Nuclear Power & Politics - Is Sustainable Living Debatable?

Neither McCain nor Obama oppose nuclear power, their differences of opinion aren't on the background facts of nuclear power, but on impact on the environment. McCain focuses on an aggressive expansion of nuclear power plants, while Obama focuses nuclear power playing a only a part of the overall energy portfolio.

McCain is campaigning for "cheap, clean, secure energy for America" and the need to "transform electricity" through nuclear power. Nuclear power is a proven, reliable, zero-emission source of energy, and he is campaigning that it is time to recommit to advancing our use of nuclear power. McCain also supports the idea that nuclear power is a major contender in climate control.

Obama on the other hand, is adamant about the fact that nuclear energy is not optimal. He has stated that, "there are no silver bullet solutions to our energy crises. Our economy, security and environment will be best served through a sustained effort to diversify our energy sources." Obama has not ruled nuclear power out, but only as long as its clean and safe.

The researchers at Paradise Earth decided to take a closer look at the impact that nuclear power generation will have on, not only our economy, but also our environment. How would constructing these nuclear power plants benefit our troubled nation?

• Nuclear power technology is already in the works and operating throughout the world, so an investment in research and development won't be necessary.
• Nuclear power generation emits somewhat low levels of carbon dioxide; the contribution of nuclear power plants to global warming is minimal.
• One single plant can produce high levels of electrical energy.

But at what cost?

• Radioactive waste is still an unsolved problem. The waste from nuclear energy is extremely dangerous and it has to be carefully looked after for several thousand years (10,000 years according to United States Environmental Protection Agency standards). And what happens if nuclear waste falls into the wrong hands?
• Despite extremely high security standards, it is technically impossible to build a facility that is 100% secure and accidents can still happen. The consequences of an accident would be absolutely devastating both for human beings as for the environment. The more nuclear power plants (and nuclear waste storage shelters) that are built, the higher the probability of a disastrous failure (and/or terrorist attack) somewhere in the world.
• The energy source for nuclear energy is Uranium, which is a scarce resource; its supply is estimated to last only for the next 30 to 60 years depending on the actual demand.

It is equally important to look seriously at sustainability; is nuclear energy sustainable? For several reasons, nuclear power is neither {green} nor sustainable:

• Both nuclear waste and retired nuclear plants are a life-threatening legacy for future generations. Sustainability is blatantly contradicted if generations to come have to deal with dangerous waste generated from preceding generations.
• Uranium, the source of energy for nuclear power, is available on earth only in limited quantities. Uranium is being consumed during the operation of the nuclear power plant so it won't be available any more for future generations. This again contradicts the principle of sustainability.

The debate over nuclear power plants has been going on for decades, worldwide. Politicians, activists, environmentalists and the average citizen cannot longer turn a blind eye to the consequences of our existence on Planet Earth. Our future and the survival of our natural resourcesdepend solely on our ability to support sustainable living.

For more information on how to save our natural resources visit Paradise Earth online

Nuclear Power - Not a Renewable Energy Resource and It's Not Green

There is quite a bit of talk about nuclear power as it is being touted as a clean reliable energy source. It is actually put on par with solutions to our power needs like solar and wind power. I beg to differ. The nuclear power industry is getting as old as I am! Nuclear plant owners are trying to see if they may be able to capitalize on these developments. They are doing retrofits and upgrades in every plant they can in order to spruce themselves up for the unwary public.

The problem as I stated earlier is the age of the nuclear plants currently in existence. Around 40 percent of U.S. nuclear power stations are over 30 years old. More than 90 percent of all plants in the U.S. are over 20 years old. Well, you might say, so what? If they are working out, then let's use them. Therein lies the rub. Nuclear power plants are built using reinforced concrete and structural steel , with concrete having the higher numbers in so far as materials used are concerned.

Over time the materials used to build a plant start to corrode and develop cracks (known as stress corrosion cracking [SCC]) because of age and exposure to radiation. If you consider steam turbines then the blade attachment areas and disc bores of low pressure turbine rotors are in danger of SCC.

