Friday, November 13, 2020

WNN Daily World Nuclear News November 13, 2020

  

13 November 2020
NEW NUCLEAR: Hongyanhe 6 enters commissioning phase

Cold functional testing was recently completed at unit 5 of the Hongyanhe nuclear power plant in China's Liaoning province, China General Nuclear (CGN) announced. The ACPR-1000 reactor is scheduled to enter commercial operation in the first half of 2022.
Cold functional tests are carried out to confirm whether components and systems important to safety are properly installed and ready to operate in a cold condition. They are the first comprehensive tests to check the performance of the entire reactor. The main purpose of these tests is to verify the leak-tightness of the primary circuit and components - such as pressure vessels, pipelines and valves of both the nuclear and conventional islands - and to clean the main circulation pipes.
The cold functional testing of Hongyanhe 6 began on 19 October. After completing a series of commissioning tests for the reactor coolant system, chemical and power control system, the primary circuit reached the 228 bar maximum pressure platform on 25 October for pressure holding tests. The tests were completed on 27 October. A total of 68 commissioning tests were completed over this period. CGN said "all the data meet the design requirements and the primary circuit hydraulic test is qualified."
Construction of Phase I (units 1-4) of the Hongyanhe plant, comprising four CPR-1000 pressurised water reactors, began in August 2009. Units 1 and 2 have been in commercial operation since June 2013 and May 2014, respectively, while unit 3 entered commercial operation in August 2015 and unit 4 in September 2016.
Phase II of the Hongyanhe plant - units 5 and 6 - comprises two 1080 MWe CGN-designed ACPR-1000 reactors. Construction of unit 5 began in March 2015 and that of unit 6 started in July the same year. Cold functional testing of unit 5 began on 10 October last year, marking the start of its commissioning phase.
In late December last year, CGN announced a change in the schedule for starting up units 5 and 6. It said the units are now expected to start operating in the second half of 2021 and the first half of 2022, which is, respectively, one year and six months later than previously scheduled.
The Hongyanhe plant is owned and operated by Liaoning Hongyanhe Nuclear Power Company, a joint venture between CGN and State Power Investment Corporation, each holding a 45% stake, with the Dalian Municipal Construction Investment Company holding the remaining 10%.
The ACPR-1000 - a three-loop unit with double containment and core-catcher - was launched by CGN in November 2011. In 2012 central planners in Beijing directed China National Nuclear Corporation and CGN, to 'rationalise' their reactor programmes. This meant CNNC's ACP1000 and CGN's ACPR-1000 were 'merged' into one standardised design - the Hualong One (HPR1000). Yangjiang units 5 and 6 were the first ACPR-1000 units to enter commercial operation, in July 2018 and July 2019, respectively. The ACPR-1000 is also being built as units 5 and 6 of the Tianwan plant. Tianwan 5 entered commercial operation in September, while Tianwan 6 is expected to be put into commercial operation by the end of 2021.

NEW NUCLEAR: Irradiation testing of IMSR moderator graphite begins

Terrestrial Energy and Nuclear Research and Consultancy Group (NRG) have started a graphite irradiation testing programme at the High Flux Reactor (HFR) in the Netherlands. This work is part of a broader programme underway for confirmatory testing of components and systems in the Integral Molten Salt Reactor (IMSR).
NRG, operator of the European Union-owned HFR at Petten, is providing technical services to support Terrestrial Energy for "in-core" materials testing and development of the IMSR power plant. The testing programme at NRG is designed to confirm the predicted performance of selected graphite grades throughout the seven-year cycle of the IMSR. Its scope simulates IMSR core conditions, encompassing the full range of IMSR operating temperatures and of the neutron flux.
The HFR has now reached full power indicating the successful start of the test programme, Terrestrial said. The test programme involved many months of preparation, which included test design, characterisation of the as-manufactured graphites, analysis and development of the loading matrix. This effort utilised the expert services of Terrestrial Energy's engineering consultant, Frazer-Nash Consultancy.
The graphite irradiation programme aims to enable Terrestrial to select the most suitable graphite grade for use in the IMSR reactor, as well as qualifying graphite for IMSR use. Different graphite grades will be subjected to neutron irradiation at elevated temperatures and characterised on a range of material properties. The data set created will cover the lifespan of the graphite components in the IMSR.
The collaboration between Terrestrial Energy and NRG is part of a wider partnership between Terrestrial and the European Union's scientific community, following a March 2018 technical services agreement with the European Commission's Joint Research Centre in Karlsruhe, Germany to perform confirmatory studies of the fuel and primary coolant salt mixture for the IMSR.
"Our work with NRG at its Petten HFR facility is an important element of our overall IMSR test programme, now well underway," said Terrestrial Energy CEO Simon Irish. "The start of in-core irradiation tests speaks to our progress and comes after many months of prior work."
Vinod Ramnandanlal, commercial director of NRG, added, "We recognise the commercial capabilities of molten salt technologies and the growing interest in their development and deployment today. We are delighted to be supporting Terrestrial Energy as it moves forward with in-core irradiation testing, the first developer to commence such testing."
Molten salt reactors use fuel dissolved in a molten fluoride or chloride salt, which functions as both the fuel (producing the heat) and the coolant (transporting the heat away and, ultimately, to the electricity generating equipment). Terrestrial's IMSR builds on 50 years of experience at the USA's Oak Ridge National Laboratory, and integrates the primary reactor components, including the graphite moderator, into a sealed and replaceable reactor core unit. The IMSR uses two molten salt streams - a fuel salt that contains the uranium and another salt to transfer heat from the reactor to the electricity generation system.
Earlier this week, Terrestrial announced the US Department of Energy's Argonne National Laboratory had begun detailed testing of the fuel salt for the IMSR.

