nuclear-news

The News That Matters about the Nuclear Industry Fukushima Chernobyl Mayak Three Mile Island Atomic Testing Radiation Isotope

France’s mini nuclear reactor plan – Nuward, gets another financial handout from the European Commission

The European Commission (EC) has approved, under European Union (EU) state
aid rules, a €300m ($320m) French measure to support Electricité de
France’s (EDF) subsidiary Nuward in researching and developing small
modular nuclear reactors (SMRs). The EC said the measure will contribute to
the achievement of the strategic objectives of the European industrial
strategy and the European Green Deal.

France notified to the Commission its
plan to grant €300m to Nuward to support its research and development
(R&D) project on SMR technology. The project aims to develop processes for
the design and construction of SMRs based on a simple and modular design
and with a power output equivalent to or less than 300 MWe. The front-end
design is the third phase of the overall Nuward project, which contains
five distinct phases.

In December 2022, the Commission already approved a
€50m French measure to support the second phase of the project, aimed at
acquiring new knowledge for the design and construction of SMRs. The aid
will take the form of a direct grant of up to €300m that will cover the
R&D project until early 2027. The measure will support Nuward in sizing the
modules and components of the SMRs and validating their integration in the
SMRs by means of numerical simulators and laboratory tests. Nuward will
also carry out industrialisation studies relating to the modular design and
mass production of SMRs. Finally, the measure will also support Nuward in
the preparation of the required safety demonstrations for the approval of
the project by the national nuclear safety authorities.

 Nuclear Engineering International 1st May 2024

https://www.neimagazine.com/news/newseuropean-commission-approves-state-aid-for-nuward-smr-11725920

May 10, 2024 Posted by | EUROPE, politics, Small Modular Nuclear Reactors | Leave a comment

Small reactors don’t add up as a viable energy source

By M.V. Ramana and Sophie Groll. 6 May 24,  https://cosmosmagazine.com/science/engineering/small-reactors-dont-add-up/

The nuclear industry has been offering so-called Small Modular Reactors (SMRs) as an alternative to large reactors as a possible solution to climate change.

SMRs are defined as nuclear reactors with a power output of less than 300 megawatts of electricity, compared to the typically 1000 to 1,500 megawatts power capacity of larger reactors.

Proponents assert that SMRs would cost less to build and thus be more affordable. 

However, when evaluated on the basis of cost per unit of power capacity, SMRs will actually be more expensive than large reactors. 

This ‘diseconomy of scale’ was demonstrated by the now-terminated proposal to build six NuScale Power SMRs (77 megawatts each) in Idaho in the United States. 

The final cost estimate of the project per megawatt was around 250 percent more than the initial per megawatt cost for the 2,200 megawatts Vogtle nuclear power plant being built in Georgia, US. 

Previous small reactors built in various parts of America also shut down because they were uneconomical.

The high cost of constructing SMRs on a per megawatt basis translates into high electricity production costs. 

According to the 2023 GenCost report from the Australian Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Energy Market Operator, the estimated cost of generating each megawatt-hour of electricity from an SMR is around AUD$400 to AUD$600. 

In comparison, the cost of each megawatt-hour of electricity from wind and solar photovoltaic plants is around AUD$100, even after accounting for the cost involved in balancing the variability of output from solar and wind plants.

Building SMRs has also been subject to delays. Russia’s KLT-40 took 13 years from when construction started to when it started generating electricity, instead of the expected three years.

Small reactors also raise all of the usual concerns associated with nuclear power, including the risk of severe accidents, the linkage to nuclear weapons proliferation, and the production of radioactive waste that has no demonstrated solution because of technical and social challenges

One 2022 study calculated that various radioactive waste streams from SMRs would be larger than the corresponding waste streams from existing light water reactors.

The bottom line is that new reactor designs, such as SMRs, will not rescue nuclear power from its multiple problems. Any energy technology that is beset with such environmental problems and risks cannot be termed sustainable.

Nuclear energy itself has been declining in importance as a source of power: the fraction of the world’s electricity supplied by nuclear reactors has declined from a maximum of 17.5 percent in 1996 down to 9.2 percent in 2022. All indications suggest that the trend will continue if not accelerate.

The decline in the global share of nuclear power is driven by poor economics: generating power with nuclear reactors is costly compared to other low-carbon, renewable sources of energy and the difference between these costs is widening. 

Nuclear reactors built during the last decade have all demonstrated a pattern of cost and time overruns in their construction.

The Vogtle nuclear power plant being built in Georgia, involving two reactors designed to generate around 1,100 megawatts of electricity each, is currently estimated to cost nearly USD$35 billion

In 2011, when the utility company building the reactor sought permission from the American Nuclear Regulatory Commission, it projected a total cost of USD$14 billion, and ‘in-service dates of 2016 and 2017’ for the two units. 

In France, the 1,630-megawatt European Pressurised Reactor being built in Flamanville was originally estimated to cost 3 billion euros and projected to start in 2012, but the cost has soared to an estimated 13.2 billion euros and is yet to start operating as of March 2024.

These cost increases and delays confirm the historical pattern identified in a study published in 2014: of the 180 nuclear power projects around the world it studied, 175 had exceeded their initial budgets, by an average of 117 percent, and took 64 percent longer than initially projected. 

However, the recent projects are even more extreme in the magnitude of the disconnect between expectations and reality.

These reactor projects, and the Hinkley Point C project under construction in the United Kingdom, also confirm another historical pattern: costs of nuclear power plants go up with time, not down. This is unlike other energy technologies, such as solar and wind energy, where costs have declined rapidly with experience.

The climate crisis is urgent. The world has neither the financial resources nor the luxury of time to expand nuclear power. As physicist and energy analyst Amory Lovins argued: “… to protect the climate, we must save the most carbon at the least cost and in the least time.”  

Expanding nuclear energy only makes the climate problem worse. 

The money invested in nuclear energy would save far more carbon dioxide if it were instead invested in renewables. 

And the reduction in emissions from investing in renewables would be far quicker.

