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Fukushima Daiichi Nuclear Power Plant

March 11, 2023

Not to be confused with the Fukushima Daini Nuclear Power Plant.
See also: Fukushima Daiichi nuclear disaster

The Fukushima Daiichi Nuclear Power Plant (福島第一原子力発電所, Fukushima Daiichi Genshiryoku Hatsudensho, Fukushima number 1 nuclear power plant) is a disabled nuclear power plant located on a 3.5-square-kilometre (860-acre) site[1] in the towns of Ōkuma and Futaba in Fukushima Prefecture, Japan. The plant suffered major damage from the magnitude 9.0 earthquake and tsunami that hit Japan on March 11, 2011. The chain of events caused radiation leaks and permanently damaged several of its American-designed reactors, making them impossible to restart. By political decision, the remaining reactors were not restarted.

Fukushima Daiichi Nuclear Power Plant
Aerial photo from 2007.
CountryJapan
LocationŌkuma, Fukushima
Coordinates37°25′23″N 141°01′59″E / 37.42306°N 141.03306°E / 37.42306; 141.03306Coordinates: 37°25′23″N 141°01′59″E / 37.42306°N 141.03306°E / 37.42306; 141.03306
StatusBeing decommissioned
Construction beganJuly 25, 1967 (1967-07-25)
Commission dateMarch 26, 1971 (1971-03-26)
Decommission date
  • 11 March 2011
Owner(s)
Operator(s)Tokyo Electric Power Company
Nuclear power station
Reactor typeBWR
Reactor supplierGeneral Electric
Toshiba
Hitachi
Power generation
Units cancelled2 × 1,380 MW
Units decommissioned1 × 460 MW (Unit 1)
4 × 784 MW (Units 2, 3, 4 and 5)
1 × 1,100 MW (unit 6)
Nameplate capacity5,306 MW (1979–2011)
External links
Websitewww.tepco.co.jp/en/nu/press/f1-np/index-e.html
CommonsRelated media on Commons
[edit on Wikidata]

First commissioned in 1971, the plant consists of six American-designed boiling water reactors. These light water reactors[2] drove electrical generators with a combined power of 4.7 GWe, making Fukushima Daiichi one of the 15 largest nuclear power stations in the world. Fukushima was the first nuclear plant to be designed, constructed, and run in conjunction with General Electric and Tokyo Electric Power Company (TEPCO).[3]

The March 2011 disaster disabled the reactor cooling systems, leading to releases of radioactivity and triggering a 30 km (19 mi) evacuation zone surrounding the plant; the releases continue to this day. On April 20, 2011, the Japanese authorities declared the 20 km (12 mi) evacuation zone a no-go area which may only be entered under government supervision.

In November 2011, the first journalists were allowed to visit the plant. They described a scene of devastation in which three of the reactor buildings were destroyed; the grounds were covered with mangled trucks, crumpled water tanks and other debris left by the tsunami; and radioactive levels were so high that visitors were only allowed to stay for a few hours.[4]

In April 2012, Units 1–4 were shut down. Units 2–4 were shut down on April 19, while Unit 1 was the last of these four units to be shut down on April 20 at midnight.[citation needed] In December 2013 TEPCO decided none of the undamaged units will reopen.

In April 2021, the Japanese government approved the discharge of radioactive water, which has been treated to remove radionuclides other than tritium, into the Pacific Ocean over the course of 30 years.[5]

The sister nuclear plant Fukushima Daini ("number two"), 12 km (7.5 mi) to the south, is also run by TEPCO. It also suffered serious damage during the tsunami, especially at the seawater intakes of all four units, but was successfully shut down and brought to a safe state through extraordinary actions by the plant crew.[6]

Power plant information

 
Cross-section sketch of a typical BWR Mark I containment, as used in Units 1 to 5. The reactor core (1) consists of fuel rods and control rods (39) which are moved in and out by the device (31). Around the pressure vessel (8), there is an outer containment (19) which is closed by a concrete plug (2). When fuel rods are moved in or out, the crane (26) will move this plug to the pool for facilities (3). Steam from the dry well (11) can move to the wet well (24) through jet nozzles (14) to condense there (18). In the spent fuel pool (5), the used fuel rods (27) are stored.

The reactors for Units 1, 2, and 6 were supplied by General Electric, those for Units 3 and 5 by Toshiba, and Unit 4 by Hitachi. All six reactors were designed by General Electric.[7][8] Architectural design for General Electric's units was done by Ebasco. All construction was done by Kajima.[9] Since September 2010, Unit 3 has been fueled by a small fraction (6%)[10] of plutonium containing mixed-oxide (MOX) fuel, rather than the low enriched uranium (LEU) used in the other reactors.[11][12] Units 1–5 were built with Mark I type (light bulb torus) containment structures.[13][14] The Mark I containment structure was slightly increased in volume by Japanese engineers.[15] Unit 6 has a Mark II type (over/under) containment structure.[13][14][16]

Unit 1 is a 460 MWe boiling water reactor (BWR-3) constructed in July 1967. It commenced commercial electrical production on March 26, 1971, and was initially scheduled for shutdown in early 2011.[17] In February 2011, Japanese regulators granted an extension of ten years for the continued operation of the reactor.[18] It was damaged during the 2011 Tōhoku earthquake and tsunami.[19]

Unit 1 was designed for a peak ground acceleration of 0.18 g (1.74 m/s2) and a response spectrum based on the 1952 Kern County earthquake, but rated for 0.498 g.[13][20] The design basis for Units 3 and 6 were 0.45 g (4.41 m/s2) and 0.46 g (4.48 m/s2) respectively.[21] All units were inspected after the 1978 Miyagi earthquake when the ground acceleration was 0.125 g (1.22 m/s2) for 30 seconds, but no damage to the critical parts of the reactor was discovered.[13] The design basis for tsunamis was 5.7 metres (18 ft 8 in).[22]

The reactor's emergency diesel generators and DC batteries, crucial components in helping keep the reactors cool in the event of a power loss, were located in the basements of the reactor turbine buildings. The reactor design plans provided by General Electric specified placing the generators and batteries in that location, but mid-level engineers working on the construction of the plant were concerned that this made the backup power systems vulnerable to flooding. TEPCO elected to strictly follow General Electric's design in the construction of the reactors.[23]

