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World's Largest Solar Array to use Stirling Engine
An anonymous reader writes "Stirling engines are not a neglected or forgotten technology after all, according to a story at PESN. With 20 years of in-the-field fine-tuning, Stirling Energy Systems is now ready to go big -- real big. They signed a purchase agreement Tuesday with Southern California Edison (SEC), to install a 20,000 dish array that will cover 4,500 acres and will be capable of generating 500 megawatts of electricity -- more than all other U.S. solar projects combined -- making this the largest solar installation in the world. Each collector has a 37-foot-diameter array of mirrors to focus the sun's rays on the Stirling engine, which turns the heat into rotational torque for electricity generation. According to a spokesperson for SCE, this purchase will be in their commercial interest, requiring no subsidy in order to compete, implying that the efficiencies of the technology will give them an edge in the market."
If anyone is wondering, 500 megawatts can power about 500,000 homes.
Sterling engines are pretty cool. They have one huge advantage over silicon solar power: much much less pollution in production. Photovoltaics are basically large chips, they use the same nasty chemicals and lots of electricity. Sterling engines are just machines, and very scalable apparently.
Funny that one solar-dynamic powerplant will double the solar power being utilized.
One of the Sterling engine makers has a deep-space powercell that combines a sterling converter and a big hunk of plutonium oxide. Man, I wish I could get one for the basement...
Josh
gigantino.tv - Heavy but weighs nothing.
The voters here in Colorado were suckered into an initiative requiring the utility companies to get 15% of their power from renewable sources whether it made economic sense or not. Since it looks like this thing actually does then I hope someone from the local utility reads /.
It sounds a lot smaller when you put it that way.
The Edison URL should be www.edisonnews.com. Yes, we require you to put the www on the front of it. And yes, I work for them.
Fantasy remains a human right; we make in our measure and in our derivative mode... -- JRR Tolkien
Stirling engines certainly aren't forgotten or neglected. Swedish submarines use Stirling engines for propulsion, for instance.
Trust the Computer. The Computer is your friend.
Stirling engines seem legitimate enough, but the linked site describing them seems somewhat crack-potish. They promote cold fusion and zero point energy, as well as a number of "alternative energy sources" I've never even heard of. There's also a page trying to disprove the Peak Oil theory, which should be real popular with the Slashdot crowd. Anyway, I sometimes wish that /. nerds had a greater understanding of the pure sciences, rather than just software engineering. Oh well.
Let see, it is about $5/gallon in the UK and the US is complaining about $3/gallon wtf. This is just under estimate too because I am converting from £ to $ and liters to gallons.
http://en.wikipedia.org/wiki/Stirling_engine#Probl ems_with_Stirling_engines
Quantum mechanics: the dreams that stuff is made of.
There have already been two big solar projects in Southern California Edison territory, called Solar One and Solar Two. Both were so expensive to operate that they couldn't even cover their operating costs, let alone their construction costs.
Yeah. Because everyone wants a nuclear reactor that combines the wonderful properties of graphite (see "The graphite fire" subsection) as a moderator, with water (graphite generates explosive hydrogen with high temperature steam) often in the primary or secondary cooling loop (helium is the primary coolant), with safety features such as no containment structure (this list is just a start - there's many times more that didn't make the list)
Yes, PBMRs have a negative void coefficient (reaction slows as temperature increases); big deal, so does almost every reactor build in the west in the past three decades. Yes, helium is the primary coolant; that doesn't help when there's a jam or corrosion that leads to a rupture, in which case water and/or air enters the chamber (a much hotter chamber than PWRs) - and yes, this has already happened. Containment structures have saved our collective arses from the unexpected too many times to be omitted.
PBMR proponents talk about safety, but they're really about reactor cost. They're hardly the only innovative reactor design out there, but they're apparently the only one that your average slashdotter knows about. There are thorium breeders, reactors that run on unenriched fuel, and designs like my favorite, BREST - a lead-bismuth breeder which can cool itself with natural convection, uses the ground as shielding, has the fuel naturally encased in lead, and unlike most breeders, uses no liquid sodium.
