VVER reactor class | |
---|---|
Generation | Generation I reactor Generation II reactor Generation III reactor Generation III+ reactor |
Reactor concept | Pressurized water reactor |
Reactor line | VVER (Voda Voda Energo Reactor) |
Reactor types | VVER-210 VVER-365 VVER-440 VVER-1000 VVER-1200 VVER-TOI |
Main parameters of the reactor core | |
Fuel (fissile material) | 235U (LEU) |
Fuel state | Solid |
Neutron energy spectrum | Thermal |
Primary control method | Control rods |
Primary moderator | Water |
Primary coolant | Liquid (light water) |
Reactor usage | |
Primary use | Generation of electricity |
Power (thermal) | VVER-210: 760 MWth VVER-365: 1,325 MWth VVER-440: 1,375 MWth VVER-1000: 3,000 MWth VVER-1200: 3,212 MWth VVER-TOI: 3,300 MWth |
Power (electric) | VVER-210: 210 MWel VVER-365: 365 MWel VVER-440: 440 MWel VVER-1000: 1,000 MWel VVER-1200: 1,200 MWel VVER-TOI: 1,300 MWel |
The water-water energetic reactor (WWER),[1] or VVER (from Russian: водо-водяной энергетический реактор; transliterates as vodo-vodyanoi enyergeticheskiy reaktor; water-water power reactor) is a series of pressurized water reactor designs originally developed in the Soviet Union, and now Russia, by OKB Gidropress.[2] The idea of such a reactor was proposed at the Kurchatov Institute by Savely Moiseevich Feinberg. VVER were originally developed before the 1970s, and have been continually updated. As a result, the name VVER is associated with a wide variety of reactor designs spanning from generation I reactors to modern generation III+ reactor designs. Power output ranges from 70 to 1300 MWe, with designs of up to 1700 MWe in development.[3][4] The first prototype VVER-210 was built at the Novovoronezh Nuclear Power Plant.
VVER power stations have mostly been installed in Russia, but also in Ukraine, Belarus, Armenia, China, the Czech Republic, Finland, Hungary, Slovakia, Bulgaria, India and Iran. Countries that are planning to introduce VVER reactors include Bangladesh, Egypt, Jordan, and Turkey. Germany shut down its VVER reactors in 1989-90,[5] and cancelled those under construction.
History
The earliest VVERs were built before 1970. The VVER-440 Model V230 was the most common design, delivering 440 MW of electrical power. The V230 employs six primary coolant loops each with a horizontal steam generator. A modified version of VVER-440, Model V213, was a product of the first nuclear safety standards adopted by Soviet designers. This model includes added emergency core cooling and auxiliary feedwater systems as well as upgraded accident localization systems.[6]
The larger VVER-1000 was developed after 1975 and is a four-loop system housed in a containment-type structure with a spray steam suppression system (Emergency Core Cooling System). VVER reactor designs have been elaborated to incorporate automatic control, passive safety and containment systems associated with Western generation III reactors.
The VVER-1200 is the version currently offered for construction, being an evolution of the VVER-1000 with increased power output to about 1200 MWe (gross) and providing additional passive safety features.[7]
In 2012, Rosatom stated that in the future it intended to certify the VVER with the British and U.S. regulatory authorities, though was unlikely to apply for a British licence before 2015.[8][9]
The construction of the first VVER-1300 (VVER-TOI) 1300 MWE unit was started in 2018.[4]
Design
The Russian abbreviation VVER stands for 'water-water energy reactor' (i.e. water-cooled water-moderated energy reactor). The design is a type of pressurised water reactor (PWR). The main distinguishing features of the VVER[3] compared to other PWRs are:
- Horizontal steam generators
- Hexagonal fuel assemblies
- No bottom penetrations in the pressure vessel
- High-capacity pressurizers providing a large reactor coolant inventory
Reactor fuel rods are fully immersed in water kept at (12,5 / 15,7 / 16,2 ) MPa (1812/2277/2349 psi) pressure respectively so that it does not boil at the normal (220 to over 320 °C [428 to >608°F]) operating temperatures. Water in the reactor serves both as a coolant and a moderator which is an important safety feature. Should coolant circulation fail, the neutron moderation effect of the water diminishes due to increased heat which creates steam bubbles which do not moderate neutrons, thus reducing reaction intensity and compensating for loss of cooling, a condition known as negative void coefficient. Later versions of the reactors are encased in massive steel reactor pressure vessels. Fuel is low enriched (ca. 2.4–4.4% 235U) uranium dioxide (UO2) or equivalent pressed into pellets and assembled into fuel rods.
