Pulses inside the pulse mode of operation at RF Gun

Similar documents
XFEL High Power RF System Recent Developments

INFN School on Electron Accelerators. RF Power Sources and Distribution

Detailed Design Report

RF considerations for SwissFEL

RF Solutions for Science.

The FLASH objective: SASE between 60 and 13 nm

RF plans for ESS. Morten Jensen. ESLS-RF 2013 Berlin

Pulsed Klystrons for Next Generation Neutron Sources Edward L. Eisen - CPI, Inc. Palo Alto, CA, USA

A HIGH POWER LONG PULSE HIGH EFFICIENCY MULTI BEAM KLYSTRON

RF Power Generation II

DESIGN AND PERFORMANCE OF L-BAND AND S-BAND MULTI BEAM KLYSTRONS

Towards an X-Band Power Source at CERN and a European Structure Test Facility

Klystron Lifetime Management System

Next Linear Collider. The 8-Pack Project. 8-Pack Project. Four 50 MW XL4 X-band klystrons installed on the 8-Pack

L-Band RF R&D. SLAC DOE Review June 15 th, Chris Adolphsen SLAC

CEPC Klystron Development

Nick Walker DESY MAC

Evaluation of Performance, Reliability, and Risk for High Peak Power RF Sources from S-band through X-band for Advanced Accelerator Applications

The PEFP 20-MeV Proton Linear Accelerator

IOT OPERATIONAL EXPERIENCE ON ALICE AND EMMA AT DARESBURY LABORATORY

Low Level RF for PIP-II. Jonathan Edelen LLRF 2017 Workshop (Barcelona) 16 Oct 2017

J/NLC Progress on R1 and R2 Issues. Chris Adolphsen

Research and Development on Superconducting Radio-Frequency Technology for Electron Linear Accelerators. Deliverable

Experience with the Cornell ERL Injector SRF Cryomodule during High Beam Current Operation

3 cerl. 3-1 cerl Overview. 3-2 High-brightness DC Photocathode Gun and Gun Test Beamline

TECHNICAL SPECIFICATION Multi-beam S-band Klystron type BT267

High-power klystrons. The benchmark in scientific research. State-of-the-art RF sources for your accelerator

Status of BESSY II and berlinpro. Wolfgang Anders. Helmholtz-Zentrum Berlin for Materials and Energy (HZB) 20th ESLS-RF Meeting

RUNNING EXPERIENCE OF FZD SRF PHOTOINJECTOR

Status of RF Power and Acceleration of the MAX IV - LINAC

Present Status and Future Upgrade of KEKB Injector Linac

Karin Rathsman. Calculations on the RF Source and Distribution

Empirical Model For ESS Klystron Cathode Voltage

Current status of XFEL/SPring-8 project and SCSS test accelerator

PEP-I1 RF Feedback System Simulation

Solid State Modulators for X-Band Accelerators

The TESLA RF System. S. Choroba. for the TESLA Collaboration. DESY Notkestr. 85, D Hamburg, Germany

CLIC Feasibility Demonstration at CTF3

KEKB INJECTOR LINAC AND UPGRADE FOR SUPERKEKB

Operating Experience and Reliability Improvements on the 5 kw CW Klystron at Jefferson Lab

High Brightness Injector Development and ERL Planning at Cornell. Charlie Sinclair Cornell University Laboratory for Elementary-Particle Physics

Diamond RF Status (RF Activities at Daresbury) Mike Dykes

RF Upgrades & Experience At JLab. Rick Nelson

A New 4MW LHCD System for EAST

STATUS OF THE SWISSFEL C-BAND LINEAR ACCELERATOR

LCLS RF Reference and Control R. Akre Last Update Sector 0 RF and Timing Systems

45 MW, 22.8 GHz Second-Harmonic Multiplier for High-Gradient Tests*

IOT RF Power Sources for Pulsed and CW Linacs

North Damping Ring RF

First Simultaneous Top-up Operation of Three Different Rings in KEK Injector Linac

Design, Fabrication and Testing of Gun-Collector Test Module for 6 MW Peak, 24 kw Average Power, S-Band Klystron

SRS and ERLP developments. Andrew moss

Summary of recent photocathode studies

ILC-LNF TECHNICAL NOTE

The Elettra Storage Ring and Top-Up Operation

TWO BUNCHES WITH NS-SEPARATION WITH LCLS*

Behavior of the TTF2 RF Gun with long pulses and high repetition rates (TESLA note )

POLARIZED LIGHT SOURCES FOR PHOTOCATHODE ELECTRON GUNS AT SLAC?

