The infrared absorption spectra of four Ume-aluminosihcate glasses have been studied at high temperatures in the spectral range 1 to 5 µm. The glass composition varies essentially by the FeO content. The effect of temperature is pointed out up to 1450 °C. The emission spectrometry technique used is appHed to thin slabs of semitransparent materials heated in plane-parallel platinum crucibles exposed to strong temperature gradients. The absorption coefficient is identified, for each wavelength, by a non-linear constraint optimization technique. As an illustration of the major influence of the spectrum on the heat exchanges in semitransparent devices, a modeling of the combined conductive/radiative heat transfer is performed in a glass wall

Fabris, Rino

Huclin, Jean Christophe

Lallemand, Michel

Sakami, Mohamed

English

Repositorium für Naturwissenschaften und Technik

Origina PaperIdentification method for infrared absorption spectra ofsemitransparent media by their emission dataApplication to lime-aluminosilicate glasses at high temperaturesRino Fabris and Jean Christophe HuclinVétrotex International, Chambéry (France)Mohanned Sakami and Michel LallennandLaboratoire d'Etudes Thermiques, ENSMA CNRS, Poitiers (France)The infrared absorption spectra o f four Ume-aluminosihcate glasses have been studied at high temperatures in the spectral range1 to  5 | im . The glass composition varies essentially by the FeO content. The effect o f temperature is pointed out up to 1450 °C. Theemission spectrometry technique used is appHed to th in slabs of semitransparent materials heated i n plane-parallel p la t inum cruciblesexposed to strong temperature gradients. The absorption coefficient is identified, for each wavelength, by a non-linear constraintoptimization technique. As an illustration o f the major influence o f the spectrum on the heat exchanges in semitransparent devices,a modeling o f the combined conductive/radiative heat transfer is performed in a glass wal l .Identifizierung von Infrarotabsorptionsspektren halbdurchlässiger Materialien an Hand der Emissionsdaten. Anwendungauf Kalk-Alumosilicatgläser bei hohen TemperaturenDie Infrarotabsorptionsspektren von vier Ka lk-Alumos i l i ca tg läse rn wurden bei hohen Temperaturen i m Spektralbereich  1 bis  5 j i muntersucht. Die Glaszusammensetzung wies erhebliche Schwankungen des FeO-Gehaltes auf. Der Tempera tu re in f luß bis 1450 °Cwird aufgezeigt. Die Emissionsspektrometrie wi rd auf d ü n n e Platten aus ha lbdurch läss igem Mater ia l angewendet, die i n planparalle-len Platintiegeln aufgeheizt und dabei hohen Temperaturgradienten unterworfen waren. Der Absorptionskoeffizient w i r d für jedeWellenlänge mit Hilfe eines nichtlinearen Optimierungsverfahrens (mit Zwangsbedingung) ermittelt . Zu r I l lustrat ion des ü b e r r a g e n -den Einflusses des Spektrums auf den W ä r m e a u s t a u s c h in ha lbdurchläss igen Medien w i r d ein Mode l l für den kombinierten W ä r -meübergang durch Leitung und Strahlung in einer Glaswand entwickelt.1. IntroductionDuring the melting of glass and most o f the formingprocesses, i.e. in the temperature range between 1000and 1500°C, heat is transferred mainly by radiation (ratio of radiative flux/conductive flux >20) in the infraredspectral interval ranging from  1 to  5 }xm. Thus, thermalmodehng of coupled conduction/convection/radiationheat transfer of glass tanks or forming devices requiresthe knowledge of the optical data of the basic material,especially of the absorption spectrum and its evolutionwith temperature in the solid and liquid states.There are three main spectrometry methods for thedetermination of absorption spectra, the reflectionmethod [1 and 2], the transmission method [3 to 5] andthe emission method [6 to 8]. The last one appears to bethe most practical way at high temperatures, but i t requires special care. Indeed, on the one hand, i f the glasssample is directly introduced into a furnace, i t is neces-sary to separate the proper emission from the spuriousradiation o f the heater and, on the other hand, i f theReceived November 12, 1993, revised manuscript January 11,1994.glass