M.V. Ramana is the Simons Chair in Disarmament, Global and Human Security and Professor at the School of Public Policy and Global Affairs, at the University of British Columbia in Vancouver, Canada. He is the author of The Power of Promise: Examining Nuclear Energy in India (Penguin Books, 2012) and Nuclear is not the Solution: The Folly of Atomic Power in the Age of Climate Change (forthcoming from Verso Books).

Sophie Groll is a master’s student at the School of Public Policy and Global Affairs, at the University of British Columbia in Vancouver, Canada studying public policy and global affairs. Her focus is on environmental policy, low-carbon energy sources, and net-zero transition discourses.

Originally published under Creative Commons by 360info™.

May 7, 2024 Posted by | Small Modular Nuclear Reactors | Leave a comment

Why UK Government nuclear quango has ruled out Trawsfynydd from initial mini-nuke rollout

The site in Gwynedd could still be considered later on in the process

Owen Hughes, Business correspondent, 3 MAY 2024

A UK Government nuclear quango has dropped Trawsfynydd from the initial rollout of small modular reactors. Former Prime Minister Boris Johnson had said in 2022 that the UK Government are “looking to build another small modular reactor(SMR) on the site at Trawsfynydd”.

The Nuclear Decommissioning Authority (NDA) and Welsh Government owned Cwmni Egino had been working up plans for a new nuclear station close to the former power station, which stopped generating in 1991 and is in the long process of being decommissioned. The location had also previously been tipped by Rolls Royce SMR as a location for an SMR.

But those hopes have been dealt a blow after Great British Nuclear(GBN) said the site would not be considered in its initial rollout phase. It is understood the size of the site and the volume of cooling water counted against it. They also said it may not be able to deploy as quickly as some other sites.

It has though not been ruled out completely and could play a part in the future. A source explained that the initial rollout was looking at locations that could host four or five SMRs, which Traws does not have capacity for.

But once these larger sites are developed a further rollout would consider smaller sites that could host one or two SMRs, with would put the Gwynedd site back in contention.

On Anglesey, UK Government is buying the Wylfa site in a bid to progress nuclear development on the island after two failed attempts for a Wylfa B. This could be used for four or five SMRs or a single large scale nuclear power station…………………………………

GBN’s plans for its first phase of work for SMRs proposes to make decisions on investments by 2029, with power on the grid by the mid-2030s.  https://www.dailypost.co.uk/news/north-wales-news/uk-government-nuclear-quango-ruled-29108206

May 6, 2024 Posted by | Small Modular Nuclear Reactors, UK | Leave a comment

TODAY. Small modular reactors – yes -the nuclear lobby will keep hyping them – no matter what!

Well, we all do know why. The small nuclear reactor (SMR)power industry – moribund though it is, is essential for the nuclear weapons industry – for a number of reasons, but importantly – to put a sweet gloss on that murderous industry.

Never mind that USA’s NuScale’s SMRs were a resounding flop – NuScale is still being touted, along with all the other little nuclear unicorns manouvreing to get tax-payer funding.

The facts remain, and apparently just need to be hammered again and again:

SMRs are not cheap, not safe, do not reduce wastes, are not reliable for off-grid power, are not more efficient fuel users than are large reactors.

The latest hyped -up push for SMRs is in Canada – with the boast that they will benefit indigenous communities . Successful bribery of indigenous people would give a huge boost to the global nuclear lobby, – as indigenous people have historically been the most distrustful of uranium mining and of the whole nuclear fuel chain.

The gimmicks this time are floating nuclear power plants – barges carrying Westinghouse’s eVinci microreactors. These would take over from the current deisal power plants serving remote communities. There are already some solar, wind and battery projects – frowned upon by the nuclear lobby, of course.

These projects are being strongly promoted, but poorly explained to indigenous communities, would bring radiological hazards along Canada’s Northern shoreline

And what really are the chances that these little nuclear power sources would be effective anyway? Recent reports by the International Atomic Energy Agency (IAEA) reveal that while 83 small nuclear reactors are “in development”, but there are only 2 in operation.

In both cases, the development of the reactors was a very lengthy and expensive process.

The Chinese SMR HTR-PM- “Between January and December 2022, the reactors operated for only 27 hours out of a possible maximum of 8,760 hours. In the subsequent three months, they seem to have operated at a load factor of around 10 percent.” 

For the Russian SMR –  “The operating records of the two KLT-40S reactors have been quite poor. According to the IAEA’s PRIS [Power Reactor Information System] database, the two reactors had load factors of just 26.4 and 30.5 percent respectively in 2022, and lifetime load factors of just 34 and 22.4 percent.”

Will Canada’s remote indigenous communitites buy the duplicitous nuclear lobby’s propaganda on SMRs ? And then, subsequently, will the rest of us buy it, despite the facts. I guess that the corporate media will help, – if lies are repeated often enough, people come to believe them.

May 4, 2024 Posted by | Christina's notes, Small Modular Nuclear Reactors | Leave a comment

Small modular reactors aren’t the energy answer for Canada’s remote communities and mines

Screenshot

The energy costs associated with small modular reactors exceed those of diesel-based electricity. Policy-makers should focus on renewables.

by Sarah Froese, Nadja Kunz, M. V. Ramana August 26, 2020  https://policyoptions.irpp.org/magazines/august-2020/small-modular-reactors-arent-the-energy-answer-for-remote-communities-and-mines/

A new type of theoretical nuclear power plant design called small modular reactors (SMRs) has been in the news of late. Earlier this year, at the 2020 Canadian Nuclear Association conference, Minister of Natural Resources Seamus O’Regan announced that the federal government will release an SMR Action Plan this fall. Ontario, New Brunswick and Saskatchewan have announced their backing and possibly some financial support for the development of these reactors.

Promoters suggest that remote communities and off-grid mining operations are promising markets for SMRs in Canada. These communities and mines pay a lot for electricity because they are reliant on diesel generators, and transporting and storing diesel to these locations can be very expensive. Thus, supporters hope, SMRs might be a way to lower electricity costs and carbon dioxide emissions.

We examined this proposition in detail in a recently published paper and concluded that this argument has two problems. First, the electricity that SMRs produce is far more expensive than diesel-based electricity. Second, even ignoring this problem, the total demand for electricity at these proposed markets is insufficient to justify investing in a factory to manufacture the SMRs.

