1 / 33

Radiation monitoring: what do we have and what do we need?

Radiation monitoring: what do we have and what do we need?. M. Calviani, M. Brugger, P. Peronnard, J. Saraiva, G. Spiezia (EN/STI) R2E/Availability Workshop October 2014. Summary. Use of the monitoring system Brief summary of Run I experience RadMon development Injectors monitoring

stacy-holmes
Download Presentation

Radiation monitoring: what do we have and what do we need?

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Radiation monitoring: what do we have and what do we need? M. Calviani, M. Brugger, P. Peronnard, J. Saraiva, G. Spiezia (EN/STI) R2E/Availability Workshop October 2014

  2. Summary • Use of the monitoring system • Brief summary of Run I experience • RadMon development • Injectors monitoring • Requirements from users • What would be needed for Run II M. Calviani: Radiation monitoring - R2E/Availability Workshop

  3. What do we use the monitoring for • Measurement of radiation levels in the machines: • High energy hadron fluence (HEH) • Total ionizing dose (TID) • Understanding of the radiation field in the tunnel and shielded areas and support for simulation extrapolation • Important service to equipment groups for failure analysis • Input/requirement for equipment design M. Calviani: Radiation monitoring - R2E/Availability Workshop

  4. What would happen if don’t have it • Cannot correlate equipment failure with radiation levels  risk of changing equipment w/o solving the problem • Cannot anticipate need for equipment upgrades – rad-tolerant • Cannot study radiation impact of changing operational parameters • Cannot dissociate the possible radiation source • Limited info on eventual radiation quantity responsible for degradation (TID, NIEL, HEH) M. Calviani: Radiation monitoring - R2E/Availability Workshop

  5. Types of detectors employed M. Calviani: Radiation monitoring - R2E/Availability Workshop

  6. LHC RadMon coverage • LHC • Critical areas (UJ, RR, US, UX, RE, UA) • DS and start of ARC • LSS • Experiments M. Calviani: Radiation monitoring - R2E/Availability Workshop

  7. RadMon locations in DS/ARC • DS/ARC (from cell 7 to 20) • RadMon are placed below the interconnect between the last MB/MQ of a given cell • Equipment below MB/MQ! cell i cell i+1 MQ MB MB MB Tunnel equipment (QPS, CRYO, BLM or EPC) cell i+1 cell i MB MB MB MB MQ • Dedicated LHC-MD  extraction of an operative ratio between BLM dose and expected HEH from RadMons = ~1 SEU count/mGy M. Calviani: Radiation monitoring - R2E/Availability Workshop

  8. Experience from Run I (1/5) • Nice summary of Run I observation is available here • Radiation levels summarized with the use of different types of detectors (RadMons, BLMs, FGCs, etc.) M. Calviani: Radiation monitoring - R2E/Availability Workshop

  9. Experience from Run I (2/5) • Lesson: • Important to follow-up machine operational parameters (TCL/RR) M. Calviani: Radiation monitoring - R2E/Availability Workshop

  10. Experience from Run I (3/5) • Lessons: • BLM analysis fundamental for the DS/ARC • When BLM/RadMon available, good agreement between them Point 4 M. Calviani: Radiation monitoring - R2E/Availability Workshop

  11. Experience from Run I (4/5) • Very important to follow-up radiation monitoring following operational variations • Sometimes just scaling is risky... Predictions 2012 Observations end 2012 Decreased: TCL closed Increased: tight collimators Increased: higher cum. lumi M. Calviani: Radiation monitoring - R2E/Availability Workshop

  12. Experience from Run I (5/5) • We should not forget the p-Pb and Pb-Pb runs • Due to the Bound-Free Pair Production (BFPP), even for short runs, radiation levels can be up to 5 times those of a “standard” pp run • DS cells most affected ~3 days ~7 months M. Calviani: Radiation monitoring - R2E/Availability Workshop

  13. Open points in view of Run II • 25 ns operation uncertainties: • Evolution of beam-gas levels during 25 ns operation still to be fully clarified • During Chamonix 2012 it was stated that pressure will not increase more than 2x with respect to 50 ns • However – experience showed that pressure variation depends strongly on real operational parameters Still an open point M. Calviani: Radiation monitoring - R2E/Availability Workshop

  14. Open points in view of Run II • LHC Point 4 and Point 6 • UX45: radiation levels in 2012 higher than expected from 2011  triggered TE/CRG relocation activities • How the situation will evolve with 25ns operation? • UX65: still calm, as no special equipment might increase the beam-gas interaction • Monitoring has been improved M. Calviani: Radiation monitoring - R2E/Availability Workshop

