1 / 27

Booster Cavity: Parametric Study

Booster Cavity: Parametric Study. Mohamed Hassan , Timergali Khabiboulline , Vyacheslav Yakovlev 09/11/2013. Specifications for Design of New Accelerating Cavities for the Fermilab Booster. Fermilab’s Booster Cavity. 2-Tuner. 1-Stem Connection. 3-Gap. 4-Taper.

damisi
Download Presentation

Booster Cavity: Parametric Study

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. Booster Cavity: Parametric Study Mohamed Hassan, TimergaliKhabiboulline , VyacheslavYakovlev 09/11/2013

  2. Specifications for Design of New Accelerating Cavities for the Fermilab Booster

  3. Fermilab’s Booster Cavity 2-Tuner 1-Stem Connection 3-Gap 4-Taper Cavity is divided into four areas to easily identify the cavity parameters Current Cavity dimensions will be marked in red, and all dimensions are in inches

  4. Criteria of Comparison • Criteria of Comparison? • With eigen-mode simulation, the quality factor and energy (not the power) that would produce a required gap voltage could be calculated • Decreasing the energy needed for 55 kV gap voltage (increasing the Q) simply means less power loss inside the cavity thus less heating • These performance indicators will be calculated at two permeability values, namely; 8.4 and 3.0 that corresponds to the edge frequencies of the current booster operation ~Integral Average Simple Average

  5. Stem Connection Parameters Rconn Increasing the radius of the stem conn would help in decreasing the overall power loss inside the cavity

  6. Stem Connection Parameters Cont. Rconn_i Decreasing the radius of the stem inner conductor would help in decreasing the overall power loss inside the cavity

  7. Tuner Parameters Rtunner1 Decreasing the radius of the tuner base radius would help in decreasing the overall power loss inside the cavity

  8. Tuner Parameters Cont. Rtunner2 Decreasing the radius of tuner top radius would help in decreasing the overall power loss inside the cavity, though would decrease the bandwidth quite a bit (sorted out)

  9. Gap Parameters R_Tube_Ring Gap Radius doesn’t have much effect on improving Q

  10. Gap Parameters Cont. Rblend_Tube Gap Radius doesn’t have much effect on improving Q

  11. Taper Parameters Rcone Decreasing Rcone would help in decreasing the overall power loss inside the cavity

  12. Vivaldi Taper Tapercould be approximated as exponential (vivaldiequation) C=-0.04 (closest to current taper) Rconn Rcone Rpipe Lv Ls

  13. Vivaldi Taper Cont. Rpipe=1.125”, Rcone=4.375”, Lv=28.12” Ls=5.5”, Rconn=2” Taper curve eq C=-0.04 C=-0.1 C=0.1 Steeper negative taper would help in decreasing the overall power loss inside the cavity

  14. Vivaldi Taper Cont. Rpipe=1.125”, Rcone=4.375”, Lv=28.12” Ls=1”, Rconn=2.5”, Rtunner1=1” Taper curve eq Rtunner1 Rconn Ls

  15. Vivaldi Taper Cont. Rpipe=1.125”, Rcone=4.375”, Lv=28.12”, Rconn=2.5”, Rtunner1=1” and changing Ls • Steeper negative taper would help in decreasing the overall power loss inside the cavity • However, it would come on the cost of sacrificing the bandwidth

  16. Taper as a Matching Section? Rpipe=1.125 Rcavity=6 Rconn=2 Rconn_i=1 Zc=100Ω Zs=42Ω 14Ω 100Ω 42Ω/3 = 14Ω Three tuners in parallel are connected How to optimally match a 14Ω to 100Ω ?

  17. Taper as a Matching Section Cont.? How to optimally match a 14Ω to 100Ω? Z1(z) Z0 Zl Z=0 Z=L Exponential Taper Klopfenstein Taper Triangular Taper

  18. Taper as a Matching Section? • Standard tapers are used to minimize the mismatch between two impedances over wide frequency band however, we have a different goal

  19. Tuner Ferrites: Other Possibilities • With all stackpole ferrites we project to have about 2 MHz shift upward in frequency band that would necessitates biasing the ferrites less to increase mu by about 15% to recover that frequency shift • Power loss will not decrease!, actually we project about 5% increase in power loss

  20. Bore Radius Effect on the Cavity Performance Rpipe=2.5 Rpipe=1.625 Rpipe=1.125 • Increasing the beam pipe radius has a considerable effect on both the bandwidth and Q factor

  21. Preliminary New Design Ref Cavity Design1 • Sacrifice for 2.4 MHz in bandwidth that will need to be compensated for by biasing less the ferrites • About 30% saving in power loss

  22. Conclusion • Full parametric study have been carried out identifying the potential performance changes upon varying each cavity physical parameter • Preliminary new design is proposed • Better optimization is probably possible but needs more time

  23. Booster Cavity: Proposed Measurements Mohamed Hassan, TimergaliKhabiboulline , VyacheslavYakovlev 09/11/2013

  24. Tuner Stem Temperatures Temperatures are in deg F John Reid

  25. Thermal Profile for Various Scenarios of Operation *Temperature in degC 55 KV, 15Hz 60 KV, 15Hz 55 KV, 7Hz

  26. Simulated Temperature Profile for 55 kV, 15 Hz 55 kV, 15Hz Temperature [deg F] Temperature [deg F] All Copper Only • Under 55kV 15 Hz operation, we project that the highest temperature of copper is about 130 F, while it is about 204 F in Ferrties.

  27. How to get a better comparison? • Run at a fixed frequency • Run without blower (is not included in the model) • Run to reach a steady state heating • Find an accurate way to measure the power loss and temperature • We should be able to compare then three vital quantities; quality factor, power loss, and temperature for a certain gap voltage (perhaps 10 kV, 20 kV) • Need to add as many as possible temperature sensors on each tuner • Repeat the measurements for several frequencies (37 MHz, 45 MHz, and 53 MHz)

More Related