Site layout

 
Aerial view of the plant area in 1975, showing separation between Units 5 & 6, and the majority of the complex
・Unit 6: direction of Sōma
・Unit 4: direction of Iwaki

The plant is on a bluff which was originally 35 meters above sea level. During construction, however, TEPCO lowered the height of the bluff by 25 meters. One reason for lowering the bluff was to allow the base of the reactors to be constructed on solid bedrock in order to mitigate the threat posed by earthquakes. Another reason was the lowered height would keep the running costs of the seawater pumps low. TEPCO's analysis of the tsunami risk when planning the site's construction determined that the lower elevation was safe because the sea wall would provide adequate protection for the maximum tsunami assumed by the design basis. However, the lower site elevation did increase the vulnerability for a tsunami larger than anticipated in design.[24]

The Fukushima Daiichi site is divided into two reactor groups, the leftmost group – when viewing from the ocean – contains units 4, 3, 2 and 1 going from left to right. The rightmost group – when viewing from the ocean – contains the newer units 5 and 6, respectively, the positions from left to right. A set of seawalls protrude into the ocean, with the water intake in the middle and water discharge outlets on either side.

  •  

    Aerial view of the Fukushima I plant area in 1975, showing sea walls and completed reactors

  •  

    Closeup of Units 4, 3, 2 and 1

  •  

    Major buildings

  •  

    Illustration of post-accident state of 1–4 reactors, all but 2 display obvious damage to secondary containment

Reactor data

Units 7 and 8 were planned to start construction in April 2012 and 2013 and to come into operation in October 2016 and 2017 respectively. The project was formally canceled by TEPCO in April 2011 after local authorities questioned the fact that they were still included in the supply plan for 2011, released in March 2011, after the accidents. The company stated that the plan had been drafted before the earthquake.[25]

Unit[26] Type[27]
(Containment) 		Net power[28] Start construction[28] First criticality[28] Commercial operation[28] Shutdown[28] NSSS[27] A-E[9] Builder[9]
1 BWR-3
(Mark I) 		439 MW July 25, 1967 October 10, 1970 March 26, 1971 May 19, 2011 General Electric Ebasco Kajima
2 BWR-4
(Mark I) 		760 MW June 9, 1969 May 10, 1973 July 18, 1974 May 19, 2011 General Electric Ebasco Kajima
3 BWR-4
(Mark I) 		760 MW December 28, 1970 September 6, 1974 March 27, 1976 May 19, 2011 Toshiba Toshiba Kajima
4 BWR-4
(Mark I) 		760 MW February 12, 1973 January 28, 1978 October 12, 1978 May 19, 2011 Hitachi Hitachi Kajima
5 BWR-4
(Mark I) 		760 MW May 22, 1972 August 26, 1977 April 18, 1978 December 17, 2013 Toshiba Toshiba Kajima
6 BWR-5
(Mark II) 		1067 MW October 26, 1973 March 9, 1979 October 24, 1979 December 17, 2013 General Electric Ebasco Kajima
7 (planned) ABWR 1380 MW Canceled 04/2011 Planned 10/2016
8 (planned) ABWR 1380 MW Canceled 04/2011 Planned 10/2017

Electrical connections

The Fukushima Daiichi plant is connected to the power grid by four lines, the 500 kV Futaba Line (双葉線), the two 275 kV Ōkuma Lines (大熊線) and the 66 kV Yonomori Line (夜の森線) to the Shin-Fukushima (New Fukushima) substation.

The Shin-Fukushima substation also connects to the Fukushima Daini plant by the Tomioka Line (富岡線). Its major connection to the north is the Iwaki Line (いわき幹線), which is owned by Tohoku Electric Power. It has two connections to the south-west that connect it to the Shin-Iwaki substation (新いわき).

Operating history

 
Plant still under construction circa 1971

The plant reactors came online one at a time beginning in 1970 and the last in 1979. From the end of 2002 through 2005, the reactors were among those shut down for a time for safety checks due to the TEPCO data falsification scandal.[29][30] On February 28, 2011, TEPCO submitted a report to the Japanese Nuclear and Industrial Safety Agency admitting that the company had previously submitted fake inspection and repair reports. The report revealed that TEPCO failed to inspect more than 30 technical components of the six reactors, including power boards for the reactor's temperature control valves, as well as components of cooling systems such as water pump motors and emergency power diesel generators.[31] In 2008, the IAEA warned Japan that the Fukushima plant was built using outdated safety guidelines, and could be a "serious problem" during a large earthquake.[32] The warning led to the building of an emergency response center in 2010, used during the response to the 2011 nuclear accident.[32][33]

On April 5, 2011, TEPCO vice president Takashi Fujimoto announced that the company was canceling plans to build Reactors No. 7 and 8.[34][35] On May 20 TEPCO's board of directors' officially voted to decommission Units 1 through 4 of the Fukushima Daiichi nuclear power plant and to cancel plans to build units 7 and 8. It refused however to make a decision regarding units 5 and 6 of the station or units 1 to 4 of the Fukushima Daini nuclear power station until a detailed investigation is made. In December 2013 TEPCO decided to decommission the undamaged units 5 and 6; they may be used to test remote clean-up methods before use on the damaged reactors.[36]

Electricity generation for the Fukushima I NPP by Unit in GW·h[28]
 
