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#1
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What about a national battery?
That is, a battery that could supply the nation's electrical needs for a few
days during a blackout. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. The whole shebang would need only 5 billion tons of lead. The US has 7 million tons of lead reserves, while the entire world has approximately 80 million tons. We'd better get busy looking for more. Chinese toys might be a good place to start... (Caution: Real maths in use) http://physics.ucsd.edu/do-the-math/...sized-battery/ |
#2
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What about a national battery?
"HeyBub" wrote in
m: That is, a battery that could supply the nation's electrical needs for a few days during a blackout. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. The whole shebang would need only 5 billion tons of lead. The US has 7 million tons of lead reserves, while the entire world has approximately 80 million tons. We'd better get busy looking for more. Chinese toys might be a good place to start... (Caution: Real maths in use) http://physics.ucsd.edu/do-the-math/...sized-battery/ Somewhere I read that the battle between DC and AC is being revived. DC should be better at withstanding weather related interruptions, so fewer (big) power outages at the transmission line and transformer(?) levels. Don't ask me about the physics ... I don't think that a branch falling down on an AC line and breaking it is any different from a DC line, but apparently it would be easier and cheaper to bury DC lines than AC lines. -- Best regards Han email address is invalid |
#3
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What about a national battery?
On 11/18/2011 6:36 AM, Han wrote:
.... Somewhere I read that the battle between DC and AC is being revived. DC should be better at withstanding weather related interruptions, so fewer (big) power outages at the transmission line and transformer(?) levels. Don't ask me about the physics ... I don't think that a branch falling down on an AC line and breaking it is any different from a DC line, but apparently it would be easier and cheaper to bury DC lines than AC lines. Any weather-related issues are only a side-effect--the underlying reason for DC over AC for transmission is cutting the AC losses. It's now a possibility that wasn't practical before the advent of solid-state electronics that could be made to handle the necessary voltages/currents. Manitoba Hydro has been an early implementor... http://www.hydro.mb.ca/corporate/facilities/transmission_system.shtml http://www.hydro.mb.ca/corporate/facilities/ts_nelson.shtml Siemens has been building transmission lines in China and India, last I knew there were plans on east coast in US w/ PEPCo altho I haven't followed progress. Anything like offshore wind will rely on them to get large amounts of power back to shore. -- |
#4
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What about a national battery?
On Nov 18, 8:21*am, dpb wrote:
On 11/18/2011 6:36 AM, Han wrote: ... Somewhere I read that the battle between DC and AC is being revived. *DC should be better at withstanding weather related interruptions, so fewer (big) power outages at the transmission line and transformer(?) levels. Don't ask me about the physics ... I don't think that a branch falling down on an AC line and breaking it is any different from a DC line, but apparently it would be easier and cheaper to bury DC lines than AC lines. Any weather-related issues are only a side-effect--the underlying reason for DC over AC for transmission is cutting the AC losses. It's now a possibility that wasn't practical before the advent of solid-state electronics that could be made to handle the necessary voltages/currents. Manitoba Hydro has been an early implementor... http://www.hydro.mb.ca/corporate/facilities/transmission_system.shtml http://www.hydro.mb.ca/corporate/facilities/ts_nelson.shtml Siemens has been building transmission lines in China and India, last I knew there were plans on east coast in US w/ PEPCo altho I haven't followed progress. *Anything like offshore wind will rely on them to get large amounts of power back to shore. -- Also, the insulation required for a DC line is whatever the nominal voltage is, while the insulation on an AC line must be 1.414 times the nominal voltage. The line losses are similar, but there has to be an efficient way to transform from one voltage to another at the end points, that is where semiconductors can now replace the transformer and its losses. |
#7
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What about a national battery?
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#8
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What about a national battery?
