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Four-Wheel Drive
How Four-Wheel Drive Works
BY KARIM NICE
There
are almost as many different types of four-wheel-drive systems as there are
four-wheel-drive vehicles.
It seems that every
manufacturer has several different schemes for providing power to all of the
wheels.
The language used by the
different carmakers can sometimes be a little confusing, so before we get
started explaining how they work, let's clear up some terminology:
·
Four-wheel drive -
Usually, when carmakers say that a car has four-wheel drive, they
are referring to a part-time system. For reasons we'll explore
later in this article, these systems are meant only for use in low-traction
conditions, such as off-road or on snow or ice.
·
All-wheel drive -
These systems are sometimes called full-time four-wheel drive.
All-wheel-drive systems are designed to function on all types of surfaces, both
on- and off-road, and most of them cannot be switched off.
Part-time and full-time
four-wheel-drive systems can be evaluated using the same criteria. The best
system will send exactly the right amount of torque to each wheel, which is the
maximum torque that won't cause that tire to slip.
In this article, we'll
explain the fundamentals of four-wheel drive, starting with some background on
traction, and look at the components that make up a four-wheel-drive system.
Then we'll take a look at a couple of different systems, including the one
found on the Hummer, manufactured for GM by AM General.
We need to know a little
about torque, traction and wheel slip before
we can understand the different four-wheel-drive systems found on cars.
Torque,
Traction and Wheel Slip
Torque is the twisting force
that the engine produces. The torque from the engine is what moves
your car.
The various gears in the transmission and differential multiply
the torque and split it up between the wheels.
More torque can be sent to
the wheels in first gear than in fifth gear because first gear has a larger
gear-ratio by which to multiply the torque.
The bar graph below indicates
the amount of torque that the engine is producing. The mark on the graph
indicates the amount of torque that will cause wheel slip. The car that makes a
good start never exceeds this torque, so the tires don't slip; the car that
makes a bad start exceeds this torque, so the tires slip. As soon as they start
to slip, the torque drops down to almost zero.
The interesting thing about
torque is that in low-traction situations, the maximum amount of torque that
can be created is determined by the amount of traction, not by the engine. Even
if you have a NASCAR engine in your car, if the tires won't stick to the
ground there is simply no way to harness that power.
For the sake of this article,
we'll define traction as the maximum amount of force the tire can
apply against the ground (or that the ground can apply against the tire --
they're the same thing). These are the factors that affect traction:
The weight on the tire --
The more weight on a tire, the more traction it has. Weight can shift as a car
drives. For instance, when a car makes a turn, weight shifts to the outside
wheels. When it accelerates, weight shifts to the rear wheels.
The coefficient of friction --
This factor relates the amount of friction force between two surfaces to the
force holding the two surfaces together. In our case, it relates the amount of
traction between the tires and the road to the weight resting on each tire. The
coefficient of friction is mostly a function of the kind of tires on the
vehicle and the type of surface the vehicle is driving on. For instance, a
NASCAR tire has a very high coefficient of friction when it is driving on
a dry, concrete track. That is one of the reasons why NASCAR race cars can
corner at such high speeds.
The coefficient of friction
for that same tire in mud would be almost zero. By contrast, huge, knobby,
off-road tires wouldn't have as high a coefficient of friction on a dry
track, but in the mud, their coefficient of friction is extremely high.
Wheel slip --
There are two kinds of contact that tires can make with the road: static and
dynamic.
·
static contact --
The tire and the road (or ground) are not slipping relative to each other. The
coefficient of friction for static contact is higher than for dynamic contact,
so static contact provides better traction.
·
dynamic contact --
The tire is slipping relative to the road. The coefficient of friction for
dynamic contact is lower, so you have less traction.
Quite simply, wheel slip
occurs when the force applied to a tire exceeds the traction available to that
tire. Force is applied to the tire in two ways:
·
Longitudinally --
Longitudinal force comes from the torque applied to the tire by the engine or
by the brakes. It tends to either accelerate or decelerate the car.
·
Laterally --
Lateral force is created when the car drives around a curve. It takes force to
make a car change direction -- ultimately, the tires and the ground provide
lateral force.
Let's say you have a fairly
powerful rear-wheel-drive car, and you are driving around a curve on a wet
road. Your tires have plenty of traction to apply the lateral force needed to
keep your car on the road as it goes around the curve. Let's say you floor the
gas pedal in the middle of the turn (don't do this!) -- your engine
sends a lot more torque to the wheels, producing a large amount of longitudinal
force. If you add the longitudinal force (produced by the engine) and the
lateral force created in the turn, and the sum exceeds the traction available,
you just created wheel slip.
