NBI负离子源中操作参数对单束偏转的影响

A. Hurlbatt, F. Bonomo, G. Orozco, R. Nocentini, C. Wimmer, U. Fantz
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摘要

对于当前和未来的大型托卡马克,用于加热和电流驱动的中性束是由能量高达1 MeV,电流高达40 A的大型负离子束中和产生的。为了提高效率并防止光束线组件的高热负荷,使用永磁体以低能量将共提取的电子从光束中偏转。当负离子被加速时,这个场也会影响它们,导致束流以剩余偏移和偏转角度退出网格系统。这对光束的整体发散有不利影响,在未来的设备中可以进行补偿。在BATMAN Upgrade测试设备上,通过计算光束发射光谱(BES)的相对光束角度,并通过使用一维碳纤维复合材料(1D-CFC)瓦量热法来确定光束位置,对单个光束的残余偏转进行了测量。它描述了这些测量是如何进行的,并且它们仅限于相对测量,对于单个光束和单个视线。根据所使用的操作参数,光束偏转的量变化显著,可达0.6°(10 mrad)。正如预期的那样,观察到束流偏转角度受到加速度系统电压变化的影响。然而,波束偏转角也随着射频功率和其他源参数的变化而变化,初步估计,这些参数只会影响波束发散,而不会影响波束偏转。这些通过除所使用的电网电压以外的参数对光束偏转的改变可能会对计划使用抑制系统来抑制之字形偏转的系统产生影响。由于源参数的变化,抑制系统的有效性可能会降低,这可能导致光束损失和下游组件的高热负荷。
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Impact of operational parameters on single beamlet deflection in a negative ion source for NBI applications
For current and future large scale tokamaks, neutral beams for heating and current drive are generated from the neutralisation of large negative ion beams with energies up to 1 MeV and current of up to 40 A. To improve efficiency and prevent high heat loads on beamline components, permanent magnets are used to deflect co-extracted electrons out of the beam at a low energy. This field also affects the negative ions as they are accelerated, causing beamlets to exit the grid system with a residual offset and deflection angle. This adversely affects the overall divergence of the beam, and compensation is foreseen in future devices. Measurements of the residual deflection of a single beamlet have been carried out at the BATMAN Upgrade test facility by calculating relative beamlet angles from beam emission spectroscopy (BES) spectra, and through the use of one-dimensional carbon fibre composite (1D-CFC) tile calorimetry to find beamlet positions. It is described how these measurements can be made, and that they are limited to relative measurements only, for a single beamlet and for a single line of sight. The amount of beamlet deflection is shown to change significantly, by up to 0.6°(10 mrad), depending on the operational parameters used. As is to be expected the beamlet deflection angle is observed to be affected by changes to the voltages of the acceleration system. However, the beamlet deflection angle is also observed to change with RF power and other source parameters, which, to a first approximation, should only affect beamlet divergence, and not the deflection. These changes to beamlet deflection through parameters other than the grid voltages used may have consequences for systems planning to use suppression systems for the zig-zag deflection. The effectiveness of the suppression system may be reduced due to changes in the source parameters, which could lead to beam losses and high heat loads on downstream components.
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