Nuclear News

Laufer

Developing a first-­of-­a-­kind reactor is a daunting endeavor. To be successful, advanced reactor designers need to achieve cost certainty by delivering a safe and affordable product at the promised cost. To meet this goal, Kairos Power structured its approach around four key strategies: 1) achieving technology certainty through a rapid iterative approach; 2) achieving construction certainty by demonstrating the ability to build it; 3) achieving licensing certainty by proving Kairos can license it; and 4) achieving supply chain certainty by vertically integrating critical capabilities. By mitigating risk in these four key areas, Kairos Power is confident that it will get true cost certainty for our future products.

The third prong in Kairos’s strategy—achieving licensing certainty—was a key driver in the decision to build the Hermes low-­power demonstration reactor, and it remains a major workstream as the company’s construction permit application (CPA) undergoes review by the U.S. Nuclear Regulatory Commission. Licensing a new nuclear technology is no small challenge, and there are multiple approaches companies can take. Here’s a look at how we at Kairos are approaching it.

Paragon Energy Solutions and Reuter-Stokes have signed a contract to design and manufacture neutron monitoring detectors for small modular reactor developer NuScale Power.

Examining Supply-Side Options to Achieve 100% Clean Electricity by 2035 was written by research staff at the National Renewable Energy Laboratory, so its reliance on solar and wind energy to decarbonize the grid by 2035 is not surprising. But that’s a big ask for any variable energy technology, especially if the nation’s largest source of clean power—nuclear energy—is relegated to a supporting role. Massive additions of solar and wind energy on the order of 2 TW would require a supporting infrastructure of new transmission lines, as well as batteries and hydrogen for daily and seasonal energy storage that would drive demand and capacity requirements higher.

The Hanford tanks, on which building began in 1943, were never supposed to hold waste for many decades. If grouting and disposal had occurred according to plans from the 1980s, this waste would already be in the ground and we would have saved almost $100 billion. (Photo: DOE)

At the end of June, a federal judge approved, with the agreement of the Washington State Department of Ecology, a request to push back the deadline 20 months for beginning nuclear waste treatment at the $17 billion Waste Treatment and Immobilization (Vit) Plant at the Hanford Site because of pandemic-related delays. The Direct-Feed Low-Activity Waste program is the Department of Energy’s plan to start treating low-level radioactive waste first at the Vit Plant and then start treating high-level radioactive waste sometime in the 2030s.

This is the fifth delay granted by the court for the project, which should have begun operations in 2007. In one sense, this delay is good, since turning LLW into glass through vitrification is about as smart as singing into the wind. The chemistry of this waste makes it much better suited to grouting, a treatment used by everyone else in the United States and the world.

U.S. utility Constellation Energy has signed a memorandum of understanding with ULC-Energy, an Amsterdam-based nuclear development company, to support deployment of a fleet of Rolls-Royce small modular reactors in the Netherlands.

Advanced reactor developers are designing many new nuclear energy products, targeting commercial demonstration before 2030. These products aim to provide different products and grid services beyond what is provided by the first generations of commercial nuclear plants, namely, gigawatt-scale electricity production. These reactors are intended for deployment in many novel scenarios, including being closer to population centers. They will be sited in governmental processes that encourage far more public participation than was possible when many of the existing plants were sited and built in the 1960s and 1970s. This means that community engagement and approval likely will be critical for project success. This article, which discusses this issue of social license, is an adaptation of “Social license in the deployment of advanced nuclear technology,” published in Energies in 2021.¹ A more detailed discussion can be found in the original article.

The International Atomic Energy Agency’s board of governors has adopted a resolution calling for an immediate end to the Russian occupation of Ukraine’s Zaporizhzhia nuclear power plant. According to a report from Reuters, the 35-member board voted 26–2 yesterday in favor of the resolution, with seven abstentions. The two “no” votes were cast, unsurprisingly, by Russia and China, while abstentions came from Burundi, Egypt, India, Pakistan, Senegal, South Africa, and Vietnam.

Portland, Ore.–based NuScale Power and KGHM Polska Miedź S.A. have signed the first task order and a statement of commencement to begin work under an agreement signed in February to initiate deployment in Poland of NuScale’s small modular reactor technology, the American firm announced this week. The task order was inked September 7 at the 31st Economic Forum, held September 6–8 in Karpacz, Poland.

The Nuclear Regulatory Commission is increasing its oversight of the Waterford Steam Electric Station’s Unit 3 reactor due to a decade-long miscalibration of a radiation monitor.

In a September 13 letter to Entergy Operations, the NRC classified the issue at the Killona, La., facility as a “white finding”—agency parlance for a problem of low to moderate safety significance. (The NRC’s Reactor Oversight Process uses color-coded inspection findings and indicators to measure plant performance, starting at green and increasing to white, yellow, and red, commensurate with the safety significance of the issues involved.)

Nuclear power generation surpassed coal generation in the United States for the first time in 2020. As utilities continue to retire coal-fired plants, reusing the shuttered sites to host nuclear reactors could help the nation reach the goal of net-zero emissions by 2050 and prove economically beneficial both for nuclear deployments and for the communities impacted by fossil fuel generation. That’s according to a Department of Energy report released this week, detailing how hundreds of U.S. coal power plant sites that have recently retired or plan to close within the decade could be suitable for new nuclear power plants. Nuclear power’s high capacity factors mean those plants could deliver an added benefit—delivering more baseload power to the grid from the nameplate capacity replacement.

