Nuclear power in China

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As of March 2016, the People's Republic of China has 33 nuclear reactors operating with a capacity of 28.8 GW and 22 under construction with a capacity of 22.1 GW.[1][2][3] Additional reactors are planned, providing 58 GW of capacity by 2020.[4] China's National Development and Reform Commission has indicated the intention to raise the percentage of China's electricity produced by nuclear power from the current 2% to 6% by 2020 (compared to 20% in the United States and 74% in France).[5][not in citation given] Nuclear power contributed 3% of the total production in 2015 – 170 billion kWh.[6] Nuclear was the fastest-growing electricity source in 2015 (29% growth)[7] However, rapid nuclear expansion may lead to a shortfall of fuel, equipment, qualified plant workers, and safety inspectors.[8][9]

Due to increasing concerns about air quality, climate change and fossil fuel shortages, nuclear power has been looked into as an alternative to coal power in China.[10][11] China has two major nuclear power companies, the China National Nuclear Corporation operating mainly in north-east China, and the China General Nuclear Power Group, - formerly known as China Guangdong Nuclear Power Group, - operating mainly in south-east China.[12] The People's Republic of China is also involved in the development of nuclear fusion reactors through its participation in the ITER project, having constructed an experimental nuclear fusion reactor known as EAST located in Hefei,[13] as well as research and development into the thorium fuel cycle as a potential alternative means of nuclear fission.[14]

China wants to maximize self-reliance on nuclear reactor technology manufacturing and design although international cooperation and technology transfer are also encouraged. Advanced pressurized water reactors such as the ACPR1000 and the AP1000 are the mainstream technology in the near future. By mid-century fast neutron reactors are seen as the main technology. More long-term plans for future capacity are 120-150 GW by 2030.[15] Fast neutron reactors are planned to contribute 1400 GW by 2100.[16][17][18]

China is positioned to become a reactor exporter, through development of the CPR-1000.[19]

The nuclear safety plan of 2013 stated that beyond 2016 only Generation III plants would be started, and until then only a very few Generation II+ plants would be built.[20]

History

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On 8 February 1970, China issued its first nuclear power plan, and the 728 Institute (now called Shanghai Nuclear Engineering Research and Design Institute)[21] was founded. On 15 December 1991, China's first nuclear power reactor, a 288 MWe PWR at the Qinshan Nuclear Power Plant, was connected to the grid.[22]

Geography

Nuclear power plants in China (view)
Red pog.svg Active plants
Green pog.svg Under construction plants
Blue pog.svg Firmly planned plants

Most nuclear power plants in China are located on the coast and generally use seawater for cooling a direct once-through cycle. The New York Times has reported that China is placing many of its nuclear plants near large cities, and there is a concern that tens of millions of people could be exposed to radiation in the event of an accident.[12] China's neighboring Guangdong and Lingao nuclear plants have around 28 million people within a 75-kilometre radius that covers Hong Kong.[23]

China is evaluating the construction of a high level waste (HLW) repository in the Gobi Desert, probably constructed near Beishan starting around 2041.[24]

Future projects

Following the Fukushima accident and consequent pause in approvals for new plants, the target adopted by the State Council in October 2012 became 60 GWe by 2020, with 30 GWe under construction. In 2015 the target for nuclear capacity on line in 2030 was 150 GWe, providing almost 10% of electricity, and 240 GWe in 2050 providing 15%. However the post-Fukushima slowdown may mean that the 2030 figure is only about 120 GWe.[15][25] These have reduced the targets from before the Fukushima accident of having over 80 GWe (6%) of installed capacity by 2020, and a further increase to more than 200 GW (16%) by 2030,[26] as agreed in the 22 March 2006 government "Long-term development plan for nuclear power industry from 2005 to 2020".[22] The State Council Research Office (SCRO) has recommended that China aim for no more than 100 GW before 2020 (built and building), in order to avoid a shortfall of fuel, equipment and qualified plant workers. It expressed concern that China is building several dozen more Generation 2 reactors, and recommended shifting faster to Generation 3 designs such as the AP1000.[27][28]

Following the 2011 Fukushima Daiichi nuclear disaster in Japan, China froze new plant approvals,[29] followed by a slow down in the programme. No new approvals were made during 2014.[30] In 2015 the EPR and AP1000 builds were reported to be running over two years late, mainly due to key component delays and project management issues.[30] However these delays do not necessarily put the overall programme to 2030 in doubt.[30]

In September 2015 State Nuclear Power Technology Corporation president, Zhongtang Wang, stated that by the end of 2015, China would have 53 nuclear power units operating or under construction, and this should reach 88 by the end of 2020.[31]

The role of the IPPs

The first major successful profitable commercial project was the Daya Bay Nuclear Plant, which is 25% owned by CLP Group of Hong Kong and exports 70% of its electricity to Hong Kong. Such imports supply 20% of Hong Kong's electricity.

