Improving beam simulations as well as machine and target protection in the SINQ beam line at PSI-HIPA

IF 1 Q3 NUCLEAR SCIENCE & TECHNOLOGY Journal of Neutron Research Pub Date : 2020-10-20 DOI:10.3233/jnr-200162

D. Reggiani, B. Blau, R. Dölling, P. Duperrex, D. Kiselev, V. Talanov, J. Welte, M. Wohlmuther

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引用次数: 4

Abstract

With a nominal beam power of nearly 1.4 MW, the PSI High Intensity Proton Accelerator (HIPA) is currently at the forefront of the high intensity frontier of particle accelerators. Key issues of this facility are minimization of beam losses as well as safe operation of the SINQ spallation source. Particular attention is being recently paid towards an improved understanding of the properties of the SINQ beam line by both enhancing the beam transport simulations and developing new diagnostic elements which can also, in some cases, preserve the target integrity by preventing too large beam current density, inaccurate beam steering or improper beam delivery. Moreover, part of the SINQ beam diagnostic concept is being rethought in order to include important missing devices like BPMs. On the simulation side, newly developed composite calculations involving general purpose particle transport programs like MCNPX and BDSIM will deliver insights about beam losses and transmission through collimators. All recent and planned developments of the SINQ beam line will be discussed in this contribution.

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改进波束模拟以及PSI-HIPA SINQ波束线中的机器和目标保护

PSI高强度质子加速器(HIPA)的标称束流功率接近1.4 MW，目前处于高强度粒子加速器的前沿。该设施的关键问题是最小化光束损失以及SINQ散裂源的安全操作。最近，人们特别关注通过增强光束输运模拟和开发新的诊断元件来提高对SINQ光束线特性的理解，这些诊断元件在某些情况下还可以通过防止光束电流密度过大、光束转向不准确或光束输送不当来保持目标的完整性。此外，部分SINQ光束诊断概念正在重新考虑，以包括重要的缺失设备，如bpm。在模拟方面，新开发的复合计算涉及通用粒子输运程序，如MCNPX和BDSIM，将提供有关光束损失和准直器传输的见解。所有最近的和计划中的SINQ光束线的发展将在这篇文章中讨论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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