SMRs have been proposed as a way to deal with many problems associated with large nuclear power plants, in particular the high costs of construction, running to tens of billions of dollars. SMR designs have much in common with large nuclear reactors, including, most basically, their reliance on nuclear fission reactions to produce electricity. But they also differ from large nuclear reactors in two ways. First, they have electricity outputs of less than 300 megawatts (MW) and sometimes as low as a few MW, considerably lower than the outputs of 700 to 1500 MW typical of large nuclear reactors. Second, SMR designs use modular means of manufacturing, so that they need only be assembled, rather than fully constructed, at the plant site. While large reactors that have been constructed in recent years have also adopted modular construction, SMR designers hope to rely more substantially on these techniques.

A standard metric used to evaluate the economics of different energy choices is called the levelized cost of energy (LCOE). We calculated that the LCOE for SMRs could be over ten times greater than the LCOE for diesel-based electricity. The cheapest options are hybrid generation systems, with wind or solar meeting a part of the electricity demand and diesel contributing the rest.

Why this high cost? The primary problem is that the small outputs from SMRs run counter to the logic of economies of scale. Larger reactors are more cost-efficient because they produce more electricity for each unit of material (such as concrete and steel) they use and for the number of operators they employ. SMR proponents argue that they can make up for this through the savings from mass manufacture at factories and the learning that comes with manufacturing many reactors. The problem is that building a factory requires a sizable market, sometimes referred to as an order book. Without a large number of orders, the investment needed to build the factory will not be justified.

We estimated the potential market for SMRs at remote mines and communities in Canada. We drew primarily upon two databases produced by Natural Resources Canada regarding mining areas and remote communities. As of 2018, there were 24 remote mining projects that could be candidates for SMR deployment within the next decade. Currently, these projects use diesel generators with a total installed capacity of 617 MW. For remote communities, we calculated a fossil fuel (primarily diesel) generation capacity of 506 MW. But many of these communities had demands that were too low for even the smallest-output SMR under review at the Canadian Nuclear Safety Commission.

Even if all these potential buyers want to adopt SMRs for electricity supply, without regard to the economic or noneconomic factors weighing against the construction of nuclear reactors, the combined demand would likely be much less than 1000 MW. The minimum demand required to justify the cost of producing SMRs would be three to seven times higher.

Furthermore, we concluded that the economics of SMRs don’t compete when compared with other alternatives. The cost of electricity from SMRs was found to be much higher than the cost of wind or solar, or even of the diesel supply currently used in the majority of these mines and communities.

Of course, our estimates for the LCOEs of different sources are dependent on various assumptions. We tried varying these assumptions within reasonable limits and found that the main result — that electricity from SMRs is far more expensive than the corresponding costs of generating electricity using diesel, wind, solar or some combination thereof — remains valid. All else being equal, the assumed capital cost of constructing a SMR would have to decline by over 95 percent to be competitive with a wind-diesel hybrid system. The limited experience with SMRs that are being built around the world suggests that construction costs will be higher, not lower, than advocates promise.

Meanwhile, renewables and storage technologies have seen substantial cost declines over the past decades. Recent estimates place wind, solar and hybrid systems at costs competitive with diesel power. Successful demonstrations suggest that renewable hybrid applications are becoming increasingly feasible for heavy industry, and the implementation of numerous numerous projects in northern communities suggests a high level of social acceptance. Many northern and, in particular, Indigenous communities have an interest in self-determined decision-making and maintaining a good relationship with the land. In June 2019, for example, the Anishinabek Chiefs-in-Assembly, representing 40 First Nations across Ontario, unanimously expressed opposition to SMRs. Grand Council Chief Glen Hare announced that the Anishinabek Nation is “vehemently opposed to any effort to situate SMRs within our territory.”

Instead of focusing on SMRs, policy-makers should bolster support for other renewable generation technologies as key mechanisms to reduce carbon emissions and align with community values.

May 4, 2024 Posted by | Canada, Small Modular Nuclear Reactors | Leave a comment

A Closer Look at Two Operational Small Modular Reactor Designs

There are literally dozens of small modular reactor (SMR) and microreactor designs being developed by different companies around the world, and some of the work has been going on for decades. Yet, only two designs have actually been built and put into commercial operation. POWER takes a closer look at both of them.

Power, by Aaron Larson 1 May 24

Many nuclear power supporters have long thought small modular reactors (SMRs) would revolutionize the industry. Advocates expect SMRs to shorten construction schedules and bring costs down through modularization and factory construction. They often cite numerous other benefits that make SMRs seem like no-brainers, and yet, only two SMR designs have ever been built and placed in commercial operation.

The International Atomic Energy Agency (IAEA) publishes booklets biennially on the status of SMR technology. In the IAEA’s most recent booklet, it notes 25 land-based water-cooled SMRs and another eight marine-based water-cooled designs are under development globally. It also lists 17 high-temperature gas-cooled SMRs, eight liquid-metal-cooled fast-neutron-spectrum SMRs, 13 molten-salt SMRs, and 12 microreactors. If you do the math, that’s 83 SMR designs under development, but only the KLT-40S and HTR-PM are actually operational.

KLT-40S

The KLT-40S is a pressurized water reactor (PWR) that was developed in Russia. It is an advanced version of the KLT-40 reactor, which has been used in nuclear-powered icebreakers. The first KLT-40S units, and, to date, the only two of these units to enter commercial operation, were deployed in the Akademik Lomonosov—the world’s first purpose-built floating nuclear power plant (FNPP, Figure 1 on original).

Main Design Features.………………………………………………………………………………………………………….

Deployment Details.…………………………….

Construction and testing of the FPU was completed in 2017 at the Baltic shipyard. In May 2018, the vessel was towed 4,000 kilometers (km), around Finland and Sweden, to Murmansk, completing the first leg of its journey to Pevek. Fuel loading was completed in Murmansk in October 2018. First criticality was achieved in November 2018, then in August 2019, the vessel embarked on the second leg of its journey—a distance of 4,700 km—towed by two tugboats to the Arctic port town of Pevek, where it was connected to the grid on Dec. 19, 2019. Akademik Lomonosov was fully commissioned on May 22, 2020, and it currently provides heat to the town of Pevek and supplies electricity to the regional Chaun-Bilibino power system.

