Optical in-situ measurement of relative deformations of the LHC main dipole cold masses

Author

Aznar, S. ; Billan, J. ; Perez, J. Garcia ; China, M. La ; Ferracin, P. ; Redaelli, S. ; Scandale, W. ; Todesco, E.

Author_Institution

LHC Div., CERN, Geneva, Switzerland

Volume

12

Issue

1

fYear

2002

fDate

3/1/2002 12:00:00 AM

Firstpage

1736

Lastpage

1740

Abstract

The LHC cryodipoles are composed of an evacuated cryostat and a cold mass, which is cooled by superfluid helium at 1.9 K. To obey constraints imposed by beam dynamics the particle beams must be centered within the mechanical axis of the dipole with a sub-millimeter accuracy. This requires in turn that the relative displacements between the cryostat and the cold mass must be monitored with accuracy at all times. Because of the extreme environmental conditions (the displacement must be measured in vacuum and between two points at a temperature difference of about 300 degrees), no adequate existing monitoring system was found for this application. We describe here a novel optical sensor developed for our scope and we present results of measurements made during the cold test of the dipoles.

Keywords

cooling; cryogenics; ion accelerators; ion beams; ion optics; particle beam dynamics; particle beam focusing; storage rings; superconducting magnets; superfluid helium-4; synchrotrons; 1.9 K; He; LHC cryodipoles; LHC main dipole cold masses; beam dynamics; evacuated cryostat; mechanical axis; monitoring system; optical in-situ measurement; particle beam; relative deformations; superfluid helium coolant; Displacement measurement; Helium; Large Hadron Collider; Optical sensors; Particle beam measurements; Particle beam optics; Particle beams; Temperature sensors; Ultraviolet sources; Vacuum systems;

fLanguage

English

Journal_Title

Applied Superconductivity, IEEE Transactions on

Publisher

ieee

ISSN

1051-8223

Type

jour

DOI

10.1109/TASC.2002.1018743

Filename

1018743