Reactivity is controlled by control rods that can be inserted into the reactor from above. These rods are made from a neutron absorbing material and, depending on depth of insertion, hinder the chain reaction. If there is an emergency, a reactor shutdown can be performed by full insertion of the control rods into the core.
Primary cooling circuits
As stated above, the water in the primary circuits is kept under a constant elevated pressure to avoid its boiling. Since the water transfers all the heat from the core and is irradiated, the integrity of this circuit is crucial. Four main components can be distinguished:
- Reactor vessel: water flows through the fuel assemblies which are heated by the nuclear chain reaction.
- Volume compensator (pressurizer): to keep the water under constant but controlled pressure, the volume compensator regulates the pressure by controlling the equilibrium between saturated steam and water using electrical heating and relief valves.
- Steam generator: in the steam generator, the heat from the primary coolant water is used to boil the water in the secondary circuit.
- Pump: the pump ensures the proper circulation of the water through the circuit.
To provide for the continued cooling of the reactor core in emergency situations the primary cooling is designed with redundancy.
Secondary circuit and electrical output
The secondary circuit also consists of different subsystems:
- Steam generator: secondary water is boiled taking heat from the primary circuit. Before entering the turbine remaining water is separated from the steam so that the steam is dry.
- Turbine: the expanding steam drives a turbine, which connects to an electrical generator. The turbine is split into high and low pressure sections. To boost efficiency, steam is reheated between these sections. Reactors of the VVER-1000 type deliver 1 GW of electrical power.
- Condenser: the steam is cooled and allowed to condense, shedding waste heat into a cooling circuit.
- Deaerator: removes gases from the coolant.
- Pump: the circulation pumps are each driven by their own small steam turbine.
To increase efficiency of the process, steam from the turbine is taken to reheat coolant in the secondary circuit before the deaerator and the steam generator. Water in this circuit is not supposed to be radioactive.
Tertiary cooling circuit and district heating
The tertiary cooling circuit is an open circuit diverting water from an outside reservoir such as a lake or river. Evaporative cooling towers, cooling basins or ponds transfer the waste heat from the generation circuit into the environment.
In most VVERs this heat can also be further used for residential and industrial heating. Operational examples of such systems are Bohunice NPP (Slovakia) supplying heat to the towns of Trnava[12] (12 kilometres [7.5 mi] away), Leopoldov (9.5 kilometres [5.9 mi] away), and Hlohovec (13 kilometres [8.1 mi] away), and Temelín NPP (Czech Republic) supplying heat to Týn nad Vltavou 5 kilometres (3.1 mi) away. Plans are made to supply heat from the Dukovany NPP to Brno (the second-largest city in the Czech Republic), covering two-thirds of its heat needs.[13]
Safety barriers
A typical design feature of nuclear reactors is layered safety barriers preventing escape of radioactive material. VVER reactors have three layers:
- Fuel rods: the hermetic Zirconium alloy (Zircaloy) cladding around the uranium oxide sintered ceramic fuel pellets provides a barrier resistant to heat and high pressure.
- Reactor pressure vessel wall: a massive steel shell encases the whole fuel assembly and primary coolant hermetically.
- Reactor building: a concrete containment building that encases the whole first circuit is strong enough to resist the pressure surge a breach in the first circuit would cause.