As an aside, we really should move to safe breeder designs, either thorium or uranium based.
U-235 is only 0.7% of natural uranium, and natural uranium isn't incredibly plentiful in deposits concentrated enough to justify mining (I read once that known deposits would supply the world at current power consumption for only a few hundred years). It's a shame that most U-238 goes to waste (yes, some is used in things like armor, bullets, and weights, but we produce far more of it than is used for such tasks)
Next to my desk we have an Ire Extinguisher. Our boss is really assertive, so we like the idea of having it.
I'm not sure why the lack of interest in pebble beds, but I'm guessing they need some political pressure...
As I understand it, the pebble bed nuclear reactors make it really hard to re-enrich the uranium after usage. This is a bad idea as re-enriched uranium can be reused and produces less radioactive waste in the long run. All we have to do to solve the reenrichment problem and a large part of our nuclear waste is to build a fast breeder reactor and start recycling the used material.
This was the original plan when nuclear power plants were first developed. President Carter used execuitive order to ban fast breeder reactors back in the 70's, so it wouldn't take much to undo that ban.
Fly me to the moon Let me sing among those stars Let me see what spring is like On jupiter and mars
Oh! Logic train a'comin!
:P
ding ding ding Ding Ding DING DING DING Diing diiing diiiing.....
Darn, missed it.
Plain and simple, gas prices in Europe are high because of taxes.
Oil companies aren't monopolies - it's a very varied industry, and fiercely competitive. It's worse than many industries, because they're all selling essentially the same thing. They'll push particular blends and additives, but it really comes down to the same product, so it's really down to whoever can sell it the cheapest.
By the way, the main reason that oil companies are turning such tidy profits right now is because they had been working to be profitable at 20$/barrel, and suddenly it's at 60$/barrel. Note that the high prices are much more of a benefit to producers than refiners, although the whole industry is quite profitable right now. If you have infrastructure or build infrastructure, it's in such demand, you're going to make money.
Next to my desk we have an Ire Extinguisher. Our boss is really assertive, so we like the idea of having it.
Car engines can't be nuclear. While nuclear reactors can be made with the appropriate power output for a car, the biggest problem is that the driver would be killed by the neutrons that would drift out of the engine. Neutrons are a bitch to shield against and a car would not be able to carry the necessary material.
A company in Australia is developing this type of technology for self-contained power generation in remote locations (and 3rd world countries/natural disaster areas). They are using a parabolic dish made from mirror polished bands of stainless steel. Stainless steel (while expensive) stands up to bad weather much better than glass mirrors - and by making the dish with bands (with gaps in between them) you reduce the effect that wind had on the dish.
They are making a dish that isn't affected by wind (except for wind that flattens buildings) doesn't get damaged by hail (unless it's bigger than a cricket ball) and is only 5% less efficient than the same size mirror dish. They don't have a website worth mentioning - but they are developing all this in conjunction with the CSIRO - so you may find something here (CSIRO) http://www.csiro.gov.au/ about it all. Look for Sterling engine power generation. The CSIRO did publish something recently in a subscription only publication about this.
In case you were wondering how I know - my brother works for the small electronics firm that came up with the parabolic dish idea. They have also come up with a sun tracking mechanism that costs $15 to manufacture.
Pity a 5KW generation system costs $25000 all up - but they expect it to last for 25 years or more.
All dollar figures here are Australian Pesos.
Oh yeah - they get around the "How do you generate electricity at night without sunlight light" issue, by using the dish to heat up 300KG (or so) of salt and graphite - which then acts as a heat battery. Apparently they can run the Stirling engine for 3 days or so after the Salt Cell gets to about 900 degrees centigrade.
1. There is a big debate over the graphite's role in Chernobyl. The Soviets who put out the fire were insistant that the graphite was burning - they even had debates over how to put out the burning graphite without encouraging faster burning or secondary reactions. Nuclear professionals in America are insistant that nuclear grade graphite only erodes - that it doesn't burn - and lab tests of fresh graphite hold this out. Even simple erosion of radioisotope-laden graphite would be awful, of course (especially in this case where the graphite is in direct contact with the nuclear reactants and daughter products), but it's hard to deny the Soviet field reports. In all likelyhood, fresh nuclear-grade graphite doesn't burn well, but after it is bombarded by high energy radiation and corrosive chemicals for long periods, it does.
