Okay, I am posting this mostly as a rant. I'm really getting pissed about all the anti-nuclear crap out there. I'm very pro nuclear energy and I'm in need of spouting off, so here goes.
I hate it when “environmentalists” stomp on everything nuclear. It’s ridiculous, because the reason I like…make that love… nuclear energy is it’s environmental benfiits.
We have a problem: Energy. Actually it's always been a problem, and often the limiting factor in human endeavors. Right now, most of the electricity in the world is being generated by burning fossil fuels. Cars are also powered by fossil fuels, and ideas like electric or hydrogen cars don't help all that much if the energy comes from... burning something.
The problems, obviously are supply, co2 emissions, costs, other environmental problems ect...
Now first of all, lets get a couple of things out of the way.
In regards to wind power, solar power, tidal power and so on.
I'm completely in favor of using renewable natural energy sources where avaliable, but the fact is that it's just not realistic to expect these to be able to do anything more than provide a small portion of total energy needs.
Solar energy is free, but the cells sure aren't. And the fact is that it is never really economical or realistic because of the amount of space needed to generate a given amount of electricity. The energy carried by light over a given area is not that large. It may amount to 80 to 90 watts per square meter, at the most. (that's in a desert, at noon, in the summer). Solar cells are currently about 25% efficient with new designs promising 40%, and due to the nature of light conversion, it's not really a realistic expectation to have better than 50% effecient solar cells.
If you do the math you'll find that most temperate places can expect something on the order of 100-230 kilowatt hours per square meter per year for solar cells, under ideal conditions. That does not count power conversion or battery tending or anything. Considering the amount of power used...well... it just ain't in the cards.
Wind energy is somewhat better, but not all locations are suitable for wind power and of those suited, the real estate required is very large. The maintenance on the turbines is not huge, but it is enough to make it more expensive than most other forms of electricity. Furthermore, it has the habbit of changing based on whims. If you have a coal fired power plant you can turn up the boiler when power is needed. Wind energy, like many other renewable, is based on nature. Thus, if a high demand day happens during a stalled high pressure system... well thats just no good.
And the fact is that we (humanity) needs energy. And lots of it
Energy efficiency and conservation is great, but it can only get you so far. Despite all the efforts toward energy star appliances, efficient lighting, hybrid cars and so on, energy consumption has never gone down. All these efforts have been able to do is reduce the rate at which it has gone up. It’s not realistic at all to expect that conservation could dramatically reduce overall power needs any time soon.
And people will not give up their air conditioners and big screen tv’s. Sorry to break it to everyone, but making the population reduce their standard of living voluntarily for a non-immediate goal doesn’t sell well, and the economic consequences aren’t fun either.
So what do we really need? A reliable, economical, practical, doable source of energy that can produce lots of it in a reasonably small area (as in a power plant).
And right now the only energy source that fits the bill is nuclear energy. We have the fuel, it’s not hard to make. The technology exists. It can be done. It is being done. It may have some shortcomings, but they are not unsolvable problems.
So lets address the two problems that so-called environmentalists like to point to.
First, safety-
Nuclear energy is safe. It’s damn safe. I have no problem living near a plant and I would have no problem working at one. The US has an impeccable record of nuclear safety, with no deaths ever resulting from commercial nuclear energy, no major incidents and the only deaths associated with nuclear energy directly go back to the 1950’s, when reactor design was very hit or miss.
We even have thousands of people living within feet of reactors… in sealed vessels… emerced under thousands of feet of salt water!
”But what about three mile island???” Well I’ll address that with this: Three Mile Island was a disaster… for public relations. And the utility company will need to spend a lot of money cleaning it up… from within the containment dome. Which is containing it!
Nobody died in the incident and safeguards have been instituted since then. Noone was ever in any real danger. Some of the newer designs for reactors are much safer than the ones currently in use. But today, thanks to environmentalists, all the reactors in service are vintage 1960-70’s.
