MAX IV Stability Task Force TW

MAX IV Stability Task Force TW

MAX IV Stability Task Force Update Topical Workshop on Diagnostics for Ultra-Low Emittance Rings (TW-DULER) Brian Norsk Jensen DLS UK, 20th of April 2018 Outline ● Why work on stability? ● The Stability Philosophy at MAX IV ● Tolerances and Goals ● Examples from Construction work for MAX IV ● What has been done inside the Lab? ● Some Ongoing Stuff ● Some things I think we should do Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Mission: Stable Beams Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Why Work on Stability? ● Our users need Stable Measurements – Flux – Pointing Stability – Quality of Light (polarization, coherence, free of frequency content,…) – Availability ● The MAX IV Stability Task Force Is Responsible for All Stability! – Accelerators and Beamlines – Procurement Participation – Vibrations – Mechanical – Thermal – Logging – Collecting Input – Problem Solving – Characterization: Seismometers, Accelerometers, Vibrometer, Shaker, … ● Only One Person Specifically Allocated to this Work – I Get and Need Help from Many Colleagues • Mechanical, Accelerator Physicists, IT, Control Room and Beamline Staff, … – I have Great Help from People at the LTH, Dept. of Construction Sciences!!! Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Strategy and Approach ● Challenges are not always overcome by Fancy or Traditional Solutions ● ZOOM Out! ● Cross Disciplines, Interconnectedness of Things! – Mechanical and Thermal Stability, Magnetic Design, Alignability and Tolerances – Everything has to Work Well! – Risk of Sub Optimization ● Not only One single FIX – Work on all Fronts – Thorough Analysis before Assuming Solutions ● Shifting the Problem – Reducing Sensitivity ● Responsibility Policy setting Specific Tolerance Goals – Responsibility taken by MAX IV – Civil Engineering, Reducing Cost – Collaborative work – Co-Creation – On the Same Side Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 General Approach ● Passive Systems As Far as it Goes! – Mechanical – Thermal ● Isolate sources – Vibrations – Thermal ● Active systems Only if You Really Need It! – Tunnel Temperatures: “Active Passivity” – SOFB, BbB, FOFB - use with Care – Mechanical Systems Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Speaking Tolerances ● Original Vibration Tolerance defined from 3GeV Storage Ring Properties – Electron Beam σ: 2-3µm – 10% σ = 200-300nm – Amplification factor assumed to be 10 in general. – 20nm-30nm RMS, 퐢퐧퐭퐞퐠퐫퐚퐭퐞퐝 퐟퐨퐫 퐟 > ퟓ퐇퐳 ● We now have a Facility: – In average < 5-10nm, RMS f>5Hz During Rush Hour – Bursts with Higher Levels nearest Highway (5-18Hz) – Night time <2nm, RMS f>5Hz – New Tolerance for Introducing new Vibration Sources: May not change the Vibration Level significantly ● Tolerances applies to Rings and Beamlines – Linac can take more, (even when used for FEL) ● Thermal Stability Tolerances Need to be Handled from Case to Case ● Settling in Buildings cannot be Prevented – In worst case: Re-alignment Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Correlated Motions ● MAX IV is subjected to a Circular Vibration with ca 3 580 000m amplitude and a period of 24 Hours ● We are mainly concerned about Relative Displacements Stable Supports Stable Supports ● ● Sensitivity to Vibrations can be Reduced by increasing Correlation ● The MAX IV Floor is the “Backbone” of our Machines and Beamlines ● Stable Supports Ensure Correlated Motions (in Phase) Illustrations: http://upload.wikimedia.org/wikipedia/commons/1/17/Ship_wave_bending.svg http://commons.wikimedia.org/wiki/File:Rotating_earth_axial_tiles_to_orbit.gif Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Geotechnical investigations ● Geology Characterization ● Resistivity ● Seismic investigations ● Mockup – Testing Production Process – Evaluation of performance Analysis: Mats Svensson, TYRÉNS Analysis: Nils Rydén, PEAB Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Mockup Photos: Perry Nordeng Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Civil Engineering, Analysis Calculations: Peter Davidsson, CreoDynamics.com Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Civil Engineering Shear Wave Velocities Concrete, 0.3m, >2400 m/s Stabilized UGM, 0.3m, 1300 m/s Low Baltic Clay Till, Large Footprint, No Isolated 2-8m layer, Lime Stabilized Soil, Foundations for Roofs etc. 250-300 m/s 4m in average, >900m/s