Electricity generation for the Fukushima I
Year Unit 1 Unit 2 Unit 3 Unit 4 Unit 5 Unit 6
1970 60.482
1971 2024.3
1972 2589.1
1973 2216.8 5.949
1974 1629.7 3670.1 284.7
1975 0 622.1 2961.8
1976 1563.9 4191.4 4807.1
1977 0 49.7 2171.1 875.1
1978 1497.6 3876.3 2753.7 3163.2 4806.7
1979 2504.4 2976 4916.3 3917.4 3898.6 3235.6
1980 1249.5 2889 4287 4317 4282.6 6441.1
1981 1084.8 3841.8 3722.8 4667.5 4553.9 7418.6
1982 2355 5290.2 2886.8 5734.7 4061.3 6666.5
1983 3019.5 3422.7 4034 4818.2 5338.8 5387.8
1984 2669.761 3698.718 4497.326 4433.166 4691.482 5933.242
1985 1699.287 4266.285 5798.641 4409.031 4112.429 5384.802
1986 2524.683 5541.101 4234.196 4315.241 4157.361 7783.537
1987 3308.888 3851.078 3748.839 5964.048 3995.012 7789.201
1988 2794.464 4101.251 5122.991 5309.892 5952.712 5593.058
1989 1440.778 6516.393 5706.694 4232.648 4766.535 5128.362
1990 2352.405 3122.761 2919.548 4273.767 3956.549 7727.073
1991 1279.986 3853.054 4491.022 6483.384 6575.818 6948.662
1992 1794.061 4568.531 6098.742 4082.747 4841.234 5213.607
1993 2500.668 4186.704 4204.301 4206.577 4059.685 6530.932
1994 3337.532 2265.961 4202.304 6323.277 4246.206 8079.391
1995 3030.829 6396.469 5966.533 5485.662 5878.681 6850.839
1996 2298.589 5192.318 4909.655 4949.891 5666.866 6157.765
1997 3258.913 4618.869 2516.651 4556.81 4609.382 9307.735
1998 3287.231 3976.16 2632.682 5441.398 5369.912 6328.985
1999 2556.93 3158.382 5116.09 5890.548 6154.135 7960.491
2000 3706.281 5167.247 5932.485 4415.901 1647.027 7495.577
2001 487.504 5996.521 5637.317 5858.452 5905.13 7778.874
2002 3120.2 5101.018 3567.314 4687.718 6590.488 6270.918
2003 0 1601.108 2483.557 0 2723.76 4623.905
2004 0 3671.49 3969.674 4728.987 5471.325 1088.787
2005 851.328 3424.939 5103.85 1515.596 2792.561 7986.451
2006 3714.606 3219.494 4081.932 4811.409 4656.9 5321.767
2007 610.761 5879.862 4312.845 5050.607 5389.565 6833.522
2008 3036.562 5289.599 6668.839 4410.285 3930.677 8424.526
2009 2637.414 4903.293 4037.601 5462.108 5720.079 7130.99
2010 2089.015 6040.782

Warnings and design critique

In 1990, the U.S. Nuclear Regulatory Commission (NRC) ranked the failure of the emergency electricity generators and subsequent failure of the cooling systems of plants in seismically very active regions one of the most likely risks. The Japanese Nuclear and Industrial Safety Agency (NISA) cited this report in 2004. According to Jun Tateno, a former NISA scientist, TEPCO did not react to these warnings and did not respond with any measures.[37]

Filmmaker Adam Curtis mentioned the risks of the type of boiling water reactors cooling systems such as those in Fukushima I,[38] and claimed the risks were known since 1971[39] in a series of documentaries in the BBC in 1992 and advised that PWR type reactors should have been used.

Tokyo Electric Power Company (TEPCO) operated the station and was warned their seawall was insufficient to withstand a powerful tsunami, but did not increase the seawall height in response. The Onagawa Nuclear Power Plant, operated by Tohoku Electric Power, ran closer to the epicenter of the earthquake, but had much more robust seawalls of greater height and avoided severe accident.[40]

Incidents and accidents

Prior to March 2011

1978

Fuel rods fell in reactor No. 3, causing a nuclear reaction.[41] It took about seven and a half hours to place the rods back into proper positions. There was no record of the incident, as TEPCO had covered it up; interviews of two former workers in 2007 led to its discovery by TEPCO management.[42]

February 25, 2009

A manual shutdown was initiated during the middle of a start-up operation. The cause was a high pressure alarm that was caused by the shutting of a turbine bypass valve. The reactor was at 12% of full power when the alarm occurred at 4:03 am (local time) due to a pressure increase to 1,030 psi (7,100 kPa), exceeding the regulatory limit of 1,002 psi (6,910 kPa). The reactor was reduced to 0% power, which exceeded the 5% threshold that requires event reporting, and pressure dropped back under the regulatory limit at 4:25 am. Later, at 8:49 am the control blades were completely inserted, constituting a manual reactor shutdown. An inspection then confirmed that one of the 8 bypass valves had closed and that the valve had a bad driving fluid connection. The reactor had been starting up following its 25th regular inspection, which had begun on October 18, 2008.[43]

March 26, 2009

Unit 3 had problems with over-insertion of control blades during outage. Repair work was being done on equipment that regulates the driving pressure for the control blades, and when a valve was opened at 2:23 pm a control blade drift alarm went off. On later inspection, it was found that several of the rods had been unintentionally inserted.[44]

November 2, 2010

Unit 5 had an automatic SCRAM while an operator was conducting an adjustment to the control blade insertion pattern. The SCRAM was caused by a reactor low water level alarm. The turbine tripped along with the reactor and there was no radiation injury to workers.[45]

Nuclear disaster of March 11, 2011

Main article: Fukushima Daiichi nuclear disaster
See also: Timeline of the Fukushima Daiichi nuclear disaster
 
Three of the reactors at Fukushima Daiichi overheated, causing meltdowns that eventually led to explosions, which released large amounts of radioactive material into the air.[46]

On March 11, 2011, an earthquake categorized as 9.0 MW on the moment magnitude scale occurred at 14:46 Japan Standard Time (JST) off the northeast coast of Japan, one of the most powerful earthquakes in history. Units 4, 5 and 6 had been "shut down" prior to the earthquake for planned maintenance.[47][48] The remaining reactors were shut down/SCRAMed automatically after the earthquake, and the remaining decay heat of the fuel was being cooled with power from emergency generators. The subsequent destructive tsunami with waves of up to 14 metres (46 ft) that over-topped the station, which had seawalls, disabled emergency generators required to cool the reactors and Spent fuel pools in Units 1–5. Over the following three weeks there was evidence of partial nuclear meltdowns in units 1, 2 and 3: visible explosions, suspected to be caused by hydrogen gas, in units 1 and 3; a suspected explosion in unit 2, that may have damaged the primary containment vessel; and a possible uncovering of the Spent fuel pools in Units 1, 3 and 4.[49] Units 5 & 6 were reported on March 19, by the station-wide alert log updates of the IAEA, to have gradually rising spent fuel pool temperatures as they had likewise lost offsite power, but onsite power provided by Unit 6's two diesel generators that had not been flooded, were configured to do double-duty and cool both Unit 5 and 6's spent fuel pools "and cores".[50] As a precautionary measure, vents in the roofs of these two units were also made to prevent the possibility of hydrogen gas pressurization and then ignition.[50]

Radiation releases from Units 1–4 forced the evacuation of 83,000 residents from towns around the plant.[51] The triple meltdown also caused concerns about contamination of food and water supplies, including the 2011 rice harvest, and also the health effects of radiation on workers at the plant.[52][53][54] Scientists estimate that the accident released 18 quadrillion becquerels of caesium-137 into the Pacific Ocean, contaminating 150 square miles of the ocean floor.[55]

The events at units 1, 2 and 3 have been rated at Level 5 each on the International Nuclear Event Scale, and those at unit 4 as Level 3 (Serious Incident) events, with the overall plant rating at Level 7 (major release of radioactive material with widespread health and environmental effects requiring implementation of planned and extended countermeasures).[56]

After March 2011

 
IAEA Experts at Fukushima Daiichi Nuclear Power Plant Unit 4, 2013

April 3, 2011

2 bodies were discovered in the basement turbine room, most likely because the workers ran there during the tsunami.

