Presentation is loading. Please wait.

Presentation is loading. Please wait.

PETS components and waveguide connections CLIC Workshop 2007 David Carrillo.

Published byMarilyn Aven Modified over 9 years ago

Similar presentations

Presentation on theme: "PETS components and waveguide connections CLIC Workshop 2007 David Carrillo."— Presentation transcript:

1 PETS components and waveguide connections CLIC Workshop 2007 David Carrillo

2 David Carrillo CIEMAT Index A design to connect PETS with accelerating structures will be discussed choke flange And also we will deal with two components for testing the PETS Input coupler Single test bar device

3 David Carrillo CIEMAT Choke flange X-band This device allows power transmission without electrical contact between waveguides Motivation: During the CLIC operation the two linacs (drive and main) will have independent alignment. That is why the development of the special device which transfer power without mechanical contact from PETS to accelerating structures is important Schematic layout of independent alignment of the two linacs with the fixed RF phase

4 David Carrillo CIEMAT 3D solid view of quarter of choke flange Choke flange It consists of a transition from rectangular to circular waveguide In between there is a choke that stop electromagnetic energy to flow outwards and provide full transmission of energy to the other port This device is flexible and provides a place to produce vacuum inside the waveguide Being equipped with outside bellow it will provide the range of the possible transverse orientations of the two waveguides

5 David Carrillo CIEMAT Choke flange S11(blue) and radiation modes (dB) Frequency (GHz) Electric field complex magnitude It is necessary to minimize reflection and radiation through the choke. Also there is a compromise between length and E field on the surface. Device has been designed as short as possible E magnitude It will be tested at SLAC at nominal power of 135/2 MW (E field on surface < 30 MV/m

6 David Carrillo CIEMAT X-shift Frequency (GHz) S11 (dB) 0.2 0.5 mm 0.0 0.3 mm Choke flange. Shifts & twist z x y Coordinate axis Shifts in different directions and twists are simulated in order to study the device performance x-shift appears to be the most critical displacement issue

7 David Carrillo CIEMAT Z-shift 0.5 mm -0.5 mm S11 (dB) Y-shift Frequency (GHz) 0.5 mm S11 (dB) Dynamic range for the accepted performance (S11< -45 dB) X – shift: ± 0.25 mm Y – shift: ± 0.5 mm Z – shift: ± 0.5 mm Twist: < 5 0 x, y shifts do not change the transmitted RF phase Choke flange. Shifts & twist Twist 5050 3030 Frequency (GHz)

8 David Carrillo CIEMAT Mode launcher Inside the PETS, electrons are decelerated and they produce mode TM 01. In order to measure PETS RF quality this mode must be put into the PETS by the mode launcher (coupler) The input signal is the fundamental one (TE 10 mode) in the rectangular waveguide which is transformed into the TM 01 (not fundamental) in the circular waveguide

9 David Carrillo CIEMAT Mode launcher It is designed for low power tests Not only reflection must be minimized but also transmission to TE 11 Electric field complex magnitude S 11 S12 (TE 11 ) Frequency (GHz)

10 David Carrillo CIEMAT Two couplers will be built to provide low power RF measurements The number of measures will be done: – Test the couplers themselves – Measure S parameters with extractor/or both couplers – Measure phase-advance between PETS cells Mode launcher PETS Power Extractor Mode launcher

11 David Carrillo CIEMAT Testing single PETS bar A device has been designed to do RF tests of the single PETS bar It consists of two side blocks that will be put together with a single PETS bar in order to create inside a mode (TE 10 ) with same phase advance, v g, etc as the decelerating mode (TM 01 ) PETS Single bar Phase/period=90 Frequency =11.994 GHz Vg/c=0.466 Mode TE 10

12 David Carrillo CIEMAT Testing single PETS bar wr90 taper PETS bar + 2 side blocks Full assembly simulation

13 David Carrillo CIEMAT Testing single PETS bar Without this device, all single bars must be put together (8 bars), and it can only be measured performance of the whole PETS as can be seen in the following picture With the single test bar device, a defective bar could be found (if we ever get one ) It would be possible as well to know specifically which is wrong with the bar (matching cells, shape profile, etc)

14 David Carrillo CIEMAT Conclusions A Choke flange design has been done, which will allow a flexible connection between PETS and accelerating structures and also will provide a vacuum port Single bar test device will allow us to measure RF quality of single bars before putting all together Mode launcher designed will be used to introduce and extract power in order to test phase-shift and S parameters for PETS

Download ppt "PETS components and waveguide connections CLIC Workshop 2007 David Carrillo."

Similar presentations

Single-Cell Standing Wave Structures: Design

Single-Cell Standing Wave Structures: Design
5th Collaboration Meeting on X-band Accelerator Structure Design and Test Program. May 2011 Review of waveguide components development for CLIC I. Syratchev,

5th Collaboration Meeting on X-band Accelerator Structure Design and Test Program. May 2011 Review of waveguide components development for CLIC I. Syratchev,
SLAC workshop 7-10 July 2009 WP1: microwave based accelerators Status of CLIC X-band high-power components G. Riddone, 08.07.2009 (contribution from A.

SLAC workshop 7-10 July 2009 WP1: microwave based accelerators Status of CLIC X-band high-power components G. Riddone, (contribution from A.
Time Varying Structural Behaviour of the PETS “On-Off” mechanism piston movement impact Riku Raatikainen 18.7.2011.

