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Indian Civil Nuclear News & Discussions.

India could soon receive up to 2500 tonnes of uranium from Kazakhstan as an agreement in this regard is set to be signed between the two sides by the month-end. :smitten:

Nuclear Power Corporation of India Limited (NPCIL) and Kazatomprom are holding talks and a contract for supply of uranium is expected to be signed by the end of this month, Kazakh Ambassador Kairat Umarov told reporters here.

The fuel will be meant for the existing nuclear plants that are under IAEA safeguards, he said. On the quantity of uranium to be supplied under the contract, Umarov said he was not aware as the companies were dealing with the issue directly.



Sources, however, said the discussions centred around supply of 2500 tonnes, a quantity which India wanted for running its reactors to full capacity.

Incidentally, China recently signed an agreement with Kazakhstan, one of the largest producers of uranium, for supply of 23000 tonnes of the nuclear fuel till 2020.

China is expanding its nuclear industry and in this regard is building 50 nuclear power stations. Umarov expressed hope that the first contract between the companies of India and Kazakhstan would lay foundation for to long-term association
 
nuclear fuel treaty with US,france,canada,russia and now Kazakhstan. good going India.:tup:
 
India’s first indigenously designed 500MW fast breeder nuclear power project at Kalpakkam achieved its second milestone when the huge main vessel was lowered into the safety vessel, an official said on Sunday.

“We have been waiting to do this for quite sometime but were not permitted by the rain gods. As the sky was clear, we decided to go ahead with the lowering of the main vessel and completed it on Saturday,” Project Director Prabhat Kumar told IANS from Kalpakkam in Tamil Nadu.

The Rs. 5,600 crore project is being built by the Bharatiya Nabhikiya Vidyut Nigam Limited (Bhavini) at the Kalpakkam nuclear enclave, around 80 km from here.

A fast breeder reactor is one which breeds more material for a nuclear fission reaction than it consumes and key to India’s three stage nuclear power programme.

Lowering of the huge stainless steel main vessel - 12.9 metres in diameter and 12.94 metres in height, weighing 206 tonnes - is considered a major step in completing the 500 MW power project by the September 2011 deadline.

The lowering of main vessel was delayed as civil construction works are on and the officials did not want to risk even a speck of dust inside the vessel that would hold the coolant liquid sodium, reactor fuel and grid plates.

The sodium-cooled fast reactor designed by the Indira Gandhi Centre for Atomic Research (IGCAR) has three vessels - a safety vessel, a main vessel and an inner vessel.

Outermost is the stainless steel safety vessel, which was lowered into the reactor vault last June - the first milestone.

The third and smallest of the three vessels is the inner vessel - 11 metres tall. It houses pumps, heat exchangers and other equipment. Together, they all go inside the main vessel.

The cone-shaped inner vessel, thermal baffle, grid plate and primary pipes are also ready and officials expect the roof slab of the nuclear reactor to be closed by next March.

As for the power generation part of the project, erection of the gas-insulated switchyard is nearing completion and the gas filling process has begun.


A fast breeder reactor is one which breeds more material for a nuclear fission reaction than it consumes and key to India's three-stage nuclear power programme.....Good going India :cheers:
 
There are very few countries having Fast Breeder reactors. India is yet to make them in large scale ( numbers)
 
Does that mean the fuel in fast breeder will never end ?

No, that is not true the fuel has to be disposed eventually :smitten:

Fission of the nuclear fuel in any reactor produces neutron-absorbing fission products, and because of this it is necessary to reprocess the fuel and breeder blanket from a breeder reactor if one is to fully utilise its ability to breed more fuel than it consumes.

India’s first 40 MWt Fast Breeder Test Reactor (FBTR) attained criticality on 18 October 1985. Thus, India became the sixth nation to have the technology to build and operate an FBTR after US, UK, France, Japan and the former USSR. India has developed the technology to produce the plutonium rich U-Pu mixed carbide fuel. This can be used in the Fast Breeder Reactor.

India has the capability to use thorium cycle based processes to extract nuclear fuel. This is of special significance to the Indian nuclear power generation strategy as India has large reserves of thorium — about 360,000 tonnes — that can fuel nuclear projects for an estimated 2,500 years. The higher construction expense of the Fast Breeder Reactor in comparison with the Pressurised Heavy Water Reactors (PHWR) in use is one of the main reasons why India is looking at the cheaper option - uranium fuel

Fast breeder reactor - Wikipedia, the free encyclopedia
 
The safety inadequacies of India's fast breeder reactor

By Ashwin Kumar and M. V. Ramana | 21 July 2009

Article Highlights

  • India's Department of Atomic Energy plans to build a large fleet of fast breeder nuclear reactors in the coming years.
  • However, many other countries that have experimented with fast reactors have shut down their programs due to technical and safety difficulties.
  • The Indian prototype is similarly flawed, inadequately protected against the possibility of a severe accident.

