SASKATCHEWAN
Westinghouse Secures First Customer for eVinci Nuclear Microreactor
Sonal Patel
Updated Mon, November 27, 2023
Westinghouse’s first customer for its eVinci microreactor—a flagship 5-MWe/13-MWth “nuclear battery”—is poised to be the Saskatchewan Research Council (SRC), Canada’s second-largest research and technology organization.
SRC—a Saskatchewan government Treasury Board Crown Corporation that serves as a commercial laboratory to provide research and development (R&D) for Saskatchewan industries—on Nov. 27 said it plans to pilot an eVinci microreactor by 2029. However, that timeframe will be subject to licensing and regulatory requirements. The location of the eVinci microreactor will be "determined as the project progresses," the provincial government said on Monday.
SRC, which will serve as the microreactor's licensed operator, will pursue the demonstration boosted with CA$80 million in government funding announced by Saskatchewan Premier Scott Moe on Monday. The CA$80 million will cover "SRC's costs for licensing and SRC's project costs," SRC told POWER. "We will be working with Westinghouse to learn how this technology can be applied in Saskatchewan, and part of that will be to understand project costs for future deployments," it said.
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The eVinci microreactor has very few moving parts, working "essentially as a battery, providing the versatility for power systems ranging from several kilowatts to 5 MW of electricity, delivered 24 hours a day, 7 days a week for eight-plus years without refueling," Westinghouse says. "It can also produce high temperature heat suitable for industrial applications including alternative fuel production such as hydrogen, and has the flexibility to balance renewable output." The technology is 100% factory built and assembled before it is shipped in a container to any location. Courtesy: WestinghouseMore
Westinghouse's eVinci microreactor ranges from several kilowatts to 5 MW of electricity, "delivered 24 hours a day, 7 days a week for eight-plus years without refueling," Westinghouse says. "It can also produce high-temperature heat suitable for industrial applications including alternative fuel production such as hydrogen, and has the flexibility to balance renewable output." The technology is 100% factory-built and assembled before it is shipped in a container to any location. Courtesy: Westinghouse[/caption]
An Industrial Application That Could Lay 'Groundwork' for More Projects
If built by the anticipated timeframe, the eVinci demonstration would become Saskatchewan's first advanced nuclear reactor. SaskPower, a utility owned by the provincial government, has selected GE Hitachi Nuclear Energy’s (GEH’s) 300-MW BWRX-300 for its first two potential nuclear units. While SaskPower intends to decide to build the new nuclear units in 2029, it suggests construction of the first small modular reactor (SMR) could begin as early as 2030, with a targeted in-service date of 2034. In August, Canada’s federal government committed CA$74 million to support SaskPower’s potential deployment through two federal mechanisms.
Last year, the Canadian federal government awarded Westinghouse a CA$27.2 million grant from its Strategic Innovation Fund (SIF) to support further development of the eVinci microreactor. The “investment” is aimed at helping to fight climate change and “build on Canada’s global leadership in SMRs,” said François-Philippe Champagne, Minister of Innovation, Science and Industry.
SRC's effort to pilot an eVinci microreactor follows a May 2022–signed memorandum of understanding (MOU) between Westinghouse and SRC to jointly develop a project to locate an eVinci microreactor in Saskatchewan. “Our vision is to see the first eVinci microreactor in an industrial application and lay the groundwork for many more projects in the future,” SRC President and CEO Mike Crabtree said on Monday. “What we learn through this project will prepare SRC to assist communities and industries in future projects.”
SRC, notably, served as the licensed owner and operator of the SLOWPOKE-2, a 20-kW nuclear research reactor housed at the SRC Environmental Analytical Laboratories in Saskatoon. The 1981-commissioned research reactor ran for 38 years until decommissioned in 2019. While SLOWPOKE-2 provided an intense neutron source for teaching, training, and research, SRC has suggested an eVinci microreactor could be developed as a distributed energy alternative to diesel-powered generators.
