The testing of the properties of packed-particle beds and regenerators at cryogenic temperatures as low as 4 K is an essential part of the magnetic refrigeration research and development program at the Los Alamos National Laboratory. We envision magnetic refrigeration and heat pump systems operating in various ranges from 4 K to ambient temperature and above. Only pressurized helium gas appears suitable as the heat exchange fluid for the low-temperature applications. Because published data on the properties of porous beds at low temperatures is sparse, we have found it necessary to develop an experimental test apparatus to study the properties of various configurations of beds and regenerators. Two of the well-known methods for such studies are the steady-enthalpy-flux method and the single-blow transient method. We have developed an experimental system in which gas flow can be suddenly switched to an alternate better (or colder) flow in step-function fashion at temperatures from 4 to 300 K. This apparatus will yield information on steady-state heat transfer and friction factors as well as on the transient behavior. Such information is very important to the design of high-efficiency magnetic refrigeration systems. This paper describes this experimental apparatus and presents the results and analysis of recent measurements on packed-particle beds in the liquid helium and liquid nitrogen temperature ranges

Barclay, J. A.

Overton, W. C. Jr.

Sarangi, S.

Stewart, W. F.

UNT Digital Library

Los Al~ NManal Laborat~ Is opwotod by Fm Unlwslly 01 CWfPfnl~ Ior Iha UnllOd Slolas Oopmtmonl 01 Enofgy under ContraCl w-740$ EN&3S.LA-uR--8j-235lDE83 017320TITLE:EXPERIMENT TO DETERMINE PROPERTIES OF PACKED PARTICLEBEDS AND REGENERATORS AT CRYOGENIC TEMPERATURESAUTHOR(S):J. A. Barclay, W. p %rezton: .Tr.,W. F. Stewart,and S. SarangiSUBMITTEDTO: 1983 Cryogenic Engineei-ingConference, Colorado Spi-ings,CO -Also to be published in the Advances in Cryogenic EngineeringPlenum Publishing Company. New YorkDISCLAIMERTbbropxlwom~md uanoauuntofwork pmufalbymrosoncy o(thoUnllodS.tMaOovornrmnt, NaltkrlbUnltdSutm&mmtmany~Wtkf,~mytitMrompbyoco, makm mrywmrorrty,eap or implial, oruournm ●rylogollloblllty urrqmml-bflltyfortlm socumcy, cornploto~wumfulnm o(mry Infrwmatlmk ammatus, pwxlua,ot~dlocfaod, or ropmnlslhal Itnum would nolinfrlngo privatelyownodrighlo. Rofsr-am horohr 10 ony IpMlc arnrnorchl pmducl, promn, of oomim by trdo mm.. hrformrkmonufaclumr, or cMhmwlm rhea M ~rily camllula or imply i~ ondmmonl, romn-rmndmlkwr,or favurhr~ by tho United SIata Wvomment or ●ny qency Ihard, Tbo VW●nd ophrkom of ●Awwi oapruuod heroin do not ~rlly slmte or rofkct lb of tlmUnltal Sl~lcc (hwemrnonl or nny ogorrcyIhormf.By acccplsnco 01 Ihlrn ●llclf!. the rmbllnhor Iocoqmma Ihm Ihg U S CJrjvnrnm#nl rnlmnn ● nonn~clunwa, roynlly-lrao Iicong@ 10 publlsh or roproducoIha publlnhnd fftfm 0! thin COnlrllluMn, 0’ IIJ nlhw ulhorn 10 do go, lot U 9 (30vernmoru DUrpW09w~lb’’!l!!l; ,,, ,,,:~~~~[a~~~L.sAlam~~ewMexic.87545Los Alamos National LaboratoryEXPERIMENT TO DATERMINE PROPERTIES OF PACKED PARTICLEBEDS AND REGENEWTORS AT CRYOGENIC TEMPERATURES*J. A. Barclay, W. C. Overton, Jr., W. F. Stewart, andSunil Sarangi#Los Alamos National Laboratory, Los Alamos, NM 87545.- .. ..INTRODUCTIONThe testing of the properties of packed-particle beds and regene-rators at cryogenic temperatures as low as 4 K is an essential part ofthe magnetic refrigeration research and development program at the LoeAlamos National Laboratory; We envision inagneticrefrigeration andheat pump systems operating in various ranges from 4 K to ambient tem-perature and above. Only pressurized helium gas appears suitable asthe heat exchange fiuld for the lo~-temperature applications. Becausepublished data on the properties of porous bede at low temperatures insparse, we have found it necessary to develop an experimental testapparatus to study the properties of various