Compared to the RBMK reactors – the type involved in the Chernobyl disaster – the VVER uses an inherently safer design because the coolant is also the moderator, and by nature of its design has a negative void coefficient like all PWRs. It does not have the graphite-moderated RBMK's risk of increased reactivity and large power transients in the event of a loss of coolant accident. The RBMK reactors were also constructed without containment structures on grounds of cost due to their size; the VVER core is considerably smaller.[14]
Versions
VVER-440
One of the earliest versions of the VVER-type, the VVER-440 manifested certain problems with its containment building design. As it was at the beginning with the models V-230 and older not constructed to resist the design basis large pipe break, the manufacturer added with the newer model V-213 a so called Bubble condenser tower, that – with its additional volume and a number of water layers – has the aim to suppress the forces of the rapidly escaping steam without the onset of a containment-leak. As a consequence, all member-countries with plants of design VVER-440 V-230 and older were forced by the politicians of the European Union to shut them down permanently. Because of this, Bohunice Nuclear Power Plant had to close two reactors and Kozloduy Nuclear Power Plant had to close four. Whereas in the case of the Greifswald Nuclear Power Plant, the German regulatory body had already taken the same decision in the wake of the fall of the Berlin wall.
VVER-1000
When first built the VVER design was intended to be operational for 35 years. A mid-life major overhaul including a complete replacement of critical parts such as fuel and control rod channels was thought necessary after that.[15] Since RBMK reactors specified a major replacement programme at 35 years designers originally decided this needed to happen in the VVER type as well, although they are of more robust design than the RBMK type. Most of Russia's VVER plants are now reaching and passing the 35 year mark. More recent design studies have allowed for an extension of lifetime up to 50 years with replacement of equipment. New VVERs will be nameplated with the extended lifetime.
In 2010 the oldest VVER-1000, at Novovoronezh, was shut down for modernization to extend its operating life for an additional 20 years; the first to undergo such an operating life extension. The work includes the modernization of management, protection and emergency systems, and improvement of security and radiation safety systems.[16]
In 2018 Rosatom announced it had developed a thermal annealing technique for reactor pressure vessels which ameliorates radiation damage and extends service life by between 15 and 30 years. This had been demonstrated on unit 1 of the Balakovo Nuclear Power Plant.[17]
VVER-1200
The VVER-1200 (or NPP-2006 or AES-2006)[7] is an evolution of the VVER-1000 being offered for domestic and export use.[18][19] The reactor design has been refined to optimize fuel efficiency. Specifications include a $1,200 per kW overnight construction cost, 54 month planned construction time, a 60 year design lifetime at 90% capacity factor, and requiring about 35% fewer operational personnel than the VVER-1000. The VVER-1200 has a gross and net thermal efficiency of 37.5% and 34.8%. The VVER 1200 will produce 1,198 MWe of power.[20][21]
The first two units have been built at Leningrad Nuclear Power Plant II and Novovoronezh Nuclear Power Plant II. More reactors with a VVER-1200/491[22] like the Leningrad-II-design are planned (Kaliningrad and Nizhny Novgorod NPP) and under construction. The type VVER-1200/392M[23] as installed at the Novovoronezh NPP-II has also been selected for the Seversk, Zentral and South-Urals NPP. A standard version was developed as VVER-1200/513 and based on the VVER-TOI (VVER-1300/510) design.
