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#428367 Fusion for Energy signs multi-million ...
Fusion for Energy signs multi-million deal with Airbus Safran Launchers, Nuvia Limited and Cegelec CEM to develop robotics equipment for ITER
The contract for a value of nearly 100 million EUR is considered to be the single biggest robotics deal to date in the field of fusion energy. The state of the art equipment will form part of ITER, the world’s largest experimental fusion facility and the first in history to produce 500 MW. The prestigious project brings together seven parties (China, Europe, Japan, India, the Republic of Korea, the Russian Federation and the USA) which represent 50% of the world’s population and 80% of the global GDP.
The collaboration between Fusion for Energy (F4E), the EU organisation managing Europe’s contribution to ITER, with a consortium of companies consisting of Airbus Safran Launchers (France-Germany), Nuvia Limited (UK) and Cegelec CEM (France), companies of the VINCI Group, will run for a period of seven years. The UK Atomic Energy Authority (UK), Instituto Superior Tecnico (Portugal), AVT Europe NV (Belgium) and Millennium (France) will also be part of this deal which will deliver remotely operated systems for the transportation and confinement of components located in the ITER vacuum vessel.
The contract carries also a symbolic importance marking the signature all procurement packages managed by Europe in the field of remote handling. Carlo Damiani, F4E’s Project Manager for ITER Remote Handling Systems, explained that “F4E’s stake in ITER offers an unparalleled opportunity to companies and laboratories to develop expertise and an industrial culture in fusion reactors’ maintenance.”
Cut-away image of the ITER machine showing the casks at the three levels of the ITER machine. ITER IO © (Remote1 web). Photo Credit: f4e.europa.euIllustration of lorry next to an ITER cask. F4E © (Remote 2 web). Photo Credit: f4e.europa.euAerial view of the ITER construction site, October 2016. F4E © (ITER site aerial Oct). Photo Credit: f4e.europa.eu
Why ITER requires Remote Handling?
Remote handling refers to the high-tech systems that will help us maintain and repair the ITER machine. The space where the bulky equipment will operate is limited and the exposure of some of the components to radioactivity, prohibit any manual intervention inside the vacuum vessel.
What will be delivered through this contract?
The transfer of components from the ITER vacuum vessel to the Hot Cell building, where they will be deposited for maintenance, will need to be carried out with the help of massive double-door containers known as casks. According to current estimates, 15 of these casks will need to be manufactured and in their largest configuration they will measure 8.5 m x 3.7 m x 2.6 m approaching 100 tonnes when transporting the heaviest components. These enormous “boxes”, resembling to a conventional lorry container, will be remotely operated as they move between the different levels and buildings of the machine. Apart from the transportation and confinement of components, the ITER Cask and Plug Remote Handling System will also ensure the installation of the remote handling equipment entering into the vacuum vessel to pick up the components to be removed. The technologies underpinning this system will encompass a variety of high-tech skills and comply with nuclear safety requirements. A proven manufacturing experience in similar fields and the development of bespoke systems to perform mechanical transfers will be essential.
Background information
MEMO: Fusion for Energy signs multi-million deal with Airbus Safran Launchers, Nuvia Limited and Cegelec CEM to develop robotics equipment for ITER
Multimedia
To see how the ITER Remote Handling System will operate click on clip 1 and clip 2
To see the progress of the ITER construction site click here
To take a virtual tour on the ITER construction site click here
Image captions
Cut-away image of the ITER machine showing the casks at the three levels of the ITER machine. ITER IO © (Remote1 web)
Illustration of lorry next to an ITER cask. F4E © (Remote 2 web)
Aerial view of the ITER construction site, October 2016. F4E © (ITER site aerial Oct)
The consortium of companies
The consortium combines the space expertise of Airbus Safran Launchers, adapted to this extreme environment to ensure safe conditions for the ITER teams; with Nuvia comes a wealth of nuclear experience dating back to the beginnings of the UK Nuclear industry. Nuvia has delivered solutions to some of the world’s most complex nuclear challenges; and with Cegelec CEM as a specialist in mechanical projects for French nuclear sector, which contributes over 30 years in the nuclear arena, including turnkey projects for large scientific installations, as well as the realisation of complex mechanical systems.
