In the 1950s, automobile prognosticators foretold
that we would have flying cars by the end of the century, and here we are,
still stuck on the ground. It's probably for the best, considering that
thousands of hours of flight training are required to take an airplane off the
ground. Even so, it's a pretty neat idea. For now, though, let's just stick to
a few years into the future, or even just one. With all the development in the
last decade, trying to get electric vehicles [EV] out of the concept vaults and
into people's garages, one has to wonder where it's all going to end up.
Battery and motor technology, of course, are only one half of the equation, but
what of the supporting infrastructure, charging stations and repair facilities?
Tesla Motors, a leading EV manufacturer and startup company, had made great strides in making EVs more accepted by the driving public, offering industry-leading range, and even a growing network of fast-charging stations that will one day make it across the US and Canada. The Model S is now in full production, deliveries have started, and CEO Elon Musk even announced their first full week of profitability on December 3, 2012. On the other hand, some EV and EV-related companies haven't been able to hold on, including now-bankrupt A123 Systems, and advanced rechargeable battery developer and manufacturer, and flailing CODA Motors, who just laid off 15% of their workforce.
The Future…
A recent report released by Pike Research, “ElectricVehicles: 10 Predictions for 2013,” lays out their predictions for EVs in
2013. Seeing as 2013 isn't that far off, just a couple of weeks, as a matter of
fact, what should we be looking forward to? Here are a few highlights from the
report:
1.
Battery Components. Rechargeable battery packs are made up of a number of compnent, the
most critical of which are the anode, cathode, and electrolyte. Companies
developing rechargeable battery packs haven't very much success, and financing
such ventures has started to wane, so we're expecting to see a shift from
developing whole packs to perfecting individual components. Large chemical
companies, such as Dow Energy Materials and BASF, will continue to invest in
R&D of the individual components, which will still require a battery
manufacturer to put the pieces together.
2.
Charging Rates. Various EV manufacturers have offered a range of EV charging stations,
some as low as 7kW [LI] and take up to 8 hours to fully charge, and others,
such as the Tesla Supercharger, up to 100 kW [LIII], which can charge an 80kWh
Model S battery pack in about an hour. What drivers, especially commuters, are
realizing, though, is that the LI chargers are a good balance between charge
time and charger expense. Expect more companies to install LI chargers at
workplaces, which are cheaper and will sufficiently charge most EVs in the four
to eight hours they are parked, as well as more consumers opting for LI
chargers at home, where they can charge overnight.
3.
Fuel Cell Vehicles. Hydrogen Fuel Cell [HFC] vehicles are the cleanest hybrids that exist,
making use of an all-electric power-train coupled with an HFC that converts
hydrocarbon-rich or pure hydrogen fuel into electricity with zero emissions.
The expense and weight of HFCs have come down over the years, but still not
quite enough for a wide distribution. Some 3,000 HFC vehicles are expected to
hit fleets, government operations, and qualified trials in 2013. Depending on
these trials, a wider distribution by Toyota and Honda could start as early as
2014 or 2015.
The following aren't EV-specific highlights,
but still point to some advancements making it even to internal combustion
engine [ICE] vehicles:
1.
Start-Stop Technology. We already know that idling costs as much as 3¢/min, but imagine if you
could shut the engine off automatically. There are already a few vehicles with
Start-Stop Technology [SST], which automatically shuts down the engine, even
before coming to a complete stop. SST, and perhaps an extension of it, coasting
technology [CT], could increase fuel economy by up to 10% according to BMW and
Audi. Along with SST and CT, advancements will have to be made with larger
battery packs and heavier starters, as well as electronic steering and brakes,
which do not rely on engine-generated vacuum to operate.
2.
48-Volt Battery. Years ago, the 42V lead-acid battery came and failed to enter the
automobile market, citing the impracticality and expense of the step-down
converters required to run 12V components. Since then, converter prices and
reliability have gotten better, making the introduction of 48V batteries a
better option, especially in vehicles with start-stop technology. With a 48V
battery, headlights and other electric accessories won't fade when the engine
is stopped at 0mph. Engine restarting will also be faster. AllCell
Technologies, Balqon, and others are developing 48V lead-acid and lithium-ion
[Li-ion] batteries for just such an application.
The EV market is still in its infancy, and
there are sure to be both successes and failures. At first, it seemed that
consumers weren't willing ot accept the limitations imposed by pure EVs, but
perceptions are turning around. I, for one, expect that it will continue to
grow and expand, and it seems that the researchers at Pike Research agree.
Author Bio:
B.
Jerew is green automotive technology expert who cut his teeth as a Toyota
master technician. He has provided this post on behalf of MyCarLender.com, a service that
matches car-shoppers to lenders willing to approve them for financing.