A Compact Magnet System for the Tsinghua Tabletop Kibble Balance

arXiv - PHYS - Instrumentation and Detectors Pub Date : 2024-09-05 DOI:arxiv-2409.03334

Yongchao Ma, Nanjia Li, Weibo Liu, Kang Ma, Wei Zhao, Songling Huang, Shisong Li

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Abstract

Although the so-called magnetic geometrical factor, $Bl$, of a Kibble balance does not appear in the Kibble equations, it offers the precision link between electrical and mechanical quantities and furthers a quasi-quantum traceability path for mass metrology. This feature makes the magnet system, supplying the $Bl$ in Kibble equations, play a core role in Kibble balances. Following the open-hardware idea, we report here on the design, manufacture, assembly, optimization, and finally performance of a compact magnet system for the Tsinghua tabletop Kibble balance. Notably, the magnet system showcased in this study facilitates a straightforward upper levitation of splitting through a streamlined mechanism guide, substantially enhancing the ease of open and close operations. Experimental tests show the realized magnet systems can yield a high $Bl$ value (e.g., 400 Tm for a bifilar coil and 800 Tm for a single coil with a wire gauge of 0.2 mm) meanwhile a low volume/weight (40 kg) thanks to the uniformity improvement of magnetic profiles. Furthermore, important parameters related to systematic effects, such as the current effect, are checked, aiming for a final mass-realization accuracy at the $10^{-8}$ level.

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用于清华桌面式卡布天平的紧凑型磁铁系统

尽管基布尔天平的所谓磁性几何因子（$Bl$）并不出现在基布尔方程中，但它提供了电气量和机械量之间的精密联系，并为质量计量提供了一条准量子溯源路径。这一特点使得磁铁系统在基布尔天平中发挥了核心作用，它提供了基布尔方程中的$Bl$。按照开放式硬件的思路，我们在此报告清华台式基布尔天平紧凑型磁体系统的设计、制造、组装、优化和最终性能。值得注意的是，本研究中展示的磁铁系统通过流线型的机构导轨实现了分体的直接上悬浮，大大提高了开合操作的便利性。实验测试表明，实现的磁体系统可以产生较高的 Bl$ 值（例如，线规为 0.2 毫米的双纤线圈为 400 Tm，单线圈为 800 Tm），同时由于磁性轮廓的均匀性得到改善，体积/重量较小（40 千克）。此外，还检查了与系统效应（如电流效应）有关的重要参数，目的是将最终的质量实现精度提高到 10^{-8}$ 的水平。

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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arXiv - PHYS - Instrumentation and Detectors

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