Your search keyword '"G. Agarici"' showing total 2 results

1. Iter like lower hybrid Passive Active Multi-Junction antenna manufacturing and tests

Author

A. Argouarch, M. Houry, D. Raulin, A. Saille, F. Faisse, Julien Hillairet, D. Volpe, Jc. Hatchressian, B. Zago, Jh. Belo, Karl Vulliez, M. Lipa, Lena Delpech, Gilles Lombard, D. Thouvenin, Gilles Berger-By, Marc Missirlian, J. Achard, M. Prou, A. Martinez, S. Madeleine, Jp. Joanard, F. Samaille, E. Corbel, Patrick Mollard, G. Agarici, C. Goletto, Bernard Bertrand, R. Magne, Z. Bej, T. Hoang, Jm. Verger, S. Poli, D. Guilhem, M. Chantant, M. Goniche, L. Marfisi, R. Lambert, C. Brun, C. Portafaix, E. Delmas, M. Maury, A. Armitano, P. Fejoz, A. Ekedahl, L. Doceul, M. Preynas, M. Lyonne, B. Soler, F. Bouquey, P. Joubert, and E. Rousset

Subjects

Coupling, Engineering, Tokamak, business.industry, Electrical engineering, Mechanical engineering, Converters, Tore Supra, law.invention, Design objective, law, Radio frequency, Antenna (radio), business, Power density

Abstract

A new concept of multijunction-type antenna has been developed, the Passive Active Multijunction, which improves the cooling of the waveguides and the damping of the neutron energy (for ITER) compared to Full Active Multijunction. Due to the complexity of the structures, prototypes of the mode converters and of the Passive-Active-Multijunction launcher were fabricated and tested, in order to validate the different manufacturing processes and the manufacturer's capability to face this challenging project. This paper describes the manufacturing process, the tests of the various prototypes and the construction of the final Passive-Active-Multijunction launcher, which entered into operation in October 2009. It has been commissioned and is fully operational on the Tore-Supra tokamak, since design objectives were reached in March 2010: 2.75 MW - 78 s, power density of 25MW/m2 in active waveguides, steady-state apparent surface temperatures < 350 °C; 10 cm long distance coupling.

Published

2011

2. Development of & integration of the IC H&CD system configuration in the ITER Tokamak complex and auxiliary buildings

Author

Rajeev Kumar, Rajesh Singh, B. Beaumont, D. Rathi, R.L. Moon, R. Sartori, Frédéric Durodié, Ujjwal Baruah, Jean-Michel Bernard, Namita Singh, G. Agarici, F. Kazarian, Ph. Lamalle, Richa Trivedi, M. Mills, Aparajita Mukherjee, Richard Goulding, L. Meunier, D.W. Swain, T. Gassmann, M. Shannon, B. Beckett, B. Bruyere, T. Alonzo, B. Arambhadiya, David A Rasmussen, M.P.S. Nightingale, D. Lockley, and E. Manon

Subjects

Engineering, Tokamak, Electric power transmission, business.industry, law, Cyclotron, Iter tokamak, Electrical engineering, Radio frequency, Plasma, System configuration, business, law.invention

Abstract

The Ion Cyclotron Heating and Current Drive (IC H & CD) system for ITER will provide Radio frequency (RF) heating and current drive to the ITER plasma. This system is designed to provide 20 MW into the plasma using frequencies in the range of 40 MHz to 55 MHz, which could be upgraded to 40 MW in future. This paper presents the recent development of the IC H&CD system configuration in the ITER Tokamak complex & auxiliary buildings with developed interfaces.

Published

2011