Fukushima I Nuclear Power Plant - AbsoluteAstronomy.com

The , also known as Fukushima Dai-ichi (dai-ichi means "number one"), is a disabled nuclear power plant

Nuclear power plant

A nuclear power plant is a thermal power station in which the heat source is one or more nuclear reactors. As in a conventional thermal power station the heat is used to generate steam which drives a steam turbine connected to a generator which produces electricity.Nuclear power plants are usually...

located on a 3.5 square kilometres (864.9 acre) site in the towns of Okuma

Okuma, Fukushima

is a town located in Futaba District, Fukushima, Japan.As of 2010, the town has an estimated population of 11,511 and a density of 146.26 persons per km². The total area is 78.70 km². In March 2011 the town was evacuated by government order due to the Fukushima I nuclear accident.-External ...

and Futaba

Futaba, Fukushima

is a town located in Futaba District, Fukushima, Japan.As of 2003, the town had an estimated population of 7,406 and a density of 144.09 persons per km². The total area is 51.40 km².-2011 disaster:...

in the Futaba District

Futaba District, Fukushima

is a district located in Fukushima, Japan.As of 2003, the district has an estimated population of 75,220 and a density of 86.95 persons per km². The total area is 865.12 km².-Towns and villages:*Futaba*Hirono*Katsurao*Kawauchi*Namie*Naraha*Ōkuma...

of Fukushima Prefecture

Fukushima Prefecture

is a prefecture of Japan located in the Tōhoku region on the island of Honshu. The capital is the city of Fukushima.-History:Until the Meiji Restoration, the area of Fukushima prefecture was known as Mutsu Province....

, Japan

Japan

Japan is an island nation in East Asia. Located in the Pacific Ocean, it lies to the east of the Sea of Japan, China, North Korea, South Korea and Russia, stretching from the Sea of Okhotsk in the north to the East China Sea and Taiwan in the south...

. First commissioned in 1971, the plant consists of six boiling water reactor

Boiling water reactor

The boiling water reactor is a type of light water nuclear reactor used for the generation of electrical power. It is the second most common type of electricity-generating nuclear reactor after the pressurized water reactor , also a type of light water nuclear reactor...

s (BWR). These light water reactor

Light water reactor

The light water reactor is a type of thermal reactor that uses normal water as its coolant and neutron moderator. Thermal reactors are the most common type of nuclear reactor, and light water reactors are the most common type of thermal reactor...

s 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 I was the first nuclear plant to be constructed and run entirely by the Tokyo Electric Power Company (TEPCO). The plant suffered major damage from the 9.0 earthquake

2011 Tōhoku earthquake and tsunami

The 2011 earthquake off the Pacific coast of Tohoku, also known as the 2011 Tohoku earthquake, or the Great East Japan Earthquake, was a magnitude 9.0 undersea megathrust earthquake off the coast of Japan that occurred at 14:46 JST on Friday, 11 March 2011, with the epicenter approximately east...

and subsequent tsunami

Tsunami

A tsunami is a series of water waves caused by the displacement of a large volume of a body of water, typically an ocean or a large lake...

that hit Japan on March 11, 2011 and is not expected to reopen. The earthquake and tsunami disabled the reactor cooling systems, leading to nuclear radiation leaks and triggering a 30 km evacuation zone surrounding the plant. On April 20, 2011, the Japanese authorities declared the 20 km evacuation zone a no-go area which may only be entered under government supervision.

The Fukushima II Nuclear Power Plant

Fukushima II Nuclear Power Plant

The , or Fukushima Dai-ni , is a nuclear power plant located on a site in the town of Naraha and Tomioka in the Futaba District of Fukushima Prefecture, Japan...

, or Fukushima Dai-ni, is located to the south and also run by TEPCO.

Power plant information

The reactors for Units 1, 2, and 6 were supplied by General Electric

General Electric

General Electric Company , or GE, is an American multinational conglomerate corporation incorporated in Schenectady, New York and headquartered in Fairfield, Connecticut, United States...

, those for Units 3 and 5 by Toshiba

Toshiba

is a multinational electronics and electrical equipment corporation headquartered in Tokyo, Japan. It is a diversified manufacturer and marketer of electrical products, spanning information & communications equipment and systems, Internet-based solutions and services, electronic components and...