HTR-PM

On Dec. 6, 2023, China National Nuclear Corp. announced it had commenced commercial operation of the high-temperature gas-cooled modular pebble bed (HTR-PM) reactor demonstrator. The HTR-PM project was constructed at a site in Rongcheng, Shandong Province, roughly midway between Beijing and Shanghai in eastern China…………………………………

Main Design Features.…………………………………………………………………………………………………..

Deployment Details.……………………………………………………………………. The civil work for the nuclear island buildings was completed in 2016 with the first of two reactor pressure vessels installed in March that year. The fuel plant reached its expected production capacity in 2017. Startup commissioning and testing of the primary circuit were finished by the end of 2020. The HTR-PM achieved first criticality in September 2021, and was ultimately grid connected on Dec. 20, 2021.

Spotty Results at Best

While it is laudable that these SMRs—the KLT-40S and HTR-PM—have been placed in commercial operation, their performance since entering service has come under fire. In The World Nuclear Industry Status Report 2023 (WNISR), a Mycle Schneider Consulting Project, co-funded by the German Federal Ministry for the Environment, Nature Conservation, Nuclear Safety, and Consumer Protection, it says both designs have operated at low capacity factors recently.

Concerning the Chinese HTR-PM, the WNISR says, “Between January and December 2022, the reactors operated for only 27 hours out of a possible maximum of 8,760 hours. In the subsequent three months, they seem to have operated at a load factor of around 10 percent.” The Russian units’ performance has been nearly as dismal. “The operating records of the two KLT-40S reactors have been quite poor. According to the IAEA’s PRIS [Power Reactor Information System] database, the two reactors had load factors of just 26.4 and 30.5 percent respectively in 2022, and lifetime load factors of just 34 and 22.4 percent. The reasons for the mediocre power-generation performance remain unclear,” the report says.

Meanwhile, the promises of shortened timelines and lower costs were not borne out by these projects. “The experience so far in constructing these two SMRs as well as estimates for reactor designs like NuScale’s SMR show that these designs are also subject to the historical pattern of cost escalations and time overruns. Those cost escalations do make it even less likely that SMRs will become commercialized, as the collapse of the Carbon Free Power Project involving NuScale reactors in the United States illustrated,” the WNISR says………….. https://www.powermag.com/a-closer-look-at-two-operational-small-modular-reactor-designs/

May 4, 2024 Posted by | China, Russia, Small Modular Nuclear Reactors | Leave a comment

ARC might need to redesign its SMR technology: former president + US bans import of enriched uranium + more to the story


Susan O’Donnell, 2 May 24
To clarify, there’s currently no enrichment plant in the US that produces HALEU (fuel enriched between 5 and 20 percent), as far as I’m aware. Any nuclear fuel enrichment happening in the U.S. would be for the existing light-water reactors that use fuel enriched to less than 5 percent.
My take: the idea that the ARC reactor design could change from using HALEU fuel to low enriched uranium is frankly ridiculous. It would not be the same reactor at all, it would be a completely different design. 

Quote: “It’s not something that can’t be fixed,” Sawyer said.

Fixed? WTF? This whole project is a scam.

U.S. Senate passes Russian uranium import ban

https://www.ukrinform.net/rubric-economy/3858689-us-senate-passes-russian-uranium-import-ban.html

The article above is about the shortage of HALEU, the fuel currently only available in Russia that is needed by the designs of advanced reactors cooled by liquids other than water. The design for the ARC reactor slated for Point Lepreau in New Brunswick requires HALEU.

New Brunswick’s Telegraph Journal:

ARC might need to redesign its SMR technology: former president

Norm Sawyer points to other companies around the world that pivoted quickly to address the lack of enriched uranium available

Adam Huras
Published May 01, 2024

The former president and CEO of ARC Clean Technology says the company might need to redesign its small modular nuclear reactor technology.

Norm Sawyer points to other companies around the world that pivoted quickly to address the lack of enriched uranium available.

Brunswick News reported earlier this week that ARC is still in search of a new enriched uranium supplier, after it originally planned to buy from Russia.

Meanwhile, Energy Minister Mike Holland says he has been assured that “there’s a queue for North American enriched uranium and we’re in it,” maintaining the company that the Higgs government spent $20 million on won’t be shut out.

Firms around the world developing a new generation of small nuclear reactors to help cut carbon emissions have been forced to face a big problem: The only company that sells the enriched fuel they need is Russian.

“It’s not only ARC, the industry in general is really dealing with the fallout of the war,” Sawyer said, who is now a nuclear consultant through his own firm. “Russia is the main supplier of HALEU around the world.”

High-assay low-enriched uranium (HALEU) is an integral component of the company’s ARC-100 sodium-cooled fast reactor, as well as a number of other advanced reactors currently in development attempting to achieve smaller designs.

But it’s not as simple as finding that enriched uranium closer to home.

While Canada mines uranium – there are currently five uranium mines and mills operating in Canada, all located in northern Saskatchewan – it does not have uranium enrichment plants.

The U.S. opened its first and only enrichment plant last year, operated by Centrus Energy in Ohio, amid a federal push to find a solution to the Russia problem.

It remains the only facility in the U.S. licensed to enrich uranium.

It currently has contracts with two American companies pursuing SMR technology, although it says it could rapidly expand production with federal investment.

One of those, TerraPower, a nuclear reactor developer founded by Bill Gates, has said Russia’s invasion would mean a delay to the deployment of its Natrium reactor by at least two years.

Other companies have pivoted.

Sawyer pointed to Denmark’s Seaborg Technologies that announced last year it would be changing its proposed SMR fuel from HALEU to low-enriched uranium “due to the risks associated with developing a sufficient supply.”

That resulted in design changes.

It was a move the company said was necessary to meet its planned timeline to see a first group of SMRs ready by 2028……………………………………………………..