On Nov 18, 6:13*pm, "hr(bob) "
wrote: On Nov 18, 8:21*am, dpb wrote: On 11/18/2011 6:36 AM, Han wrote: ... Somewhere I read that the battle between DC and AC is being revived. *DC should be better at withstanding weather related interruptions, so fewer (big) power outages at the transmission line and transformer(?) levels. Don't ask me about the physics ... I don't think that a branch falling down on an AC line and breaking it is any different from a DC line, but apparently it would be easier and cheaper to bury DC lines than AC lines. Any weather-related issues are only a side-effect--the underlying reason for DC over AC for transmission is cutting the AC losses. It's now a possibility that wasn't practical before the advent of solid-state electronics that could be made to handle the necessary voltages/currents. Manitoba Hydro has been an early implementor... http://www.hydro.mb.ca/corporate/facilities/transmission_system.shtml http://www.hydro.mb.ca/corporate/facilities/ts_nelson.shtml Siemens has been building transmission lines in China and India, last I knew there were plans on east coast in US w/ PEPCo altho I haven't followed progress. *Anything like offshore wind will rely on them to get large amounts of power back to shore. -- Also, the insulation required for a DC line is whatever the nominal voltage is, while the insulation on an AC line must be 1.414 times the nominal voltage. *The line losses are similar, but there has to be an efficient way to transform from one voltage to another at the end points, that is where semiconductors can now replace the transformer and its losses.- Hide quoted text - - Show quoted text - The losses on AC are greater due to capacitive effects.Capacitive effects are greater in buried cables as the conductors are closer together and the insulator has a lesser permitivity than air. However the main reason for buried cables bing expesive is that they have to be de-rated due to lack of cooling when buried. ie bigger conductors are needed. |
#9
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What about a national battery?
I think it's an interesting idea. Makes me wonder if there
are some simpler things we can do, in the meantime. Trim some trees, and bury power lines when possible. -- Christopher A. Young Learn more about Jesus www.lds.org .. "HeyBub" wrote in message m... That is, a battery that could supply the nation's electrical needs for a few days during a blackout. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. The whole shebang would need only 5 billion tons of lead. The US has 7 million tons of lead reserves, while the entire world has approximately 80 million tons. We'd better get busy looking for more. Chinese toys might be a good place to start... (Caution: Real maths in use) http://physics.ucsd.edu/do-the-math/...sized-battery/ |
#10
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What about a national battery?
On 11/18/2011 6:56 AM, Stormin Mormon wrote:
I think it's an interesting idea. Makes me wonder if there are some simpler things we can do, in the meantime. Trim some trees, and bury power lines when possible. It's only $$$$...and the protesters who raise barriers against accomplishing anything anymore. -- |
#11
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What about a national battery?
HeyBub wrote:
That is, a battery that could supply the nation's electrical needs for a few days during a blackout. For one thing, you wouldn't have a single "national" battery. You would have many regional batteries located in more strategic locations with access to major grid tie-in points. The north-american grid system is not wired to be able to handle energy input from a single location. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. And it wouldn't use lead-acid batteries. It would use molten sodium batteries. It's already been done in Texas as a way to compensate for needing to upgrade a transmission line to a small town (Presidio). It would have been more expensive to string a new transmission line capable of supplying the town with electricity during peak use, so what they are doing instead is storing power in the battery during non-peak time and then drawing power from it during peak time. =========== http://www.smartplanet.com/blog/thin...ore-power/3747 Presidio, Texas, a border town of under 5,000 people in the Rio Grande Valley, recently had a 4 megawatt battery installed by Electric Transmission Texas to improve service. It cost $25 million and was bigger than a house. The Big Ol’ Battery (BOB) is dwarfed by Fairbanks’ Battery Energy Storage System (BESS), installed by ABB Group in 2003. BESS can hold a charge of 26 Megawatts for up to 15 minutes and is used to back up the local grid. The two batteries are quite different. BOB uses sodium and sulfur. BESS is nickel-cadmium. But what Don Sadoway of MIT has discovered is that if your metal is molten, it can hold a lot more power in a lot less space. Sadoway says his battery costs less than lithium, and holds a charge for a longer period of time. A battery the size of a shipping container would carry 1 megawatt for several hours. The design is relatively simple. Melted magnesium at the top, melted antimony at the bottom, and a salt composed of both elements in the middle. The salt breaks down as the battery is charged, then rebuilds as electrons are discharged. Sadoway, who recently turned 60, said his inspiration was the way aluminum is coaxed from bauxite by being melted using electricity. For his birthday he’s getting a symposium in his honor this June. Sadoway is a University of Toronto alumnus. (Go True Blue.) While the Sadoway battery is impressive, it really illustrates how far research must travel to make a smart grid a reality. Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. Power demand also fluctuates. Better, more powerful, and cheaper batteries are needed to match supply with demand. Sadoway’s battery is one small step down a long, long road. It’s an interesting technique, but it’s probably not our final answer. |
#12
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What about a national battery?