BWXT Medical has submitted a new drug application to the U.S. Food and Drug Administration to request approval of its technetium-99m generator for medical imaging. A daughter isotope of molybdenum-99, Tc-99m is used in more than 40 million diagnostic procedures annually. BWXT Medical is a subsidiary of Lynchburg, Va.-based BWX Technologies.

The Nuclear Regulatory Commission yesterday announced that it has issued a renewed license for Westinghouse Electric Company’s Columbia Fuel Fabrication Facility (CFFF), authorizing operations at the plant for another 40 years—through September 12, 2062.

Located in Hopkins, S.C., the CFFF manufactures fuel rods for use in commercial nuclear reactors. According to Westinghouse, 10 percent of the nation’s electricity comes from the fuel manufactured at the facility.

Scientists in the Departments of Radiation Oncology and Medicine at the University of Washington (UW) and Fred Hutchinson Cancer Center (Fred Hutch) are directly targeting cancerous cells traveling through patients’ bloodstreams with diseases such as leukemia and lymphoma using an intravenous injection of the radioactive isotope astatine-211 (At-211). The work, its challenges, and its promise were described in a recent news release from the National Isotope Development Center (NIDC), which is managed by the Department of Energy’s Isotope Program.

Maybe hold off commenting on those Palisades decommissioning plans for now: Michigan Gov. Gretchen Whitmer last Friday penned a letter to energy secretary Jennifer Granholm pledging state support for a Holtec International plan to restart the recently shuttered Palisades nuclear plant in Covert, Mich. It was Whitmer’s second letter to the Department of Energy head expressing support for Palisades and touting its value to the state.

Steven Arndt
president@ans.org

Much has been written about regulation over the years, including whether or not the nuclear industry is overregulated or whether the regulator is in the industry’s “pocket.” Having a capable and independent regulator is important to the industry for a number of reasons, such as ensuring the safety and security of nuclear facilities and the trust an effective regulator can engender in vendors, investors, international organizations, and the public. However, regulation simply to engender trust or ensure all voices are heard is neither effective nor sufficiently adaptive to support a vibrant and innovative industry. Moreover, overregulation slows innovation, stifles creativity, drives costs upward, and creates scheduling challenges.

So how did the Nuclear Regulatory Commission become the “gold standard” of regulation? The pat response is because of its long history, experience, and available resources. I would contend, however, that what the NRC did better than most—if not all—national nuclear regulators was innovate and develop new ideas and act as the cocreator of the nuclear industry.

ENUSA’s president and CEO Mariano Moreno (left) and Westinghouse’s nuclear fuel president Tarik Choho shake hands on their latest partnership. (Photo: Westinghouse)

Westinghouse Electric Company and Madrid-based ENUSA intend to collaborate on VVER-440 fuel fabrication, the American firm announced last week at the World Nuclear Association’s World Nuclear Symposium.

The partnership, Westinghouse stated in a September 8 release, “will build on decades of performance delivering a Western alternative to Russian fuel in the European market.” There are currently 16 nuclear power reactors in Europe operating with VVER-440 fuel, and utilities in the region are actively looking for alternatives to Russian-supplied fuel for those units, according to the release.

Signers’ language: “We have a mutual interest in partnering in VVER-440 fuel manufacturing and potentially other related areas,” said Tarik Choho, Westinghouse’s president of nuclear fuel. “With our proven track record supplying for VVER reactors, we stand ready to support even greater energy security for our customers and European countries. We look forward to strengthening our partnership with ENUSA and leveraging their valuable experience in this field.”

The Nuclear Regulatory Commission last Friday announced the publication of its ninth report to the Convention on Nuclear Safety, describing the federal government’s actions under the convention to achieve and maintain safety for the nation’s nuclear power reactor fleet.

An International Atomic Energy Agency treaty, the Convention on Nuclear Safety was adopted in 1994 and entered into force in 1996. In 1999, it was ratified by the U.S. Senate.

The aim of the convention, according to the IAEA, is to “commit contracting parties operating land-based civil nuclear power plants to maintain a high level of safety by establishing fundamental safety principles to which states would subscribe.” Signatories are required to submit reports for peer review at meetings held every three years.

Who better to talk with about the licensing of nuclear facilities and materials than Christopher T. Hanson, the chairman of the five-member Nuclear Regulatory Commission? Hanson is the principal executive officer of and official spokesman for the NRC. As a collegial body, the Commission formulates policies, develops regulations governing nuclear reactor and nuclear material safety, issues orders to licensees, and adjudicates legal matters.

The Department of Energy is offering cost-shared funding that could lead to the demonstration of an “energy park” drawing 20–300 MW of thermal energy from a U.S. nuclear power plant under a funding opportunity amendment issued in August by the DOE’s Office of Nuclear Energy Light Water Reactor Sustainability (LWRS) program, in coordination with the DOE’s Office of Energy Efficiency and Renewable Energy Hydrogen and Fuel Cell Technologies Office.

Research by scientists at the Department of Energy’s Princeton Plasma Physics Laboratory (PPPL) and collaborating institutions has the potential to improve plasma performance in tokamak nuclear fusion reactors, according to a recent paper in Nuclear Fusion. The research focused on the use of a PPPL-developed dropper to apply coatings of boron powder to the tungsten components inside a tokamak, thereby helping protect the tungsten against the intensely hot plasma. According to lead author Grant Bodner, this process offers “a way to deposit boron coatings without turning off the tokamaks’ magnetic field.”