electric-powered racer had a long cigar shape in an effort to
reduce aerodynamic drag. The rapidly developing automotive industry followed and
one of the most significant designs of that era is the 1924 Tropfenwagen (“droplet
shape” in German) described by Hucho (1998, p. 18–19). This automobile’s shape was
dominated by the airfoil shape (particularly from the top view) and recent tests in the
Volkswagen wind tunnel showed a drag coefficient ofCD =0.28, which is outstanding
even by today’s standards. (Note that in automotive applications the vehicle’s frontal
area is used as a reference for the drag and lift coefficients.) Only four years later, in
1929, the Opel-designed rocket race car was the first to employ wings (see vehicle
description in Hucho 1998, p. 31–32). Those wings extended sideways, oriented at a
negative angle of attack to create downforce. This major innovation was completely
ignored and it took another 35 years to fully realize the significance of this principle.
Finally, the idea resurfaced in the form of the GMC-supported 1965 Chaparral 2C
(Falconer & Nye 1992), which used a variable pitch rear wing to create downforce,
changing the shape of race cars from that day on. To explain the significance of
aerodynamic downforce on race car performance, the tire characteristics must be
discussed briefly first.
The motion of air around a moving vehicle affects all of its components in one
form or another. Engine intake and cooling flow, internal ventilation, tire cooling, and
overall external flow all fall under the umbrella of vehicle aerodynamics. The present
discussion, however, focuses on the effects of external aerodynamics only, and additional
information on internal flows can be found in publications such as Hucho
(1998, ch. 11–12). As mentioned earlier, the discussion on race car aerodynamics
cannot be complete without briefly discussing tire characteristics. Although it is clear
that airplanes fly on wings (hence the significance of aerodynamics), the fact that race
cars “fly” on their tires is less obvious and requires additional clarification. In fact,
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Figure 1
Tire-generated side force versus slip angle, and the effect of normal force. Inset depicts
definition of side slip.
aerodynamic forces can be used to improve tire adhesion and, thus, improve vehicle
performance. For example, Figure 1 describes the forces acting on a side-slipping
tire on the road. The right-hand side schematics depict the three forces (e.g., FX FY
FZ) acting on the tire in a Cartesian coordinate system aligned with the vehicle, and
of course the three moments (MX MY MZ) must be included as well. In this case the
vehicle is heading into the -x direction, but due to a positive side force (could be inertia
due to cornering) it slides at an angle β, as shown in the figure. Somewhat similar to
the well-known dry friction model, a force is created by the tire, which is proportional
to the normal force and initially varies linearly with the slip angle β. So the first observation
here is that to generate side force (as in cornering) the tire must be subject to a
certain level of side slip. When this slip angle is too large [e.g., over 5 degrees (deg) in
this figure] the vehicle is sliding. Some commercial tires generate less side force under
such side-sliding conditions, but race car tire manufacturers desire to maintain most
of the side force under moderate sliding conditions. So beyond the linear slip range a
commercial tire may have a negative slope whereas the racing tire should maintain a
flat shape, as shown. In addition, the two curves in the left-hand side diagram depict
the effect of increasing the normal load, and, as mentioned, with higher normal force
larger lateral forces can be created (hence the analogy to dry friction). Of course a similar
diagram may be drawn for the tire longitudinal force (e.g., traction/acceleration
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or braking/deceleration) versus longitudinal slip. In this longitudinal case the slip is
the ratio between actual road and tire rotation speed. For more information on tires
and vehicle dynamics the reader is referred to Milliken & Milliken (1995). The immediate
conclusion is that if aerodynamics can be used to increase the normal force
acting on the tire, a similar improvement in traction can be expected.
In most forms of racing it is desirable to create the fastest vehicle in a particular
category. Traditionally, the effects of external aerodynamics are summarized in terms
of drag, lift, and stability. Usually the side force (due to aerodynamic side slip) was
not examined carefully because race cars go much faster than the prevailing winds,
and, instead of lift, the generation of efficient downforce became the main issue.
The three aerodynamic moments came to light when designers realized that vehicle
stability (and handling) can be improved by properly balancing the downforce (e.g.,
front/rear) on the tires. Such desirable aerodynamic downforce can be generated by
adding lifting surfaces onto, or by modifying, the vehicle’s body. When a vehicle
moves fast, lateral instability may become uncomfortable from the driver’s point
of view. This was observed early with speed record cars that used huge stabilizers
(similar to airplane vertical surfaces) in the back (with pure aerodynamic stabilization
in mind). An example of this school of thought can be found in vehicles such as the
1970 Blue Flame rocket-propelled car (that passed 1001.7 km/h) shown in Hucho
(1998, p. 366), or the 1966 Peugeot CD race car (Hucho 1998, p. 372) that used
two large vertical fins on its rear deck. The common design aspect of these two cars
is the effort to improve lateral stability by pure aerodynamic means (e.g., by using
large rear-mounted rudder-type surfaces). As noted earlier, only toward the end of
the 1960s did race car designers realize the huge advantage of using aerodynamics
to augment tire traction (and subsequently cornering and stability). To explain this
statement we must return to Figure 1. Let us assume for the sake of discussion that
the vertical load on a tire resulting from the vehicle weight is 200 kilograms (kg).
