280 likes | 459 Views
Status of HIPPI/WP3 developments at CEA/Saclay. Cavity “B” design Coupler design Power source Test stand Schedule. G. Devanz. RF design. Based on ASH b 0.47 design Design frequency 704.4 MHz. asymmetric. symmetric. RF design. RF design. Static Lorentz Detuning (1).
E N D
Status of HIPPI/WP3 developments at CEA/Saclay • Cavity “B” design • Coupler design • Power source • Test stand • Schedule G. Devanz
RF design Based on ASH b 0.47 design Design frequency 704.4 MHz asymmetric symmetric
Static Lorentz Detuning (1) Fixed ends, no rings
Static Lorentz Detuning (2) Fixed ends, Nb thickness = 4 mm, rings When stiffeners are added on tube |k| drops below 3 Hz/(MV/m)², the optimal ring radius is unchanged, but …
Static Lorentz Detuning (3) With a more realistic thinner weld region : Fixed ends Nb thickness = 4 mm
Static Lorentz Detuning (4) Big changes arise when an external stiffness (tuner+ He tank) is taken into account Free ends Limit ~ 50 Fixed ends Limit ~ 3.6 Cavity stiffness
Manageable zone Static Lorentz Detuning (5) We are aiming at an external stiffness in 50 to 100 kN/mm
Static Lorentz Detuning (6) Example of the cavity A test at Saclay: effect of the low frame stiffness • CASTEM computation with a simplified model of the frame: Low stiffness of 2.4 kN/mm due to buckling • Data from pressure sensitivity measurement : frame stiffness ~ 1 kN/mm • intrinsic K is -3.7 Hz/(MV/m2), effective K is ranging from -20 to -35 Hz/(MV/m2) • Cross-check with INFN for K calculation (ANSYS) OK
Dynamic Lorentz Detuning (1) Computation of Lorentz coefficients for each mechanical mode: • Compute Mechanical modes with given B.C. (CASTEM code from CEA) and built a modal basis • Provide radiation pressure distribution on cavity surface (FISH) • Project on modal basis • Compute the cavity response to harmonic modulation in time domain for each mode. Assume a given damping coefficient for each mode ; wait for steady state • Compute the time dependant detuning of the cavity in steady state before : Superfish runs (many of them) now: Slater directly on the FEM mesh by external code coupled to CASTEM Most of the calculation are done with these conditions • cavity ends are not fixed : A given external stiffness of 70 kN/mm is assumed • Mechanical Qs are 50 or 100
Dynamic Lorentz Detuning (2) Example : optimisation of the radius of the second family of ring R2 = 90 R2 = 100 R2 = 110 At lower frequencies, the R2 = 110 case (blue) is better : lower ks and higher frequencies for a given mechanical mode
Dynamic Lorentz Detuning (3) Other methods provide more information on the cavity behavior : impulse response and step response Step response 1ring / 2rings
Dynamic Lorentz Detuning (4) Scan of the Lorentz force modulation frequency Transfer function What happens if the cavity is symmetric ? Only 1 mode is relevant for LFD below 500 Hz with a symmetric cavity ! Value @ 0 Hz is the static | K | Mode 1 of asym. Mode 1 of sym.
Piezo tuner (preliminary) The harmonic scan method can be applied to a piezo-like element Warning : not normalized “Piezo” amplitude ~ 0.5 micron in this simulation Harmonic force, not harmonic displacement !
Mechanics Regulations the cavity must sustain twice the maximum pressure Max Pressure = 1.3 bar during test in vertical cryostat -> Preg = 2.6 bars Structural FEM calculations with fixed ends Sym + 1 familly of rings : max stress on beam tube iris 90 MPa Previous + stiffeners on beam tube iris : max stress around ring /cell junction 70 Mpa and 50 Mpa @ equator weld With second set of rings: max stress @ stiffener/outer cell junction 40 MPa stress @ equator 29 MPa
Tuning *assuming sy = 40 MPa
Conclusion on cavity • The best choice is a symmetric cavity with 2 series of rings • Dynamic behavior is more simple • Compared to asymmetric, RF performance is only slightly degraded • The second ring series is useful against Lorentz force detuning and strengthen the cavity w/ respect to external pressure Elliptical cavity ‘B’ with 2 sets of stiffening rings Equipped with cold tuning system (prelim. design) Helium tank with power coupler port & stiffening wings
Schedule for cavity B Mechanical drawings ready Niobium order placed in August ‘05 (avail. in Dec. ‘05) Cavity order to be placed in November 2005 Fabrication (around 8 months) cavity B ready for June 2006
Coupler Coupler architecture • Some proposed designs for SPL require peak powers exceeding 1 MW. The coupler should be specified with at least 1MW peak, 10 % duty cycle • HIPPI RF source will reach 1MW peak power • KEK/SNS type : coaxial warm window + He cooled coaxial part • We have developped a window at 700 MHz with IPN based on KEK/Toshiba design
Coupler – window (1) Matching calculations (HFSS) Starting from SNS geometry 100 mm diameter, 50 W E H S11
Coupler – window (2) 2 prototypes build by Toshiba
Coupler (2) Thermal calculations • Thermo-mechanical model for the window ready (HFSS fields + CASTEM ) • Currently building a thermal model for the coaxial part Coupling calculations (HFSS) • Qext of 106 with a f=130 mm beam pipe is obtained with flush antenna • The coupling port location on the tube depends on the He tank side and stiffeners design. Multipactor simulations (MUPAC) for the coaxial part • TW and SW on 80 and 100 mm diameter 50 W coaxial lines
Coupler MP TW 80 mm most stable barriers TW 100 mm most stable barriers TW 80-100 mm most stable barriers Lower power range SW 80-100 mm most stable barriers For all conditions, 100 mm behaves better
Schedule for coupler Coupler: Mechanical drawings ready for Feb. 06 Order placed in June 06 Fabrication (10 Months) : coupler ready for March 2007
Power source Klystron 704 MHz & 1.0 MW peak – 2 ms – 50 Hz (max. HT cathode = 95 kV) • Order placed in July ’05 • Fabrication : 16 months • Circulator 704 MHz & 1.0 MW peak & 100 kW average • Order placed in August ’05 • Fabrication : 8 months HV generator upgrade • Design of the HV tank : April - Dec. 2005 • Supply of mechanical and electrical components : May ‘06 • Order of the HV (110kV - 2.5 A) power supply in Nov. ‘06 • Fabrication of the HV power supply around 9 months • Modification of HV tank and cabling : June – Oct. 2006 Goal : elements at Saclay for Dec. ‘06
Test Stand What still has to be done (from now to end of 2006): • Study of the implantation • Order of the missing WGs (we already have the power loads & bi-directional couplers) • Building of electronic racks (interlocks, diagnostics) • Preparation of the test area (cabling, water cooling, …) • Preparation of the acquisition/control system (already existing for tests at frep=1Hz) Test of the (HV generator + klystron): January 2007 Conditioning of power coupler(s): June 2007 We also have to move all our equipments to a new building in 2006 (liquefier, compressor, vertical and horizontal cryostats, RF power sources, …)