configurations of bedsand regenerators. Two of the well-known methods for such studies arethe steady-enthalpy-fluxmethodi and the 8in?le-blow transientmethod.2 We have developed anexperimental s,stem in which gas flowcan be suddenly switched to an alternate hotter (or colder) flow instep-function fashion at temperatures from 4 to 300 K. This apparatuswill yield information on steady-state heat tr@nmfer and frictionfactors as well as on the transient behavior. Such Information isvery important to the design of hi8h-efficiency magnetic refriglratiansystems,This paper describes this experimental apparatus and presentsthe results and ana ysis of recent measurements on packed-particlebeds in the liquid helium ad liquid nitrogen temperature ranges.TiII Leave frum— .—,.—— — ..._‘ II!Indian l.n~tituteof Technology, Kharagpur 721 3(X!,India*Work perform , under chc auspices of the U, S. Department of Energyw{.thsupport L~OIn DARYA and NASA/KSC.ii: 5~.=br- ..—— ———— ———— —-LN2 11II su.OP ! VAI. IDYNEPMP W901ik0 ANALOG FLExI13LE: PROCESSOR DISK DRIVEda AP>;II:! e;[“%’%]wLHc!:~ +II/J11.1 ill!L,, -,,- ,. .~ 1.-7-Iu1-.—— — ———- —..m:qE*FERENCE---- -—-Fig. 1. Schematic of apparatus and data acquisition system. portionsenclosed by dashed lines are inside a large dewar. The gas flow rateis measured by an external flow meter at gas output.13XPERIME?TTALThe key to the operation of the experimental system, shown sche-matically in Fig. 1, is the flow cycling valve. This is ~ precision-machined valv~j that allows switching and/or blocking of the gasctrem flow even at liquid helium temperatures in accordance with thevarious cycles of operation depicted in Fig. 2, The valve can beoperated manually by rotating a control shaft which extends out ofthe dewar. Switching times are of the order of 1/2 to 1 s. pressur-ized hell’umgas enters the system, as shown in Fig, 1, at a ratedetermined by the setting of a control valve at gas output, The gas1s cr)nlecl initially to LN2 temperature by the heat exchanger f.ndi-car.ed.Itmay be further cooled to 4 K by heat excharigein the LHe pot.Temperatures above 4 K can be &chieved by switching the gas flowthrough Lt,eheater.The cold $JHSenters the cycling valve, as shown in Fig. 2 (A).In position (h), Che gas temperature, prussurc, and flow rate can beset as required. Switching to position (B) tt’fFig. 2, one can bringthe tent bed 10 thermal equilibrium at gas-etream flow ternperatura,In po8tt,lon(C), cold ~iis input flows throufiha 1OOO-W heater bed. lnth!.~pualtlon the gas flow 1s 1(IK to 20 K hotter than the input gas,where, ag~ln Lhc flow vnriablea can be set a’~requ[red. In position(0) the hottvr gns C{lnbe divortud thrcu~h the te~t bed.OUT - —.+.—-. ——————— —.r)*4---- [c!:>—--———- ..—m)-.**sI *7‘., *S*a*S—*—--- ~—-..— ——— ——--JFig. 2. Schematic showing various modes of gss flow through thecycling valve, heater, and test bed.The response cC the test bed to this temperature step function isrecorded automatic ly by the computer system indicated in FiA. 1.This system measures practically simultaneously the temperatures ofall the Au-.O7% Fe-chromel sensors shGwn in Fig, 3. At a chosen time,these thermocouples are switched by the r~:ed-relayand A/D system ofthe HP-3497datb acquisition electronics so that 11 thermocouples areread in about 1/2 s, We chose to repeat the measurement of the wholeset every 6 s. These data were then storad in the memor~ of the HP87kM computer and here ~vaila!)lefor later analysis or output to aprintet as desired.The thermocouple locations in Elm test bed are described in cy-lindrl.calcoordinati~s(r,z), where r - 0 is the ce,~te;,r = a is theinside radiuu, z = O is th-aleft-meet bed screen of l?ig.3, and z = L1s the right-most screen. Points z M -L/4 and + 5 L/4 are in the freegan stream. ‘t’hcrmocoupleare at (0,-L/4), (O,L/4), (O,L/2), (.