Providing a reliable source of industrial-grade heat—of up to 600C—or operating in combined heat and power mode, the “very small modular reactor” could support various applications in the province, including remote mining operations, remote communities, and industry. It says the microreactor could also serve as a crucial energy source to power distributed hydrogen generation, desalination, and other integrated energy applications.
A Major Milestone for Westinghouse’s Novel Nuclear Battery
Bagging a first customer for the eVinci marks a big win for Westinghouse. While Westinghouse has long-fielded a research and development (R&D) effort, including developing and testing components for its heat pipe and novel moderator, it has more recently picked up the pace of its varied eVinci business activities to ready it for the market by 2027.
The nuclear technology giant introduced eVinci in 2017 as one of several key advanced nuclear designs in its portfolio, touting the microreactor’s innovative design, which has several safety features and is based on design simplicity. At the time, Westinghouse set an ambitious six-year technology development goal, anticipating that the next-generation nuclear reactor would be integral for decentralized generation markets.
At the heart of the eVinci is a fully passive heat pipe–cooled design that will use tristructural isotropic (TRISO) fuel. Its alkali metal heat pipe technology relies on alkali metal phase change to capture temperature uniformity within the reactor core. The reactor’s core, built around a solid steel monolith, has channels for both heat pipes and fuel pellets, with each fuel pin placed adjacent to several heat pipes. The array of closed heat pipes essentially removes heat from the nuclear core and transfers that heat to air, which then turns a turbine in an open-air Brayton thermodynamic power conversion cycle.
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eVinci’s reactor core is a solid-steel monolith that features channels for fuel pellets, the moderator (metal hydride), and heat pipes, which are arranged in a hexagonal pattern. The monolith will serve as the second fission product barrier (the fuel pellet is the first barrier) as well as the thermal medium between the fuel channels and heat pipes. The heat pipes will extract heat from the core using a technology based on thermal conductivity and fluid phase transition. Courtesy: Westinghouse[/caption]
Along with providing redundancy of the primary heat removal path, the heat pipes eliminate the need for a reactor coolant pump, bulk coolant, and associated equipment, as well as enable a modular core design, Westinghouse President of eVinci Microreactor Jon Ball told POWER in October.
An eVinci microreactor and surrounding infrastructure is about “half the size of a hockey rink,” Westinghouse says. In addition, unlike a high-temperature gas reactor (HTGR), heat pipe reactors are not pressurized and have no moving parts, though they are passive (naturally driven) and can self-adjust to the amount of heat transferred—which allows inherent load following.
Readying eVinci for Market
However, while heat pipe technology is not new—the passive heat transport devices have been applied for nearly 60 years in aerospace and other industries and are mature and robust with an extensive experimental test database—they have not been utilized in commercial nuclear technology. eVinci, notably, will also utilize high-assay low-enriched uranium (HALEU) in TRISO form, further contributing to the reactor's safety and efficiency.
Following Westinghouse’s recent success in manufacturing a 12-foot heat pipe at its Waltz Mill, Pennsylvania, facility (as part of a $9 million federal cost-share project under the Advanced Reactor Demonstration Program), the company has garnered a series of crucial partnerships with potential customers.
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Westinghouse successfully manufactured a 12-foot heat pipe at their facility in Waltz Mill, Pennsylvania. The heat pipe is one of the largest of its kind ever built and will be used to support the Nuclear Test Reactor (NTR). Courtesy: Westinghouse
Westinghouse in 2023 successfully manufactured a 12-foot heat pipe at their Waltz Mill, Pennsylvania facility. The heat pipe is one of the largest of its kind ever built and will be used to support the Nuclear Test Reactor (NTR). Courtesy: Westinghouse[/caption]
In June, Westinghouse moved to establish eVinci Technologies as a separate business unit, with Ball—a long-time nuclear expert who was pivotal in leading the creation, development, and customer adoption of GE Hitachi’s BWRX-300—at its helm. In October, Westinghouse then launched a new design and manufacturing facility near downtown Pittsburgh that will house eVinci’s engineering and licensing operations, testing, prototype trials, business development, and sales. Construction on the facility is slated to wrap up early in 2024.
