A summary of heat-flux sensor calibration data.This paper presents a statistical evaluation of the responsivity data on a number of heat-flux sensors, calibrated cal·i·brate tr.v. cal·i·brat·ed, cal·i·brat·ing, cal·i·brates 1. To check, adjust, or determine by comparison with a standard (the graduations of a quantitative measuring instrument): using an electrical substitution radiometer radiometer (rā'dēŏm`ətər), instrument for detection or measurement of electromagnetic radiation; the term is applied in particular to devices used to measure infrared radiation. as a transfer standard up to 5 W * [cm.sup.-2]. The sensors, furnished by the customers, were of circular-foil or thermopile thermopile: see thermoelectricity. type. Comparison of the NIST (National Institute of Standards & Technology, Washington, DC, www.nist.gov) The standards-defining agency of the U.S. government, formerly the National Bureau of Standards. It is one of three agencies that fall under the Technology Administration (www.technology. and the customer measured responsivity values showed that the measurements agree within 3% for more than half the number of sensors tested, so far. Considering the variation in the customer calibration techniques and the wide measuring range of the sensors used in the calibration, the agreement is encouraging. Key words: calibration; heat flux; sensors; transfer technique. ********** 1. Introduction The Optical Technology Division (OTD OTD Of the Day OTD Office of Technology Development OTD Observed Time Difference OTD Doctor of Occupational Therapy OTD Out The Door OTD Overseas Trained Doctors OTD Optical Transient Detector OTD On Time Delivery OTD Order-To-Delivery ) at the National Institute of Standards and Technology National Institute of Standards and Technology, governmental agency within the U.S. Dept. of Commerce with the mission of "working with industry to develop and apply technology, measurements, and standards" in the national interest. (NIST) has been developing techniques to calibrate To adjust or bring into balance. Scanners, CRTs and similar peripherals may require periodic adjustment. Unlike digital devices, the electronic components within these analog devices may change from their original specification. See color calibration and tweak. heat-flux sensors using thermal radiation thermal radiation Process by which energy is emitted by a warm surface. The energy is electromagnetic radiation and so travels at the speed of light and does not require a medium to carry it. from high-temperature blackbodies. Past calibrations at other laboratories and round-robin experiments demonstrated large differences in the measured responsivity of these sensors. The objective of the NIST program was to address this unacceptable discrepancy by developing traceable calibration techniques [1]. As an outcome of this effort, the OTD started offering a heat-flux sensor calibration service. The calibration range was up to 5 W * [cm.sup.-2], referenced to a transfer-standard electrical substitution radiometer. Reference [2] gives a description of the transfer calibration method. Recently, some customers expressed concern about the NIST transfer technique because of the large differences in the measured responsivity, as high as 10% to 15%, between their measurements and the NIST calibration results. The disagreement in measured responsivity values between different laboratories has been a continuing problem [3] in heat-flux sensor calibration. Large uncertainty in the measurements to some extent is a contributing factor for the observed differences. However, the 10% to 15% differences reported by some customers were even larger than the reported measurement uncertainties. Consequently, heat-flux sensor calibrations particularly at high flux levels, has been a major topic of discussion at the American Society of Mechanical Engineers (body) American Society of Mechanical Engineers - (ASME) A group involved in CAD standardisation. (ASME ASME - American Society of Mechanical Engineers ) and American Society for Testing and Materials International (ASTM ASTM abbr. American Society for Testing and Materials ) committees in recent years. To resolve the discrepancies in the calibrations and to contribute to a proper understanding of factors involved in heat-flux sensor calibration, OTD initiated several studies. As a part of this activity, OTD offered to perform a blind check-calibration of sensors for the heat-flux measurement community. The objective was to understand whether the large differences in calibration were widespread or just limited to a few isolated cases. The response to the check-calibration offer was overwhelming, resulting in the calibration of a number of sensors for various organizations, both government and private. This report presents results of the OTD calibrations of the sensors and compares the measured responsivities with calibration data furnished by the participating organizations. 