The stringent requirements on temperature control of the superconducting magnets for the Large Hadron Collider (LHC), impose that the cryogenic temperature sensors meet compelling demands such as long-term stability, radiation hardness, readout accuracy better than 5 mK at 1.8 K and compatibility with industrial control equipment. This paper presents the results concerning long-term stability of resistance temperature sensors submitted to cryogenic thermal cycles. For this task a simple test facility has been designed, constructed and put into operation for cycling simultaneously 115 cryogenic thermometers between 300 K and 4.2 K. A thermal cycle is set to last 71/4 hours: 3 hours for either cooling down or warming up the sensors and 1 respectively 1/4 hour at steady temperature conditions at each end of the temperature cycle. A Programmable Logic Controller (PLC) drives automatically this operation by reading 2 thermometers and actuating on 3 valves and 1 heater. The first thermal cycle was accomplished in a temperature calibration facility and all the thermometers were recalibrated again after 10, 25 and 50 cycles. Care is taken in order not to expose the sensing elements to moisture that can reputedly affect the performance of some of the sensors under investigation. The temperature sensors included Allen-Bradley and TVO carbon resistors, Cernox, thin-film germanium, thin-film and wire-wound Rh-Fe sensors

Balle, C

Casas-Cubillos, J

Rieubland, Jean Michel

Suraci, A

Togny, F

Vauthier, N

CERN Document Server

EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCHEuropean Laboratory for Particle PhysicsINFLUENCE OF THERMAL CYCLING ON CRYOGENIC THERMOMETERSCh. Balle, J. Casas, J.M. Rieubland, A. Suraci, F. Togny and N. VauthierThe stringent requirements on temperature control of the superconducting magnets for the Large HadronCollider (LHC), impose that the cryogenic temperature sensors meet compelling demands such aslong-term stability, radiation hardness, readout accuracy better than 5 mK at 1.8 K and compatibility withindustrial control equipment.This paper presents the results concerning long-term stability of resistance temperature sensors submittedto cryogenic thermal cycles. For this task a simple test facility has been designed, constructed and put intooperation for cycling simultaneously 115 cryogenic thermometers between 300 K and 4.2 K. A thermalcycle is set to last 71/4 hours: 3 hours for either cooling down or warming up the sensors and 1respectively 1/4 hour at steady temperature conditions at each end of the temperature cycle. AProgrammable Logic Controller (PLC) drives automatically this operation by reading 2 thermometers andactuating on 3 valves and 1 heater. The first thermal cycle was accomplished in a temperature calibrationfacility and all the thermometers were recalibrated again after 10, 25 and 50 cycles. Care is taken in ordernot to expose the sensing elements to moisture that can reputedly affect the performance of some of thesensors under investigation. The temperature sensors included Allen-Bradley® and TVO® carbon resistors,Cernox™, thin-film germanium, thin-film and wire-wound Rh-Fe sensors.LHC DivisionPresented at the 1999 Cryogenic Engineering and International Cryogenic Materials Conference(CEC-ICMC'99), 12-16 July 1999, Montreal, CanadaGeneva, Large Hadron Collider ProjectAdministrative SecretariatLHC DivisionCERNCH - 1211 Geneva 23SwitzerlandLHC Project Report 321Abstract1 December 19991INFLUENCE OF THERMAL CYCLING ONCRYOGENIC THERMOMETERSCh. Balle, J. Casas, J.M. Rieubland,A. Suraci, F. Togny and N. VauthierLHC Division, CERN1211 Geneva 23, SwitzerlandABSTRACTThe stringent requirements on temperature control of the superconducting magnets forthe Large Hadron Collider (LHC), impose that the cryogenic temperature sensors meetcompelling demands such as long-term stability, radiation hardness, readout accuracy betterthan 5 mK at 1.8 K and compatibility with industrial control equipment.This paper presents the results concerning long-term stability of resistance temperaturesensors submitted to cryogenic thermal cycles. For this task a simple test facility has beendesigned, constructed and put into operation for cycling