The owners of some plants want to replace low pressure steam paths with higher pressure steam flow equipment. This theoretically could result in higher output. The emphasis on theoretically is mine. I have worked in the nuclear power industry as an engineer and one thing is certain, and that is nothing is certain. It is hoped that this solution will address reliability issues with these existing steam turbines.

The retrofit that most are opting for would include installing new low pressure rotors, rotating and stationary blades, inner casings and blade carriers. The scope of this type of retrofit would be large and costly. They would have to install or replace: high efficiency, integrally shrouded, reaction type blading for their front stages; longer last stage rotating blades to reduce the energy content of the steam leaving the turbine, thereby increasing turbine output; provide consistent and predictable vibration characteristics, snubbers at three quarter height will need to interconnect the last stage rotating blades and the second to last stage blades will need to be linked by integral tip shrouding; provide reduced stage leakage due to better sealing and reaction characteristics over the length of the blade; and select materials to provide erosion corrosion characteristics.

These upgrades are not all that would need to be done, and I include them here to show the complexity of this proposed fix of the aging nuclear power plants. This is not to confuse the layman but merely to show that this undertaking would be of immense scope and would cost millions of dollars. Dollars perhaps better spent pursuing alternative energy in the form of renewable energy resources.

The owners of some of these plants are saying that by the low carbon output (i.e. lower CO2 which has been shown to cause global warming) and possible gains in capacity, they could in some cases identify around 350MW of electricity increase by 2014.

I don't want to give the impression that nuclear power should be abandoned, I am a scientist and I would not make rash statements like this without some sort of research. It is simply obvious that we are already paying a very high price for electricity generated by nuclear power. The cost alone would be enough to deter some, and there is still the question of safety. Obviously we have not mastered nuclear power to the point that we can claim that it is 100 percent safe. The byproduct of nuclear power or it's waste is weapons grade plutonium. That is enough to make me question the sanity of utilizing this option. There has never been a permanent solution for the question of waste storage.

There would certainly be a decrease of carbon dioxide emissions if we pursue this course, however is that enough? We have the technology for several different course to pursue. The carbon dioxide emission problem would simply cease to exist with renewable energy resources generating our electricity. The money needed for this option is not available, but if we can spend so recklessly on nuclear power, could we not use the same funds for sustainable and renewable energy sources?

I am saddened to say that in some cases utility operators, owners of the aging nuclear plant system would not invest in installing new power transmission lines to enable more wind turbine or solar power systems. Too costly, and not part of the scope of their work. This from the people selling us our electric power. My bills have increased over the past year by 20 percent. My income certainly did not increase by anywhere near that amount.

We should at least look at this problem and lobby our elected officials to make a stand for the sake of all Americans, for the sake of the people of earth in general. The utility companies work for you and me, write to them, we are their customers. We should at least try.

Why don't we investigate wind power or solar power, there would be costs, but that is another article altogether. Just bear in mind that nuclear power is not renewable or sustainable.

I am an engineer, artist, writer, single father and a gourmet cook, I have extensive life experience covering a wide variety of topics. I have traveled extensively in the U.S. and I know many areas well. I am a teacher at times, as well as a mentor. I have written extensively about many subjects and decided I would like to try and bring about change in certain areas such as, alternative energy, single parenting and other topics that are concerns for the residents of this planet. I am well versed in the marketing of products and ideas. I want to help make the world a better place than it was when I arrived here

High Costs, Waste Issues Stall Nuclear Renaissance

Depending upon which side of the fence you are sitting, the nuclear renaissance is either in full blossom or an arid landscape. The new uranium miners - Paladin Resources, UrAsia and SXR Uranium One - celebrate the record spot and long-term uranium price. Exelon Corp Chief Executive John Rowe is less sanguine, based upon comments he made this past Friday, "The government may have fooled me on 17 reactors that I currently run, but I'm the one who's being foolish if I build a new plant without knowing what they're going to do with the spent fuel." Exelon is the largest owner of nuclear power plants in the United States.

