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United Kingdom
1-10 Employees
2023
Our mission is to use our expertise and experience to contribute to building the next generation of the nuclear industry, which we believe will experience a high demand for nuclear skills in the coming years. Welcome to Nuclear Training Services, the leading training provider for the UK nuclear industry. Our company was founded by two well-respected consultancies, Nuclear Consulting and Global Nuclear Security Partners. With extensive experience and knowledge in the civil and defence nuclear sectors, we are uniquely positioned to offer customised and high-quality training solutions to individuals and organisations in the nuclear industry. At Nuclear Training Services, we are dedicated to providing innovative, flexible, and practical training programmes that meet the evolving needs of our clients. We believe that training is a critical component of success in the nuclear industry, and we are committed to providing the highest quality training solutions available. The nuclear industry is a complex and potentially hazardous field that requires highly skilled professionals. Nuclear Training Services is one of the leading providers of classroom-based training programmes for the nuclear industry in the UK.
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Advanced Reactor Technologies and Innovations
... Advanced Reactor Technologies and Innovations – Nuclear Training ...
Tewkesbury, United Kingdom
1-10 Employees
2022
UK Atomics is a subsidiary of Copenhagen Atomics and is working to deploy thorium reactors. UK Atomics collaborates with leading UK universities to validate molten salt reactors technologies.
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UK atomics - UK atomics
... UK Atomics can become an industry leader within advanced modular reactors ...
Los Angeles, United States
1-10 Employees
2010
We are headquartered in California USA, with offices in France, Japan, UK and India. CENTROID LAB is an independent engineering services and solutions company established in 2015, who solve wide-ranging industry specific problems that involve dynamic simulations, computational fluid dynamics and analysis, 3D modeling and visualization. We have close alliances and partnerships with leading research and industry patrons, such as the Idaho National Laboratory (INL), National Renewable Energy Laboratory (NREL), and Electric Power Research Institute (EPRI). Our team of highly qualified consultants and engineers also stand ready to provide engineering services, consultancy and technical support for your project specific needs involving: • 3D Modeling, Simulation and Visualization, • Fluid Simulation and Analysis, • Custom Software Tool Development. We have worked on projects with regulatory agenies including Nuclear Regulatory Commission. We have several advanced state-of-the-art technologies which help design before build.
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Featured
Centroid Lab – Simulate before you spend.
... Simulation of Security Related Scenarios in Advanced Reactors ...
Berkeley, United States
11-50 Employees
2016
We are doing something that has never been done before. Our focus on public and stakeholder engagement reflects “best practice” and lessons learned from past experience in the field of nuclear waste disposal. Our lead investor is NAC International, a leading nuclear fuel cycle consulting and technology solutions. Headquartered in Berkeley, CA, Deep Isolation is a global company with offices in Washington DC, the United Kingdom, and Japan. Our partnerships with Bechtel and NAC International enable our capability for global solution delivery. PHOENIX AZ, March 11, 2024 — Deep Isolation, a leading innovator in nuclear waste storage and disposal solutions, will present its three latest publications and offer insights into site screening criteria at Waste Management Symposia 2024. Directional borehole disposal can provide robust and deep isolation for many types of radioactive waste, expanded location options for repositories as well as modular implementation adaptable to specific waste management programs and inventories. Mission-driven expertise to dispose of nuclear waste in the safest possible manner.
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Advanced nuclear reactors: Profiling research projects aimed at limiting volume of waste
... Advanced nuclear reactors: Profiling research projects aimed at limiting volume of waste - NS ...
Gurugram, India
251-500 Employees
1984
Together, we are committed to minimizing water wastage by Recycling every drop of water. With over 30 years of experience, Membrane Group has been supplying both Systems as well as Innovative solutions to Industries, Municipalities and Institutions all around the world. Membrane Group is equipped with 4 State-of-the-art Manufacturing Units located in India. The group has invested in leading manufacturing and testing equipment. Water industry is a highly service oriented industry and we at Membrane Group take customer satisfaction very seriously. We operate through 8 Offices located across India in all major cities so as to ensure our clients get timely service. Membrane Group is India’s leading manufacturer and distributor for Water & Waste Water Treatment Plants and Components.
