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1-10 Employees
2019
We are bringing many species, and potentially ourselves, to the brink of extinction. We are causing Climate Change because we are burning fossil fuels to meet our energy needs. Fusion Reactors is developing a fusion reactor to deliver electricity to the grid from fusion energy. Fairness: We will endeavour to provide affordable and clean electricity, with the same passion, in all parts of the world, regardless of wealth and circumstance. We believe in sustainable practice in every possible dimension, from the behaviour of our people to our final product. We believe that the United Nations' Sustainable Development Goals are underpinned by access to clean energy. We believe that as a technology company we have a responsibility to deliver affordable and clean energy to all. Fusion energy is the energy released when light nuclei fuse (join) together.
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Featured
FUSION REACTORS
... Fusion Reactors is a company at the forefront of affordable, reliable, safe and sustainable energy generation. ...
Dorchester, United Kingdom
1-10 Employees
2021
We are applying our breakthrough technology to create meaningful solutions to prescient problems today. We are developing innovative system designs to address global challenges such as those in health access and zero carbon energy. A second facility built around a DT MSF reactor is planned for development starting in late Q3, 2023. First demonstrations of medical isotope production are planned for late 2023 or early 2024. Through partnerships with organisations such as the UKAEA, Astral has already provided valuable data using its reactor technologies that will accelerate the development of fusion power. Due to the ultra-compact and modular nature of our systems, we are able to design fusion research facilities built around a plurality or cluster of Astral reactors to maximize neutron flux within a focused test volume. Nuclear medicine is a vital tool used around the world to diagnose and treat life-threatening diseases every day. We aim to provide medical isotope production at the point of care for both diagnostic and therapeutic applications.
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Featured
Fusion Technologies
... Astral's first multi-state fusion reactor ...
Rochester, United Kingdom
11-50 Employees
2020
We are now bringing that peace of mind from the few to us all. The Clean Air Technologies group have a track record in delivering critical air safety components for prestigious global engineering projects. We have always been experts in delivering clean air and diffusion systems and with the addition of data we are reinforcing our core promise of peace of mind. The key difference between our offering and competitor's products is the real time data we provide on the cleanliness of the air entering the space. The product is focused purely on filtering air, leaving heating, cooling and fresh air make up to the base build HVAC system. Shown here is the system configured for a 3.2m exposed and 2.4m raft ceiling. CAOT Designers will specify hardware and provide designs for your site team to install. CAOT Technicians will return to commission the system and set up monitoring.
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Featured
Clean Air Office Technologies | Powered by Clean Air Technologies
... ITER Fusion Reactor ...
France
51-100 Employees
2016
MOMENTUM supervises the construction contracts of ITER Organization and is a pivotal structure in the construction project of the future´s fusion reactor.
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About | Iter Project | Momentum | Saint-Paul-les-Durance
... Momentum is supervising the building of the fusion reactor into the ITER project, a multinational scientific collaboration without historical parallel. The aim: make fusion happen! Fusion is solar energy, our future. ...
1-10 Employees
2014
Make Sure GBL Technology Is On Your Path. GBL’s High Power Density technology will obliterate cycle time and force change in root behavior. Chemical energy storage, including batteries and ultra caps, imposes strong first order limitations on mobility, efficiency and utility pillars. No investment in chemical energy storage will be enough. GBL is developing capacitor technology that will scale to an energy density equivalent of a lithium ion battery while also charging in a fraction of a second.
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General 6 — GREAT BALL OF LIGHT INC
... Fusion Reactors ...
Broomfield, United States
1-10 Employees
Join us on our mission, (video too) to this sustainable journey to a brighter, limitless future. Realistically, we are a black swan technology because of our overwhelming cost and scale advantage along with the “out of the box” fusion approach that the mainstream fusion community is unaware of. Tanzella is an energy research professional for the development of alternative energy production, optimization, and utilization. At Electric Fusion Systems, Inc., we are pioneering a futuristic and efficient pathway to harnessing fusion energy. Our revolutionary technology is so versatile that it offers limitless possibilities, from portable applications like automotive transportation to large-scale industrial and electric utility solutions. Electric Fusion Systems revolutionary patent pending technology is the marriage of a new form of lithium proton fusion fuel and a switching power supply designed to provide safe electrical power on demand for the grid. Electric Fusion Systems simulations and theoretical modeling efforts are centered around hiring outside experts in fusion and fusion simulations. Electric Fusion Systems prototype is a roller-bag sized power plant that uses a lithium-ammonia fuel loaded with 200 megawatt hours of power.
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Pioneering Fusion Energy Solutions - Electric Fusion Systems
... Clean compact electric fusion reactors for small to large scale distributed power production. Delivers constant energy, anywhere, anytime. No CO2 or GHGs, No ☢️ ...