ENERGY & ENVIRONMENT: DOE publishes strategic framework for hydrogen effort

The US Department of Energy (DOE) yesterday released its Hydrogen Program Plan to provide a strategic framework for its hydrogen research, development, and demonstration (RD&D) activities. The plan, which reinforces DOE's commitment to develop the technologies that can enable hydrogen expansion in the USA, incorporates the RD&D efforts of multiple DOE offices to advance the production, transport, storage, and use of hydrogen across different sectors of the economy.
"Hydrogen is an exciting fuel source that has the potential to integrate our nation's energy resources, but to fully recognise its potential across the economy, we need to lower costs and see a significant increase in hydrogen supply and demand," Secretary of Energy Dan Brouillette said. "This administration is excited by the Department-wide efforts and collaborations outlined in this Plan that will address these issues and help secure hydrogen as an option in the nation's energy future."
According to DOE, the plan serves as the overarching document to set the strategic direction of the Hydrogen Program, and to complement the technical and programmatic multi-year plans from each DOE office engaging in hydrogen RD&D activities.
Hydrogen is a versatile fuel that offers a path to sustainable long-term economic growth, Deputy Energy Secretary Mark Menezes and the heads of the various offices said in a message to stakeholders. It can add value to multiple sectors of the economy, serve as a sustainable fuel for transportation and as input to produce electricity and heat for homes and even be exported. "But realising the true potential for hydrogen requires a commitment to continued research and development as well as ramping up demonstrations and deployments with the private sector to achieve scale. Unlike other fuels, hydrogen requires more integration of the fossil, nuclear, and renewable energy systems, and it will take an integrated approach from all energy sectors to realise the full potential and benefits of hydrogen," they said.
The plan's strategic framework incorporates the research, development, and demonstration efforts of the Offices of Energy Efficiency and Renewable Energy, Fossil Energy, Nuclear Energy, Electricity, Science, and the DOE's Advanced Research Projects Agency-Energy (ARPA-E) to advance the production, transport, storage, and use of hydrogen.
"For decades, DOE has supported the development of technologies to complement the production of hydrogen fuel from our traditional sources," Menezes said. "The RD&D activities outlined in the Plan will contribute to this important DOE-wide effort to support our all-of-the-above energy strategy."
A key aspect of the strategy is to enable hydrogen production from a diverse array of low-carbon domestic energy resources, including renewables, nuclear energy, and fossil fuels (with carbon capture, utilisation and storage - CCUS).
Assistant Secretary for Nuclear Energy Rita Baranwal said the programme plan allows DOE to streamline its efforts around hydrogen R&D. "@GovNuclear [the Office of Nuclear Energy] is currently working to demonstrate high- and low-temperature electrolysis at US reactors to produce hydrogen at scale, which could open up new markets for the nuclear industry," she tweeted.
DOE in October selected two projects to advance flexible operation of light-water reactors with integrated hydrogen production systems to receive cost-shared funding through the Office of Nuclear Energy's US Industry Opportunities for Advanced Nuclear Technology Development funding opportunity announcement, in collaboration with the Office of Energy Efficiency and Renewable Energy's Hydrogen and Fuel Cell Technologies Office.
Under one of those projects, Minneapolis-based Xcel Energy will work with Idaho National Laboratory (INL) to demonstrate a system that uses a nuclear plant's steam and electricity to split water. The resulting hydrogen will initially be used at the power plant, but it could eventually be sold to other industries. The system is likely to be demonstrated at the Prairie Island Nuclear Generating Station, INL said this week.
The second proposal sees FuelCell Energy Inc of Connecticut team with INL to demonstrate and validate a solid oxide electrolysis cell hydrogen production system for integration into nuclear power plants.
A two-year project to demonstrate commercial hydrogen production via low-temperature electrolysis at Energy Harbor's Davis-Besse Nuclear Plant near Toledo, Ohio, received DOE funding in September 2019. Arizona Public Service, under the same award, is also evaluating the integration of nuclear energy with hydrogen production at the Palo Verde nuclear power plant.



IN OTHER NEWS:

Kyushu Electric Power Company plans to restart unit 1 of its Sendai nuclear power plant in Japan's Kagoshima prefecture on 17 November, having completed construction of a bunkered back-up control centre as required under revised safety regulations. The utility expects the 890 MWe pressurised water reactor to reach criticality the following day, and for power generation to resume on 19 November. Sendai 1 was the first reactor to be restarted in August 2015. However, Kyushu took the unit offline on 16 March as it missed the deadline for completion of the back-up control centre.

Utah Associated Municipal Power Systems will evaluate the possibilities of building a four or six-module plant instead of a 12-module NuScale SMR plant in Idaho, it has told POWER magazine. This follows NuScale's announcement earlier this week of a power uprate to its SMR module and the launch of the smaller plant solutions which it said offers potential customers more options in terms of size, power output, operational flexibility, and could also reduce construction schedules and costs.

Orano group subsidiary Orano Med has increased its capacity for the production of the medical radioisotope lead-212 at its Maurice Tubiana Laboratory at Bessines-sur-Gartempe. The process recovers the isotope from thorium, allowing thorium nitrate from the group's mining activities to be recycled.

Australia's National Radioactive Waste Management Facility is a vital piece of national infrastructure which will support the ongoing development of the nation's nuclear medicine and research industries, Minister for Resources, Water and Northern Australia Keith Pitt said yesterday. Pitt said the site which has been identified for the facility - Napandee, near Kimba in South Australia - is technically suitable and the facility is broadly supported by the community. The government will continue to progress the legislation that will allow the facility to be delivered, he said.


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