simultaneously 115 cryogenicthermometers between 300 K and 4.2 K. A thermal cycle is set to last71/4 hours: 3 hours for either cooling down or warming up the sensors and 1 respectively1/4 hour at steady temperature conditions at each end of the temperature cycle. AProgrammable Logic Controller (PLC) drives automatically this operation by reading2 thermometers and actuating on 3 valves and 1 heater. The first thermal cycle wasaccomplished in a temperature calibration facility and all the thermometers wererecalibrated again after 10, 25 and 50 cycles. Care is taken in order not to expose thesensing elements to moisture that can reputedly affect the performance of some of thesensors under investigation. The temperature sensors included Allen-Bradley® and TVO®carbon resistors, Cernox™, thin-film germanium, thin-film and wire-wound Rh-Fe sensors.INTRODUCTIONWithin the framework of various tests and developments of a cryogenic thermo-meter1-4 for the LHC, the long-term stability of the temperature characteristics incorrelation with thermal cycles had to be evaluated for the various LHC prototypetemperature sensors (RhFe thin film and wire-wound, Allen-Bradley®, TVO® andCernox™). In the past much work has been published concerning either the long-term orthermal cycling stability of cryogenic temperature sensors5-10. Data is missing for some ofthe sensors under investigation and also it is often unreliable or at least difficult to interpret.For instance many contradictory reports concerning the performance of Allen-Bradley®temperature sensors exist, it is possible to find many recipes9-10 to improve theircharacteristics by encapsulation techniques, sudden thermal cycles, exposure to hightemperature, etc. To further complicate this situation it is worth pointing out that Allen-Bradley® resistors were produced for the electronic industry and their characteristics from acryogenic point of view may change from year to year. Allen-Bradley® thermometer is2Table 1. LHC-conditions Table 2. LHC cryogenic thermometer needsItems Value Temperature Range/K Accuracy [mK] QuantityExpected LHC-lifetime 20 year 1.6…2.2 10 2418LHC-Temperature Range 1.8…300 K 2.2…4.0 20 2550Cooling-speed 60 K/day 4.0…6.0 30 4061Warming-speed 40 K/day 6.0…25 1000 3603Cool-down and Warm-up 1/year 25…300 5000 3603300 – 1.8 K thermal cycles 20/lifetimestill a LHC prototype even though the fabrication of these sensors was ceased in 1997;CERN still holds a stock large enough for satisfying the LHC requirements.The measurement of temperature is critical for the proper operation of the LHC and itwas then decided to investigate the stability of LHC prototype temperature sensors whensubjected to thermal cycles between 4.2 and 300 K. It is important to note that such cyclesare relatively slow and the temperature sensors are never exposed to humidity. Themaximum cooling rate is given by the test of individual magnets. The main parameters forsuch a test are dictated by the relevant LHC-specifications that are shown in Tables 1and 2. The accuracy budget is defined by the LHC process constraints and it is arbitrarilydivided in equal parts between the uncertainties related to the sensing element and theconditioning electronics.TESTA total number of 100 thermal cycles between 300 K and 4.2 K will be attained by theend of summer 1999. The number of cycles is higher than the specifications of the LHCmachine, which represents a safety margin for taking into account uncertainties due to therelatively small number of sensors under test and to the variability of sensor fabrication. Forsimplicity no monitoring of the thermometers is done when using the cycling cryostat. Thethermometers are calibrated at CERN’s main calibration facility during the first thermalcycle and then on cycles 10, 25, 50 and 100. This calibration facility has been describedelsewhere4.Thermal cycling setupTo simulate the above-mentioned conditions, a simple cycling facility has been built.Apart from thermometers many other cryogenic devices can be installed for investigatingageing processes provoked by thermal cycling without exposure to humidity or air.Cryostat. The main part is the cylindrical helium chamber made of copper (Figure 2).which is located