And Chernobyl? A perfect example of why safety systems are necessary. Chernobyl had a graphite-core design which had not been used in the west since the 1940’s, due to the inherent safety problems. There was no containment dome. The reactor was massive and an admittedly flawed design. It was run improperly and the safety systems were manually overridden during a non-standard “turbine rundown test.”
There is no reason why Chernobyle had to happen and such an event is not a concern with modern pressurized water reactors.
Next waste-
Nuclear reactors produce waste. Radioactive waste. This is a problem, but it does not lack solutions. The current trend is toward long-term burial, such as at Yucca mountain.
There are other methods however, which were outlawed during the Carter Administration, due to pressure from “environmental” groups. Despite the lack of US research, they have been developed further elsewhere. These include.
1. Reprocessing – Extracts the usable fuel of both uranium and long-lived plutonium and other heavy elements. This can be reused in reactors and the remaining fission products are much smaller in volume and do not pose as great a long term risk, requiring only 500 years or less to decay to safe levels. While this may sound like a long time, it is far less than the times for standard spent fuel.
2. The use of advanced fast-neutron breeder designs can reduce waste to lower levels which can be disposed of more safely and will be of low radioactivity in 300 years or less. This is a relatively short time, geologically speaking.
3. Photo-neutron transmutation. Without getting too far into this, it basically involves an accelerator which can be used to break down nuclear waste to harmless intert material. The accelerator takes a lot of energy, however the process can also produce energy if the heat produced by the reaction is tapped. A one megawatt accelerator, for example, could produce ten megawatts of usable electricity, through the decay process of short-lived isotopes.
I forget who said it, but one of my favorite quotes was (to paraphrase) that nuclear energy has risks. But they are small, manageable and acceptable risks. Global warming, however, is a totally unacceptable risks.
So what do I propose?
1. A renewed policy for electrical generation with a focus on nuclear energy
2. Standardization and streamlining of reactor design and construction – rather than designing every faculty independently and going through the regulatory, safety and approval processes completely each time, create several standard modular reactor designs. Take into account the newest and most promising technologies, such as sub-critical reactors, thorium breeders, heavy water moderated, liquid metal cooled etc. Create designs. Test them thoroughly and then start building.
Take the example of aircraft. The 747 was first flown in 1969. They still build them, although numerous improvements and modifications have been made to the design. Imagine if each and every aircraft order was designed from the ground up and tested and approved independently. The cost would be enormous.
3. Construction of several large nuclear energy facilities across the country. Each should produce at least a few gigawatts of electiricty. This is because it is much more efficient to have fewer larger facilities than many smaller ones. This way reprocessing and containment technologies can be implemented on site and safety measures can be deployed at fewer sites.
4. Each site should not be a single power plant, but rather have multiple reactors and turbine/generators. This allows for continued operations during refueling or maintenance as well as reduces the severity of a (highly unlikely) accident. Should a breach of some sort occur, the scale will be limited and not effect physically separate units.
5. Disposal of waste based on advanced reprocessing and the use of fast-neutron reactors and accelerator-driven transmutation.
What it boils down to is this: You can go nuclear. You can do it right. And you can achieve a very safe and plentiful energy supply. However, to some degree it’s all or nothing. You can’t build a few plants and not have the proper disposal infrastructure and closed-system reprocessing systems.
Not taking this technology to it’s full potential does not make sense. As research continues toward fusion or other technologies for the future, we need to recognize that we have the technology for clean energy NOW. It’s all been done. It can be done. It should be done.
Wind farms and solar cells are great, and I encourage that they be used wherever they can be. But they just can’t cut it for major electrical needs.
If energy can be generated cleanly, cheaply and in large enough amounts, the possibilities are almost endless. Desalination of massive amounts of water for agriculture or drinking. Treatment of waste. The destruction of nearly any chemical waste by reducing it to the elemental components. Massive heating and cooling. Transportation and manufacturing. Food production in huge greenhouses and under sunlamps.
