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Safety issues for WP2 E. Baussan on behalf of WP2.

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Presentation on theme: "Safety issues for WP2 E. Baussan on behalf of WP2."— Presentation transcript:

1 Safety issues for WP2 E. Baussan on behalf of WP2

2 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 2 Safety Issues for WP2 Outlines: – Physics with a neutrino superbeam –Technological Challenge –Status on WP2 –Safety ALARA ApproachALARA Approach SimulationSimulation

3 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 3 Neutrino Beam Experiments

4 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 4 HP-SPL for neutrino beams

5 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 5 Super Beam Neutrino Experiment Layout

6 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 6 Super Beam Neutrino Experiment Layout

7 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 7 Super Beam Neutrino Experiment Layout Memphys Detector: Underground water Cherenkov detector at Laboratoire Souterrain de Modane Fréjus at 4800 m.w.e.Underground water Cherenkov detector at Laboratoire Souterrain de Modane Fréjus at 4800 m.w.e. Total fiducial volume: up to 400 kton: 3 x 65mX60 modules could be designed up to 572kton: 3x 65mX80mTotal fiducial volume: up to 400 kton: 3 x 65mX60 modules could be designed up to 572kton: 3x 65mX80m PMT R&D + detailed study on excavation existing & ongoing + prototype Cherenkov detector MEMPHYNOPMT R&D + detailed study on excavation existing & ongoing + prototype Cherenkov detector MEMPHYNO Underground water Cherenkov detector at Laboratoire Souterrain de Modane Fréjus at 4800 m.w.e.Underground water Cherenkov detector at Laboratoire Souterrain de Modane Fréjus at 4800 m.w.e. Total fiducial volume: up to 400 kton: 3 x 65mX60 modules could be designed up to 572kton: 3x 65mX80mTotal fiducial volume: up to 400 kton: 3 x 65mX60 modules could be designed up to 572kton: 3x 65mX80m PMT R&D + detailed study on excavation existing & ongoing + prototype Cherenkov detector MEMPHYNOPMT R&D + detailed study on excavation existing & ongoing + prototype Cherenkov detector MEMPHYNO

8 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 8 Technological challenge

9 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 9 Target Technology

10 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 10 Target Technology

11 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 11 Horn : Previous Studies Beam and Target Parameter:

12 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 12 Horn: status for WP2

13 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 13 Horn: status for WP2

14 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 14 Horn: Dynamic Stress Analyses due to Thermal and Magnetic pulses Dynamic stresses are due to  Transient Joule heating due to the current passing through the horn’s skin  Secondary Particles  Magnetic Pulses/forces Pulse: 100μs T=1/50/4s=0.08s von Mises stresses due to thermal loads magnetic pressure on the horn stress vs time in the horn, 25pulses static stress deformation

15 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 15 Horn: Static stress, deformation  dynamic stress superimposed on the quasi-static stress are the basis of the fatigue life time estimate of the horn – work ongoing  in order to assess the horn deformation and horn life time, the calculation of the stress inside the horn is necessary. The stress level in the structure should be low enough in comparison with the fatigue limit of the materials. Loads coming from the magnetic pressure and the thermal dilatation of the material 9.9mm10.5mm displacement due to magnetic pressure displacement due to magnetic pressure and thermal dilatation Horn without integrated target horn with integrated target: highly stress domain exists on the inner conductor and in the right angles connection domains + high energy deposition on the inner conductor Horn with separated target and rounded back-plate, corners