Also in October, the Department of Energy (DOE) revealed eVinci would be part of its first batch of microreactors to further their designs through a front-end engineering and experiment design (FEEED) process at Idaho National Laboratory’s (INL’s) DOME test bed. Testing at DOME could start “as early as 2026,” the DOE said.
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The new eVinci accelerator hub under construction in the borough of Etna in Pennsylvania will be home to engineering and licensing operations, testing, prototype trials, business development and sales. It also includes manufacturing space. Courtesy: Westinghouse
The new eVinci "accelerator hub" under construction in the borough of Etna in Pennsylvania will be home to engineering and licensing operations, testing, prototype trials, business development, and sales. It also includes manufacturing space. Courtesy: Westinghouse[/caption]
Crucial Next Steps: Scaling Up, Licensing
Ball told POWER eVinci’s nuclear test reactor (NTR) at DOME will be “roughly a one-fifth scale version of the commercial eVinci that we’re planning to license and deploy.” The reason Westinghouse is testing the NTR at DOME is that the company is in the process of scaling up some of the laboratory testing that has already been performed on the system, Ball said. “Ultimately, what we need to be able to do is demonstrate the scaling and our understanding of the core performance, which will be a key aspect in terms of the licensing of the eVinci commercial system,” he added.
Once Westinghouse has completed the NTR, it plans to scale up its ability to manufacture longer heat pipes required for its commercial system. “We’ve made tremendous progress to date and have every confidence that we’re going to be successful as we continue to scale the system to our commercial size,” Ball said.
The next crucial step will be to license the eVinci. In the U.S., Westinghouse has already submitted 31 technical white papers detailing the eVinci reactor's safety aspects and three topical reports to the U.S. Nuclear Regulatory Commission (NRC), considering a license submission under 10 CFR Part 52.
In 2021, the company said it planned a comprehensive testing and analysis program that would be sufficient for the Design Certification (DC) of the “eVinci facility,” which would support the deployment of standard eVinci reactors for a range of sites in the U.S. However, in addition to a DC, it said it intended to explore various licenses, including a manufacturing license (10 CFR 52 Subpart F), a certificate of compliance, and a license for transport (10 CFR 71).
In Canada, Westinghouse has initiated the Vendor Design Review (VDR) process, submitting its first package to the Canadian Nuclear Safety Commission (CNSC) in June. On Monday, SRC told POWER it would lead the licensing process for the Saskatchewan's first deployment. "CNSC regulations must be met," it noted. "The CNSC makes licensing decisions for reactors and reactor operators in Canada."
Westinghouse is also working with both regulators—the NRC and the CNSC—to coordinate the evaluation of future joint reviews on “a couple of key topics,” Ball said. “Those documents have not been submitted yet, but that is the near-term intent, to submit the first package that will have a joint review,” he said.
—Sonal Patel is a POWER senior associate editor (@sonalcpatel, @POWERmagazine).
NM
Final testing underway at $486M air system for nuclear waste site near CarlsbadAdrian Hedden, Carlsbad Current-Argus
Tue, November 28, 2023
Construction of an almost half-billion-dollar rebuild of the ventilation system at the Waste Isolation Pilot Plant was nearing completion, and testing was being conducted ahead of an expected 2025 start date following years of delays for the project.
It began in 2018, intended to increase airflow in the WIPP underground for workers to breathe, allowing waste emplacement, mining and maintenance to occur simultaneously.
At WIPP, transuranic (TRU) nuclear is disposed of via burial in an underground salt deposit.
More: A nuclear reactor in Carlsbad? City officials call for project at federal waste repository
It is brought via truck to the WIPP site about 30 miles east of Carlsbad from U.S. Department of Energy laboratories and facilities around the country.
Airflow was restricted at the WIPP facility after a ruptured drum from Los Alamos National Laboratory in 2014 contaminated parts of the underground.
The Safety Significant Confinement Ventilation System (SSCVS), combined with a new air intake shaft at the site, was intended to up the remaining air flow from 170,000 cubic feet per minute (cfm) to 540,000 cfm.
