Superconducting strands can be characterized by their Minimum Quench Energy (MQE), i.e. the minimum heat pulse needed to trigger a quench in operation conditions (field, temperature, current), in the limit of a (temporally and spatially) d-shaped disturbance. The sub-mm/µs range of perturbation space has only recently been achieved using the electrical graphite-paste heater technique [1]. The present work has put this technique into practice for the strands of the LHC main magnets, which are designed to operate at 1.9K in peak fields of up to 9T [1]. No way has been found yet to calibrate MQE measurements. To make relative statements on the MQE of different samples possible, the reproducibility of the measurements was emphasized. First heater prototypes did not come up to this stipulation. Finally the tip-heater configuration was found to meet the requirements. It generates a heat pulse in a thin resistive graphite paste deposit on top of a small tip that is pressed against the sample with a clamp. The clamp guarantees a maximum of exposure of the sample to the surrounding cryogen. The most striking aspect of repeated measurements on a reference sample is that in open bath conditions the MQE as a function of transport current in subcooled helium can reach hundred times the corresponding value in adiabatic conditions (i.e. with the sample potted in a low conductivity medium). This extraordinary cooling performance of superfluid helium, predicted by many (e.g. [2]) has rarely been shown in superconductor stability experiments

Bauer, P

Donnier, J

Oberli, L R

CERN Document Server

1EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCHEuropean Laboratory for Particle PhysicsLarge Hadron Collider ProjectLHC Project Report 248AbstractSuperconducting strands can be characterized by their Minimum Quench Energy (MQE), i.e. theminimum heat pulse needed to trigger a quench in operation conditions (field, temperature, current), in thelimit of a (temporally and spatially) δ-shaped disturbance. The sub-mm/µs range of perturbation space hasonly recently been achieved using the electrical graphite-paste heater technique [1]. The present work hasput this technique into practice for the strands of the LHC main magnets, which are designed to operate at1.9K in peak fields of up to 9T [1]. No way has been found yet to calibrate MQE measurements. To makerelative statements on the MQE of different samples possible, the reproducibility of the measurements wasemphasized. First heater prototypes did not come up to this stipulation. Finally the tip-heater configurationwas found to meet the requirements. It generates a heat pulse in a thin resistive graphite paste deposit ontop of a small tip that is pressed against the sample with a clamp. The clamp guarantees a maximum ofexposure of the sample to the surrounding cryogen. The most striking aspect of repeated measurements ona reference sample is that in open bath conditions the MQE as a function of transport current in subcooledhelium can reach hundred times the corresponding value in adiabatic conditions (i.e. with the samplepotted in a low conductivity medium). This extraordinary cooling performance of superfluid helium,predicted by many (e.g. [2]) has rarely been shown in superconductor stability experiments.CERN, LHC Division – Geneva (Switzerland) (*) Supported by the association EURATOM-OEAPresented at ASC’98 – Applied Superconductivity Conference, Palm Spring, CA, USA, September 1998Administrative SecretariatLHC DivisionCERNCH - 1211 Geneva 23SwitzerlandGeneva, 7 October 1998Tip Heater for Minimum Quench Energy Measurements onSuperconducting StrandsP. Bauer*, J. Donnier, L. Oberli2Tip Heater for Minimum Quench Energy Measurements onSuperconducting StrandsP. Bauer*, J. Donnier, L. OberliCERN, CH1211 Geneva 23, SwitzerlandAbstract - Superconducting strands can be characterized bytheir Minimum Quench Energy (MQE), i.e. the minimum heatpulse needed to trigger a quench in operation conditions (field,temperature, current), in the limit of a (temporally andspatially) δ-shaped disturbance. The sub-mm/µs range ofperturbation space has only recently been achieved using theelectrical graphite-paste heater technique [1]. The present workhas put this technique into practice for the