In July 2012 a contract was agreed to build two AES-2006 in Belarus at Ostrovets and for Russia to provide a $10 billion loan to cover the project costs.[24] An AES-2006 is being bid for the Hanhikivi Nuclear Power Plant in Finland.[25] The plant supply contract was signed in 2013, but terminated in 2022 mainly due to Russian invasion of Ukraine.[26]
From 2015 to 2017 Egypt and Russia came to an agreement for the construction of four VVER-1200 units at El Dabaa Nuclear Power Plant.[27]
On 30 November 2017, concrete was poured for the nuclear island basemat for first of two VVER-1200/523 units at the Rooppur Nuclear Power Plant in Bangladesh. The power plant will be a 2.4 GWe nuclear power plant in Bangladesh. The two units generating 2.4 GWe are planned to be operational in 2023 and 2024.[28]
On 7 March 2019 China National Nuclear Corporation and Atomstroyexport signed the detailed contract for the construction of four VVER-1200s, two each at the Tianwan Nuclear Power Plant and the Xudabao Nuclear Power Plant. Construction will start in May 2021 and commercial operation of all the units is expected between 2026 and 2028.[29]
From 2020 an 18-month refuelling cycle will be piloted, resulting in an improved capacity utilisation factor compared to the previous 12-month cycle.[30]
Safety features
The nuclear part of the plant is housed in a single building acting as containment and missile shield. Besides the reactor and steam generators this includes an improved refueling machine, and the computerized reactor control systems. Likewise protected in the same building are the emergency systems, including an emergency core cooling system, emergency backup diesel power supply, and backup feed water supply,
A passive heat removal system had been added to the existing active systems in the AES-92 version of the VVER-1000 used for the Kudankulam Nuclear Power Plant in India. This has been retained for the newer VVER-1200 and future designs. The system is based on a cooling system and water tanks built on top of the containment dome.[31] The passive systems handle all safety functions for 24 hours, and core safety for 72 hours.[7]
Other new safety systems include aircraft crash protection, hydrogen recombiners, and a core catcher to contain the molten reactor core in the event of a severe accident.[19][24][32] The core catcher will be deployed in the Rooppur Nuclear Power Plant and El Dabaa Nuclear Power Plant.[33] [34]
VVER-TOI
The VVER-TOI is developed from the VVER-1200. It is aimed at development of typical optimized informative-advanced project of a new generation III+ Power Unit based on VVER technology, which meets a number of target-oriented parameters using modern information and management technologies.[35]
The main improvements from the VVER-1200 are:[4]
- power increased to 1300 MWe gross
- upgraded pressure vessel
- improved core design to improve cooling
- further developments of passive safety systems
- lower construction and operating costs with a 40-month construction time
- use of low-speed turbines
The construction of the first two VVER-TOI units was started in 2018 and 2019 at the Kursk II Nuclear Power Plant.[36][4]
In June 2019 the VVER-TOI was certified as compliant with European Utility Requirements (with certain reservations) for nuclear power plants.[4]
An upgraded version of AES-2006 with TOI standards, the VVER-1200/513, is being built in Akkuyu Nuclear Power Plant in Turkey.[37]
Future versions
A number of designs for future versions of the VVER have been made:[38]