India's Department of Atomic Energy (DAE) is planning a large expansion of nuclear power, in which fast breeder reactors play an important role. Fast breeder reactors are attractive to the DAE because they produce (or "breed") more fissile material than they use. The breeder reactor is especially attractive in India, which hopes to develop a large domestic nuclear energy program even though it has primarily poor quality uranium ore that is expensive to mine.

Currently, only one fast reactor operates in the country--a small test reactor in Kalpakkam, a small township about 80 kilometers (almost 50 miles) south of Chennai. The construction of a larger prototype fast breeder reactor (PFBR) is underway at the same location. This reactor is expected to be completed in 2010 and will use mixed plutonium-uranium oxide as fuel in its core, with a blanket of depleted uranium oxide that will absorb neutrons and transmute into plutonium 239. Liquid sodium will be used to cool the core, which will produce 1,200 megawatts of thermal power and 500 megawatts of electricity. The reactor is to be the first of hundreds that the DAE envisions constructing throughout India by mid-century.

However, such an expansion of fast reactors, even if more modest than DAE projections, could adversely affect public health and safety. While all nuclear reactors are susceptible to catastrophic accidents, fast reactors pose a unique risk. In fast reactors, the core isn't in its most reactive--or energy producing-- configuration when operating normally. Therefore, an accident that rearranges the fuel in the core could lead to an increase in reaction rate and an increase in energy production. If this were to occur quickly, it could lead to a large, explosive energy release that might rupture the reactor vessel and disperse radioactive material into the environment.

Many of these reactors also have what is called a "positive coolant void coefficient," which means that if the coolant in the central part of the core were to heat up and form bubbles of sodium vapor, the reactivity--a measure of the neutron balance within the core, which determines the reactor's tendency to change its power level (if it is positive, the power level rises)--would increase; therefore core melting could accelerate during an accident. (A positive coolant void coefficient, though not involving sodium, contributed to the runaway reaction increase during the April 1986 Chernobyl reactor accident.) In contrast, conventional light water reactors typically have a "negative coolant void coefficient" so that a loss of coolant reduces the core's reactivity. The existing Indian fast breeder test reactor, with its much smaller core, doesn't have a positive coolant void coefficient. Thus, the DAE doesn't have real-world experience in handling the safety challenges that a large prototype reactor will pose.

More largely, international experience shows that fast breeder reactors aren't ready for commercial use. Superphénix, the flagship of the French breeder program, remained inoperative for the majority of its 11-year lifetime until it was finally shuttered in 1996. Concerns about the adequacy of the design of the German fast breeder reactor led to it being contested by environmental groups and the local state government in the 1980s and ultimately to its cancellation in 1991. And the Japanese fast reactor Monju shut down in 1995 after a sodium coolant leak caused a fire and has yet to restart. Only China and Russia are still developing fast breeders. China, however, has yet to operate one, and the Russian BN-600 fast reactor has suffered repeated sodium leaks and fires.

When it comes to India's prototype fast breeder reactor, two distinct questions must be asked: (1) Is there confidence about how an accident would propagate inside the core and how much energy it might release?; and (2) have PFBR design efforts been as strict as necessary, given the possibility that an accident would be difficult to contain and potentially harmful to the surrounding population?

The simple answer to both is no.

The DAE, like other fast-reactor developers, has tried to study how severe a core-disruptive accident would be and how much energy it would release. In the case of the PFBR, the DAE has argued that the worst-case core disruptive accident would release an explosive energy of 100 megajoules. This is questionable.

The DAE's estimate is much smaller when compared with other fast reactors, especially when the much larger power capacity of the PFBR--and thus, the larger amount of fissile material used in the reactor--is taken into account. For example, it was estimated that the smaller German reactor (designed to produce 760 megawatts of thermal energy) would produce 370 megajoules in the event of a core-disruptive accident--much higher than the PFBR estimate. Other fast reactors around the world have similarly higher estimates for how much energy would be produced in such accidents.

The DAE's estimate is based on two main assumptions: (1) that only part of the core will melt down and contribute to the accident; and (2) that only about 1 percent of the thermal energy released during the accident would be converted into mechanical energy that can damage the containment building and cause ejection of radioactive materials into the atmosphere.

