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Featured
Today on Nuclear Engineering International
... Today on Nuclear Engineering ...
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Featured
Nuclear Engineering International
... Subscribe to Nuclear Engineering International magazine, Journal and books on Nuclear energy sector at buythatmag.com, UK’s leading marketplace for subscription of power magazines. Order online and get free delivery Special offers for libraries, schools and ...
Raleigh, United States
1-10 Employees
2002
NC State Nuclear Engineering continues its traditional role in educational leadership and innovation. North Carolina State University’s pioneering experiment in nuclear education became the center of attention of the United States and the world. Authorization was gained from the North Carolina General Assembly to construct the Burlington Engineering Laboratories, which now house the department and the reactor. Co-op Experience: Engineering students can gain hands-on job experience while pursuing their degrees, and get paid for it, through the Cooperative Education Program. Donations help the NE department evolve and keep pace with the latest technology, while giving our students the skills, global awareness and sense of responsibility they need to make a difference in the world. Over the years, our program has sought to meet the needs of the time and to anticipate future developments. In 1950, Clifford Beck, then of Oak Ridge, Tennessee, obtained support from NC State’s Dean of Engineering, Harold Lampe, for the idea of building the nation’s 1st university nuclear reactor and establishing the 1st university nuclear engineering educational curriculum. Menius, Jr., Raymond Murray, Arthur Waltner, and Newton Underwood.
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Featured
Nuclear Engineering Department Advisory Council
... The Nuclear Engineering Advisory Council (NEDAC) provides observations, advice, feedback and support to the Department Head and faculty of NC State’s Department of Nuclear Engineering. … ...
Bristol, United Kingdom
1-10 Employees
2018
CERAP UK’s aim is to deliver support to nuclear operators by providing engineering services, calibration, and irradiation services for newbuild, operating facilities and decommissioning. Thanks to CERAP UK being one of the key suppliers to many clients who are working together to facilitate this target, it will be achieved. The service activities of CERAP, ADVANCE Engineering, ATRON Metrology and SEFC are carried out by the legal entities CERAP UK in the United Kingdom, CERAP Switzerland in Switzerland and NÜSAM in the United Arab Emirates. CERAP UK provides customers with elite radiation protection and consultancy services using our 35+ years in the nuclear industry to develop innovative radiological protection techniques to supply customers with advanced approaches to radiation protection and risk mitigation. CERAP UK ensures that there is an open line of communication between us and the customers. Depending on their activities, CERAP and its subsidiaries are ISO accredited: 9001 / 17025 / 18001. At CERAP UK we offer several different services to support our customers for risk prevention and radiation protection management. We provide a magnitude of consultancy services to fulfill customer’s risk mitigation need and management requirements.
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Featured
Radiation Protection &Nuclear Engineering Consultancy
... Radiation Protection &Nuclear Engineering ...
Egremont, United Kingdom
11-50 Employees
2014
Designing and implementing solutions that increase productivity and reduce costs.
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Featured
Nuclear Engineering O&M Services
... COMS, a Nuclear Engineering Consulting Firm Providing Operational, Maintenance and Engineering Services ...
Guyancourt, France
501-1000 Employees
1984
Rtone is an ABMI affiliate specializing in IoT and intelligent product design.
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Featured
Infr’atomAll generations nuclear engineering
... We provide support in all areas of engineering: mechanical, general installation, electrical, civil engineering, roads, nuclear safety and project management. ...
Wick, United Kingdom
1-10 Employees
We are an organisation, with a wide range of experience and expertise. Built upon the extensive knowledge and unique skills of our core personnel, Caithness Engineering Services offers a wide range of specialist services and bespoke engineering packages tailored to meet the exacting requirements of projects at any scale. We aim to provide the reassurance of an experienced hand, while bringing a fresh, new, dynamic and adaptable approach to our business. With that in mind, we strive to be as flexible as possible in delivering our solutions to best fulfil the desired outcomes of our clients. As the sector moves from its traditional operational approach into decommissioning and new technology development, we can draw from our team’s extensive experience and knowledge gained over many years in both civil and MOD branches to support fully operational nuclear establishments through the decommissioning of complex process plants or development of new innovative nuclear initiatives. As the keystone of the Scottish energy sector evolves with new and innovative technologies so do we. Bringing experience in ensuring the compliance of new and operational assets through to decommissioning of redundant assets, this is an area in which we have extensive knowledge consolidated into a specialist web-based data management platform enabling full client integration and asset data management. Delivering bespoke consultancy services specifically tailored to our client’s requirements.
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Featured
Caithness Engineering Services – Nuclear, Oil & Gas and Renewables
... Caithness Engineering Services – Nuclear, Oil & Gas and ...