16 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 16 Horn: status for WP2 Target Station Baseline : Solid Static targetSolid Static target Use multiple 4 targets+ hornsUse multiple 4 targets+ horns Beam frequency 12.5 HzBeam frequency 12.5 Hz Cooling (EUROnu WP2 Note 10-06)Cooling (EUROnu WP2 Note 10-06) Power distribution due to Joule losses & secondary particlesPower distribution due to Joule losses & secondary particles Energy balance, to maintain working temperatureEnergy balance, to maintain working temperature Flow rateFlow rate Jet distribution along the outer conductorJet distribution along the outer conductor h correlation for jets’ geometryh correlation for jets’ geometry Target Station Baseline : Solid Static targetSolid Static target Use multiple 4 targets+ hornsUse multiple 4 targets+ horns Beam frequency 12.5 HzBeam frequency 12.5 Hz Cooling (EUROnu WP2 Note 10-06)Cooling (EUROnu WP2 Note 10-06) Power distribution due to Joule losses & secondary particlesPower distribution due to Joule losses & secondary particles Energy balance, to maintain working temperatureEnergy balance, to maintain working temperature Flow rateFlow rate Jet distribution along the outer conductorJet distribution along the outer conductor h correlation for jets’ geometryh correlation for jets’ geometry

17 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 17 Feed back from other neutrino beam experiments Striplines plate with soft transition Recommandations from others facilities:Recommandations from others facilities: –Cracks in welds –Use flexible pipes to reduce stress and fatigue –Water leaks due to galvanic corrosion => avoid trapped water and choose material carefully –Use semi flexible conductor because of important magnetic force between stripline => can break cable –Heat dissipation of the stripline –Remote design for repairing/exchange –Need Spares –… Recommandations from others facilities:Recommandations from others facilities: –Cracks in welds –Use flexible pipes to reduce stress and fatigue –Water leaks due to galvanic corrosion => avoid trapped water and choose material carefully –Use semi flexible conductor because of important magnetic force between stripline => can break cable –Heat dissipation of the stripline –Remote design for repairing/exchange –Need Spares –…

18 Safety in the SB Framework

19 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 19 Toward a safety WP2 roadmap

20 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 20 Design Design of the SB line : Proton Driver lineProton Driver line Experimental HallExperimental Hall –MW Target Station –Decay Tunnel –Beam Dump Maintenance RoomMaintenance Room Service GalleryService Gallery –Power supply –Cooling system –Air-Ventilation system Waste AreaWaste Area 20 decay tunnel (25 m) spare area beam target/horn station shielding beam dump horn power supply and electronics gallery hot cell

21 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 21 Safety : Elements MW Target Station : Focusing SystemFocusing System Crane SystemCrane System Automated robotAutomated robot Mechanical structure for the for hornMechanical structure for the for horn Dose Rate Monitoring SystemDose Rate Monitoring System Residual Dose Rate PlateformResidual Dose Rate Plateform Operation under helium AtmosphereOperation under helium Atmosphere –flushing with air –filter to measure radioactive pollution (dust, tritium …) Investigation of other radionucleides transport (environmental constraint)Investigation of other radionucleides transport (environmental constraint) …

22 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 22 Complementary infrastructures *Schematic diagram of the main cooling plant Conceptual design of the SPL II, A high-power superconducting H- linac at CERN – CERN-2006-006 - 12 July 2006 SPL Cooling system : Complementary plants needed for - cooling the 4 horns, decay tunnel and beam dump - cooling the 4 horns, decay tunnel and beam dump - cooling and recirculating helium inside the vessel - cooling and recirculating helium inside the vessel

23 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 23 Complementary infrastructures Conceptual design of the SPL II, A high-power superconducting H- linac at CERN – CERN-2006-006 - 12 July 2006 Electrical infrastructure : Complementary plants needed for the super beam infrastruture - alimentation station for the horns - alimentation station for the horns - air conditioning installation - air conditioning installation

24 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 24 Radiation simulation : shielding investigation Target: - Material: Graphite - Material: Graphite - Cylinder: 130 cm x 4mm (Diameter) - Cylinder: 130 cm x 4mm (Diameter) Shielding for the Target Station : - Walls and roof: 80 cm of Iron, 8 Slabs (2.5m x 2m x10cm) 8 Slabs (2.5m x 2m x10cm) - Lateral and Front Marble Slabs - Front Iron Slab Beam Features (CNGS like): - Proton Energy : 400 GeV/c - Proton Energy : 400 GeV/c - Intensity : 8.0 10 12 pps - Intensity : 8.0 10 12 pps - Irradiation time : 200 days - Irradiation time : 200 days  Evolution of the DER with time performed with FLUKA 2011.2.3 Horn: - Material: Anticorodal 110 - Material: Anticorodal 110