Home Guy wrote:
HeyBub wrote: That is, a battery that could supply the nation's electrical needs for a few days during a blackout. For one thing, you wouldn't have a single "national" battery. You would have many regional batteries located in more strategic locations with access to major grid tie-in points. The north-american grid system is not wired to be able to handle energy input from a single location. Read the article. The author pointed that out. His "National Battery" was in the aggregate. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. And it wouldn't use lead-acid batteries. It would use molten sodium batteries. Again, read the article. The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices |
#13
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What about a national battery?
HeyBub wrote:
And it wouldn't use lead-acid batteries. It would use molten sodium batteries. Again, read the article. Read my article. Any such large-scale battery would not use lead-acid. There are two such large-scale batteries in use. One uses NiCad, the other uses molten sodium. Here's why we'll never see a "national battery" using lead-acid technology: http://oilprice.com/Energy/Energy-Ge...y-Problem.html There is simply not enough lead in the world to meet the baseline design goal (power the country for 1 week). Even if this is scaled back to 1 day, it would require about 700 million tons of lead. There are about 80 million tons of lead in known world reserves. See also: http://www.renewableenergyworld.com/...-and-stability |
#14
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What about a national battery?
"HeyBub" wrote in
: Again, read the article. Sorry, I haven't read the article. Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). Isn't high current charge and discharge one of those reasons? -- Best regards Han email address is invalid |
#15
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What about a national battery?
On 18 Nov 2011 19:34:01 GMT, Han wrote:
"HeyBub" wrote in : Again, read the article. Sorry, I haven't read the article. Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). Isn't high current charge and discharge one of those reasons? Size and weight |
#16
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What about a national battery?
" wrote in
news On 18 Nov 2011 19:34:01 GMT, Han wrote: "HeyBub" wrote in : Again, read the article. Sorry, I haven't read the article. Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). Isn't high current charge and discharge one of those reasons? Size and weight Of course, Li is quite a bit lighter than Pb ... -- Best regards Han email address is invalid |
#17
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What about a national battery?
" wrote in
news On 18 Nov 2011 19:34:01 GMT, Han wrote: "HeyBub" wrote in : Again, read the article. Sorry, I haven't read the article. Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). Isn't high current charge and discharge one of those reasons? Size and weight lithium-ion battery packs are used because they have the highest energy density per pound. that translates to longer range.(for a given weight) -- Jim Yanik jyanik at localnet dot com |
#18
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What about a national battery?
On Nov 18, 7:35*pm, "
wrote: On 18 Nov 2011 19:34:01 GMT, Han wrote: "HeyBub" wrote in : Again, read the article. Sorry, I haven't read the article. *Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). *Isn't high current charge and discharge one of those reasons? Size and weight - Tch. Energy density, |
#19
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What about a national battery?
On Nov 18, 7:34*pm, Han wrote:
"HeyBub" wrote : Again, read the article. Sorry, I haven't read the article. *Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). *Isn't high current charge and discharge one of those reasons? -- Best regards Han email address is invalid The reasonis that lithium is a rare and expensive metal. The latest big discovery was (you might have guessed..).) yes Afghanistan. Irag for oil, Afghanistan for lithium. Needed for the transport of the future. |
#20
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What about a national battery?
