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It's the most radical alteration to combustion-engine design yet.
you haven’t noticed,
internal-combustion engines are kind of big – even the three-cylinder unit on
the new Ford Fiesta SFE is too large to carry around in your arms.
However, what if you drive
a car that doesn’t necessarily need an engine that big, or an engine that
contains all the standard rotating parts?
What if your electric car
just needs a simple range-extending generator?
Well, Toyota has you
covered with the FPEG.
FPEG stands for Free
Piston Engine Linear Generator (FPELG didn’t have the same ring to it), and it
could very well be the first seriously major change to the standard
internal-combustion engine in its century-long history.
All Toyota had to do was
take a look at an older engine design, incorporate a long-standing law of
physics, and spend measureless time and money to make everything work. Easy,
right?
The big change between the
FPEG and a standard car engine is the removal of both the crankshaft and the connecting
rods.
When it comes to providing
juice for electric-car batteries, you don’t need the rotational motion of the
crankshaft – all it does is add weight and complication.
So Toyota ditched the
crankshaft (and, by proxy, the connecting rods, since they bolt to the
crankshaft).
However, that leaves us
with an engine and a piston that lacks the ability to move back and forth in
the cylinder; the power stroke will push the piston down, but without the
crankshaft and con rods, what will push it back up?
To remedy that issue,
Toyota created a gas-filled chamber underneath the piston.
As the piston moves
downwards in the cylinder, it compresses that gas, which acts as a spring to
launch the piston back up to the top.
That’s all well and good,
but again, without the crankshaft, how is power delivered to the vehicle once
the air-fuel mixture is ignited?
That’s where the law from
physics comes into play. Toyota replaced the crankshaft with a magnet just
below the piston (a neodymium-iron-boron magnet, specifically) and a coil of
wire built into the cylinder wall.
Thanks to the beauty of
physics, if you drop a magnet through a coil of wire, it generates a voltage.
If that wire is connected
in a circuit, current will flow.
In more scientific terms,
when a magnet is moved relative to a conductor, it creates an electromotive
force; what you have there is Faraday’s law of induction.
Toyota’s FPEG takes full
advantage of Faraday’s law.
As the piston moves
through the cylinder, the magnet connected to the piston will move through the
coiled wire built into the cylinder.
That creates the
electromotive force, which will then supply current to batteries or directly to
an electric motor.
Toyota’s discovered a
unique way to turn mechanical energy into electrical energy while
simultaneously deleting unnecessary parts of the equation.
The result is a
15-or-so-horsepower engine that, in a balanced two-cylinder configuration, is
less than a foot around and about two feet long.
That’s a small, light
engine – perfect for electric cars, where every bit of weight savings will
translate to increased efficiency.
15 horsepower might not
seem like much, but it’s enough to keep a small car rolling down the highway at
the speed limit.
Toyota’s got one single
use in mind for the FPEG, one that we’ve already discussed – range-extending
motors for electric cars.
15 horsepower is enough to
provide juice to a range-anxious EV driver, and as mentioned before, it would
be smaller and lighter than the current slew of range-extender engines, so
there are many benefits to be had from the FPEG.
However, since it’s still
a prototype, don’t expect it to be in your next Prius plug-in.
That said, Toyota and BMW
are entering into a new joint-venture based around a new sports car.
If that car happens to be
a hybrid, you may see this engine right at the heart of that beast.
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