In a September 19th article, we interviewed Steven Kraft, Nuclear Energy Institute Director for Used Fuel Management. Mr. Kraft hinted the stalls around the nuclear renaissance in the United States would revolve around the spent fuel depository issue. What happens with the 40,000 metric tons of used nuclear reactor fuel? Right now, they are chilling out in 141 concrete cooling ponds scattered around the country.

For the past quarter century, the nuclear industry expected the reactor fuel would end up in a centralized depository, as has been proposed at Yucca Mountain, Nevada. Thanks to U.S. Senator Reid, and his efforts to squash this site, the Department of Energy has been paralyzed in moving forward. Alternatives are now being proposed, and the U.S. part of the nuclear renaissance remains stalled.

Then the other shoe drops. Because of the vociferous environmental lobbyists, pre-construction costs dissuade nuclear utilities from accelerating their plans to build new nuclear reactors in the United States. Utilities do what is convenient - they pass on these licensing costs to their utility consumers. Because of the environmental lobby, Georgia electricity consumers are paying the freight to license the new nuclear reactors proposed by Atlanta-based Southern Co. Charlotte-based Duke Energy hopes to get the same deal in North Carolina.

How much does it cost to license a nuclear power plant? Standard & Poors analyst Dimitri Nikas estimated the permits to construct a nuclear plant would cost between $1.5 billion and $2 billion. This means roughly one-half the cost of constructing a nuclear plant in the United States goes to pay for a permit to build and operate the reactor.

Because of this expensive proposition, nuclear energy costs more to produce electricity in the United States than it would in places like China, Korea, Japan or just about anywhere else. For a nuclear plant costing $2 million per megawatt to build, the power plant's electricity would cost $55 per megawatt hour. By comparison, a coal-fired power plant costs consumers $53 per megawatt hour for their electricity. A combined cycle integrated gasification plant fueled by coal produces electricity for $50 per megawatt hour.

On the bright side, the S&P analyst believes that after the first wave of nuclear power plant construction, overall costs could plunge to $1.5 million per megawatt hour for electricity, or roughly $44 per megawatt hour. Because of this drop Mr. Niklas concluded nuclear energy "is by far the most competitive cost from any resource, except perhaps hydroelectricity generation." This is more good news for uranium miners now supplying the nuclear industry and those who hope to do so over the next decade.

The question facing most Americans - and we would guess 99 percent haven't the slightest clue about this problem - is whether or not they would prefer losing the nuclear option as part of their electricity generation. The environmental lobby would cheer the loss but the utility consumer would lose up to 20 percent of their baseload electricity generation. And on a darker note, the alternative would be more coal-fired power plants - not wind or solar power, which are still more than one decade away from offering any sort of hope for baseload electricity generation.

To put this into perspective, coal now generates 54 percent of America's electricity. One pound of coal produces 1.25 kilowatt hours of electricity, enough to power one 100-watt light bulb for 10 hours. The average internet user consumes more than his body weight in coal just to surf the net: 12 hours weekly over the course of one year consumes 300 pounds of coal. (For example, the electricity consumed to order StockInterview's "Investing in the Great Uranium Bull Market," would burn up one lump of coal.) Total demand for electricity by personal computers now amounts to 8 percent of the U.S. electrical supply. In the future, over one billion people will be accessing the Internet. This amount of computer time would be equal to the total 'current' capacity of U.S. electrical production.

If the U.S. nuclear renaissance doesn't get launched, we will either be accessing the Internet by polluting our environment with several hundred additional millions of tons of CO2 emissions, or the Internet users will suffer. Wind and solar won't power the Internet, but coal, gas and especially nuclear will.

And at this stage of the uranium renaissance, U.S. utilities have contracted with three non-U.S. uranium mining companies - Paladin, SXR Uranium One and UrAsia - to purchase uranium mined in Namibia, South Africa and Kazakhstan. Where is the energy independence in that observation? Next we'll be buying our electricity from the Russians, Chinese, and quite possibly the Iranians, if this nonsense continues. Please bring this to the attention of your local environmental lobbying office.

