RU2490609C1 - Method of testing pyrometers in working conditions - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: proposed method comprises measuring and recording the reference source equivalent temperature by atmospheric radiation in spectral band of one line of strong absorption and reference source temperature by contact gage, comparing the recorded temperatures and correcting the gain of measurement channel. Note here that ambient temperature is measured while gain correction is performed using the results of comparison between equivalent temperature of atmospheric absorption line and ambient temperature.

EFFECT: higher accuracy and stability of measurements.

2 cl

Description

The present invention relates to the field of metrological support of pyrometric systems, including recording objects with a temperature close to ambient temperature, and can be used in temperature control systems for axleboxes of rolling stock of railways, both in linear control points and in manual pyrometers temperature control by the lineman.

A known method for checking pyrometers under operating conditions, including alternately presenting to the pyrometer radiation from the object under study (measuring channel) and a test object (comparison channel), the temperature of which can be controlled. When the signals in the channels are aligned, the temperature of the test object is measured, which is taken as the temperature of the studied object. This method, called the compensation method in the theory and practice of measurements [see Great Encyclopedic Dictionary. Physics], has been used in industrial designs of Signal-technik GmbN HOA-90S outdoor cameras measuring the temperature of axleboxes of rolling stock of railways and installed on highways in France and Germany since the 1990s, as well as in RF patent No. 1904, published on 16.03. 1996. Its advantage lies in the possibility of conducting relatively accurate measurements even when using a meter with a non-linear temperature dependence of the output signal. The disadvantages of this method are methodological errors arising due to the non-identical optical characteristics of the comparison channel and the measuring channel, as well as the non-ideal test object, the emissivity of which can differ significantly from unity. In addition, such a method is not operational, since it does not allow temperature measurements of objects in real time.

There is also a known method for calibrating pyrometers under operating conditions, which consists in sequentially presenting to the measuring channel after each measurement the radiation of test objects (passive and active), the temperature of which is measured by control thermal sensors, calculating by the microprocessor module the difference in responses from the active and passive emitters, and comparing the obtained difference with the given settings stored in the programmable memory of the microprocessor module. If the microprocessor control module detects a discrepancy, the automatic gain control mode is activated by means of a digital (integrated) potentiometer (RF patent No. 2374112, published November 20, 2009). This method allows a piecewise linear approximation of the nonlinear temperature dependence of the output signal in a tabular manner for threshold temperature values of the controlled object. However, it requires, depending on the temperature of the outside air, as well as on the contamination of the inlet window, periodic calibration according to an external certified test object. It is also obvious that such a calibration method does not allow satisfactory accuracy of measuring the temperature of objects outside approximation points, and when changing not only the temperature of the object, but also the ambient temperature.

There is also a known method for calibrating pyrometers under operating conditions, which uses the response of the measuring channel to infrared radiation from the “sky background” in the inspection zone of the axle box when measuring the temperature of the axle boxes in the axle box (RF patent No. 2099226, published on December 20, 1997). The disadvantage of this method of calibrating the reference voltage is the dependence of the "sky background" on the state of the weather and time of day, even if the spectral sensitivity range of the radiation receiver in the measuring channel is limited by an atmospheric "transparency window", for example, 8-12 microns.

There is also a known method for verifying pyrometers under operating conditions, the closest in technical essence to the proposed one, where the operational absolute calibration of the pyrometer is performed using infrared radiation from the operator’s open mouth (RF patent No. 2194255, published December 10, 2002). The disadvantages of this method, the method of checking pyrometers in the working environment is the need to meet the requirements for pairing the field of view of the pyrometer and the oral cavity of the operator, which is not possible for each pyrometer and that requires special operator skills. It should be noted that the atmosphere exhaled by the operator can significantly distort the spectral composition of the radiation (due to enrichment with carbon dioxide, water vapor and other ingredients), which also requires special operator skills. Finally, there are no representative statistics on the emissivity of the oral cavity of the average operator; therefore, this method of operational calibration cannot pretend to be a metrologically sound method.

The problem solved by the proposed method is the self-verification of the pyrometer before measurements to the exact extent when, as a reference source of infrared (IR) radiation, an object known in temperature is presented to the measuring channel with an emissivity close to unity (an emitter with an emissivity equal to unity is considered absolutely black body, blackbody).

The technical result when using the proposed method is to increase the accuracy and stability of the metrological characteristics of the pyrometer by quickly checking the calibration characteristics of the pyrometer using a high-precision emitter (with an emissivity of more than 0.95) and automatically amending the results of subsequent measurements.

The specified technical result is achieved by the fact that in the known method of calibrating pyrometers under operating conditions, including measuring and recording the equivalent temperature of the reference source by its radiation and its temperature by the contact sensor, comparing the recorded temperature values and adjusting the gain of the measuring channel, measuring and recording the equivalent temperature carried out by atmospheric radiation in the spectral range of one of the lines of strong absorption, measure the temperature swirling medium and adjustment of the gain is carried out based on the results of comparison equivalent radiation absorption lines of atmospheric temperature and the ambient temperature. In the particular case of performing the registration of the equivalent temperature is carried out by atmospheric radiation in the spectral range of the line of strong absorption of carbon dioxide.