2. There *Is* water in the system of most PBMR designs. As I stated, helium is the primary coolant; however, some use water as a secondary coolant in the core (such as China's design), and even some designs that don't use it in the core have a secondary loop in which water is pyrolized into hydrogen and oxygen.
3. "seven layers of containment". Um, yeah right. There's only one pressure-tight containment level in PBMRs. The graphite isn't pressure tight - it's just a coating, and one that gets highly contaminated in the process. The reactor vessel and associated helium loop and pellet recycling are pressure tight. Unlike most nuclear reactors, the reactor building is not a positive pressure structure.
4. "Without the helium moderator the chain reaction stops". This is called "a negative void coefficient", and it's nothing remotely new. Three mile island had a negative void coefficent too. The problem is that the reactor core, even if *all* reaction were to cease, still has a huge amount of heat inside of it, and this residual heat is what poses the threat. By the way, helium is not a moderator - graphite is. You'll note that in demonstrations, the only thing that they demonstrate is shutting down the helium coolant - they never violate the integrity of the pressure vessel. This is because oxygen (and even potentially water or steam) can get in, and this can have very serious consequences. And, without a containment structure...
5. "Gas moderated reactors are a means to make Thorium breeders" - Once again, the term is "gas cooled", not "gas moderated". Do you even know what a moderator is?
Next to my desk we have an Ire Extinguisher. Our boss is really assertive, so we like the idea of having it.
And the fears over Three Mile Island are just plain ignorance. It was a minor incident that didn't hurt anyone. Don't believe me? Too bad. The Pennsylvania court system does. After years of litigation, the courts ruled there isn't enough evidence anyone was harmed by the accident to support even going to trial.
My favorite quote is, "The court has searched the record for any and all evidence which construed in a light most favorable to Plaintiffs creates a genuine issue of material fact warranting submission of their claims to a jury. This effort has been in vain."
Here's a link to the ruling - Click Me
Oh, Edmund, can it be true? that I hold here, in my mortal hand, a nugget of purest green?
"breeder" still manages to refer to several different types, so there isn't a blanket answer. Ordinary "breeders" still have that same *potential* problem, but we don't just have "ordinary" breeders anymore.
While the current fad seems to be over PBMRs, maybe because of the neat name I guess, my favorite still remains the Integral Fast Reactor, not only because of safety features, but because these could run for decades just by burning all the spent fuel from our conventional reactors. Newflash: we don't *need* a hole in the ground for most nuclear waste, just chuck it into an IFR.
Maybe you never had the misfortune of having to clean up after a nuclear accident? And maybe he had access to a lot more information about these accidents than you or I ever will? I dunno, that's why I asked if anyone knew why he banned breeders. Apparently, it was an attempt to hinder proliferation of weapons-grade plutonium, a subject I suspect never came up in your nuke power training...
Cite source for clean-up as the Navy had not yet had one accident by the time he was discharged. To this day, we are still waiting for a screw up.
I never said it was a Navy screwup. Non-Navy screw ups galore.
Money for nothing, pix for free
So..
(shaking rust off memory)They ran the power (heat) output of the core low. Over controled it below min levels, decreased water flow, cranked up the power by pulling some rods to get power up. Power ran up to high side, dropped some rods in, added water too quickly, cooled core too much, no steam output, turbines stall, tech panics and pulls ALL of the rods (big no-no, he forgot to RTFM), core temp climbs, water cannot be provided quickly enough (no power), water flashes off into steam, core over heats, ignites graphite - boom. More or less.
A nice feedback loop they they magnified causing increasing excursions with ever larger over corrections - doh! Current reactor designs use the working fluid ( or intermediate heat transfer fluid) as the moderator; the reaction cannot proceed with out the moderator being present to slow the neutrons. If the fluid drains out, the reaction halts and the reactor cools. If the reactor gets too hot, the moderator boils off, again halting the reaction. Kinda hard to get into a meltdown condition.