Tag Archives: NRU


NRU is the Key to Canadian Nuclear Science and Innovation

The NRU reactor
The National Research Universal (NRU) reactor at Chalk River.

An advanced engineering and manufacturing economy – particularly one that values national autonomy and security – derives good value from having a nuclear research capability. The core of such a capability is a research reactor.

Canada has this capacity in the National Research Universal reactor (NRU), located in Chalk River, Ontario and operated by Canadian Nuclear Laboratories, formerly AECL. But it will lose this capacity when the reactor shuts down as planned by March 31, 2018.

The NRU, a high-capability research reactor, is the core in a Canada-wide nuclear research and development infrastructure. It underpins CANDU reactor technology used in nuclear power plants, and supports many life-enhancing applications in as medicine, crop science, and food safety.

The NRU is a strategic training infrastructure. It develops the human capital Canada needs to maintain its international credibility on nuclear energy, non-proliferation, safety and security policies. This expertise includes having the means to regulate nuclear activities and provide for the safety and security of our citizens.

Innovation involving the NRU is already occurring in a number of key areas, such as advanced reactor fuels – a key selling point for CANDU reactors in countries such as the UK and China; and improved safety margins – which is a national security imperative for Canada both at home and abroad.

Innovation is greatly stimulated where there are crucibles or clusters of research and development, even if small, in a specific geographical area. In the nuclear field there are key R&D clusters around Chalk River Laboratories, the Sylvia Fedoruk Centre for Nuclear Innovation in Saskatoon, and southern Ontario.

Together these, plus research facilities at more than a dozen universities, and major scientific facilities such as British Columbia’s TRIUMF and Saskatchewan’s Canadian Light Source (CLS), make up Canada’s “nuclear eco-system”. In southern Ontario, the cluster includes engineering, manufacturing and construction companies that build and maintain the infrastructure for nuclear power generation as well as nuclear R&D.

But the NRU also has a role, practically as well as symbolically, for the success of Canada’s foreign policy, national security, and global markets action plan.

Canada owns the CANDU reactor technology used by seven countries. We have recognized expertise in all areas of the nuclear fuel cycle, from the mining and milling of uranium to the fabrication of advanced fuels to decommissioning and waste management. We bring high safety and security norms to the world. We have a proliferation-resistant reactor design based on natural uranium, not enriched fuel.

The NRU supports operating power reactors in Canada, particularly in life extension. It provides the special conditions that allow testing, experimentation and problem-solving, essential in dealing with aging reactor components. High radioactive environments are necessary to replicate reactor conditions. The NRU provides these, but not just for Canadian-based CANDU reactors.


Applying Nuclear Expertise to Solve the Auto Industry’s Challenges

This article was originally printed in the Winter/Spring 2015 edition of Lead, Reach and Connect, which is published twice per year for the Automotive Parts Manufacturers’ Association (APMA). It has been reprinted with permission from the APMA and Matrix Group Publishing Inc. and cannot be reproduced without prior written consent. To view the full edition of the magazine, please go to https://apma.ca/news/publish/finallowresapmawinterspring15websitepdf#content-head.

By Clemente Angiolillo and Daniel Banks

neutron beamlines
The neutron beamlines at the National Research Universal (NRU) reactor protrude out from the shielding wall around the reactor to allow materials to be analyzed non-destructively in the beams.

Situated two hours northwest of the nation’s capital on the scenic shores of the Ottawa River, Canadian Nuclear Laboratories (CNL), Canada’s national nuclear science and technology organization, has been a key player in the global nuclear sector from its inception over 60 years ago. Through the work done at Chalk River Laboratories, CNL gave the world a uniquely Canadian reactor design known as CANDU, and put forth pioneering innovations in the area of nuclear medicine and environmental remediation technologies, just to name a few areas of expertise.

However, as several auto parts suppliers will attest, the solutions offered by nuclear technologies have application in other industries as well. Today, as the auto industry grapples with many technical challenges to meet stringent fuel efficiency targets— achieved partly by obtaining favourable strength-to-weight ratios for motor vehicles— as well as enhancing quality assurance of parts and components, researchers at CNL are bringing their unique facilities and expertise to the auto industry’s doorsteps, and with remarkable results.

in-situ examination
A visiting researcher prepares an advanced in-situ examination of an alloy’s properties under various conditions of applied load on a neutron beamline.