harry wrote in
: On Nov 18, 7:34*pm, Han wrote: "HeyBub" wrote innews:xIOdnW1YJ5xx-VvTnZ2dnUVZ_u : Again, read the article. Sorry, I haven't read the article. *Nevertheless, below ... The author chose lead-acid for his example because: A. Lead is the cheapest B. Efficient (85% in a charge cycle) C. Well-tested technology (over 150 years of use and development) D. Lead is common E. Lead-acid batteries are, by far, the most common option in power storage devices There must be a reason that lithium batteries are most often used for systems large (cars) and small (laptops, camera batteries). *Isn't high current charge and discharge one of those reasons? -- Best regards Han email address is invalid The reasonis that lithium is a rare and expensive metal. The latest big discovery was (you might have guessed..).) yes Afghanistan. Irag for oil, Afghanistan for lithium. Needed for the transport of the future. Harry, don't believe everything extremeists are telling you. Lithium isn't that rare. Next you are going to say that someone is going to war against Poseidon, because of the rare earth minerals on the bottom of the oceans. -- Best regards Han email address is invalid |
#21
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What about a national battery?
On Nov 18, 8:15*am, Home Guy wrote:
Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. You didn't mention geothermal - that's about as reliable as it gets. Edison's original concept was that each home or group of homes would have its own power plant. Primarily that was probably due to the limitations of DC power, but the concept is still a good one. R |
#22
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What about a national battery?
On 11/18/2011 8:34 AM, RicodJour wrote:
On Nov 18, 8:15 am, Home wrote: Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. You didn't mention geothermal - that's about as reliable as it gets. .... Limitations on sources. -- |
#23
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What about a national battery?
On Nov 18, 9:34*am, RicodJour wrote:
On Nov 18, 8:15*am, Home Guy wrote: Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. You didn't mention geothermal - that's about as reliable as it gets. Edison's original concept was that each home or group of homes would have its own power plant. *Primarily that was probably due to the limitations of DC power, but the concept is still a good one. And more on the topic of the OP, what would seem to be more practical is what some people are already implementing in their homes as part of a solar and/or wind generator installation; that is, a bank of batteries sized to tide that individual house over through periods of low power generation combined with unavailability of power from the grid. Generally those same people are still tied into the grid (although some may choose not to) and can sell power back to the grid when their production exceeds their use, and then vice versa when the situation is reversed. If everyone had a setup like that, that would accomplish the same goal without the need for huge honkin' batteries, inverters, transformers, etc. nate |
#24
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What about a national battery?
And more on the topic of the OP, what would seem to be more practical is what some people are already implementing in their homes as part of a solar and/or wind generator installation; that is, a bank of batteries sized to tide that individual house over through periods of low power generation combined with unavailability of power from the grid. Generally those same people are still tied into the grid (although some may choose not to) and can sell power back to the grid when their production exceeds their use, and then vice versa when the situation is reversed. If everyone had a setup like that, that would accomplish the same goal without the need for huge honkin' batteries, inverters, transformers, etc. ============== It's sad that many solar inastallations that use "grid tie" inverters CANNOT operate without the grid. Mark |
#25
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What about a national battery?
On Nov 19, 1:24*am, "MarkK" wrote:
And more on the topic of the OP, what would seem to be more practical is what some people are already implementing in their homes as part of a solar and/or wind generator installation; that is, a bank of batteries sized to tide that individual house over through periods of low power generation combined with unavailability of power from the grid. *Generally those same people are still tied into the grid (although some may choose not to) and can sell power back to the grid when their production exceeds their use, and then vice versa when the situation is reversed. *If everyone had a setup like that, that would accomplish the same goal without the need for huge honkin' batteries, inverters, transformers, etc. ============== It's sad that many solar inastallations that use "grid tie" inverters CANNOT operate without the grid. Mark It is a safety thing, not "sad". http://en.wikipedia.org/wiki/Anti-islanding |
#26
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What about a national battery?
On Nov 18, 2:34*pm, RicodJour wrote:
On Nov 18, 8:15*am, Home Guy wrote: Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. You didn't mention geothermal - that's about as reliable as it gets. Edison's original concept was that each home or group of homes would have its own power plant. *Primarily that was probably due to the limitations of DC power, but the concept is still a good one. R Any batteries would only last a few hours. People can manage for a few hours without electricity so the whole exercise is pointless. |
#27
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What about a national battery?
harry wrote:
On Nov 18, 2:34 pm, RicodJour wrote: On Nov 18, 8:15 am, Home Guy wrote: Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. You didn't mention geothermal - that's about as reliable as it gets. Edison's original concept was that each home or group of homes would have its own power plant. Primarily that was probably due to the limitations of DC power, but the concept is still a good one. R Any batteries would only last a few hours. People can manage for a few hours without electricity so the whole exercise is pointless. Sigh. Read the article. The author is computing on a week's worth of stored power. |
#28
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What about a national battery?
