[8D] Here is a Idea. Have a array of solar panals power a turnine that pumps water to a resoivor during the day and at night let the water out of the lake to power turbines that power generaters that generate electicity that power railroads![8D][8D] This soulves the problem of having huge batterys
We are past the headache stage. It is turning into a huge migraine!
[banghead]
Now there’s an application for the “Hobo wheel”
Okay…now what we need you to do is reach up where the lttle valve is on the IV and turn it a bit more counter-clockwise…then sit back and relax.
Ummmmm…I think you’d need a solar panel farm the size of Arkansas or therabouts to do anything useful…and where are we putting the water after its been pumped? There’s going to be a lot of that, too.
There is a pumped-storage plant just south of Ludington, Michigan (of ferryboat fame), and north of where I go every summer. It doesn’t use solar panels for pumping–in fact, it uses electricity to fill the reservoir (which is huge) at night, when there is a bigger supply available, then creates electricity by sending the water back into Lake Michigan during the day, helping the grid weather the peaks.
(Check out the post below mine!)
You NEVER, EVER pump during the day. That is not done. If you have solar power, you put it into the grid. What you do is pump water back at night. Why you ask? Because power at night is cheaper. So you use cheap power to pump the water and release it during the daylight hours, generally after 11:00AM when the price of electricity is high.
You can see from this table that the off-peak time price is lower than the peak time.
http://www.theice.com/dailyIndices/powerIndex.html
But if the pumped power is from low cost solar power you coul release it at any time.
They do this at Niagara Falls
So, yes, let’s use solar panels to reverse Niagara Falls!
Keep in mind, too, that an electric railroad would be demanding power at all hours of the day, so your panels would have to be able to stay ahead of a 24-hour demand.
The answer really is hydroelectric power–but that would be too dull!
I suppose every waterfall is solar powered if you think about it. Rain and snow are delivered thanks to the evaporation of water which conveniently happens via solar power. So when all the rain and snow occur at higher elevations, the result is that the water moves to lower levels. We can build dams to harness hydroelectric power, and VOILA! It all works. [:D]
Chris
Denver, CO
Chris, at night we do pump water “uphill” back into the lakes at night, again cheaper power. They do this a lot in the west.
Dunkirk - this is the way it is - Power is a lot more expensive during the day, why would you use the expensive power to pump watrer to use at night. That is just plain dumb. You put it into the grid. Then you use cheap off-peak power to pump water uphill. That is they way it is done. Look at the price chart in the link I put in my earlier post. Solar power is not cheap, it is one the the most expensive of the renewable power sources and higher than any of teh normal power sources.
dunkirk, pumped storage is almost always intended as a peak-shifting technology, not as a means of cost-effective energy storage. Listen to these guys – they know their business.
Remember that in most cases there is a fairly large cost to construct these facilities, even when the local/Federal EPA et al. allow you to use existing bodies of water at high elevation as the basis for your reservoir system. Now, you have to ask whether it makes better sense to build a large solar array – which is almost always intended for installation far, far away from areas where there is lots of water on the surface (where it evaporates to clouds, which block much of the photoelectric insolation…) – and devote its entire output to pumping water uphill rather than converting to phase-corrected AC and driving a proportional share of daytime peak with it. Remember that with pumps you get losses, both electrical and physical, both ways, whereas with direct conversion both the amount and the proportion of the loss would be less.
Now, if you were somehow to have a large generating capacity far from the grid, and used that electricity to pump water from places that didn’t need the water to places that did, and then arranged for water use THERE via hydro, you might be able to piece together a rationale for construction. But I’d need extensive convincing with some very, very hard numbers…
dharmon, the problem isn’t the IV, it’s that he’s been pushing the button on the pain pump a bit too often… ;-0
If you were isolated, then backpump. But if you’re on the grid, buy low, sell high [8D]
If your electric railroad were solar, you’d build twice the capacity you needed. While the sun is shining you’d sell half of it back to the grid (at peak prices [8D]) and when the sun set, you’d buy all your power back off the grid, (at nighttime prices [8D]).
That’s better than backpumping because backpumping is less than 100% efficient, while selling peak and buying off-peak is 137% efficient because you’re selling for $55 what you buy back later for $40.
Thank you Overmod. To add to the mix, there are companies working to store A/C in storage type batteries. Very interesting, but a long way till is is viable. Another thing being done is pumping air into reservoirs at night and then using the compressed gas to drive a turbine during the day. Fuel cells are interesting, but far from practical applications.
Remember, Dynamics can backfeed a system, but it can only supplement what is needed, It will never cover the load.
There are some awesome environmental objections to pumped storage facilities which involve the upper and lower reservoirs. If they are existing lakes, the variations in water level pretty will pretty well destroy whatever environmental values there might be; if either reservoir requires new storage, that’s going to submerge a lot of land, or play havoc with an existing river, or both.
Then the solar panel problem is also immense. If we suppose you are in the desert southwest, you can figure – very very roughly – about 10 kw hours per square metre per day from your facility. So to replace a nice little 500 megawatt power plant (12,000,000 kw hours per day) you need about 1,000,000 square metres. Which is about half a square mile of collector. And a 500 mw plant is a small plant…
And then you’d have to import the water.
And treat the water. Boiler water is very picky for power plants, just as it was for steam engines. You can get away with lower water quality for condenser water.
But you do not need water for a solar array. It is already being converted to electricity.
The amount of water pumped at night should not effect the water level in a reservoir, unless it is a very small one.
Try searching for information at Mother Earth News
http://www.motherearthnews.com/
underworld
[:D][:D][:D][:D][:D]
The solar generated electricty could be trasmitted to a place were there are already
pumped storage. A solar array in the central time zone could pump water in the eastern time zone getting a extra hour of sunlight. Come on guys somebody here must be a fan of “Popular Mechanics”
It is not efficent enough to pump the water that far, the loses would override any gain.
And you do not get it, you put the power in the grid. This is generated during daylight hours, when the price is high, you sell it.
transmit the electricy 200 miles to the pumps