~/2,1./2),(0,3L/4), (0,51./4),(n,L/2), and (a+t,L/2). lt wag hoped thatthese Last two weuld show a tempcruture difference between tho inoi.deantioutside wnll of the contal.ner. This was not realized on chc firstrune bocauw thermocouple leads for the (&tt,L/2) position broke. Theconical shape at Lho I.nlL nnd output of the bed Waa eelectt!din the/Au-O.07 % Fe- CtiROMELTHERMOCOUPLE LEADSS. S. CAPILLARI ES /EPOXY FILLED ,S.S. TUBE1; u~uLJ(S.S. CONEI[< L h fi~> ‘/I\SOFTSOLDER5.0 cm--l ~n fS.S. RINGS100 MESH SCREENS.S. BODY~(\0.030 cm WALL TEST BED FILLERGd METAL POWDERPb BALLS, etc.Fig, 3. Schematic of :ypical test bed showing thermocouple ‘posi-tions. Length L between screens = 4.9 cm, wall thickness t = 0.03 cmand inner radius a = 2.67 cm. Input gas stream enters at the left.belief that the gas stream flows over the input and output screenswould be uniform over the cross sectional area.We note in Fig. 1 the pressure gauges DP (differential pressureacross bed), AP (absolute pressure at bed Gutput), and DP (d?.fferen-tial pressure) across the OFM (orifice flow meter). These gauges areof the variable reluctance type and show gooL characteristics at roomtemperature. However, the calibration was not consis~ent at low tem-peratures. These were then moved to a room-temperature position,which necessitated long connec~ing tubes from the low-temperatureregion near the bottom of the dewar. Due to the associated uncertaint-ies in the DP gau8e readings, we will 90L repor~ here our attempts tofit initial friction fuctor data to an x-y type of Ergun equation.”We need only to mention that our y-values, which contain the measuredAp across the DP gaugcj were inordlnatnly large. However, ourReynolds number calculations are based on flew velocities measured bya well-calibrated flow meter nt the point indicated by “gas output” inrig. 1. Accordingly, the Re values are believed to be accurate.EXPEKIMKNTA[,RESULTS AND ANALYSISi # 1 IRUN NUMBER I)21K7BED PRESSURE= IatrnFLOW RATE = 0.0034 g-cm-2-s-1L I I I d00 30 60 50 I20LAPSE TIME (S)Fig. 4. Response of lead-ball test bed to hot-to-cold step function.Thermocouple loc?tlons input at (0,-L/4), in bed, and output ‘at(0,SL/4) are described in text. The helium flow gas pressur~ was 3.0 atmtithe whole bed to come to approximate equilibrium at 90 K at a flowrate of 0.11 g-s-1-cm-2 (i.e., the total flow rate in the screenarea of 22.37 cm2 times this value or 0.25 8-s-1 through the wholebed). The cycling valve was then sw~tched from position (D) to posi-tion (B) in about 1 s, allowing cold gas at 75.5 K co be introducedinto the bed. Note in Fig. 4 that the measured input temperaturedrOFpCd 10 K from 88 K to 78 K in only about 5 s. This is as close toa qtep fl,nctionss we could obtain in this temperature range. In the4 K to 20 K range, switching times were somewhat faster.Figure 5 shows the response to switching from 97K to 77K, andin Fig, 6we see the corresponding response to switching from 14.5 Kto 4.5 K. It is surpr!sfng that the temperature at (().5L/4)dropsbefore that at (0,3L/4), which does not occur in the cases shown inFigs. 4 and 5. We believe this arises from enhanced peripheral straamvelocity due to the greatly decreased viscosity of the He gas at theselow temperatures.The temperature versus time curves at different locations wereunnlyzed to determine the heat transfer coefficients. The procedurz1s essentially the same as the maximum slope method of LockeS exceptt.hn~(a) The effects of (i.)longltudlnnl conduction, (11) gas disper-100 I i I I -~”~RUN NUMBER D7N3/-%, BED PRESSURE = 2 atm\ FLOW RATE = 0.006 g-cm-z -s-~\\‘!,Jj!&,=,,‘1OUTPUT(1/2, I1/2) ~,\‘k,(o, I/4 ) ‘-%- 0---- --c----- _-- O----*INPUT7oo~ - ++LAPSE TIME (rein)Fig. 5. Response of the lead-ball bed to a hot-to-cold step function”in the 97 K-to-75 K temperature range at a pressure of 2.C atm.sion and (iii) temperature-dependent matrix specific heat havebees considered in deriving the theoretical curves, and(b) Comparison of the theoretical and experimental profiles we:ebxsed on an average slope over 0.2 ~ Elg~ 0.8 ,instead of the maximum tilope.It has been showns that the average slope method overcomes someof the shortconiin.gsof the maximum slope method and may be used withlarger grid size.The theoretical curves are computed by solving the followinggoverning equations:W8#lJ—--.