Los Alamos, United States
501-1000 Employees
1998
We are recognized as an independent qualified expert whose advice and products are accepted as authoritative by our clients and their stakeholders. We are committed to solving the issues with which we are tasked in a manner that fully reflects each clients’ distinctive needs, restraints, and timeframes. We are fully committed to seeking the right answer for each and every client. We are committed to providing the right level of service. We are also proud to support the U.S. We are devoted to building the best and most innovative scientific and engineering firm in the nation, placing our clients first, and driving growth in a manner that respects and benefits the communities in which we work and live. We are passionate about our people because we know our people are what drives our success. Founded in 1997, TechSource is comprised of over 500 senior level scientists, engineers, and industry leaders from the national laboratories, federal technology programs and the nuclear industry.
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Featured
Nuclear Science & Engineering
... Nuclear Science & Engineering ...
Katastralgemeinde Seibersdorf, Austria
51-100 Employees
2003
Die Hauptaufgaben der Nuclear Engineering Seibersdorf GmbH (NES), welche im Auftrag der Republik Österreich durchgeführt werden, liegen in der Sammlung, Aufarbeitung, Konditionierung und Lagerung radioaktiven Abfalls und der Dekontaminierung und Dekommissionierung (Rückbau) von nuklearen Anlagen, insbesondere aus 45 Jahren Forschung und Entwicklung am Standort Seibersdorf.
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Featured
NES - Nuclear Engineering Seibersdorf
... NES - Nuclear Engineering ...
Argenta, Italy
1001-5000 Employees
1853
Our civilization is built on energy: its generation, conservation and use has driven the evolution of human kind. The two Italian companies are committed to the research and development of Small Modular Reactors and Advanced Modular Reactors.
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Featured
Nuclear design & engineering
... Nuclear design & engineering ...
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 Nuclear Engineering
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 60 |
| Amount of suitable service providers | 80 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1853 |
| Youngest suiting company | 2018 |
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Nuclear engineering is a branch of engineering focused on the development, design, and management of systems and components that utilize nuclear reactions to generate energy. This discipline covers a broad spectrum of applications, from the design of nuclear power plants, which provide a significant portion of the world's electricity, to the development of medical diagnostic equipment such as MRI machines, leveraging nuclear technology for non-invasive body scans. Nuclear engineers are also pivotal in the advancement of nuclear medicine, creating treatments that target cancer cells with precision, minimizing damage to surrounding healthy tissues. Additionally, they play a crucial role in ensuring the safety and efficiency of nuclear reactors, including the handling and disposal of radioactive materials, safeguarding both the environment and public health. The field's impact extends into research, where nuclear engineers explore fusion energy, a potential source of limitless, clean power. Their work not only contributes to solving some of today's most pressing energy challenges but also paves the way for innovations in medical treatment and safety protocols, underscoring the critical role nuclear engineering plays in advancing technology for societal benefit.
1. High Energy Density
Nuclear energy has a significantly higher energy density compared to fossil fuels and renewable energy sources. This means that nuclear reactors can produce a vast amount of electricity from a relatively small amount of fuel, making it an efficient and space-saving option for generating power.
2. Low Greenhouse Gas Emissions
One of the pivotal advantages of nuclear engineering is its minimal greenhouse gas emissions during electricity generation. Unlike coal or gas plants, nuclear power stations do not produce carbon dioxide or methane, which are major contributors to climate change. This makes nuclear energy a cleaner alternative for meeting the world's increasing energy demands.
3. Reliability
Nuclear power plants operate at a high capacity factor, meaning they can produce maximum power more than 90% of the time during the year. This reliability is unparalleled when compared to renewable sources like solar and wind, which are subject to weather conditions and daily cycles.
4. Longevity and Sustainability
Nuclear reactors have a long lifespan, often operating for 40-60 years with the possibility of extensions. Additionally, with advancements in nuclear technology, such as breeder reactors and fusion reactors, nuclear energy has the potential to become even more sustainable, using fuel more efficiently and reducing waste.
While evaluating the different suppliers make sure to check the following criteria:
1. Regulatory Compliance
Ensure the supplier meets all local and international nuclear safety and regulatory standards to mitigate legal and operational risks.
2. Technical Expertise
Evaluate the supplier's experience and capability in nuclear engineering, including their track record in delivering complex projects successfully.
3. Quality Control Systems
Check for robust quality assurance and control mechanisms to ensure the highest standards of materials and workmanship.
4. Innovation and Technology
Assess the supplier's commitment to innovation, and whether they incorporate the latest technologies and methodologies in their solutions.
5. Financial Stability
Confirm the supplier's financial health to ensure they can sustain long-term projects and potential unforeseen challenges.