, and Unit 4 by Hitachi

Hitachi

Hitachi is a multinational corporation specializing in high-technology.Hitachi may also refer to:*Hitachi, Ibaraki, Japan*Hitachi province, former province of Japan*Prince Hitachi and Princess Hitachi, members of the Japanese imperial family...

. All six reactors were designed by General Electric. Architectural design for General Electric's units was done by Ebasco

Electric Bond and Share Company

The Electric Bond and Share Company was originally a holding company that sold securities of electric utilities. It was created by General Electric in 1905. The company was restructured after the Public Utility Holding Company Act of 1935. Later known as EBASCO Services, it provided engineering...

. All construction was done by Kajima. Since September 2010, Unit 3 has been fueled by a small fraction (6%) of mixed-oxide (MOX) fuel

MOX fuel

Mixed oxide fuel, commonly referred to as MOX fuel, is nuclear fuel that contains more than one oxide of fissile material. MOX fuel contains plutonium blended with natural uranium, reprocessed uranium, or depleted uranium. MOX fuel is an alternative to the low-enriched uranium fuel used in the...

, rather than the low enriched uranium (LEU) used in the other reactors. Units 1–5 were built with Mark I type (light bulb torus) containment structures

Containment building

A containment building, in its most common usage, is a steel or reinforced concrete structure enclosing a nuclear reactor. It is designed, in any emergency, to contain the escape of radiation to a maximum pressure in the range of 60 to 200 psi...

. The Mark I containment structure was slightly increased in volume by Japanese engineers. Unit 6 has a Mark II type (over/under) containment structure.

Unit 1 is a 460 MW boiling water reactor

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. In February 2011, Japanese regulators granted an extension of ten years for the continued operation of the reactor. It was damaged during the 2011 Tōhoku earthquake and tsunami

2011 Tōhoku earthquake and tsunami

.

Unit 1 was designed for a peak ground acceleration

Peak ground acceleration

Peak ground acceleration is a measure of earthquake acceleration on the ground and an important input parameter for earthquake engineering, also known as the design basis earthquake ground motion...

of 0.18 g

G-force

The g-force associated with an object is its acceleration relative to free-fall. This acceleration experienced by an object is due to the vector sum of non-gravitational forces acting on an object free to move. The accelerations that are not produced by gravity are termed proper accelerations, and...

(1.74 m/s²) and a response spectrum

Response spectrum

A response spectrum is simply a plot of the peak or steady-state response of a series of oscillators of varying natural frequency, that are forced into motion by the same base vibration or shock. The resulting plot can then be used to pick off the response of any linear system, given its natural...

based on the 1952 Kern County earthquake

1952 Kern County earthquake

The 1952 Kern County earthquake occurred on July 21, 1952, in Kern County, California, with a magnitude of 7.5Mw. It was the largest earthquake to strike Southern California since the Fort Tejon earthquake of 1857 and the 1872 Lone Pine earthquake, causing immense and widespread damage. The main...

, but rated for 0.498 g. 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. All units were inspected after the 1978 Miyagi earthquake

1978 Miyagi earthquake

The occurred at 17:14 local time on 12 June. It had a magnitude of 7.7, JMA magnitude 7.4, and triggered a small tsunami. The earthquake reached a maximum intensity of Shindo 5 in Sendai and caused 28 deaths and 1,325 injuries.-Geology:...

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. The design basis for tsunamis was 5.7 meters.

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 back up power systems vulnerable to flooding. TEPCO elected to strictly follow General Electric's design in the construction of the reactors.

Site layout

The location of the plant was 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 the bluff was lowered was so that the base of the reactors could be constructed on solid bedrock to mitigate the threat posed by earthquakes. Another reason was the lowered height would keep the running costs of the seawater pumps low. TEPCO did not factor in the tsunami risk when planning the site's construction. Therefore, the lowered height would result in the plant being more vulnerable to tsunami

Tsunami

A tsunami is a series of water waves caused by the displacement of a large volume of a body of water, typically an ocean or a large lake...

.

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.

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.