Neither of these assumptions is justifiable. Britain's Atomic Energy Authority has done experiments that suggest up to 4 percent of the thermal energy could be converted into mechanical energy. And the phenomena that might occur inside the reactor core during a severe accident are very complex, so there's no way to stage a full-scale experiment to compare with the theoretical accident models that the reactor's designers used in their estimates. In addition, important omissions in the DAE's own safety studies make their analysis inadequately conservative. (Our independent estimates of the energy produced in a hypothetical PFBR core disruptive accident are presented in the Science and Global Security article, "Compromising Safety: Design Choices and Severe Accident Possibilities in India's Prototype Fast Breeder Reactor" and these are much higher than the DAE's estimates.)

Turning to the second question: In terms of the stringency of the DAE's design effort, the record reveals inadequate safety precautions. One goal of any "defense-in-depth" design is to engineer barriers to withstand the most severe accident that's considered plausible. Important among these barriers is the reactor's containment building, the most visible structure from the outside of any nuclear plant. Compared to most other breeder reactors, and light water reactors for that matter, the design of the PFBR's containment is relatively weak and won't be able to contain an accident that releases a large amount of energy. The DAE knows how to build stronger containments--its newest heavy water reactor design has a containment building that is meant to withstand six times more pressure than the PFBR's containment--but has chosen not to do so for the PFBR.

The other unsafe design choice is that of the reactor core. As mentioned earlier, the destabilizing positive coolant void coefficient in fast reactors is a problem because it increases the possibility that reactivity will escalate inside the core during an accident. It's possible to decrease this effect by designing the reactor core so that fuel subassemblies are interspersed within the depleted uranium blanket, in what is termed a heterogeneous core. The U.S. Clinch River Breeder Reactor, which was eventually cancelled, was designed with a heterogeneous core, and Russia has considered a heterogeneous core for its planned BN-1600 reactor. The DAE hasn't made such an effort, and the person who directed India's fast breeder program during part of the design phase once argued that the emphasis on the coolant void coefficient was mistaken because a negative void coefficient could lead to dangerous situations in an accident as well. That might be true, but it misses the obvious point that the same potentially dangerous situations would be even more dangerous if the void coefficient within the core is positive.

Both of these design choices--a weak containment building and a reactor core with a large and positive void coefficient--are readily explainable: They lowered costs. Reducing the sodium coolant void coefficient would have increased the fissile material requirement of the reactor by 30-50 percent--an expensive component of the initial costs. Likewise, a stronger containment building would have cost more. All of this is motivated by the DAE's assessment that "the capital cost of [fast breeder reactors] will remain the most important hurdle" to their rapid deployment.

Lowered electricity costs would normally be most welcome, but not with the increased risk of catastrophic accidents caused by poorly designed fast breeder reactors.
 
India, Russia sign nuclear deal


Press Trust Of India
Moscow, December 07, 2009
First Published: 18:02 IST(7/12/2009)
Last Updated: 18:37 IST(7/12/2009)

Print



India and Russia on Monday signed a path-breaking broad-based agreement in civil nuclear field that will ensure transfer of technology and uninterrupted uranium fuel supplies to its nuclear reactors and inked three pacts in the defence sector.

The agreements were signed after talks between Prime Minister Manmohan Singh and Russian President Dmitry Medvedev at the Kremlin here, during which they discussed a whole range of issues, including terrorism emanating from Afghanistan.

"Today we have signed an agreement that broadens the reach of our cooperation beyond supplies of nuclear reactors to areas of research and development and a whole range of areas in nuclear energy," Singh told a joint press conference with Medvedev.

The Prime Minister said the agreement will deepen and strengthen the already existing nuclear cooperation between the two countries under which four new nuclear reactors would be set up by Russia in Kudankulam in Tamil Nadu and a site for the fifth one has been identified in West Bengal.

India, Russia sign nuclear deal- Hindustan Times
 
India, Russia sign path-breaking N-agreement

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Russian President Dmitry Medvedev meets PM Manmohan Singh in the Kremlin.

India and Russia on Monday signed a path-breaking broad-based agreement in civil nuclear field that will ensure transfer of technology and uninterrupted uranium fuel supplies to its nuclear reactors and inked three pacts in the defence sector.

The agreements were signed after talks between Prime Minister Manmohan Singh and Russian President Dmitry Medvedev at the Kremlin here, during which they discussed a whole range of issues, including terrorism emanating from Afghanistan.

