THE HYDROGEN-POWERED CAR HITS
STREETS THIS FALL
1. Hydrogen Tank
Two carbon-fiber tanks store 11 pounds of hydrogen fuel under very high
pressure (10,000 psi). In emergencies (e.g., a crash), sensors trigger shutoff
valves to keep hydrogen from escaping the tank.
2. Airflow
The intake grill sends
oxygen—a crucial component in the mix—to the fuel cell stack.
3. Power Control Unit
As the car’s energy manager
and brain, the power control unit draws electricity from the fuel stack and
sends it to the motor. During acceleration, it draws stored energy from the
battery for an extra boost.
4. Battery
Unlike in traditional
electric cars, the nickel-metal hydride battery in this car stores only excess
energy for use during ignition and acceleration.
5. Electric Motor
As electricity passes through the motor,
it polarizes the stator—a stationary ring around the rotor—to create a rotating
magnetic field. Magnets mounted on the rotor align with that field and spin at
the same rate to power the drive train. The more electricity that’s sent to the
motor, the faster the field spins and the faster the car goes. When braking and
coasting, the motor generates electricity for the battery.
6. Fuel Cell
In their most basic form, fuel
cells contain an anode, cathode, and a polymer electrolyte membrane (PEM).
Because each cell generates little voltage on its own, engineers string them
together in a series—or a stack. The car’s stack contains 370 cells, each
working to transform stored chemical energy into electricity. Here’s how.
In each cell, hydrogen runs
through a flow field plate to the anode. There, a platinum-cobalt catalyst
splits the hydrogen molecules into positively charged ions and negatively
charged electrons.
Then, the PEM permits the hydrogen ions to pass through to the
cathode, but it stops electrons, forcing them instead to travel an outer
circuit, creating an electric current.
Finally, electrons and ions meet up with oxygen at the cathode to
form water, which is emitted primarily as vapor.
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