North-East Clay Till, Poisson’s Ratio = 0.48 8-13m layer, 400-650 m/s Shale/Mudstone, 1100-1200 m/s www.ekdahlgeo.se Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Calculations: Peter Davidsson, CreoDynamics.com Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Construction Work and Stabilization September 2012, Photos: Perry Nordeng Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Floor Vibrations, SAM House, Closest to E22 Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Designing Stable Supports (Vibrations of the Mass) 푚풙ሷ = ෍ 푭 x = X sin 휔푡 + 휃 푚풙ሷ + 푐풙ሶ + 푘풙 = 0 Stable Supports (Floor Vibrations) Equation of Motion: y = Y sin 휔푡 푚풙ሷ + 풄 풙ሶ − 풚ሶ + 풌(풙 − 풚) = 0 4 Pos north, dir vert - design spektrum 17 Events i tidsperioden 02-07 Januar 2011 Rød linje - snittspektra Damping ζ=c/cc -3 rms = 86.7 nm (5-100Hz), 86.8 nm (1-100Hz) 3 10 0.0025 -4 10 0.1 -5 0.15 10 2 0.25 -6 10 0.375 -7 10 0.5 1/3 1/3 Octave [mm] value Transmissibility X/Y Transmissibility 1 1 -8 10 0 1 2 10 10 10 1/3 Octave frequency [Hz] 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 Frequency ω/ωn Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Examples Stable Supports Calculations: Karl Åhnberg Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Eigen Frequency of Ring Components Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Electron Beam, Integrated Values, NO FOFB • The Tolerance Vertically is 200-300nm RMS (From the DDR) • RMS Values! Not Peak to Peak • No Beamline is “sticking out” from the average Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 PSD of the Same Data, Together With Seismic Data ● Seismometer placed in a Lab Floor Closest to the Highway Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Seismometer on Achr18 M1 Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Source Displacement Diagnostics Beamline Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Electron Beam Stability, New Logging Tool Electron Monitor Number Beam Electron Position FA Archiver: Guenther Rehm, Diamond LS Frequency [Hz] Matlab Acrobat: Magnus Sjöström, MAX IV Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Graph: Magnus Sjöström Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Graph: Magnus Sjöström Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Vibration Isolation Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Tram Line Isolation Thanks! to Jens Malmborg and Kent Persson, Dept. Construction Sciences, LTH More Considerations regarding Stability Work ● Stability Work is Never Ending – New Sources, Requirements and Issues Emerge ● Gaining and Maintaining Experience takes Time ● Measurements are relatively fast – It is the Analysis which takes time ● Fourier is Your Friend - Spectra are like Fingerprints Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Thermal Stability ● STF Have Still Not Done much in this Area – First Attempt for some Type of Logging Equipment ● Air ● Water ● Structures ● Electronics… 1.5GeV Ring Electron Beam Life Time [h] Time Life Beam Electron Ring 1.5GeV Time [s] Robert Lindvall, MAX IV RF Group Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Things to Come and to Continue ● More Logging – Treatment of FA Archiver Data, for Accelerators – Logging and Treatment of XBPM Signals – Temperature – Beamline Performance Data! ● Web Page: https://www.maxiv.lu.se/accelerators-beamlines/stability-task-force/ – Ongoing, Not much Content Yet… – Ambition to have “Live” Stability Data ● New Projects – Fast Orbit Feed Back, Testing and Power Supplies – Active Mechanical Damping – Temperature Controlled Zones Calculations by Karl Åhnberg – … Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Lessons Learned ● Proper Analysis before Assuming Solutions ● FEA Predictions are uncertain ● Be Consequential ● Logging is Essential! ● Follow the Guidelines! – Isolate Your Sources – Stabilize Your Components (Under-grouting!) Photo: Dörthe Haase ●STF can Only Help when People Get in Contact !!! Brian Norsk Jensen, MAX IV Laboratory TW-DULER, Diamond Light Source UK, 20/4 2018 Conclusions ● MAX IV Takes Responsibility for Functionality of Components Under the Condition that we have Full Influence – (If things don’t work It is Still Our Problem, even if we could Sue our Vendors) ● Vibration Tolerance Goal, defined by the 3GeV Ring Tolerances – Originally: 20-30nm RMS, f>5Hz – Now Defined by

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