SU24663A1 - A device for comparative testing of colored glass - Google Patents

Description

The invention relates to devices for comparative testing of colored glass, using a photocell located in front of the light source, in the path between which the test glass is placed.

In the proposed device, for the purpose of determining the transparency of the pjna glass of light of different wavelengths, rotary disks are located between the light source and the photocell, respectively, with a number of normal colored glasses and a number of light filters.

In FIG. 1 shows a general view of the device; FIG. 2-diagram of the electrical part of the device.

The device (Fig. 1) consists of two boxes placed on a common basis. In the right box I, a light source-incandescent lamp of 50 watts is placed. In front of the lamp there is a disk 2 with five openings, of which four are covered with normal signal glasses (red, yellow, green and blue), and the fifth remains free. Normal glasses are used to compare the measurement results obtained by testing various signal glasses. A disk with normal glasses protrudes slightly through a slot in the outer wall of the crate and rotates by hand to install an appropriate opening against the photocell and the light source.

Between the right and left boxes there is a gap 3 into which the test signal glasses are inserted. In the left box 12, an electrical circuit of the device with an amplifying lamp, photocell, and a disk with light filters is assembled. In front of the hole in the side wall of the box there is a photo cell in an aluminum case, in front of which is placed a disk with light filters, quite similar to a disk placed in box 2, with the only difference that there are four holes in it closed by color light filters, and the fifth does not let in light and serves to darken the photocell when the microammeter is set to zero. The disc with light filters is also rotated and mounted by any opening against the photocell. To check the correct installation of the discs on the required holes, the protruding rims of the discs are painted in different colors corresponding to the colors of the installed filters or normal glasses.

Electric part of the device is assembled as shown in FIG. 2 diagram. Constant resistances in the circuit of the device are two coils with wire resistances of 30,000 and 15,000 ohms, and as a variable resistance, a potentiometer that allows, by means of switch 5, to include resistances of 3000, 4000,

5,000 and 6,000 ohms, and then, using a series-connected potentiometer b in 1000 ohms, smoothly adjust the resistance to the required value.

In the diagonal of the bridge is included microammeter 7 sensitivity A,

CU, - / 20

equipped with shunts on

And YS which are turned on by the switch 8. On the front wall of the device, a resistor of the incandescent 9 and a voltmeter 11 on b and 120 volts are mounted with a switch 10 for measuring the voltages of the incandescent, anode and photocell. The entire electrical circuit of the device is shielded by a metal screen against possible external influences. The front panel, with the base on which the entire circuit is mounted, can be pulled out of the box, thus providing easy access to all parts of the device for necessary switchings and corrections. The power sources can be two dry 80 volt batteries for powering the photocell and the anode of the amplifying lamp and 4 volt rechargeable battery — one of the lamp filament supply. The batteries are switched on by means of a special block, which is inserted into the sockets of the side panel of the instrument.

When testing signal glasses with respect to their throughput, two methods of working with the device can be used: 1) a method for comparing the absolute deviations of the microammeter from test subjects and normal glasses and 2) a zero method of comparison, in which the micrometer micrometer is set to zero, and in measurements for the test glasses, deviations are obtained representing the difference in the readings of the microammeter for the normal and test glasses.

When measured by the first method, the photocell is darkened with the help of a disk with swift filters, which is installed at the closed opening, and then the voltage is applied to the amplifying lamp and the photocell. Having installed a normal amplifying glow with a rheostat, they check the anodic voltage of the lamp and the voltage on the photocell with the help of a switch. Then, at the minimum sensitivity of the microammeter (bypass Vse), it is switched on and the resistance is adjusted with a potentiometer for balance in the bridge, for which the necessary resistance is first selected by switch 5 and then the micrometer is set to zero with a potentiometer. After preparing the electrical circuit for the measurements, the incandescent lamp is switched on to the lighting network. A disc with normal glass is installed on a free hole.

The measurement process is as follows. The test glass was inserted into the gap between the drawers and, rotating the disk with light filters, recorded microammeter readings for each color filter. To compare the obtained microammeter readings, which characterize the quality of the test glass, with the readings of the microammeter from the normal glass of the corresponding color, remove the test glass and place the disc with normal glasses on the appropriate normal glass. Rotating the filter disc, record the microammeter for each filter. When comparing the results obtained from the test and normal glasses, the percentage of discrepancy in the microammeter reading for each filter is found. If this percentage exceeds the allowable percentage of discrepancy, the test glass is recognized as not conforming to established standards.

The second zero measurement method differs from the first only in that at the beginning of the disk measurement with normal glasses it is set to the corresponding normal glass and for any light filter with a potentiometer 5 and b an equilibrium in the bridge is set with the microammeter set to zero. Then the test glass is inserted and, with the same light filter, the deviations of the microammeter in the opposite direction are noticed, which is the difference in the readings between the deviations for the normal and the test glasses.

Repeat the entire measurement process for all four filters, compare the results with established tolerances.

The subject matter of the invention.

Claims (2)

1. A device for comparative testing of colored glass using a photocell located in front of the light source, in the path between which the test glass is introduced, characterized in that, in order to determine the transparency of the test glass for light of different wavelengths corresponding to those of normal glass, The light source 1 and the photocell F have a rotary disk 2 and 4, respectively, with a number of normal colored glasses and a number of light filters. 2. At the device according to p. T use an amplifying circuit for amplifying the photocurrent. fig .. FIG. Avww