“On the heels of CNL’s participation at the Automotive Parts Manufacturers’ Association (APMA) Annual Conference & Exhibition held in Windsor, ON in early June, we were pleased to announce that we had secured a new customer named AGS Automotive Systems Inc. to perform metallographic and surface analysis of various chrome plated parts,” says Elliott Gillespie, CNL director of marketing and international business.

The recently appointed marketing director says the technical challenge of this commercial contract is to perform indepth studies on the components to locate potential particulate or contaminants residing between very thin material plating layers, thus ensuring optimization of longterm corrosion resistance once the parts are placed in extreme weather conditions. AGS Automotive is a Tier 1 automotive parts supplier (and APMA member) specializing in bumper impact assemblies with capabilities in metal stamping, chrome-plating, Class A painting and welding. The company operates 10 facilities in North America and has approximately one-third of the chromeplated bumper business—producing mainly front and rear impact system assemblies and modules, as well as some general stampings, running boards and exterior painted trim parts such as grills—as sister company Tiercon Corp. Customers include GM, Toyota, Chrysler, Volkswagen and other major original equipment makers.

Years of automotive research 

new alloy sample
A visiting researcher makes small adjustments to the positioning of a new alloy sample on a neutron beamline to map its properties in three dimensions.

Lest one get the impression that CNL’s work in the automotive parts sector is a recent business activity, think again. Years of research on technologies to make lightweight car engines reliably have been afoot at Chalk River and may soon pay off with big dividends to parts suppliers. In addition, the value of CNL’s contributions to these technologies are being recognized by peer organizations and partners such as the Canadian Academy of Engineering (CAE), who recently bestowed a CNL researcher with a prestigious honour.

Dr. Dimitry Sediako, a Senior Research Officer, was inducted as a Fellow of the CAE in June 2014 in recognition of his contributions to improving manufacturing technologies in engine block casting and heat treatment, among other achievements. According to CNL customer Nemak Canada, these technologies, when implemented, will speed production times and reduce energy usage, thereby saving millions in manufacturing costs.

Some of these achievements and applications strike automotive manufacturers as novel and have potential customers wondering how exactly nuclear technologies can deliver value to the auto parts sector. Part of the formula for success is having diverse supporting facilities and the right expertise, but the other important piece is direct access to industry partners. And then there is the power of neutrons.

The power of neutrons

CNL hosts the only major neutron beam laboratory in Canada at its multipurpose National Research Universal reactor. Neutron beams, like no other tool, can be used to non-destructively probe deep inside engine blocks and determine the amount of stress in the material at any given point, which is a key factor in the reliability of the engine. Having honed this capability for decades, CNL’s researchers are world leaders in using neutron beams to determine properties of metallic materials, and have examined parts for jet engines, car engines, ship hulls, pipelines, bridges, and rail tracks, in addition to parts for nuclear reactors.

Dr. Dimitry Sediako
Researcher Dr. Dimitry Sediako sets up an engine block for non-destructive examination of residual stress on a neutron beamline at the National Research Universal (NRU) reactor at Canadian Nuclear Laboratories (CNL).

Although not yet standardized in the automotive industry, leading companies are now beginning to make use of this hightech tool. Dr. Sediako has built partnerships with researchers from Nemak Canada, major automotive manufacturers such as General Motors (GM) and Ford Motor Company, four universities (Ryerson University, University of British Columbia, University of Waterloo, McGill University), and Canmet Materials Laboratory, each of which contributed their own tools and expertise in metallurgy, mechanical testing and computer modelling.

In one line of research, Nemak’s objective was to find the best way to build robust V-6 aluminum engine blocks. These engines have extremely low tolerance for distortion in the shape of the cylinder holes in the block. Stress relief methods are used after casting the block to increase stability, and yet each manufacturing step comes with its own costs and impacts on the materials properties. To improve over current manufacturing practices, the team needed to understand more clearly the factors contributing to stability.

Nemak and its research partners from Ryerson University accessed Chalk River’s neutron beams for several studies with Dr. Sediako’s assistance to acquire and interpret the neutron diffraction data. These studies included elucidating the stress distribution and microstructure in new aluminum alloys and in engine blocks, before and after stress relief methods such as heat treatment. Additionally, they included pioneering observations of microstructural evolution during solidification of the alloys.

The results were vital contributions to the success of the research, helping Nemak to determine that simplifying the heat treatment process is feasible without compromising reliability. Nemak is now moving forward to validate the new process by performing final tests before the engine can be used in vehicles sold to customers, such as putting a prototype engine block in a test vehicle.