- MIR-1200 (Modernised International Reactor) – designed in conjunction with Czech company ŠKODA JS[39] to satisfy European requirements[40]
- VVER-1500 – VVER-1000 with dimensions increased to produce 1500 MWe gross power output, but design shelved in favour of the evolutionary VVER-1200[41]
- VVER-1700 Supercritical water reactor version.
- VVER-600 two cooling circuit version of the VVER-1200 designed for smaller markets, authorised to be built by 2030 at the Kola Nuclear Power Plant.[42][43]
Power plants
Power plant | Country | Coordinates | Reactors | Notes |
---|---|---|---|---|
Akkuyu | Turkey | 36°08′40″N 33°32′28″E / 36.14444°N 33.54111°E | (4 × VVER-1200/513) (AES-2006 with TOI-Standard) | Under construction.[44] |
Astravets | Belarus | 54°45′40″N 26°5′21″E / 54.76111°N 26.08917°E | (2 × VVER-1200/491) | Unit 1 operational since 2020.[45] Unit 2 to start operating in 2023.[46] |
Balakovo | Russia | 52°5′28″N 47°57′19″E / 52.09111°N 47.95528°E | 4 × VVER-1000/320 (2 × VVER-1000/320) | Units 5 and 6 construction cancelled. To be dismantled.[47] |
Belene | Bulgaria | 43°37′46″N 25°11′12″E / 43.62944°N 25.18667°E | (2 × VVER-1000/466B) | Suspended in 2012.[48] |
Bohunice | Slovakia | 48°29′40″N 17°40′55″E / 48.49444°N 17.68194°E | 2 × VVER-440/230 2 × VVER-440/213 | Split in two plants, V-1 and V-2 with two reactors each. VVER-440/230 units at V-1 plant closed in 2006 and 2008. |
Bushehr | Iran | 28°49′46.64″N 50°53′09.46″E / 28.8296222°N 50.8859611°E | 1 × VVER-1000/446
(1 × VVER-1000/446) |
A version of the V-392 adapted to the Bushehr site.[49] Unit 2 cancelled by Rosatom in 2007, units 3 and 4 planned. |
Dukovany | Czech Republic | 4 × VVER 440/213 | Upgraded to 510 MW in 2009-2012. Upgrade to 522 MW planned.[50] | |
El Dabaa | Egypt | 31°2′39″N 28°29′52″E / 31.04417°N 28.49778°E | (4 × VVER 1200/529) | Under construction.[51][52][53] |
Greifswald | Germany | 4 × VVER-440/230 1 × VVER-440/213 (3 × VVER-440/213) | Decommissioned. Unit 6 finished, but never operated. Unit 7 and 8 construction cancelled. | |
Kalinin | Russia | 2 × VVER-1000/338 2 × VVER-1000/320 | Construction of unit 4 suspended in 1991 and unit 3 slowed down in 1990. In early 1990s construction of unit 3 restarted and commissioned in 2004. Unit 4 in 2012.[54] | |
Hanhikivi | Finland | 1 × VVER-1200/491 | Postponed indefinitely as of March 2022.[55] Contract terminated in May 2022.[26] | |
Khmelnytskyi | Ukraine | 2 × VVER-1000/320 (2 × VVER-1000/392B) | Unit 4 construction cancelled in 2021. Unit 3 planned to be completed with Czech company Škoda JS as VVER-1000 and units 5 and 6 contract signed - Westinghouse AP1000.[56] | |
Kola | Russia | 2 × VVER-440/230 2 × VVER-440/213 | All units prolonged to 60-year operation lifespan.[57] | |
Kudankulam | India | 8°10′08″N 77°42′45″E / 8.16889°N 77.71250°E | 2 × VVER-1000/412 (AES-92) (4 × VVER-1000/412) (AES-92) | Unit 1 operational since 13 July 2013; Unit 2 operational since 10 July 2016.[58] Units 3,4,5 and 6 under construction. |
Kozloduy | Bulgaria | 4 × VVER-440/230 2 × VVER-1000 | Older VVER-440/230 units closed 2004-2007. | |
Kursk II | Russia | 51°41′18″N 35°34′24″E / 51.68833°N 35.57333°E | 2 × VVER-TOI
(2 × VVER-TOI) |
First VVER-TOI.[36] |
Leningrad II | Russia | 59°49′52″N 29°03′35″E / 59.83111°N 29.05972°E | 2 × VVER-1200/491 (AES-2006)
(2 × VVER-1200/491 (AES-2006)) |
The units are the prototypes of the VVER-1200/491 (AES-2006), unit 1 in commercial operation since october 2018, unit 2 since march 2021. |
Loviisa | Finland | 2 × VVER-440/213 | Western control systems, clearly different containment structures. Later modified for a 530 MW output. | |