Photoinjector Laser Operation and Cathode Performance

RF Design of the LCLS Gun C.Limborg, Z.Li, L.Xiao, J.F. Schmerge, D.Dowell, S.Gierman, E.Bong, S.Gilevich February 9, 2005

Design and Simulation of High Power RF Modulated Triode Electron Gun. A. Poursaleh

What can be learned from HERA Experience for ILC Availability

Status of CTF3. G.Geschonke CERN, AB

Development of klystrons with ultimately high - 90% RF power production efficiency

KARA and FLUTE RF Overview/status

2 Work Package and Work Unit descriptions. 2.8 WP8: RF Systems (R. Ruber, Uppsala)

WG2 Group Summary. Chris Adolphsen Terry Garvey Hitoshi Hayano

Technology Challenges for SRF Guns as ERL Sources in View of Rossendorf work

ILC RF System R&D. Chris Adolphsen, SLAC. Section of 1.3 GHz SC Linac. June 29, 2007 PAC07 Talk FRYC01

X-Band Klystron Development at

Status of the X-ray FEL control system at SPring-8

Status of SOLARIS. Paweł Borowiec On behalf of Solaris Team

Agilent 5345A Universal Counter, 500 MHz

reported by T. Shintake KEK / RIKEN Japan Summary of C-band R&D for Linear Collider at KEK New soft-x-ray FEL Project at RIKEN/SPring-8

4.4 Injector Linear Accelerator

P P S - M W S C A N 1 H

The LEP Superconducting RF System

18 GHz, 2.2 kw KLYSTRON GENERATOR GKP 24KP 18GHz WR62 3x400V

14 GHz, 2.2 kw KLYSTRON GENERATOR GKP 22KP 14GHz WR62 3x400V

Karin Rathsman, Håkan Danared and Rihua Zeng. Report from RF Power Source Workshop

Chris Gilmour Studies into the Design of a Higher Efficiency Ku Band ring-loop Travelling Wave Tube SWS using the CST PIC Software.

Basic rules for the design of RF Controls in High Intensity Proton Linacs. Particularities of proton linacs wrt electron linacs

SLAC X-band Technology R&D. Tor Raubenheimer DOE Briefing June 11 th, 2010

Activities on FEL Development and Application at Kyoto University

SRF-gun Development Overview. J. Sekutowicz 17 th September, 2015 SRF15, Whistler, Canada

Implementation of the feed forward correction for the FLASH photo injector laser and future plans for a feedback system

Development of High Power Vacuum Tubes for Accelerators and Plasma Heating

ADVANCED HIGH-POWER MICROWAVE VACUUM ELECTRON DEVICE DEVELOPMENT

Dark current and multipacting trajectories simulations for the RF Photo Gun at PITZ

Design Studies For The LCLS 120 Hz RF Gun Injector

STATUS OF THE SwissFEL C-BAND LINAC

Digital BPMs and Orbit Feedback Systems

Linac upgrade plan using a C-band system for SuperKEKB

TTF / VUV-FEL. Schedule 2005 and Project Management Issues. Schedule 2005 Project Organisation Budget & Controlling

Introduction: CW SRF linac types, requirements and challenges High power RF system architecture

CERN EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCH. A 50 Hz LOW-POWER SOLID-STATE KLYSTRON-MODULATOR

RF Power Klystrons & 20 Year Look. R. Nelson 7/15/15

Results of recent photocathode studies at FLASH. S. Lederer, S. Schreiber DESY. L. Monaco, D. Sertore, P. Michelato INFN Milano LASA

650MHz/800kW Klystron Development at IHEP

The FAIR plinac RF Systems

Transcription:

Pulses inside the pulse mode of operation at RF Gun V. Vogel, V. Ayvazyan, K. Floettmann, D. Lipka, P. Morozov, H. Schlarb, S. Schreiber FLASH Seminar, DESY March 29, 2011

Contents Why we need a PiPmode of operation at RF Gun What we need, to operate FLASH in the PiPmode PiPstudy in August 2009 and in January 2011 Summary and Plans 3/29/2011 V. Vogel FLASH Seminar 2

Why we need a PiPmode at RF GUN dts~ 76 C For PRR=10Hz, Ploss=61.8 kw T iris ~ 72 C > Ts= 119 C ( T pickup ~ 148 C) No way to increase pulse length, no way for quasi CW operation Alternative: SC GUN DC GUN Cold GUN in PiPmode Cold Traveling wave GUN Breakdown & Pulsed Surface Heating Studies: Thermal Fatigue behavior versus Grain Orientation by Markus AICHELER (Ruhr-Universitaet Bochum) 3/29/2011 V. Vogel FLASH Seminar 3

Pulses inside the Pulse mode Laser pulse Power in GUN Klystron RF power 0 1 2 3 4 5 6 7 8 9 1 0 11 1 2 13 1 4 15 1 6 17 1 8 19 2 0 21 2 2 23 2 4 25 26 T im e 3/29/2011 V. Vogel FLASH Seminar 4