What I’ve been told that there are a number of things taking place to ensure that there’s a queue for North American enriched uranium and we’re in it,” Holland said.

“That’s what I’ve been told and told definitively.”

Holland said the U.S. has a “vested interest” in aiding Canada and its SMR technology because Canada has the uranium they’re going to need as well.

“There are people saying ‘hey, if Canada is going to be your large supplier we’re going to have to work out, quid pro quo, that we don’t get excluded,’” he said.

Holland maintained that “our toe is stuck in the door so we have an opportunity to be part of that supply chain………………………………..

Sawyer said making a change to a different fuel means components will need to be redesigned.

“Obviously, you design a reactor for the type of fuel you’re going to use so there’s obviously some work to be done to realign the reactor core to the new type of fuel,” he said. “Is it easy? I’m not sure if it’s easy. There is some work to be done, there’s no doubt.”

Sawyer added that there’s two components to SMRs: the reactor design, construction and deployment, and then the fuel.

“Any delay on either one of those sides of the equation could cause a delay later on,” he said.

 https://tj.news/new-brunswick/arc-might-need-to-redesign-its-smr-technology-former-president#:~:text=The%20former%20president%20and%20CEO,small%20modular%20nuclear%20reactor%20technology.&text=Article%20content-,Norm%20Sawyer%20points%20to%20other%20companies%20around%20the%20world%20that,lack%20of%20enriched%20uranium%20available.

May 4, 2024 Posted by | Canada, Small Modular Nuclear Reactors | Leave a comment

Five Things the “Nuclear Bros” Don’t Want You to Know About Small Modular Reactors

1. SMRs are not more economical than large reactors.

2. SMRs are not generally safer or more secure than large light-water reactors.

3. SMRs will not reduce the problem of what to do with radioactive waste.

4. SMRs cannot be counted on to provide reliable and resilient off-the-grid power for facilities, such as data centers, bitcoin mining, hydrogen or petrochemical production.

5. SMRs do not use fuel more efficiently than large reactors.

Ed Lyman, April 30, 2024 https://blog.ucsusa.org/edwin-lyman/five-things-the-nuclear-bros-dont-want-you-to-know-about-small-modular-reactors/

Even casual followers of energy and climate issues have probably heard about the alleged wonders of small modular nuclear reactors (SMRs). This is due in no small part to the “nuclear bros”: an active and seemingly tireless group of nuclear power advocates who dominate social media discussions on energy by promoting SMRs and other “advanced” nuclear technologies as the only real solution for the climate crisis. But as I showed in my 2013 and 2021 reports, the hype surrounding SMRs is way overblown, and my conclusions remain valid today.

Unfortunately, much of this SMR happy talk is rooted in misinformation, which always brings me back to the same question: If the nuclear bros have such a great SMR story to tell, why do they have to exaggerate so much?

What are SMRs?

SMRs are nuclear reactors that are “small” (defined as 300 megawatts of electrical power or less), can be largely assembled in a centralized facility, and would be installed in a modular fashion at power generation sites. Some proposed SMRs are so tiny (20 megawatts or less) that they are called “micro” reactors. SMRs are distinct from today’s conventional nuclear plants, which are typically around 1,000 megawatts and were largely custom-built. Some SMR designs, such as NuScale, are modified versions of operating water-cooled reactors, while others are radically different designs that use coolants other than water, such as liquid sodium, helium gas, or even molten salts.

To date, however, theoretical interest in SMRs has not translated into many actual reactor orders. The only SMR currently under construction is in China. And in the United States, only one company—TerraPower, founded by Microsoft’s Bill Gates—has applied to the Nuclear Regulatory Commission (NRC) for a permit to build a power reactor (but at 345 megawatts, it technically isn’t even an SMR).

The nuclear industry has pinned its hopes on SMRs primarily because some recent large reactor projects, including Vogtle units 3 and 4 in the state of Georgia, have taken far longer to build and cost far more than originally projected. The failure of these projects to come in on time and under budget undermines arguments that modern nuclear power plants can overcome the problems that have plagued the nuclear industry in the past.

Developers in the industry and the US Department of Energy say that SMRs can be less costly and quicker to build than large reactors and that their modular nature makes it easier to balance power supply and demand. They also argue that reactors in a variety of sizes would be useful for a range of applications beyond grid-scale electrical power, including providing process heat to industrial plants and power to data centers, cryptocurrency mining operations, petrochemical production, and even electrical vehicle charging stations.

Here are five facts about SMRs that the nuclear industry and the “nuclear bros” who push its message don’t want you, the public, to know.

Continue reading

May 2, 2024 Posted by | business and costs, Reference, safety, Small Modular Nuclear Reactors, spinbuster | 1 Comment

France Increases State Funding for Advanced Nuclear R&D Project

by Jov Onsat, Rigzone Staff, Thursday, May 02, 2024

The French government has received clearance from the European Commission to provide Electricité de France (EDF) a further EUR 300 million ($321.6 million) for the front-end design phase of a project to develop small modular nuclear reactors (SMRs).

The project by Nuward, the nuclear energy-focused subsidiary of state-owned EDF, aims to come up with a design that has a power output of up to 300 megawatts electric.

The front-end design is the third phase of the five-phase project. The Commission previously approved EUR 50 million ($53.6 million) in French state aid for the second phase, which focused on gathering new knowledge for SMR design and construction.

Under the measure, the aid will take the form of a direct grant of up to EUR 300 million that will cover the R&D [research and development] project until early 2027”, the Commission said in a statement announcing clearance for the new funding from European Union competition regulations. “The measure will support Nuward in sizing the modules and components of the SMRs and validating their integration in the SMRs by means of numerical simulators and laboratory tests.

“Nuward will also carry out industrialization studies relating to the modular design and mass production of SMRs. Finally, the measure will also support Nuward in the preparation of the required safety demonstrations for the approval of the project by the national nuclear safety authorities”.

The Commission recently launched an alliance to accelerate the development of SMRs, following moves by the United Kingdom and United States to commercially scale up the advanced nuclear generation technology.

