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Beloyarsk Nuclear Power Station

Coordinates: 56°50′30″N 61°19′21″E / 56.84167°N 61.32250°E / 56.84167; 61.32250
From Wikipedia, the free encyclopedia

Beloyarsk Nuclear Power Station
The Beloyarsk Nuclear Power Plant
Map
Official name
  • Белоярская АЭС
CountryRussia
Coordinates56°50′30″N 61°19′21″E / 56.84167°N 61.32250°E / 56.84167; 61.32250
StatusOperational
Construction began1958
Commission date26 April 1964
OperatorRosenergoatom
Nuclear power station
Reactor typeSBR
Reactor supplierOKBM Afrikantov
Cooling sourcePyshma River
Power generation
Units operational1 × 600 MW
1 × 885 MW
Units planned1 × 1220 MW
Units decommissioned1 × 108 MW
1 × 160 MW
Nameplate capacity1,485 MW
Annual net output10,100 GW·h (planned)
External links
Websitewww.rosenergoatom.ru/en/npp/beloyarsk-npp/
CommonsRelated media on Commons

The Beloyarsk Nuclear Power Station (NPS; Russian: Белоярская атомная электростанция им. И. В. Курчатова [pronunciation]) was the third of the Soviet Union's nuclear plants. It is situated by Zarechny in Sverdlovsk Oblast, Russia. Zarechny township was created to service the station, which is named after the Beloyarsky District. The closest city is Yekaterinburg.

Early reactors

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Units 1 and 2

Two earlier reactors were constructed at Beloyarsk: an AMB-100 reactor (operational 1964–1983) and an AMB-200 reactor (operational 1967–1989).

Both were supercritical water reactors; the first unit used 67 tons of uranium enriched to 1.8%, while the second unit used 50 tons of uranium enriched to 3.0%. The first unit had an indirect steam cycle, while the second had a direct one.[1]

Although they were comparable in power to the Shippingport Atomic Power Station, the Soviet planners regarded the Beloyarsk reactors as prototypes.[2] Their main novelty was the use of superheated steam ran through a standard turbine thus resulting in a better efficiency compared to the earlier Obninsk Nuclear Power Plant pilot plant. The first Beloyarsk unit produced about 285 MW heat of which about 100 MW were converted to electricity.[2] The second unit, which used two turbines, had a similar conversion efficiency of about 36%.[1]

Later reactors

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Cutaway model of the BN-600 reactor

Two reactors are now in operation: a BN-600 fast breeder reactor, generating 600 MWe gross and a BN-800 fast breeder reactor, generating 885 MWe gross. The BN-800 is the largest fast neutron power reactor in service in the world. Three turbines are connected to the BN-600 reactor. The BN-600 reactor core is 1.03 metres (41 in) tall and has a diameter of 2.05 metres (81 in). It has 369 fuel assemblies, each consisting of 127 fuel rods with an enrichment of 17–26% 235U. In comparison, typical enrichment in other Russian reactors is in the range of 3–4% 235U. BN-600 reactors use liquid sodium as a coolant. The station lacks a containment building.

Construction of the BN-800 reactor

Construction started on the larger BN-800 fast breeder reactor in 1987. Protests halted progress in 1988, but work resumed in 1992 following an order by President Boris Yeltsin. Financial difficulties resulted in slow progress. Construction costs have been estimated at 1 trillion rubles and the new reactor was expected to be finished in 2012–2015. The BN-600 was originally planned to be decommissioned in 2010 but its lifetime was expected to be extended to cover the gap; it has been operating since 1980.

On 27 June 2014, controlled nuclear fission started in the BN-800 fast breeder reactor. The newest reactor helps to close the nuclear fuel cycle and to achieve a fuel cycle without or with less nuclear waste. Russia was, at the date, the only country that operates fast neutron reactors for energy production.[citation needed] However issues detected during low power operation required further fuel development work. On 31 July 2015, the unit again achieved minimum controlled power again, at 0.13% of rated power. Commercial operations are expected to start before the end of 2016, now with a power rating of 789 MWe.[3] In December 2015, Unit 4 was connected to the national grid.[4][5]

Unit Type El. Output (MW) Start of project First criticality Shut down
1 AMB-100 108 1958-06-01 1964-04-26 1983-01-01
2 AMB-200 160 1962-01-01 1967-12-29 1990-01-01
3 BN-600 600[6] 1969-01-01 1980-04-08 2040 est.[7]
4 BN-800 885[8] 1987 2014-06-27 2056 est.[9]
5 BN-1200 1,220 2027 est.[10] 2035 est.[10]

See also

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References

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  1. ^ a b Steven B Krivit; Jay H Lehr; Thomas B Kingery, eds. (2011). Nuclear Energy Encyclopedia: Science, Technology, and Applications. Wiley. pp. 318–319. ISBN 978-1-118-04347-9.
  2. ^ a b Paul R. Josephson (2005). Red Atom: Russia's Nuclear Power Program from Stalin to Today. University of Pittsburgh Pre. p. 28. ISBN 978-0-8229-7847-3.
  3. ^ "Fast reactor progress at Beloyarsk". Nuclear Engineering International. 14 January 2016. Retrieved 19 January 2016.
  4. ^ "Rosenergoatom already learning from BN-800". World Nuclear Association. 10 December 2014. Retrieved 12 December 2015.
  5. ^ "Russia connects BN-800 fast reactor to grid". World Nuclear Association. 11 December 2015. Retrieved 12 December 2015.
  6. ^ BELOYARSK-3
  7. ^ BN-600 reactor at Beloyarsk aims for further life extension
  8. ^ BELOYARSK-4
  9. ^ Nuclear Power in Russia
  10. ^ a b Russia progresses with BN-1200M sodium-cooled fast reactor development

Further reading

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  • Dollezhal, N. A. (1958). "The uranium-graphite reactor and superheated steam power stations". Journal of Nuclear Energy. 7 (1–2): 109–IN12. doi:10.1016/0891-3919(58)90242-0. For the design of the first two reactors.
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