Mechanical design concept version 2.0 for the miniBeBe subsystem of the Multi-Purpose Detector at the Nuclotron-based Ion Collider fAcility of the Joint Institute for Nuclear Research

arXiv - PHYS - Instrumentation and Detectors Pub Date : 2024-08-01 DOI:arxiv-2408.00556

M. Herrera, M. E. Patiño, Mauricio Alvarado, Ivonne Maldonado, Denis Andreev, Alejandro Ayala, Wolfgang Bietenholz, César Ceballos, Eleazar Cuáutle, Isabel Domínguez, L. A. Hernández, Israel Luna, Tuyana Lygdenova, Pablo Martínez-Torres, Alfredo Raya, Ulises Sáenz-Trujillo, M. E. Tejeda-Yeomans, Galileo Tinoco-Santillán

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Abstract

We present the design of the mechanical structure of the miniBeBe detector, a subsystem of the Multi-Purpose Detector, soon to enter into operation at the Nuclotron based Ion Collider fAcility of the Joint Institute for Nuclear Research. The miniBeBe detector was designed and is currently being developed by the MexNICA Collaboration to contribute to the level-zero trigger of the Time of Flight. The mechanical structure meets the requirements of minimizing the material budget and be free of ferromagnetic materials, without compromising its robustness. The design also allows easy module replacement for maintenance and overall removal at the end of the first stage of the experiment, without affecting the rest of the subsystems, to leave room for the installation of the Inner Tracking System. In addition, a Finite Element Method analysis of the mechanical components under load was performed. Based on this analysis, it was determined that the design meets the space constraints within the Multi-Purpose Detector, as well as a deformation of less than 1 mm with overall stress of less than 2 MPa, such that no material used in the design is at risk of mechanical failure during operation. A cooling system heat transfer analysis was performed showing that the detector Silicon Photo-Multipliers can be kept within a temperature range of 19$^{\circ}$C to 23$^{\circ}$C, which is adequate for their optimal performance.

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联合核研究所基于核素光子的离子对撞机设施多用途探测器迷你贝贝子系统的机械设计概念 2.0 版

我们介绍了微型BeBe探测器的机械结构设计，该探测器是多用途探测器的一个子系统，即将在核研究联合研究所的基于Nuclotron的离子对撞机设施投入运行。MexNICA合作组织设计并正在开发微型BeBe探测器，以便为飞行时间的零级触发做出贡献。该探测器的机械结构满足了最大限度减少材料预算和不使用铁磁材料的要求，同时又不影响其坚固性。该设计还允许在第一阶段试验结束时，在不影响其他子系统的情况下，方便地更换模块进行维护和整体拆卸，以便为安装内部跟踪系统留出空间。此外，还对负载下的机械部件进行了有限元法分析。根据分析结果，确定设计符合多用途探测器的空间限制，变形小于 1 毫米，总应力小于 2 兆帕，因此设计中使用的任何材料在运行期间都不会有机械故障的风险。进行的冷却系统热传导分析表明，探测器硅光电倍增管的温度可保持在 19^{\circ}$C 至 23^{\circ}$C 的范围内，这足以使其达到最佳性能。

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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