I think that the idea here is to
produce some current while grabbing the remainder of the energy (over ninety
percent of incoming) to produce hot water.
Thus the reason for 200C. The
bottom of the thermal cycle will be never higher than 100C while the top end is
pushed to 200C.
The actual heat differential is
plausibly enough to drive a reverse Rankin cycle engine able to produce 75%
brake horsepower.
This all suggests that the whole
package is capable of been cleverly engineered into a highly efficient heat and
power generation package although complex enough to give Rube Goldberg an
headache.
In the meantime Rossi Focardi are
ending all this effort by making it completely obsolete which was already true
and why it has never gained much traction.
Solar power, with a side of hot running water
by David L. Chandler
MIT News Office
Doctoral student Daniel Kraemer, right, and Professor Gang Chen display
a prototype of a flat-panel solar-thermoelectric generating device. Photo:
Melanie Gonick
MIT researchers and their collaborators have come up with an unusual, high performance and possibly less expensive way of turning the sun's heat into electricity.
Their system, described in a paper published online in the journal
Nature Materials, produces power with an efficiency roughly eight times higher
than ever previously reported for a solar thermoelectric device - one that
produces electricity from solar heat.
It does so by generating and
harnessing a temperature difference of about 200 degrees Celsius between the
interior of the device and the ambient air.
The concept "is very radical," says Gang Chen, MIT's Carl
Richard Soderberg Professor in Power Engineering and director of the Pappalardo
Micro and Nano Engineering Laboratories, who co-authored the new paper with MIT
doctoral student Daniel Kraemer and collaborators from Boston College Solar-Thermal
Energy Conversion
Center , an Energy
Frontier Research
Center at the U.S.
While solar thermal electricity
systems aren't a new idea, they typically involve vast arrays of movable
mirrors that track the sun and focus its rays on a small area. The new approach
uses flat, stationary panels similar to traditional solar panels, eliminating
the need for tracking systems.
Like the silicon photovoltaic cells that
produce electricity when struck by sunlight, Chen's system is a solid-state
device with no moving parts. A thermoelectric generator, placed inside a vacuum
chamber made of glass, is covered with a black plate of copper that absorbs
sunlight but does not re-radiate it as heat. The other side of the generator is
in contact with ambient temperatures. Placed in the sun, the entire unit heats
up quickly, even without facing the sun directly.
The device requires much less material than conventional photovoltaic
panels, and could therefore be much less expensive to produce. It can also be
integrated into solar hot water systems,
allowing the expenses of the structure and installation to serve two functions
at once. Such solar waterheaters are
rarely seen in the United States ,
but are already a highly successful mass-market product in China and Europe ,
where they provide households with hot water and in some cases space heating as
well.
The materials used to build such solar thermoelectric generators, made
through a nanostructured process, were developed jointly a few years ago in
Chen's lab at MIT and in co-author Zhifeng Ren's lab at Boston College. Their
teams have continued to work on improving these materials and integrating them
into complete systems.
Chen points out that the U.S. Department of Energy has programs to
develop thermoelectric systems, mostly geared toward harnessing waste heat from
car and truck engines. He says that solar applications for such devices also
can "have an important role to play" in reducing carbon emissions.
"Hopefully we can prove that," he adds.
Li Shi, associate professor of mechanical engineering at the University
of Texas at Austin, says this approach to solar power is "very novel,
simple, and easy for low-cost implementation." The efficiency level they
have demonstrated so far, at 4.6 percent, is "already quite impressive,"
he says.
"With the use of other or new thermoelectric materials that can
operate at a higher temperature," Shi adds, "the efficiency may be
improved further to be competitive with that for state-of-the-art amorphous
silicon solar cells. This can potentially provide a different approach to
realizing the $1-per-watt goal for solar-electricity conversion."
The new system wouldn't be a substitute for solar photovoltaics,
Chen says, but offers "another way" of tapping into the enormous
amount of solar energy that bathes the Earth every day. And because it can be
piggybacked onto the existing solar hot-water
industry, the thermoelectric device could be a relatively inexpensive addition,
with "no subsidies required," Chen suggests. "It can be a
game-changing thing," he says.
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