Unit	Type	Containment	Start construction	First criticality	Commercial operation	Electric power	Reactor supplier	Architecture	Construction	Fuel
Fukushima I – 1	BWR Boiling water reactor The boiling water reactor is a type of light water nuclear reactor used for the generation of electrical power. It is the second most common type of electricity-generating nuclear reactor after the pressurized water reactor , also a type of light water nuclear reactor... -3	Mark I	July 25, 1967	October 10, 1970	March 26, 1971	460 MW	General Electric General Electric General Electric Company , or GE, is an American multinational conglomerate corporation incorporated in Schenectady, New York and headquartered in Fairfield, Connecticut, United States...	Ebasco	Kajima	LEU
Fukushima I – 2	BWR-4	Mark I	June 9, 1969	May 10, 1973	July 18, 1974	784 MW	General Electric	Ebasco	Kajima	LEU
Fukushima I – 3	BWR-4	Mark I	December 28, 1970	September 6, 1974	March 27, 1976	784 MW	Toshiba Toshiba is a multinational electronics and electrical equipment corporation headquartered in Tokyo, Japan. It is a diversified manufacturer and marketer of electrical products, spanning information & communications equipment and systems, Internet-based solutions and services, electronic components and...	Toshiba	Kajima	LEU/MOX MOX fuel Mixed oxide fuel, commonly referred to as MOX fuel, is nuclear fuel that contains more than one oxide of fissile material. MOX fuel contains plutonium blended with natural uranium, reprocessed uranium, or depleted uranium. MOX fuel is an alternative to the low-enriched uranium fuel used in the...
Fukushima I – 4	BWR-4	Mark I	February 12, 1973	January 28, 1978	October 12, 1978	784 MW	Hitachi Hitachi Hitachi is a multinational corporation specializing in high-technology.Hitachi may also refer to:Hitachi, Ibaraki, JapanHitachi province, former province of Japan*Prince Hitachi and Princess Hitachi, members of the Japanese imperial family...	Hitachi	Kajima
Fukushima I – 5	BWR-4	Mark I	May 22, 1972	August 26, 1977	April 18, 1978	784 MW	Toshiba	Toshiba	Kajima
Fukushima I – 6	BWR-5	Mark II	October 26, 1973	March 9, 1979	October 24, 1979	1,100 MW	General Electric	Ebasco	Kajima
Fukushima I – 7 (planned)	ABWR Advanced Boiling Water Reactor The Advanced Boiling Water Reactor is a Generation III boiling water reactor. The ABWR is currently offered by GE Hitachi Nuclear Energy and Toshiba...		Canceled 04/2011		(As originally planned) October 2016	1,380 MW			Canceled 04/2011
Fukushima I – 8 (planned)	ABWR		Canceled 04/2011		(As originally planned) October 2017	1,380 MW			Canceled 04/2011

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

The plant reactors came online from 1970 through 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. On Feb 28, 2011 TEPCO submitted a report to the Japanese Nuclear and Industrial Safety Agency

Nuclear and Industrial Safety Agency

The is a Japanese nuclear regulatory and oversight branch of the Agency for Natural Resources and Energy under the Ministry of Economy, Trade and Industry. It was created in 2001 during the 2001 Central Government Reform. It has a main office in Kasumigaseki, Chiyoda, Tokyo that works with the...

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. In 2008, the IAEA warned Japan that the Fukushima was built using outdated safety guidelines, and could be a "serious problem" during a large earthquake. The warning led to the building of an emergency response center in 2010, used during the response to the 2011 nuclear accident.

On 4 April 2011, TEPCO vice president Takashi Fujimoto announced that the company was canceling plans to build Reactors No. 7 and 8. 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. It said in the interim it will work to preserve these reactors in the state of cold shutdown.

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 US Nuclear Regulatory Commission

Nuclear Regulatory Commission

The Nuclear Regulatory Commission is an independent agency of the United States government that was established by the Energy Reorganization Act of 1974 from the United States Atomic Energy Commission, and was first opened January 19, 1975...

(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

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.

Film maker Adam Curtis

Adam Curtis

Adam Curtis is a British BAFTA winning documentarian and a writer, television producer, director and narrator. He works for BBC Current Affairs.-Early life and education:Curtis was born in 1955...

mentioned the risks of the type of boiling water reactor

Boiling water reactor

s cooling systems such as those in Fukushima I, and claimed the risks were known since 1971 in a series of documentaries in the BBC in 1992 and advised that PWR type

Pressurized water reactor

Pressurized water reactors constitute a large majority of all western nuclear power plants and are one of three types of light water reactor , the other types being boiling water reactors and supercritical water reactors...

reactors should have been used.

