SU1186958A1 - Method of calibrating photometric scales of optical instruments - Google Patents

Abstract

A METHOD FOR GRADUATING PHOTOMETRIC SCALES OF OPTICAL DEVICES, which consists in introducing transmission standards into the light beam of a calibrated instrument, register the readings of the calibrated instrument, corresponding values of the transmittance of standards T, and determine the transmittance values on the photometric instrument of the calibrated instrument instrument of the instrument of the instrument T, and determine the transmittance values on the photometric instrument of the calibrated instrument. in order to improve the accuracy of the graduation of the photometric scale, the light beam is additionally shielded with an opaque gate when the standard is removed from the light beam so that the readings of the calibrated instrument correspond to the transmission value of one of the standards, then one of the transmission standards is introduced into the light beam and the transmission values T are additionally determined from the ratio T - rli-ti I o / - on the photometric slider (TOO I / 0 where Tj, Te are the transmittance values of the standards,%, then the light is shielded by an opaque flap to the reading value of the calibrated instrument corresponding to the transmittance T ", one of the transmittance standards is determined and new additions are determined Lni (L telnye photometric values of T; from the ratio t; ()%. 00 O) ate 00

Description

The invention relates to a measurement technique, in particular to the calibration of photometric scales of optical instruments, such as photometers, spectrophotometers, spectrometers. The purpose of the invention is to improve the accuracy of the graduation of the photometric scale. FIG. 1 shows a device for calibrating a photometric scale of an optical instrument, a general view; in fig. 2 - the same, the valve is fixed by an emphasis in the working position. The device (Fig. 1) comprises a base 1 mounted on the housing 2. In the base 1 there is a hole 3 for the light beam of the calibrated instrument. On the one hand, the base 1 has guides 4, into which the valve 5 is installed, equipped with a micrometer screw 6 for moving it across the light beam in front of the opening 3. On the other side of the base 1, there is one standard from a set of transmission standards, namely a sector disk 7. Sector the disk 7 is fixed on the drive shaft 8, which is the holder of the transmission standard of the actuator 9 installed in the base 1. The device for calibration (Fig. 2) also contains a plate 10 with a slot installed in the guides 4 and has an axis 11, on which the valve 5 is fixed, with the possibility of rotating it around the axis 11. On the plate 10 there are stops 12 and 13 and a return spring 14 for fixing the valve 5, respectively, in the working and non-working position. A micrometer screw 6 is installed on the plate 10. Such a device can have several plates 10 installed in parallel with one another. Example 1. A device for calibrating the photometric gauges (Fig. 1) is placed in the light beam of the spectrophotometer. The device contains a set of transmission standards (sector disks with face values of 10, 30, 40, 50, 60, 70, 80, 85, 90 and 95 (%)). The pen of the recorder of the spectrophotometer is displayed by the division of T (1оо), chosen for 100% of the photometric scale. The gain and slit of the spectrophotometer are set so that the noise level does not exceed 0.05% T with sufficient sensitivity of the instrument. On the drive shaft 8 install the sector disk 7 with a nominal value of 50% Te. By means of the actuator 9, the sector disk is rotated, and the pen of the recorder is mounted on a division T (5 °) corresponding to a transmission of 50%. Thus, a point of 50% is obtained on the photometric scale of the instrument being calibrated. The sector disk 7 is stopped and installed so that its sectors are located outside the light beam. In this case, the pen of the recorder is installed on the division Tpo). Since the sector disk of 50% is already mounted on the drive shaft, it is convenient to start the determination of additional transmission values on the photometric scale of the calibrated instrument with a value of T, 25%. To this end, the light beam is screened with a flap 5, peremployed with the aid of a micrometric screw 6 until the pen of the recorder returns to the T (5 °) division obtained using the specified transmission standard. Failure to remove the shutter from the light beam causes the sector disk 7 with a nominal value of 50% transmittance to rotate and obtain a point T (25) on the photometric scale corresponding to 25% njjonycKani, according to the ratio T:: ()%, as in this case. Then the sector disk 7 is stopped, it is removed from the drive shaft 8, on which the sector disk 7 with a rating of Te 30% transmission is installed. Drive it into rotation, get a point T (i5) on the photometric scale. A sector disk 7 with a nominal value of 30% transmission is alternately mixed into sector disks with nominal values of T 70, 90, 40, 10% and receive correspondingly additional points T (h5), T (45), T (2o) and T (5). The valve 5 is removed from the light beam. Using a sector disk with a nominal rating of 80%, a point T (§о) is obtained, and additional points of the photometric scale T, using transmission standards 70, 80, 95%. The points corresponding to the standards with face values of 10, 30, 40, 60, 70, 85, 90, 95% are obtained by alternating rotation in the light beam of the corresponding sector disks with the deduced gate 5. New additional values (T,) on the photometric scale of the device receive introducing the flap 5 into the light beam at a position where the pen readings of the recorder of the spectrophotometer are set on one of the Te values already determined according to the described sequence of operations (for example, T (25)), install the sector disk with the transmittance rating Te from the yes Te 10, 30, 40, 50, 70, 80, 85 90, 95% and determine new additional values of the photometric scale T, - from the ratio t; (-, ..,. Thus, 60 points of the photometric scale are obtained: 1 ; 3; 4; 5; 6; 7; 8; 8.5; 9; 9.5; 10; 12; 15; 16; 18; 20; 21; 24; 25; 25.5; 27; 28; 28 , 5; 30; 32; 34; 35; 36; 38; 40; 42; 42.5; 45; 47.5; 48; 49; 50; 51; 54; 56; 57; 59.5; 60; ; 64; 66.5; 68; 70; 72.25; 76; 76.5; 80; 80.75; 81; 85; 85.5; 90; 90.25; 95. Example 2. Calibration is carried out as in Example 1 before replacing the sector disk 7 with a nominal value of 30% transmittance with sector disks with nominal values of 70, 90, 40, 10% (Fig. 2).