On Nov 18, 1:15*pm, Home Guy wrote:
HeyBub wrote: That is, a battery that could supply the nation's electrical needs for a few days during a blackout. For one thing, you wouldn't have a single "national" battery. You would have many regional batteries located in more strategic locations with access to major grid tie-in points. *The north-american grid system is not wired to be able to handle energy input from a single location. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. And it wouldn't use lead-acid batteries. *It would use molten sodium batteries. It's already been done in Texas as a way to compensate for needing to upgrade a transmission line to a small town (Presidio). *It would have been more expensive to string a new transmission line capable of supplying the town with electricity during peak use, so what they are doing instead is storing power in the battery during non-peak time and then drawing power from it during peak time. =========== http://www.smartplanet.com/blog/thin...tteries-pack-m... Presidio, Texas, a border town of under 5,000 people in the Rio Grande Valley, recently had a 4 megawatt battery installed by Electric Transmission Texas to improve service. It cost $25 million and was bigger than a house. The Big Ol’ Battery (BOB) is dwarfed by Fairbanks’ Battery Energy Storage System (BESS), installed by ABB Group in 2003. BESS can hold a charge of 26 Megawatts for up to 15 minutes and is used to back up the local grid. The two batteries are quite different. BOB uses sodium and sulfur. BESS is nickel-cadmium. But what Don Sadoway of MIT has discovered is that if your metal is molten, it can hold a lot more power in a lot less space. Sadoway says his battery costs less than lithium, and holds a charge for a longer period of time. A battery the size of a shipping container would carry 1 megawatt for several hours. The design is relatively simple. Melted magnesium at the top, melted antimony at the bottom, and a salt composed of both elements in the middle. The salt breaks down as the battery is charged, then rebuilds as electrons are discharged. Sadoway, who recently turned 60, said his inspiration was the way aluminum is coaxed from bauxite by being melted using electricity. For his birthday he’s getting a symposium in his honor this June. Sadoway is a University of Toronto alumnus. (Go True Blue.) While the Sadoway battery is impressive, it really illustrates how far research must travel to make a smart grid a reality. Renewable power is not reliable — clouds obscure the sun, and sometimes the wind doesn’t blow. Power demand also fluctuates. Better, more powerful, and cheaper batteries are needed to match supply with demand. Sadoway’s battery is one small step down a long, long road. It’s an interesting technique, but it’s probably not our final answer. The man is clearly mentally deranged. |
#29
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What about a national battery?
On 11/18/2011 4:20 AM, HeyBub wrote:
.... only 5 billion tons of lead. The US has 7 million tons of lead reserves, while the entire world has approximately 80 million tons. We'd better get busy looking for more. Chinese toys might be a good place to start... Or all that lead paint had to be good for something besides hazardous landfill material/employment. -- |
#30
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What about a national battery?
On Fri, 18 Nov 2011 04:20:26 -0600, "HeyBub"
wrote: That is, a battery that could supply the nation's electrical needs for a few days during a blackout. Good idea. We could put it in the northern half of Manitoba, which isn't used anyhow. We could run the cables when they put in that new pipeline. The author computes it could be done with a sufficiently large, or sufficiently numerous, lead-acid batteries. The whole shebang would need only 5 billion tons of lead. The US has 7 million tons of lead reserves, while the entire world has approximately 80 million tons. We'd better get busy looking for more. Chinese toys might be a good place to start... (Caution: Real maths in use) http://physics.ucsd.edu/do-the-math/...sized-battery/ |
#31
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What about a national battery?
I hadn't noticed that. Well, back to the drawing board.
Unless you want to put batteries in everyone's homes? -- Christopher A. Young Learn more about Jesus www.lds.org .. wrote in message ... This is a great exercise in math but virtually all blackouts are in the distribution system, not in the generation system. If you can't get the power from the generators to the consumer, you can't get the power from a battery to the consumer. |
#32
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What about a national battery?