April 9, 2013

TEPCO publicly admits Radionuclide contaminated water may have leaked from the storage units, possibly contaminating the soil and water nearby. The leak was controlled and stored in containment tanks. Contaminated water continued to accumulate at the plant, and TEPCO announces plans to filter radioactive particles and discharge purified water.[57]

July 9, 2013

TEPCO officials reported that radioactive caesium was 90 times higher than it was 3 days prior (July 6), and that it may spread into the Pacific Ocean. TEPCO reported that the caesium-134 levels in the well water were measured at 9 kilobecquerel per liter, 150 times the legal level, while Caesium-137 was measured at 18 kilobecquerel per liter, 200 times the permitted level.[citation needed]

August 7, 2013

Japanese officials said highly radioactive water was leaking from Fukushima Daiichi into the Pacific Ocean at a rate of 300 tons (about 272 metric tons) per day. Japanese Prime Minister Shinzo Abe ordered government officials to step in.[58]

April 12, 2016

Reactors were being cooled with 300 tonnes of water each day.[citation needed]

September 10, 2019

Since the 3 plants was damaged by the earthquake, tsunami, and subsequent hydrogen gas explosions in 2011, TEPCO has continued to pump water onto the previously melted-down fuel cores to prevent them from once again overheating. Contaminated cooling water has collected on site, where more than 1 million tons has been stored in hundreds of tall steel tanks. Large filtration systems are used to clean the water of its radioactive contaminants, but cannot remove tritium, a radioactive isotope of hydrogen (Hydrogen-3) bonded into water molecules (tritiated water). In 2016, only 14 grams of tritium in total was estimated to be contained in 800,000 cubic meters of contaminated water stored on site.[59] As the tritium-contaminated water continued to accumulate, the site will run out of space to build more tanks by 2022, when it may have to pump the purified but tritiated water directly into the Pacific Ocean. It is not known yet how much water will be released by TEPCO, which will dilute the water first.[60]

April 13, 2021

Main article: Discharge of radioactive water of the Fukushima Daiichi Nuclear Power Plant

Japan's government approved the release of treated radioactive water from the plant into the Pacific Ocean – beginning in 2023 – over the course of an estimated 40 years.[5]

July 23, 2021

Main article: 2020 Summer Olympics

A note in the 2020 Tokyo Olympic games opening speech referenced the disaster and how Japan has recovered from the disaster.

Dismantling of reactors

 
Prime Minister Yoshihide Suga inspected the Daiichi Nuclear Power Plant on September 26, 2020

The reactors will take 30–40 years to be decommissioned.[61] On August 1, 2013, the Japanese Industry Minister Toshimitsu Motegi approved the creation of a structure to develop the technologies and processes necessary to dismantle the four reactors damaged in the Fukushima accident.[62]

To reduce the flow of contaminated water into the Pacific Ocean, TEPCO spent ¥34.5 billion (approx. $324 million) to build a 1.5 kilometer-long underground wall of frozen soil around the plant, constructed by Kajima Corporation. 1,500 one-hundred-foot long (thirty-metre), supercooled pipes were inserted into the ground in order to freeze the surrounding groundwater and soil. The wall ultimately failed to significantly decrease the groundwater flowing into the site.[63][64]

The cost of decommissioning and decontamination of the Fukushima Daiichi nuclear power plant has been estimated at $195 billion, which includes compensation payouts to victims of the disaster. The amount also includes decommissioning of Fukushima Daiichi reactors, which is estimated at $71 billion.[65] TEPCO will shoulder $143 billion of decommissioning and decontamination, while the Ministry of Finance of Japan will provide $17 billion. Other power companies will also contribute to the cost.[65]

On September 26, 2020, Prime Minister Yoshihide Suga visited the Daiichi Nuclear Power Plant to show that his cabinet prioritized the reconstruction of areas that were affected by natural and nuclear disasters.[66]

See also

 
Wikimedia Commons has media related to Fukushima I Nuclear Power Plant.
2011 earthquake and tsunami accident

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External links

  • Fukushima Daiichi Decommissioning Official site
  • . Units 1–4 can be seen from left to right.
  • 3D Google Earth view September 14, 2013, at the Wayback Machine