6. Environmental and Safety Record
Review the supplier's environmental policies and safety record to ensure they align with your sustainability goals and safety requirements.
7. Customer Support and Maintenance
Ensure the supplier offers comprehensive after-sales support, including maintenance, training, and technical assistance, to facilitate smooth operations.
In the energy sector, nuclear engineering plays a pivotal role in the design, operation, and maintenance of nuclear power plants. Businesses in this industry leverage nuclear engineering expertise to enhance the efficiency and safety of power generation, contributing to a more sustainable energy future. This use case underscores the importance of nuclear engineers in addressing global energy demands while minimizing environmental impact. Another significant application of nuclear engineering is in the field of medical isotopes production. Companies specializing in healthcare and pharmaceuticals rely on nuclear technologies to create isotopes used in diagnostic imaging and cancer treatment. This collaboration between nuclear engineers and medical professionals facilitates advancements in medical imaging, offering more precise and effective diagnostic and therapeutic options. Furthermore, nuclear engineering expertise is vital in the development of national defense systems. Defense contractors and governments work closely with nuclear engineers to innovate and maintain nuclear weaponry and propulsion systems for submarines and aircraft carriers. This intersection of engineering and defense underscores the critical role of nuclear technology in national security, ensuring a strategic advantage in military capabilities. Lastly, in the realm of industrial applications, businesses utilize nuclear technology for materials testing and quality assurance. Nuclear engineering techniques such as neutron activation analysis and radiography enable companies to inspect materials and components with unparalleled precision, optimizing manufacturing processes and ensuring product reliability. This use case highlights the versatility of nuclear engineering in improving industrial efficiency and product quality across various sectors.
Nuclear engineering encompasses a broad spectrum of technologies, each at different stages of development, making it challenging to assign a single Technology Readiness Level (TRL). However, conventional nuclear fission technology, which powers the majority of the world's nuclear reactors, operates at a high TRL, typically TRL 9, indicating it is fully mature and has been proven in operational environments. This high level of readiness is attributed to decades of research, development, and operational experience that have culminated in reliable, efficient, and safe nuclear power plants. Advanced nuclear technologies, such as small modular reactors (SMRs) and fusion energy, find themselves at varying TRLs, generally between TRL 3 (experimental proof of concept) and TRL 6 (technology demonstrated in relevant environment), due to ongoing research and development efforts aimed at overcoming technical challenges like achieving sustained net energy gain from fusion and ensuring the scalability, transportability, and economic feasibility of SMRs. The disparity in TRLs within nuclear engineering reflects the field's dynamic nature, where established technologies coexist with emerging innovations, each contributing to the evolution of nuclear energy as a pivotal component of the global energy mix.
In the short-term, the nuclear engineering sector is poised to witness significant advancements in safety and efficiency. The development and integration of advanced passive safety systems, which require no operator actions to maintain the reactor's safety in case of an emergency, are at the forefront. Additionally, the introduction of small modular reactors (SMRs) promises to make nuclear power more accessible and cost-effective, facilitating deployment in a wider range of locations and applications. Looking into the mid-term, the focus shifts towards sustainability with the proliferation of Generation IV reactors. These reactors are designed not only to minimize nuclear waste but also to utilize fuel more efficiently. Another notable advancement is the progress in thorium reactor technology, offering a potentially safer and more abundant alternative to conventional uranium fuel. This phase also expects to see significant strides in fusion technology, edging closer to achieving a commercially viable fusion reactor, which could revolutionize energy production by providing a nearly limitless, clean energy source. Long-term advancements in nuclear engineering aim to fully realize the potential of fusion energy and establish it as a mainstay in global energy supply. Breakthroughs in material science are anticipated to solve current challenges in reactor design, making them more resilient and longer-lasting. Furthermore, the integration of artificial intelligence and robotics in nuclear power plants is expected to enhance operational efficiency, maintenance, and safety. Environmental restoration and the development of advanced waste management techniques will also be crucial, ensuring nuclear energy's role in a sustainable future.
Some interesting questions that has been asked about the results you have just received for Nuclear Engineering
What are related technologies to Nuclear Engineering?
Based on our calculations related technologies to Nuclear Engineering are Water/Ocean Cleaning Technologies, Waste Management, Renewable Energy, Sustainable Fashion, Smart Grid
Which industries are mostly working on Nuclear Engineering?
The most represented industries which are working in Nuclear Engineering are Science and Engineering, Energy, Manufacturing, Professional Services, Others
How does ensun find these Nuclear Engineering Companies?
ensun uses an advanced search and ranking system capable of sifting through millions of companies and hundreds of millions of products and services to identify suitable matches. This is achieved by leveraging cutting-edge technologies, including Artificial Intelligence.
