The nanometer beam size at the CLIC interaction point imposes magnet vibration tolerances that range from 0.2 nm to a few nanometers. This is well below the floor vibra-tion usually observed. A test stand for magnet stability was set-up at CERN in the immediate neighborhood of roads, operating accelerators, manual shops, and regular office space. It was equipped with modern stabilization tech-nology. First results are presented, demonstrating signif-icant damping of floor vibration. CLIC quadrupoles have been stabilized vertically to an rms motion of (0.9 ± 0.1) n above 4 Hz, or (1.3 ± 0.2) nm with a nominal flow of cooling water. For the horizontal and longitudinal directions respectively, a CLIC quadrupole was stabilized to (0.4 ± 0.1) nm and (3.2 ± 0.4) nm

Assmann, R W

Coosemans, Williame

Guignard, Gilbert

Leros, Nicolas

Redaelli, S

Schnell, Wolfgang

Schulte, Daniel

Wilson, Ian H

Zimmermann, Frank

CERN Document Server

EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCHCERN-SL DIVISIONCERN-SL-2002- 046   (AP)Status of the CLIC Study on Magnet Stabilization andTime-Dependent LuminosityR. Aßmann, W. Coosemans, G. Guignard, N. Leros, S. Redaelli,W. Schnell, D. Schulte, I. Wilson, F. Zimmermann,The nanometer beam size at the CLIC interaction point imposes magnet vibrationtolerances that range from 0.2nm to a few nanometers. This is well below the floorvibration usually observed. A test stand for magnet stability was set-up at CERNin the immediate neighborhood of roads, operating accelerators, manual shops, andregular office space. It was equipped with modern stabilization tech-nology. Firstresults are presented, demonstrating signif-icant damping of floor vibration. CLICquadrupoles have been stabilized vertically to an rms motion of (0.9 + 0.1) nabove 4 Hz, or (1.3 + 0.2) nm with a nominal flow of cooling water.  For thehorizontal and longitudinal directions respectively, a CLIC quadrupole wasstabilized to (0.4 + 0.1) nm and (3.2 + 0.4) nm.8th European Particle Accelerator Conference, 3-7 June 2002Paris, FranceCLIC Note CLIC Note 530Geneva, Switzerland22 July, 2002SL/DIV RepsSTATUS OF THE CLIC STUDY ON MAGNET STABILIZATION ANDTIME-DEPENDENT LUMINOSITYR. Aßmann, W. Coosemans, G. Guignard, N. Leros, S. Redaelli ,W. Schnell, D. Schulte, I. Wilson, F. Zimmermann, CERN, Geneva, SwitzerlandAbstractThe nanometer beam size at the CLIC interaction pointimposes magnet vibration tolerances that range from 0.2nm to a few nanometers. This is well below the floor vibra-tion usually observed. A test stand for magnet stability wasset-up at CERN in the immediate neighborhood of roads,operating accelerators, manual shops, and regular officespace. It was equipped with modern stabilization tech-nology. First results are presented, demonstrating signif-icant damping of floor vibration. CLIC quadrupoles havebeen stabilized vertically to an rms motion of (0.9 0.1) nmabove 4 Hz, or (1.3 0.2) nm with a nominal flow ofcooling water. For the horizontal and longitudinal direc-tions respectively, a CLIC quadrupole was stabilized to(0.4 0.1) nm and (3.2 0.4) nm.1 INTRODUCTIONThe CLIC study [1] aims at a 3 TeV collision energywith a transverse spot size of 43 nm (horizontal) times 1 nm(vertical). The associated magnet vibration tolerances aresevere [2] (see Table 1). It must be determined early onwhether they are feasible. Vibration data is analyzed viaa power spectral density     of displacement with as the discrete vibration frequency [3]. The integrated rmsvibration  above a minimal frequency   is:       ~~      (1)Here,  is the number of samples, ~~ the sampling time,and , are integers. The vertical direction is denotedby , the horizontal by  and the longitudinal by . Thelongitudinal direction is collinear with the beam and forour set-up perpendicular to the wide side of the table. Ta-ble 1 summarizes the requirements for the CLIC linac andfinal doublet (FD) quadrupoles [3]. The most challengingrequirements are in the vertical plane with tolerances of1.3 nm (linac) and 0.2 nm (FD) uncorrelated rms vibrationabove a minimal frequency of 4 Hz. Below effectsof magnet vibrations are cured by beam-based feedbacks.The value of depends on the repetition frequency, thelayout, and the gain of the feedback. About 25 pulses areneeded for correction [2] so that for CLIC is about100 Hz/25.A CLIC study on magnet stability was proposed [5] toaddress this critical issue. The study aims in particular at PhD student of the University of Lausanne, Institut de Physique desHautes Energies (IPHE), Switzerland.Table 1: Summary of magnet stability requirements for a2% loss in luminosity [3, 4].Magnet 	Linac 2600 4 Hz 14 nm 1.3 nmFinal Focus 2 4 Hz 4 nm 0.2 nmbringing existing stabilization technology to the accelera-tor field. In view of the available resources it was decidedto buy existing industrial solutions instead of developingequipment directly