|
|
|
 |
|
Handling 102
Cornering Speed
1) Tire's Grip
Most obviously, the selection of tires is
decisive to cornering grip. Car engineers have nothing to do with
the friction of the tires, which is determined by the compound and
texture. However, they can choose the most suitable tires for
their cars.
In the past decade, increasing tire's
diameter and width is a common trend shared by all car makers. Do
you still remember the Lamborghini Countach employed 15-inch tires
? Today's most exotic Ferrari, Porsche and Viper have 18 to
19-inch rubbers! Larger diameter accompany with larger width
increase the contact patch area (that is, the area of the tire
contacts with the ground), thus result in more grip. However, this
also result in poorer wet road grip because the pressure acting
upon the contact patch (that is, the car's weight divided by
contact patch area) is reduced thus the tire becomes easier to
"float" on the water. Therefore the texture also need to
be improved for better water clearance.
Low profile tires are also fashionable in
these days. Since the thickness becomes thinner, it is more
resistant to side wall deflection under substantial cornering
force. However, this is not much related to grip.
It must be mentioned that wide tires are not
always good. Especially are front tires, the wider they are, the
more resistance generates when they are steered. This create a
heavy and insensitive steering feel, also more tire roar and wear.
If you want to modify your car by using wider tires, always
consider the drawback first. In my opinion, most well-sorted
production sports cars have already equipped with the most
suitable tires.
2. Suspension Design
To maximize cornering grip, the suspension must
keep the tires perpendicular to ground under all conditions such
as bump and body roll so that the contact patch area remains
maximum.
Generally speaking, double wishbones
suspension does the best job to keep the tire perpendicular to
ground. The below figure shows how the conventional double
wishbones suspension deals with bump and body roll. You can see
there's no camber change at all under bump.
But the scene changes very much under body roll - camber changes
for the same degree as the body roll. Track width also increases.
Camber change reduces the contact patch area thus grip, and also
introduces non-neutral steering (we'll discuss this later). Track
width variation forces the tires to slip thus also reduce grip.
Therefore engineers invented unequal length
double wishbones. As shown in the below figure, the variation in
camber and track width are largely reduced under body roll,
although there is a small trade-off in wheel control under bump.
Unequal length non-parallel double wishbones (below) is even more
impressive, whose camber angle at the heavy-loaded outside wheel
is nearly unchanged, although it is less good under bump.
3. Weight Transfer due to lateral force
When a car is cornering at
speed, the car's weight transfers from the inside wheel to the
outside wheel. The rate of change is proportional to the height of
center of gravity (CG), the lateral acceleration ( in g ) and
inversely proportional to the track width. As this :
Weight
transfer = ( Lateral acceleration x Weight x
Height of CG ) / Track width
.
For example, a Factory Five Roadster is cornering at 0.85 g. Assuming its track width is 1600
mm, height of CG is 500 mm and it weighs 1250 kg, then we can
calculate the weight transfer is 332 kg. Assuming the car has a
perfect 50 / 50 weight distribution between front and rear, then
we can see each inside wheel takes 146.5 kg while the outside
478.5 kg. What a big difference! Therefore you can see the
outside wheel has far more influence to handling than the inside
wheel. This explain why we prefer unequal length non-parallel
double wishbones, because it has the least camber change on the
outside wheel.
If the car corners at
extremely high g-force, our calculation may find the weight
transfer approaching half the weight of the whole car, this means
the outside wheels take all the load while the inside wheels are
virtually unloaded! Then the car is going to roll over! Don't
worry, this is almost impossible in reality, as it requires
impractically high lateral acceleration. In our FFR Roadster example,
that equals to 1.6 g. Before that, the tires would have already
run out of its traction limit and slide.
However, if the car is
the elk-freightening Mercedes A-class or a high center of gravity
SUV, with their
exaggerate high center of gravity versus narrow track width, roll
over might occurs even at a leisure cornering speed.
*
*
*
We've discussed the
properties of weight transfer, but how does it relate to grip ?
Look at the following
graph. It illustrates the Grip - Load characteristic of a typical tire.
As you can see, as the load
increases on the tire, the grip generated by the tire increases,
but at a declining rate. This says, when weight transfer to the
outside wheel, the grip on the outside wheel is increased, but not
increase as much as the grip loss on the inside wheel.
Therefore the total grip
decreases as weight transfer occurs. The more weight transfer, the
less the total grip becomes.
Now can have some
conclusions : to maximize the cornering grip, we must minimize the
weight transfer. We can achieve this by lowering the CG, by
reducing the weight of the car or by enlarging the track width.
The first could be implemented by placing the heavy engine and
transmission as low as possible, by using a wide V-angle or even
boxer engine, and by lowering the seats. The second can be
implemented by using lightweight materials and better chassis
structure, and reducing the size of the car, but this seems to
conflict with the third method. Therefore I don't recommend to
increase the track width to as wide as Lamborghini Diablo. It
won't help making the car nimble too. Another advantage of weight
reduction is obvious: quicker to accelerate and to stop.