In this case, the plate 10 is moved with the valve 5, which is in the working position, i.e. pressed against the stop 12. Then the following operations are performed. With a rotating sector disc with a nominal value of 30%, the shutter 5 is removed from the light beam, while the return spring 14 presses the shutter 5 against the stop 13 (the stop 12 provides the possibility of reproducing the found position of the shutter). Get a point of 30% on the photometric scale. Stop the sector dick with 30% T, replace it with the sector disk with 70% and with its rotation get the point T (70). The valve 5 is introduced into the light beam up to the stop 12 and a point T (s5) is obtained. Stop the sector dis 70% and replace it with the sector disc 90%, bring it into rotation and get the point T (45) - Then take the shutter 5 from the light beam and get the point T (9o) - Stop the sector wild 90% and replace

it is 40% on the sector disk, is brought into rotation, a point T (4 °) is obtained, and a flap 5 is introduced into the light beam, thus obtaining the point Tc2cJ. Similarly, get the point T (1o), T (5). Applying a sector disc with a nominal value of 80%, then immediately get the dividing of the photometric scale T (8c) and 1 (64); 1 (70) and 7 (56); Ttes) and T (76).

Graduation by the proposed method in Example 1 allows, with the same number of standards as in the base object, to obtain a significantly larger number of photometric points with the same average time spent on obtaining one point. Example 2 shows that the implementation of the method allows you to get a gain in the number of points compared to the base object by 1.9 times and at the same time reduce the average time taken to obtain one point.

Claims (1)

METHOD FOR GRADING PHOTOMETRIC SCALES OF OPTICAL INSTRUMENTS, namely, that transmission standards are introduced into the light beam of the calibrated device, the readings of the calibrated device are recorded corresponding to the transmission values of the standards Tj, and transmission values are determined on the photometric scale of the calibrated device, characterized in that the accuracy of the calibration of the photometric scale, additionally screen the light beam with an opaque damper when the transmission standard is removed from the light beam ak to the calibrated instrument readings correspond to the value of one of the transmission standards, is then introduced into a light beam of one of the transmission standards and further comprising determining the values of transmittance T, on the calibrated instrument photometric scale from the relation t .__ / Ta \ a / ¹ '- v 100' / o 'where Te, Te are the transmittance values of the standards,%, then the light beam is shielded with an opaque damper to the reading value of the calibrated device corresponding to the transmittance T „one of the transmittance standards is introduced and determine new additional values of the photometric scale T / from the relation ¹¹ - ⁽ 100 ^{, / о} ' Figure 1 g