The public-private coalition aims to come up with a working model by the 2030s. “The Alliance targets a wide range of SMR stakeholders including vendors, utilities, specialized nuclear companies, financial institutions, research organizations, training centers and civil society organizations”, the Commission said in a press release February 9 announcing the initiative…………………..

Earlier the UK government announced an investment of GBP 300 million ($376 million) for the domestic production of high-assay low-enriched uranium (HALEU), challenging Russia’s status as the only commercial manufacturer of the fuel for SMRs. The UK previously funded a program by Rolls-Royce PLCs to design an SMR model, which is currently awaiting approval for deployment in Poland, as announced by the company last week—though the product is still undergoing the regulatory design assessment in the UK.

The UK will become the first country in Europe to launch a high-tech HALEU nuclear fuel program, strengthening supply for new nuclear projects and driving Putin further out of global energy markets”, the UK Department of Energy Security and Net Zero (DESNZ) said in a news release January 7 announcing the HALEU funding.

The DESNZ said GBP 10 million ($12.5 million) has also been allotted to develop sites and promote skills development for the production of other “advanced nuclear fuels”.

The International Atomic Energy Agency says HALEU is only produced in the U.S. and Russia but only the latter makes the fuel at a commercial scale. SMRs need HALEU, which contains five to 20 percent of uranium-235, beyond the five percent level that fuels most of today’s nuclear power plants, according to the United Nations nuclear watchdog.

The UK move was followed by an announcement by the US Department of Energy (DOE) offering contracts worth up to $500 million in total for HALEU production, besides funding offers for SMR design development. “Currently, HALEU is not commercially available from U.S.-based suppliers, and boosting domestic supply could spur the development and deployment of advanced reactors in the United States”, the DOE noted in a media statement January 9 announcing the funding offer.

Last year the U.S. Nuclear Regulator Commission issued the country’s first certification for an SMR design, that of NuScale Power Corp.  https://www.rigzone.com/news/france_increases_state_funding_for_advanced_nuclear_rd_project-02-may-2024-176607-article/

May 2, 2024 Posted by | France, Small Modular Nuclear Reactors | Leave a comment

Rolls-Royce scales back plans to build nuclear factories in UK

Rolls-Royce has scaled back plans to build two new factories for its small modular reactor (SMR) programme in the UK, following delays to a government design competition.

The FTSE 100 company had originally proposed one factory to make heavy pressure vessels for its SMRs and another to make the building blocks of the reactors. 

It had drawn up a final shortlist of locations for the pressure vessels factory, including the International Advanced Manufacturing Park on the outskirts of Sunderland, Teesworks in Redcar and the Gateway industrial park in Deeside, Wales.

But on Friday Rolls confirmed it no longer intends to proceed with that plan because there is no longer time to build the factory and make the first pressure vessels for the early 2030s, when it hopes to complete its first SMRs.

It is still proceeding with work to build the second factory, however.

The company had been waiting for the outcome of an ongoing SMR design competition in the UK – first announced by the Government in 2015 – before it made a decision on the pressure vessel plant. 

But that competition has been repeatedly delayed, with the arms length body Great British Nuclear only formally created last summer and winners not due to be announced until this June at the earliest. 

Instead the engineering giant will now buy its heavy pressure vessels from a third party supplier.

The large, metal components sit at the heart of nuclear reactors and must be able to withstand extremely high temperatures and pressures. They are only made by a select group of companies, partly due to the need for specialist welding techniques.

Among their number is now Sheffield Forgemasters, which was nationalised by the Ministry of Defence in 2021.

Earlier this month, Sheffield became the sole UK company to gain the qualifications needed to make SMR reactor vessel components. 

Despite having shelved its plans for a heavy pressure vessel factory, Rolls is still pressing ahead with plans to build its second factory, which will build the modular units that make up its SMRs. 

It is understood that sites shortlisted for the pressure vessel factory will also be contenders for the second plant but no decisions have been made.

On Friday, a spokesman for Rolls-Royce SMR confirmed the company had now “prioritised work on our modules assembly and test facility”, adding: “Our efforts are focused on identifying the best site to support our deployment at pace.”

The company has also not ruled out reviving its plan for a heavy pressure vessel factory at some point in the future, so long as it manages to build up a healthy pipeline of orders. 

A Government spokesman said: “Our world leading SMR competition aims to be the fastest of its kind, helping secure billions in investment for the UK, meaning cleaner, cheaper and more secure energy in the long-term.”

May 2, 2024 Posted by | business and costs, Small Modular Nuclear Reactors, UK | Leave a comment

Rolls-Royce scales back plans to build nuclear factories in UK

Curtailing comes after repeated delays to an ongoing government design competition

Rolls-Royce has scaled back plans to build two new factories for its small
modular reactor (SMR) programme in the UK, following delays to a government
design competition. The FTSE 100 company had originally proposed one
factory to make heavy pressure vessels for its SMRs and another to make the
building blocks of the reactors.

It had drawn up a final shortlist of
locations for the pressure vessels factory, including the International
Advanced Manufacturing Park on the outskirts of Sunderland, Teesworks in
Redcar and the Gateway industrial park in Deeside, Wales.

But on Friday Rolls confirmed it no longer intends to proceed with that plan because
there is no longer time to build the factory and make the first pressure
vessels for the early 2030s, when it hopes to complete its first SMRs.

It is still proceeding with work to build the second factory, however. The
company had been waiting for the outcome of an ongoing SMR design
competition in the UK – first announced by the Government in 2015 –
before it made a decision on the pressure vessel plant.

But that competition has been repeatedly delayed, with the arms-length body Great
British Nuclear only formally created last summer and winners not due to be
announced until this June at the earliest. Instead the engineering giant
will now buy its heavy pressure vessels from a third party supplier. The
large, metal components sit at the heart of nuclear reactors and must be
able to withstand extremely high temperatures and pressures. They are only
made by a select group of companies, partly due to the need for specialist
welding techniques.

Rolls is still pressing ahead with plans to build its
second factory, which will build the modular units that make up its SMRs.
It is understood that sites shortlisted for the pressure vessel factory
will also be contenders for the second plant but no decisions have been
made.

