The experimental capability to generate and utilize concentrated solar flux has been demonstrated at a number of facilities in the United States. To advance this research area, the National Renewable Energy Laboratory (NREL) has designed and constructed a versatile High Flux Solar Furnace (HFSF). Research is ongoing in areas of material processing, high temperature and UV enhanced detoxification, chemical synthesis, high flux optics, solar pumped lasers, and high heating rate processes. Surface modifications via concentrated solar flux, however, are currently performed without the means to accurately monitor the temperature of the surface of interest. Thermoelectric and pyrometric devices are not accurate due to limitations in surface contact and knowledge of surface emissivity, respectively, as well as interference contributed by the solar flux. In this article, we present a noncontact optical technique that simultaneously measures the directional spectral emissivity, and temperature of the surface during solar processing. A Fourier Transform Infrared (FT-IR) spectrometer is coupled to a processing chamber at NREL’s HFSF with a fiber-optic radiation transfer assembly. The system measures directional emission and hemispherical-directional reflectance in a spectral region that lacks contribution from solar flux. From these radiative property measurements during solar processing, the spectral emittance and temperature at the measurement point can be obtained. The methodology, validation measurements, and in-situ measurements during solar processing of materials are presented. Knowledge of surface temperature during solar processing is an important parameter for process control. Based on validation measurements for spectral emittance, the temperature error associated with the novel instrument is less than ±5 percent for surfaces of mid-range emittance. The error decreases for surfaces of higher emittance. This is far better than optical methods which are “lost” in terms of knowing the appropriate emittance for conversion of measured radiant intensity to temperature.

1.
Beckman, P., and Spizzichino, A., 1963, The Scattering of Electromagnetic Waves from Rough Surfaces, Macmillan, New York.
2.
Bohren, C. F., and Huffman, D. R., 1983, Absorption and Scattering of Light by Small Particles, John Wiley and Sons, New York.
3.
Brewster, M. Q., 1992, Thermal Radiative Transfer and Properties, John Wiley and Sons, New York, NY.
4.
DeWitt, D. P., and Incropera, F. P., 1988, Theory and Practice of Radiation Thermometry, D. P. DeWitt and G. D. Nutter, eds., John Wiley and Sons, New York.
5.
Farquaharson, S., Cosgrove, J. E., Haigis, J. R., Smith, W. W., Solomon, P. R., and Markham, J. R., 1993, “Multi-plexed Fiber Optic Collector for FT-IR Reflectance and Radiance Spectroscopy,” SPIE Conference proceedings, B, pp. 144-153.
6.
Lewandowski, A., Bingham, C, O’Gallagher, J., Winston, R., and Sagie, D., 1990, “Performance Characterization of the SERl High Flux Solar Furnace,” presented at the International Energy Agency, 5th Symposium on Solar High Temperature Technologies, Davos Switzerland.
7.
Markham, J. R., Best, P. E., and Solomon, P. R., 1994, “Spectroscopic Method for Measuring Surface Temperature that is Independent of Material Emissivity, Surrounding Radiation Sources, and Instrument Calibration,” Applied Spectroscopy. Vol. 48, No. 2.
8.
Markham
J. R.
,
Best
P. E.
,
Solomon
P. R.
, and
Yu
Z. Z.
,
1992
, “
Measurement of Radiative Properties of Ash and Slag by FT-IR EiTiission and Reflection Spectroscopy
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
114
, pp.
458
464
.
9.
Markham
J. R.
,
Kinsella
K.
,
Carangelo
R. M.
,
Brouillette
C. R.
,
Carangelo
M. D.
,
Best
P. E.
, and
Solomon
P. R.
,
1993
, “
Bench Top FT-IR Based Instrument for Simultaneously Measuring Surface Spectral Emittance and Temperature
,”
Rev. of Sci. Instru.
, Vol.
64
, No.
9
, pp.
2515
2522
.
10.
Markham
J. R.
,
Solomon
P. R.
, and
Best
P. E.
,
1990
, “
An FT-IR Based Instrument for Measuring Spectral Emittance of Material at high Temperature
,”
Rev. Sci. Instru.
, Vol.
61
, No.
12
, p.
3700
3700
.
11.
Meyers
V. H.
,
Ono
A.
, and
DeWitt
D. P.
,
1986
, “
A Method for Measuring Optical Properties of Semitransparent Materials at High Temperatures
,”
AIAA J.
, Vol.
24
, p.
321
321
.
12.
Salikhov, T. P., Kan, V. V., and Riskiev, T. T., 1994, “New Principles of Determining the True Temperature in Solar and Imaging Furnaces,” ASME Proceedings of the Joint Solar Engineering Conference, San Francisco, CA.
13.
Seigel, R., and Howell, J. R., 1992, Thermal Radiation Heat Transfer, 3rd ed., Hemisphere, Washington, DC.
14.
Solomon, P. R., Carangelo, R. M., and Carangelo, M. D., 1994, “Recent Advances in FT-IR Technology,” Proceedings of the SPIE/AWMA Meeting Optical Instrumentation for Gas Emission Monitoring and Atmospheric Measurements, Vol. 2366, pp. 156–165.
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