The Waste Isolation Pilot Plant is pictured on Thursday, Oct. 5, 2023, in Carlsbad, NM.
More: Oil & gas industry joins fight against nuclear waste site proposed in southeast New Mexico
It was initially planned for completion in 2022 but was marred in delays tied to the COVID-19 pandemic, a dispute with the first contractor hired for the work and a budget climbing from the initial $288 million price tag to the latest estimate at $486 million, according to a 2022 report from the Government Accountability Office.
The DOE announced on Nov. 21 that workers began the commissioning phase of the project, first testing electrical cables for the mechanical aspects of the system like motors, fans and air filtration units.
As work building various components of the SSCVS is completed, they are gradually shifted to commissioning to ensure proper function, read a DOE news release, and interaction with other parts of the system.
More: Feds tout progress in cleaning up nuclear waste at Los Alamos using Carlsbad-area site
Construction continues on Thursday, Oct. 5, 2023, at Waste Isolation Pilot Plant in Carlsbad, NM.
The SSCVS will add a layer of protection from any future radiological events in the underground, read the release, by pushing air brought in to the site through a series of fans and filters before it is exhausted into the environment.
That includes two buildings: the Salt Reduction and New Filter buildings.
The Salt Reduction Building will pre-filter salt out of the air as it is drawn from the WIPP underground.
More: Air shaft at nuke repository near Carlsbad hits final depth amid recent safety incidents
Then, the New Filter Building will sees fans push the air through high efficiency particulate air (HEPA) filters, to remove any other contaminates before the air is released above ground.
Michael Gerle, environmental regulatory compliance director with the DOE’s Carlsbad Field Office said the project when complete will support WIPP’s continued mission of cleaning up the DOE’s nuclear waste.
Officials estimated that based on WIPP’s legal capacity and production rates of the waste, the facility could remain operational until 2080, and recently said they planned to increase shipments to the site up to 17 per week.
More: Nuclear waste disposal permit issued for New Mexico site, WIPP to get bigger in November
“The SSCVS will enhance the quantity, and quality, of air flow for our workforce in the WIPP underground mine,” Gerle said. “Additionally, the new infrastructure will ensure our operations remain safe for the environment and the public.”
The Waste Isolation Pilot Plant is pictured on Thursday, Oct. 5, 2023, in Carlsbad, NM.
Switching to the commissioning phase of the project was an important process to ensure the SSCVS would function properly during WIPP operations, said Ralph Musick, capital asset project manager at Salado Isolation Mining Contractors (SIMCO) – the DOE’s primary contractor at WIPP.
“This achievement is the culmination of many people’s efforts to support the engineering, procurement and construction of WIPP’s SSCVS project,” he said. “Initiating commissioning is a careful, step-by-step process to eventually integrate the SSCVS into daily WIPP operations.”
More: New Mexico could try again to challenge nuclear waste storage project in court
Safety issues at both the SSCVS and shaft were reported in the latest Defense Nuclear Facility Safety Board report for October for WIPP, published Nov. 3.
At the shaft, a rigging cable broke after it scrapped against a spool guide, causing a loader vehicle to swing uncontrollably in the shaft, striking a scaffolding platform.
No workers injuries were reported but hoisting and rigging work was suspended amid an indefinite “safety pause,” the report read, until a new hoisting and rigging plan is approved.
Concerns with the SSCVS’s underground continuous air monitors (CAMs) were also expressed, read the report, leading to a “full-scale” emergency exercise which was conducted Oct. 16.
Other CAMs in place at WIPP previously malfunctioned on Sept. 29, read the board’s report for that month, and set off alarms which led to an evacuation of the underground and an order to shelter in place for the rest of the facility.
Adrian Hedden can be reached at 575-628-5516, achedden@currentargus.com or @AdrianHedden on X, formerly known as Twitter.
This article originally appeared on Carlsbad Current-Argus: Final testing underway at new air system for nuclear waste repository
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