High Intensity Beam Test of Beryllium for Target and Beam Window Applications Presented by: Brian Hartsell Contributors: Kavin Ammigan, Patrick Hurh NBI.

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Presentation transcript:

High Intensity Beam Test of Beryllium for Target and Beam Window Applications Presented by: Brian Hartsell Contributors: Kavin Ammigan, Patrick Hurh NBI 2012

Why Beryllium?  Graphite radiation damage issues caused LBNE to look at Beryllium for target use.  Complete structural failure at p/cm 2 during BLIP run.  Simulations with beryllium components do not seem to line up with the ‘real world’. Beryllium for Target and Beam Window Applications 2

Beryllium tests and past uses at FNAL  Beam windows  Pbar Lithium lens windows  Possible damage seen at 0.15mm sigma spot size, no damage at 0.19mm sigma. Beryllium for Target and Beam Window Applications 3

Beryllium test  1999 testing of NuMI prototype target  Beam sigmas of 0.16mm, 0.22mm in x,y at 120GeV  180 pulses, 1.03e13 POT/pulse, 10us pulse  Each fin is approx 2mm x 6mm x 25mm Beryllium for Target and Beam Window Applications 4 Be Fins Upstream Graphite Fins DS

1999 NuMI Test – Physical Inspection  Light microscope images show ‘dark spot’ on first fin, upstream side.  No marks on other upstream or downstream faces. Beryllium for Target and Beam Window Applications 5

1999 NuMI Test – Physical Inspection  SEM images of the spot (left).  Also found another spot (right) with similar discoloration. Beryllium for Target and Beam Window Applications 6

1999 NuMI Test – Modeling Beryllium for Target and Beam Window Applications 7

Output from MARS and Python Script  Parse MARS output for energy deposition values.  Build a list of locations and corresponding EDep.  Generate ANSYS input tables and plots for verification. Beryllium for Target and Beam Window Applications 8

ANSYS Beryllium Material Properties  Temperature dependent material properties used up to 600°C.  Bilinear Kinematic Hardening Beryllium for Target and Beam Window Applications 9

1999 NuMI Test – ANSYS Thermal Modeling  Temperature from MARS energy deposition results  Maximum temperature approximately 560°C.  Let fin cool to 20°C before next pulse. Times are not ‘real’. Beryllium for Target and Beam Window Applications 10

1999 NuMI Test - Modeling  Maximum principal stress – typical views  Deformations shown at ~50x  Bulge is ~5µm high, 1mm in diameter after 16 pulses. Beryllium for Target and Beam Window Applications 11 End of pulse – 560°C

1999 NuMI Test - Modeling  Maximum principal stress – typical views Beryllium for Target and Beam Window Applications 12 After cooldown to 22°C Large tensile preload for next pulse

1999 NuMI Test - Modeling  Plastic strain – at end of 1 st pulse Beryllium for Target and Beam Window Applications 13

1999 NuMI Test - Modeling  Estimates of life from plastic strain cycling:  Very conservative estimates from Coffin-Manson relation Beryllium for Target and Beam Window Applications 14 Point of max displacement >1M pulses Max plastic strain on surface: 18k pulses Center of fin at beam center: 14k pulses Global maximum plastic strain: 10k pulses

What’s wrong here?  Other Beryllium components have seen comparable beam for many more than 14,000 pulses without failure.  Is thickness a factor?  Modeled a thin Be window (.5mm) and compared to a thick window (5mm used on Li lens).  Thin windows no not appear to fare better. Beryllium for Target and Beam Window Applications 15

Areas for improvement  Beryllium material properties  Strain rate dependency with temperature effects.  Incorporating radiation damage  Lithium lens saw ~10M pulses, corresponds to 1DPA in beam center.  Move to explicit dynamic simulation package  LS-DYNA, AUTODYN, etc  Accurate failure mechanism  Need more data points with failures of Beryllium.  Any beryllium failures from audience? Beryllium for Target and Beam Window Applications 16

Going forward  Expand the NuMI test simulation to find number of pulses until plastic strain remains consistent.  Sensitivity studies for NuMI test simulation:  Beam location, spot size, beam profile (gaussian, flat top, etc), fin geometry, simulation mesh size  Look into the possible beryllium window failure in lithium lens.  Ultimate goal:  Reliable prediction of Beryllium failure given beam parameters and geometry. Beryllium for Target and Beam Window Applications 17

Thank you! Beryllium for Target and Beam Window Applications 18

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