A novel application of Fiber Bragg Grating (FBG) sensors in MPGD

D Abbaneo,T Lenzi,D Pierluigi,S Salva,G Raffone,S Ferry,P Aspell,H Postema,G Passeggio,G De Lentdecker,M Naimuddin,A Ranieri,S Cauwenbergh,F Loddo,A Vorobyev,G De Robertis,M Ferrini,G Saviano,B Philipps,Y Ban,A Lalli,S Braibant,S Krutelyov,F Guilloux,L Passamonti,M Van Stenis,G Rashevski,R Sharma,A Puig Baranac,A Marchioro,O Aboamer,S Banerjee,M Abi Akl,N Zaganidis,V Barashko,A Madorsky,A Radi,M Hohlmann,P Iaydjiev,F Zenoni,G Sultanov,Jason Sang Hun Lee ,D Piccolo,P Vitulo,G Endrőczi ,L Guiducci,S Swain ,R Yonamine,M Wang,A Cimmino,Y G Jeng ,A Safonov,P Altieri,A Russo,A Aleksandrov,O Bouhali,M Maggi,Martin M.f Choi ,F R Cavallo ,A Magnani,Erik Verhagen ,Aashaq Shah ,H Kim,A Mohapatra,I Awan,K Mandal,J Hauser,P Paolucci,P Barria,J Molnár ,A Malta Rodrigues ,D Wang,Anita Ahmad ,Z Szillási ,S Colafranceschi,S Bally,K Höepfner ,Marco Valente ,M Dabrowski ,A Çelik ,F Errico,A Fenyvesi,Sungyun Choi ,Jeremie Alexandre Merlin ,S Buontempo,I Park,J Sturdy,L M Pant ,Ashok Kumar ,C Riccardi,G Bencze,M Abbrescia,Supratik Mukhopadhyay ,L Benussi,M Shopova,S Czellár ,A Conde Garcia,V Bhopatkar,M Caponero,P Verwilligen,M Tytgat,R Venditti,A Braghieri,S Muhammad,P Mal ,P Giacomelli,A Colaleo,Y Assran,I Vai,D Acosta,A Korytov,N Béni ,C Caputo,J Christiansen,L Litov,H R Hoorani ,A Marinov,F Primavera,M S Ryu ,T Tuuva,Yang Yu ,B Pavlov,A Castaneda,N Majumdar,S Roychowdhury,R Radogna,C Calabria,S Volkov,P E Karchin ,A Zhang,Francesco Peluso Cassese ,B Dorney,A K Mohanty ,I K Furić ,J Talvitie,S Dildick,R Hadjiiska ,J Bos,E Oliveri,A Gutiérrez ,M Rodozov,S Nuzzo,Rui De Oliveira ,G Ryu,T Kamon,C Asawatangtrakuldee,J Gilmore,S Bianco,A Tatarinov,W Ahmed,M Abbas,A S Sharma ,V Golovtsov,U K Yang ,T Maerschalk,G Mitselmakher,L Ropelewski

doi:10.1051/epjconf/201817403002

Abstract

We present a novel application of Fiber Bragg Grating (FBG) sensors in the construction and characterisation of Micro Pattern Gaseous Detector (MPGD), with particular attention to the realisation of the largest triple (Gas electron Multiplier) GEM chambers so far operated, the GE1/1 chambers of the CMS experiment at LHC. The GE1/1 CMS project consists of 144 GEM chambers of about 0.5 m2 active area each, employing three GEM foils per chamber, to be installed in the forward region of the CMS endcap during the long shutdown of LHC in 2108-2019. The large active area of each GE1/1 chamber consists of GEM foils that are mechanically stretched in order to secure their flatness and the consequent uniform performance of the GE1/1 chamber across its whole active surface. So far FBGs have been used in high energy physics mainly as high precision positioning and re-positioning sensors and as low cost, easy to mount, low space consuming temperature sensors. FBGs are also commonly used for very precise strain measurements in material studies. In this work we present a novel use of FBGs as flatness and mechanical tensioning sensors applied to the wide GEM foils of the GE1/1 chambers. A network of FBG sensors have been used to determine the optimal mechanical tension applied and to characterise the mechanical tension that should be applied to the foils. We discuss the results of the test done on a full-sized GE1/1 final prototype, the studies done to fully characterise the GEM material, how this information was used to define a standard assembly procedure and possible future developments.

Highlights

To upgrade the Compact Muon Solenoid (CMS[1]) muon system 144 GEM chambers will be installed in the high pseudo-rapidity region of CMS during Long Shutdown 2 (LS2) of the Large Hadron Collider [2]
The Fiber Bragg Grating (FBG) sensors act as low cost precision spatial and temperature sensing tools and they are commonly used for strain measurements [7] [8] [9]
3 Another FBG application: the load gauge. Another important application of FBG in GEM chamber construction is the possibility to be used as load gauge for precise measurement of the tensile load applied to the foils, of the different layers, in the same moment

Summary

Introduction

To upgrade the Compact Muon Solenoid (CMS[1]) muon system 144 GEM chambers will be installed in the high pseudo-rapidity region of CMS during Long Shutdown 2 (LS2) of the Large Hadron Collider [2]. The large active area of each GE1/1 (GEM Endcap) chamber, approximately 0.4 m2 [4], consists of a triple-GEM foil stack stretched by means of screws placed around the stack frame (fig.). The FBG sensors act as low cost precision spatial and temperature sensing tools and they are commonly used for strain measurements [7] [8] [9]. The GE1/1 assembly procedure employs a mechanical stretching procedure to apply tension to the GEM foils by means of a series of lateral screws inserted into the internal GE1/1 frame This technology allows mechanical assembly of the GEM chamber without the use of internal spacers or glue

FBG sensors as a strain measurement

Another FBG application: the load gauge

Conclusion