adapted to the CLIC requirements.Figure 1: The CLIC vibration test stand. A honeycomb ta-ble with minimized structural resonances is supported byactively stabilized feet. A quadrupole doublet from theCLIC test facility is put onto the table and connected tocooling water. Geophones (blue) measure the vibrations onthe floor, the table, and on top of the magnets.2 EXPERIMENTAL SET-UPA test stand for magnet vibration (see Fig. 1) was set upon the CERN site in Meyrin, in the immediate neighbor-hood of roads, operating accelerators, manual shops, andregular office space. Vibration properties were surveyedand found of appropriate level (not too low and not toohigh) [3]. The rms floor vibration above 4 Hz is about6 nm and reflects the good geological conditions in theGeneva region. Though sub-nm stability is routinely ob-served in deep CERN accelerator tunnels [6], one cannotrely on this. Technical noise can easily enhance the vibra-tion levels to the 5 nm level. The level of ground motionand technical noise at the CERN test stand is ideally suitedto demonstrate that the critical CLIC vibration tolerancescan be achieved in a realistic accelerator environment.Advanced measurement and stabilization equipment wasacquired or used from the CLIC alignment study [7]. Theexperimental set-up was completed in March 2002. Themain components are described:1) Four geophones from GeoSig for monitoring vibra-tion amplitudes with sub-nm accuracy in the frequencyrange of 1 Hz to 315 Hz. This includes options for ana-log and digitized data acquisition.2) Four actively stabilized feet (STACIS2000 systemfrom TMC), which rely on integrated geophones to mea-sure ground vibration, rubber pads for passive damping,and piezo-electric movers for active damping of load vi-brations induced from the ground.3) A honeycomb support structure (table) with length2.4 m, width 0.9 m, and height 0.6 m with a lowest struc-tural resonance at 230 Hz.4) A pneumatic system (PEPS system from TMC) con-sisting of four air piston supports for passive damping, dis-tance sensors for micrometer alignment, and table top geo-phones for feedback on the air pressure (active damping).Results achieved with items 1)-3) are reported, however,only using three STACIS feet (the fourth was broken). Thepneumatic system was temporarily installed but detailedstudies could not yet be performed. The present experi-mental set-up is illustrated in Fig. 1.The sensors were carefully studied to establish the reso-lution and accuracy. In terms of rms vibration above a mini-mal frequency a resolution of better than 0.2 nm is obtainedat 4 Hz and better than 0.1 nm at 10 Hz. The resolution im-proves for higher frequencies because velocity is measured.The absolute scale of the GeoSig sensors has recently beencalibrated by the manufacturer. In order to assign an errorto the absolute scale, the rms motion for frequencies be-tween 2 Hz and 60 Hz is compared to the result from anolder Mark Product sensor that was used for 1995 groundmotion measurements [6]. In the range of valid measure-ments the Mark Product sensor systematically gives a 14%higher rms vibration, as shown in Fig. 2. A 14% error isassigned to the absolute scale. In the following all mea-surements refer to the GeoSig sensors.02468100 2 4 6 8 10 12 14Measurement Mark Product [nm]Measurement GeoSig [nm]Fit IdealLow frequencylimit of GeoSig sensorsFigure 2: Rms vertical vibration measured for frequenciesbelow 60 Hz with two different geophones.3 CLIC QUADRUPOLE STABILIZATIONThe vibration of the considered quadrupole doublet de-pends on the floor vibration, the damping from the ac-tive feet, sources of technical noise like cooling water, andstructural resonances in table, quadrupole, and support.The transfer function of vibration from the floor to thetable top was studied. It is shown in Fig. 3. A vibrationdamping of up to a factor of 20 is achieved. With thisdamping the table top is stabilized in noisy conditions to(0.3 0.1) nm vertically (see Fig. 4), sufficient for the linacrequirement and close to the requirement for the Final Fo-cus magnet. The amplification above 200 Hz is a knownproblem [8] and is suspected to be due to electronic noisein the feedback circuit. It is not relevant for our application.0.111 10 100Transmission (Table/Floor)Minimal frequency [Hz]VerticalLongitudinalHorizontalFigure 3: Transmission of horizontal, vertical, and longitu-dinal vibration amplitude from floor to table top.0.0010.010.11101001 10 100Vertical rms motion above f min [nm]Minimal frequency fmin [Hz]Beam-basedfeedbacksFloor (quiet and noisy)Table top(quiet and noisy)Linac toleranceFF quad toleranceFigure 4: Vertical rms vibration versus frequency for quietand noisy conditions at the floor and on the table top.The quadrupole doublet was either directly screwed ontothe table top or placed on its alignment support (microme-ter alignment movers) that then was