Tübingen, Germany
11-50 Employees
1879
Das erforschen wir bei Himmelwerk gemeinsam mit unseren Partner:innen an Universitäten und Instituten. Die Umrichter von Himmelwerk sind jeweils auf bestimmte Frequenzbereiche ausgelegt, sodass sich Temperaturen punktgenau einstellen lassen. Die Himmelwerk Induktionsanlagen lassen sich leicht und automatisiert in bestehende Produktionsabläufe integrieren. Wie die Induktionstechnologie funktioniert, was in unserem Himmelwerk-Labor passiert und wie Induktion morgen aussieht, zeigen wir hier.
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Plasma generation with ITER - Himmelwerk
... Plasma generation in nuclear fusion reactor | ITER project | High-frequency systems from Himmelwerk | For a sustainable & ecological ...
Bernau am Chiemsee, Germany
1-10 Employees
2014
We are a not-for-profit organisation which was established in 1983. NAFEMS strives to continually evolve the ways in which it operates and to constantly improve the extent to which it fulfils the primary aims that are listed above. NAFEMS, the only dedicated International Association for the Engineering Modelling, Analysis & Simulation Community, is a not-for-profit organisation established in 1983 which focuses on the practical application of numerical engineering simulation techniques such as the Finite Element Method for Structural Analysis (FEA), Computational Fluid Dynamics (CFD) & Multibody Simulation. NAFEMS has a long history of providing training courses, webinars, seminars, conferences & online publications that are individually tailored to offer engineers of all skill levels the right tools to improve their professional status. We focus on the practical application of numerical engineering simulation techniques such the Finite Element Method for Structural Analysis, Computational Fluid Dynamics, and Multibody Simulation. In addition to end users from all industry sectors, our stakeholders include technology providers, researchers and academics. Stay up to date with our technology updates, events, special offers, news, publications and training. If you work with engineering simulation, you should be a part of NAFEMS.
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Featured
UK Atomic Energy Authority and Cambridge simulate fusion reactor with Intel and Dell
... UK Atomic Energy Authority and Cambridge simulate fusion reactor with Intel and Dell The United Kingdom Atomic Energy Authority (UKAEA) and Cambridge University are building ...
Minneapolis, United States
501-1000 Employees
1966
That's why we're committed to providing our employees with the resources and support they need to succeed. As the industry leaders in permeation and package testing for nearly six decades, we’re proud to close out another year and celebrate our team’s success in 2023 as we plan for 2024. Our new Dansensor CheckMate 4 solution for package testing quality control delivers maximum uptime and efficiency while maintaining accuracy and simplifying the process with intuitive software. Our people and products deliver the best value with the broadest range of solutions. For over 55 years, we have provided the most accurate and repeatable results that world leading companies count on to protect and enhance their product quality and integrity.
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Nuclear research: Using SIMS to study plasma facing materials (PFMs) in fusion reactors.
... Nuclear research: Using SIMS to study plasma facing materials (PFMs) in fusion reactors. ...
Paris, France
11-50 Employees
2015
We are a venture capital firm that helps founders tackle hard problems with capital, resources and collaboration. Atmio closed €1.3m round led by HCVC for its Operating System to find, fix, and report methane leaks. Chiral announces $3.8m round to build the future infrastructure for the industrial manufacturing of nano-transistors. Founded by former Apple and Palantir engineers, the company develops dual-use autonomous surveillance towers powered by AI. The new round will allow Automata to further expand Linq, its leading lab automation platform.
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Home page - Hardware Club
... RENAISSANCE FUSION RAISES €15M SEED FOR ITS FUSION REACTOR ...
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Some interesting numbers and facts about the results you have just received for Fusion Reactor
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 35 |
| Amount of suitable service providers | 23 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1879 |
| Youngest suiting company | 2021 |
A fusion reactor is an advanced technological apparatus designed to harness the power of nuclear fusion, the same process that powers the sun and stars. At its core, a fusion reactor aims to combine light atomic nuclei, typically isotopes of hydrogen like deuterium and tritium, under extreme conditions of temperature and pressure. This fusion results in the formation of a heavier nucleus, a process that releases a vast amount of energy. The pursuit of controlled nuclear fusion in reactors is driven by the promise of providing a clean, nearly limitless source of energy, free from the long-lived radioactive waste associated with current nuclear fission reactors. The role of fusion reactors in the field of energy production is transformative, offering the potential to significantly reduce reliance on fossil fuels and mitigate the impact of energy production on the environment. Despite the technical and engineering challenges that remain, such as achieving a net energy gain, the successful development and implementation of fusion reactors could revolutionize the global energy landscape. This technology is seen not only as a pinnacle of scientific achievement but also as a cornerstone for future sustainable energy solutions, underscoring its profound impact and significance within the fields of energy science and environmental preservation.
1. Energy Efficiency
Fusion reactors are renowned for their exceptional energy efficiency. Unlike traditional nuclear fission reactors, fusion reactors have the potential to produce significantly more energy from the same amount of fuel. This efficiency leap is due to the fusion process itself, where the merging of light atomic nuclei releases vast amounts of energy, dwarfing what can be obtained from splitting atoms in fission.