Neutrons help GM

During a recent webinar organized in conjunction with APMA, CNL worked with Nemak and GM to showcase the application of nuclear technology to develop better engine components, and elaborate on the range of nuclear capabilities available to automotive companies through CNL.

GM uses neutron beams to accelerate the development of engine heads and blocks. These projects span three primary research areas:

• Evaluating effectiveness of heat treatment and quenching methods.
• Directly observing phase precipitation during solidification.
• Creep testing to make better predictions of reliability over the long-term.

In the first area of evaluating effectiveness of heat treatment and quenching methods, neutron experiments clearly falsified a hypothesis for GM that air quenching of cylinder heads would be a benefit over water quenching because of an overall reduction in residual stresses. The results showed significant stresses remained with air quenching deep inside the cylinder heads, at a depth of about one centimetre.

On the second research area of directly observing phase precipitation during solidification, GM uses modelling software to try to predict the properties of the components or alloys after they solidify, but sometimes the models fail to predict the actual results. Neutrons can uniquely identify phases that precipitate during solidification. In other words, they allow GM to “watch” the solidification process experimentally to better understand what is causing the discrepancies.

The third research area is concerned with “creep testing,” which in essence means determining how the shape of the part may change over time and eventually fail or cause problems. The neutron beam experiments allow GM to look at how the arrangement of the atoms is changing in the material to better understand how these changes take place.

Neutrons help Ford

CNL has an ongoing research project with Ford to examine new ways of joining dissimilar materials together to be used in light-weight vehicles. For example, self-piercing riveting (SPR) is a leading alternative to traditional welding methods, and has been widely used by Audi, Mercedes, BMW, and Jaguar, as well as Ford on their aluminum cars and sports utility vehicles. SPR joints have excellent mechanical properties and high fatigue resistance. But the 3D residual stress field in a mixed metal SPR joint had not been experimentally studied before, making prediction of fatigue life of such SPR joints difficult. Ford turned to CNL’s neutron beam capability because other ways of determining stresses were too difficult, considering the complex geometry and number of different materials involved. It plans to use the results from the neutron analysis to validate its existing residual stress prediction method, and document these findings to inform broader manufacturing processes.

“We know there are tremendous opportunities in the automotive and related advanced manufacturing sectors,” concludes Gillespie. “These industries are capital intensive and commercially focused with resources dedicated to R&D [research and development] advancement. We are confident that in the near future CNL will be regarded as a valued supply chain partner and an active participant in their respective product development and quality assurance programs.”

International discussions are also driving work in this area. The recently announced United States-Canada Clean Energy Dialogue, initiated by Prime Minister Stephen Harper and President Barack Obama, recognizes lighter-weight, sustainable materials as a key research area in the development of next-generation vehicles.

In addition to neutron beams, CNL is offering potential customers a wide range of expertise and facilities that it has been using to solve unique problems for clients outside the nuclear industry, including surface science tools and burst testing services, to name a couple examples.

About CNL

Canadian Nuclear Laboratories is a world leader in nuclear science and technology offering unique capabilities and solutions across a wide range of industries. Actively involved with industry-driven research and development in nuclear, automotive, aerospace, defence, security and life sciences, we provide solutions to keep these sectors competitive internationally.

With ongoing investments in new facilities and a focused mandate, Canadian Nuclear Laboratories is well positioned for the future. A new performance standard reinforced with a strong safety culture underscores every activity.

For more information on the complete range of services at Canadian Nuclear Laboratories, please visit www.cnl.ca or contact communications@cnl.ca.


Innovations we Need – Now, and for Generations

By John Stewart
Director, Policy and Research
Canadian Nuclear Association

In case you missed this in the early January darkness: A Canadian team based at Vancouver-area TRIUMF has demonstrated a practical answer to the impending shortage of medical isotopes.

Technetium-99m (TC-99m), a commonly used isotope for medical imaging and diagnosis, has until now mainly been derived from molybdenum-99 from the NRU research reactor in Ontario. But the NRU is scheduled to end molybdenum production in 2016.

Industry experts were warning that this would leave global supplies of TC-99m very tight and vulnerable to shortages. But Canada’s nuclear science and technology know-how, with support from the federal government, has been working on answers. The team uses a common brand of medical cyclotron – developed and manufactured in Canada – to make TC-99m without a reactor.

Yanick Lee (right) and Ran Klein (centre) show off the Ottawa Hospital’s cyclotron.
The cyclotron at the Ottawa Hospital produces isotopes used for PET scans, which allow cardiac and cancer patients to receive precisely targeted treatments.