What we need, to operate GUN in the PiPmode Design of new SW RF Gun Goal : Keep all of advantages of GUN5 design, but in short pulse Klystron ~10 MW pulse power, ~ 150 KW average power, bandwidth about 3 MHz Modulator Pulse repetition rate ~ few khz Modification of software and electronics 3/29/2011 V. Vogel FLASH Seminar 5

Design of new RF Gun For acceleration of one electron bunch in the GUN, we need 60 M/m only for time at most of 1 ns. GUN 5 Qo= 25000, Ql= ~ 12000, > t= 3 ms. For 60 MV/m -6.2 MW RF PiP GUN 1. Qo= 25000, Ql= ~ 12000, > t= 3 ms. For 60 MV/m (~20 MW RF during fill time) combine power from two klystrons or power multiplier: SLED 2 delay line open cavity 2. Qo= 25000, Ql= ~ 4000, > t= 1 ms. For 60 MV/m 18.6 MW RF For 40 MV/m 8.2 MW RF 3/29/2011 V. Vogel FLASH Seminar 6

We have three types of MBK RF power sources 117kV, 140 A, efficiency > 60% P impulse max 10.5 MW P rfaverage 150 kw P collector average 300 kw P * body with RF (2.8-4.5) kw Bandwidth > 3 MHz U = 118.8kV, I = 129.5A E3736 VKL 8301 TH1802 Thales sn#4 Output power (MW) 10 8 6 4 2 0 Saturation 90% of Saturation 1297 1298 1299 1300 1301 1302 1303 Frequency (MHz) Pout (MW) 10 8 6 4 2 0 1296 1297 1298 1299 1300 1301 1302 1303 1304 Frequency (MHz) Pin =95 W, Saturation Pin = 33 W Pin= 43 W, 90% Power Pout (MW) 10 240W 190W 80W 40W 8 12W 6 4 2 0-10 -5 0 5 10 15 Frequency (MHz) -1300 MHz 3/29/2011 V. Vogel FLASH Seminar 7

Modulator Linear type modulator Direct hard-switch modulator -120kV SLAC, KEK,.. DESY, Diversified Technologies, Inc., Toshiba factory test stand,.. Trise~ 0.4 ms T hv 1.6 4 ms Imax ~ ka PRR ~ khz Low voltage P/S Trise~ 0.6 ms Thv 2.5-10000 ms Imax ~ 200-300A PRR ~ khz High voltage P/S 3/29/2011 V. Vogel FLASH Seminar 8

PiP mode study at FLASH with existing components GOAL offirstrun: Examination of the hardware and software. Optimization of the RF pulse shape. For pulse shape generation an user tables was used In feed-forward mode of operation 3/29/2011 V. Vogel FLASH Seminar 9

pulses inside the pulse mode first test at FLASH 910 us 27.08.2009 12.5 ns ADC Flat top 3 us 9 us 20 us 46 bunches,(50khz), P forward = 4.0MW about 1 hour of operation without any interlock! 3/29/2011 V. Vogel FLASH Seminar 10

Dark current study P klystron 3.7 MW P klystron 4.0 MW 3/29/2011 V. Vogel FLASH Seminar 11

Second run 16/01/2011 GUN mode Normal mode, gun set points: Pf = 3.70, Flattop = 350uS, T window = 43 C 41 pulse, each 10mS, in total RF 800mS New DOOCS panel for PiPmode Table generation (FF,SP, GT) was extended Feedback loop can be closed 3/29/2011 V. Vogel FLASH Seminar 12

Bypass mode FEL mode 3/29/2011 V. Vogel FLASH Seminar 13

Klystron output power: max 5.6MW, min 0.7 MW RF window temperature during test normal mode, 13 kw average power, Pf = 3.7 MW, 370mS PiP mode, 16 kw average power, Pf = 4.2MW, 10/10mS, 680mS Temperature of water for GUN cooling 3/29/2011 V. Vogel FLASH Seminar 14

Outlook With PiPmode in the FLASH on the existing RF GUN we can expect to have: Single beam pulse Two beam pulses, separated on 1000 ms Three beam pulses, separated on 500 ms. Fifty beam pulses, separated on 20 ms In the next FLASH study run, we will continue the PiPmode study: -new software for feedback regulation -optimization of PF pulse shape -long time test -lasing in PiP mode -up to now we don t have a problem with breakdown in the GUN in PiPmode, maybe 10 MW klystron at GUN RF station? 3/29/2011 V. Vogel FLASH Seminar 15

Thank you for attention! welcome for discussion 3/29/2011 V. Vogel FLASH Seminar 16

2024 © artsdocbox.com Privacy Policy | Terms of Service | Feedback