New in the proposed method is the measurement and registration of equivalent temperature from atmospheric radiation in the spectral range of one of the strong absorption lines, which acts as a reference source of infrared radiation, while the measuring channel is presented with a temperature-known object with an emissivity close to unity (blackbody), allowing its use in operating conditions.

Strong absorption lines are possessed by carbon dioxide, water vapor, and some other atmospheric components (see the Handbook on infrared technology. / Ed. Wolf W., Csis G. In 4 volumes. / T.1. Physics of infrared radiation: Trans. English - M.: Mir, 1995, p. 349, table 5, p. 409). The most beneficial is the use of atmospheric carbon dioxide radiation, which has several strong absorption spectral lines: 2.7 μm, 4.27 μm and 15 μm. The benefit is due to the fact that, firstly, the absorption in these lines is so great that changing the height of the sight even up to 4 kilometers above the Earth’s level does not practically change the shape of the lines, while for water vapor the changes are significant (http: //www.astronet .ru / db / msg / 1188291 / text). Secondly, the 4.27 micron line is located in the atmospheric window, which allows the use of serial industrial developments of radiation detectors, that is, receivers with a high level of technology development.

The use of carbon dioxide radiation as a reference source also makes it possible to bring the temperature of the reference source as close as possible to the ambient temperature in the surface layer, that is, to practically level out the influence of such a known weather effect as the temperature inversion, sometimes observed in the surface layer of the atmosphere. The high reliability of the coincidence of the ambient temperature measured in the surface layer with the temperature of the 150-meter surface layer of carbon dioxide (which corresponds to the level of 95% absorption) is due to the following theoretical and practical prerequisites. It is known that there are three types of heat transfer: thermal conductivity, convection and radiant exchange [TSB, article “Heat Transfer”]. It is also known that the thermal conductivity of carbon dioxide is almost two times less than that of air, and the specific gravity is almost so many times higher [Physical Encyclopedia, article “Gas”]. This means that the rate of change in the temperature of carbon dioxide due to thermal conductivity and convection significantly lags behind the rate of change of temperature of the remaining mass of air. It is very important that the absorption spectral bands, and hence the carbon dioxide emissions, do not at all coincide with those of nitrogen, oxygen and water vapor - the other main gaseous ingredients of the atmosphere. And this leads to the fact that the radiant exchange in the lower atmosphere of carbon dioxide occurs only between it and the earth's surface, without affecting other gases in this process. As a result, the temperature of carbon dioxide is much closer to the temperature of the Earth's surface than to the temperature of the atmosphere.

The use of gas column radiation in a strong absorption line when calibrating the pyrometer under operating conditions does not require the field of view of the pyrometer and the reference source to be coupled, and, most importantly, provides high stability and independence of the metrological characteristics of the reference source from the operator and the device.

Implementation of the proposed method is as follows. As a reference source, one of the strong absorption spectral lines is used, for example, atmospheric carbon dioxide in the spectral range from 4.2 μm to 4.45 μm (line 4.27 μm), while the ambient temperature is recorded by an external temperature sensor, for example, alcohol thermometer. The required spectral range is formed by an interference filter of thin non-absorbing films of the appropriate number and thickness. The radiation detector in this case is performed, for example, on the basis of the semiconductor material Cd _x Hg _1-x Te (cadmium, mercury and tellurium alloy) with a molar composition x = 0.3, which, when cooled to minus 30 ° C, provides a spectral sensitivity range up to 5 microns. The optical channel of the pyrometer is formed with an intermediate image and a mechanical modulator with mirror blades, which minimizes the effect of scattered light and self-radiation of the structure to temperatures of objects below the environment. The calibration characteristic of the pyrometer constructed using the indicated optical design and the cooled receiver has such useful properties that it changes (within a relatively wide range) the transparency of the input window, the sensitivity of the radiation receiver, and the ambient temperature by a parallel shift in the converted coordinates. And then the compensation of this shift is carried out by changing the gain, checking the pyrometer from the reference source at only one temperature point. The last operation is easily algorithmized in the microprocessor control module.

The tests, including full-scale ones, showed that the proposed verification method allows even winter stability of the calibration characteristic not to fall outside the range of ± 2.5 ° C, which meets the requirements for measuring instruments by the State verification scheme of measuring instruments temperature (GOST 8.558-93- Part 3. Radiation pyrometers)

Claims (2)

1. A method for calibrating pyrometers under operating conditions, including measuring and recording the equivalent temperature of the reference source by its radiation and its temperature using a contact sensor, comparing the recorded temperature values and adjusting the gain of the measuring channel, characterized in that the measurement and registration of the equivalent temperature are carried out according to atmospheric radiation in the spectral range of one of the lines of strong absorption, measure the ambient temperature, and the correction coefficient This amplification is carried out by comparing the equivalent radiation temperature of the atmospheric absorption line and the ambient temperature. 2. The method of checking pyrometers under operating conditions according to claim 1, characterized in that the measurement and registration of the equivalent temperature is carried out by atmospheric radiation in the spectral range of the line of strong absorption of carbon dioxide.