is studied by the th in plane-parallel crucible tech-nique, high-temperature gradients are generated in thespecimen and have to be account for in order to deter-mine the true physical spectrum [9 to 11].I n the present work, the absorption spectra o f fourlime-aluminosilicate glasses are identified by their emission up to 1450 °C in the wavelength interval  1 to  5 pm.The experimental emission data is obtained in presenceof controlled temperature gradients by an original t h incrucible technique and a point-by-point non-linearidentification process is used.2. Principle of the experimental methodThe glass samples are plane-parallel slabs o f Semitrans-parent Materials (labeffed S T M ) in non-isothermal situ-ation. The specimens are deposited in a plat inum cru-cible heated electrically up to 1450 °C. A t each run, twodifferent samples o f glasses are simultaneously investi-gated. The first one is the studied sample and the otherone is a reference glass (a high-cobalt containing glass)o f very high opacity in the whole wavelength range (vis----Riño Fabris; Jean Christophe Huclin; Mohamed Sakami; Michel Lallemand:a)I7Íinterface 1 (s lab// environment /7Q) ^ I\ semitransparent medium \ ^  i 0 / • 1interface 2 (slab^environmentFigure 1. Geometry o f the plane-parallel semitransparent slab.1.50.90.31 1 1 1 ^ = 2 p m / //Vil Ly'{j=i.\}m)^  4 pmr x?= 5 pm1 1 1 1 10Figure 2. Theoretical spectral intensity as a function o f theoptical thickness for different wavelengths.ible and infrared). One assumes the temperature field inthe slabs to be monodimensional.When a temperature distribution is set up in a perfectplane-parallel semitransparent slab o f thickness,  d (fig-ure 1) l imited by two reflective boundaries, its internalspectral emission is governed by the Radiative TransferEquation (RTE):dy+ K,L,{y)  n^K,Ll [T{y)\ (1)where Lx(y) is the monochromatic intensity, L!i[T{y)] the local Planck function and the absorption coef-ficient.The problem consists, for a given wavelength, in theidentification o f the coefficient /c^, appearing in thedifferential equation (1), from the knowledge o f the corresponding normal spectral outgoing intensity, Lf^^(d). The monochromatic normal emergent intensity o fthe slab is given by( 1 - g i )[1-^1^2 exp ( -2 /c ; t^)]'^(\-Q2)LUTr)cxp(-K,d) + + K,cxp(-K,d)jLUny)] 0[Qxp(K;^y)  + Q2 Qxp{K;,y)]dy where and Q2 are the reflectivities of the STM/air andthe STM/crucible interfaces, respectively, and 7} is thecrucible bottom temperature.3. Identification methodThe spectral absorption coefficient of a glass may beobtained by an identification process through solvingapproximately the non-linear equationL,(K,,d) Lr\d) (3)by the constrained optimization method [8]min\\Lx(K;,,d)  Lf^'(d)\\ subject to the conditionsII f^M\  ^ ^ / i  ^ Real(4)where in the expression o f LX{KX, d), given by equation(2), the measured temperature profile is inserted. I nequation (4), is an a pr ior i information chosen in sucha way that for each wavelength equation (3) has a uniquesolution. I n [11] equation (4) was approached by a Newton-Gauss iterative method; here a dichotomymethod is used.The a pr ior i information is a result of the mathemat-ical analysis of the model. I n figure  2 the evolution ofthe theoretical intensity has been plotted as a func-tion o f the optical thickness, X, or opacity, z K^d, fora set of wavelengths; the different curves were calculatedwi th a mean specimen temperature of 1400 C and a temperature difference o f 200 K between its two interfaces. I t is observed for some values of optical thick-ness that the two curves and Lf^^ cross each other intwo points, furthermore, passes through a maximumat TQ. Accordingly, equation (3) has two mathematicalsolutions, one of them being physically irrelevant. Butfor T < To the problem has a unique solution. Conse-quently, according to figure  2 one subjects the non-linearproblem to the supplementary constraint z < 1.7. I f noattention is paid to this special behavior, the solutionsare dependent on the initially chosen values and wrongspectra may be recovered, as shown in figure 3.As a matter of fact the proposed problem