Nuclear technology doesn’t exist in a vacuum. It’s an integral part of our health care system, helping Canadian doctors to help their patients faster, better, and less intrusively. Not to mention an integral part of our materials science, which supports our whole manufacturing and engineering capability. Not to mention an integral part of our low-carbon, low-cost electric power supply.

Nuclear technology solves real-world problems that affect our quality of life: How long we live. How well our cars run. How safely our planes land. How affordable energy is.

As we noted in our last post, timely solutions like the isotope breakthrough may only be the tip of the iceberg compared to what nuclear innovation could bring humanity in coming decades. The world’s demand for low-carbon energy and clean air is probably the biggest single challenge we face as a species.  And it is increasingly clear that nuclear is the only minimal-carbon energy that can be there on the scale we need, when we need it.

Many reactor designs can be part of that solution, which will be global in scale. Here are some examples of CNA member organizations working in science and technology partnerships right now to make it happen:

  • Burnaby, BC-based General Fusion, which has a prototype fusion reactor, has a cooperative research and development agreement (CRADA) with the U.S. Department of Energy’s Los Alamos National Laboratory, and is putting them in place with the Lawrence Berkeley National and Princeton Plasma Physics labs.
Terrestrial Energy’s IMSR80.
  • Mississauga, ON-based Terrestrial Energy, which is developing integral molten salt reactors, recently announced an initial collaboration with USDOE’s Oak Ridge National Laboratory, the home of the original working MSR design.
  • CNA members GE Hitachi Nuclear Energy (GHNE) and Westinghouse Electric, plus Areva Federal Services, have joined with USDOE’s Argonne National Laboratory in a partnership on next-generation reactors.

National laboratories don’t form these partnerships just to make headlines. They’re looking to solve big problems. Canada and CNA members are going to be part of those answers.


Advancing Health Care: An Inside View

By John Stewart
Director, Policy and Research
Canadian Nuclear Association

CNA is reaching out this fall to users of nuclear technology across Canada’s health care sector. It’s part of the Nuclear Leadership Forum’s work toward a Nuclear Innovation Agenda – making sure Canada retains its world leadership in nuclear in decades to come.

The Ottawa Hospital’s Chair of Nuclear Medicine, Dr. Lionel Zuckier, invited CNA to visit this large hospital’s radiochemical laboratory on October 29.

Dr. Lionel Zuckier (right) illustrates the value of PET imaging to CNA’s Dr. John Barrett.
Dr. Lionel Zuckier (right) illustrates the value of PET imaging to CNA’s Dr. John Barrett.

Dr. Zuckier and his colleagues explained how advances in molecular imaging are constantly making treatments more personalized and accurate. This has greatly reduced each patient’s radiation exposure while making treatments faster, less intrusive, and more effective.

Yanick Lee (right) and Ran Klein (centre) show off the Ottawa Hospital’s cyclotron.
Yanick Lee (right) and Ran Klein (centre) show off the Ottawa Hospital’s cyclotron.

The Ottawa Hospital hosts impressive molecular medicine facilities: a cyclotron, hot cells, chemistry modules, a dose preparation “clean room,” and many imaging and treatment machines.

Like others in the health community, Ottawa Hospital leaders express concern about the supply-demand picture for medical isotopes around 2016. Many say that immediately following the end of the National Research Universal (NRU) reactor’s molybdenum production, alternative supplies will not be sufficient to cover patient needs.

Yanick Lee demonstrates a small hot cell, where freshly produced isotopes are received from the cyclotron.
Yanick Lee demonstrates a small hot cell, where freshly produced isotopes are received from the cyclotron.

Canadian Association of Medical Radiation Technologists (CAMRT) President Francois Couillard blogged about this issue in September.

Yanick opens up a chemistry module, where isotopes are processed before going to the dose preparation room.
Yanick opens up a chemistry module, where isotopes are processed before going to the dose preparation room.

According to the hospital’s Ran Klein, Cardiac Imaging Core Lab Manager at the National Cardiac PET Centre, “More than 100,000 Canadian patients each year get technetium scans that are crucial to their diagnostic and prognostic accuracy – especially for cardiac patients (40% of all nuclear imaging is cardiac imaging). What are we going to do in 2016? We are not ramping up to deal with that.”

Dr. Klein continued that even in the longer term, there are serious supply issues. “I have nothing against India, South Africa, or Pakistan (some of the alternative supplying countries) but you are losing control of the supply chain, and you are losing control of the regulatory structure around it.”