Fusion for Energy
Fusion for Energy (F4E) is the European Union’s organisation for Europe’s contribution to ITER.
One of the main tasks of F4E is to work together with European industry, SMEs and research organisations to develop and provide a wide range of high technology components together with engineering, maintenance and support services for the ITER project.
F4E supports fusion R&D initiatives through the Broader Approach Agreement signed with Japan and prepares for the construction of demonstration fusion reactors (DEMO).
F4E was created by a decision of the Council of the European Union as an independent legal entity and was established in April 2007 for a period of 35 years.
Its offices are in Barcelona, Spain.
http://www.fusionforenergy.europa.eu
http://www.youtube.com/user/fusionforenergy
http://twitter.com/fusionforenergy
http://www.flickr.com/photos/fusionforenergy
ITER
ITER is a first-of-a-kind global collaboration. It will be the world’s largest experimental fusion facility and is designed to demonstrate the scientific and technological feasibility of fusion power. It is expected to produce a significant amount of fusion power (500 MW) for about seven minutes. Fusion is the process which powers the sun and the stars. When light atomic nuclei fuse together form heavier ones, a large amount of energy is released. Fusion research is aimed at developing a safe, limitless and environmentally responsible energy source.
Europe will contribute almost half of the costs of its construction, while the other six parties to this joint international venture (China, Japan, India, the Republic of Korea, the Russian Federation and the USA), will contribute equally to the rest.
The site of the ITER project is in Cadarache, in the South of France.
http://www.iter.org
For Fusion for Energy media enquiries contact:
Aris Apollonatos
E-mail: aris.apollonatos@f4e.europa.eu
Tel: + 34 93 3201833 + 34 649 179 42
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#428140 Singapore International Robotics Expo
Singapore International Robo Expo debuts as the robotics sector is poised for accelerated growth
In partnership with Experia Events, the Singapore Industrial Automation Association sets its sights on boosting the robotics solutions industry with this strategic global platform for innovation and technology
Singapore, 18 October 2016 – The first Singapore International Robo Expo (SIRE), organised by Experia Events and co-organised by the Singapore Industrial Automation Association (SIAA), will be held from 1 to 2 November 2016, at Sands Expo and Convention Centre, Marina Bay Sands.
Themed Forging the Future of Robotics Solutions, SIRE will comprise an exhibition, product demonstrations, networking sessions and conferences. SIRE aims to be the global platform for governments, the private sector and the academia to engage in dialogues, share industry best practices, network, forge partnerships, and explore funding opportunities for the adoption of robotics solutions.
“SIRE debuts at a time when robotics has been gaining traction in the world due to the need for automation and better productivity. The latest World Robotics Report by the International Federation of Robotics has also identified Singapore as a market with one of the highest robot density in manufacturing – giving us more opportunities for further development in this field, and well as its extension into the services sectors.
With the S$450 million pledged by the Singapore government to the National Robotics Programme to develop the industry over the next three years, SIRE is aligned with these goals to cultivate the adoption of robotics and support the growing industry. As an association, we are constantly looking for ways to bring together robotic adoption, collaboration among partners, and providing support with funding for our members. SIRE is precisely the strategic platform for this,” said Mr Oliver Tian, President, SIAA.
SIRE has attracted strong interest from institutes of higher learning (IHLs), research institutes, local and international enterprises, with innovation and technology applicable for a vast range of industries from manufacturing to healthcare.