belongs toill-posed problems (no unique solution, sensitivity tonoise).4. Experimental procedureThe glass sample holder is made up of pure platinum( (150x30x6 )mm^); i t is electrically heated by an ac current supply (figures 4a and b). Brass electrodes cooled— ° _ = ­== ° -=--Identification method for infrared absorption spectra . by water circulation are clamped on the side pieces andhelp to hold the device in place. The sample holderallows a three-dimensional displacement. The mainplatinum device provides four cylindrical crucibles (diameter 12 mm), each one of a different depth so thatsample thicknesses can be achieved between 1.2 and4 mm.One assumes that in the longitudinal dimension notemperature gradients are present. On the other hand,since the glass slab exchanges heat simultaneously bynatural convection and by radiation wi th the surround-ings,  a high temperature gradient results for the thick-ness o f the slab. Small holes {dll  0.5 mm/5 mm) aredrilled in the platinum in the vicinity of the glass/plati-num interface in order to measure the bot tom slab tem-perature by conventional pyrometry.A complete sketch of the experimental facility isshown in figure 5. A water-cooled pipe is placed uponthe glass sample, which serves to collect the useful infra-red beam in the normal direction. Two diaphragms areconnected to it in order to define the fixed solid angleof observation; i t is helpful for elimination of spuriousradiation coming from other samples and crucibles. Theradiation beam is brought by a parabolic off-axis mirrorwhich focuses on the entrance slit o f a grating mono-chromator (a single beam Perkin-Elmer 112 G connect-ed to a microcomputer). Two kinds of detectors havebeen used, a PbS cell in the 1 to 2.6 | im region and a pneumatic detector of Golay for the 2.6 to 5 j im region.The chopping frequencies were 20 Hz and 1 kHz, respectively, for the Golay cell and the PbS detector. Theelectrical signal was analyzed by a lock-in amplifierE G & G 5206.The emitted intensity of the sample is measured foreach wavelength by determining the ratio between theemission of the sample and that of the reference medium, collected alternatively, by means of a sampleholder translation from the sample to the reference glass,thus, providing the relative spectral emissivity^Omes(5)The surface temperature, T êf, of the reference glass ismeasured by a pyrometer at 0.63 | im. Then, the surfacetemperature of the sample is deduced by comparison inthe spectral opacity range of the reference glass emissionand the sample emission, according to the relationship{LT% L%Tgi) (6)where L5^|f and Lf^^f denote the measured emissionintensity of the sample in the opacity range of the spec-t rum (i.e. where the absorption is very strong) and theoutgoing intensities. L^x(Tref) and L^xiTgy) are the Planckfunction at the temperature of the reference surface andof the studied glass, respectively.Figure 3. Comparison o f the exact spectrum w i t h the recoveredspectra o f a borosilicate glass as a function o f the in i t i a l valuesfor the non-linear identification process. Curve 1: recoveredspectrum w i t h the in i t ia l value <  TQ, curve 2: recovered spec-t r u m w i t h the in i t ia l value > TQ, curve 3: exact spectrum.a)\cut line side pieceb)Figures 4a and b. Schematic setup o f a glass sample holdermade up o f pure plat inum ( ( 1 5 0 x 3 0 x 6 ) mm^); a) cross-sectionin thQ x-y plane, b) cross-secdon i n the x z plane. Numbers1 to 4 are glass crucibles. : cut line in the x z plane.parabofic mirrormonochromotorPE 112 G detectorsPbS & Golaychopper pyrometer- glass studiedsynchron detectionEG &  G 5206 n platinium dispositionreference glassFigure 5. Experimental setup.