strands of the LHCmain magnets, which are designed to operate at 1.9K in peakfields of up to 9T [1]. No way has been found yet to calibrateMQE measurements. To make relative statements on the MQEof different samples possible, the reproducibility of themeasurements was emphasized. First heater prototypes did notcome up to this stipulation. Finally the tip-heater configurationwas found to meet the requirements. It generates a heat pulse ina thin resistive graphite paste deposit on top of a small tip that ispressed against the sample with a clamp. The clamp guaranteesa maximum of exposure of the sample to the surroundingcryogen. The most striking aspect of repeated measurements ona reference sample is that in open bath conditions the MQE as afunction of transport current in subcooled helium can reachhundred times the corresponding value in adiabatic conditions(i.e. with the sample potted in a low conductivity medium). Thisextraordinary cooling performance of superfluid helium,predicted by many (e.g. [2]) has rarely been shown insuperconductor stability experiments.I.  DEFINING THE  MQE MEASUREMENTA strand cooled by liquid helium in a perpendicularmagnetic field and carrying a transport current is locallyheated during a short time. The MQE is the minimum heatpulse which just triggers a quench. The hardware for MQEmeasurements comprises a critical current test-rig, a pulsegenerator, voltage taps, and a heater (Figure 1). The criticalcurrent Ic was defined with the 10-14Ωm criterion. At thisresistivity the heat generation is small, so that measurementscan be performed at currents above Ic. The following samplehas been used as reference:d=1.065mm; Cu/Sc=1.6; coating: SnAg; Ic(9T/1.9K)= 740A;Ic(8T/4.2K)=350A; ρCu(9T)=5.610-10Ωm;,  ρCu(6T)=4.3.10-10Ωm.Originally defined as the quench energy in the limit of δ-likeperturbations, experiments and simulations like in (Figure 2)indicate that MQE is independent of pulse duration tini in therange 0-100µs and spatial extension xini<0.1mm. Based on theexperiments shown in Figure 2 the pulse time for theexperiments has been fixed to 10µs, the spatial extension is~0.6mm.Manuscript received  September 12, 1998* Supported by the association EURATOM-OEAWFigure 1:  MQE measurement set-up. The bath below the λ-plate can becooled down to 1.9K through pumping on a JT-valve-heat exchanger circuit.The solenoid is designed for 14T at 1.8K. Current leads and battery PS aredesigned for 2000A. The sample is wound on a G11 cylinder with the wireaxis almost perpendicular to the magnetic field. 3 sets of heaters togetherwith 16 pairs of voltage taps are distributed along the sample. The sample issoldered on top and bottom to the in and out current lead. The pulsegenerator delivers square pulses (1µs-1ms) of up to100W into a load of 1-70Ω.01002003004005006007001 10 100 1000 10000pulse duration tin i  [µs]quench energy QE [µJ]MQEFigure 2: Quench Energy (QE) versus pulse duration tini, measurement (dots,not calibrated) and simulation (line). Reference wire: 8T, 4.23K, 0.7Ic,Kapton sandwich heater, heater length 0.3mm. The QE remains constant aslong as tini is smaller than quench decision time (>30µs in our experiments).II. HEATER PROTOTYPESThe heater technique for the LHC-stability investigationswas inspired by the successful MQE measurements conductedCRYOSTATBATTERY PSHEATERMAGNETTRANSIENTRECORDERPULSEGENERATORLAMBDAPLATECURRENTCONTROLQUENCHPROTECTIONHEATERNETWORK3at BNL [3] and KEK [4], based on graphite paste heaters. Thistechnique makes use of the particular resistivity of thegraphite paste, which is in such a range (some Ωm at10T/1.9K) that considerable heating power (1-100W) can begenerated in very small volumes (0.001mm3), thus giving riseto very small thermal time constants (1µs). The abovementioned range of low-temperature electrical resistivity isnormally covered by semi-conductors. In the course of thiswork attempts have been made to use a sputtered Ge layer asheating element. Although promising this technique had to beabandoned because of the difficulty to control the variousparameters involved. A first heater prototype, very similar tothe heaters used at KEK and BNL, the Kapton-sandwichheater, consists of two layers of 25µm adhesive Kapton foilwhich enclose a thin copper strip (10µm thick, 0.3mm large).The upper Kapton layer has a punched hole (∅ 0.3mm) whichgives way to the underneath copper strip and into which thegraphite paste is applied before clamping the heater stripbetween sample and sample-holder. Although first resultswere quite encouraging (e.g. Figure 2) this set-up quicklyrevealed its major weakness: due to a lack of control ofpressure between sample and heater, and of the position of theheater with respect to the sample, repeated measurements on atest sample showed a big spread (>factor 2) at 4.2K/8T(Figure 3). In superfluid helium, where the heat loss from theheater to the helium becomes an additional factor, thereproducibility of the Kapton-sandwich heaters was notacceptable. Even the use of a stainless-steel clamp with theheater current lead embedded (supposed to ensure  control ofpressure and position) did not produce any substantialimprovement.1010010000.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.1 1.2I/IcMQE [µJ]Kapton sandwich heatertip-heatersimulationRef Wire 4.2K / 8TFigure 3: MQE in 4.2K/8T, reference strand; Spread of Kapton-sandwichheater measurements compared to tip heater measurements. The lowestcurve (dotted) is a numerical simulation which agrees fairly well withmeasurement. MQE in pool boiling helium is well understood since [5].The tip heater electrically generates a heat pulse in the pointwhere tip touches the strand. The electrical tip resistance (10-20Ω) is given by a 40µm graphite paste (Epotecny’s E300)deposit on top of the heater-tip together with the contactresistance. The heater tips are small cylinders (1.75mm long,∅ 0.6mm) with rounded edges, made of insulating material(=low back loss) and covered with a sputtered 2µm Agcoating (=low heat generation due to heater current). A clampfixes the sample position relative to the tip and the tip ispressed against the sample with a flexible blade, which acts atthe same time as heater current supply. The clamp is made ofinsulating, machinable glass and exposes on the average 90%of the strand perimeter to the helium bath. The distribution ofhelium can be shown with the help of Figure 4. The lowerpart of the clamp has two perpendicular channels to cool thesample from below where it is clamped from above. In thecenter the sample is pinned from underneath by the heater andexposed to the open bath helium on the upper surface wherethe upper clamp-part has a dome-like reservoir connected tothe bath through a drilling. The heater current lead is a u-shaped copper rod, filed to half the diameter and silver platedat the end which presses against the back of the heater tip. Itis bent and generates a considerable pressure (100g/0.1mm2).The contact resistance at the back end of the heater is small(some mΩ). The other end of the heater current lead serves asone pole for both heater voltage and heater current. Thesecond pole for the heater current is a point further away onthe sample. The second pole for the heater voltage is a pointon the sample, 1cm from the heater.Figure 4: Tip heater drawing: 1 heater current lead , 2 sample, 3 thermo-retracting sleeve (optional), 4 heater tip, 5 helium reservoir (connected to thebath through a channel), 6 helium channels. The heater tip is squeezedbetween sample on top and the heater current lead from below. The heatercurrent lead acts as a spring.Measurements on the reference strand showed that the quenchdecision length rarely exceeds the clamp-dimension. (Thequench decision length is the length of a hypothetical normalzone (T<15K) which produces the quench decision voltagewhen crossed by the transport current. The quench decisionvoltage is the voltage at which the just quenching and the justrecovering cases split.) Therefore the helium content in theimmediate vicinity of the heated spot plays a crucial role.III. THE SLEEVE EFFECTIn the course of heater development an attempt was madeto reduce heat loss by insulating the initially heated “slice” ofthe strand by means of a thermo-retractable sleeve. A featureof the MQE(I/Ic) curve of LHC-type strands is that at highcurrents they are essentially adiabatic (as if “uncooled”).Simulations and measurements (Figure 5) revealed thatinsulating short sections centered around the heater (using2437.5mm4thermo-shrinking sleeves) extends the adiabatic MQE-regimeto lower currents. The sleeve therefore strongly influences themeasurement.1101001000100000.