The neutral beam injector, an additional heating system for the ITER project, will be optimized in the NBI test facility under construction in Padova. The facility includes the SPIDER ion source representing the full size prototype for the production of negative ions, based on RF plasma with expected beam 100kV energy and 50A current. The source will be equipped with a system of 84 electrostatic probes for the investigation of the homogeneity of plasma parameters, such as plasma density, electron temperature, and plasma potential and possibly of the Electron Energy Distribution Function. Measurements will be performed in the extraction region of the ion source, where most of the extracted negative ions are produced. The system consists of 2D arrays of different sensors, covering the Plasma Grid (PG) surface and the Bias Plate (BP), which are the components facing the plasma in the extraction region. The probe system design accounts for the constraints related to the need of embedding the sensors within the PG and BP. It has been carried out with the aim of providing sensors easy maintenance and enough robustness to withstand the experimental operation of SPIDER. A special machining of the insulating part has been adopted in order to avoid sensor short circuit due to deposition of metals such as caesium or copper on the BP and PG surfaces during the operation of the SPIDER source. Given the RF plasma, a particular attention is paid to the RF conditioning of the current collected by the probes in order to minimize the spurious effects on the voltage-current characteristic of the sensors. In order to test in advance the electrostatic sensor and to check possible weak points in the design, prototype sensors were manufactured and successfully tested in plasma conditions as similar as possible to the plasma which will be produced in the SPIDER source. The system is presently being installed on the SPIDER grids. In this contribution the overall system description and status will be provided, including the in-vessel and ex-vessel parts, following the path from the sensors up to the conditioning electronics and the acquisition system.
Design and Status of the Electrostatic Probe System for the SPIDER Experiment
Spolaore M;Brombin M;Serianni G;Pasqualotto R;Pomaro N;Taliercio C
2017
Abstract
The neutral beam injector, an additional heating system for the ITER project, will be optimized in the NBI test facility under construction in Padova. The facility includes the SPIDER ion source representing the full size prototype for the production of negative ions, based on RF plasma with expected beam 100kV energy and 50A current. The source will be equipped with a system of 84 electrostatic probes for the investigation of the homogeneity of plasma parameters, such as plasma density, electron temperature, and plasma potential and possibly of the Electron Energy Distribution Function. Measurements will be performed in the extraction region of the ion source, where most of the extracted negative ions are produced. The system consists of 2D arrays of different sensors, covering the Plasma Grid (PG) surface and the Bias Plate (BP), which are the components facing the plasma in the extraction region. The probe system design accounts for the constraints related to the need of embedding the sensors within the PG and BP. It has been carried out with the aim of providing sensors easy maintenance and enough robustness to withstand the experimental operation of SPIDER. A special machining of the insulating part has been adopted in order to avoid sensor short circuit due to deposition of metals such as caesium or copper on the BP and PG surfaces during the operation of the SPIDER source. Given the RF plasma, a particular attention is paid to the RF conditioning of the current collected by the probes in order to minimize the spurious effects on the voltage-current characteristic of the sensors. In order to test in advance the electrostatic sensor and to check possible weak points in the design, prototype sensors were manufactured and successfully tested in plasma conditions as similar as possible to the plasma which will be produced in the SPIDER source. The system is presently being installed on the SPIDER grids. In this contribution the overall system description and status will be provided, including the in-vessel and ex-vessel parts, following the path from the sensors up to the conditioning electronics and the acquisition system.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
