PIP-II Linac Cryogenic Distribution System Design Challenges

T. BanaszkiewiczWroclaw University of Science and Technology, Wroclaw, Poland, M. ChorowskiWroclaw University of Science and Technology, Wroclaw, Poland, P. DudaWroclaw University of Science and Technology, Wroclaw, Poland, M. StanclikWroclaw University of Science and Technology, Wroclaw, Poland, R. DhuleyFermi National Accelerator Laboratory, Batavia, USA, A. MartinezFermi National Accelerator Laboratory, Batavia, USA, W. SoyarsFermi National Accelerator Laboratory, Batavia, USA
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Abstract

The PIP-II linac Cryogenic Distribution System (CDS) is characterized by extremely small heat inflows and robust mechanical design. It consists of a Distribution Valve Box (DVB), Intermediate Transfer Line, Tunnel Transfer Line, comprising 25 Bayonet Cans, and ends with a Turnaround Can. Multiple helium streams, each characterized by distinct helium parameters, flow through each of these elements. The CDS geometry allows maintaining an acceptable pressure drop for each helium stream, considering the planned flows and helium parameters in different operation modes. This is particularly crucial for the return line of helium vapors, which return from cryomodules to the cold compressors and thus have very restrictive pressure drop requirements. On both sides of the DVB there are fixed supports for process pipes. One of the DVB design challenges was to route the process pipes in such a way that their shape provided sufficient compensation for thermal shrinkage. This ensures th at the forces resulting from thermal shrinkage acting on the cryogenic valves remain at a level acceptable to the manufacturer. The required thermal budget of the CDS was achieved by thermo-mechanical optimization of its components, like process pipes fixed supports in Bayonet Cans.
PIP-II 直列加速器低温配送系统设计挑战
PIP-II 直列加速器低温分配系统(CDS)的特点是热流入量极小,机械设计坚固耐用。它由一个分配阀箱 (DVB)、中间传输线、隧道传输线(包括 25 个卡口罐)和一个周转罐组成。多股氦气流流经上述每个元件,每股氦气流都具有不同的氦气参数。考虑到不同运行模式下的计划流量和氦气参数,CDS 的几何形状允许每股氦气流保持可接受的压降。这一点对于氦蒸汽的回流管线尤为重要,因为氦蒸汽会从低温模块返回到冷压缩机,因此对压降的要求非常严格。在 DVB 的两侧有用于工艺管道的固定支架。DVB 的设计难点之一是如何使工艺管道的形状为热收缩提供足够的补偿。这样可以确保热收缩作用在低温阀门上的力保持在制造商可以接受的水平。CDS 所需的热预算是通过对其组件(如卡口罐中的工艺管固定支架)进行热机械优化来实现的。
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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