Felix Dietrich | AWLC14 | | Stress simulation in the ILC positron target with ANSYS Felix Dietrich (TH-Wildau), Sabine Riemann, Friedrich Staufenbiel (DESY)
Felix Dietrich | AWLC14 | | page 2 Outline > Alternative source > Goal of the studies > Model > Implementation into ANSYS > Temperature calculation > Results > Summary > Next steps
Felix Dietrich | AWLC14 | | page 3 Alternative source
Felix Dietrich | AWLC14 | | page 4 Goal of the studies > Beam parameters are given ( ~29J/g peak energy > How is the dynamic stress evolving in the target with 300Hz scheme in the tungsten target > Target lifetime depend on static and dynamic stress Energy deposition within fraction of a nanosecond instantaneous temperature rise Reaction of material within milliseconds Stress dynamics > Benchmark: SLC target But SLC number of positrons per second was about 50 times lower than at ILC
Felix Dietrich | AWLC14 | | page 5 Model
Felix Dietrich | AWLC14 | | page 6 Implementation into ANSYS
Felix Dietrich | AWLC14 | | page 7 Temperature calculation > With good mesh, the temperature change resulting from energy deposition by each bunch shows regular behavior with negligible numerical errors
Felix Dietrich | AWLC14 | | page 8 Temperature rise: 1st attempt > The temperature increases per bunch by 1.6K > The graph shows the temperature rise for the first triplet
Felix Dietrich | AWLC14 | | page 9 Results: Stress evolution – Model 2 > The Picture shows the equivalent stress (von- Mises) at diferent positions in the Material > The Picture was taken at: µs (t=5ns first bunch of mini train) > Deformation is scaled by 730 for visualization; max. surface displacement is about 8µm
Felix Dietrich | AWLC14 | | page 10 Result: Short time – Model 2 > Results are calculated for 1µs > Red line shows max. stress at any given point at one time > The other lines are calculated an the center of the disc at different depth (1.4cm equals the surface; 0.9cm equals a depth of 0.5cm)
Felix Dietrich | AWLC14 | | page 11 Result: Conclusion short time > Max. temperature rise by one triplet is T=210°C within ~1 s > Heat dispersion into the target body within microseconds is negligible temperature of the target body is 22°C > Max. stress after one triplet 377MPa > Every mini train adds a different stress load First mini train +225MPa Second mini train +110MPa Third mini train +37MPa > Max. stress by one triplet is below fatigue stress limit 377MPa<520MPa
Felix Dietrich | AWLC14 | | page 12 Results: Long time > First attempt 2 µs pause > Same configuration like the first graph > Results are preliminary
Felix Dietrich | AWLC14 | | page 13 Temperature rise: 2nd attempt > The temperature rises linearly over the whole mini train > That saves computing time
Felix Dietrich | AWLC14 | | page 14 Results for 2nd attemept: Model 1 > Results are calculated for 3µs > Max. stress is about 400MPa > Results are preliminary
Felix Dietrich | AWLC14 | | page 15 Results for 2nd attempt: Model 2 > Results are calculated for 3µs > Max. sress is about 420MPa > Results are preliminary
Felix Dietrich | AWLC14 | | page 16 Summary
Felix Dietrich | AWLC14 | | page 17 Next steps > Simulations of a longer period: Few triplets Include target rotation Check whether interferences of stress waves are possible > Degradation of material is expected due to irradiation evaluation of dynamic load has to be repeated with modified parameters
Felix Dietrich | AWLC14 | | page 18 Addition
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