SU699360A1 - Thermal radiation measuring device - Google Patents

Description

The invention relates to thermal measurements and can be used in the study of heat exchange processes in the energy sector and various heat engines. Battery sensors are known that are used as sensing elements and are a thermopile assembled from series-connected thermocouples, the working ends of which are mounted on a black foil plate. The thermo-emf value developed by the thermopile is proportional to the radiant flux and depends on the equilibrium temperature of the foil plate and the temperature difference between the working (hot) temperatures and the cold ends of its thermocouples. IL The disadvantage of this battery sensor is the instability of the temperatures of the cold ends of the thermopile, which affects on measurement accuracy. The closest in technical essence to the proposed is a radiation compensated thermoelement. comprising a case, receiving and compensating plates attached to the case, having coatings with a face-to-incident side with varying degrees of absorption each, thermopile and measuring device 2. The disadvantage of this thermoelement is. outputting the cold ends of the thermopile to the front side of the plates, which contributes to their direct heating from the incident radiant flux and creates additional heating of the compensating plate, attaching the hot ends to the front surface of the receiving plate, which makes it difficult for the heat flux to access it, heat flux emitted from the back side of the receiving plate. These disadvantages narrow the measurement range and their accuracy. The purpose of the invention is to improve the accuracy and the expansion of the measurement range. 36 This is achieved by the fact that a through hole is installed in the housing of the device for measuring thermal radiation, in which the receiving and compensating plates are installed, on the reverse side of which additional coatings are applied with the absorptive capacity of the reverse absorbency of the coatings applied on the front side of the plates. This thermocouple is attached to the yla t from the side of additional covers. Such an embodiment of the device makes it possible to increase the temperature difference between the heat sprinkling plate and the heating plate, to increase the thermo-emf removed from the thermopile and thereby increase the measurement accuracy. The application of additional coatings reduces the body heat capacity, its effect on the instrument readings and expands the measurement range. This is due to the fact that the reverse side of the receiving blackened plate is made of blast with a small degree of blackness, which reduces the heat flux emitted from this surface. /.EiG-T/ ,; CX is the density of the heat flux emitted from the back side of the receiving plate; EJ is the degree of blackness of the back side of the receiving plate; (Y is the Boltzmann constant; T, is the equilibrium temperature of the receiving plate. As the heat flux radiated from the back side of the receiving plate decreases, its equilibrium temperature rises. At the opposite side of the compensating plate reflecting the heat flux, blackened for increase in heat flux radiated from this surface. This heat flux is equal to I a-er T., where c is the heat flux density from the compensating plate radiated from the back side; f is the blackness degree of the back side compensating The T plate is the equilibrium temperature of the compensating plate. The equilibrium temperature of the compensating plate decreases accordingly, since the thermo-emf, thermopile, is proportional to the temperature difference between the hot and 60 cold ends of the thermopile, equal to the equilibrium temperature of the plasma, ie, proportional to the equilibrium temperature The temperature of the receiving and compensating plates. As this differential increases, the thermopile signal also increases accordingly, which improves the measurement accuracy. FIG. 1 A device for measuring thermal radiation is shown on a mathematical basis; in fig. 2 is the same side view} in FIG. 3 - absorption plates. The device for measuring thermal radiation contains 1, made with a through hole, in which two absorption plates, receiving 2 and compensating 3, are laid, with coatings on the front and back sides. The front side of the plate 2 has a coating with a high reflectivity, and the reverse - with a high absorption capacity. Plate 3 has a high absorbency coating on the front side, and a reverse one with a high reflectivity coating. In case 1, plates 2 and 3 are located side by side and symmetrically to the axis of the through hole, to the reverse sides of plates 2 and 3 a thermopile is attached from series-connected chromel-copep thermocouples. Each thermocouple is attached by hot and cold joints to plates 2 and 3; Moreover, the mount of the junction of each thermocouple is attached to the pin of the l-ine 3 3 1. 3; having a high absorption capacity on the front side, and a cold junction to the plate 2, which has a high reflectance capacity from the front side. The thermocouple cracking of the plates 2 and 3 is carried out with a heat-resistant and electrically insulating varnish. The thermopile 4 is connected to the measuring device 5 by means of wires 6. The device body 1 is mounted on the handle 7. Receiving plates 2 and 3 are fixed in case 1 with thin mica plates 8. Case 1 is made in a material with a low thermal conductivity, for example, plastic . The device for measuring thermal radiation operates as follows. The device is mounted so that the measured heat flux is perpendicular to the front side of the plates. The measured heat flux heats up the receiving blackened and compensating (reflecting) plates to a certain equilibrium temperature. The difference of these temperatures will be the higher, the greater the heat flux and the higher the difference of the degrees of absorption of the receiving and compensating plates with the lateral and reverse sides. The plates heat the hot and cold ends of the termobatteries. At the same time, thermo-emf is supplied to the measuring instrument calibrated in units of heat flow capacity (w / m). Due to such an arrangement of the device between the plates, the temperature difference increases, which leads to an increase in thermo-emf removed from the battery and, accordingly, an increase in the measurement accuracy. With the number of thermocouples in the thermopile, it is possible to widely change the measurement range, the expansion of which is both baked with additional coatings. Claims An apparatus for measuring thermal radiation, comprising a housing, is attached to the housing a receiving and compensating plates having coatings with a face-to-incident side with varying degrees of absorption each, a thermopile and a measuring instrument, characterized in that, in order to improve accuracy and extend the range measurements, a through hole is made in the body, in which the receiving and compensating plates are installed, on the reverse side of which additional coatings are applied with in terms of their ability to absorb absorptivity of coatings deposited on the front side of the plates, while the terlobatter is attached to the plates on the side of additional coatings. Sources of information taken into account when executing 1. Klimovitsky M, D., Karlin V, A, Quick Reference Guide to Thermal Control in Ferrous Metallurgy, M., Metallurg-kzdat, 1962, p. 59-60. 2. The author of the USSR N 183432, cl. G 01 K 7/12, 1965 (prototype).

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