March 11, 2023
fukushima, daiichi, nuclear, power, plant, confused, with, fukushima, daini, nuclear, power, plant, also, fukushima, daiichi, nuclear, disaster, 福島第一原子力発電所, fukushima, daiichi, genshiryoku, hatsudensho, fukushima, number, nuclear, power, plant, disabled, nucle. Not to be confused with the Fukushima Daini Nuclear Power Plant See also Fukushima Daiichi nuclear disaster The Fukushima Daiichi Nuclear Power Plant 福島第一原子力発電所 Fukushima Daiichi Genshiryoku Hatsudensho Fukushima number 1 nuclear power plant is a disabled nuclear power plant located on a 3 5 square kilometre 860 acre site 1 in the towns of Ōkuma and Futaba in Fukushima Prefecture Japan The plant suffered major damage from the magnitude 9 0 earthquake and tsunami that hit Japan on March 11 2011 The chain of events caused radiation leaks and permanently damaged several of its American designed reactors making them impossible to restart By political decision the remaining reactors were not restarted Fukushima Daiichi Nuclear Power PlantAerial photo from 2007 CountryJapanLocationŌkuma FukushimaCoordinates37 25 23 N 141 01 59 E 37 42306 N 141 03306 E 37 42306 141 03306 Coordinates 37 25 23 N 141 01 59 E 37 42306 N 141 03306 E 37 42306 141 03306StatusBeing decommissionedConstruction beganJuly 25 1967 1967 07 25 Commission dateMarch 26 1971 1971 03 26 Decommission date11 March 2011Owner s TEPCOOperator s Tokyo Electric Power CompanyNuclear power stationReactor typeBWRReactor supplierGeneral ElectricToshibaHitachiPower generationUnits cancelled2 1 380 MWUnits decommissioned1 460 MW Unit 1 4 784 MW Units 2 3 4 and 5 1 1 100 MW unit 6 Nameplate capacity5 306 MW 1979 2011 External linksWebsitewww wbr tepco wbr co wbr jp wbr en wbr nu wbr press wbr f1 np wbr index e wbr htmlCommonsRelated media on Commons edit on Wikidata First commissioned in 1971 the plant consists of six American designed boiling water reactors These light water reactors 2 drove electrical generators with a combined power of 4 7 GWe making Fukushima Daiichi one of the 15 largest nuclear power stations in the world Fukushima was the first nuclear plant to be designed constructed and run in conjunction with General Electric and Tokyo Electric Power Company TEPCO 3 The March 2011 disaster disabled the reactor cooling systems leading to releases of radioactivity and triggering a 30 km 19 mi evacuation zone surrounding the plant the releases continue to this day On April 20 2011 the Japanese authorities declared the 20 km 12 mi evacuation zone a no go area which may only be entered under government supervision In November 2011 the first journalists were allowed to visit the plant They described a scene of devastation in which three of the reactor buildings were destroyed the grounds were covered with mangled trucks crumpled water tanks and other debris left by the tsunami and radioactive levels were so high that visitors were only allowed to stay for a few hours 4 In April 2012 Units 1 4 were shut down Units 2 4 were shut down on April 19 while Unit 1 was the last of these four units to be shut down on April 20 at midnight citation needed In December 2013 TEPCO decided none of the undamaged units will reopen In April 2021 the Japanese government approved the discharge of radioactive water which has been treated to remove radionuclides other than tritium into the Pacific Ocean over the course of 30 years 5 The sister nuclear plant Fukushima Daini number two 12 km 7 5 mi to the south is also run by TEPCO It also suffered serious damage during the tsunami especially at the seawater intakes of all four units but was successfully shut down and brought to a safe state through extraordinary actions by the plant crew 6 Contents 1 Power plant information 1 1 Site layout 1 2 Reactor data 1 3 Electrical connections 1 4 Operating history 2 Warnings and design critique 3 Incidents and accidents 3 1 Prior to March 2011 3 1 1 1978 3 1 2 February 25 2009 3 1 3 March 26 2009 3 1 4 November 2 2010 3 2 Nuclear disaster of March 11 2011 3 3 After March 2011 3 3 1 April 3 2011 3 3 2 April 9 2013 3 3 3 July 9 2013 3 3 4 August 7 2013 3 3 5 April 12 2016 3 3 6 September 10 2019 3 3 7 April 13 2021 3 3 8 July 23 2021 4 Dismantling of reactors 5 See also 6 References 7 External linksPower plant information Edit Cross section sketch of a typical BWR Mark I containment as used in Units 1 to 5 The reactor core 1 consists of fuel rods and control rods 39 which are moved in and out by the device 31 Around the pressure vessel 8 there is an outer containment 19 which is closed by a concrete plug 2 When fuel rods are moved in or out the crane 26 will move this plug to the pool for facilities 3 Steam from the dry well 11 can move to the wet well 24 through jet nozzles 14 to condense there 18 In the spent fuel pool 5 the used fuel rods 27 are stored The reactors for Units 1 2 and 6 were supplied by General Electric those for Units 3 and 5 by Toshiba and Unit 4 by Hitachi All six reactors were designed by General Electric 7 8 Architectural design for General Electric s units was done by Ebasco All construction was done by Kajima 9 Since September 2010 Unit 3 has been fueled by a small fraction 6 10 of plutonium containing mixed oxide MOX fuel rather than the low enriched uranium LEU used in the other reactors 11 12 Units 1 5 were built with Mark I type light bulb torus containment structures 13 14 The Mark I containment structure was slightly increased in volume by Japanese engineers 15 Unit 6 has a Mark II type over under containment structure 13 14 16 Unit 1 is a 460 MWe boiling water reactor BWR 3 constructed in July 1967 It commenced commercial electrical production on March 26 1971 and was initially scheduled for shutdown in early 2011 17 In February 2011 Japanese regulators granted an extension of ten years for the continued operation of the reactor 18 It was damaged during the 2011 Tōhoku earthquake and tsunami 19 Unit 1 was designed for a peak ground acceleration of 0 18 g 1 74 m s2 and a response spectrum based on the 1952 Kern County earthquake but rated for 0 498 g 13 20 The design basis for Units 3 and 6 were 0 45 g 4 41 m s2 and 0 46 g 4 48 m s2 respectively 21 All units were inspected after the 1978 Miyagi earthquake when the ground acceleration was 0 125 g 1 22 m s2 for 30 seconds but no damage to the critical parts of the reactor was discovered 13 The design basis for tsunamis was 5 7 metres 18 ft 8 in 22 The reactor s emergency diesel generators and DC batteries crucial components in helping keep the reactors cool in the event of a power loss were located in the basements of the reactor turbine buildings The reactor design plans provided by General Electric specified placing the generators and batteries in that location but mid level engineers working on the construction