MKER explained

The MKER (Russian: МКЭР, '''М'''ногопетлевой '''К'''анальный '''Э'''нергетический '''Р'''еактор: Mnogopetlevoy Kanalynyi Energeticheskiy Reaktor, translation: multi-loop pressure tube power reactor) is a Russian third generation nuclear reactor design.[1] It was a development of the RBMK nuclear power reactor.[2] No reactor of the MKER-800 type (and presumably other types) will continue to be developed, as ROSATOM have shelved the design.

Operation

The MKER is a pressure tube reactor with modern safety features including a containment building and passive nuclear safety systems. Fuel can be changed while the reactor is in operation (online refueling), improving grid and fuel efficiency.[3] Vertical injectors promote a natural convective flow of the light water primary circuit fluid through inlined channels in the reactor core. Graphite blocks in the reactor core serve as a neutron moderator.[4]

There are three different types of MKER: the MKER-800, MKER-1000 and MKER-1500. No MKER of the MKER-800 type will be completed.[5]

MKER-800

The MKER-800 has an electrical generation capacity of 800 MW. An automated process control system for the MKER-800 was under development in a joint project of Westinghouse and NIKIET.[6] Plans for the MKER-800 were scrapped.[2] Four MKER-800 units were originally planned for the Leningrad Nuclear Power Plant.[7]

MKER-1000

The MKER-1000 has a thermal power output of 3000 MWth and an electrical output of 1,068 MW. There are four circuits and 1,832 fuel elements in the reactor core. Total fissile material in the reactor is 163 tonnes. Overall responsibility for construction of the MKER design is held by Northern Construction Administration. Major assemblies are produced by the Izhorsky Zavod in Saint Petersburg, and the turbine supplier is the Leningradsky Metallichesky Zavod. Main building and reactor containment is designed by Atomenergoproekt.[6] The MKER is intended to directly substitute for existing RBMK plants producing heat, electricity and medical isotopes.[5]

The reactor building of the MKER consists of a dual containment structure with an inner diameter of 55.5 meters. An inner liner intended to prevent leakage of radioactive material into the atmosphere can withstand internal pressures of 2 bar. Protection from external damage is provided by an outer concrete wall. The two structures are independent and separated physically from one another on a common foundation. Damage from an earthquake of

ML

8 would be contained by this structure.[8] [9]

Automatic control is an integral part of the MKER design. Located between the reactor building and the turbine hall, the control room oversees the automatic control system and various plant safety systems. It occupies a protected central location, minimizing possibility of damage or compromise.[8]

The MKER-1000 core includes the pressure tube reactor and eight coolant injector pumps. There are multiple coolant loops with 16 independent circuits, two circuits sharing a pump each.[10] From an overall thermal capacity of 3,000 MWth electrical generation of 1,000 MW plus an additional 130 MW of thermal energy for building heat can be obtained. The design specified turbine is a type K-1000-6, 1 / 3000 at 3000 rpm with an alternator of type TZV-1100-2UZ. Both evaporative cooling and open cycle cooling variations have been proposed.[10]

Low-enriched uranium dioxide fuel with concentrations of 2.0 to 2.4% U-235 equivalence is specified. Fuel is changed using a remote-controlled crane and spent fuel rods would spend up to five years in a cooling pond located in the reactor hall before further processing. The continuous refuelling cycle brings a fuel burnup benefit; individual rods can be left longer in the reactor instead of being swapped en masse as required in most PWR designs.[9]

MKER-1500

A further proposed development of the MKER is the MKER-1500 with a corresponding electrical generation capacity of 1500 MW. Transfer of heat from the reactor core has been improved in the new design, with primary loops divided into four independent circuits. The diameter of the coolant tubes is expanded to 600 mm and injector pump configuration is changed. Cooling circuits are relocated below the containment.[4] The MKER-1500 was also proposed for the Leningrad nuclear power plant.[11]

Other links

Notes and References

  1. http://www-pub.iaea.org/MTCD/publications/PDF/cnpp2003/CNPP_Webpage/PDF/2002/Documents/Documents/Russian%20Federation%202002.pdf IAEA - RUSSIAN FEDERATION
  2. Web site: WNA - Nuclear Power in Russia . 2008-12-08 . 2013-02-13 . https://web.archive.org/web/20130213052522/http://world-nuclear.org/info/inf45.html . dead .
  3. http://www.nikiet.ru/eng/structure/presstube.html NIKIET - Department of Pressure-Tube Power Reactors
  4. https://web.archive.org/web/20041229111149/http://www.nikiet.ru/eng/conf/19oct2004/programme/session2/32_Finiakin_NIKIET.doc MULTILOOP PRESSURE TUBE POWER REACTORS (MKER) – CONSOLIDATION OF EXPERTISE IN DESIGN OF DOMESTIC PRESSURE TUBE REACTORS
  5. https://world-nuclear.org/information-library/country-profiles/countries-o-s/russia-nuclear-power.aspx World Nuclear Association - "This design too has been shelved"
  6. Web site: LAES - Main contractors and suppliers . 2008-12-08 . 2013-09-30 . https://web.archive.org/web/20130930201547/http://www.lnpp.ru/new_lnpp/eng-htm/cont/proizv/perspek/dolgo/dolgo1.htm . dead .
  7. http://www.bellona.org/english_import_area/international/russia/npps/leningrad/9358 Bellona - Statistics from Leningrad Nuclear Power Plant
  8. Web site: LAES - The proposed NPP design meets the following requirements . 2008-12-08 . 2016-03-04 . https://web.archive.org/web/20160304065426/http://www.lnpp.ru/new_lnpp/eng-htm/cont/proizv/perspek/dolgo/dolgo3.htm . dead .
  9. Web site: LAES - The MKER-1000 reactor unit incorporates as follows . 2008-12-08 . 2016-03-04 . https://web.archive.org/web/20160304185655/http://www.lnpp.ru/new_lnpp/eng-htm/cont/proizv/perspek/dolgo/dolgo5.htm . dead .
  10. Web site: LAES - The MKER-1000 reactor unit incorporates as follows . 2008-12-08 . 2018-06-24 . https://web.archive.org/web/20180624133054/http://www.lnpp.ru/new_lnpp/eng-htm/cont/proizv/perspek/dolgo/dolgo4.htm . dead .
  11. http://www.nikiet.ru/eng/conf/19oct2004/programme/plenary_session/03_Cherkashov_NIKIET.doc THE PRESSURE-TUBE LINE IN RUSSIAN NUCLEAR ENGINEERING