_version_ 1866910409134440448
author Francia, A. Romero
Marcone, A. Perillo
Pianese, S.
Andersen, K.
Izquierdo, G. Arnau
Briz, J. A.
Perez, D. Carbajo
Carlier, E.
Coiffet, T.
Esposito, L. S.
Grenard, J. L.
Grenier, D.
Humbert, J.
Kershaw, K.
Lendaro, J.
Rolo, A. Ortega
Scibor, K.
Senajova, D.
Sgobba, S.
Sharp, C.
Steyaert, D.
Velotti, F. M.
Vincke, H.
Vlachoudis, V.
Calviani, M.
author_facet Francia, A. Romero
Marcone, A. Perillo
Pianese, S.
Andersen, K.
Izquierdo, G. Arnau
Briz, J. A.
Perez, D. Carbajo
Carlier, E.
Coiffet, T.
Esposito, L. S.
Grenard, J. L.
Grenier, D.
Humbert, J.
Kershaw, K.
Lendaro, J.
Rolo, A. Ortega
Scibor, K.
Senajova, D.
Sgobba, S.
Sharp, C.
Steyaert, D.
Velotti, F. M.
Vincke, H.
Vlachoudis, V.
Calviani, M.
contents The Super Proton Synchrotron (SPS) is the last stage in the injector chain for CERN's Large Hadron Collider, and it also provides proton and ion beams for several fixed-target experiments. The SPS has been in operation since 1976, and it has been upgraded over the years. For the SPS to operate safely, its internal beam dump must be able to repeatedly absorb the energy of the circulating beams without sustaining damage that would affect its function. The latest upgrades of the SPS led to the requirement for its beam dump to absorb proton beams with a momentum spectrum from 14 to 450~GeV/$c$ and an average beam power up to $\sim$270~kW. This paper presents the technical details of a new design of SPS beam dump that was installed in one of the long straight sections of the SPS during the 2019--2020 shutdown of CERN's accelerator complex. This new beam dump has been in operation since May 2021, and it is foreseen that it will operate with a lifetime of 20~years. The key challenges in the design of the beam dump were linked to the high levels of thermal energy to be dissipated -- to avoid overheating and damage to the beam dump itself -- and high induced levels of radiation, which have implications for personnel access to monitor the beam dump and repair any problems occurring during operation. The design process therefore included extensive thermomechanical finite-element simulations of the beam-dump core and its cooling system's response to normal operation and worst-case scenarios for beam dumping. To ensure high thermal conductivity between the beam-dump core and its water-cooling system, hot isostatic pressing techniques were used in its manufacturing process. A comprehensive set of instrumentation was installed in the beam dump to monitor it during operation and to cross-check the numerical models with operational feedback.
format Preprint
id arxiv_https___arxiv_org_abs_2312_15485
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Design and early operation of a new-generation internal beam dump for CERN's Super Proton Synchrotron
Francia, A. Romero
Marcone, A. Perillo
Pianese, S.
Andersen, K.
Izquierdo, G. Arnau
Briz, J. A.
Perez, D. Carbajo
Carlier, E.
Coiffet, T.
Esposito, L. S.
Grenard, J. L.
Grenier, D.
Humbert, J.
Kershaw, K.
Lendaro, J.
Rolo, A. Ortega
Scibor, K.
Senajova, D.
Sgobba, S.
Sharp, C.
Steyaert, D.
Velotti, F. M.
Vincke, H.
Vlachoudis, V.
Calviani, M.
Accelerator Physics
High Energy Physics - Experiment
Nuclear Experiment
Instrumentation and Detectors
The Super Proton Synchrotron (SPS) is the last stage in the injector chain for CERN's Large Hadron Collider, and it also provides proton and ion beams for several fixed-target experiments. The SPS has been in operation since 1976, and it has been upgraded over the years. For the SPS to operate safely, its internal beam dump must be able to repeatedly absorb the energy of the circulating beams without sustaining damage that would affect its function. The latest upgrades of the SPS led to the requirement for its beam dump to absorb proton beams with a momentum spectrum from 14 to 450~GeV/$c$ and an average beam power up to $\sim$270~kW. This paper presents the technical details of a new design of SPS beam dump that was installed in one of the long straight sections of the SPS during the 2019--2020 shutdown of CERN's accelerator complex. This new beam dump has been in operation since May 2021, and it is foreseen that it will operate with a lifetime of 20~years. The key challenges in the design of the beam dump were linked to the high levels of thermal energy to be dissipated -- to avoid overheating and damage to the beam dump itself -- and high induced levels of radiation, which have implications for personnel access to monitor the beam dump and repair any problems occurring during operation. The design process therefore included extensive thermomechanical finite-element simulations of the beam-dump core and its cooling system's response to normal operation and worst-case scenarios for beam dumping. To ensure high thermal conductivity between the beam-dump core and its water-cooling system, hot isostatic pressing techniques were used in its manufacturing process. A comprehensive set of instrumentation was installed in the beam dump to monitor it during operation and to cross-check the numerical models with operational feedback.
title Design and early operation of a new-generation internal beam dump for CERN's Super Proton Synchrotron
topic Accelerator Physics
High Energy Physics - Experiment
Nuclear Experiment
Instrumentation and Detectors
url https://arxiv.org/abs/2312.15485