COPYRIGHT © 2007 by StockInterview, Inc. ALL RIGHTS RESERVED.

James Finch contributes to StockInterview.com and other publications. StockInterview’s “Investing in the Great Uranium Bull Market” has become the most popular book ever published for uranium mining stock investors. Visit [http://www.stockinterview.com]

Construction's Nuclear Future

With the UK's oil and gas reserves in decline, coal increasingly viewed as a dirty fuel and many power stations coming to the end of their natural life, there's a danger that the country's lights might start to go out. A lot of emphasis has been put on wind power but this is notoriously unreliable and requires an alternative power supply when the wind doesn't blow. As a result, nuclear power is now the favoured option for much of the UK's future power supply.

The country has had a thriving nuclear industry since the 1950s when Calder hall in Cumbria came on stream as the first commercial nuclear power station. Since then, many plants have been developed but those built since the 1960s are at, or approaching, the end of their useful lives. In order to prevent a future shortfall in energy supplies, the Labour government announced in 2008 that it was in the public interest for nuclear power to play a role in the future energy mix. The coalition government has since reiterated its commitment to nuclear power.

The Next Generation...

Although the government is not directly involved in the financing or building of new nuclear plants, it is developing policies and frameworks to enable them to go ahead. It is encouraging private utility companies to construct the UK's next generation of nuclear power stations and these companies have committed to the development of some £40 billion of new nuclear plant facilities.

At present, three consortia are involved in the development of new nuclear power stations:

• EDF Energy purchased British Energy in 2009 and has an 80/20 joint venture with Centrica. It is building two 1600 MW reactors at Hinkley Point and a further two of the same size at Sizewell. The first is due to be operating by 2017 and all four by 2025. These are to replace Hinkley Point B, which is due to close in 2016, and Hinkley Point A that closed in 2000 after 35 years service. Further plants are planned once the first phase is complete.
• Horizon Nuclear Power, a joint venture between E.ON and RWE npower, expects to have 6 GW of new capacity operating by 2025, with sites in Anglesey and Gloucestershire. It is due to decide on the technology shortly and have its first plant operating by 2019. E.ON and RWE currently operate three nuclear power stations in Germany and have interests in 17 others worldwide.
• NuGeneration Ltd (a consortium comprising Iberdrola, Scottish & Southern Energy and GDF Suez) has acquired land at Sellafield and plans to build 3.6 GW of nuclear capacity there. The reactor technology to be used has yet to be decided.

All the new planned power stations are to use existing technology. The choice at present is between the Westinghouse AP1000 and EPR from Franco-German company AREVA. Both types are in use throughout the world, with the latter being prevalent in France, which obtains 80% of its energy from nuclear power.

The new plants are generally being built close to existing nuclear power stations. The reasons for this include them being already connected to the national grid and having large water supplies for cooling. In addition, the local communities are used to nuclear plants, depend on them for employment, and are less likely to object to new developments.

The first plants are due to start operating in late 2017 or early 2018, with a new station then coming online every 18-24 months for many years after that. Preparation work is already underway, with EDF Energy having submitted a planning application to begin preliminary work at Hinkley Point.

Prospects for Construction Companies and Employees...

Orders for plant and services are likely to develop from 2012-2013, giving huge opportunities for construction companies to get involved. Around 80% of the building work is reckoned to be non-nuclear specific and so can be handled on the same lines as any construction project. Companies that get involved early are likely to have the chance for further contracts for many years into the future.

Having originally been a world leader in building nuclear power stations, the UK now has internationally recognised expertise in cleaning up and decommissioning nuclear sites. With the next generation of development now due to begin, there is the possibility that the country may again be at the forefront. This could ultimately lead to export opportunities as other countries turn to nuclear power, with an estimated 400 reactors expected to be built worldwide in coming years.

