The gas electron multiplier technology has been proven to tolerate rat e larger than 50 MHz/cm2 without noticeable aging and to provide sub resolution on working chambers up to 45 cm x 45 cm. A new gas electron multiplier-based tracker is under development for the Hall A upgrade at Jefferson Lab. The chambers of the tracker have been designed in a modular way: each chamber consists of 3 adjacent gas electron multiplier modules, with an active area of 40 cm x 50 cm each. We optimized the gas flow inside the gas electron multiplier module volume, using the COMSOL physics simulator framework; the COMSOL-based analysis includes the design of the inlet and outlet pipes and the maximization of the uniformity of the gas flow. We have defined the procedures for the assembling of the gas electron multiplier modules and designed a mechanical system (TENDIGEM) that will be used to stretch the GEM foils at the proper tension (few kg/cm); the TENDIGEM is based on the original design developed at LNF.
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机译:事实证明,气体电子倍增器技术可以承受大于50 MHz / cm2的老鼠,而不会出现明显的老化,并且可以在45 cm x 45 cm的工作室上提供亚分辨率。杰斐逊实验室正在为Hall A升级项目开发一种基于气体电子倍增器的新型跟踪器。跟踪器的腔室采用模块化设计:每个腔室由3个相邻的气体电子倍增器模块组成,每个模块的有效面积均为40 cm x 50 cm。我们使用COMSOL物理模拟器框架优化了气体电子倍增器模块内部的气体流量;基于COMSOL的分析包括进气管和出气管的设计以及气流均匀性的最大化。我们已经定义了气体电子倍增器模块的组装程序,并设计了一个机械系统(TENDIGEM),该系统将以适当的张力(几公斤/厘米)拉伸GEM箔。 TENDIGEM基于LNF开发的原始设计。
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