 Telegraph 27th April 2024

https://www.telegraph.co.uk/business/2024/04/27/rolls-royce-plans-build-smr-water-vessel-factory-uk

May 1, 2024 Posted by | business and costs, Small Modular Nuclear Reactors, UK | Leave a comment

New Nuclear Energy: Assessing the National Security Risks

 https://blogs.gwu.edu/elliott-iistp/research-2/ 26 Apr 24

IISTP Research Professor Sharon Squassoni publishes a comprehensive report assessing the risks of nuclear energy and nuclear weapons.

Read the complete report: New Nuclear Energy: Assessing the National Security Risks“.

GWU REPORT: NATIONAL SECURITY RISKS GROW WITH NEW NUCLEAR ENERGY

Drone strikes against Ukraine’s nuclear reactors highlight risks 

WASHINGTON, DC – April 23, 2024 – Proliferation of nuclear weapons, nuclear terrorism, sabotage, coercion and military operations – these risks associated with nuclear energy can all be expected to grow as countries seek to implement their new nuclear energy objectives, according to a new report published today by George Washington University’s (GWU) Sharon Squassoni.  The aim of 22 countries to triple nuclear energy capacity by 2050, announced on the margins of COP-28, was adopted with little thought to the national security implications. The promotion of small modular reactors (SMRs)– specifically tailored to developing countries – will heighten, not diminish risks. 

The report by GW professor Sharon SquassoniNew Nuclear Energy: Assessing the National Security Risks,” comes as drone strikes against Ukrainian nuclear power plants highlight nuclear reactor vulnerabilities. Other national security risks will accompany significant nuclear growth as renewed interest in nuclear energy to reduce greenhouse gas emissions sparks programs across the globe. Squassoni, a professor at GWU’s Elliott School of International Affairs, now researches risk reduction from nuclear energy and nuclear weapons after serving in the State Department, Arms Control and Disarmament Agency and the Congressional Research Service. 

Proliferation and nuclear terrorism are the top two national security risks, but sabotage, coercion and military operations pose other risks. An attempt to reduce dependence on foreign suppliers – a national security risk itself — using nuclear energy could worsen the risk of proliferation by motivating fuel cycle independence.  SMRs are still in development, with few restrictions on designs. Reactors fueled with highly enriched uranium or plutonium will increase risks of proliferation and terrorism because those materials are weapons-usable. Reactors designed to include lifetime cores will build up plutonium over time. Fast reactor designs that require reprocessing, especially continuous recycling of fuel, could ultimately confer latent nuclear weapons capabilities to many more states. In sum, the kinds of reactors now under consideration do nothing to reduce known risks, and some pose heightened risks. There appears to be no attempt to forge agreement among suppliers or governments to restrict reactor choices that pose greater proliferation risks.

If the mass production of small modular reactors lowers barriers to entry into nuclear energy, there will be many more states deploying nuclear power reactors, including those with significant governance challenges. Russian and Chinese programs to promote nuclear energy target many of those states. Cooperation among key states essential to minimize the safety, security and proliferation risks of nuclear energy is at an all-time low. The call to triple nuclear energy coincides with the disintegration of cooperation, the unraveling of norms and the loss of credibility of international institutions that are crucial to the safe and secure operation of nuclear power.

April 28, 2024 Posted by | safety, Small Modular Nuclear Reactors | 1 Comment

Potential for small and micro modular reactors to electrify developing regions

Nature Energy (2024)

Abstract

While small-scale nuclear power is typically thought of for niche markets, recent work has suggested that it could help address the massive gaps in energy access in developing countries. However, nuclear energy has safety, governance and economic considerations that affect its deployment. Here we present a global analysis of regions suitable for nuclear reactor deployment based on physical siting criteria, security, governance and economic competitiveness. We use high-resolution population and satellite night-time light data to identify areas in need of electricity. We show that, technically, reactors in the 1–50 MWe range could serve 70.9% of this population. However, economics alone would make microreactors uncompetitive compared with renewables and energy storage for 87% of this population. Grid extensions and small modular nuclear reactors (with more competitive economics) could electrify these populations, but governance issues could limit deployment for all but 20% of this population. Together, governance and economics eliminate 95% of the potential market for microreactors.…………………………………………………………………more https://www.nature.com/articles/s41560-024-01512-y

April 23, 2024 Posted by | Small Modular Nuclear Reactors | Leave a comment

Say no to small modular reactors: Stop normalizing the exploitation of nature

The Bulletin, By Erin Hurley | April 1, 2024 Erin Hurley is a fourth-year student at St. Thomas University in Fredericton, New Brunswick, where she studies Environment & Society and Journalism. She was a research assistant last year on the Plutonium Project, funded by the Social Sciences and Humanities Research Council (SSHRC), for which she explored news media discourses on proposed small modular reactors in New Brunswick. This year, she is a research assistant on the SSHRC-funded CEDAR (Contesting Energy Discourses through Action Research) Project, for which she is focusing on news media coverage of energy transitions in the province.

Among other global crises, the worsening impacts of climate change are intensifying every year. Last year was the warmest on record and, beginning in March 2023, raging wildfires filled cities across Canada with smoke for months. This year is already shaping up to be warmer than the last. This is why a lot of young people are questioning the very systems we live under. This is why many of us support a rapid and just transition in energy. But in this process, some governments are promoting an expansion of nuclear power, supposedly to solve climate change. I fear that such an expansion will result in my generation having to confront an equally terrifying set of problems resulting from the nuclear fuel chain.

This is precisely what I already see happening around me in the Canadian province of New Brunswick where I live and study. Over the last few years, the province’s government has advocated for and funded the development of what it calls small modular reactors (SMRs). Even though SMR doesn’t include the word “nuclear,” these are nuclear reactors. Ostensibly, these reactors are meant to decarbonize the Canadian economy. But in 2021, New Brunswick Energy Minister Mike Holland protested the 2030 target for phasing out coal in the province, saying new nuclear reactors would not be ready in time to meet that goal. How will the expansion of nuclear power decarbonize the economy if, meanwhile, New Brunswick is still extracting and burning fossil fuels?