  15. RadMons developments • During LS1 more than 100 RadMons have been installed in machines • 450 in total • Injectors, target area, experimental areas.. • LHC: ARC P1-2-5-8 + relocations for R2E • RadMon v5 • LHC • RadMon v6 • Experimental areas (n_TOF, AD) • Injection lines M. Calviani: Radiation monitoring - R2E/Availability Workshop

  16. RadMons development • Features of v6: • Remote configurability • Self-diagnostic • Radiation resistance 3 times higher • New sensors • Advantages with respect to v5: • Resolution improved by a factor of 10 • Reduced number of tunnel access to change settings • Longer life-time M. Calviani: Radiation monitoring - R2E/Availability Workshop

  17. RadMons development • Overall resolution improvement – factor of 3 to 10 • TID limit 3x times larger M. Calviani: Radiation monitoring - R2E/Availability Workshop

  18. BatMon – versatile instrument • Where versatile installation is required • E.g. PLC failures in LHC Point 4 and 6 requiring urgent checks • Validation of the relocation strategy • Measure R-factor in critical area via voltage change • Measurement requests for machine studies M. Calviani: Radiation monitoring - R2E/Availability Workshop

  19. Injector’s radiation monitoring • R2E up to 2012 concentrated on the LHC, in order to mitigate radiation effects for Run 1 • However issues are present in the injector chain as well, simply “less visible” • In order to guarantee machine availability also in the future, it’s important to dedicate resources on it as well • Info available at http://r2e-injectors.web.cern.ch/ M. Calviani: Radiation monitoring - R2E/Availability Workshop

  20. Issues with present radiation monitoring • BLMs(ACEM – Aluminum Cathode Electron Multipliers) • Saturation in critical areas, of no use for loss distribution • Not calibrated to dose • Ongoing campaign to install LHC-type BLMs in PSB (not PS)  important to be able to evaluate cumulative dose • SPS ionisation chambers – low granularity (1 every 32 meters) • HLD (not online system) • Radiation Surveys • Depends on activation, cannot directly relate to rad levels for equipment M. Calviani: Radiation monitoring - R2E/Availability Workshop

  21. PSB example (RS vs. HLD) M. Calviani: Radiation monitoring - R2E/Availability Workshop

  22. PS example (RS vs. HLD) M. Calviani: Radiation monitoring - R2E/Availability Workshop

  23. M. Calviani: Radiation monitoring - R2E/Availability Workshop

  24. M. Calviani: Radiation monitoring - R2E/Availability Workshop

  25. Injector monitoring - future • Requirements: • Appropriate BLM coverage with sufficient granularity in PS/PSB/SPS • RadMon installation extension • Passive dosimetry • Important to follow-up this measurements and improve analysis speed M. Calviani: Radiation monitoring - R2E/Availability Workshop

  26. Requirements from users • A weekly report was published during 2011/2012, providing radiation levels in critical areas • Service to users in support of the RadWG M. Calviani: Radiation monitoring - R2E/Availability Workshop

  27. Requirements from users • However: • It was a manual system, requiring full support from the MCWG team • Difficult for users to understand levels if equipment away from the detector location  interpretation/extrapolation from MCWG team needed • Loss scenarios can modify radiation levels distributions • Investment should be made to try to automatize it! M. Calviani: Radiation monitoring - R2E/Availability Workshop

  28. Requirements from users • An attempt of realizing an online system was performed in collaboration with EN/ICE LHC R2E Dashboard • Complex to maintain, since as of now data requires manual manipulation Dedicated support of EN/ICE requested to revise the system M. Calviani: Radiation monitoring - R2E/Availability Workshop

  29. What will be needed for Run II • Reactivation of the MCWG analysis team • Dedicated support from the BLM team to provide cumulated doses on a weekly basis • RadMon team to continue support the detectors • Continue keep track of the detectors inventory (Layout DB?) • Support of the groups for fast reporting on equipment failures • Continue improving on radiation monitoring in the injectors M. Calviani: Radiation monitoring - R2E/Availability Workshop

  30. M. Calviani: Radiation monitoring - R2E/Availability Workshop

  31. Fundamental to follow-up on these, at the moment done manually! M. Calviani: Radiation monitoring - R2E/Availability Workshop

  32. Conclusions • Monitoring is and will be an important aspects of the R2E (and Availability) activities • In the LHC and in the Injector chain • It is now required as a service rather than studies • Powerful instrument that allow providing a service to equipment owners in understanding radiation-related failures M. Calviani: Radiation monitoring - R2E/Availability Workshop

More Related