Institut für Angewandte Physik LINAC AG H. Podlech 1 MYRRHA Injector Design and Related R&D 2 nd Open Collaboration Meeting on Superconducting Linacs for.

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Institut für Angewandte Physik LINAC AG H. Podlech 1 MYRRHA Injector Design and Related R&D 2 nd Open Collaboration Meeting on Superconducting Linacs for High Power Proton Beams (SLHiPP-2) LNS-INFN Catania May 2012 Holger J. Podlech H. Klein, D. Mäder, R. Ratzinger, A. Schempp, R. Tiede, M. Vossberg, C. Zhang Institute for Applied Physics (IAP) University of Frankfurt, Germany

Institut für Angewandte Physik LINAC AG H. Podlech 2 The MYRRHA Proton-Driver

Institut für Angewandte Physik LINAC AG H. Podlech 3 Scheme of the MYRRHA Injector

Institut für Angewandte Physik LINAC AG H. Podlech MHz: Advantages Lower RFQ energy (1.5 MeV vs 3.0 MeV) Use of 4-Rod RFQ (less expensive, less sensitive, lower voltage) Thermal power RFQ: 25 kW/m safe Larger aperture in CH-cavities Total injector length independent of f (almost)

Institut für Angewandte Physik LINAC AG H. Podlech 5 Shunt Impedance of RFQ-Structures MYRRHA

Institut für Angewandte Physik LINAC AG H. Podlech 6 4-Rod-RFQ +Transmission line resonator +Excellent Tuning +Easy acces (tuning, repair) +Proven Technology +Inexpensive +Less sensitive against tolerances -Locally higher power densities

Institut für Angewandte Physik LINAC AG H. Podlech MHz 4-Rod-RFQ Voltage reduced to 40 kV (from MHz) Expected shunt impedance: >67 k m Specific power: 25 kW/m (47 kW/m demonstrated) Length: 4m Total losses: 100 kW RF power with beam (5 mA): 107 kW RF amplifier: kW

Institut für Angewandte Physik LINAC AG H. Podlech 8 Stem Design 176 MHz RFQ

Institut für Angewandte Physik LINAC AG H. Podlech 9 RFQ test cavity for thermal analysis P/L up to 40 kW/m

Institut für Angewandte Physik LINAC AG H. Podlech 10 High Power cw-RFQ 50 kW/m thermal power load (A. Schempp, IAP, A. Bechtold, NTG)

Institut für Angewandte Physik LINAC AG H. Podlech 11 CH-Cavities CH-Structure Crossbar-H-Mode-Structure rt or sc multi-cell cavity KONUS or EQUUS Beam Dynamics

Institut für Angewandte Physik LINAC AG H. Podlech 12 rt CH cavities Dominik Mäder

Institut für Angewandte Physik LINAC AG H. Podlech 13 MAX CH-Prototype (rt)

Institut für Angewandte Physik LINAC AG H. Podlech 14 Parameters MAX CH-Prototype (rt) ParameterUnitValue RF Structure---CH FrequencyMHz175 Duty cycle%100 Length (inner)mm382.5 Diametermm674.6 Aperture diametermm24 Effective voltagekV325 Q-value (90% MWS) Z eff (90% MWS) M /m 70 PcPc kW5 P maxkW12 P/L maxkW/m40

Institut für Angewandte Physik LINAC AG H. Podlech 15 RT Part: Comparison RF Power

Institut für Angewandte Physik LINAC AG H. Podlech 16 Code Benchmarking (LORASR-WINTRACE) LORASR WINTRACE

Institut für Angewandte Physik LINAC AG H. Podlech 17 MYRRHA sc CH cavities CH3 CH4 CH5 CH6 First CH (sc) prototype

Institut für Angewandte Physik LINAC AG H. Podlech 18 Field Distribution – Gap voltage 1. sc CH-cavity

Institut für Angewandte Physik LINAC AG H. Podlech 19 Bellow Tuner Static Tuners Helium VesselCoupler Flanges 325 MHz CH-Prototype Praparation Flanges Frequency (MHz) Cells7 Length -def (mm) 505 Diameter (mm)348 E a (MV/m)5 E p /E a 5.1 B p /E a [mT/(MV/m)]13 G ( ) 64 R a /Q 0 ( ) 1248 R a R s ( 2 ) 80000