In order to access the capital needed to meet the 2020 target of 80GW, China has begun to grant equity in nuclear projects to China's Big Five power corporations:

Like the two nuclear companies China National Nuclear Corporation and China Guangdong Nuclear Power Group (CGNPG) the Big Five are State-owned "Central Enterprises" (中央企业) administered by SASAC. However, unlike the two nuclear companies, they have listed subsidiaries in Hong Kong and a broad portfolio of thermal, hydro and wind.

Generation IV

Rudolf Schulten, father of the AVR reactor.

The HTR-PM is as of July 2015 slated for completion in 2017. It is a HTGR, a Generation IV design. The HTR-PM is a descendant of the AVR reactor.

Safety and regulation

The National Nuclear Safety Administration (NNSA), under the China Atomic Energy Authority, is the licensing and regulatory body which also maintains international agreements regarding safety. It was set up in 1984 and reports to the State Council directly. In relation to the AP1000, NNSA works closely with the US Nuclear Regulatory Commission.

China has requested and hosted 12 Operational Safety Review Team (OSART) missions from IAEA teams to October 2011, and each plant generally has one external safety review each year, either OSART, WANO peer review, or CNEA peer review (with the Research Institute for Nuclear Power Operations).[32]

The challenge (in the proposed rapid build-out of nuclear power) for the government and nuclear companies is to "keep an eye on a growing army of contractors and subcontractors who may be tempted to cut corners".[12] China is advised to maintain nuclear safeguards in a business culture where quality and safety are sometimes sacrificed in favor of cost-cutting, profits, and corruption. China has asked for international assistance in training more nuclear power plant inspectors.[12]

Following the Fukushima Daiichi nuclear disaster in Japan, China announced on 16 March 2011, that all nuclear plant approvals were being frozen, and that 'full safety checks' of existing reactors would be made.[29][33] Although Zhang Lijun, Vice Minister of Environmental Protection, has indicated that China's overall nuclear energy strategy would continue,[33] some commentators have suggested that additional safety-related costs and public opinion could cause a rethink in favor of an expanded renewable energy program.[33][34] In April 2011, China Daily reported that approvals for construction of nuclear power plants in marine areas have been suspended.[35] The safety inspections were due to finish by October 2011, and the current status of the projects is unclear.[36] In April 2012, Reuters reported that China was likely to resume nuclear power plants approvals sometime during the first half of 2012. The official target of a capacity of 40 GW by 2020 is unchanged but earlier plans to increase this to 86 GW has been reduced to 70-75 GW due shortages of equipment and qualified personnel as well as safety concerns.[37]

China's current methods for storing spent nuclear fuel (SNF) are only sustainable until the mid 2020s, and a policy to handle SNF needs to be developed.[38]

Reactor Technology

CPR-1000

The most numerous reactor type under construction is the CPR-1000, with fifteen units under construction as of June 2010, and another 15 approved and proposed. This reactor type is a Chinese development of the French 900 MWe three cooling loop design imported in the 1990s, with most of the components now built in China. Intellectual property rights are retained by Areva however, which affects CPR-1000 overseas sales potential.[10]

On 15 July 2010, China’s first CPR-1000 nuclear power plant, Ling Ao-3, was connected to the grid.[39]

China plans to develop a domestic program to become self-sufficient in reactor design and construction, as well as other parts of the fuel cycle, though they currently operate using imported Uranium. Shu Guogang, GM of China Guangdong Nuclear Power Project said, "We built 55 percent of Ling Ao Phase 2, 70 percent of Hongyanhe, 80 percent of Ningde and 90 percent of Yangjiang Station."[40]

AP1000

Sanmen Nuclear Power Plant, located in Zhejiang China

The Westinghouse AP1000 is the main basis of China's move to Generation III technology, and involves a major technology transfer agreement. It is a 1250 MWe gross reactor with two coolant loops. The first four AP1000 reactors are being built at Sanmen and Haiyang, for CNNC and CPI respectively. At least eight more at four sites are firmly planned after them.[22] In 2015 the build was reported to be running over two years late, mainly due to key component delays and project management issues.[30]

EPR

In 2007 negotiations were started with the French company Areva concerning the European Pressurized Reactor (EPR), third generation reactors. Two Areva EPR reactors are being built at Taishan, and at least two more are planned. Areva says the reactors are 4590 MWt, with net power 1660 MWe.

In October 2008, Areva and CGNPC announced establishment of an engineering joint venture as a technology transfer vehicle for development EPR and other PWR plants in China and later abroad. The JV will be held 55% by CGNPC and other Chinese interests, and 45% by Areva. It will engineer and procure equipment for both the EPR and the CPR-1000.