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Paul James

Economics Of Nuclear Technology

The Economics of Nuclear Power

Electricity Generation
Nuclear Technology can also be used to produce ELECTRICITY which is very important according to economical condition of a country. Nuclear plant can produce more electricity than thermal or hydro electric plant.
Isotope produced using Nuclear Technology is used in many chemical and pharma companies.

1)Nuclear power is cost competitive with other forms of electricity generation, except where there is direct access to low-cost fossil fuels.

2)Fuel costs for nuclear plants are a minor proportion of total generating costs, though capital costs are greater than those for coal-fired plants.

3)In assessing the cost competitiveness of nuclear energy, decommissioning and waste disposal costs are taken into account.

The relative costs of generating electricity from coal, gas and nuclear plants vary considerably depending on location. Coal is, and will probably remain, economically attractive in countries such as China, the USA and Australia with abundant and accessible domestic coal resources as long as carbon emissions are cost-free. Gas is also competitive for base-load power in many places, particularly using combined-cycle plants, though rising gas prices have removed much of the advantage.

Nuclear energy is, in many places, competitive with fossil fuel for electricity generation, despite relatively high capital costs and the need to internalise all waste disposal and decommissioning costs. If the social, health and environmental costs of fossil fuels are also taken into account, nuclear is outstanding.

External costs

The report of a major European study of the external costs of various fuel cycles, focusing on coal and nuclear, was released in mid 2001 - ExternE. It shows that in clear cash terms nuclear energy incurs about one tenth of the costs of coal. The external costs are defined as those actually incurred in relation to health and the environment and quantifiable but not built into the cost of the electricity. If these costs were in fact included, the EU price of electricity from coal would double and that from gas would increase 30%. These are without attempting to include global warming.

The European Commission launched the project in 1991 in collaboration with the US Department of Energy, and it was the first research project of its kind "to put plausible financial figures against damage resulting from different forms of electricity production for the entire EU". The methodology considers emissions, dispersion and ultimate impact. With nuclear energy the risk of accidents is factored in along with high estimates of radiological impacts from mine tailings (waste management and decommissioning being already within the cost to the consumer). Nuclear energy averages 0.4 euro cents/kWh, much the same as hydro, coal is over 4.0 cents (4.1-7.3), gas ranges 1.3-2.3 cents and only wind shows up better than nuclear, at 0.1-0.2 cents/kWh average.

Fuel costs are one area of steadily increasing efficiency and cost reduction. For instance, in Spain nuclear electricity cost has been reduced by 29% over 1995-2001. This involved boosting enrichment levels and burn-up to achieve 40% fuel cost reduction. Prospectively, a further 8% increase in burn-up will give another 5% reduction in fuel cost.

The cost of fuel

From the outset the basic attraction of nuclear energy has been its low fuel costs compared with coal, oil and gas fired plants. Uranium, however, has to be processed, enriched and fabricated into fuel elements, and about two thirds of the cost is due to enrichment and fabrication. Allowances must also be made for the management of radioactive spent fuel and the ultimate disposal of this spent fuel or the wastes separated from it.

But even with these included, the total fuel costs of a nuclear power plant in the OECD are typically about a third of those for a coal-fired plant and between a quarter and a fifth of those for a gas combined-cycle plant.

Fuel costs are one area of steadily increasing efficiency and cost reduction. For instance, in Spain nuclear electricity cost was reduced by 29% over 1995-2001. This involved boosting enrichment levels and burn-up to achieve 40% fuel cost reduction. Prospectively, a further 8% increase in burn-up will give another 5% reduction in fuel cost.

Comparing electricity generation

For nuclear power plants any cost figures normally include spent fuel management, plant decommissioning and final waste disposal. These costs, while usually external for other technologies, are internal for nuclear power.

Decommissioning costs are estimated at 9-15% of the initial capital cost of a nuclear power plant. But when discounted, they contribute only a few percent to the investment cost and even less to the generation cost. In the USA they account for 0.1-0.2 cent/kWh, which is no more than 5% of the cost of the electricity produced.