Metsamor | Armenia | 2 × VVER-440/270 | One reactor was shut down in 1989, unit 2 decommissioning planned in 2026. | |
Mochovce | Slovakia | 3 × VVER-440/213 (1 × VVER-440/213) | Units 3 and 4 under construction since 1985, unit 3 commissioned in 2023 and unit 4 is to be commissioned in 2025.[59] | |
Novovoronezh | Russia | 1 x VVER-210 (V-1) 1 x VVER-365 (V-3M) 2 × VVER-440/179 1 × VVER-1000/187 | All units are prototypes. Unit 1 and 2 shutdown. Unit 3 modernised in 2002.[60] | |
Novovoronezh II | Russia | 51°15′53.964″N 39°12′41.22″E / 51.26499000°N 39.2114500°E | 2 × VVER-1200/392M (AES-2006) | Unit 1 is the prototype of the VVER-1200/392M (AES-2006), commissioned in 2017, followed by unit 2 in 2019. |
Paks | Hungary | 4 × VVER-440/213 (2 × VVER-1200/517) | Two VVER-1200 units under construction.[61] | |
Rheinsberg | Germany | 1 × VVER-70 (V-2) | Unit decommissioned in 1990 | |
Rivne | Ukraine | 2 × VVER-440/213 2 × VVER-1000/320 (2 × VVER-1000/320) | Units 5 and 6 planning suspended in 1990. | |
Rooppur | Bangladesh | 24°6′47″N 89°4′07″E / 24.11306°N 89.06861°E | 2 × VVER- 1200/523 | Units 1 and 2 under construction; planned operational in 2023 and 2024.[62] |
Rostov | Russia | 47°35′57.63″N 42°22′18.76″E / 47.5993417°N 42.3718778°E | 4 × VVER-1000/320 | Plant construction suspended in 1990 - unit 1 was nearly 100% completed. Construction restarted in 1999-2000 and unit 1 commissioned in 2001 and unit 4 in 2018.[63] |
South Ukraine | Ukraine | 1 × VVER-1000/302 1 × VVER-1000/338 1 × VVER-1000/320 (1 × VVER-1000/320) | Unit 4 construction suspended in 1989 and cancelled in 1991.[64] | |
Stendal | Germany | (4 × VVER-1000/320) | All 4 units construction cancelled in 1991 after Germany reunification.[65] | |
Temelin | Czech Republic | 2 × VVER-1000/320
(2 × VVER-1000/320) |
Western control systems. Both units upgraded to 1086 MWe and commissioned in 2000 and 2002 respectively, units 3 and 4 (same type) cancelled in 1990 due to change of political regime, only foundation was completed. Units 3 and 4 now planned with a different design. | |
Tianwan | China | 34°41′13″N 119°27′35″E / 34.68694°N 119.45972°E | 2 × VVER-1000/428 (AES-91) 2 × VVER-1000/428M (AES-91) (2 × VVER-1200) | VVER-1200 construction started in May 2021 and February 2022. |
Xudabao | China | 40°21′5″N 120°32′45″E / 40.35139°N 120.54583°E | (2 × VVER-1200) | Construction on the first reactor commenced in 28 July 2021, with construction starting on the second reactor in 19 May 2022. |
Zaporizhzhia | Ukraine | 47°30′30″N 34°35′04″E / 47.50833°N 34.58444°E | 6 × VVER-1000/320 | Largest nuclear power plant in Europe. |
Technical specifications
Specifications | VVER-210[66] | VVER-365 | VVER-440 | VVER-1000 | VVER-1200 (V-392M)[67][68][69] |
VVER-1300[70][71][72] |
---|---|---|---|---|---|---|
Thermal output, MW | 760 | 1325 | 1375 | 3000 | 3212 | 3300 |
Efficiency, net % | 25.5 | 25.7 | 29.7 | 31.7 | 35.7[nb 1] | 37.9 |
Vapor pressure, in 100 kPa | ||||||
in front of the turbine | 29.0 | 29.0 | 44.0 | 60.0 | 70.0 | |
in the first circuit | 100 | 105 | 125 | 160.0 | 165.1 | 165.2 |
Water temperature, °C: | ||||||
core coolant inlet | 250 | 250 | 269 | 289 | 298.2[73] | 297.2 |
core coolant outlet | 269 | 275 | 300 | 319 | 328.6 | 328.8 |
Equivalent core diameter, m | 2.88 | 2.88 | 2.88 | 3.12 | — | |
Active core height, m | 2.50 | 2.50 | 2.50 | 3.50 | — | 3.73[74] |
Outer diameter of fuel rods, mm | 10.2 | 9.1 | 9.1 | 9.1 | 9.1 | 9.1 |
Number of fuel rods in assembly | 90 | 126 | 126 | 312 | 312 | 313 |