These are no secret. Any
one interested in motor racing already knows them.
Weight versus Downforce
But then you may ask a
question: reduce the car's weight also reduce the grip generated
by the tires, so what's the advantage ?
Firstly, because the car
is lighter, centrifugal force acted on it is smaller. In theory
the reduced grip could exactly withstand the reduced centrifugal
force. Secondly, we could use aerodynamic downforce to increase
the grip without increasing the centrifugal force. As a result,
the car can corner faster.
4. Weight Transfer due to body roll
Body roll also introduces
weight transfer thus reduction of total grip. Let's see the
following drawing :
The lateral displacement
of center of gravity (CG) is d. If we again use the Factory Five
Roadster
example (track width 1600 mm, height of CG 500 mm, weight 1250
kg), if it rolls 10 degrees when cornering, d will be 500 x sin10°
= 86.8 mm. Then the load of the outside wheels can be calculated
as: ( 1250 x ( 800 + 86.8 ) ) / 1600 = 693 kg while the inside
wheels take 557 kg. So there is 68 kg weight transfer. Although it
is not a great amount compare with the weight transfer due to
lateral acceleration, its influence should not be ignored because
camber change exists in this case.
We want to keep the body
roll to an adequate level. We can use stiffer spring and anti-roll
bar to reduce roll in the price of ride comfort. We can move the
roll center, which is determined by the suspension geometry, as
close to the CG as possible so that the roll moment is largely
reduced, but this has a very bad drawback - a large jerking force
will be generated and jerk up the body thus raise the CG.
Alternatively, we could leave the body roll alone and try to lower
the CG, so the weight transfer is also reduced.
After all, I don't
recommend to eliminate body roll, since it is an important signal
to tell us how well the car enters a corner and how close it
approaches its limit. Body roll is a kind of feedback.
5. Four-Wheel Drive
Finally, 4WD can maximize
the total grip of the car, both in straight line and cornering.
The former case is easier to understand: compare with RWD and FWD
cars, 4-wheel drive cars distributed less tractive force to each
of its driving wheels, so it is less likely that the tractive
force exceed the frictional force generated between tires and
ground. In other words, the driving wheels are less likely to
slide. However, since we are talking about handling, straight line
grip is not our interest.
For cornering grip,
whose direction is perpendicular to the wheel's tractive force,
the above mentioned theory is completely useless. The actual
theory is quite complicated, it requires the concept of Slip
Angle, which will be introduced in later sections. We will
continue this discussion later.
Steering
Surprisingly, steering
mechanism is not in our scope. In fact, most good cars today use
rack-and-pinion steerings whose designs are more or less the same.
What makes one car's steering superior to another is the weight
distribution, drivetrain system and suspension geometry etc.
Steering Response
I always said mid-engined
cars are superior in handling. Some ignorant auto journalists
interpret as "because the heavy engine is placed in the
middle of the car, it is easier to achieve 50 / 50 weight
distribution between front and rear. In other words, the car is
more balanced."
Wrong ! Most mid-engined
sports cars have about 60% weight bias towards the rear, thanks to
the engine, gearbox and differential are all located at the rear
half of the car. In contrast, a Factory Five Roadster has the
engine in front and the transmission mid mounted (right behind the
motor), so it could
actually achieve the perfect 50 / 50. Other good front-engined
cars such as BMW 3-series and Honda S2000 also achieve 50 / 50,
thanks to the lay-back engines.
The reason I prefer
mid-engined cars is, instead of better balance, mid-engined cars
have superior steering response. This is because they have lower
polar moment of inertia. Considering the two system shown in
below.
Both of them have equal
front to rear weight distribution. The one having the mass
concentrating near the CG (in other words, lower polar moment of
inertia) is easier to rotate about the CG. This could be easily
verified by our experience. Applying the same steering force, the
mid-engined car steers more quickly. The same for countering a
steering action. This means it is responsive to steer and correct.
There is another
advantage: since less effort is required to steer the car, we can
reduce or even discard power steering, which always filter the
feedback from the road thus downgrade the steering feel.
Dynamic Balance
Another reason I prefer mid-engined car is actually the slightly rear-biased weight
distribution. In acceleration, we need more weight on the rear
wheels to generate more traction for better launch. Obviously, FR
cars are inferior in this respect. (FF cars, however, might be
even better, but we shall see FF’s disadvantages later)
If acceleration is not
much related to handling, braking must be very decisive. When
braking into a corner, weight transfers from the rear to the
front, hence actually creating unbalance to a car which achieves
50 / 50 in static condition. In contrast, a 40 / 60 mid-engined
car may achieve a real dynamic balance under braking.
>>>
Continued here...
Go back to the FFR FAQ
|
|
|
|
|