ST Kinetics, the Title Sponsor for the inaugural edition of the event, is one of the key exhibitors, together with other leading industry players such as ABB, Murata, Panasonic, SICK Pte Ltd, and Tech Avenue amongst others. Emerging SMEs such as H3 Dynamics, Design Tech Technologies and SMP Robotics Singapore will also showcase their innovations at the exhibition. Participating research institute, A*STAR’s SIMTech, and other IHLs supporting the event include Ngee Ann Polytechnic, Republic Polytechnic and the Institute of Technical Education (ITE).
Visitors will also be able to view “live” demonstrations at the Demo Zone and come up close with the latest innovations and technologies. Some of the key highlights at the zone includes the world’s only fully autonomous outdoor security robot developed by SMP Robotics Singapore, as well as ABB’s Yumi, IRB 14000, a collaborative robot designed to work in close collaboration and proximity with humans safely. Dynamic Stabilization Systems, SIMTech and Design Tech will also be demonstrating the capabilities of their robotic innovations at the zone.
At the Singapore International Robo Convention, key speakers representing regulators, industry leaders and academia will come together, exchange insights and engage in discourse to address the various aspects of robotic and automation technology, industry trends and case studies of robotics solutions. There will also be a session discussing the details of the Singapore National Robotics Programme led by Mr Haryanto Tan, Head, Precision Engineering Cluster Group, EDB Singapore.
SIRE will also host the France-Singapore Innovation Days in collaboration with Business France, the national agency supporting the international development of the French economy. The organisation will lead a delegation of 20 key French companies to explore business and networking opportunities with Singapore firms, and conduct specialized workshops.
To further foster a deeper appreciation and to inspire the next generation of robotics and automation experts, the event will also host students from higher institutes of learning on Education Day on 2 November. Students will be able to immerse themselves in the exciting developments of the robotics industry and get a sampling of how robotics can be applied to real-world settings by visiting the exhibits and interacting with representatives from participating companies.
Mr Leck Chet Lam, Managing Director, Experia Events, says, “SIRE will be a game changer for the industry. We are expecting the industry’s best and new-to-market players to showcase their innovations, which could potentially add value to the operations across a wide spectrum of industry sectors, from manufacturing to retail and service, and healthcare. We also hope to inspire the robotics and automation experts of tomorrow with our Education Day programme.
Experia Events prides itself as a company that organises strategic events for the global stage, featuring thought leaders and working with the industries’ best. It is an honour for us to be partnering SIAA, a recognised body and key player in the robotics industry. We are privileged to be able to help elevate Singapore’s robotics industry through SIRE and are pulling out all stops to ensure that the event will be a resounding success.”
SIRE is supported by Strategic Partner, IE Singapore as well as agencies including EDB Singapore, GovTech Singapore, InfoComm Media Development Authority, A*STAR’s SIMTech, and Spring Singapore.
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For further enquiries, please contact:
Marilyn HoExperia Events Pte LtdDirector, CommunicationsTel: +65 6595 6130Email: marilynho@experiaevents.com
Genevieve YeoExperia Events Pte LtdAssistant Manager, CommunicationsTel: +65 6595 6131Email: genevieveyeo@experiaevents.com
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#428053 Omnidirectional Mobile Robot Has Just ...
Spherical Induction Motor Eliminates Robot’s Mechanical Drive System
PITTSBURGH— More than a decade ago, Ralph Hollis invented the ballbot, an elegantly simple robot whose tall, thin body glides atop a sphere slightly smaller than a bowling ball. The latest version, called SIMbot, has an equally elegant motor with just one moving part: the ball.
The only other active moving part of the robot is the body itself.
The spherical induction motor (SIM) invented by Hollis, a research professor in Carnegie Mellon University’s Robotics Institute, and Masaaki Kumagai, a professor of engineering at Tohoku Gakuin University in Tagajo, Japan, eliminates the mechanical drive systems that each used on previous ballbots. Because of this extreme mechanical simplicity, SIMbot requires less routine maintenance and is less likely to suffer mechanical failures.
The new motor can move the ball in any direction using only electronic controls. These movements keep SIMbot’s body balanced atop the ball.