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.1I/IcMQE [µJ]adiabaticno sleeve1mm sleeve3mm sleeveFigure 5: Reference strand measurement, 1.9K/9T. Covering 1mm, 3mm orthe whole sample with a thermo-retracting sleeve gradually shifts the onsetof the superfluid cooling enhanced MQE regime to lower currents.The quench decision length (Figure 6) corresponding to thecurves in Figure 5 as well reflects the presence of the sleeve:0123456789100.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.1I/Icquench decision length [mm]adiabaticopen bath1mm sleeve3mm sleeveFigure 6: Reference wire measurements:  quench decision length in varyingcooling conditions,  1.9K/9T.As long as the quench decision length is smaller than theuncooled part the case is adiabatic. As soon as the MinimumPropagating Zone (MPZ) emerges from under the sleeve, thequench decision length, quench decision time and MQE risestrongly to reach the cooled homologue.As formerly discussed in [6] metastable normal zonesappeared in the sleeve-effect measurements as a consequenceof discontinuity in the cooling at the edge of the sleeve. Theopen bath MQE measurements revealed that for I/Ic<0.7 theset-up could be considered as “cryo-stable” (with steady stateheat transfer flux of up to the huge value of 175kW/m2).IV. REFERENCE STRAND MEASUREMENTSTo test the predictions of a numerical model (explained indetail in [7]) concerning the effect of cooling to superfluidhelium on MQE (Figure 7), experiments have beenconducted:1)  experiments involving the variation of the cooledperimeter fraction f (Figure 8);2)  an investigation of the effect of helium volume on MQE,varying the temperature of the HeII-bath (Figure 9).The cooled perimeter fraction f determines the strength ofheat transfer because it appears in the heat balance equationwhich describes the problem ([8]) as a multiplier of thecooling function. MQE curves for the same helium volume11010010000.4 0.5 0.6 0.7 0.8 0.9 1 1.1I/IcMQE [µJ]f=0% adiabaticf=15% f=50%f=70%f=100%Figure 7: 1.9K / 8.4T reference strand MQE simulation. Effect of coolingparameter f (cooled perimeter fraction) at fixed helium volume (200% ofconductor volume). Heat transfer coefficients: aK=180W/K4/m2 andafb=250W/K/m2 for Kapitza heat transfer (“k”)and film-boiling (“fb”). Anincreased cooled perimeter fraction shifts the bump to higher currents(indicated by arrow ). The parameter f  has almost no effect on the “height ofthe bump”, which is determined by the helium volume parameters.but changing f differ with respect to the occurrence of the“helium bump” (or “superfluid enhancement”). The height ofthe bump, which refers to the fact that an increase in heliumvolume can push MQE by a factor of ten or more, is mainlyconditioned by the helium volume parameter. The fact thatthe cooled perimeter fraction f (or the heat transfercoefficient) determines the “position” of the bump along thecurrent axis shows that there is a threshold of cooling strengthversus Joule heating which creates two regimes: one in whichcooling can act and the other in which cooling, thoughpresent, cannot intervene. The analysis of the simulated datareveals that the bump occurs when a recovery of the wire ispossible even after the temperature has by far exceeded thecritical temperature and partial burn-out along the initiallyheated length occurred. Heat transfer plays a noticeable roleand since quench decision time and quench decision lengthincrease, the effect of cooling is amplified. Above the bump,at high current, the MQE is hardly more than the enthalpyreserve of the wire between bath temp. Tb and a temperaturebetween current sharing Tcs and critical  Tc. With themaximum temperatures remaining below critical Tc thecooling rates (~∆T) involved are negligible.51101001000100000.