In 2015 the build was reported to be running over two years late, mainly due to key component delays and project management issues.[30]

CAP1400 development

In 2008 and 2009 Westinghouse made agreements to work with the State Nuclear Power Technology Corporation (SNPTC) and other institutes to develop a larger version of the AP1000, probably of 1400 MWe capacity, possibly followed by a 1700 MWe design. China will own the intellectual property rights for these larger designs. Exporting the new larger units may be possible with Westinghouse's cooperation.[10]

In December 2009, a Chinese joint venture was set up to build an initial CAP1400 near the HTR-10 Shidaowan site.[10][41] In 2015 site preparation started, and approval to progress was expected by the end of the year.[31]

ACPR1000 development

In 2010 the China Guangdong Nuclear Power Corporation announced the ACPR1000 design, a further design evolution of the CPR-1000 to a Generation III level, which would also replace intellectual property right limited components. CGNPC aims to be able to independently market the ACPR1000 for export by 2013.[42]

CANDU-6 Heavy Water reactors

Qinshan Nuclear Power Plant, located in Zhejiang China

6 heavy water reactors to be located at Qinshan NPP, 3 of them are operational, the other three are still under construction. These reactors do not require enriched fuel, and can use the waste products of other light water reactors as fuel.

VVER-1000

Russia's Atomstroyexport was general contractor and equipment provider for the Tianwan AES-91 power plants using the V-428 version of the well-proven VVER-1000 reactor of 1060 MWe capacity. Russia's Energoatom is responsible for maintenance from 2009. Two further Tianwan units will use the same version of the VVER-1000 reactor.

Nuclear power plants under construction

Name Maximum capacity Current phase capacity Construction started Active capacity Scheduled completion Reactor types
Tianwan 8,380 MW 4,080 MW 1999-10-20 20 October 1999 1,980 MW 2018/2019 4 × VVER-1000
2 × CNP-1000
2 × VVER-1200
Ningde 6,108 MW 4,072 MW 2008-02-18 18 February 2008 3,060 MW 2015/2016 CPR-1000 6 × CPR-1000[10]
Hongyanhe 6,122 MW 4,122 MW 2007-08-27 27 August 2007 3,072 MW 2015/2016 CPR-1000 4 × CPR-1000[43]
Yangjiang 6,000 MW 4,000 MW 2008-12-16 16 December 2008 2,042 MW 2014/5/7/8 CPR-1000 4 × CPR-1000[43][44]
2 × ACPR-1000
Qinshan 6,838 MW 5,438 MW 1985-03-2020 March 1985 4,038 MW 2014/2015 PWR, PHWR
Fangjiashan 2,000 MW 2,000 MW 2008-12-26 26 December 2008 2,040 MW 2014/2015 CPR-1000 2 × CPR-1000[45]
Fuqing 6,000 MW 4,000 MW 2008-11-21 21 November 2008 1,020 MW 2014/5/6/7 CPR-1000 4 × CPR-1000[46]
2 × ACP-1000
Sanmen 6,600 MW 2,200 MW 2009-04-19 19 April 2009 0 MW 2016 AP1000 6 × AP1000[47][48]
Haiyang 8,800 MW 2,200 MW 2009-09-24 24 September 2009 0 MW 2016 AP1000 8 × AP1000[47][48]
Taishan 6,800 MW 3,400 MW 2009-10-28 28 October 2009 0 MW 2015/2016 EPR 4 × EPR[49][50]
Xianning 4,400 MW 2,200 MW 2011 0 MW 2015/2016 4 × AP1000[51]
Fangchenggang 6,000 MW 2,000 MW 2010-07-30 30 July 2010 0 MW 2015/17/19 6 × CPR-1000
Changjiang 2,440 MW 1,220 MW 2010-04-25 25 April 2010 0 MW 2015/2016 4 × CNP-650
Total 76,328 MW 40,932 MW 17,252 MW

Organizations

Public opposition

China is experiencing civic protest over its ambitious plans to build more nuclear power plants following the Fukushima nuclear disaster. There has been "inter-provincial squabble" over a nuclear power plant being built near the southern bank of the Yangtze River. The plant in the centre of the controversy is located in Pengze county in Jiangxi and across the river the government of Wangjiang county in Anhui wants the project shelved.[52]

More than 1,000 people protested in Jiangmen City Hall in July 2013 to demand authorities abandon a planned uranium-processing facility that was designed as a major supplier to nuclear power stations. The Heshan Nuclear Power Industry Park was to be equipped with facilities for uranium conversion and enrichment as well as the manufacturing of fuel pellets, rods and finished assemblies. Protesters feared the plant would adversely affect their health, and the health of future generations. As the weekend protest continued, Chinese officials announced the state-run project's cancellation.[53]

By 2014, concerns about public opposition caused Chinese regulators to develop public and media support programmes, and developers to begin outreach programmes including site tours and visitor centres.[54]

See also

References

  1. https://www.iaea.org/PRIS/home.aspx
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  7. http://world-nuclear.org/info/Country-Profiles/Countries-A-F/China--Nuclear-Power/
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  14. Ambrose Evans-Pritchard, 20 March 2011, Safe nuclear does exist, and China is leading the way with thorium, Telegraph UK
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  21. http://www.snerdi.com.cn/en/
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  25. http://world-nuclear.org/info/Country-Profiles/Countries-A-F/China--Nuclear-Power/
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  46. http://www1.cfi.net.cn/newspage.aspx?id=20080619001112&AspxAutoDetectCookieSupport=1
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External links

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