Time Varying Structural Behaviour of the PETS “On-Off” mechanism piston movement impact Riku Raatikainen
Development of an X-band Dielectric PETS C. Jing, Euclid Techlabs / ANL HG Workshop, May. 2011.

Development of an X-band Dielectric PETS C. Jing, Euclid Techlabs / ANL HG Workshop, May
Design of Standing-Wave Accelerator Structure

Design of Standing-Wave Accelerator Structure
Different mechanisms and scenarios for the local RF

Different mechanisms and scenarios for the local RF
8/24/2015Pengda Gu, Structure Meeting Study on 30GHz Pulse Compressor 1.Simulation of a multi-cavity RF pulse compressor using a coupled resonator model.

8/24/2015Pengda Gu, Structure Meeting Study on 30GHz Pulse Compressor 1.Simulation of a multi-cavity RF pulse compressor using a coupled resonator model.
CLIC Drive Beam Linac Rolf Wegner. Outline Introduction: CLIC Drive Beam Concept Drive Beam Modules (modulator, klystron, accelerating structure) Optimisation.

CLIC Drive Beam Linac Rolf Wegner. Outline Introduction: CLIC Drive Beam Concept Drive Beam Modules (modulator, klystron, accelerating structure) Optimisation.
CIEMAT CONTRIBUTION TO TBL PETS (January 2009) David Carrillo on behalf of the Accelerators Team.

CIEMAT CONTRIBUTION TO TBL PETS (January 2009) David Carrillo on behalf of the Accelerators Team.
HIGH RF POWER TESTING FOR THE CLIC PETS - 2010 International Workshop on Linear Colliders 20 th October 2010 Alessandro Cappelletti for the CLIC team with.

HIGH RF POWER TESTING FOR THE CLIC PETS International Workshop on Linear Colliders 20 th October 2010 Alessandro Cappelletti for the CLIC team with.
RF COMPONENTS USING OVER-MODED RECTANGULAR WAVEGUIDES FOR THE NEXT LINEAR COLLIDER MULTI- MODED DELAY LINE RF DISTRIBUTION SYSTEM S. G. Tantawi, N. M.

RF COMPONENTS USING OVER-MODED RECTANGULAR WAVEGUIDES FOR THE NEXT LINEAR COLLIDER MULTI- MODED DELAY LINE RF DISTRIBUTION SYSTEM S. G. Tantawi, N. M.
ENGINEERING DESIGN AND FABRICATION OF PETS V. Soldatov¹, D. Gudkov¹, I. Syratchev², A. Samoshkin¹, G. Riddone², A. Olyunin¹, S. Atieh² 1 – JINR, Dubna,

ENGINEERING DESIGN AND FABRICATION OF PETS V. Soldatov¹, D. Gudkov¹, I. Syratchev², A. Samoshkin¹, G. Riddone², A. Olyunin¹, S. Atieh² 1 – JINR, Dubna,
7.8GHz Dielectric Loaded High Power Generation And Extraction F. Gao, M. E. Conde, W. Gai, C. Jing, R. Konecny, W. Liu, J. G. Power, T. Wong and Z. Yusof.

7.8GHz Dielectric Loaded High Power Generation And Extraction F. Gao, M. E. Conde, W. Gai, C. Jing, R. Konecny, W. Liu, J. G. Power, T. Wong and Z. Yusof.
RF particle acceleration Kyrre N. Sjøbæk * FYS 4550 / FYS 9550 – Experimental high energy physics University of Oslo, 26/9/2013 *k.n.sjobak(at)fys.uio.no.

RF particle acceleration Kyrre N. Sjøbæk * FYS 4550 / FYS 9550 – Experimental high energy physics University of Oslo, 26/9/2013 *k.n.sjobak(at)fys.uio.no.
30 GHz waveguide line modification towards 12 GHz.

30 GHz waveguide line modification towards 12 GHz.
INTEGRATION OF RF STRUCTURES IN THE TWO-BEAM MODULE DESIGN G. Riddone, CERN, Geneva, Switzerland A. Samoshkin, D. Gudkov, JINR, Dubna, Russia Abstract.

INTEGRATION OF RF STRUCTURES IN THE TWO-BEAM MODULE DESIGN G. Riddone, CERN, Geneva, Switzerland A. Samoshkin, D. Gudkov, JINR, Dubna, Russia Abstract.
Feedback from structure tuning: Effects and Compensation of length (phase) difference in dual-feed couplers 22 May 2015 Rolf Wegner.

Feedback from structure tuning: Effects and Compensation of length (phase) difference in dual-feed couplers 22 May 2015 Rolf Wegner.
Development of Dielectric-Based Wakefield Power Extractors Chunguang Jing 1,2, W. Gai 1, A. Kanareykin 2, Igor Syratchev, CERN 1. High Energy Physics Division,

Development of Dielectric-Based Wakefield Power Extractors Chunguang Jing 1,2, W. Gai 1, A. Kanareykin 2, Igor Syratchev, CERN 1. High Energy Physics Division,
Test Facilities and Component Developments Sami Tantawi SLAC May 15, 2008.

Test Facilities and Component Developments Sami Tantawi SLAC May 15, 2008.

Similar presentations

Ads by Google