Aperture and failure scenarios

Aperture and failure scenarios F. Velotti, J. Borburgh, K. Cornelis, B. Goddard, V. Kain, T. Kramer, M. Meddahi, J. Uythoven

Outline • New ion injection system layout • Kickers, septa and beam parameters • Nominal injection • Protons • Ions • MSI-V and MKP-I • 3 MKPs (A, A, C) and MSI-V • Acceptance analysis – TT2/TT10/SPS • Failure case studies • Conclusions

New Ion Injection System Layout MSI-V MKP-I MBB displaced by 10 mm Absorber block for ion beams

Injection elements parametersfor ion beam • MKP-I • q = 1.33 mrad • B.dl = 0.08 Tm • L = 4.15 m • Positioned 10 m upstream QF.120 • MSI-V (V = vacuum and not vertical!) • q = 13 mrad • L = 3 m (2 magnets) • Positioned just upstream the TIDVG • MSI • q = 10.7 (*4) mrad

Injection element parameters for proton beams • FT Optics (Q26) • MKPA/C • V = 49.2 kV • B.dlA = 0.087 Tm • B.dlC = 0.035 Tm • MKP • Off • MSI • q = 10.4 (*4) mrad • LHC Optics (Q20) • MKPA/C • V = 52 kV • B.dlA = 0.092 Tm • B.dlC = 0.037 Tm • MKP • V = 52 kV • B.dl = 0.138 Tm • MSI • q = 10.8 (*4) mrad

Beam parameters (for the following studies)

FT beam (Q26) Injected and dumped (H-plane) MKP-I MKP MSI MSI-V Ion dump TBSJ MDSH off

LHC Beam (Q20) Injected and dumped (H-plane) MKP-I MKP MSI MSI-V Ion dump TBSJ MDSH off

FT beam in the injection region V-plane MKP-I MSI-V TIDVG (vertical aperture machine bottleneck)

1. Ion Beam (Q20)Injected and dumped (H-plane) MKP-I MKP MSI MSI-V Ion dump TBSJ Injection bump to help dumping the beam in case of MKP-I failure – 29 mm at QF.122 MDSH off

2. Ion Beam (Q20)Injected and dumped (H-plane) • MKPA/C • V = 29.3 kV • B.dlA = 0.052 Tm • B.dlC = 0.021 Tm • MKP • Off • MSI • q = 10.7 (*4) mrad • MSI-V • q = 12.3 mrad MKP MSI-V Ion dump Bump of 25 mm at QF.120 MKPs h displacement not shown Only using existing kickers!!

Acceptance analysis - TT2/TT10/SPS • From TT2 to SPS, for LHC and ion beams (Q20) • From emittance exchange section in TT10 to SPS, for FT optics (MAD-X doesn’t like too much skew quads) • Static and dynamic errors assigned • Correction made with SVD method • BPM error reading considered

Acceptance analysis - TT2/TT10/SPS Static Errors Before Correction BPM Reading Errors After Correction For any BPMs has been considered a 5% probability of complete failure Dynamic Errors

Acceptance analysis – TT10/SPSFT Beam MSI-V MSI • More than 7 s acceptance at the MSI-V (+3 sw.r.t. MSI)

Acceptance analysis – TT10/SPSFT Beam • Considering injection errors, the phase space portraits at the exit of the MSI and MSI-V show that the MSI-V is always in the shade of the MSI • Phase advance between MSI exit and MSI-V entrance is 8.8° (no elements in between) +/- 15 sigma FT beam, cut at the MSI and projected to MSI-V

Acceptance analysis – TT10/SPSFT Beam • Steering with MSI at injection • Between 97.5% and 103% of the nominal value (maximum range in 2012 operation) • No Beam should intercept the MSI-V MSI-V entrance MSI-V exit +/- 5 s FT beam

Acceptance analysis - TT2/TT10/SPSLHC Beam MSI-V MSI • More than 19 s acceptance at the MSI-V (+8 sw.r.t. MSI) • To steer the injection, the MSI strength is adjusted by ~2% the nominal value

Acceptance analysis - TT2/TT10/SPSIon Beam Here MSI-V is the limit (5 s)! • The orbit at the MSI-V can still be optimised • e.g. varying the septum angle

Failure cases • MKPs not firing • Taking into account injection errors • Main magnet failures in the transfer line • MSI failure • Current smaller than the nominal can be a problem for the MSI-V

MKP Failures • If the injection system fails, the beam will be lost on the injection dump • Considering injection errors (same as before) both the proton and ion beam cores (3 s) will still hit completely the absorber block FT Beam Ion Beam +/-3 s beam envelope for the biggest and smallest excursion from the nominal orbit

Failure in the transfer lines • TT10 is equipped with quadrupole current surveillance, hence the beam is not extracted from the PS if the current is not in the predefined range • Currently, any failure of the main dipoles will not avoid the beam to be extracted from the PS • A pick up at the entrance of the SPS will stop the extraction from PS if the orbit deviation is larger than 30 mm • An upgrade of the SIS (maybe also FGC) is foreseen for 2014 and it will interlock both quad and dipole currents StephaneCettour Cave: Private conversation

Failure of the MSI • The proton beams are the real threat for the MSI-V (although one shot most likely won’t kill it) • They can become dangerous in case of MSI current failures • If the MSI current is between the 75 and 95% of its nominal value, part of the proton beams will hit the MSI-V FT – LHC 0.13 MJ – 0.14 MJ 95% 90% 85% 80% 75%

Conclusions • The new septum, according to these first studies, seems not to add any new aperture limitation in the injection channel • In case of MKP-I failure, the ion beam core will be safely dumped on the new absorber block • Current errors in the MSI can be a very dangerous scenario for the MSI-V • Interlocking needs to be studied • For the rest it seems to be well “protected” by the MSI

Aperture and failure scenarios

Aperture and failure scenarios

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