Most people don't even come
close to exceeding the available traction on dry pavement, or even on flat, wet
pavement. Four-wheel and all-wheel-drive systems are most useful in
low-traction situations, such as in snow and on slippery hills.
The benefit of four-wheel
drive is easy to understand: If you are driving four wheels instead of two,
you've got the potential to double the amount of longitudinal force (the force
that makes you go) that the tires apply to the ground.
This can help in a variety of
situations. For instance:
·
In snow -- It takes a
lot of force to push a car through the snow. The amount of force available is
limited by the available traction. Most two-wheel-drive cars can't move if
there is more than a few inches of snow on the road, because in the snow, each
tire has only a small amount of traction. A four-wheel-drive car can utilize
the traction of all four tires.
·
Off road --
In off-road conditions, it is fairly common for at least one set of tires to be
in a low-traction situation, such as when crossing a stream or mud puddle. With
four-wheel drive, the other set of tires still has traction, so they can pull
you out.
·
Climbing slippery hills --
This task requires a lot of traction. A four-wheel-drive car can utilize the
traction of all four tires to pull the car up the hill.
There are also some
situations in which four-wheel drive provides no advantage over two-wheel
drive. Most notably, four-wheel-drive systems won't help you stop on slippery
surfaces. It's all up to the brakes and the anti-lock braking system (ABS).
Now let's take a look at the
parts that make up a four-wheel-drive system.
Components of a Four-wheel-drive System
The
main parts of any four-wheel-drive system are the two differentials (front and
rear) and the transfer case. In addition, part-time systems have locking hubs,
and both types of systems may have advanced electronics that help them make
even better use of the available traction.
Differentials A
car has two differentials, one located between the two front wheels and one
between the two rear wheels. They send the torque from the driveshaft or transmission
to the drive wheels. They also allow the left and right wheels to spin at
different speeds when you go around a turn.
When
you go around a turn, the inside wheels follow a different path than the
outside wheels, and the front wheels follow a different path than the rear
wheels, so each of the wheels is spinning at a different speed. The
differentials enable the speed difference between the inside and outside
wheels. (In all-wheel drive, the speed difference between the front and rear
wheels is handled by the transfer case -- we'll discuss this next.)
There
are several different kinds of differentials used in cars and trucks. The types
of differentials used can have a significant effect on how well the vehicle
utilizes available traction.
Transfer Case
This
is the device that splits the power between the front and rear axles on a
four-wheel-drive car.
Back
to our corner-turning example: While the differentials handle the speed
difference between the inside and outside wheels, the transfer case in an
all-wheel-drive system contains a device that allows for a speed difference
between the front and rear wheels. This could be a viscous coupling, center
differential or other type of gearset. These devices allow an all-wheel-drive
system to function properly on any surface.
The transfer case on a part-time
four-wheel-drive system locks the front-axle driveshaft to the rear-axle
driveshaft, so the wheels are forced to spin at the same speed. This requires
that the tires slip when the car goes around a turn. Part-time systems like
this should only be used in low -traction situations in which it is relatively
easy for the tires to slip. On dry concrete, it is not easy for the tires to
slip, so the four-wheel drive should be disengaged in order to avoid jerky
turns and extra wear on the tires and drive train.
Some
transfer cases, more commonly those in part-time systems, also contain an
additional set of gears that give the vehicle a low
range. This extra gear ratio gives the vehicle extra torque and a
super-slow output speed. In first gear in low range, the vehicle might have a
top speed of about 5 mph (8 kph), but incredible torque is produced at the
wheels. This allows drivers to slowly and smoothly creep up very steep hills.
Locking Hubs
Each
wheel in a car is bolted to a hub. Part-time four-wheel-drive trucks usually
have locking hubs on the front
wheels. When four-wheel drive is not engaged, the locking hubs are used to
disconnect the front wheels from the front differential, half-shafts (the
shafts that connect the differential to the hub) and driveshaft. This allows
the differential, half-shafts and driveshaft to stop spinning when the car is
in two-wheel drive, saving wear and tear on those parts and improving
fuel-economy.
Manual
locking hubs used to be quite common. To engage four-wheel drive, the driver
actually had to get out of the truck and turn a knob on the front wheels until
the hubs locked. Newer systems have automatic locking hubs that engage when the
driver switches into four-wheel drive. This type of system can usually be
engaged while the vehicle is moving.