2. Transfer Calibration Procedure The OTD transfer calibration technique works on the principle of electrical substitution radiometry Radiometry A branch of science that deals with the measurement or detection of radiant electromagnetic energy. Radiometry is divided according to regions of the spectrum in which the same experimental techniques can be used. . The reference standard is a room-temperature electrical substitution radiometer (ESR ESR - Eric S. Raymond ). The ESR calibration is traceable to the High Accuracy Cryogenic Radiometer (HACR HACR Hispanic Association on Corporate Responsibility HACR Heating, Air Conditioning & Refrigeration HACR High Accuracy Cryogenic Radiometer HACR Helicopter Active Control Rotor ), the U.S. primary standard for optical radiation power [4], through a chain of calibrations. The radiant source for the calibration is a 25 mm diameter dual-cavity variable temperature blackbody blackbody Theoretical surface that absorbs all radiant energy that falls on it, and radiates electromagnetic energy at all frequencies, from radio waves to gamma rays, with an intensity distribution dependent on its temperature. (VTBB VTBB Vacuum Tower Bottom Blend (petroleum refining) ) mounted on a computer-controlled horizontal translation stage. Figure 1 shows a schematic layout of the VTBB apparatus and the calibration scheme. The direct resistance heating Resistance heating The generation of heat by electric conductors carrying current. The degree of heating for a given current is proportional to the electrical resistance of the conductor. of the VTBB graphite tube element using large AC currents at low voltages allows quick heating and cooling of the cavity. An optical pyrometer Noun 1. optical pyrometer - a pyrometer that uses the color of the light emitted by a hot object pyroscope pyrometer - a thermometer designed to measure high temperatures measures the VTBB cavity-partition temperature by sensing radiation from one end of the cavity. A PID controller See PID. regulates the power supply to maintain the partition temperature to within [+ or -]0.1 K of the set value. The VTBB operating temperature range is from 993 K to 2973 K. The reference standard ESR is water-cooled and is suitable for continuous operation. During calibration, the test heat-flux sensor and the reference ESR are located outside the blackbody exit in a test plane at a fixed distance from the blackbody aperture. Different calibration ranges are possible by a combination of the sensor location and the VTBB temperature. The distance between the blackbody exit and the test plane is about 12.5 mm for calibrations up to 50 kW * [m.sup.-2]. For calibrations in the lower ranges of 25 kW * [m.sup.-2] and 10 kW * [m.sup.-2], the corresponding distances are about 62 mm and 140 mm, respectively. [FIGURE 1 OMITTED] After stabilization of the temperature to the set value, the VTBB is located in front of the reference ESR and the test sensor, sequentially. The output signals from the instruments are recorded for the test duration in approximately 0.4 s intervals. The sensor responsivity is calculated by a linear regression Linear regression A statistical technique for fitting a straight line to a set of data points. fit to the sensor signal (mV) data for different values of incident flux (W * [cm.sup.-2]) as measured by the radiometer. The measured responsivity of the sensor is expressed in mV * k[W.sup.-1] * [m.sup.2] or mV * [W.sup.-1] * [cm.sup.2]. The regression curve Noun 1. regression curve - a smooth curve fitted to the set of paired data in regression analysis; for linear regression the curve is a straight line regression line fit for the data is generally linear with regression coefficients close to unity. The relative expanded total uncertainty [5] in the measured responsivity is about 2% for a coverage factor of k = 2. 3. Intercomparison Results The check-calibration comprised of measuring the responsivities of a total number of twelve sensors received from the participating organizations. The sensors calibrated were of thermopile (Schmidt-Boelter) and circular-foil (Gardon) types, which are sensitive to total flux, including both radiative and convective components. The design range of the sensors varied from about 5 W * [cm.sup.-2] to 550 W * [cm.sup.-2]. The transfer calibration range was up to 5 W * [cm.sup.-2], which covered only a fraction of the design range of some of the sensors. However, the limited range calibrations of these sensors provide useful data in statistical evaluation of the differences in the measured responsivities. The check-calibration program covered a period of about 1 year. The transfer technique procedure included the calibration of a reference sensor before measurements on a customer sensor to monitor the long-term repeatability of the procedure. The reference sensor is of Schmidt-Boelter type with a design range of 10 W * [cm.sup.