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.1I/IcMQE [µJ] f=0.1f=0.8f=0.7f=0.5f=0.3 open bathf=0.9adiabatic f=0Figure 8: Reference strand MQE measurements at 1.9K/9T. Effect of thecooled perimeter fraction f on MQE. Compare to simulations in Figure 7.The striking resemblance of f-effect and sleeve-effect can beseen as well in the following example: comparing for examplethe I/Ic=0.5 point in the 1mm sleeve case in Figure 5 and inthe f=0.5 case in Figure 8 (both have MQE~3100µJ and aquench decision length of ~9mm) reveals that in both casesthe cooled fraction of surface along quench decision length is~0.55. This implies that for MQE only the average cooledsurface along the MPZ counts and not the way the cooledspots are distributed.By varying the temperature of the helium bath between1.9 and 2.1K one does neither change drastically Ic nor the1101001000100000.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.1 1.2I/IcMQE [µJ]ad iabatic2.1K2.05K2K1.95K 1.9KFigure 9: Reference strand MQE measurement: MQE at 9T in open bathconditions  with varying bath temperature Tb between 1.9K and 2.1K.specific heat of the strand. Consequently, and this has beenconfirmed by measurement, the MQE should not vary in theadiabatic case. On the other hand the open bath MQE reflectsthe variation in temperature because the apparent heatconductivity of helium II is a rapidly changing function of Treaching its maximum at 1.9K. Together with the specificheat, which varies as well strongly in this temperature range,it influences the heat transfer via the penetration depth of heatand henceforth the helium volume participating in the heattransfer process. In fact the experiment in Figure 9 isequivalent to varying the helium volume (“Channel limit”) incontact with the sample at a fixed temperature. Modelcalculations predict that the helium volume parameter affectsmainly the amplitude of the superfluid enhancement, in a waysimilar to the stapled curves in Figure 9. Another predictionof the model, namely the saturation of the helium volumeeffect at approximately two times the conductor volume couldnot be verified.V. CONCLUSIONSWith the aim of characterizing the stability of LHC typestrands a Minimum Quench Energy (MQE) measurementtechnique based on graphite paste tip heaters was developed.The parameter which most influences MQE is the cooling. Asshown in repeated measurements on a reference sample the“superfluid enhancement” of MQE, due to the extraordinaryheat conduction properties and the relatively high specificheat of superfluid helium, yields a leap in MQE of 10-100times the adiabatic case. The qualitative understanding of theeffect of the cooling parameters on MQE provided by amodel (described in [8]), namely that the magnitude of thebump (=superfluid enhancement) is related to the heliumvolume and its position along the current axis given by the“Kapitza heat transfer coefficient”, has been confirmedexperimentally.ACKNOWLEDGMENTThe authors wish to thank D. Leroy and M. Wilson fortheir constant support and advice. This work would have beenimpossible without the cryogenic and technical support fromC.H. Denarie, J. Stott, P. Jacquot, J.L. Servais, R. Guigue andP. Chevassus.REFERENCES[1] K. Seo, M. Morita , S. Nakamura, T. Yamada and Y. Jizo, “MinimumQuench Energy Measurements for Superconducting Wires”, IEEETrans. on Magn., Vol. 32 (4), p. 3089-3093, 1996.[1] R. Perin, “The Superconducting Magnet System for the LHC”, IEEETMAG, 1991.[2] H. Kobayashi, K. Yasukochi, K. Tokuyama, “Heat Transfer to LiquidHelium in a Narrow Channel Below 4.2K” , Proc. 6th ICEC, IPC Science& Technology Press, Guildford, England, p.307, 1976[4] M.N. Wilson and R. Wolf, “Minimum Quench Energies of RutherfordCables and Single Wires”, IEEE Trans. On Appl. SC, vol. 7, Nr.2, 1995.[3] S.W. Kim, T. Shintomi, N. Kimura, Y. Makida, H. Hirabayashi, T.Mito,l A. Iwamoto, J. Yamamoto, A. Kimura, “Experimental Studies ofRutherford Cables for Superconducting Accelerator Magnets”, IEEETrans. on Magn., Vol.32(4/1), p. 2784-2787, 1996. [4] C. Meuris, A. Mailfert, “Influence of the Spacers on the Stability ofChannel Cooled Superconducting Coils”, IEEE Trans. on Magn.,Vol.17(1), p. 1079, 1981.[5] W. Nick, “Theoretical Results of Stability in Pool Boiling Helium-I”,Stability of Superconductors, p. 139, Int. Institute of Refrigeration Com.A1/2, Saclay, France, 1981.[6] P. Bauer, L. Oberli, R. Wolf, M.N. Wilson, “Minimum Quench Energiesof LHC Strands”, paper submitted to the ASC 98, Palm Springs

Tip Heater for Minimum Quench Energy Measurements on Superconducting Strands

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