^ 9 -5. Studied glassesThe infrared absorption spectra o f four l ime-a lumino-silicate glasses (whose compositions are reported i ntable 1) have been investigated by means o f the emissionof the non-isothermal glass slabs. These four glassesmainly differ in their ferrous iron content f rom which-=-----—Table 1. Glass compositions in w t %glass Si02 AI2O3 CaO C Fe203 FeOA 62 15 23 0.003B 61.5 15 23 - 0.5 0.171C 61.5 15 23 0.07 0.5 0.374D 60 15 23 - 2 0.75reference glass: E-glass w i t h 2 w t % Co1 2 3 4 ^ in |jm ^ Figure 6. Infrared absorption spectra o f lime-aluminosilicateglasses A to D at 1300°C. 0 \ \ K I \ \ L c:21 2 3 4 5 in |jmFigures 7a and b. Comparison o f the absorption spectra o flime-aluminosilicate glasses A and D at 1300°C and at roomtemperature; a) glass sample A , b) glass sample D .the absorption band centered around 1.2 | i m originateswhich is o f major interest for thermal application inglass manufacturing.1 2 3 4 ^ in pm ^ Figure 8. Absorpt ion spectra o f glass sample B at temperatures20, 800, 1000, 1150 and 1300°C.The bot tom face of the crucible was carefully pol-ished and the normal reflectivity of the glass/platinuminterface has been determined by the Fresnel formulataking into account the optical constants of both glassand platinum. The thickness of the glass layer was obtained by means of a video device which allows the optical control of the crucible f i l l up.A temperature difference ranging from 100 K for the1 m m thick crucible to 180 K for the 4 m m crucible wasobserved. A l l measurements have been performed in airat atmospheric pressure.6. Identified spectra of lime-aluminosilicateglassesFor each wavelength of the investigated spectral rangethe emitted intensity is measured. Then, the temperatureprofile (assumed to be linear) is inserted in the expression of the theoretical intensity emission of the slab(equation (2)) and the optimization method (equation(4)) is developed according to the constraint r < 1.7 determined from figure 3.1 10 1 1 1 1 1 1 1 / - n^=20°C.^  1450°C / -1/ \ ^ ll V \\1 1 1 1 ^ >=1300°C 900°C1 1 1 1 2 3 4X? in urnFigure 9. Absorption spectra of glass sample C at temperatures20, 900, 1300 and 1450 °C.---- —-— ­=— =I n figure  6 the absorption spectra of the four speci-mens have been plotted in the wavelength range from 1 to  4 | im at 1300°C. I t can be seen that the four absorp-tion spectra have the same trend, which are character-istic of the same vitreous network. The influence of theiron content, the only species which has been changed,appears clearly. A broad absorption band of Fe^^ ionscentered around 1.1 ^ m can be noted, i t is attributed toelectronic transitions. Beyond 2.7 fim (the hydroxylpeak) the spectrum is due to atomic arrangement v ibrations. From 2.7 to  4 [im the absorption coefficient isinfluenced by the concentration in hydroxyl groups [12and 13]. Beyond 4.2 | im the observed strong increase ofthe spectra (the so-called thermal opacity range) is thehigh-frequency wing due to vibrations of the silica ran-dom lattice.I n figures  7 a and b the absorption spectra o f glassspecimens A and D at room temperature and at 1300 °Care reported and figures  8 and  9 display spectra forspecimens B and  C for different temperatures rangingfrom room temperature to 1450 °C. The main featuresare: the spectral shift o f the opacity cut-off toward theshort wavelength when the temperature increases [4 and14] and, as a general trend, the lowering of the magni-tude of all spectra, specially in the wavelength regionfrom 2.7 to  4 |xm. A n exception is the clear glass (A)for which the converse effect is observed in the intervalbetween  1 and 2.7 | im . However, the temperature effecton the absorption spectrum, even in the extreme tem-perature conditions, is weak when compared to the effectdue to a small percent variation in the Fe203 content.7. ApplicationThe experimental results described in section 6. havebeen used to illustrate the influence of the ferrous bandin the heat transfer of silicate glass. A plane-parallelglass wall is considered whose spectrum is of a variablemagnitude in the spectral band from  1 to 2.7 [im. Thewall has a thickness of 5 cm and exchanges heat by con-duction and radiation only. The boundary conditionsare as follows: One interface is at the fixed temperature, 1500°C, o f emissivity  0.4, the other interfaceis exposed to a heat loss flux up to 100 kW/m^, its emis-sivity is 82  1. The refractive index is taken as «  1.5,the thermal conductivity of the medium is k  2 W / ( m K ) and is assumed to be temperature-inde-pendent.The absorption