inside a cryostat under vacuum (Figure 1) and equipped with:• three baskets (ø 5 cm x 11 cm) to carry up to 120 thermometers,• an ISO-KF flange to open and close the chamber for manipulating the baskets. Leaktightness is provided by an indium gasket,• a tube inside the chamber fixed on the centre of the ISO-KF flange, used to guide thebaskets,• two control thermometers TT4 and TT5 measuring two different locations inside thechamber,• an electrical connector on the ISO-KF flange to connect the two control thermometers,• the exchange gas flow controlled by inlet and outlet tubes,• an external cooling loop to cool down the chamber,• an external electrical heater EH6 to warm up the chamber,• an external thermal radiation screen which is cooled down by the outlet from the liquidhelium transfer line,• liquid helium from a 500 l storage dewar, forced through the transfer line.3HV8PI1S500l ReservoirTT5TT4FT10HeliumLPCryostatOutletFT13HeliumHPThermometer to cycleScreenEH6FSV7FSV12FSV3HV9 HV11PSV2Figure 1. Piping & instrumentation diagram Figure 2. Loading of the helium chamberInstrumentation. This cycling facility is intended to run without operatorintervention. Thus instrumentation and the relevant control should be simple and robust. AProgrammable Logic Controller (PLC) takes care of all automatic procedures and stops thecycling after a given number of cycles. The instrumentation controlled by the PLC is:• FSV3, a switching valve controlling the transfer of LHe into the cryostat,• Control thermometers TT4 and TT5 (Allen-Bradley® type). The supply of a properexcitation current and the 4-20 mA output signal is ensured by signal conditioners,• EH6, an electrical heater from Minco® with a power of 30 Watt,• FSV7 and FSV12, two solenoid valves.Before starting the automatic procedure it is necessary to adapt the manual valves to thethermal load of the devices under test. The following equipment is used:• HV7, HV9, HV11, three precision needle hand-valves from Hoke® for adjusting incombination with FSV7 and FSV12 the cooling speed,• FT10 and FT13, two flow meters 0 to 2.2 m3/h and 0 to 15 m3/h as a help for the operatorwhen adjusting the precision needle hand-valves,• the pumping group, to establish a vacuum better then 10-6 mbar.For diagnostics a 32-channel paper recorder monitors all electrical signals fromthermometers, heaters and valves positioners.Functional principle. Via an operator interface the duration of the 4.2 and 300 Kplateaus and the total number of thermal cycles to perform is entered into the PLC. Onethermal cycle is composed of four successive phases (Figure 4). Table 3 shows the setup forthis experiment when cycling 120 thermometers. The main heat capacity is stored in thecopper used for lodging the sensors, its approximate total weight is about 0.95 kg.Table 3. Setup for cycling 120 thermometersActuator/Sensor 300 K to 20 K 20 K to 4.2 K 4.2 K to 300 KFSV3 open open closedFSV7 open closed openFSV12 closed open openEH6 0 0 30 WFT10 0.7 m3/h 3.0 m3/h 04FT13 0 0.8 m3/h 010 cycles 15 cycles 25 cyclesTime 3 1 31/4²Time [h]3002001000Cool-down Warm-upFigure 3. Operation Figure 4. Definition of one thermal cycleProcedureLoad. The facility was loaded with the following resistance thermometers:15 x CRT (Carbon Resistance Thermometer) from Allen-Bradley®, USA, Model 100 Ohm,1/8 Watt  4 x CRT from Allen-Bradley®, USA, Model 100 Ohm, 1/8 Watt, placed inside a coppercanister and sealed with Stycast®, by CNRS-IPN, France16 x CRT from TVO®, Russia15 x CX (Cernox™) from Lake Shore®, USA, Model CX-1050-SDAdjustment. The hand-valves were adjusted to obtain a cooling and warming speed ofapproximately 100 K/h. The plateaus at 4.2 K and 300 K were set to 75 minutes (Figure 4).Those parameters are imposed to some extent by the aim of completing 100 thermal cyclesplus 5 long calibrations, within a time span of one year.Operation. Figure 3 shows how the calibration procedures are interleaved within thethermal cycles. Arbitrarily it was assumed that the most significant changes in the sensorcharacteristics would occur during the first cycles, which explains why 0, 10, 25, and 50cycles are chosen as calibration cycles. Common sense and previous experience with othersensing