SU731308A1 - Double-wave photometer - Google Patents

Description

The invention relates to measuring equipment, and more particularly to devices designed for photometric measurement of heterogeneous objects.

Known two-wave fotokolorimet- ry ⁵ in which luminous flux from the light source is split by a semitransparent mirror into two streams passing through the two filter and fall into two photocell. The disadvantages of such devices are light losses during the separation of the flux by a translucent mirror and the difficulty of registering radiation with two photodetectors.

Also known is a two-wave photometer, 1. containing a light source, two monochromators with dispersing elements and a photodetector.

Large light losses occur in the photometer due to the presence of a large number of optical elements in the path of the light-beam of the 2nd beam.

The aim of the invention is to reduce light loss.

This goal is achieved by the fact that in a two-wavelength photometer, the monochromators have common input and output slits made in the form of two rigidly fixed and lying in the same plane mirrors, which are simultaneously a switch of 3 monochromators and equipped with a means for communicating oscillations about an axis passing through the centers of the mirrors and parallel to the main planes of the dispersing elements of the monochromators.

The drawing shows a schematic representation of the proposed two-wave photometer.

The two-wave photometer has a light source 1, a condenser lens 2, a flat mirror 3, a monochromator switch 4 with two mirror sections 5 and 6, mounted in the main focus of the collimator mirror 7, dispersing elements 8 and 9, a flat mirror 10, a condenser lens 11, a photometric object 12 mounted at the focus of the condenser lens 11 and the photodetector 13.

Two-wave photometer works as follows.

The light beam from the light source 1 is focused by a condenser lens 2 through a flat mirror 3 onto the entrance slit of the monochromators, the role of which is played by the mirror section 5 of the monochromator switch, which performs periodic oscillations between two positions. Then, the light beam collimated by the mirror 7, depending on the position of the switch 4, falls on one of the dispersing elements 8 and 9, reflecting from which, it again falls on the collimator mirror 7 and focuses on the exit slit of the monochromators, the role of which is played by the second mirror section 6 monochromator switches. Then the light beam is focused by a condenser lens 11 onto a photometric object 12, passing through which it enters the photodetector 13.

Thus, the monochromator switch 4 periodically transfers the light beam from the dispersing element 8 to the dispersing element 9, as a result of which the light beam passing through the photometric object 12 periodically changes the wavelength between two values corresponding to the setting of the dispersing elements 8 and 9. One wavelength is set at the maximum of the absorption band of the photometer object 12, and the second near this band. When a photometric object 12 is introduced, only a light beam with a wavelength corresponding to the maximum of the absorption band is attenuated, which leads to the appearance of a variable component 5 in the photodetector, which is processed by an electronic measuring circuit.

Claims (1)

Claim A two-wave photometer containing a point of light, two monochromators with dispersing elements and a photodetector, characterized in that, in order to reduce light losses, monochromators have a common entrance and exit slits, 15 made in the form of two mirrors rigidly fixed and lying in the same plane, simultaneously which are a switch of monochromators and equipped with means for communicating oscillations about an axis 20 passing through the centers of the mirrors and parallel to the main planes of the dispersing elements of the monochromators.