Based on this figure the maximum cornering force that can be created by this tire is
somewhat less than 200 kg. Of course, good racing tires can generate larger forces and
also the weight transfer (due to vehicle dynamics) is ignored here for simplicity. The
above condition can represent a vehicle in a steady cornering maneuver, and tire slip
is represented by point A in the figure (and tire full sliding is still a few degrees away).
However, with aerodynamic downforce the normal force on the tire can be increased,
whereas the vehicle weight is unchanged, resulting in improved performance (e.g.,
see point B or point C in the Figure 1). If the driver decides to turn at the same
speed (same side force) then the tire will require less slip (point B) and tire wear
and heating will be reduced. On the other hand, the driver can go much faster (e.g.,
point C) compared to the nonaero-assisted case shown by point A without risking
wheel-sliding condition (in Figure 1 point A and C have the same side-slip value).
This simple fact was not realized until the mid-1960s, and by properly utilizing
the aero-assisted tire performance, dramatic improvement can be obtained in cornering,
in accelerating out of corners, in braking (at high speed only), and in lateral
stability. The handling aspect was particularly important because by controlling the
downforce distribution between the front and rear wheels, the vehicle stability could
be altered (e.g., by relying on the tires’ increased performance rather than on aero
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Figure 2
Trends in maximum
cornering acceleration,
during the past 50 years.
effects of large stabilizing fins). Consequently, the improved cornering due to the
use of aerodynamic downforce (Metz 1985, and as explained earlier) led to the dramatic
increase in cornering speeds from the 1960s to the mid-1990s, as shown by
Figure 2. In those years, cornering acceleration grew from less than the gravitational
acceleration (g) to close to 4g due to the increased use of aerodynamic downforce.
Figure 2 presents the maximum cornering speeds of the more powerful race cars
of the era (e.g., open wheels or prototypes). The solid line shows the general trend
of improving maximum tire traction (similar to friction coefficient) over the years,
whereas the dashed line shows the dramatic increase that occured once the use of
aerodynamic downforce began. One interesting aspect of this phenomenon is that
tire traction (with fixed downforce–generating devices) varies with speed. This means
that a high-speed braking may start with a 4-g deceleration, but the driver should immediately
reduce the braking effort because tire adhesion will be reduced gradually,
as the vehicle slows down. Also, note that the generation of aerodynamic downforce
is accompanied by increased drag, but the ability to corner faster and control vehicle
stability clearly contributed to the increased speeds.
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Table 1 Typical total downforce and percent of front downforce (%F)
requirement for various race track conditions
Downforce (lb at 200 mph) %F
Road course 5000 45
Short oval 3500 35
Long oval 2500 35
Super speedway 1500 33
After this short introduction it becomes evident that the aerodynamic aspects of
race car design are not focused on vehicle drag reduction alone. In the case of highspeed
road courses, for example, the aerodynamic downforce can increase tire-to-road
adhesion without increasing vehicle mass. This improves both cornering and braking
and also allows the control of vehicle stability characteristics (handling). This means
that the aerodynamic center of pressure must be behind the vehicle center of gravity
and the distance or margin is referred to as balance, showing the ratio of downforce
between the front and rear tires. Page (2000), in his description of an open-wheel
Indy-type racing car, provides the following information (summarized in Table 1) on
the desirable downforce (at 200 mph) and on the percent of aerodynamic downforce
on the front axle (%F), for various race tracks.
Note that because of the highly competitive nature of the motor racing industry,
the results of advanced research (often highly sophisticated) are kept confidential and
not published in the open literature. Therefore, the ratio of published data to actual
research is much smaller than in other engineering disciplines (e.g., aerospace). Also,
the goal of such aerodynamic research, in general, is to develop efficient downforce
with minimum drag penalty. The principles of drag reduction and vehicle streamlining,
focusing on longer laminar boundary layers and less flow separations, are
well documented for airplane-type configurations (e.g., see the approach used for
airfoils in Liebeck 1973). Therefore, the following discussion focuses mainly on the
aerodynamic downforce aspects of race cars.
