SU1400239A1 - Method of measuring radiating ability of metals - Google Patents

Abstract

The invention relates to radiation pyrometry and can be used in instrument making and research practice. The aim of the invention is to improve the accuracy of measurement of the emissivity. When measuring the emissivity of metals by the blackbody method in the form of a tube after aligning the receiver, when the model of the cheripot body is sighted, turning the tube around the axis and simultaneously measuring the signal, the maximum signal is obtained, the position of the tube is fixed and conducts. measurement By rotating the sample in order to find the maximum effective emissivity of the blackbody model and more accurately determine the sample temperature, the error in determining the emissivity of this method can be reduced to 1.5%. 1 il. with S.

Description

 And the acquisition of a rldnanionpay of 1 meter can be in the instrument engineering and research practice.

Failure of the invention is to improve the accuracy of measurement of the metal's obstructive ability.

In the drawing, a schematic diagram of an apparatus for realizing this method is shown.

; Sample tube 1 with a black model 2 (MCT) is placed in a water-cooled chamber 3 with a window 4. A two-beam spectrophoto-TfMBTp 5 is optically connected to the tube, the recording tube 6 is connected to the output of the tube, the sample tube is mechanically connected to the rotator 7 , A movable mirror 8 and a pyrometer 9 are provided for measuring the temperature.

The method is carried out as follows.

A tube with a hole in the side wall5 serving as a black body model is heated by passing a current. Mirror 8 VDVIG31PT in the optical channel of the MCT and the pyrometer 9 measures the temperature of the tube ,. Mirror 8 is removed from the ca-. n $ la mht. The spectrophotometer 5 directs the MCT radiation one channel at a time, measures the required wavelength, then shifts the radiation receiver to obtain the maximum signal due to the overlapping of the receiving site of the radiation receiver with the image of a blackbody model and then use the rotator 7 and simultaneously watching the signal change, measured by the recording device 6, repeat the receiver offset operation. When the signal reaches its maximum, the tube turns off and the found position of the tube is recorded. The mirror 8 is again pushed into the PSTB channel and the specified tube temperature is measured, after which the mirror is removed. A spectrophotometer was adjusted for simultaneous operation along two optical channels: radiation No. 1T was sent through one channel, radiation from the surface of the tube was directed through one channel, and the relative signals of the tube and radiation were measured using a recording device 6.

When moving to a different wavelength, the temperament again changes the position to provide maximum

Ma. ibfiorci ssh-napa receiver, since the ncc tris from 1 ucheii and reflections depend on the wavelength and (in a small degree) on the temperature.

The step of measuring the exactness of the possibility of using the diving method by means of a trace is more comfortable. For specularly reflecting materials, which include metals, the effective emissivity ——, „,„ — of a black-body model made in the form of unzip in a tube strongly depends on the direction of sight. For example, for sanging there are such directions of sighting in which the effective emissivity differs from the emissivity by a fraction of a percent, while for other times this difference reaches A-5%, while it should be noted that E peaks, depending on The angle of sight is sharp. Rotation of the tube with a simultaneous signal measurement when viewing a blackbody model allows determining the position of the tube at which the 5-jjp model is closest to unity by the signal maximum. I

Repeated temperature measurement THKJKS contributes to the accuracy of the 4 emissivity of the emissivity, as it is produced in the position of the tube, characterized by

great value

black body models the temperature is measured more accurately than with any other orientation of the tube. Thus, by rotating the sample in order to find the maximum model, as well as more accurately measuring the sample temperature, the error in determining the emissivity of metals in this way can be reduced to 1.5%.

Claims (1)

Invention Formula The method of measuring the emissivity of metals, including the govlenna in the side wall of the sample tube of the hole, served as its black body model, offset of the radiation receiver relative to the black body model, measurement of the receiver signals corresponding to the radiation of the surface of the tube and the body 4Kpiioro radiation, and Also, the measurement of the temperature of the tube and the wave of the radiation wave, taken by the receiver, characterized in that, in order to improve the accuracy of measuring the emissivity, the tube is rotated its axis and simultaneously measure the receiver signal corresponding to the radiation of the blackness model of the body, until the ush becomes maximal, Fix i 1T, then the position of the tube, and then measure the offset of the signals corresponding to i) surface of the tube and mp / (black body spruce when the tube is in the same position. Pi