Early comparisons between SIMbot and a mechanically driven ballbot suggest the new robot is capable of similar speed — about 1.9 meters per second, or the equivalent of a very fast walk — but is not yet as efficient, said Greg Seyfarth, a former member of Hollis’ lab who recently completed his master’s degree in robotics.
Induction motors are nothing new; they use magnetic fields to induce electric current in the motor’s rotor, rather than through an electrical connection. What is new here is that the rotor is spherical and, thanks to some fancy math and advanced software, can move in any combination of three axes, giving it omnidirectional capability. In contrast to other attempts to build a SIM, the design by Hollis and Kumagai enables the ball to turn all the way around, not just move back and forth a few degrees.
Though Hollis said it is too soon to compare the cost of the experimental motor with conventional motors, he said long-range trends favor the technologies at its heart.
“This motor relies on a lot of electronics and software,” he explained. “Electronics and software are getting cheaper. Mechanical systems are not getting cheaper, or at least not as fast as electronics and software are.”
SIMbot’s mechanical simplicity is a significant advance for ballbots, a type of robot that Hollis maintains is ideally suited for working with people in human environments. Because the robot’s body dynamically balances atop the motor’s ball, a ballbot can be as tall as a person, but remain thin enough to move through doorways and in between furniture. This type of robot is inherently compliant, so people can simply push it out of the way when necessary. Ballbots also can perform tasks such as helping a person out of a chair, helping to carry parcels and physically guiding a person.
Until now, moving the ball to maintain the robot’s balance has relied on mechanical means. Hollis’ ballbots, for instance, have used an “inverse mouse ball” method, in which four motors actuate rollers that press against the ball so that it can move in any direction across a floor, while a fifth motor controls the yaw motion of the robot itself.
“But the belts that drive the rollers wear out and need to be replaced,” said Michael Shomin, a Ph.D. student in robotics. “And when the belts are replaced, the system needs to be recalibrated.” He said the new motor’s solid-state system would eliminate that time-consuming process.
The rotor of the spherical induction motor is a precisely machined hollow iron ball with a copper shell. Current is induced in the ball with six laminated steel stators, each with three-phase wire windings. The stators are positioned just next to the ball and are oriented slightly off vertical.
The six stators generate travelling magnetic waves in the ball, causing the ball to move in the direction of the wave. The direction of the magnetic waves can be steered by altering the currents in the stators.
Hollis and Kumagai jointly designed the motor. Ankit Bhatia, a Ph.D. student in robotics, and Olaf Sassnick, a visiting scientist from Salzburg University of Applied Sciences, adapted it for use in ballbots.
Getting rid of the mechanical drive eliminates a lot of the friction of previous ballbot models, but virtually all friction could be eliminated by eventually installing an air bearing, Hollis said. The robot body would then be separated from the motor ball with a cushion of air, rather than passive rollers.
“Even without optimizing the motor’s performance, SIMbot has demonstrated impressive performance,” Hollis said. “We expect SIMbot technology will make ballbots more accessible and more practical for wide adoption.”
The National Science Foundation and, in Japan, Grants-in-Aid for Scientific Research (KAKENHI) supported this research. A report on the work was presented at the May IEEE International Conference on Robotics and Automation in Stockholm, Sweden.
Video by: Carnegie Mellon University
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About Carnegie Mellon University: Carnegie Mellon (www.cmu.edu) is a private, internationally ranked research university with programs in areas ranging from science, technology and business, to public policy, the humanities and the arts. More than 13,000 students in the university’s seven schools and colleges benefit from a small student-to-faculty ratio and an education characterized by its focus on creating and implementing solutions for real problems, interdisciplinary collaboration and innovation.
Communications Department
Carnegie Mellon University
5000 Forbes Ave.
Pittsburgh, PA 15213
412-268-2900
Fax: 412-268-6929
Contact: Byron Spice For immediate release:
412-268-9068 October 4, 2016
bspice@cs.cmu.edu
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