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Featured
Advanced Oxidation Process Reactor
... Advanced Oxidation Process Reactor - water treatment company, water treatment ...
Old Toronto, Canada
501-1000 Employees
2000
We develop innovative solutions for the global electricity and medical industries, helping to empower a sustainable future. At Kinectrics, we put you in the driver’s seat of your own career, where you get the opportunity to work alongside industry leaders and mentors, to help you develop and broaden your capabilities for professional growth, in a dynamic, entrepreneurial work culture. We are dedicated to promoting diversity in our workforce, from our technical experts in the field all the way up to our leadership team. We are continuously expanding our team and we aren’t slowing down. We are committed to giving back to our community. We are the center of excellence the electricity industry relies on to provide services that mitigate risks, maintain safe operation & extend asset life. Our mission is to ensure that everyone who comes to one of our +20 locations or that is supporting an on-site project, goes home safely at the end of each day. This mission is accomplished through our independent laboratory and testing facilities, a diverse fleet of field inspection equipment, and an award-winning team of engineers and technical experts.
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SMRs, Advanced Reactors & Associated Technologies
... Small Modular Reactor (SMR) and Advanced Reactor (AR) Technology Selection Consulting ...
Nottingham, United Kingdom
11-50 Employees
1979
We provide solutions all around the world and across the UK from our offices based in Nottingham. We strive to be the world’s leading provider of quality dynamic process simulators. We have supplied our simulation solutions to many leading exploration companies and training institutions all around the world. We take our Clients project confidentiality very seriously and can always be trusted. A flexible and adaptable approach ensures we can offer a solution to any of your process operation needs. Assigned project managers to all projects means timely delivery. The chemical engineering programmes at Aston University are now equipped with state-of-the-art simulation platforms.”. The packages seem quite comprehensive and will provide an immersive experience with many of the major equipment and processes in chemical engineering.
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SIM 4400 Refrigeration System - TSC Simulation
... SIM 4502 Advanced Reactor ...
Roswell, United States
11-50 Employees
1994
Special Products: UxC Training Seminar Nuclear Power Outlook UxC Requirements Model Uranium Suppliers Annual UxC's Policy Watch. UxC's next Nuclear Fuel Training Seminar is scheduled for June 24-27, 2024 in Atlanta, Georgia. UxC announces new Nuclear Fuel Market Webinars for clients. UxC released a video during the WNFM virtual event in June 2021 discussing recent achievements and activities. Since 2020, UxC has been publishing annual editions of its Conversion & Enrichment Supplier Assessments (CESA) report. UxC has prepared a new special report to provide an overview of the zirconium alloy market for the nuclear industry entitled Nuclear Grade Zirconium Alloy Market Outlook. UxC, the industry leader in global nuclear market analysis, is pleased to announce a new report titled Small, Advanced and Micro-Reactor Assessments (SAMRA). In March 2013, UxC issued a new special report on the SMR Market Outlook (SMO).
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Featured
Small, Advanced and Micro-Reactor Assessments
... UxC: Small, Advanced and Micro-Reactor ...
Bellevue, United States
51-100 Employees
2008
Our team combines unparalleled technical and engineering expertise, experience in delivering nuclear projects, and building organizations to tackle large-scale global challenges. TerraPower was founded by Bill Gates and a group of like-minded visionaries that decided the private sector needed to take action in developing advanced nuclear energy to meet growing electricity needs, mitigate climate change and lift billions out of poverty. At TerraPower, we are innovating in nuclear to improve the lives of people everywhere and to build the clean energy of tomorrow – today. TerraPower’s work has benefitted from collaborations with companies that bring specialized expertise and spur growth in new industries in the process. TerraPower has agreements in place with many U.S. national laboratories, allowing partnerships between these federal research institutions, private-sector companies and universities.
