Minutes RF structure meeting 14.11.2008

M. Schuh, M. Vretenar, G. DeMichele, S. Ramberger, R. Wegner, N. Alharbi

DTL

  • First measurment results:
    • TM010 found at 352 MHz without waveguide couplers
    • first Q measurements with TM010 at only ~8500 (half drift tubes are made of aluminium, no RF contact in half drift tubes)
    • with post couplers: measured E0, a flat field is found at certain post-coupler lengths
    • First bead-pull measurment results (GiovanniDeMichele)
    • all futher measurement results can be found here
  • avoid to adjust field with post couplers due to higher load on coupler and lower Q
  • to do measurements without post couplers: moving only tuners to adjust field (see presentation from SNS)
  • in order to improve the Q factor, half drift tubes in the end-caps should be welded in; for Q factor measurements additional end-plates with copper plated half drift tubes may be envisaged
  • for power measurements water cooled end-caps are required
  • perform high power test (LINAC4 duty cycle) without post couplers at CERN:
    • Measure X-Rays ( action: contact safety staff) to estimate field levels
    • test with magnets in drifttube
  • SPL duty cycle as 2nd priority, there might be heat problems with the actual setup and a irreversible deformation should be avoided

PIMS, thermal drifts

  • during operation with SPL duty cycle, PIMS modules will heat up considerably, the frequency will decrease of about 200kHz (worst case)
  • if for any reason, one cell will get a small frequency offset, the power distribution within a PIMS module will change in a direction that will amplify this frequency offset and again the power distribution will change. Is this a drift (convergence) or an instability (divergence)?
  • the strongest effect will occur for a frequency offset in one end cell. So assuming an initial frequency offset of df0 = +10 kHz in one end cell,
  • the power in this cell will fall down to p1 = 99.2% of the nominal power level (more power will be dissipated in the other cells, the total power level is assumed to be constant all the time)
  • as the power of the end cell is reduced, it cools, shrinks and its frequency increases further, in numbers, to df1 = +11.57 kHz
  • again the power drops, to $p_2=98.95\% $ and the frequency increases to df2 = +12.09kHz
  • after the nth iteration, the frequency offset will be $df_n=df_0\cdot(1+q+q^2+q^3+...+q^n)$ with $q\sim0.20$ in the case of the PIMS hot prototype
  • as q<1, we have convergence and the final frequency offset is $ df_{inf}=df_0/(1-q)\sim df_0\cdot1.244 $. Plot thermal drift df
  • curves show the relation between the initial frequency offset and the final frequency offset for each of the 7 PIMS cells. Furthermore, the Tilt sensitivity and max-min/mean voltage errors including the discussed drift effects are given for frequency offsets in each cell. Plot thermal drift Verr -- (RolfWegner)

-- MarcelSchuh - 20 Nov 2008

Attachments Attachments
Topic attachments
I Attachment History Action Size DateSorted ascending Who Comment
PDFpdf First_bead-pull_DTL.pdf r1 manage 185.2 K 2008-11-20 - 10:43 MarcelSchuh  
Unknown file formateps thermal_drifts_Verr.eps r1 manage 21.3 K 2008-11-20 - 10:47 MarcelSchuh Plot thermal drift Verr
Unknown file formateps thermal_drifts_df.eps r1 manage 21.3 K 2008-11-20 - 10:46 MarcelSchuh Plot thermal drift df
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Topic revision: r4 - 2008-11-21 - SuitbertRamberger
 
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