The province has funded two companies—Moltex Energy and ARC Clean Technology—to develop small modular reactors. On their websites, Moltex and ARC market nuclear power as “clean,” “carbon free,” and a “clean energy solution.”

Last year, Moltex CEO Rory O’Sullivan spoke to me, my fellow students, and professors working on the Plutonium Project at St. Thomas University in Fredericton, New Brunswick, in which we explored these small modular reactors being proposed for the province to develop an understanding of the assumptions, claims, and implications of these technologies. I remember O’Sullivan as friendly and well-spoken. He emphasized that a transition away from fossil fuels is necessary and that renewable energy is a key element in this transition. Yet he told us that wind farms, for example, could not generate enough energy to sustain our society, and that battery storage was not advanced enough to help with this, and thus renewables could not be considered an effective climate solution on their own. This is why he advocates for small modular reactors—as a necessary supplement to renewables in the energy transition. But, again, he stressed that, at Moltex, they were working to reduce any potential safety risks.

This made me wonder: What about the highly radioactive waste these reactors will produce?

Even if SMRs produce less waste than past nuclear reactors (although not when weighted by how much electricity they produce), spent fuel will remain dangerously radioactive for thousands of years. While nuclear proponents have argued that a deep geological repository would be an effective storage space for the waste, there are many uncertainties surrounding this proposal, and the long-term impacts are unknown. The proposed sites for the repository are located on traditional Indigenous lands in the Wabigoon Lake Ojibway Nation-Ignace and Saugeen Ojibway Nation-South Bruce areas in Ontario. Because the safety of the proposed repository is unproven, storing radioactive waste there would jeopardize the health of the local Indigenous communities and their lands.

Moltex and ARC have advertised reprocessing as a way to recycle waste and use it to power other reactors. However, this is also incredibly dangerous, because once plutonium is separated from used nuclear fuel, it can be used much more easily in the production of atomic weapons. If separated plutonium were to fall into the wrong hands, the result would be nuclear proliferation—an increased number of nuclear weapons across the globe.

In addition to the waste and proliferation problems, small modular reactors will not be built and operating in time to be an effective climate solution. Canada’s climate targets involve decreasing greenhouse gas emissions to 40 per cent below 2005 levels by 2030 and reaching net-zero by 2050. However, ARC predicts that it will finish building its first small modular reactor by 2028 which will “replace the existing coal generation station in 2030” at Point Lepreau Nuclear Generating Station in Saint John, New Brunswick. And Moltex does not expect to have an “operational reactor” until “the early 2030s.”

This timeline will clearly not help Canada reach its decarbonization goal by 2030, and so the country will not be on track for the 2050 goal either. Given these realities, I find it hard to believe that nuclear power is in the best interest of humans, non-human species, or the planet as a whole.

Capitalist nations that prioritize economic growth above all else, such as the United States and Canada, have normalized the exploitation of nature……………………………………………….. more https://thebulletin.org/2024/04/say-no-to-small-modular-reactors-stop-normalizing-the-exploitation-of-nature/#post-heading

April 3, 2024 Posted by | Canada, Small Modular Nuclear Reactors | 1 Comment

New nuclear reactor types will not solve waste and safety issues

26 March 2024  https://www.modernpowersystems.com/news/newsnew-nuclear-reactor-types-will-not-solve-waste-and-safety-issues-11634478

Novel nuclear power plant designs do not resolve the technology’s fundamental challenge of hazardous nuclear waste, a 22 March report commissioned by Germany’s Federal Office for the Safety of Nuclear Waste Management (BASE) has concluded. “None of the alternative reactor types would make a final repository redundant,” the government agency said, according to a report by online news agency Clean Energy Wire.

Despite efforts by producers of Generation IV reactors to “intensively advertise” the concept’s supposed benefits, said BASE, it “could not detect any trends that would make the construction of alternative reactor types at an industrial scale likely in the next years.” On the contrary, the disadvantages and uncertainties from a security perspective would continue to outweigh the technology’s advantages, the study led by the Institute for Applied Ecology (Öko-Institut) found.

New nuclear plant designs, such as small modular reactors (SMR), would not only perpetuate the difficult long-term question of nuclear waste disposal, but also had little to offer for solving short-term climate action problems, BASE added.

The report looked at seven novel reactor types, which according to their producers are more efficient in nuclear fuel use and run more safely and reliably, are economically viable, and cause less radioactive waste. While some of these improvements seem plausible, the report said that central questions regarding safety remain unanswered with all new concepts. “In some areas, there are even disadvantages compared to today’s light water reactors,” which remain the favoured technology in six surveyed countries (USA, Russia, China, South Korea, Poland and Belgium). Alternative reactor types still required “substantial“ research and development, and it would likely still take several decades before they can be deployed at a relevant scale, the researchers added. Promises about new concepts in nuclear technology as a potential boost for climate action therefore had to be considered “not realistic,” they concluded.

While Germany closed down its three last reactors in spring 2023 after a decades-long debate, many other countries continue to rely on nuclear technology or even plan to considerably expand it in a bid to bring down their energy-related greenhouse gas emissions. At the International Atomic Energy Agency’s (IAEA) first ever nuclear energy summit in Brussels earlier March, more than two dozen states called for a revival of the technology, including France, the Netherlands, the USA and Japan. “Without the support of nuclear power, we have no chance to reach our climate targets on time,” International Energy Agency (IEA) chief Fatih Birol said in a report carried by news agency Reuters.

Nuclear power in Europe

The role of nuclear power in Europe’s emissions reduction plans has been a contentious issue for many years, with Germany and France emerging as the main opposing forces between two groups of countries aiming to rely entirely on renewable power or to also use nuclear power in a future climate neutral energy system. While Germany has achieved a substantial expansion of its renewable power capacity and now sources more than half of its electricity that way, the country still faces challenges regarding the required grid modernisation and back-up and storage capacity to complement wind turbines and solar panels. France, on the other hand, has the largest share of nuclear power production of any country but struggles to secure funding for new projects and to comply with cost and construction time plans for existing ones.

March 29, 2024 Posted by | Small Modular Nuclear Reactors, wastes | Leave a comment

« Previous Entries