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Featured
Advanced Reactor Modeling Interface - TerraPower
... Open-source software can help improve options for advanced reactor designs and lay the foundation for a strong regulatory basis for new reactors. ...
New York, United States
11-50 Employees
2021
NANO Nuclear’s products in technical development are “ZEUS”, a solid core battery reactor, and “ODIN”, a low-pressure coolant reactor, each representing advanced developments in portable, on-demand capable, advanced nuclear microreactors. The Company envisions readily replaceable mobile reactors which it can provide to customers, along with operative personnel, to power projects, residential and commercial enterprises, and major development projects.
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Featured
NANO Nuclear Energy Inc.
... . - micro-Small Modular Reactor (µSMR) and Advanced Nuclear Reactor (ANR) ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for Advanced Reactor
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 37 |
| Amount of suitable service providers | 28 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1979 |
| Youngest suiting company | 2023 |
An Advanced Reactor refers to a category of nuclear reactors designed with superior safety features, efficiency, and environmental benefits compared to their traditional counterparts. These next-generation reactors, encompassing a variety of technologies such as molten salt reactors, high-temperature gas-cooled reactors, and fast neutron reactors, aim to minimize nuclear waste and enhance the economic viability of nuclear power. By employing passive safety systems, advanced reactors significantly reduce the likelihood of accidents, relying on natural physical phenomena to cool down the reactor without human intervention or mechanical assistance. Furthermore, they are engineered to be more modular, allowing for factory construction and easier on-site assembly, which can lead to reduced construction times and costs. The role of advanced reactors within the energy sector is pivotal; they promise to bridge the gap towards a more sustainable and reliable energy mix, supporting the global transition away from fossil fuels. Their development is seen as crucial in meeting increasing energy demands while addressing climate change concerns, offering a cleaner, scalable source of base-load power. As countries strive to achieve carbon neutrality, the deployment of advanced reactors could play a significant role in diversifying energy sources and ensuring energy security, marking a significant stride towards innovative, cleaner energy solutions.
1. Enhanced Safety Features
Modern advanced reactors are designed with numerous safety improvements that significantly minimize the risk of accidents. These systems often include passive safety mechanisms that can automatically cool the reactor without human intervention or external power sources, making them more resilient to potential failures.
2. Reduced Waste Production
One of the most significant advantages of advanced reactors is their ability to reduce the volume and toxicity of nuclear waste. Some designs are capable of reusing spent fuel, thus diminishing the overall environmental impact and addressing one of the primary concerns associated with nuclear energy.
3. Greater Efficiency
Advanced reactors are engineered to operate more efficiently than their predecessors, achieving higher temperatures and better fuel utilization. This increased efficiency not only boosts power output but also extends the life of nuclear fuel, resulting in lower operating costs and further environmental benefits.
4. Flexibility in Location and Size
Unlike traditional nuclear power plants, advanced reactors offer flexibility in terms of size and location. They can be built in smaller modules to suit specific energy needs and can be located closer to urban centers due to their enhanced safety features. This flexibility facilitates the integration of nuclear power into various energy grids, contributing to a more diversified and secure energy supply.
While evaluating the different suppliers make sure to check the following criteria:
1. Technical Expertise and Innovation
Ensure the supplier has a strong track record in developing advanced reactors, with a focus on innovation and the use of cutting-edge technologies.
2. Regulatory Compliance
Confirm that the supplier adheres to all relevant safety and environmental regulations, both domestically and internationally.
3. Cost-Effectiveness
Evaluate the supplier's ability to provide cost-effective solutions without compromising on quality or performance.
4. Material Quality
Verify the quality of materials used in the reactors, which should meet industry standards and withstand the operational demands of an advanced reactor.
