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2006-03-07 India-Pakistan
Implementing India's nuclear separation plan
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Posted by john 2006-03-07 16:54|| || Front Page|| [2 views since 2007-05-07]  Top

#1 . An average Indian reactor is of 220 MW
Wow! Home grown or French Navy?
Posted by 6 2006-03-07 17:22||   2006-03-07 17:22|| Front Page Top

#2 Home grown.
The ones under construction now are 540 MW.
They have designed 700 MW ones though and future reactors will be this size.


Posted by john 2006-03-07 17:45||   2006-03-07 17:45|| Front Page Top

#3 The fast breeders are 500 MW.

The Indian Naval reactor is rumored to be 190 MW
Posted by john 2006-03-07 17:46||   2006-03-07 17:46|| Front Page Top

#4 Reuters - India will open 14 of its 22 nuclear plants for international inspections by 2014 as part of a landmark civilian nuclear cooperation deal with the United States, Prime Minister Manmohan Singh said on Tuesday.

Here are some key facts about India's plan to separate its civilian and military nuclear facilities:

- 14 thermal reactors that generate about 65 percent of atomic power will be placed on the civilian list between 2006 and 2014 and opened to inspections. India has 15 nuclear power plants in operation, with an installed generating capacity of 3,310 megawatts (MW). Seven more plants with a capacity of 3,420 MW are under construction and scheduled for completion by 2009.

- Four nuclear power plants in operation (capacity 620 MW) and two under construction (capacity 2000 MW) are currently under International Atomic Energy Agency (IAEA) safeguards.

- The experimental fast-breeder reactor (FBR) programme, the subject of hard bargaining during the negotiations, will fall outside the ambit of safeguards. This leaves out the fast breeder test reactor, which was completed in 1985, and the 500 MW Prototype Fast Breeder Reactor, scheduled for completion by 2010. The FBRs, which use spent fuel from existing heavy water reactors to process plutonium, are intended as the mainstay of the country's nuclear power programme.

- India has decided to place under safeguards all future civilian thermal power reactors and civilian breeder reactors with the caveat that it will determine which ones fall in the civilian list. India has plans to increase the installed capacity of its nuclear power reactors to 20,000 MW by 2020.

- Reprocessing, enrichment and other facilities associated with the fuel cycle for the strategic programme have been kept out of the separation plan.

- The Canadian-built CIRUS research reactor, which has been used to produce weapons-grade plutonium, will be shut down by 2010. India has said it is ready to shift another research reactor, "Apsara," out of a high-security atomic research centre in Mumbai and place it under safeguards.

- The safeguards will apply in "perpetuity" but only as long as foreign fuel supplies remain uninterrupted. This will require safeguards and fuel supply agreements with the IAEA applicable only to India.

Sources: Reuters, Indian Atomic Energy Commission (www.aec.gov.in), IAEA (www.iaea.org)
Posted by john 2006-03-07 17:49||   2006-03-07 17:49|| Front Page Top

#5 btw, "home grown" means CANDU derivative.
The heavy water reactors are based on Canadian designs.
The fast breeders and the other research reactors - such as Kamini the only U233 reactor in the world, and the (still to be built) thorium reactor are of purely Indian design.


Posted by john 2006-03-07 17:53||   2006-03-07 17:53|| Front Page Top

#6 India operates more Candu derived units than any country outside Canada itself.

These are heavy water reactors that use natural uranium fuel. No enrichment is needed.

When used in low burnup mode, significant amounts of weapons grade plutonium are available in the spent fuel rods. Power output is quite low in this mode though.

The recycling of the heavy water causes a build up of Tritium.

Both Canada and India have developed (independently) the technology for detritiating heavy water. This gives a low cost source of large amounts of Tritium (used to boost the yield of a nuclear weapon primary).

Canada recently shut down two CANDU units prematurely becuse it was too expensive to fix their corroded coolant pipes.
In contrast, India has managed to fix (and essentially refurbish) the coolant pipes of its CANDU units quite cheaply, extending their life by decades.

Posted by john 2006-03-07 18:23||   2006-03-07 18:23|| Front Page Top

#7 Some background info on the Indian nuclear program

As the US Congress debates the Indo-US agreement on nuclear cooperation, a key aspect from the American viewpoint is that India has certain inherent strengths in the area of nuclear technology, which would enable India to forge ahead, albeit slowly, even without US cooperation.

Central to this argument is the availability of huge reserves of thorium in India. Thorium reserves have been estimated to be between 3,60,000 and 5,18,000 tonnes. The US estimates the “economically extractable” reserves to be 2,90,000 tonnes, one of the largest in the world. Our uranium reserves, by contrast, are estimated to be at a maximum of around 70,000 tonnes.

