1.
INTRODUCTION
Cars are immensely complicated machines, but when you
get down to it, they do an incredibly simple job. Most of the complex stuff in
a car is dedicated to turning wheels, which grip the road to pull the car body
and passengers along. The steering system tilts the wheels side to side to turn
the car, and brake and acceleration systems control the speed of the wheels.
Given that the overall function of a car is so basic (it just needs to
provide rotary motion to wheels), it seems a little strange that almost all
cars have the same collection of complex devices crammed under the hood and the
same general mass of mechanical and hydraulic linkages running throughout. Why
do cars necessarily need a steering column, brake and acceleration pedals, a
combustion engine, a catalytic converter and the rest of it?
According to many leading automotive engineers, they don't; and more to
the point, in the near future, they won't. Most likely, a lot of us will be
driving radically different cars within 20 years. And the difference won't just
be under the hood -- owning and driving cars will change significantly, too.
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GM's sedan model Hy-wire
2.
HY-WIRE BASICS
Two basic elements
largely dictate car design today: the internal combustion engine and mechanical
and hydraulic linkages. If you've ever looked under the hood of a car, you know
an internal combustion engine requires a lot of additional equipment to function
correctly. No matter what else they do with a car, designers always have to
make room for this equipment.
The same goes for
mechanical and hydraulic linkages. The basic idea of this system is that the
driver maneuvers the various actuators in the car (the wheels, brakes, etc.)
more or less directly, by manipulating driving controls connected to those
actuators by shafts, gears and hydraulics. In a rack-and-pinion steering
system, for example, turning the steering wheel rotates a shaft connected to a
pinion gear, which moves a rack gear connected to the car's front wheels. In
addition to restricting how the car is built, the linkage concept also dictates
how we drive: The steering wheel, pedal and gear-shift system were all designed
around the linkage idea.
The defining characteristic of the Hy-wire
(and its conceptual predecessor, the Autonomy) is that it doesn't have either
of these two things. Instead of an engine, it has a fuel cell stack, which
powers an electric motor connected to the wheels. Instead of mechanical and
hydraulic linkages, it has a drive by wire system -- a computer actually
operates the components that move the wheels, activate the brakes and so on,
and based on input from an electronic controller. This is the same control
system employed in modern fighter jets as well as many commercial planes.
The result of these two substitutions is a very different
type of car -- and a very different driving experience. There is no steering
wheel, there are no pedals and there is no engine compartment. In fact, every
piece of equipment that actually moves the car along the road is housed in an
11-inch-thick (28 cm) aluminium chassis -- also known as the skateboard --at
the base of the car. Everything above the chassis is dedicated solely to driver
control and passenger comfort.
This means the driver and passengers don't have to sit behind a mass of
machinery. Instead, the Hy-wire has a huge front windshield, which gives
everybody a clear view of the road. The floor of the fiberglass-and-steel
passenger compartment can be totally flat, and it's easy to give every seat
lots of leg room. Concentrating the bulk of the vehicle in the bottom section
of the car also improves safety because it makes the car much less likely to
tip over.
But the coolest thing
about this design is that it lets you remove the entire passenger compartment
and replace it with a different one. If you want to switch from a van to a
sports car, you don't need an entirely new car; you just need a new body (which
is a lot cheaper).
The
Hy-wire has wheels, seats and windows like a conventional car, but the
similarity pretty much ends there. There is no engine under the hood and no
steering wheel or pedals inside.
3. POWER
The "Hy" in Hy-wire stands for hydrogen, the standard fuel for
a fuel cell system. Like batteries, fuel cells have a negatively charged
terminal and a positively charged terminal that propels electrical charge
through a circuit connected to each end. They are also similar to batteries in
that they generate electricity from a chemical reaction. But unlike a battery,
you can continually recharge a fuel cell by adding chemical fuel -- in this
case, hydrogen from an on board storage tank and oxygen from the atmosphere.
The basic idea is to use
a catalyst to split a hydrogen molecule (H2) into two H protons (H+, positively
charged single hydrogen atoms) and two electrons (e-). Oxygen on the cathode
(positively charged) side of the fuel cell draws H+ ions from the anode side
through a proton exchange membrane, but blocks the flow of electrons.
The
electrons (which have a negative charge) are attracted to the protons (which
have a positive charge) on the other side of the membrane, but they have to move
through the electrical circuit to get there. The moving electrons make up the
electrical current that powers the various loads in the circuit, such as motors
and the computer system. On the cathode side of the cell, the hydrogen, oxygen
and free electrons combine to form water (H2O), the system's only emission
product.