"Today we have signed an agreement that broadens the reach of our cooperation beyond supplies of nuclear reactors to areas of research and development and a whole range of areas in nuclear energy," Singh told a joint press conference with Medvedev.

The Prime Minister said the agreement will deepen and strengthen the already existing nuclear cooperation between the two countries under which four new nuclear reactors would be set up by Russia in Kudankulam in Tamil Nadu and a site for the fifth one has been identified in West Bengal.

The new civil nuclear pact provides for uninterrupted uranium fuel supplies from Russia even in the event of termination of bilateral ties in this field for any reason.

The Indo-Russian pact on atomic cooperation is a significant document and goes much further than the 123 agreement between India and the US, officials said. The pact also has provisions for transfer of enrichment and nuclear technology, which is denied in the 123 agreement with the US.

Medvedev said the nuclear agreement opens the way for greater cooperation beyond Kudankulam.

"The nuclear cooperation between the two countries have a very good future. We are satisfied with the cooperation and I hope today's agreement will pave the way for greater cooperation in this field in the years to come," he said.

Asked about provision of ENR to India against the backdrop of a G-8 resolution in July this year under which Russia and seven other countries committed that they will refrain from transferring such technology, he said: "Nothing changes for us."

-LINK
 


Russia is one of those friend of India who were always there for India; No matter what was the situation.
 
India to supply low-cost nuclear parts for export

GE Hitachi Nuclear Energy Ltd. and Westinghouse Electric Co. plan to use India as a low-cost supplier of nuclear parts for export to the U.S. and Europe, executives said on Thursday.

“We see India as a very good supply chain for us to supply our world market,” said Daniel Roderick, senior vice president at GE Hitachi Nuclear Energy, an alliance between General Electric Co. and Japan’s Hitachi Ltd. based in Wilmington, N.C.

The decision was driven by cost pressures both companies face as they prepare to build nuclear reactors in India, and it would not have been possible if the 45-nation Nuclear Suppliers Group had not lifted a three-decade global ban on nuclear trade with India last year.

In order to keep costs low enough to supply cost-competitive power to India, GE Hitachi said itplans to localize up to 70 percent of production, while Westinghouse plans to use local manufacturing and labour for up to 80 percent of its India work.

Once that expertise is transferred, both firms plan to turn to their Indian partners to help meet global demand for nuclear reactor parts.

GE Hitachi has signed cooperation agreements with three Indian companies: Larsen & Toubro Ltd., Bharat Heavy Electricals Ltd., and Bharat Forge Ltd. Roderick also said GE Hitachi would begin hiring to expand its India operations in January.

Westinghouse has signed an agreement with Larsen & Toubro and is negotiating three more, said Meena Mutyala, vice-president for global growth at Westinghouse.

“India is very good in high-precision manufacturing,” she said. “We plan to use that to the extent possible.”

The earliest a new Westinghouse reactor could be up and running in India is 2018, she added.

GE and Westinghouse have each been allotted a site to build nuclear power plants with up to 10,000 megawatt capacity, as part of India’s goal of ramping up its nuclear capacity to 63,000 megawatts by 2030 from 4,120 megawatts today.

Several roadblocks remain. The U.S. and India must finalize non-proliferation assurances before U.S. firms can export nuclear technology to India. The countries must also agree on a reprocessing agreement, which would make India the third, after Japan and a consortium of European states, to be able to reprocess spent nuclear fuel from the U.S. Finally, U.S. companies, unlike their government-linked French and Russian competitors, must wait for India to enact new legislation that gives private companies greater liability protection before they can build reactors here.

The Indian government is in the process of acquiring land for five proposed reactor sites, and there have been media reports of some farmer protests. As India industrializes, conflicts over land use have intensified, and violent farmer protests have derailed the plans of some of India’s most powerful industrialists.

But S.K. Jain, managing director of the government-run Nuclear Power Corporation of India Ltd., said the government is committed to paying people a fair price for their land, and said he was confident the acquisitions would go fast enough for construction to begin in 12 to 18 months.

“There will always be 3 to 4 percent who are never satisfied,” he said. “It’s a noisy democracy. I don’t see


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Great news :victory:...It reminds me of an article where analysts predicts that india will be immune to any sanctions in a decade or so...The reason they mentioned was exactly in synch with the above event....Their overall point was that companies will shift most of their work to India because of cost-effectiveness thereby making it counter-productive for any sanctions... Comments welcome...
 
I am really happy. India's energy resources are now clearly under our control.

Thanks Manmohan!
 
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