of the plant were concerned that this made the backup power systems vulnerable to flooding TEPCO elected to strictly follow General Electric s design in the construction of the reactors 23 Site layout Edit Aerial view of the plant area in 1975 showing separation between Units 5 amp 6 and the majority of the complex Unit 6 direction of Sōma Unit 4 direction of Iwaki The plant is on a bluff which was originally 35 meters above sea level During construction however TEPCO lowered the height of the bluff by 25 meters One reason for lowering the bluff was to allow the base of the reactors to be constructed on solid bedrock in order to mitigate the threat posed by earthquakes Another reason was the lowered height would keep the running costs of the seawater pumps low TEPCO s analysis of the tsunami risk when planning the site s construction determined that the lower elevation was safe because the sea wall would provide adequate protection for the maximum tsunami assumed by the design basis However the lower site elevation did increase the vulnerability for a tsunami larger than anticipated in design 24 The Fukushima Daiichi site is divided into two reactor groups the leftmost group when viewing from the ocean contains units 4 3 2 and 1 going from left to right The rightmost group when viewing from the ocean contains the newer units 5 and 6 respectively the positions from left to right A set of seawalls protrude into the ocean with the water intake in the middle and water discharge outlets on either side Aerial view of the Fukushima I plant area in 1975 showing sea walls and completed reactors Closeup of Units 4 3 2 and 1 Major buildings Illustration of post accident state of 1 4 reactors all but 2 display obvious damage to secondary containmentReactor data Edit Units 7 and 8 were planned to start construction in April 2012 and 2013 and to come into operation in October 2016 and 2017 respectively The project was formally canceled by TEPCO in April 2011 after local authorities questioned the fact that they were still included in the supply plan for 2011 released in March 2011 after the accidents The company stated that the plan had been drafted before the earthquake 25 Unit 26 Type 27 Containment Net power 28 Start construction 28 First criticality 28 Commercial operation 28 Shutdown 28 NSSS 27 A E 9 Builder 9 1 BWR 3 Mark I 439 MW July 25 1967 October 10 1970 March 26 1971 May 19 2011 General Electric Ebasco Kajima2 BWR 4 Mark I 760 MW June 9 1969 May 10 1973 July 18 1974 May 19 2011 General Electric Ebasco Kajima3 BWR 4 Mark I 760 MW December 28 1970 September 6 1974 March 27 1976 May 19 2011 Toshiba Toshiba Kajima4 BWR 4 Mark I 760 MW February 12 1973 January 28 1978 October 12 1978 May 19 2011 Hitachi Hitachi Kajima5 BWR 4 Mark I 760 MW May 22 1972 August 26 1977 April 18 1978 December 17 2013 Toshiba Toshiba Kajima6 BWR 5 Mark II 1067 MW October 26 1973 March 9 1979 October 24 1979 December 17 2013 General Electric Ebasco Kajima7 planned ABWR 1380 MW Canceled 04 2011 Planned 10 20168 planned ABWR 1380 MW Canceled 04 2011 Planned 10 2017Electrical connections Edit The Fukushima Daiichi plant is connected to the power grid by four lines the 500 kV Futaba Line 双葉線 the two 275 kV Ōkuma Lines 大熊線 and the 66 kV Yonomori Line 夜の森線 to the Shin Fukushima New Fukushima substation The Shin Fukushima substation also connects to the Fukushima Daini plant by the Tomioka Line 富岡線 Its major connection to the north is the Iwaki Line いわき幹線 which is owned by Tohoku Electric Power It has two connections to the south west that connect it to the Shin Iwaki substation 新いわき Operating history Edit Plant still under construction circa 1971 The plant reactors came online one at a time beginning in 1970 and the last in 1979 From the end of 2002 through 2005 the reactors were among those shut down for a time for safety checks due to the TEPCO data falsification scandal 29 30 On February 28 2011 TEPCO submitted a report to the Japanese Nuclear and Industrial Safety Agency admitting that the company had previously submitted fake inspection and repair reports The report revealed that TEPCO failed to inspect more than 30 technical components of the six reactors including power boards for the reactor s temperature control valves as well as components of cooling systems such as water pump motors and emergency power diesel generators 31 In 2008 the IAEA warned Japan that the Fukushima plant was built using outdated safety guidelines and could be a serious problem during a large earthquake 32 The warning led to the building of an emergency response center in 2010 used during the response to the 2011 nuclear accident 32 33 On April 5 2011 TEPCO vice president Takashi Fujimoto announced that the company was canceling plans to build Reactors No 7 and 8 34 35 On May 20 TEPCO s board of directors officially voted to decommission Units 1 through 4 of the Fukushima Daiichi nuclear power plant and to cancel plans to build units 7 and 8 It refused however to make a decision regarding units 5 and 6 of the station or units 1 to 4 of the Fukushima Daini nuclear power station until a detailed investigation is made In December 2013 TEPCO decided to decommission the undamaged units 5 and 6 they may be used to test remote clean up methods before use on the damaged reactors 36 Electricity generation for the Fukushima I NPP by Unit in GW h 28 Electricity generation for the Fukushima I Year Unit 1 Unit 2 Unit 3 Unit 4 Unit 5 Unit 61970 60 4821971 2024 31972 2589 11973 2216 8 5 9491974 1629 7 3670 1 284 71975 0 622 1 2961 81976 1563 9 4191 4 4807 11977 0 49 7 2171 1 875 11978 1497 6 3876 3 2753 7 3163 2 4806 71979 2504 4 2976 4916 3 3917 4 3898 6 3235 61980 1249 5 2889 4287 4317 4282 6 6441 11981 1084 8 3841 8 3722 8 4667 5 4553 9 7418 61982 2355 5290 2 2886 8 5734 7 4061 3 6666 51983 3019 5 3422 7 4034 4818 2 5338 8 5387 81984 2669 761 3698 718 4497 326 4433 166 4691 482 5933 2421985 1699 287 4266 285 5798 641 4409 031 4112 429 5384 8021986 2524 683 5541 101 4234 196 4315 241 4157 361 7783 5371987 3308 888 3851 078 3748 839 5964 048 3995 012 7789 2011988 2794 464 4101 251 5122 991 5309 892 5952 712 5593 0581989 1440 778 6516 393 5706 694 4232 648 4766 535 5128 3621990 2352 405 3122 761 2919 548 4273 767 3956 549 7727 0731991 1279 986 3853 054 4491 022 6483 384 6575 818 6948 6621992 1794 061 4568 531 6098 742 4082 747 4841 234 5213 6071993 2500 668 4186 704 4204 301 4206 577 4059 685 6530 9321994 3337 532 2265 961 4202 304 6323 277 4246 206 8079 3911995 3030 829 6396 469 5966 533 5485 662 5878 681 6850 8391996 2298 589 5192 318 4909 655 4949 891 5666 866 6157 7651997 3258 913 4618 869 2516 651 4556 81 4609 382 9307 7351998 3287 231 3976 16 2632 682 5441 398 5369 912 6328 9851999 2556 93 3158 382 5116 09 5890 548 6154 135 7960 