It’s all possible with enough energy.
I hate it when “environmentalists” stomp on everything nuclear. It’s ridiculous, because the reason I like…make that love… nuclear energy is it’s environmental benfiits.
We have a problem: Energy. Actually it's always been a problem, and often the limiting factor in human endeavors. Right now, most of the electricity in the world is being generated by burning fossil fuels. Cars are also powered by fossil fuels, and ideas like electric or hydrogen cars don't help all that much if the energy comes from... burning something.
The problems, obviously are supply, co2 emissions, costs, other environmental problems ect...
Now first of all, lets get a couple of things out of the way.
In regards to wind power, solar power, tidal power and so on.
I'm completely in favor of using renewable natural energy sources where avaliable, but the fact is that it's just not realistic to expect these to be able to do anything more than provide a small portion of total energy needs.
Solar energy is free, but the cells sure aren't. And the fact is that it is never really economical or realistic because of the amount of space needed to generate a given amount of electricity. The energy carried by light over a given area is not that large. It may amount to 80 to 90 watts per square meter, at the most. (that's in a desert, at noon, in the summer). Solar cells are currently about 25% efficient with new designs promising 40%, and due to the nature of light conversion, it's not really a realistic expectation to have better than 50% effecient solar cells.
If you do the math you'll find that most temperate places can expect something on the order of 100-230 kilowatt hours per square meter per year for solar cells, under ideal conditions. That does not count power conversion or battery tending or anything. Considering the amount of power used...well... it just ain't in the cards.
Wind energy is somewhat better, but not all locations are suitable for wind power and of those suited, the real estate required is very large. The maintenance on the turbines is not huge, but it is enough to make it more expensive than most other forms of electricity. Furthermore, it has the habbit of changing based on whims. If you have a coal fired power plant you can turn up the boiler when power is needed. Wind energy, like many other renewable, is based on nature. Thus, if a high demand day happens during a stalled high pressure system... well thats just no good.
And the fact is that we (humanity) needs energy. And lots of it
Energy efficiency and conservation is great, but it can only get you so far. Despite all the efforts toward energy star appliances, efficient lighting, hybrid cars and so on, energy consumption has never gone down. All these efforts have been able to do is reduce the rate at which it has gone up. It’s not realistic at all to expect that conservation could dramatically reduce overall power needs any time soon.
And people will not give up their air conditioners and big screen tv’s. Sorry to break it to everyone, but making the population reduce their standard of living voluntarily for a non-immediate goal doesn’t sell well, and the economic consequences aren’t fun either.
So what do we really need? A reliable, economical, practical, doable source of energy that can produce lots of it in a reasonably small area (as in a power plant).
And right now the only energy source that fits the bill is nuclear energy. We have the fuel, it’s not hard to make. The technology exists. It can be done. It is being done. It may have some shortcomings, but they are not unsolvable problems.
So lets address the two problems that so-called environmentalists like to point to.
First, safety-
Nuclear energy is safe. It’s damn safe. I have no problem living near a plant and I would have no problem working at one. The US has an impeccable record of nuclear safety, with no deaths ever resulting from commercial nuclear energy, no major incidents and the only deaths associated with nuclear energy directly go back to the 1950’s, when reactor design was very hit or miss.
We even have thousands of people living within feet of reactors… in sealed vessels… emerced under thousands of feet of salt water!
”But what about three mile island???” Well I’ll address that with this: Three Mile Island was a disaster… for public relations. And the utility company will need to spend a lot of money cleaning it up… from within the containment dome. Which is containing it!
Nobody died in the incident and safeguards have been instituted since then. Noone was ever in any real danger. Some of the newer designs for reactors are much safer than the ones currently in use. But today, thanks to environmentalists, all the reactors in service are vintage 1960-70’s.