screwed onto the table.The measured vertical and horizontal vibration on floor, ta-ble, and quadrupole is shown in Fig. 5 for the direct con-nection to the table. At 4 Hz a vertical vibration amplitudeof (0.9 0.1) nm is obtained on top of the quadrupole dou-blet. Vibration was reduced for all directions, with valuesof (0.4 0.1) nm and (3.2 0.4) nm for residual horizontaland longitudinal quadrupole vibrations above 4 Hz. Theinfluence of cooling water on the vertical vibration level ontop of the quadrupole is shown in Fig. 6. At 4 Hz and thenominal flow of cooling water the vertical vibration is in-creased to (1.3 0.2) nm which meets the tolerance for theCLIC linac quadrupoles. The studies on water induced vi-brations are described in detail in [9]. Note that tap waterwas used for these studies, so that the effect of water pumpsis not included (vibrations are generated from turbulent wa-ter flow).0.0010.010.11101 10 100Vertical rms motion above f min [nm]Minimal frequency fmin [Hz]Table topFloorQuadFF toleranceLinac toleranceFigure 5: Vertical rms vibration versus frequency on floor,table, and quadrupole.0.511.522.533.540 10 20 30 40 50 60 70Vertical rms motion above 4 Hz [nm]Cooling flow [l/s]NominalcoolingflowLinac toleranceFigure 6: Vertical rms quadrupole vibration above 4 Hzversus flow of cooling water.The transfer function of the CLIC quadrupole alignmentsupport was studied with a speaker mounted onto the table.Acoustic waves were directed to the table to induce vibra-tions with a controllable frequency and amplitude. If thegenerated vibrations coincide with a structural resonance ofthe quadrupole support, a strong amplification in vibrationamplitude from table to quadrupole is expected. Structuralresonances were identified indeed. Inducing vibrations at37 Hz an amplification of a factor of 10 in amplitude or100 in power was measured between the quadrupole andtable. The data is shown in Fig. 7 in the form of the powerspectral densities with and without induced vibrations.1e-111e-101e-091e-081e-071e-061e-050.00010.00130 32 34 36 38 40 42 44PSD y [µm2 /Hz]Frequency [Hz]Table, A=8 VQuad., A=8 VTable, A=0 VQuad., A=0 VFigure 7: Power spectra for top of quadrupole and tablearound 37 Hz with and without acoustical noise at 37 Hz.4 CONCLUSION AND OUTLOOKA test stand for magnet vibration has been set up onthe CERN main site and was equipped with advanced sta-bilization equipment. First measurements with active vi-bration damping showed suppression of floor vibration byup to a factor of 20. CLIC prototype quadrupoles havebeen stabilized vertically to an rms motion of (0.9 0.1) nmabove 4 Hz, or (1.3 0.2) nm with a nominal flow of cool-ing water. For the horizontal and longitudinal directionsa CLIC quadrupole was stabilized to (0.4 0.1) nm and(3.2 0.4) nm without cooling water. The measured vi-bration levels meet the requirements for the 2600 CLIClinac quadrupoles. A CLIC specific engineering solutioncould be based on or include the tested technology. Struc-tural resonances were identified and can be minimized infuture magnet designs. Further studies will aim at studyingalignment stability and environmental effects (e.g. mag-netic fields), employing an alternative pneumatic system,and using the measurements for predictions of the CLICluminosity stability. Vibration must be suppressed by a fur-ther factor of 2-5 to meet the tolerance for the Final Focusquadrupole.We thank F. Ruggiero for his encouragement and sup-port. The colleagues at SLAC and DESY helped with manydiscussions and ideas.5 REFERENCES[1] G. Guignard (ed) et al: ”A 3 TeV     Linear Collider Basedon CLIC Technology”. Report CERN-2000-008.[2] R. Aßmann et al, ”Stability Considerations for Final Fo-cus Systems of Future Linear Colliders”. Proc. EPAC2000.CERN-SL-2000-059-OP. CLIC-Note-448. SLAC-REPRINT-2000-095. DESY-M-00-04I.[3] M. Aleksa et al, ”The CLIC study of magnet stability andtime dependent luminosity performance”. Proc. PAC2001.CERN-SL-2001-045-AP, CLIC-NOTE-495.[4] D. Schulte, ”Emittance Preservation in the Main Linac ofCLIC”. Proc. EPAC98. CERN/PS/98-018 (LP).[5] R. Aßmann: ”Proposal for a CLIC Study of Final Fo-cus Stabilization Technology and Time-DependentLuminosity Performance”. Unpublished. Available athttp://www.cern.ch/clic-stability.[6] V.M. Juravlev et al, ”Seismic vibration studies for future lin-ear colliders”. Proc. EPAC94. CERN-SL-94-41-RF. CLIC-Note-234.[7] D. Carrica, R. Pittin, W. Coosemans, M. Benedetti, ”Activealignment electronic system for CLIC 30-GHz modules inCTF2”. CLIC-NOTE-361 (1998).[8] R. Savage (LIGO), private communication.[9] S. Redaelli, R. Aßmann, W. Coosemans, W. Schnell, theseproceedings.

Status of the CLIC study on magnet stabilisation and time-dependent luminosity

Status of the CLIC study on magnet stabilisation and time-dependent luminosity

Abstract

Similar works

Full text

Available Versions

CERN Document Server