Institut für Angewandte Physik LINAC AG H. Podlech 20 Strategy to Hit the Frequency Bad circumstances:Countermeasures: fabrication inaccuracy (Δf = ? MHz) thermal shrinkage (Δf +450 kHz) pressure sensitivity (Δf +200 kHz) surface preparation (Δf = ? kHz) underground noise (Δf = ± 50 Hz) helium bubbles tank / end cell offset 10 mm (Δf ±1 MHz) static tuners (Δf +1.3 MHz, -2.2 MHz) slow bellow tuners (Δf ±250 kHz) fast bellow tuner (Δf ± 700 Hz)

Institut für Angewandte Physik LINAC AG H. Podlech 21 Cavity Fabrication

Institut für Angewandte Physik LINAC AG H. Podlech 22 Cavity Fabrication

Institut für Angewandte Physik LINAC AG H. Podlech MHz CH-Prototype

Institut für Angewandte Physik LINAC AG H. Podlech MHz CH-Prototype

Institut für Angewandte Physik LINAC AG H. Podlech MHz CH-Prototype: First Measurements

Institut für Angewandte Physik LINAC AG H. Podlech MHz CH-Prototype: First Measurements Design Position Deviation from Design frequency: 500 kHz < 0.2%

Institut für Angewandte Physik LINAC AG H. Podlech 27 f=217 MHz A/q<6.5 9 sc CH-cavities E a =5 MV/m U tot =35 MV Sc Solenoids (8T) Future GSI/FAIR Injector Complex cw Linac I

Institut für Angewandte Physik LINAC AG H. Podlech 28 ParameterUnitCH-1 Beta0.059 FrequencyMHz Gap number15 Total lengthmm687 Cavity diametermm409 Cell lengthmm40.82 Aperturemm20 UaUa MV3.369 Energy gainMeV2.97 Accelerating gradientMV/ m5.1 E p / E a 6.4 B p / E a mT/ (MV/m)5.4 R/ Q Ω 3320 Static tuner9 Dynamic bellow tuner3 Main parameters of the 217 MHz CH-structure cw SHE-Linac Demonstrator 3D-view of the 217 Mhz cavity with helium vessel, without tuners Helium vessel Coupler flange Pickup flange Inclined end stem Tuner flange Preparation flange Cavity construction has started April 2012

Institut für Angewandte Physik LINAC AG H. Podlech 29 cw Linac Demonstrator CH-cavity Cryo module sc solenoids First sc CH-cavity will be tested with beam at GSI =0.059, f=217 MHz, 15 cells RF power 5 kW (10 kW) Cryo module and sc solenoids ordered

Institut für Angewandte Physik LINAC AG H. Podlech 30 Clean room 100/10000 Vertical cryostats (400mm, 600mm, 900mm diameter) Horizontal cryostats Amplifiers Refrigerator And everything you need for cavity testing Infrastructure at IAP Frankfurt Linde L140 liquifier, 90 l 4K

Institut für Angewandte Physik LINAC AG H. Podlech 31 Amplifiers 175 MHz, 300 kW, cw 175 MHz, 12 kW, cw 108 MHz, 100 kW, 10% 87.5 MHz, 18 kW, cw 217 MHz, 5 kW, cw MHz, 2 kW, cw 325 MHz, 40 kW, 1% MHz, 500 W, cw

Institut für Angewandte Physik LINAC AG H. Podlech 32 Next Steps Tests of rt CH-cavity (RF+Beam) Tests of sc CH-cavities (RF+Beam) Coupler Test Stand Test of RFQ-Protoype (RF) Design of Cryomodule Construction and Test of 4-Rod RFQ (RF+Beam)

Institut für Angewandte Physik LINAC AG H. Podlech 33 Summary Frequency of MYRRHA Injector changed from 352 to 176 MHz 4-Rod RFQ 1.5 MeV 2 rt CH-cavities as booster ( MeV) 4 sc CH-cavities for main acceleration ( MeV) For required reliability two injectors are foreseen Prototypes will be tested with beam