Incidents and accident

In 1978, fuel rods fell in reactor No. 3, causing a nuclear reaction. It took about seven and a half hours to place the rods back into proper positions.
On February 25, 2009 a manual shutdown was initiated during the middle of a startup 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 4:03am due to a pressure increase to 1029.8 psi (7,100,221.1 Pa), exceeding the regulatory limit of 1002.2 psi (6,909,925.8 Pa) 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 4:25am. Later, at 8:49am 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 began on October 18, 2008.
On 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 2:23pm a control blade drift alarm went off. On later inspection it was found that several of the rods had been unintentionally inserted.
On November 2, 2010 unit 5 had an automatic SCRAM while an operator was conducting an adjustment to the control blade insertion pattern. The SCRAM
Scram
A scram or SCRAM is an emergency shutdown of a nuclear reactor – though the term has been extended to cover shutdowns of other complex operations, such as server farms and even large model railroads...

was caused by a reactor low water level alarm. The turbine tripped along with the reactor and there was no radiation injury to workers.

Nuclear disaster of 2011

On 11 March 2011 an earthquake categorised as 9.0 M_W

2011 Tōhoku earthquake and tsunami

on the moment magnitude scale

Moment magnitude scale

The moment magnitude scale is used by seismologists to measure the size of earthquakes in terms of the energy released. The magnitude is based on the seismic moment of the earthquake, which is equal to the rigidity of the Earth multiplied by the average amount of slip on the fault and the size of...

occurred at 14:46 Japan Standard Time

Japan Standard Time

Japan Standard Time or JST is the standard timezone of Japan, and is 9 hours ahead of UTC. For example, when it is midnight in UTC, it is 09:00 in Japan Standard Time. There is no daylight saving time, though its introduction has been debated several times. Japan Standard Time is the same as...

(JST) off the northeast coast of Japan

Japan

. Units 4, 5 and 6 had been shut down prior to the earthquake for planned maintenance. The remaining reactors were shut down automatically after the earthquake

Earthquake

An earthquake is the result of a sudden release of energy in the Earth's crust that creates seismic waves. The seismicity, seismism or seismic activity of an area refers to the frequency, type and size of earthquakes experienced over a period of time...

, and the remaining decay heat of the fuel was being cooled with power from emergency generators. The subsequent destructive tsunami

Tsunami

A tsunami is a series of water waves caused by the displacement of a large volume of a body of water, typically an ocean or a large lake...

with waves of up to 14 meters (the reactors were designed to handle up to 5,7 meters) disabled emergency generators required to cool the reactors. Over the following three weeks there was evidence of partial nuclear meltdown

Nuclear meltdown

Nuclear meltdown is an informal term for a severe nuclear reactor accident that results in core damage from overheating. The term is not officially defined by the International Atomic Energy Agency or by the U.S. Nuclear Regulatory Commission...

s 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 units 1, 3 and 4 spent fuel pool

Spent fuel pool

Spent fuel pools are storage pools for spent fuel from nuclear reactors. They are typically 40 or more feet deep, with the bottom 14 feet equipped with storage racks designed to hold fuel assemblies removed from the reactor. A reactor's pool is specially designed for the reactor in which the...

s. Radiation releases caused large evacuations, concern about food and water supplies, and treatment of nuclear workers.

The events at units 1, 2 and 3 have been rated at Level 7 (major release of radioactive material with widespread health and environmental effects requiring implementation of planned and extended countermeasures) on the International Nuclear Event Scale

International Nuclear Event Scale

The International Nuclear and Radiological Event Scale was introduced in 1990 by the International Atomic Energy Agency in order to enable prompt communication of safety significance information in case of nuclear accidents....

, and those at unit 4 as Level 3 (Serious Incident) events.

On 3 April 2011, two bodies were discovered in the basement turbine room most likely because the workers ran there during the tsunami.

External links

Official site Tokyo Electric Company 東京電力・福島第一原子力発電所
TEPCO News, Tokyo Electric Power Company
TEPCO Webcam showing Fukushima I Nuclear Power Plant
Archived photo. Units 1–4 can be seen from left to right.
Radiation Dose Chart
The Fukushima Daiichi Incident prepared by Dr. Matthias Braun - 01 April 2011, PEPA4-G, AREVA–NP GmbH (cryptome.org)
3D Google Earth view

The source of this article is wikipedia, the free encyclopedia. The text of this article is licensed under the GFDL.

Power plant information

Site layout

Reactor data

Electrical connections

Operating history

Warnings and design critique

Incidents and accident

Nuclear disaster of 2011

See also

External links