5. Customization Capabilities
Assess whether the supplier can tailor their reactor designs to meet your specific needs and requirements.
6. After-Sales Support
Consider the level of after-sales support offered, including maintenance, training, and access to replacement parts.
7. Proven Track Record
Look for suppliers with a proven track record of successful deployments and satisfied customers in the field of advanced reactors.
Advanced reactors hold transformative potential for the energy sector, offering cleaner, more efficient power generation solutions. In the utility industry, businesses are increasingly turning to these reactors for their ability to produce high-output, low-emission energy. This shift not only supports the global move towards sustainable energy but also promises significant operational cost reductions over time. In the world of manufacturing, advanced reactors are being utilized to generate process heat. This application is particularly relevant for industries requiring high temperatures, such as chemical production and metal refining. By replacing fossil fuel-based systems, companies can achieve more consistent temperatures, reduce greenhouse gas emissions, and lower energy costs, thereby enhancing overall manufacturing efficiency and sustainability. The pharmaceutical industry also benefits from the precise control and reliability of advanced reactors. Here, they are instrumental in the production of critical medications, where maintaining specific conditions is crucial for yield and purity. The ability to closely regulate reaction environments means higher quality pharmaceuticals and more efficient production processes, addressing both economic and regulatory pressures faced by companies in this sector. Finally, in the research and development sphere, advanced reactors are pivotal for experimental studies and innovation. They offer a controlled environment for testing new materials, processes, and technologies. This capability accelerates the development of breakthrough solutions across industries, from new energy systems to advanced materials, underscoring the reactor's role as a cornerstone of modern scientific progress.
Advanced reactors, which encompass a broad spectrum of nuclear reactor technologies designed to enhance safety, efficiency, and sustainability compared to traditional reactors, are generally classified at varying Technology Readiness Levels (TRLs) depending on the specific design and development stage. Most advanced reactors are situated between TRL 3 (experimental proof of concept) and TRL 6 (technology demonstrated in relevant environment). This range is attributed to the innovative nature of these reactors, including the use of novel coolants like molten salt or helium, advanced fuel types, and enhanced passive safety systems. The primary technical reasons behind their current TRL positioning involve the extensive research and development required to validate the operational safety and efficiency of these new technologies. Additionally, the rigorous regulatory approval process, which necessitates comprehensive testing and proof of concept in environments that closely mimic operational conditions, significantly influences their TRL status. This meticulous approach ensures that before advanced reactors can progress to higher TRLs, they must demonstrate not only technological innovation and superiority over existing solutions but also meet stringent safety and environmental standards.
In the Short-Term, advancements in advanced reactors are anticipated to focus on enhancing safety features and operational efficiencies. This includes the integration of passive safety systems that require no active controls or human intervention to maintain safety standards. Additionally, there's a push towards smaller, modular designs that promise quicker construction times and reduced initial capital costs. Such developments are poised to address immediate concerns around nuclear energy's safety and economic viability, setting a solid foundation for broader adoption. The Mid-Term phase is expected to witness significant strides in fuel technology, with the introduction of accident-tolerant fuels that can withstand higher temperatures and radiation without corroding. This period will also see the rise of high-temperature gas-cooled reactors that offer enhanced efficiency and the ability to produce high-grade heat for industrial processes. These advancements aim at expanding the utility of advanced reactors beyond electricity generation, promoting their use in various industrial applications. Looking into the Long-Term, the focus shifts to sustainability and minimizing nuclear waste. Breeder reactors, which can generate more fuel than they consume, and fusion reactors, offering a virtually limitless and clean energy source, are at the forefront of research. The realization of these technologies could revolutionize energy production, providing a sustainable and abundant source of power while significantly reducing nuclear waste. This phase represents the culmination of efforts towards making nuclear energy a cornerstone of global energy systems, emphasizing sustainability and minimal environmental impact.
