Add to ORKGWe show here the analysis of the MD test that aimed to quench the superconducting magnets in the dispersion suppressor region downstream of the main betatron collimation system. In Run I there were several attempts to quench the magnets in the same region. This was done by exciting the Beam 2 in a controlled way using the transverse damper and generating losses leaking from the collimation cleaning. No quench was achieved in 2013 with a maximum of 1 MW of beam power loss absorbed by the collimation system at 4 TeV beam energy. In 2015 a new collimation quench test was done at 6.5 TeV aiming at similar power loss over longer period, 5-10 s. The main outcome of this test is reviewed
The fast beam losses in the order of 1 ms are expected to be a potential major luminosity limitation...
Protection of LHC equipment relies on a complex system of collimators to capture injected and circul...
The limiting locations of the present LHC machine in terms of losses on cold magnets are the dispers...
In 2013, at the end of the LHC physics run I, several quench tests took place with the aim to measur...
This note summarizes the collimation quench test MD with 208Pb82+ beams at 6.37Z TeV in which a quen...
The Large Hadron Collider (LHC) has been operating since 2010 at 3.5 TeV and 4.0 TeV without experie...
The LHC superconducting magnets in the dispersion suppressor of IR7 are the most exposed to beam los...
Beam studies to address the limitations of the Phase~I collimation system were performed. The primar...
A Machine Development study session was held on December 6th, 2011 to test BLM quench thresholds in ...
The power deposited in dispersion suppressor (DS) magnets downstream of the LHC betatron cleaning in...
International audienceThe LHC heavy-ion program with 208Pb⁸²⁺ beams is foreseen to benefit from a si...
International audienceDuring some periods in its second physics run (2015-2018), the LHC has been op...
The application of superconducting materials in the field of high energy accelerator physics not onl...
In high intensity proton colliders with superconducting magnets, quenches induced by beam losses are...
A single sided mobile graphite diluter block TCDQ, in combination with a two-sided secondary collima...
The fast beam losses in the order of 1 ms are expected to be a potential major luminosity limitation...
Protection of LHC equipment relies on a complex system of collimators to capture injected and circul...
The limiting locations of the present LHC machine in terms of losses on cold magnets are the dispers...
In 2013, at the end of the LHC physics run I, several quench tests took place with the aim to measur...
This note summarizes the collimation quench test MD with 208Pb82+ beams at 6.37Z TeV in which a quen...
The Large Hadron Collider (LHC) has been operating since 2010 at 3.5 TeV and 4.0 TeV without experie...
The LHC superconducting magnets in the dispersion suppressor of IR7 are the most exposed to beam los...
Beam studies to address the limitations of the Phase~I collimation system were performed. The primar...
A Machine Development study session was held on December 6th, 2011 to test BLM quench thresholds in ...
The power deposited in dispersion suppressor (DS) magnets downstream of the LHC betatron cleaning in...
International audienceThe LHC heavy-ion program with 208Pb⁸²⁺ beams is foreseen to benefit from a si...
International audienceDuring some periods in its second physics run (2015-2018), the LHC has been op...
The application of superconducting materials in the field of high energy accelerator physics not onl...
In high intensity proton colliders with superconducting magnets, quenches induced by beam losses are...
A single sided mobile graphite diluter block TCDQ, in combination with a two-sided secondary collima...
The fast beam losses in the order of 1 ms are expected to be a potential major luminosity limitation...
Protection of LHC equipment relies on a complex system of collimators to capture injected and circul...
The limiting locations of the present LHC machine in terms of losses on cold magnets are the dispers...