4912000 3706 281 5167 247 5932 485 4415 901 1647 027 7495 5772001 487 504 5996 521 5637 317 5858 452 5905 13 7778 8742002 3120 2 5101 018 3567 314 4687 718 6590 488 6270 9182003 0 1601 108 2483 557 0 2723 76 4623 9052004 0 3671 49 3969 674 4728 987 5471 325 1088 7872005 851 328 3424 939 5103 85 1515 596 2792 561 7986 4512006 3714 606 3219 494 4081 932 4811 409 4656 9 5321 7672007 610 761 5879 862 4312 845 5050 607 5389 565 6833 5222008 3036 562 5289 599 6668 839 4410 285 3930 677 8424 5262009 2637 414 4903 293 4037 601 5462 108 5720 079 7130 992010 2089 015 6040 782Warnings and design critique EditIn 1990 the U S Nuclear Regulatory Commission NRC ranked the failure of the emergency electricity generators and subsequent failure of the cooling systems of plants in seismically very active regions one of the most likely risks The Japanese Nuclear and Industrial Safety Agency NISA cited this report in 2004 According to Jun Tateno a former NISA scientist TEPCO did not react to these warnings and did not respond with any measures 37 Filmmaker Adam Curtis mentioned the risks of the type of boiling water reactors cooling systems such as those in Fukushima I 38 and claimed the risks were known since 1971 39 in a series of documentaries in the BBC in 1992 and advised that PWR type reactors should have been used Tokyo Electric Power Company TEPCO operated the station and was warned their seawall was insufficient to withstand a powerful tsunami but did not increase the seawall height in response The Onagawa Nuclear Power Plant operated by Tohoku Electric Power ran closer to the epicenter of the earthquake but had much more robust seawalls of greater height and avoided severe accident 40 Incidents and accidents EditPrior to March 2011 Edit 1978 Edit Fuel rods fell in reactor No 3 causing a nuclear reaction 41 It took about seven and a half hours to place the rods back into proper positions There was no record of the incident as TEPCO had covered it up interviews of two former workers in 2007 led to its discovery by TEPCO management 42 February 25 2009 Edit A manual shutdown was initiated during the middle of a start up operation The cause was a high pressure alarm that was caused by the shutting of a turbine bypass valve The reactor was at 12 of full power when the alarm occurred at 4 03 am local time due to a pressure increase to 1 030 psi 7 100 kPa exceeding the regulatory limit of 1 002 psi 6 910 kPa The reactor was reduced to 0 power which exceeded the 5 threshold that requires event reporting and pressure dropped back under the regulatory limit at 4 25 am Later at 8 49 am the control blades were completely inserted constituting a manual reactor shutdown An inspection then confirmed that one of the 8 bypass valves had closed and that the valve had a bad driving fluid connection The reactor had been starting up following its 25th regular inspection which had begun on October 18 2008 43 March 26 2009 Edit Unit 3 had problems with over insertion of control blades during outage Repair work was being done on equipment that regulates the driving pressure for the control blades and when a valve was opened at 2 23 pm a control blade drift alarm went off On later inspection it was found that several of the rods had been unintentionally inserted 44 November 2 2010 Edit Unit 5 had an automatic SCRAM while an operator was conducting an adjustment to the control blade insertion pattern The SCRAM was caused by a reactor low water level alarm The turbine tripped along with the reactor and there was no radiation injury to workers 45 Nuclear disaster of March 11 2011 Edit Main article Fukushima Daiichi nuclear disaster See also Timeline of the Fukushima Daiichi nuclear disaster Three of the reactors at Fukushima Daiichi overheated causing meltdowns that eventually led to explosions which released large amounts of radioactive material into the air 46 On March 11 2011 an earthquake categorized as 9 0 MW on the moment magnitude scale occurred at 14 46 Japan Standard Time JST off the northeast coast of Japan one of the most powerful earthquakes in history Units 4 5 and 6 had been shut down prior to the earthquake for planned maintenance 47 48 The remaining reactors were shut down SCRAMed automatically after the earthquake and the remaining decay heat of the fuel was being cooled with power from emergency generators The subsequent destructive tsunami with waves of up to 14 metres 46 ft that over topped the station which had seawalls disabled emergency generators required to cool the reactors and Spent fuel pools in Units 1 5 Over the following three weeks there was evidence of partial nuclear meltdowns in units 1 2 and 3 visible explosions suspected to be caused by hydrogen gas in units 1 and 3 a suspected explosion in unit 2 that may have damaged the primary containment vessel and a possible uncovering of the Spent fuel pools in Units 1 3 and 4 49 Units 5 amp 6 were reported on March 19 by the station wide alert log updates of the IAEA to have gradually rising spent fuel pool temperatures as they had likewise lost offsite power but onsite power provided by Unit 6 s two diesel generators that had not been flooded were configured to do double duty and cool both Unit 5 and 6 s spent fuel pools and cores 50 As a precautionary measure vents in the roofs of these two units were also made to prevent the possibility of hydrogen gas pressurization and then ignition 50 Radiation releases from Units 1 4 forced the evacuation of 83 000 residents from towns around the plant 51 The triple meltdown also caused concerns about contamination of food and water supplies including the 2011 rice harvest and also the health effects of radiation on workers at the plant 52 53 54 Scientists estimate that the accident released 18 quadrillion becquerels of caesium 137 into the Pacific Ocean contaminating 150 square miles of the ocean floor 55 The events at units 1 2 and 3 have been rated at Level 5 each on the International Nuclear Event Scale and those at unit 4 as Level 3 Serious Incident events with the overall plant rating at Level 7 major release of radioactive material with widespread health and environmental effects requiring implementation of planned and extended countermeasures 56 After March 2011 Edit IAEA Experts at Fukushima Daiichi Nuclear Power Plant Unit 4 2013 April 3 2011 Edit 2 bodies were discovered in the basement turbine room most likely because the workers ran there during the tsunami April 9 2013 Edit TEPCO publicly admits Radionuclide contaminated water may have leaked from the storage units possibly contaminating the soil and water nearby The leak was controlled and stored in containment tanks Contaminated water continued to accumulate at the plant and TEPCO announces plans to filter radioactive particles