Number of fuel assemblies[66][75] | 349
(312+ARK (SUZ) 37) |
349
(276+ARK 73) |
349 (276+ARK 73), (312+ARK 37) Kola | 151 (109+SUZ 42),
163 |
163 | 163 |
Uranium loading, tons | 38 | 40 | 42 | 66 | 76-85.5 | 87.3 |
Average uranium enrichment, % | 2.0 | 3.0 | 3.5 | 4.26 | 4.69 | |
Average fuel burnup, MW · day / kg | 13.0 | 27.0 | 28.6 | 48.4 | 55.5 |
Classification
Generation | Name | Model | Country | Power plants |
---|---|---|---|---|
I | VVER | V-210 (V-1)[77] | Russia | Novovoronezh 1 (decommissioned) |
V-70 (V-2)[78] | East Germany | Rheinsberg (KKR) (decommissioned) | ||
V-365 (V-3M) | Russia | Novovoronezh 2 (decommissioned) | ||
II | VVER-440 | V-179 | Russia | Novovoronezh 3 (decommissioned) - 4 |
V-230 | Russia | Kola 1-2 | ||
East Germany | Greifswald 1-4 (decommissioned) | |||
Bulgaria | Kozloduy 1-4 (decommissioned) | |||
Slovakia | Bohunice I 1-2 (decommissioned) | |||
V-213 | Russia | Kola 3-4 | ||
East Germany | Greifswald 5 (decommissioned) | |||
Ukraine | Rivne 1-2 | |||
Hungary | Paks 1-4 | |||
Czech Republic | Dukovany 1-4 | |||
Finland | Loviisa 1-2 | |||
Slovakia | Bohunice II 1-2 Mochovce 1-2 | |||
V-213+ | Slovakia | Mochovce 3 Mochovce 4 (under construction) | ||
V-270 | Armenia | Armenian-1 (decommissioned) Armenian-2 | ||
III | VVER-1000 | V-187 | Russia | Novovoronezh 5 |
V-302 | Ukraine | South Ukraine 1 | ||
V-338 | Ukraine | South Ukraine 2 | ||
Russia | Kalinin 1-2 | |||
V-320 | Russia | Balakovo 1-4 Kalinin 3-4 Rostov 1-4 | ||
Ukraine | Rivne 3-4 Zaporizhzhia 1-6 Khmelnytskyi 1-2 South Ukraine 3 | |||
Bulgaria | Kozloduy 5-6 | |||
Czech Republic | Temelin 1-2 | |||
V-428 | China | Tianwan 1-2 | ||
V-428M | China | Tianwan 3-4 | ||
V-412 | India | Kudankulam 1-2 Kudankulam 3-6 (under construction) | ||
V-446 | Iran | Bushehr 1 | ||
III+ | VVER-1000 | V-528 | Iran | Bushehr 2 (under construction) |
VVER-1200 | V-392M | Russia | Novovoronezh II 1-2 | |
V-491 | Russia | Baltic 1-2 (construction frozen) Leningrad II 1-2 | ||
Belarus | Belarus 1-2 | |||
China | Tianwan 7-8 (under construction) Xudabao 3-4 (under construction) | |||
V-509 | Turkey | Akkuyu 1-4 (under construction) | ||
V-523 | Bangladesh | Ruppur 1-2 (under construction) | ||
V-529 | Egypt | El Dabaa 1-3 (under construction) | ||
VVER-1300 | V-510K | Russia | Kursk II 1-2 (under construction) |
See also
Notes
- ↑ Other sources - 34,8.
References
- ↑ "Kudankulam nuclear plant starts generating power, connected to southern grid". The Times Of India.
- ↑ "Historical notes". OKB Gidropress. Retrieved 20 September 2011.
- 1 2 "WWER-type reactor plants". OKB Gidropress. Retrieved 25 April 2013.
- 1 2 3 4 5 "Russia's VVER-TOI reactor certified by European utilities". World Nuclear News. 14 June 2019. Retrieved 14 June 2019.
- ↑ "Nuclear Reactors in Germany", World Nuclear Association
- ↑ Prof. H. Böck. "WWER/ VVER (Soviet Designed Pressurized Water Reactors)" (PDF). Vienna University of Technology. Austria Atominstitute. Retrieved 28 September 2011.
- 1 2 3 Fil, Nikolay (26–28 July 2011). "Status and perspectives of VVER nuclear power plants" (PDF). OKB Gidropress. IAEA. Retrieved 28 September 2011.
- ↑ "Rosatom Intends to Certify VVER in Great Britain and USA". Novostienergetiki.re. 6 June 2012. Retrieved 21 June 2012.
- ↑ Svetlana Burmistrova (13 August 2013). "Russia's Rosatom eyes nuclear contracts in Britain". Reuters. Retrieved 14 August 2013.
- ↑ "Reactor Vessel Head Degradation - Images | NRC.gov".
- ↑ "Atommash has manufactured the reactor cover for the First Unit of Akkuyu NPP (Turkey)". Aemtech.ru. 2020-11-26. Retrieved 2022-03-08.