The back-end of the fuel cycle, including spent fuel storage or disposal in a waste repository, contributes up to another 10% to the overall costs per kWh, - less if there is direct disposal of spent fuel rather than reprocessing. The $18 billion US spent fuel program is funded by a 0.1 cent/kWh levy.

French figures published in 2002 show (EUR cents/kWh): nuclear 3.20, gas 3.05-4.26, coal 3.81-4.57. Nuclear is favourable because of the large, standardised plants used.
The cost of nuclear power generation has been dropping over the last decade. This is because declining fuel (including enrichment), operating and maintenance costs, while the plant concerned has been paid for, or at least is being paid off. In general the construction costs of nuclear power plants are significantly higher than for coal- or gas-fired plants because of the need to use special materials, and to incorporate sophisticated safety features and back-up control equipment. These contribute much of the nuclear generation cost, but once the plant is built the variables are minor.
In the past, long construction periods have pushed up financing costs. In Asia construction times have tended to be shorter, for instance the new-generation 1300 MWe Japanese reactors which began operating in 1996 and 1997 were built in a little over four years.

Overall, OECD studies in teh 1990s showed a decreasing advantage of nuclear over coal. This trend was largely due to a decline in fossil fuel prices in the 1980s, and easy access to low-cost, clean coal, or gas. In the 1990s gas combined-cycle technology with low fuel prices was often the lowest cost option in Europe and North America. But the picture is changing.

Future cost competitiveness

The OECD does not expect investment costs in new nuclear generating plants to rise, as advanced reactor designs become standardised.
The future competitiveness of nuclear power will depend substantially on the additional costs which may accrue to coal generating plants. It is uncertain how the real costs of meeting targets for reducing sulphur dioxide and greenhouse gas emissions will be attributed to fossil fuel plants.
Overall, and under current regulatory measures, the OECD expects nuclear to remain economically competitive with fossil fuel generation, except in regions where there is direct access to low cost fossil fuels.

In Australia, for example, coal-fired generating plants are close to both the mines supplying them and the main population centres, and large volumes of gas are available on low cost, long-term contracts.

A 1998 OECD comparative study showed that at a 5% discount rate, in 7 of 13 countries considering nuclear energy, it would be the preferred choice for new base-load capacity commissioned by 2010 (see Table below). At a 10% discount rate the advantage over coal would be maintained in only France, Russia and China.

FACTORS FAVOURING URANIUM
Uranium has the advantage of being a highly concentrated source of energy which is easily and cheaply transportable. The quantities needed are very much less than for coal or oil. One kilogram of natural uranium will yield about 20,000 times as much energy as the same amount of coal. It is therefore intrinsically a very portable and tradeable commodity.
The fuel's contribution to the overall cost of the electricity produced is relatively small, so even a large fuel price escalation will have relatively little effect. For instance, a doubling of the 2002 U3O8 price would increase the fuel cost for a light water reactor by 30% and the electricity cost about 7% (whereas doubling the gas price would add 70% to the price of electricity).

REPROCCESSING & MOX

There are other possible savings. For example, if spent fuel is reprocessed and the recovered plutonium and uranium is used in mixed oxide (MOX) fuel, more energy can be extracted. The costs of achieving this are large, but are offset by MOX fuel not needing enrichment and particularly by the smaller amount of high-level wastes produced at the end. Seven UO2 fuel assemblies give rise to one MOX assembly plus some vitrified high-level waste, resulting in only about 35% of the volume, mass and cost of disposal.

For different fuel costs (fossil fuels) or lead time (nuclear plants). Assumes 5% discount trate, 30 year life and 70% load factor. While the figures are out of date, the comparison remains relevant. Note that the key factor for fossil fuels is the high or low cost of fuels (top portion of bars), whereas nuclear power has a low proportion of fuel cost in total electricity cost and the key factor is the short or long lead time in planning and construction, hence investment cost (bottom portion of bars). Increasing the load factor thus benefits nuclear more than coal, and both these more than oil or gas. (OECD IEA 1992)

Pranav Bhat
http://comparelinux.com