Whether
manual or automatic, these systems generally use a sliding collar that locks
the front half-shafts to the hub.
Advanced Electronics
On
many modern four-wheel and all-wheel-drive vehicles, advanced electronics play
a key role. Some cars use the ABS system to selectively apply the brakes
to wheels that start to skid -- this is called brake-traction
control.
Others
have sophisticated, electronically-controlled clutches that can better control
the torque transfer between wheels. We'll take a look at one such advanced
system later in the article.
First,
let's see how the most basic part-time four-wheel-drive system works.
Four-wheel Drive Differential
The
type of part-time system typically found on four-wheel-drive pickups and older
SUVs works like this: The vehicle is usually rear-wheel drive. The transmission
hooks up directly to a transfer case. From there, one driveshaft turns the
front axle, and another turns the rear axle.
When
four-wheel drive is engaged, the transfer case locks the front driveshaft to
the rear driveshaft, so each axle receives half of the torque coming from the
engine. At the same time, the front hubs lock.
The
front and rear axles each have an open differential. Although this system
provides much better traction than a two-wheel-drive vehicle, it has two main
drawbacks. We've already discussed one of them: It cannot be used on-road
because of the locked transfer case.
The
second problem comes from the type of differentials used: An open differential
splits the torque evenly between each of the two wheels it is connected to). If
one of those two wheels comes off the ground, or is on a very slippery surface,
the torque applied to that wheel drops to zero. Because the torque is split
evenly, this means that the other wheel also receives zero torque. So even if
the other wheel has plenty of traction, no torque is transferred to it. The
animation below shows how a system like this reacts under various conditions.
Animation of a basic system encountering various
combinations of terrain. This vehicle gets stuck when two of its wheels are on
the ice.
Previously,
we said that the best four-wheel-drive system will send exactly the right
amount of torque to each wheel, the right amount being the maximum torque that
won't cause that tire to slip. This system rates fairly poorly by that
criterion. It sends to both wheels the amount of torque that won't cause the
tire with the least traction to
slip.
There
are some ways to make improvements to a system like this. Replacing the open
differential with a limited-slip rear differential is one of the most
common ones -- this makes sure that both rear wheels are able to apply some
torque no matter what. Another option is a locking differential, which locks
the rear wheels together to ensure that each one has access to all of the
torque coming into the axle, even if one wheel is off the ground -- this
improves performance in off-road conditions.
In
the next section, we'll take a look at what could be the ultimate
four-wheel-drive system: the one on the Hummer.
The Four-wheel Drive Hummer
The
AM General Hummer military vehicle combines some advanced mechanical technology
with sophisticated electronics to create what is arguably the best four-wheel-drive
system available.
The
Hummer has a full-time system with additional features that can be engaged for
enhanced off-road performance. In this system, just as in our basic system, the
transmission is hooked up to the transfer case. From the transfer case, one
driveshaft connects to the front axle and one to the rear axle. However, the
transfer case on the Hummer does not automatically lock the front and rear
axles together. Instead, it contains a set of open-differential gears that
can be locked by the driver. In open mode (not locked), the front and rear
axles can move at different speeds, so the vehicle can drive on dry roads with
no problem. When the differential is locked, the front and rear axles each have
access to the engine's torque. If the front wheels are in quicksand, the rear
wheels get all of the torque they can handle.
The
front and rear differentials are both Torsen®
differentials. These differentials have a unique gearset: As soon as it senses
a decrease in torque to one wheel (which occurs when a tire is about to slip),
the gearset transfers torque to the other wheel. Torsen differentials can
transfer from two to four times the torque from one wheel to the other. This is
a big improvement over open differentials. But if one wheel is off the ground,
the other wheel still gets no torque.
To
handle this problem, the Hummer is equipped with a brake
traction control system. When one tire starts to slip, the brake traction
control applies the brakes to that wheel. This accomplishes two things:
·
It
keeps that tire from slipping, allowing it to make maximum use of its available
traction.
·
It
allows the other wheel to apply more torque.
The Hummer system encountering various combinations of
terrain: For the Hummer to get stuck, all four wheels would have to lose
traction.
The
brake traction control system applies significant torque to the wheel that
wants to slip, allowing the Torsen differential to apply two to four times that
increased torque to the other wheel.
Let's
put the Hummer to the test.
The
system on the Hummer is capable of sending a large amount of torque to
whichever tires have traction, even if this means sending it all to a single
tire. This brings the Hummer pretty close to our definition of an ideal
four-wheel-drive system: one that supplies each tire with the maximum amount of
torque it can handle.
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