25 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 25 Radiation simulation : shielding investigation DER (mSv/h) after stopping irradiation DER (mSv/h) after 1hour of cooling time DER (mSv/h) after 1day of cooling time DER (mSv/h) after 1month of cooling time

26 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 26 Radiation simulation : shielding investigation Target: - Material: Titanium - Material: Titanium - Cylinder: 78 cm x 1.5mm (Diameter) - Cylinder: 78 cm x 1.5mm (Diameter) Shielding for the Target Station : - Walls and roof: 80 cm of Iron, 8 Slabs (2.5m x 2m x10cm) 8 Slabs (2.5m x 2m x10cm) - Lateral and Front Marble Slabs - Front Iron Slab Beam Features: - Proton Energy : 4,5 GeV/c - Proton Energy : 4,5 GeV/c - Intensity : 18. 10 14 pps - Intensity : 18. 10 14 pps - Irradiation time : 200 days - Irradiation time : 200 days  Evolution of the DER with time performed with FLUKA 2011.2.3 Horn: - Material: Anticorodal 110 - Material: Anticorodal 110 Concrete Iron Marble

27 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 27 Radiation simulation : shielding investigation DER (mSv/h) after stopping irradiation DER (mSv/h) after 1 hour of cooling time DER (mSv/h) after 1 day of cooling time DER (mSv/h) after 1month of cooling time

28 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 28 Radiation simulations : Four Horn Station Four horn station layout Chemical composition of Material: Target => Ti(100%) Horn => Anticorodal 110 alloy Al (95.5%), Si(1,3%), Mg(1,2%), Cr(0.2%), Mn(1%),Fe (0.5%), Zn(0.2%), Cu(0.1%) Al (95.5%), Si(1,3%), Mg(1,2%), Cr(0.2%), Mn(1%), Fe (0.5%), Zn(0.2%), Cu(0.1%) Decay Pipe => Steel P355NH Fe(96.8%), Mn(1.65%), Si(0.5%), Cr(0.3%), Ni(0.3%), C(0.2%) Tunnel => Concrete O(52.9%), Si(33.7%), Ca(4.4%), Al(3,49%), Na(1,6%), Fe(1.4%), K(1,3%), H(1%), Mn(0.2%), C(0.01%) Surrounding Environment => Molasse O(49%), Si(20%), Ca,(9.7%), Al(6.4%), C(5%), Fe(3.9%), Mg(3.2%), K(1%), Na(0.5%), Mn(0.1%)

29 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 29 Simulations : Energy deposition for the Four Horn Station Beam dump energy deposition (kW/cm3) Energy deposition (kW/cm 3 ) in the all layout Energy deposition (kW/cm 3 ) in the all layout Beam dump energy deposition (kW/cm3) Target station energy deposition (kW/cm3) Transverse view Front view Transverse view

30 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 30 Radiation simulations : Four Horn Station Evolution of the target activity with cooling time: Radioactivity after 1 day (Bq.cm -3 ) Radionucleides after 1 day (Z,A)

31 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 31 Radiation simulations : Four Horn Station Evolution of the horn activity with cooling time: Radioactivity after 1 day (Bq.cm -3 ) Radionucleides after 1 day (Z,A)

32 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 32 Radiations simulations : Four Horn Station DER (mSv/h) after 1d of cooling time DER (mSv/h) after 1m of cooling time DER (mSv/h) after 6m of cooling time DER (mSv/h) after 1y of cooling time Evolution of the horn activity with cooling time:

33 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 33 Radiation simulations : All Layout DER (mSv/h) after 1d of cooling time DER (mSv/h) after 1m of cooling time DER (mSv/h) after 6m of cooling time DER (mSv/h) after 1y of cooling time

34 10/06/20111st Euronu Safety Workshop Safety Issues for WP2 34 Radiation simulations : Four Horn Station Next Steps : –Full Design simulation of the installation –Contribution of each element to the dose rate –Individual and collective dose rate calculation with cooling times –Intervention Scenarios (normal operation, maintenance, emergency….) –Costing

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