elements led us to tentatively perform the tests in this manner. In principle when anelement drifts, it either drifts indefinitely or it may reach a stable status after a certainnumber of thermal cycles.ResultsThe drift •T of the T-R-characteristic of each thermometer was calculated after 10, 25and 50 cycles as follows:• generation of an individual calibration function T(R) for each thermometer by fitting theinitial calibration points obtained during the first thermal cycle,• application of this calibration function T(R) on the later calibrations,• elimination of the mathematical approximation error by subtracting the difference of thetemperature reference between the cycle under investigation and the initial calibration:•Tn = (T(Rn) - T(R0) ) - (Tref0 - Trefn) (1)Table 4 shows the numerical results of the variation of the sensors characteristics after10, 25 and 50 thermal cycles. Due to the higher sensitivity at low temperatures all thesensors show good results at liquid helium temperatures and most of the populationcomplies with the LHC specifications listed in Table 2. It should be noted however thatsome Allen-Bradley® sensors below 2.2 K exceed the uncertainty of 5 mK as shown inFigure 5. At 20 K it is possible to see that the spread in the uncertainty is lower for sensorswith higher sensitivity, this explains the better performance of Cernox™ when comparedwith TVO®, and TVO® when compared with Allen-Bradley®. This difference is the moreobvious the higher the temperature.5Concerning the Allen-Bradley® it is worth to note that no difference in quality can beobserved between the off-the-shelf and the copper-canister encapsulated sensors. Also oneof the encapsulated samples was damaged by the thermal cycles after about 25 cycles. Theirsensitivity above 100 K is very poor and this type of sensor is typically used with aPlatinum sensor for measuring the higher temperatures. According to the publishedliterature we would have expected a much worse degradation for Allen-Bradley®. Actuallywith some selection procedure, Allen-Bradley® temperature sensors are from the thermalcycling point of view within the LHC specifications. At present, selection rules byperforming thermal cycles and measuring data at room temperature only are beinginvestigated but so far without success. The mean average temperature difference above 20K seems to reach a stable value for Cernox™. This could be an indication that this sensorbenefits from being exposed to 25 thermal cycles before use. When delivered Cernox™ areaccompanied by a low temperature test sheet implying that they have been cycled at leastonce before delivery. For TVO® and Allen-Bradley® no such stabilization behaviour isobserved.Table 4. Numeric resultsCalibration 1after 10 cyclesCalibration 2after 10+15 cyclesCalibration 3after 10+15+25 cyclesT [K] Sensor Name ²T 1 [mK] VT1 [mK] ²T 2 [mK] VT2 [mK] ²T 3 [mK] VT3 [mK]1.8 CX -0.7882 0.5535 0.5037 0.6802 -0.6513 0.4330TVO -0.0455 0.6606 0.3939 1.0351 -0.3835 1.2027AB 2.7427 2.0045 3.3095 2.8231 -1.9148 4.27032 CX -0.8491 0.4570 0.9300 0.5250 -0.7064 0.3422TVO 0.0978 0.6431 0.6417 1.1550 -0.5706 1.3620AB 3.0962 2.2987 3.9094 3.2699 -2.5211 4.90803 CX -1.0763 0.3334 0.2618 0.3449 -0.8783 0.2863TVO -0.4328 1.2796 -0.4419 1.9982 -1.1056 2.3854AB 7.6528 4.1628 7.2454 5.9068 -3.4715 8.60934.7 CX 1.7374 2.0156 -2.9928 2.1274 -5.2280 2.0487TVO 0.7607 2.1165 -1.5941 3.9934 -2.2640 4.3788AB 17.3037 8.3450 13.5193 12.7921 -8.3744 17.530020 CX 3.0921 2.4428 -2.2611 2.5180 -1.3179 2.5545TVO -1.3065 18.2370 -14.8668 31.5075 -20.3284 36.2329AB 207.4665 110.8418 139.2465 206.5669 -246.6199 421.531850 CX 4.7892 5.0310 -14.1263 5.1998 -14.9530 5.2845TVO -13.7263 57.6131 -74.9515 93.2377 -93.4202 108.2195AB 811.1598 499.0036 483.8471 951.0693 -1327.8682 2471.722580 CX 9.1676 6.9240 -20.7874 7.3440 -25.6557 7.3030AB 1388.3302 969.4480 798.4592 1825.3065 -2768.8821 5457.5423TVO -12.7281 83.8031 -116.6825 140.3333 -150.2212 154.0933180 CX 13.0871 13.5885 -43.7546 13.4965 -53.3914 13.2617TVO 96.4536 215.0169 -149.6401 216.1717 -191.2922 262.8603270 CX -28.2666 18.5580 -105.6869 16.2912 -120.5796 18.4223TVO -110.2638 157.1709 -485.0942 133.4017 -635.3769 124.22956024681012-2.5.875-1.250.625 