and discharge purified water 57 July 9 2013 Edit TEPCO officials reported that radioactive caesium was 90 times higher than it was 3 days prior July 6 and that it may spread into the Pacific Ocean TEPCO reported that the caesium 134 levels in the well water were measured at 9 kilobecquerel per liter 150 times the legal level while Caesium 137 was measured at 18 kilobecquerel per liter 200 times the permitted level citation needed August 7 2013 Edit Japanese officials said highly radioactive water was leaking from Fukushima Daiichi into the Pacific Ocean at a rate of 300 tons about 272 metric tons per day Japanese Prime Minister Shinzo Abe ordered government officials to step in 58 April 12 2016 Edit Reactors were being cooled with 300 tonnes of water each day citation needed September 10 2019 Edit Since the 3 plants was damaged by the earthquake tsunami and subsequent hydrogen gas explosions in 2011 TEPCO has continued to pump water onto the previously melted down fuel cores to prevent them from once again overheating Contaminated cooling water has collected on site where more than 1 million tons has been stored in hundreds of tall steel tanks Large filtration systems are used to clean the water of its radioactive contaminants but cannot remove tritium a radioactive isotope of hydrogen Hydrogen 3 bonded into water molecules tritiated water In 2016 only 14 grams of tritium in total was estimated to be contained in 800 000 cubic meters of contaminated water stored on site 59 As the tritium contaminated water continued to accumulate the site will run out of space to build more tanks by 2022 when it may have to pump the purified but tritiated water directly into the Pacific Ocean It is not known yet how much water will be released by TEPCO which will dilute the water first 60 April 13 2021 Edit Main article Discharge of radioactive water of the Fukushima Daiichi Nuclear Power Plant Japan s government approved the release of treated radioactive water from the plant into the Pacific Ocean beginning in 2023 over the course of an estimated 40 years 5 July 23 2021 Edit Main article 2020 Summer Olympics A note in the 2020 Tokyo Olympic games opening speech referenced the disaster and how Japan has recovered from the disaster Dismantling of reactors Edit Prime Minister Yoshihide Suga inspected the Daiichi Nuclear Power Plant on September 26 2020 The reactors will take 30 40 years to be decommissioned 61 On August 1 2013 the Japanese Industry Minister Toshimitsu Motegi approved the creation of a structure to develop the technologies and processes necessary to dismantle the four reactors damaged in the Fukushima accident 62 To reduce the flow of contaminated water into the Pacific Ocean TEPCO spent 34 5 billion approx 324 million to build a 1 5 kilometer long underground wall of frozen soil around the plant constructed by Kajima Corporation 1 500 one hundred foot long thirty metre supercooled pipes were inserted into the ground in order to freeze the surrounding groundwater and soil The wall ultimately failed to significantly decrease the groundwater flowing into the site 63 64 The cost of decommissioning and decontamination of the Fukushima Daiichi nuclear power plant has been estimated at 195 billion which includes compensation payouts to victims of the disaster The amount also includes decommissioning of Fukushima Daiichi reactors which is estimated at 71 billion 65 TEPCO will shoulder 143 billion of decommissioning and decontamination while the Ministry of Finance of Japan will provide 17 billion Other power companies will also contribute to the cost 65 On September 26 2020 Prime Minister Yoshihide Suga visited the Daiichi Nuclear Power Plant to show that his cabinet prioritized the reconstruction of areas that were affected by natural and nuclear disasters 66 See also Edit 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in Fukushima I 1 February 2 2009 Tepco official release Japanese Over insertion of control rods in Fukushima I 3 Tepco official release Japanese Fukushima I 5 Automatic SCRAM Information Martin Fackler June 1 2011 Report Finds Japan Underestimated Tsunami Danger New York Times Black Richard March 15 2011 Reactor breach worsens prospects BBC News Retrieved March 17 2011 Biela Liwag Government Scientists on Japan Nuke Meltdown No need to worry Noypi ph Retrieved March 14 2011 Conditions of Fukushima Dai ichi Nuclear Power Station Unit 2 as of 14 00 March 27 2011 PDF Archived from the original PDF on May 23 2011 Retrieved February 7 2017 a b Japanese Earthquake Update 19 March 2011 4 30 UTC IAEA Alert Log Fukushima Daiichi Nuclear Accident June 7 2011 Archived from the original on June 7 2011 Retrieved February 7 2017 Fackler Martin October 1 2013 Japan s Nuclear Refugees Still Stuck in Limbo The New York Times Retrieved July 27 2019 Anxiety in Tokyo over radiation in tap water Radiation leak feared at nuke plant people urged to stay indoors Kyodo News Agency March 15 2011 Archived from the original on March 16 2011 Martin Fackler January 21 2012 Japanese Struggle to Protect Their Food Supply The New York Times Martin Fackler and Hiroko Tabuchi October 24 2013 With a Plant s Tainted Water Still Flowing No End to Environment Fears The New York Times Retrieved July 27 2019 Japan Earthquake Update IAEA March 19 2011 RussiaToday 1 Fackler Martin August 7 2013 Japan Stepping in to Help Clean Up Atomic Plant The New York Times Retrieved July 27 2019 Tritiated Water Task Force Repor PDF Tritiated Water Task Forc Japan will have to dump radioactive Fukushima water into Pacific minister says Reuters September 10 2019 Fukushima Daiichi Decommissioning Project TEPCO www7 tepco co jp Retrieved December 22 2018 Fukushima une structure dediee aux technologies de demantelement des reacteurs Actu environnement August 2 2013 Fackler Martin August 29 2016 Japan s 320 Million Gamble at Fukushima An Underground Ice Wall The New York Times Retrieved July 27 2019 Tepco s ice wall fails to freeze Fukushima s toxic water buildup Reuters March 8 2018 Retrieved July 2 2020 a b Fukushima Daiichi Nuclear Power Plant Decommissioning NS Energy Retrieved June 3 2022 PM Suga Makes 1st Fukushima Visit since Taking Office Nippon com September 26 2020 Archived from the original on November 11 2020 External links EditFukushima Daiichi Nuclear Power Plant at Wikipedia s sister projects Media from Commons News from Wikinews Fukushima Daiichi Decommissioning Official site Archived photo Units 1 4 can be seen from left to right 3D Google Earth view Archived September 14 2013 at the Wayback Machine Retrieved from https en wikipedia org w index php title Fukushima Daiichi Nuclear Power Plant amp oldid 1139178960, wikipedia, wiki, book, books, library,

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