Additive Manufacturing of Side-Coupled Cavity Linac Structures from Pure Copper: A First Concept

Q3 Physics and Astronomy

Instruments Pub Date : 2023-12-14 DOI:10.3390/instruments7040056

Michael Mayerhofer, Stefan Brenner, Ricardo Helm, S. Gruber, Elena Lopez, Lukas Stepien, Gerald Gold, Günther Dollinger

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Abstract

Compared to conventional manufacturing, additive manufacturing (AM) of radio frequency (RF) cavities has the potential to reduce manufacturing costs and complexity and to enable higher performance. This work evaluates whether normal conducting side-coupled linac structures (SCCL), used worldwide for a wide range of applications, can benefit from AM. A unit cell geometry (SC) optimized for 75 MeV protons was developed. Downskins with small downskin angles α were avoided to enable manufacturing by laser powder bed fusion without support structures. SCs with different α were printed and post-processed by Hirtisation (R) (an electrochemical process) to minimize surface roughness. The required accuracy for 3 GHz SCCL (medical linacs) is achieved only for α>45∘. After a material removal of 140 µm due to Hirtisation (R), a quality factor Q0 of 6650 was achieved. This corresponds to 75% of the Q0 simulated by CST®. A 3 GHz SCCL concept consisting of 31 SCs was designed. The effective shunt impedance ZT2 simulated by CST corresponds to 60.13MΩm and is comparable to the ZT2 of SCCL in use. The reduction in ZT2 expected after Hirtisation (R) can be justified in practice by up to 70% lower manufacturing costs. However, future studies will be conducted to further increase Q0.

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用纯铜快速制造侧耦合腔体直列加速器结构：第一个概念

与传统制造相比，射频（RF）腔体的增材制造（AM）具有降低制造成本和复杂性并实现更高性能的潜力。这项研究评估了在全球范围内广泛应用的正常导电侧耦合线性腔体结构（SCCL）是否能从 AM 中受益。针对 75 MeV 质子开发了优化的单元格几何（SC）。避免了具有小下表面角 α 的下表面，以便在没有支撑结构的情况下通过激光粉末床熔融制造。打印出不同 α 的 SC，并通过 Hirtisation (R)（一种电化学工艺）进行后处理，以尽量减少表面粗糙度。只有当 α>45∘ 时，才能达到 3 GHz SCCL（医用直列加速器）的精度要求。由于 Hirtisation (R)，材料去除 140 µm 后，质量因子 Q0 达到 6650。这相当于 CST® 模拟的 Q0 的 75%。设计了一个由 31 个 SC 组成的 3 GHz SCCL 概念。CST 模拟的有效分流阻抗 ZT2 为 60.13MΩm，与使用中的 SCCL 的 ZT2 相当。在实践中，Hirtisation (R) 后预计 ZT2 的减少可以通过降低高达 70% 的制造成本来证明。不过，未来的研究将进一步提高 Q0。

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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来源期刊

Instruments Physics and Astronomy-Instrumentation

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

11 weeks