India currently has 15 commercial power reactors in operation, most of which are pressurised heavy water reactors (PHWR) which use natural uranium. Two Tarapur reactors are boiling water reactors (BWR) which need enriched uranium, which has to be imported.

Together they generate about 3300 MWe (Mega Watt Electrical) of power, about 4 per cent of that generated from all sources. Another six PHWRs are in construction, and along with the two “VVER” Russian built 1000 MWe reactors which use enriched uranium, they would add about 3960 MWe by 2008. The goal is to reach at least 20,000 MWe by 2020.


India's uranium reserves are low. Obtaining enriched uranium for the two Tarapur reactors and VVER type reactors requires the consent of the Nuclear Suppliers Groups countries, including Russia. This is where the agreement with the US is expected to be beneficial to India.

Also central to India's success in achieving these goals, is the harnessing of thorium, for which India has developed a three-stage nuclear programme. India has already developed and tested the technologies needed to extract energy from Thorium, but large scale execution has not yet been possible, mainly because of limited availability of Plutonium.

Stage one is the use of PHWRs. Natural uranium is the primary fuel. Heavy water (deuterium oxide, D2O) is used as moderator and coolant. The composition of natural uranium is 0.7 percent U-235, which is fissile, and the rest is U-238. This low fissile component explains why certain other types of reactors require the uranium to be “enriched” i.e. the fissile component increased.

In the second stage, the spent fuel from stage one is reprocessed in a reprocessing facility, where Plutonium-239 is separated. Plutonium, of course, is a weapons material, which goes towards creating India’s nuclear deterrent.

Pu-239 then becomes the main fissile element, the fuel core, in what are known as fast breeder reactors (FBR). A test FBR is in operation in Kalpakkam, and the construction for a 500 MWe prototype FBR was launched recently by Prime Minister Dr Manmohan Singh.

These are known as breeder reactors because the U-238 “blanket” surrounding the fuel core will undergo nuclear transmutation to produce more PU-239, which in turn will be used to create energy.

The stage also envisages the use of Thorium (Th-232) as another blanket. Th-232 also undergoes neutron capture reactions, creating another uranium isotope, U-233. It is this isotope which will be used in the third stage of the programme. Thorium by itself is not a fissile material, and cannot be used directly to produce nuclear energy. The Kamini 40 MWe reactor at Kalpakkam which became critical in Sept 1996, using U-233 fuel, has demonstrated some of these technologies.

India is currently developing a prototype advanced heavy water reactor (AHWR) of 300 MWe capacity. The AHWRs, which use plutonium based fuel, are to be used to shorten the period of reaching full scale utilisation of our thorium reserves. The AHWR is thus the first element of the third stage. AHWR design is complete but further R and D work is required, especially on safety. It is expected to be unveiled soon and construction launched.

In the third phase, in addition to the U-233 created from the second phase, breeder reactors fuelled by U-233, with Th-232 blankets, will be used to generate more U-233.

The Bhabha Atomic Research Centre has estimated that India's thorium reserves can amount to a staggering 3,58,000 GWe-yr (Giga Watt Electrical - Year) of energy, enough for the next century and beyond

BARC scientists are also looking at other designs, like an advanced thorium breeder reactor (ATBR) which requires plutonium only as a seed to start off the reaction, and then use only thorium and U-233. Here the plutonium is completely consumed and this reactor is thus considered “proliferation resistant”. A Compact High Temperature Reactor also under development at BARC . This reactor is designed to work in closed spaces and remote locations.

Success in harnessing thorium’s potential is thus critical for the India’s future energy security.

India has put in place mechanisms for ensuring safety and security of nuclear facilities. The regulatory and safety systems ensure that equipment at India's nuclear facilities are designed to operate safely and even in the unlikely event of any failure or accident, mechanisms like plant and site emergency response plans are in place to ensure that the public is not affected in any manner. In addition, detailed plans, which involve the local public authorities, are also in place to respond if the consequences were to spill into the public domain. The emergency response system is also in a position to handle any other radiation emergency in the public domain that may occur at locations, which do not even have any nuclear facility.

Regulatory and safety functions of Atomic Energy in India are carried out by an independent body, the Atomic Energy Regulatory Board (AERB). The AERB was constituted on November 15, 1983 by the President of India under the Atomic Energy Act, 1962 to carry out certain regulatory and safety functions under the Act. The regulatory authority of AERB is derived from the rules and notifications promulgated under the Atomic Energy Act, 1962 and the Environmental (Protection) Act, 1986. The mission of the Board is to ensure that the use of ionizing radiation and nuclear energy in India does not cause undue risk to health and the environment.
Posted by john 2006-03-07 20:02||   2006-03-07 20:02|| Front Page Top

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