00.6251.25.8752.5-3-2.25-1.5-0.75 00.75 1.52.25 3-10-7.5-5-2.5 02.5 57.5 10Number, T = 1.8 KCX, Lake Shore CRT, Allen-BradleyCRT, TVO'T [mK]024681012-12 -9 -6 -3 0 3 6 9 12-40-35-30-25-20-15-10 -5 0 5 10 15 20 25 30 35 40Number, T = 20 KCX, Lake Shore CRT, TVO'T [mK]024681012480440400360320280240200160120-80-40 0 40 80 120160200240280320360400440480Number, T = 20 KCRT, Allen-Bradley'T [mK]Figure 5. Distribution curves at 1.8 K and 20 K for different temperature sensors after 10 (black), 25 (grey)and 50 (white) thermal cycles (keep in mind the different •T-scales).CONCLUSIONA simple and robust, automatic cycling facility has been designed, commissioned andoperated. The first results of the thermal cycled cryogenic thermometers clearly show thatsensors with higher sensitivity across the temperature operating range have a much betterreproducibility of their characteristics. Below 4 K all sensors presented behave similarly butfor temperatures above 20 K, Cernox™ has much better stability against thermal cycles.However, Allen-Bradley®, Cernox™ and TVO® satisfy the LHC specifications.One of the aims of this test was to identify selection rules for the Allen-Bradley®. Nocorrelation in performance has been found between stability at low temperatures andvariations of resistance at room temperature, encapsulation, etc. From our results it is clearthat it is extremely difficult to improve the performance of off-the-shelf Allen-Bradley®resistors by some simple recipe.The experimental data suggest that Cernox™ characteristics are improved if they arepreviously exposed to at least 25 thermal cycles.RhFe wire-wound and thin-film temperature sensors have also been investigatedalthough more work is still required for analysing their results. The main difficulty is thepoor sensitivity of this type of temperature sensors below 20 K, which is up to one order ofmagnitude lower than Allen-Bradley®.7We intend to complete 100 thermal cycles by the third quarter of 1999 and later wewill also investigate other types of temperature sensors like germanium (bulk and thin-film), diodes, etc. Although not considered for equipping the LHC ring, these other sensorsmay find potential applications in other components of the complex cryogenic system forCERN's accelerators and detectors.REFERENCES1. Ch. Balle and J. Casas, Industrial-type Cryogenic Thermometer with Built-in Heat Interception, in:"Advances in Cryogenic Engineering", Vol. 41B, Plenum, NY (1996), p. 1715.2. E. Chanzy et al., Cryogenic Calibration System using a Helium Cooling Loop and a TemperatureController, in: "International Cryogenic Engineering Conference 1998", Institute of Physics Publishing,Bristol (1998), p. 751.3. J-F. Amand et al., Neutron Irradiation Tests in Superfluid Helium of LHC Cryogenic Thermometers, in:"International Cryogenic Engineering Conference 1998", Institute of Physics Publishing, Bristol(1998), p. 751.4. Ch. Balle, J. Casas and J-P. Thermeau, Cryogenic Thermometer Calibration Facility at CERN,in:"Advances in Cryogenic Engineering", Vol. 43A, Plenum, NY (1997), p. 741.5. L.M. Besley, The Long-term Stability of Resistance Thermometers for Temperatures below 30 K, in:"International Cryogenic Engineering Conference 1980", p. 807.6. A.L. Zahariev, D.A. Dimitrov and J.K. Georgiev, Characteristic Stabilization of Thin Film PlatinumThermometers during Thermal Cycling between 5 K and 300 K, in: "Cryogenics", Volume 36, Number8, Elsevier (1996), p. 631.7. L.M. Besley, Stability of some Cryogenic Carbon Resistance Thermometers, in: "The Review of ScientificInstruments", Vol. 54, Number 9, (1983), p. 1213.8. D. Giraudi, P.P.M. Steur, D. Ferri, F. Pavese, Resistance-temperature characteristics of the new Cernoxcryogenic thermometers in the range 1.5-350 K, in: "Proceeding of TEMPMEKO-96", (1996), p 1559. F.J. Kopp and T. Ashworth, Carbon Resistors as Low Temperature Thermometers, in: "The Review ofScientific Instruments", Vol. 43, Number 2, (1972), p. 327.10. W.L. Johnson and A.C. Anderson, The Stability of Carbon Resistance Thermometers, in: "The Review ofScientific Instruments", Vol. 42, Number 9, (1971), p. 1296.

Influence of Thermal Cycling on Cryogenic Thermometers

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