2. Environmental Impact
The environmental footprint of fusion reactors is minimal compared to conventional energy sources. Fusion reactors produce no greenhouse gas emissions during operation, making them a clean energy source. Furthermore, the byproducts of fusion reactions are not long-lived radioactive wastes, a stark contrast to the hazardous waste challenge posed by fission reactors. This benefit positions fusion reactors as a sustainable solution to the world's growing energy needs.
3. Safety
Safety is a paramount advantage of fusion reactors over other nuclear technologies. The fusion process requires precise conditions to sustain, meaning any deviation can naturally quell the reaction, eliminating the risk of a meltdown. This inherent safety feature, combined with the absence of high-level radioactive waste, makes fusion reactors a safer alternative for generating nuclear energy.
While evaluating the different suppliers make sure to check the following criteria:
1. Technology and Innovation
Ensure the supplier is at the forefront of fusion reactor technology, utilizing the latest advancements for efficient energy production.
2. Safety Standards
The supplier should adhere to the highest safety standards, given the complex nature of fusion reactors.
3. Experience and Reliability
Look for suppliers with proven experience in building and operating fusion reactors, as well as a track record of reliability.
4. Environmental Compliance
Ensure the supplier's practices and technologies align with environmental regulations and sustainability goals.
5. Cost-Effectiveness
While initial costs may be high, the supplier should offer competitive pricing and a clear ROI for their fusion reactor technology.
6. After-Sales Support
Comprehensive after-sales support, including maintenance and training, is crucial for the successful operation of a fusion reactor.
7. Customization Capabilities
The ability to customize the reactor to meet specific needs can be a significant advantage, ensuring it fits seamlessly into existing infrastructure.
Fusion reactors, a cutting-edge technology, herald a new era in energy solutions across multiple industries. In the manufacturing sector, fusion reactors can offer an unprecedented, continuous power supply, facilitating round-the-clock operations without the carbon footprint associated with traditional energy sources. This capability is particularly beneficial for industries with high energy demands, such as steel production, where consistent, high-temperature processes are essential. Within the pharmaceutical industry, fusion reactors introduce the potential for more sustainable and cost-effective production methods. The intense, controlled energy output can be harnessed for high-precision chemical reactions, crucial in drug development and manufacturing. This advancement could significantly reduce operational costs and environmental impact, making healthcare solutions more accessible. The tech industry stands to gain immensely from integrating fusion reactors into data center operations. These facilities require vast amounts of energy to maintain server operations and cooling systems. Fusion energy could provide a reliable, efficient power source, greatly reducing the carbon footprint of digital infrastructures and supporting the rapid growth of cloud computing and IoT technologies. In summary, fusion reactors present transformative opportunities across manufacturing, pharmaceuticals, and technology sectors. Their adoption could revolutionize energy consumption patterns, enhance sustainability, and drive innovation, marking a significant leap towards a cleaner, more efficient industrial landscape.
Fusion reactors, a promising source of virtually limitless, clean energy, are currently positioned at varying Technology Readiness Levels (TRLs), primarily between TRL 3 and TRL 6. This range is attributed to the significant technical challenges that researchers face in achieving and sustaining the conditions necessary for nuclear fusion. At the lower end of the spectrum, TRL 3, concepts and theoretical models are being tested through experimental proof of concept, focusing on achieving the high temperatures and pressures required for fusion to occur. Progressing to TRL 4 and 5, components and subsystems undergo validation in a laboratory environment, addressing issues such as plasma confinement and materials capable of withstanding the extreme conditions inside a reactor. The upper limit, TRL 6, involves prototype demonstration in a relevant environment, indicating a move towards integrating these systems into a functional reactor design. However, the leap to higher TRLs is hindered by technological barriers, including the development of materials that can endure prolonged exposure to fusion conditions and the engineering of efficient systems for heat extraction and electricity generation. These challenges underscore the complexity of making fusion energy a practical and sustainable power source, reflecting why the technology remains within this intermediate stage of readiness.
In the Short-Term, advancements in fusion reactor technology will focus on enhancing plasma containment and stability. Researchers are developing new superconducting materials to improve the efficiency of magnetic confinement in tokamaks, aiming to achieve longer operation periods and higher plasma temperatures. This phase is critical for increasing the feasibility of sustained fusion reactions, with several pilot projects expected to demonstrate significant progress in net energy output. The Mid-Term phase will witness the integration of advanced materials and cooling systems, enabling reactors to operate under extreme conditions for extended periods. Innovations in laser ignition techniques and the development of tritium breeding technologies will address fuel sustainability and safety concerns. These advancements pave the way for the construction of commercial-scale fusion reactors, with the potential to produce clean, limitless energy. The focus will also shift towards optimizing the efficiency and reducing the cost of energy production to make fusion power commercially viable. Looking into the Long-Term, the fusion reactor technology will evolve towards achieving grid parity and widespread deployment. Breakthroughs in artificial intelligence and robotics will automate reactor maintenance and operations, significantly reducing operational costs. The adoption of fusion energy will be facilitated by the development of international regulatory frameworks and standards. Additionally, the exploration of advanced fusion concepts, such as aneutronic fusion, promises to minimize radioactive waste and further enhance the safety and environmental benefits of fusion power.
