The measuring systems of the wire tension for the MEG II Drift Chamber   by means of the resonant frequency technique

A. M. Baldini (5); H. Benmansour (7,5); G. Cavoto (1,2); F. Cei (7,5),; M. Chiappini (5); G. Chiarello (5); C. Chiri (4); G. Cocciolo (3,4); A.; Corvaglia (4); F. Cuna (1,2); M. Francesconi (7,5); L. Galli (5); F.; Grancagnolo (4); M. Grassi (5); M. Meucci (1,2); A. Miccoli (4); D.; Nicolo'(7,5); M. Panareo (3,4); A. Papa (7,5,9); C. Pinto (3,4); F. Raffaelli; (5); F. Renga (2); G. Signorelli (5); G.F. Tassielli (8); A. Venturini (7,5),; B. Vitali (7,5); C. Voena (2) ((1) Dipartimento di Fisica Universita' La; Sapienza; Piazzale A. Moro; 00185 Roma; Italy (2) INFN Sezione di Roma,; Piazzale A. Moro; 00185 Roma; Italy (3) Dipartimento di Matematica e Fisica; Ennio De Giorgi - Universita' del Salento; Via Arnesano; Lecce; Italy (4); INFN Sezione di Lecce; Via Arnesano; Lecce; Italy (5) INFN Sezione di Pisa,; Largo B. Pontecorvo 3; 56127; Pisa; Italy (7) Dipartimento di Fisica; Universita' di Pisa; Largo B. Pontecorvo 3; 56127 Pisa; Italy (8); Dipartimento di Fisica Universita' di Bari; Campus Universitario; Via; Amendola 173; 70125 Bari; Italy (9) Paul Scherrer Institut PSI; 5232; Villigen; Switzerland)

arXiv:2207.10990·physics.ins-det·October 27, 2022

The measuring systems of the wire tension for the MEG II Drift Chamber by means of the resonant frequency technique

A. M. Baldini (5), H. Benmansour (7,5), G. Cavoto (1,2), F. Cei (7,5),, M. Chiappini (5), G. Chiarello (5), C. Chiri (4), G. Cocciolo (3,4), A., Corvaglia (4), F. Cuna (1,2), M. Francesconi (7,5), L. Galli (5), F., Grancagnolo (4), M. Grassi (5), M. Meucci (1,2), A. Miccoli (4)

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TL;DR

This paper describes a resonant frequency technique for measuring wire tension in the MEG II drift chamber, improving accuracy and reliability for wire tension control during construction.

Contribution

The paper introduces a detailed resonant frequency measurement system for wire tension, enhancing precision and addressing corrosion issues in drift chamber wire manufacturing.

Findings

01

The system accurately measures wire tension via resonant frequency.

02

Application to sample wires demonstrated effective tension control.

03

Potential improvements discussed for measurement accuracy.

Abstract

The ultra-low mass cylindrical drift chamber designed for the MEG II experiment is a challenging apparatus made of 1728 phi = 20 micron gold plated tungsten sense wires, 7680 phi = 40 micron and 2496 phi = 50 micron silver plated aluminum field wires. Because of electrostatic stability requirements all the wires have to be stretched at mechanical tensions of about 25, 19 and 29 g respectively which must be controlled at a level better than 0.5 g. This chamber is presently in acquisition, but during its construction about 100 field wires broke, because of chemical corrosion induced by the atmospheric humidity. On the basis of the experience gained with this chamber we decided to build a new one, equipped with a different type of wires less sensitive to corrosion. The choice of the new wire required a deep inspection of its characteristics and one of the main tools for doing this is a…

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Taxonomy

TopicsSuperconducting Materials and Applications · Particle accelerators and beam dynamics · Particle Accelerators and Free-Electron Lasers