The Gas Electron Multiplier (GEM) technology has been proven to tolerate rate larger than 50 MHz/cm2 without noticeable aging and to provide the sub-millimeter resolution on working chambers up to 45x45 cm2. A new GEM tracker is under development for the upgrade of the SBS spectrometer in Hall A at Jefferson Lab. The chambers of the tracker have been designed in a modular way: each chamber consists of 3 adjacent GEM modules, with an active area of 40x50 cm2 each. We have defined the procedures for the assembling of the GEM 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 the LNF. The support structure of the tracker GEM must be very light, but at the same time it must be also very resistant to the deformation. To this aim it is crucial optimizing the design of the support structure and the choice of the material; carbon fiber is a favorite candidate. Using such a composite material, it is necessary to simulate gluing between different parts of the structure and this has been possible with COMSOL software package
Development of the service frame for SBS Tracker GEM and TENDIGEM development
BELLINI, Vincenzo;SUTERA, CONCETTA MARIA
2012-01-01
Abstract
The Gas Electron Multiplier (GEM) technology has been proven to tolerate rate larger than 50 MHz/cm2 without noticeable aging and to provide the sub-millimeter resolution on working chambers up to 45x45 cm2. A new GEM tracker is under development for the upgrade of the SBS spectrometer in Hall A at Jefferson Lab. The chambers of the tracker have been designed in a modular way: each chamber consists of 3 adjacent GEM modules, with an active area of 40x50 cm2 each. We have defined the procedures for the assembling of the GEM 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 the LNF. The support structure of the tracker GEM must be very light, but at the same time it must be also very resistant to the deformation. To this aim it is crucial optimizing the design of the support structure and the choice of the material; carbon fiber is a favorite candidate. Using such a composite material, it is necessary to simulate gluing between different parts of the structure and this has been possible with COMSOL software packageI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.