In a hydrogen fuel
cell, a catalyst breaks hydrogen molecules in the anode into protons and
electrons. The protons move through the exchange membrane, toward the oxygen on
the cathode side, and the electrons make their way through a wire between the
anode and cathode. On the cathode side, the hydrogen and oxygen combine to form
water. Many cells are connected in series to move substantial charge through a
circuit.
In a hydrogen fuel
cell, a catalyst breaks hydrogen molecules in the anode into protons and
electrons. The protons move through the exchange membrane, toward the oxygen on
the cathode side, and the electrons make their way through a wire between the
anode and cathode.
On the cathode side,
the hydrogen and oxygen combine to form water. Many cells are connected in
series to move substantial charge through a circuit.
One fuel cell only
puts out a little bit of power, so you need to combine many cells into a stack
to get much use out of the process. The fuel-cell stack in the Hy-wire is made
up of 200 individual cells connected in series, which collectively provide 94
kilowatts of continuous power and 129 kilowatts at peak power. The compact cell
stack (it's about the size of a PC tower) is kept cool by a conventional
radiator system that's powered by the fuel cells themselves.
The hydrogen tanks and fuel-cell stack in the Hy-wire
This system delivers DC
voltage ranging from 125 to 200 volts, depending on the load in the circuit.
The motor controller boosts this up to 250 to 380 volts and converts it to AC current
to drive the three-phase electric motor that rotates the wheels (this is
similar to the system used in conventional electric cars).
The electric motor's job is to apply
torque to the front wheel axle to spin the two front wheels. The control unit
varies the speed of the car by increasing or decreasing the power applied to
the motor. When the controller applies maximum power from the fuel-cell stack,
the motor's rotor spins at 12,000 revolutions per minute, delivering a torque
of 159 pound-feet. A single-stage planetary gear, with a ratio of 8.67:1, steps
up the torque to apply a maximum of 1,375 pound-feet to each wheel. That's enough
torque to move the 4,200-pound (1,905-kg) car 100 miles per hour (161 kph) on a
level road. Smaller electric motors maneuver the wheels to steer the car, and
electrically controlled brake callipers bring the car to a stop.
The gaseous hydrogen
fuel needed to power this system is stored in three cylindrical tanks, weighing
about 165 pounds (75 kilograms) total. The tanks are made of a special carbon composite
material with the high structural strength needed to contain high-pressure
hydrogen gas. The tanks in the current model hold about 4.5 pounds (2 kg) of
hydrogen at about 5,000 pounds per square inch (350 bars). In future models,
the Hy-wire engineers hope to increase the pressure threshold to 10,000 pounds
per square inch (700 bars), which would boost the car's fuel capacity to extend
the driving range.
Ultimately, GM hopes
to get the fuel-cell stack, motors and hydrogen-storage tanks small enough that
they can reduce the chassis thickness from 11 inches to 6 inches (15 cm). This
more compact "skateboard" would allow for even more flexibility in
the body design.
4. CONTROL
The Hy-wire's
"brain" is a central computer housed in the middle of the chassis. It
sends electronic signals to the motor control unit to vary the speed, the
steering mechanism to maneuver the car, and the braking system to slow the car
down.
At the chassis level,
the computer controls all aspects of driving and power use. But it takes its
orders from a higher power -- namely, the driver in the car body. The computer connects
to the body's electronics through a single universal docking port. This central
port works the same basic way as a USB port on a personal computer: It
transmits a constant stream of electronic command signals from the car
controller to the central computer, as well as feedback signals from the
computer to the controller. Additionally, it provides the electric power needed
to operate all of the body's on board electronics. Ten physical linkages lock
the body to the chassis structure.
GM's diagram of the Autonomy design
The driver's control
unit, dubbed the X-drive, is a lot closer to a video game controller than a
conventional steering wheel and pedal arrangement. The controller has two
ergonomic grips, positioned to the left and right of a small LCD monitor. To
steer the car, you glide the grips up and down lightly -- you don't have to
keep rotating a wheel to turn, you just have to hold the grip in the turning
position. To accelerate, you turn either grip, in the same way you would turn
the throttle on a motorcycle; and to brake, you squeeze either grip.