Don't need batteries -- use a spinning flywheel connected to a
motor/generator for the energy storage. Then all you need is mass. Make the flywheel out of steel or even concrete or stone. Make lots of them, put them everywhere and you have a simple, low cost energy storage system with unlimited capacity. Tomsic "Stormin Mormon" wrote in message ... I hadn't noticed that. Well, back to the drawing board. Unless you want to put batteries in everyone's homes? -- Christopher A. Young Learn more about Jesus www.lds.org . wrote in message ... This is a great exercise in math but virtually all blackouts are in the distribution system, not in the generation system. If you can't get the power from the generators to the consumer, you can't get the power from a battery to the consumer. |
#33
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What about a national battery?
On 11/18/2011 1:56 PM, Tomsic wrote:
Don't need batteries -- use a spinning flywheel connected to a motor/generator for the energy storage. Then all you need is mass. Make the flywheel out of steel or even concrete or stone. Make lots of them, put them everywhere and you have a simple, low cost energy storage system with unlimited capacity. Tomsic When I was out in the Pacific at a missile range, some of the computer systems on one island had backup power that utilized flywheels. I never got a look at them and don't know for how long the motor generator units were able to provide power to the systems but they had been around for years. Of course all the primary power was supplied by big EMD diesel generators at the power house. TDD |
#34
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What about a national battery?
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#35
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What about a national battery?
On Nov 18, 4:13*pm, Han wrote:
wrote : On Fri, 18 Nov 2011 14:56:25 -0500, "Tomsic" wrote: Don't need batteries -- use a spinning flywheel connected to a motor/generator for the energy storage. *Then all you need is mass. Make the flywheel out of steel or even concrete or stone. *Make lots of them, put them everywhere and you have a simple, low cost energy storage system with unlimited capacity. The traditional storage method is pumped water. You fill up a lake at the top of the hill and run it through a turbine when you want the energy back. The advantage is, rainfall gives you free energy. I believe there are a few of those pumped storage hydroelectric systems http://en.wikipedia.org/wiki/Pumped-storage_hydroelectricity The enormous losses during pumping and regeneration seem to make this very inefficient but apparently the differences between off-peak and peak rates can make it economical. *Not relly useful for individuals or small coomunities, I'd think. The flywheel seems practical, but of course the amounts of energy stored may make the system rather dangerous when (not if) it malfunctions. *I've seen the damage when ultracentrifuges go poof, and that was really very little mass. -- Best regards Han email address is invalid I'm thinking sabotage could be pretty ugly, too. nate |
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What about a national battery?
Han wrote:
The flywheel seems practical, but of course the amounts of energy stored may make the system rather dangerous when (not if) it malfunctions. I've seen the damage when ultracentrifuges go poof, and that was really very little mass. The energy stored in a flywheel depends on: a) Its mass, and b) Its velocity. You could replicate the energy stored in a ultracentrifuge with a sixty-ton flywheel moving at 2 r.p.m. I recall busses in Switzerland running off of flywheels. When it got to the end of the line, a worker would run up to the back with a motorized probe and "re-fuel" the flywheel. Took about five minutes. The bus was then good to go on its route. |
#37
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What about a national battery?
On Fri, 18 Nov 2011 16:48:46 -0600, "HeyBub" wrote:
Han wrote: The flywheel seems practical, but of course the amounts of energy stored may make the system rather dangerous when (not if) it malfunctions. I've seen the damage when ultracentrifuges go poof, and that was really very little mass. The energy stored in a flywheel depends on: a) Its mass, and b) Its velocity. Actually, it's (1/2) mass * velocity squared. You could replicate the energy stored in a ultracentrifuge with a sixty-ton flywheel moving at 2 r.p.m. True, but that "squared" term matters. I recall busses in Switzerland running off of flywheels. When it got to the end of the line, a worker would run up to the back with a motorized probe and "re-fuel" the flywheel. Took about five minutes. The bus was then good to go on its route. I'd like to see a citation for that. |
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