AMT - Beam generated heat deposition and quench levels for LHC magnets

Name: AMT - Beam generated heat deposition and quench levels for LHC magnets
Start: 2005-03-03T09:00:00+01:00
End: 2005-03-04T15:30:00+01:00
Location: 40-S2-B01

3–4 Mar 2005

40-S2-B01

Europe/Zurich timezone

Support

julie.hadre@cern.ch

Scientific Programme

Welcome adress, Introduction & Scope of the workshop
01

by L. Rossi
Introduction to the session
02

by R. Assmann
Review of past estimations of the induced quench levels by beam losses in the LHC dipoles
12

by D. Leroy
Transient beam losses at injection and during beam dump
03

by B. Goddard
Multiturn beam losses
04

by G. Robert-Demolaize
Heat loads from beam
05

by V. Baglin
Heavy ion interactions with matter
06

by G. Smirnov
Ion operation and beam losses
07

by S. Gilardoni
LHC and magnet operation
08

by R. Schmidt
Quench levels and transient beam losses at HERA
09

by K. Wittenburg
Quench levels and transient beam losses at TEVATRON
10

by D. Still
PRESENTATION CANCELED
Why do BLMs need to know the quench levels?
11

by B. Dehning
Quench levels – experience from magnet tests at CERN
13

by A. Siemko
MEB and magnet sorting criteria
14

by L. Bottura
Insertions magnets and IR radiation
15

by R. Ostojic
Thermal analysis and its experimental verification for the present and future IR triplets
16

by A. Zlobin
Understanding AC losses for LHC magnets
17

by D. Richter
Heat transfer in superconducting magnets
18

by R. Van Weelderen
Experiment for energy deposition in a target
19

by V. Kain
Case study: Energy deposition in superconducting magnets in IR6
20

by B. Goddard
Case study: Energy deposition in superconducting magnets in IR7
21

by V. Vlachoudis
Protecting Superconducting Magnets from Radiation at Tevatron, SSC, LHC and its upgrades.
22

by N.Mokhov
Thermal modelling of IR quadrupoles
23

by F. Broggi
Modelling stability on Nb-Ti cables; R&D on stability planned in the Cern cable test facility FRESCA
24

by A. Verweij
SPQR – could it contribute?
25

by M. Calvi
Liquid helium heat transfer in superconducting cables insulation of accelerator magnets
26

by B. Baudouy
Summary and Round Table Discussion : How to go on ?
27

With R. Assmann, L. Bottura, J.B. Jeanneret, K.H. Mess, P. Pugnat, R. Schmidt, A. Siemko
Closing remarks
28

by S. Myers

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AMT - Beam generated heat deposition and quench levels for LHC magnets

Support

Welcome adress, Introduction & Scope of the workshop

Introduction to the session

Review of past estimations of the induced quench levels by beam losses in the LHC dipoles

Transient beam losses at injection and during beam dump

Multiturn beam losses

Heat loads from beam

Heavy ion interactions with matter

Ion operation and beam losses

LHC and magnet operation

Quench levels and transient beam losses at HERA

Quench levels and transient beam losses at TEVATRON

Why do BLMs need to know the quench levels?

Quench levels – experience from magnet tests at CERN

MEB and magnet sorting criteria

Insertions magnets and IR radiation

Thermal analysis and its experimental verification for the present and future IR triplets

Understanding AC losses for LHC magnets

Heat transfer in superconducting magnets

Experiment for energy deposition in a target

Case study: Energy deposition in superconducting magnets in IR6

Case study: Energy deposition in superconducting magnets in IR7

Protecting Superconducting Magnets from Radiation at Tevatron, SSC, LHC and its upgrades.

Thermal modelling of IR quadrupoles

Modelling stability on Nb-Ti cables; R&D on stability planned in the Cern cable test facility FRESCA

SPQR – could it contribute?

Liquid helium heat transfer in superconducting cables insulation of accelerator magnets

Summary and Round Table Discussion : How to go on ?

Closing remarks