Electronic motion
sensors, similar to the ones in high-end computer joysticks, translate this
motion into a digital signal the central computer can recognize. Buttons on the
controller let you switch easily from neutral to drive to reverse, and a
starter button turns the car on. Since absolutely everything is
hand-controlled, you can do whatever you want with your feet (imagine sticking
them in a massager during the drive to and from work every day).
The Hy-wire's X-drive
The X-drive
can slide to either side of the vehicle.
The 5.8-inch
(14.7-cm) colour monitor in the centre of the controller displays all the stuff
you'd normally find on the dashboard (speed, mileage, fuel level). It also
gives you rear view images from video
cameras on the sides and back of the car, in place of conventional mirrors. A
second monitor, on a console beside the driver, shows you stereo, climate
control and navigation information.
Since it doesn't
directly drive any part of the car, the X-drive could really go anywhere in the
passenger compartment. In the current Hy-wire sedan model, the X-drive swings
around to either of the front two seats, so you can switch drivers without even
getting up. It's also easy to adjust the X-drive up or down to improve driver
comfort, or to move it out of the way completely when you're not driving.
One of the coolest
things about the drive-by-wire system is that you can fine-tune vehicle
handling without changing anything in the car's mechanical components -- all it
takes to adjust the steering, accelerator or brake sensitivity is some new
computer software. In future drive-by-wire vehicles, you will most likely be
able to configure the controls exactly to your liking by pressing a few buttons,
just like you might adjust the seat position in a car today. It would also be
possible in this sort of system to store distinct control preferences for each
driver in the family.
GM
concept of the Autonomy with and without a body attached
The big concern with
drive-by-wire vehicles is safety. Since there is no physical connection between
the driver and the car's mechanical elements, an electrical failure would mean
total loss of control. In order to make this sort of system viable in the real
world, driveby- wire cars will need back-up power supplies and redundant
electronic linkages. With adequate safety measures like this, there's no reason
why drive-by-wire cars would be any more dangerous than conventional cars. In
fact, a lot of designers think they'll be much safer, because the central
computer will be able to monitor driver input. Another problem is adding
adequate crash protection to the car.
The other major hurdle for this
type of car is figuring out energy-efficient methods for producing,
transporting and storing hydrogen for the on board fuel-cell stacks. With the
current state of technology, actually producing the hydrogen fuel can generate
about as much pollution as using gasoline engines, and storage and distribution
systems still have a long way to go (see How the Hydrogen Economy Works for
more information).
So will we ever get the
chance to buy a Hy-wire? General Motors says it fully intends to release a
production version of the car in 2010, assuming it can resolve the major fuel
and safety issues. But even if the Hy-wire team doesn't meet this goal, GM and
other automakers are definitely planning to move beyond the conventional car
sometime soon, toward a computerized, environmentally friendly alternative. In
all likelihood, life on the highway will see some major changes within the next
few decades.
5. HY-WIRE CAR
SPECIFICATION
Top speed: 100 miles per
hour (161 kph)
Weight: 4,185 pounds
(1,898 kg)
Chassis length: 14 feet, 3
inches (4.3 meters)
Chassis width: 5 feet, 5.7
inches (1.67 meters)
Chassis thickness: 11
inches (28 cm)
Wheels: eight-spoke, light
alloy wheels.
Tires: 20-inch (51-cm) in
front and 22-inch (56-cm) in back
Fuel-cell power: 94
kilowatts continuous, 129 kilowatts peak
Fuel-cell-stack voltage:
125 to 200 volts
Motor: 250- to 380-volt
three-phase asynchronous electric motor
Crash protection: front
and rear "crush zones" (or "crash boxes") to absorb impact
energy
Related GM patents in
progress: 30
GM team members involved
in design: 500+
6. CONCLUSION
By using Hy-Wire
technology certain multi-national companies like General Motors is fully
intended to release a production version of the car in 2010, assuming it can
resolve the major fuel and safety issues. The life on the high way will see
some major changes within the next few decades.
7. FUTURE WORKS
Hy-wire so profoundly
changes the automotive industry that GM has more than 30 patents in progress
covering business models, technologies and manufacturing processes related to
the concept and more inventions are being added all the time.
"Someday, Hy-wire could be displayed
in a museum side-by-side with the first horseless carriages of Carl Benz or
Gottlieb Daimler, or next to Henry Ford's Model T," Burns said.
8. REFERENCES
WWW.HOWSTUFFWORKS.COM
WWW.GENERALMOTERS.COM
WWW.PEDIAIN.COM
WWW.WIKIPEDIA.COM
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