spectrum is divided into four graybandsÀ  0.5 to 1.0 ^m:  0.01 c m - ^A  1 to 2.7 ^im: K;,  0.05, 0.5, 1.0 and 3.0 c m - ^À  2.7 to 4.5 ^im:  2.5 c m ' ^ ;À  4.5 to 15 | im: K"^  100 c m - ^The one-dimensional coupled conductive/radiativeheat transfer problem has been solved by a multiflux0 0.01 0.02 0.03 0.04 0.05d in m Figure 10. Influence o f the 1 to 2.7 [im band on the temperatureprofile o f a one-dimensional semitransparent wa l l . One tem-perature boundary is prescribed, the other is exposed to a con-stant heat loss.method [9] and the results are shown i n figure 10. I tis demonstrated that the temperature gradient increaseshighly w i th the darkening o f the second infrared spec-t rum band.8. ConclusionsA special simple experimental emission spectrometry device has been used for the absorption spectra determi-nation o f semitransparent media. Its effectiveness i ncreases highly w i th elevated temperature. I t has the advantage to work in presence o f important temperaturegradients. Thanks to the non-linear proposed identif i-cation technique a clear identification o f the spectrumis obtained.9. Nomenclature9.1. Symbolsconstraint factord thickness in cmk thermal conductivity W / ( m K )specific intensity in W/(m^ sr)Planck function in W/(m^ sr)n refractive indexS T M semitransparent medium (material)T temperature in K y abscissarelative emissivitywall emissivityabsorption coefficient in cm~^X wavelength in | i mQu Qi reflectivityT optical thickness or opacity^max maximum optical thickness9.2. Superscriptsmes measurerel relative----=  = =  == = =  = = = =  = =  =9.3. Subscr iptsf bottom of cruciblegl glassX monochromatic quantityref reference1,2 interfaces10. References[1] Gentzel, L . : Messung der Ultrarot-Absorption von Glaszwischen 20 und 1360°C. Glastech. Ber. 24 (1951) no. 3,p. 55-63.[2] Neuroth, N.: Der Temperatureinfluß auf die optischenKonstanten von Glas im Gebiet starker Absorption. Glas-tech. Ber. 28 (1955) no. 11, p. 411-422.[3] Blazek, A.: Strahlungswärmeleitfahigkeit von Glas. Glas-tech. Ber. 49 (1976) no. 4. p. 75-81.[4] Wedding, B.: Measurements of high-temperature absorp-don coefficients of glasses. J. Am. Ceram. Soc. 58 (1975)no. 3-4, p. 102-105.[5] Adès, C. : Propriétés optiques des verres de silicates à hautetempérature. University of Toulouse (France), thesis 1989.[6] Berg, J. L : Near infrared absorption coefficient of moltenglass by emission spectroscopy. Int. J. Thermophys. 2 (1981) p. 381-394.[7] Goldman, D. S.; Berg, J. I.: Spectral study of ferrous ironin Ca-Al borosilicate glass at room and melt temperature.J. Non-Cryst. Solids. 38 & 39 (1980) p. 183-188.[8] Banner, D.: Propriétés radiatives des verres et des fontesde silicates en fonction de la température. Ecole CentraleParis, thesis 1990.[9] Fabris, R.: Modéhsation des transferts thermiques couplésconvection-conduction-rayonnement dans les milieuxsemi-transparents fluides. Détermination expérimentaledes propriétés radiatives des silicates alumino-calciques à haute température. University of Poitiers (France), thesis1991.[10] Fabris, R.; Lallemand, M.; Huclin, J. C : Absorption spec-tra of fused alumina-lime silicate. In: Eurotherm Seminar21, Lyon 1992, p. 271-279.[11] Sakami, M.; Lallemand, M.: Spectres infrarouges de verresà haute temperature par inversion de l'émission de couchesanisothermes. J. Phys. III. (In prep.)[12] Scholze, H.: Le verre. Nature, structure et propriétés. Paris:Institut du Verre, 1974.[13] FanderUk, I.: Optical properties of glass. Amsterdam (etal.): Elsevier 1983.[14] Grove, F. J.; Jellyman, P. E . : The infra-red transmission ofglass in the range room temperature to 1400 °C. J. Soc.Glass Technol. 39 (1961) no. 1, p. 3-15.<- 0494P00i

Identification method for infrared absorption spectra of semitransparent media by their emission data Application to lime-aluminosilicate glasses at high temperatures

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Identification method for infrared absorption spectra of semitransparent media by their emission data Application to lime-aluminosilicate glasses at high temperatures

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