And Chernobyl? A perfect example of why safety systems are necessary. Chernobyl had a graphite-core design which had not been used in the west since the 1940’s, due to the inherent safety problems. There was no containment dome. The reactor was massive and an admittedly flawed design. It was run improperly and the safety systems were manually overridden during a non-standard “turbine rundown test.”
There is no reason why Chernobyle had to happen and such an event is not a concern with modern pressurized water reactors.
Next waste-
Nuclear reactors produce waste. Radioactive waste. This is a problem, but it does not lack solutions. The current trend is toward long-term burial, such as at Yucca mountain.
There are other methods however, which were outlawed during the Carter Administration, due to pressure from “environmental” groups. Despite the lack of US research, they have been developed further elsewhere. These include.
1. Reprocessing – Extracts the usable fuel of both uranium and long-lived plutonium and other heavy elements. This can be reused in reactors and the remaining fission products are much smaller in volume and do not pose as great a long term risk, requiring only 500 years or less to decay to safe levels. While this may sound like a long time, it is far less than the times for standard spent fuel.
2. The use of advanced fast-neutron breeder designs can reduce waste to lower levels which can be disposed of more safely and will be of low radioactivity in 300 years or less. This is a relatively short time, geologically speaking.
3. Photo-neutron transmutation. Without getting too far into this, it basically involves an accelerator which can be used to break down nuclear waste to harmless intert material. The accelerator takes a lot of energy, however the process can also produce energy if the heat produced by the reaction is tapped. A one megawatt accelerator, for example, could produce ten megawatts of usable electricity, through the decay process of short-lived isotopes.
I forget who said it, but one of my favorite quotes was (to paraphrase) that nuclear energy has risks. But they are small, manageable and acceptable risks. Global warming, however, is a totally unacceptable risks.
So what do I propose?
1. A renewed policy for electrical generation with a focus on nuclear energy
2. Standardization and streamlining of reactor design and construction – rather than designing every faculty independently and going through the regulatory, safety and approval processes completely each time, create several standard modular reactor designs. Take into account the newest and most promising technologies, such as sub-critical reactors, thorium breeders, heavy water moderated, liquid metal cooled etc. Create designs. Test them thoroughly and then start building.
Take the example of aircraft. The 747 was first flown in 1969. They still build them, although numerous improvements and modifications have been made to the design. Imagine if each and every aircraft order was designed from the ground up and tested and approved independently. The cost would be enormous.
3. Construction of several large nuclear energy facilities across the country. Each should produce at least a few gigawatts of electiricty. This is because it is much more efficient to have fewer larger facilities than many smaller ones. This way reprocessing and containment technologies can be implemented on site and safety measures can be deployed at fewer sites.
4. Each site should not be a single power plant, but rather have multiple reactors and turbine/generators. This allows for continued operations during refueling or maintenance as well as reduces the severity of a (highly unlikely) accident. Should a breach of some sort occur, the scale will be limited and not effect physically separate units.
5. Disposal of waste based on advanced reprocessing and the use of fast-neutron reactors and accelerator-driven transmutation.
What it boils down to is this: You can go nuclear. You can do it right. And you can achieve a very safe and plentiful energy supply. However, to some degree it’s all or nothing. You can’t build a few plants and not have the proper disposal infrastructure and closed-system reprocessing systems.
Not taking this technology to it’s full potential does not make sense. As research continues toward fusion or other technologies for the future, we need to recognize that we have the technology for clean energy NOW. It’s all been done. It can be done. It should be done.
Wind farms and solar cells are great, and I encourage that they be used wherever they can be. But they just can’t cut it for major electrical needs.
If energy can be generated cleanly, cheaply and in large enough amounts, the possibilities are almost endless. Desalination of massive amounts of water for agriculture or drinking. Treatment of waste. The destruction of nearly any chemical waste by reducing it to the elemental components. Massive heating and cooling. Transportation and manufacturing. Food production in huge greenhouses and under sunlamps.
It’s all possible with enough energy.
