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Areal RF Station

Areal RF Station. A. Vardanyan 19.09.2012. RF System. The AREAL RF system will consist of 3 RF stations: Each RF station has a 1 klystron, and HV modulator, a low-level RF system, preamplifier and an interlock and control system. 1 station required for RF Gun

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Areal RF Station

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  1. Areal RF Station A. Vardanyan 19.09.2012

  2. RF System • The AREAL RF system will consist of 3 RF stations: • Each RF station has a 1 klystron, and HV modulator, a low-level RF system, preamplifier and an interlock and control system. • 1 station required for RF Gun • 2 stations for 1m long accelerating sections operation • LLRF systems which controls the amplitude and the phase of the RF • RF power 7 MW in peak at 3 GHz • Interlock and control system.

  3. The required operation parameters • Peak power 6 MW • Gradient 17 MV/m • RF pulse duration 1-2 µs • Repetition rate 1-2 Hz

  4. RF Power Source • Frequency 3 GHz • RF Pulse Duration 1-2 µs • Repetition Rate 1-2 Hz • Cathode Voltage 190 - 200 kV • Beam Current 95 - 105A • HV Pulse Duration 1-2 µs • RF Peak Power 7 MW

  5. K211 Klystron parameters • Output Power peak 7 MW • Efficiency 40 % • Gain (min. dB) 31 • Beam voltage 200 KV • Beam peak current 92A

  6. KY211 klystron main parameters • Water and Air Cooling For Operat. Rate (50Hz) • Water flow to body 3.64 l/min min • Water flow to collector 20.5 l/min min • Resistance of cooling water 50 kOhm cm min • Air flow to output window 85 l/min min • Cooling Air pressure 2.1 kg/cm2min

  7. Gain in dB KY211 klystron main parameters Peak RF Output Power in MW Peak RF Input Power in kW

  8. Low level radio frequency control Characteristics of Signal/Probes: • Phase stability 0.1 deg@3GHz • Amplitude stability 0.1% • Amplitude dynamic range 30 dB • Ready to be integrated into the EPICS control system The LLRF system ordered by I-Tech LIBERA.

  9. RF control System Requirements for the RF control system • Phase and amplitude stability of the accelerating field during 2 µs flat-top RF pulse. • field amplitude control 0.1% • Phase control 0.1° • A frequency and phase stable master oscillator for RF reference signals to measure the cavity fields. The RF control system will provide • remote control for all RF components, • to enable the change of the necessary parameters such as waveguide tuners, phase shifters, etc.

  10. Master Oscillator The Master oscillator designed by InWave AG according to our requirements. • Frequency ports: • 1x 1Hz 1x 9MHz • 1x 2Hz 1x 81MHz • 1x 9MHz 1x 250MHz • 1x 81MHz 2x 90MHz • 1x 125MHz 2x 10MHz (Secondary) • 1x 250MHz 1x 10MHz (main) • 2x 500MHz • 1x 1GHz • 2x 3GHz

  11. The measurement results The picture describes RMS phase Jitter 6.47 fsec !

  12. Location of RF equipment in AREAL building

  13. RF Test stand • Modulator (HV pulse power source) • HV pulse modulator • 1:18,2 pulse transformer in an oil tank. • The nominal pulse duration is 2 µs. • Requirements to the flat top ripple • should not exceed ±1%. • The pulse-to-pulse stability better than ±0.5%.

  14. RF Test stand Modulator Measurements Amplitude flatnes ~ 1.2%

  15. RF Test stand > 200 kV Modulator Measurements

  16. Test Stand Klystron Start Stage 1 Move to tunnel, Measurements Today Interlock Testing Mounting & Testing Integration wit other subsistems Klystrons & Oil tank Preparation works Prep. Klystron start PFN Tuning LLRF test LLRF Impl. 8/Oct Purchase & delivery 12/Nov Modulator & Preamplifier Preparation works 18/Aug 15/Oct 26/Oct 5/Nov Mar Apr May Jun Jul Aug Sep Oct Nov Dec

  17. Klystron Start Preparation Works Stage 1 Today RF Station Ready Modulator & Preamplifier Preparation works Klystron START without LLRF LLRF Impl. Measurement of Klystron Working Parameters for FF table (Gain, saturation, etc…) • Move to tunnel • Mounting & Testing • Interlock Testing • . • . • . • . • . • Measurements Integration wit other subsystems Cooling Vacuum Radiation Safety Interlock Integration Prep. Klystron start Klystron Mounting & Testing PFN Tuning, Power Supply , Cathode conditioning, Shielding, Cabling, Preamplifier HV ON LLRF test Adjusting PFN Coil with real Load Klystron resonator measurement for optimal Temperature Ordering VNA Cables and Calibration Unit Ordering missing parts Interlock Testing 8/Oct Oil tank ready Waveguides delivery 17/Dec 15/Oct 26/Oct 5/Nov 12/Nov 26/Nov 8/Oct 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 1 Sep Oct Nov Dec Jan

  18. RF Test stand • The wave impedance of the cable must match the impedance of the klystron transformers primary side to avoid distortion of the pulse shape. To achieve that it is supposed to use 7 cables in parallel, each of 18 mm2 cross section, 37Ω impedance, and an outer diameter of 20 mm. • 4 power supplies are required to enable the operation of the klystron and the modulator, the klystron focusing solenoid, the klystron filament, vacuum pump and the Interlock. • The interlock system protects the accelerator and the RF stations. Besides the modulator interlock system, an additional digital interlock system for the RF system is required. • It will be based on programmable logic devices which can be easily modified upon necessity. • The Digital Interlock System will be implemented after the LINAC first stage completion.

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