Nuclear technology aspects of ITER vessel-mounted diagnostics

Vayakis, G.; Bertalot, L.; Encheva, A.; Walker, Chris; Brichard, B.; Cheon, MunSeong; Chitarin, G.; Hodgson, E.R.; Ingesson, C.; Ishikawa, Masatoshi; Kondoh, T.; Meister, H.; Moreau, Philippe; Peruzzo, S.; Pak, S.; Pérez-Pichel, Germán; Reichle, R.; Testa, D.; Toussaint, M.; Vermeeren, L.; Vershkov, V.A.

doi:10.1016/j.jnucmat.2011.01.081

Cited by 26 publications

(13 citation statements)

References 26 publications

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“…Second, with the knowledge gained from the fundamental research, to design sensors for minimum effect(s) in the application on ITER and, in parallel, to mitigate with redundancy and alternative methods, particularly for critical measurements. There has been considerable progress with understanding the pertinent effects of radiation on the materials used for magnetic sensors [20,21]. Magnetic sensors are generally composed of a metallic winding, a supporting insulating structure and an electromagnetic screen, the whole mounted on a supporting structure.…”

Section: B Magnetics and Instrument Wiring And Connectorsmentioning

confidence: 99%

“…Within the research programme, specific experiments are carried out on tokamaks under the auspices of the IEA-ITPA Joint Experiments. There is now an extensive body of literature on most aspects of the problem: for example, deposition of impurities erosion of the mirror surfaces, and mitigation methods, for example shutters [19,20]. The performance of mirrors in the neutron, gamma and X-ray environment is also an area of potential concern.…”

Section: Cmentioning

confidence: 99%

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ITER diagnostic challenges

Walsh

Andrew

Barnsley

et al. 2011

2011 IEEE/NPSS 24th Symposium on Fusion Engineering

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ITER will explore a plasma parameter envelope currently not available in tokamaks. This will require a set of diagnostics that can follow this envelope. To implement these diagnostics in a reliable and robust way requires development of current techniques in many areas to make them applicable to ITER: they need to be operable in the ITER environment and satisfy the physics and engineering requirements. In some cases, the exploitation of new techniques will be required. While much work has been carried out in this area, significant further work remains to bring the system to implementation.

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Section: B Magnetics and Instrument Wiring And Connectorsmentioning

confidence: 99%

Section: Cmentioning

confidence: 99%

ITER diagnostic challenges

Walsh

Andrew

Barnsley

et al. 2011

2011 IEEE/NPSS 24th Symposium on Fusion Engineering

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“…For this measurement, inductive sensors have been utilized as a common method [ 1 ]. However, these sensors are based on the measurement of the time derivate of a magnetic field, which can induce measurement drift due to the long steady state operation of the ITER since integrators are used to retrieve the plasma current [ 2 , 3 ]. A fiber optic current sensor (FOCS) measures the plasma current by means of the Faraday effect [ 4 , 5 ].…”

Section: Introductionmentioning

confidence: 99%

Assessment of the Structural Vibration Effect on Plasma Current Measurement Using a Fiber Optic Current Sensor in ITER

Kim

Dandu

Gusarov

et al. 2023

Sensors

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In this paper, we assess the effect of cryostat bridge vibrations on the plasma current measurement accuracy when using a fiber optic current sensor (FOCS) in ITER. The impact of vibrations on the light polarization state was first experimentally investigated using a miniaturized mock-up which represented a relevant part of the ITER FOCS structure. The set-up was then numerically simulated using the Jones matrix approach. Equivalent vibration matrices obtained from the experiment were used in the simulations to determine the effect of the vibrations on the FOCS accuracy. It is demonstrated that although the vibrations imply some changes in the polarization state, this effect can be strongly reduced when a proper low-birefringent spun optical fiber is used. The ITER requirement regarding the plasma current measurement accuracy can therefore be fulfilled.

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“…However, such a high sensitivity is unnecessary for our application and their use would involve the installation of a glass bulb containing alkali gas and light sources, not suitable to be installed inside the NBI vessel. Pick-up coils (also called Mirnov coils) with a time integration of the output signal are not suitable, because the radiation-induced electromotive force (some microvolts, caused by neutrons hitting the coils conductors) would produce an unacceptable measurement drift during the long experimental pulses [ 12 ], but first and foremost because stationary or slow-varying magnetic fields must be sensed. It is possible to overcome these difficulties using a fluxgate-type magnetometer (see Figure 2 ), since its sensing part is simple, intrinsically robust and does not require delicate semiconductor components.…”

Section: Introductionmentioning

confidence: 99%

Realization and Tests of Prototype Fluxgate Magnetic Sensors for the ITER Neutral Beam Injectors

Chitarin

Marconato

Mayer³

2023

Sensors

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In the ITER neutral beam injectors (NBI), the presence of an external variable magnetic field generated by the ITER tokamak itself, could deflect the ion beam during acceleration and cause a loss of beam focusing. For this reason, the ion source, the accelerator and the neutralizer will be shielded from external magnetic field by means of a passive magnetic shield and a system of active correction and compensation coils (ACCC). The ACCC will operate in a feedback control loop and thus require the measurement of magnetic field inside the NBI vessel. Magnetic sensors for this application must be capable of measuring DC and slow variable magnetic fields, and be vacuum-compatible, radiation-hard and robust, since they will be subjected to neutron flux produced by fusion reactions in the tokamak and inaccessible for maintenance. This paper describes the realization and tests of fluxgate magnetic sensors prototypes specifically designed for this purpose before the installation in MITICA and ITER.

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Nuclear technology aspects of ITER vessel-mounted diagnostics

Cited by 26 publications

References 26 publications

ITER diagnostic challenges

ITER diagnostic challenges

Assessment of the Structural Vibration Effect on Plasma Current Measurement Using a Fiber Optic Current Sensor in ITER

Realization and Tests of Prototype Fluxgate Magnetic Sensors for the ITER Neutral Beam Injectors

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