-2]. The responsivity value of the reference sensor is 1.191 mV * [W.sup.-1] * [cm.sup.2] with a standard deviation In statistics, the average amount a number varies from the average number in a series of numbers. (statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. of 0.7% as determined from several calibrations over a period of more than 5 years. Table 1 summarizes the results of the OTD transfer calibration results along with the responsivity data received from the participants. Since the objective is to make a statistical assessment, the names of the individual participating organizations have not been identified. The responsivity values shown refer to the incident flux and the differences refer to deviation from the OTD measured value. The expanded uncertainty (k = 2) in OTD measurements varied from 2% to 2.4%. However, the corresponding uncertainty data for the participant's furnished values were not available. 4. Discussion The inter-comparison study performed is the equivalent of a reverse round-robin calibration. The responsivity values of the sensors measured at NIST correspond to using identical experimental setup and instrumentation. The only major variable is the sensor. Therefore, the results of this study have the broader implication of assessing how the OTD transfer technique stands in relation to other techniques. Except for two sensors, which showed deviations of more than 8%, all the other sensors show a favorable comparison. The calibration methods used by the participating organizations included blackbodies or radiating panels to irradiate irradiate /ir·ra·di·ate/ (i-rad´e-at) to treat with radiant energy. ir·ra·di·ate v. 1. To expose to radiation, as for diagnostic or therapeutic purposes. 2. the sensors, and the heat-flux at the sensor was calculated by radiometric principles or reference standard calorimeters. However, in most of the cases the view-angle was large in contrast to the narrow view-angle used in the NIST calibrations. Considering the wide variation in the calibration techniques, sensor types and the design ranges, the favorable comparison observed in this study is encouraging. In addition to the check-calibrations discussed above, several other calibrations on heat-flux sensors are in progress on a continuous basis. Figure 2 presents a broader comparison of the responsivities of most of the sensors calibrated so far using the transfer technique. The OTD measurements and the responsivity value furnished by the participating organizations agree within 2% for about half the number of sensors calibrated, so far. The histogram histogram or bar graph Graph using vertical or horizontal bars whose lengths indicate quantities. Along with the pie chart, the histogram is the most common format for representing statistical data. plot shown in Fig. 3 is close to a Gaussian distribution A random distribution of events that is graphed as the famous "bell-shaped curve." It is used to represent a normal or statistically probable outcome and shows most samples falling closer to the mean value. See Gaussian noise and Gaussian blur. with fewer sensors showing large deviations from the OTD calibration. [FIGURE 2 OMITTED] The check-calibration results demonstrate that the calibrations from different organizations and the OTD measurements agree reasonably well. However, what level of deviation is acceptable depends on the end application. A proposed ISO (1) See ISO speed. (2) (International Organization for Standardization, Geneva, Switzerland, www.iso.ch) An organization that sets international standards, founded in 1946. The U.S. member body is ANSI. (International Standards Organization See ISO. ) standard [6] specifies an expanded uncertainty of 3% based on a 95% confidence level. A previous round-robin calibration by the Federal Aviation Administration Federal Aviation Administration (FAA), component of the U.S. Department of Transportation that sets standards for the air-worthiness of all civilian aircraft, inspects and licenses them, and regulates civilian and military air traffic through its air traffic control had shown larger deviations [3]. The current comparison demonstrates a considerably improved agreement between different calibration methods. A recent round robin [7] between various fire testing laboratories and primary testing laboratories shows similar agreement as the present study. However, the data for the present study comprises a larger number of sensors and more varied calibration methods. [FIGURE 3 OMITTED] Heat-flux is essentially the equivalent of total irradiance ir·ra·di·ant adj. Sending forth radiant light. [Latin irradi in radiometric terms. The uncertainty in heat-flux sensor calibration is rather large and often inevitable when compared to conventional radiometric measurements involving small spectral irradiance levels. The reasons for the large uncertainty are several. To achieve high flux levels, the sensor location during calibration is close to the radiant source, which results in wider view angles. Therefore, the sensor response depends on non-uniformity in radiation emitted by the different regions of the source and on the angular response of the sensor. Other modes of heat-transfer, particularly convection, can contribute significantly to the total flux at low and moderate irradiance. These factors, along with other variables specific to the particular calibration setup, influence the final measurement uncertainty. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. Moffat [8], uncertainty estimates for a convective environment would be about [+ or -]2% repeatability, [+ or -]5% total uncertainty in calibration, and [+ or -]10% total uncertainty in the application measurements. For a majority of sensors, the difference is between 2% and 3%. This spread represents a situation where several effects, often difficult to control, influence the calibration in all of the methods. 4. Concluding Remarks A review of responsivity measurements performed on several heat-flux sensors shows that the flux-based transfer calibration and the source-based methods often employed by other organizations compare favorably. The agreement between various methods is within 3% for most of the sensors. Thus, the cases or approaches giving larger deviations need careful evaluation to determine the technical reasons leading to significantly larger discrepancies. The generally good agreement of the responsivities between different techniques reinforces the confidence that the flux transfer calibration based on traceable electrical substitution radiometry can serve as a baseline measurement for calibrating sensors beyond the present transfer calibration limits. The baseline measurement up to 5 W * [cm.sup.-2] serves as a reference to evaluate calibration of the sensor requiring source-based measurements. Table 1. Transfer calibration of heat-flux sensors up to 5 W * [cm.sup.-2] Sensor Responsivity (mV * [W.sup.-1] * [cm.sup.2]) no. Customer OTD Difference S01 3.102 3.010 3.1% S02 3.324 3.236 2.7% S03 2.950 2.891 2.0% S04 0.032 0.034 -3.6% S05 0.013 0.013 -3.0% S06 1.133 1.158 -2.2% S07 0.871 0.852 2.2% S08 0.520 0.540 -3.7% S09 0.484 0.498 -2.8% S10 0.793 0.787 0.8% S11 0.175 0.193 -9.3% S12 0.589 0.642 -8.3% Accepted: February 28, 2005 Available online: http://www.nist.gov/jres 5. References [1] A. V. Murthy, B. K. Tsai, and C. E. Gibson, Calibration of High Heat Flux Sensors at NIST, J. Res. Natl. Inst. Stand. Technol. 102(4), 479-487 (1997). [2] B. K. Tsai, C. E. Gibson, A. V. Murthy, E. A. Early, D. P. DeWitt, and R. D. Saunders, Heat Flux Sensor Calibration, NIST Special Publication 250-65 (2004). [3] P. C. Sarkos, R. G. Hill, and R. M. Johnson, Fire Calorimetry calorimetry (kăl'ərĭm`ətrē), measurement of heat and the determination of heat capacity , DOT/FAA/CT-95/46, FAA Technical Center, Atlantic City International Airport Atlantic City International Airport (IATA: ACY, ICAO: KACY, FAA LID: ACY) is a public airport located nine miles (14 km) northwest of the central business district (CBD) of Atlantic City, in Atlantic County, New Jersey. , New Jersey (1995) pp. 173-184. [4] T. R. Gentile, J. M. Houston, J. E. Hardis, C. L. Cromer, and A. C. Parr, The NIST high accuracy cryogenic radiometer, Appl. Optics 35, 1056-1068 (1996). [5] B. N. Taylor and C. E. Kuyatt, Guidelines for Evaluating and Expressing the Uncertainty of NIST Measurement Results, NIST Technical Note 1297 (1994). [6] ISO/TS 14934-1, Fire testing--Calibration and use of heat flux meters (2002). [7] W. M. Pitts, A. V. Murthy, J. L. de Ris, J. R. Filtz, K. Nyard, D. Smith, and I. Wetterlund, Round Robin Study of Total Heat Flux Gauge Calibration, NIST Special Publication 1031 (2004). [8] R. J. Moffat and C. Danek, The NIST/NSF Workshop on Heat Flux Transducer transducer, device that accepts an input of energy in one form and produces an output of energy in some other form, with a known, fixed relationship between the input and output. Calibration: Final Report, National Institute of Standards and Technology, Gaithersburg, MD (1995). A. V. Murthy Aero-Tech, Inc., Hampton, VA and G. T. Fraser and D. P. DeWitt National Institute of Standards and Technology, Gaithersburg, MD 20899-8441 murthy@nist.gov About the authors: A. V. Murthy, an aero-space engineer, is the president of Aero-Tech, Inc., Hampton, VA; Gerald T. Fraser is a Group Leader and David P. DeWitt is a faculty staff of the Optical Technology Division of the NIST Physics Laboratory. The National Institute of Standards and Technology is an agency of the Technology Administration, U. S. Department of Commerce. |
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