- ↑ "Energy in Slovakia". www.energyinslovakia.sk. Archived from the original on 2017-07-05. Retrieved 2017-03-17.
- ↑ "Nuclear Power in the Czech Republic - Nuclear Power in Czechia". World Nuclear Association.
- ↑ Higginbotham, Adam (February 4, 2020). Midnight in Chernobyl: The Untold Story of the World's Greatest Nuclear Disaster. Simon and Schuster. ISBN 9781501134630 – via Google Books.
- ↑ Martti Antila, Tuukka Lahtinen. "Recent Core Design and Operating Experience in Loviisa NPP" (PDF). Fortum Nuclear Services LTD, Espoo, Finland. IAEA. Retrieved 20 September 2011.
- ↑ "Modernization works begin at Russia's oldest VVER-1000". Nuclear Engineering International. 30 September 2010. Archived from the original on 13 June 2011. Retrieved 10 October 2010.
- ↑ "Rosatom launches annealing technology for VVER-1000 units". World Nuclear News. 27 November 2018. Retrieved 28 November 2018.
- ↑ "AES-2006 (VVER-1200)". Rosatom. Archived from the original on 26 August 2011. Retrieved 22 September 2011.
- 1 2 Asmolov, V. G. (10 September 2009). "Development of the NPP Designs Based on the VVER Technology" (PDF). Rosatom. Retrieved 9 August 2012.
- ↑ "Russian nuclear engineers invite foreign suppliers to plant projects". World Nuclear News. 7 December 2015. Retrieved 26 March 2017.
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- ↑ Kudankulam Nuclear Power Plant attains criticality
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Once Mochovce Unit 4 is complete, around two years after Unit 3 is functioning, Slovakia is expected to become a net electricity exporter to other European Union countries.
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- 1 2 V.V. Semenov (1979). "Основные физико-технические характеристики реакторных установок ВВЭР" (PDF). IAEA.
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- ↑ Андрушечко С.А. и др. (2010). "АЭС с реактором типа ВВЭР-1000".
- ↑ Беркович В.Я., Семченков Ю.М. (2012). "Перспективные проекты реакторных установок ВВЭР" (PDF). www.rosenergoatom.ru.
- ↑ Долгов А.В. (2014). "Разработка и усовершенствование ядерного топлива для активных зон энергетических установок" (PDF). www.rosenergoatom.ru. Archived from the original (PDF) on 2018-07-19. Retrieved 2019-04-19.
- ↑ Якубенко И. А. (2013). "Основные перспективные конфигурации активных зон новых поколений реакторов типа ВВЭР". Издательство Национального исследовательского ядерного университета "МИФИ". p. 52. Retrieved 2018-11-11.
- ↑ В.П.Поваров (2016). "Перспективные проекты реакторных установок ВВЭР с. 7" (PDF). www.rosenergoatom.ru. Archived from the original (PDF) on 2018-11-23. Retrieved 2019-04-19.
- ↑ Беркович Вадим Яковлевич, Семченков Юрий Михайлович (May 2016). Развитие технологии ВВЭР – приоритет Росатома [Development of VVER technology is a priority of Rosatom] (PDF) (in Russian) (rosenergoatom.ru ed.). p. 5. Archived from the original (PDF) on 2018-11-23. Retrieved 2019-04-19.
25-27
- ↑ Сергей ПАНОВ. "У истоков водо-водяных". atomicexpert.com. Archived from the original on 2018-07-05. Retrieved 2018-07-19.
- ↑ "The VVER today" (PDF). ROSATOM. Retrieved 31 May 2018.
- ↑ Сергей Панов. "У истоков водо-водяных". atomicexpert.com. Archived from the original on 2018-07-05. Retrieved 2018-07-19.
- ↑ Денисов В.П. "Эволюция водо-водяных энергетических реакторов для АЭС p.246".
External links
- The VVER today, Rosatom, 2013
- WWER-type reactor plants, OKB Gidropress
- "VVER-1200 Reactor" (PDF). - on AEM official pdf(in English)
- VVER 1200 Construction - on AEM Official YouTube Channel(in English)