-AAdyJ+@ -098 3Y2 E(1)(2)RUN NUMBER 021M9 BED PRESSURE =301mFLOW RATE =0.011g-cm-z-s-l)INPUT ‘-a ___--+_ ,Jo I I150 200 250I)0LAPSE TIME (S)FiR. 6. Response of the lead-ball bed to a hot-to-cold step func-tion in the 15 K to 4 K temperature range at a pressure of 1 atm.y = dimensionless length coordinate = (h A x)/(G Cp) ,T = dimensionless time = (h A t)/[ps ~~(1 - f)] ,A_(h~L)/(GC) ; As= kse/(GCPL) ,~g= kge/(GCpL$and a = C~/Co .Thermal conductivities k~e and kge are eifective values for matrix andflui(l,respectively; C~ is the solid specific heat while U is a localaverage value: P~ - solid density; C = gas specific heat; A _Feffective area; h - heat transfer coe ficient; and G = mass flow rate.These equations are solved on the HP-87 XM computer using thecentered difference approach7 and the dimensionless gas temperature01 is determined as a function of dimensionless length y and time T.T~leaveruge slope Mg/A(T/y) over the interval 0.2 ~~g : 0.8 forvafious values of y are computed and stored. It may be observed thatT/y - (t/>:)(c cp)/[P~ c~(l - fj]does not contain Lhc heat transfer coefficient h. Hence the oboervedhtig/A(T/y) for 0.2 S@R s 0.8 may be computed explicitly, which,ou comparison with theoretical rcsul~~, yield~” the value of y andhence h. The hcuc transfer coefficient h i,tiKelated to the Stantonnumber St accord,lngco St u h/(G Cp).IL m;~ybu observed that our VAIUVS differ ~l}~nlfi.cantlyfrOm thecorrcla~~on fiivenin Ref. 8 (i.e., St - 0.23 Re-(] .’] pr-2/3), and do.Table 1. Reynolds and Stanton numbers for data of Figs. 4-6.——Run Temp. Range (K) Lc)CatiOn Rea St St (Ref. 8)Number Matrix Gas rIrdtial Entry – ‘a tD21M9 90 75 0 1/4 20.41/2 1/2o 3/401D 7N3 97 76 1/4 14.11;2 1/201D21K7 15 4.5 0 If4 26.01/2 1/2o 3/4010.085 0.1190.0910.1300.0820.070 0.1330.0840.143oOo\8 0.1070.1130.0270.055aRe is based on hydraulic diameter and interstitial fluid velocity.anot in themselves show any systematic behavior. This is probably dueto the flow channeling in the bed and ron-uniform flow in the randunlypacked bed. Also, in the liquid helium range, some effects may be ~attributed to the extremely low viscosity of the cold helium gasflow. We intend to carry out a systematic Snvest<.gationof theproblem of flow distribution in randomly i~ackedbeds and the resultingeffects on h(,attransfer, esp~cially at cryogenic temperatures.References:1. J. C. Kim and E. B. Qvale, 1970, Analytical and experimental studiesof compact heat exchangers, Advnuces in Cryogenic Engng., 16:302.2. C. C. Furnas, 1930, Heat tra=sfer from a gas stream to a bed ofbroken solids, Am. Inst, of Chem. I!ngng., Trans. Vol. XXIV:142.3. The first model~ycllng valve was made by J. E. Dyson, Los AlamosNational Laboratory, LOS Alamos, New Mexico,4. S. Ergun, 1952, Mass transfer ra~e in packed columns: lts analogyto presst-rc10ss, Chcm. Enpjnpj.Progress, 48:227.5. G. L. Locke, 1950,—Heat trunsfer~nd flow ch~racterlsties in porous.—.so.Lids,TR No. 10, Dept. of Mech. Engnfi., Stanford University.—--—6. G. F. lio~nayr,—— —--——— ..-l~Exuct maximum slopes for transient matrixheat transfer testing, Int. J. lletitMass Transfer, 9: 67i.7. D. U. Von Ro~enberg, 19~,——-----—” --–—-—“Murho(lsof Numerical Solutions ofPartial Differential Equnt~ons,” /uoericani;lsil~ler,New York.8. W. M. KaYs and A. L. London, 1964, “Comp.\:tHeat Exchangers,”McCraw Hill, New york.

Experiment to Determine Properties of Packed Particle Beds and Regenerators at Cryogenic Temperatures

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Experiment to Determine Properties of Packed Particle Beds and Regenerators at Cryogenic Temperatures

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