HOW DOWNFORCE IS CREATED
Race car design was historically always influenced by streamlining the vehicle body,
particularly when the focus was on reducing high-speed air resistance. This trend
continued well into the middle of the 1960s, implying that aerodynamic vehicles are
also aesthetically attractive, an image that was somewhat altered by the discovery of
aerodynamic downforce and its effect on race car performance. The foremost and
simplest approach to generate downforce was to add inverted wings to the existing
race cars. However, this newly discovered advantage was not free of complications.
For example, the aerodynamic downforce increases with the square of the vehicle’s
speed whereas tires depend far less on speed. Consequently, if the inverted wings are
attached to the vehicle then the suspension spring rate must be stiffened to allow
for the additional high-speed loads. Variable downforce-generating devices followed,
mostly based on reducing wing or flap angle of attack at higher speeds. Another
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approach was to attach the wings to the unsprung suspension to avoid the stiffening
of the suspension springs. These rapid developments within a short period (of less than
a year) resulted in several catastrophic failures, followed by regulations completely
outlawing movable aerodynamic devices. Some racing organizations ruled out even
rotating cooling fans to eliminate any doubt about interpreting the meaning of “no
movable aerodynamic device.” But the addition of inverted wings was not the only
method to generate downforce. Almost immediately it was realized that the vehicle
body may be used to generate downforce as well. The main advantage is the large
planview area of the vehicle, and therefore even small values of negative pressure under
the vehicle can result in sizeable aerodynamic downforce. The answer to the heading
of this section is that aerodynamic downforce can be generated by adding wings
or by using the vehicle’s body. Therefore, in the following paragraphs I discuss the
principles of using attached wings and the various options for generating downforce
with the vehicle body.
Race Car Wings
Airplane wing design matured by the middle of the twentieth century and it was only
natural that race car designers borrowed successful airplane wing profiles to use on
their vehicles. However, this approach was not entirely successful due to the inherent
differences between these two applications. The difficulties in this technology transfer
were highlighted by Katz (1994) and his findings can be summarized as follows:
A race car lifting surface design is different from a typical airplane wing design
because (a) a race car’s front wings operate within strong ground effect, (b) open-wheel
race car rear wings have very small aspect ratio, and © there are strong interactions
between the wings and other vehicle components (e.g., body, wheels, or other wings).
These arguments are discussed in more detail in the following paragraphs.
Ground effect. The increase in the lift of an airplane’s wing when approaching the
ground was explained in the early stages of aerodynamic theory (e.g., Pistolesi 1935).
The effect is favorable for both lifting and for inverted airfoils creating downforce.
Typical results for an inverted airfoil are presented in Figure 3 (from Zerihan&Zhang
2000). The data clearly show the trend and the significant magnitude of the effect,
particularly when the ground clearance is smaller than the airfoil quarter chord. The
effect does not come freely and a similar increase in drag was measured by Zerihan
& Zhang (2000). Because many race cars use front wings, typically mounted as close
as h/c of 0.1–0.3, this principle is clearly utilized in race car design (in Figure 3, h =
ground clearance and c = airfoil chord). In a later work, Zhang & Zerihan (2003)
demonstrate the same obvious behavior for a wing with a two-element airfoil.
Because of the large magnitude of this effect, numerous studies focused on this
subject and Coulliette & Plotkin (1996) recently summarized the two-dimensional
effects. In their work they separated the contributions of parameters such as thickness,
camber, and angle of attack to the airfoil’s lift. From the race car point of view the
interesting observation is that for an inverted airfoil (e.g., creating downforce) all
of the above effects will increase the downforce near the ground. This includes the
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Figure 3
Downforce and drag coefficient versus ground clearance for an inverted LS(1)-0413 airfoil.
[From Zerihan & Zhang (2000), α = −1 deg, Re = 2×106, moving ground plane.]
positive effect of angle of attack and camber, which in the case of an airplane wing
(lifting) near the ground are negative.
Three-dimensional ground effect calculations for finite-span rectangular wings
were reported by Katz 1985b, who showed that the effect remains large even in the
case of an AR = 2 rectangular wing (which is less than most race car front wings).
The focus of this study was on estimating the unsteady loads on such wings due
to oscillatory heaving motions (due to suspension travel); this information was vital
in those early days of using lifting surfaces on race cars. Because of the very close
proximity to the ground, the type of boundary condition on the ground strongly
affects both numerical and experimental results. Wiedemann (1989) discusses some
of these effects and concludes that moving ground simulation is essential for such
cases. He shows several types of boundary layers on the ground and Berndtsson et al.
(1988) provide information on the floor boundary-layer flow, with or without rolling
ground simulation.