SU1539521A1 - Autocollimation reflector - Google Patents

Abstract

The invention relates to a measurement technique and is intended to measure the angular rotation of an object relative to the collimation axes. The aim of the invention is to extend the functionality by operating it also with an uncollimated autocollimator beam. The beam of radiation is directed to the first lens 2, which builds an image of the beam in a plane, aligned with the front focal plane of the second lens 3. The beam that has passed through the second lens 3 reflects from the flat mirror 4, which again passes the second and first lenses in reverse. When the reflector is operating, a second beam 3 and a flat mirror 4 are mounted with a converging radiation beam that are movable along the reflector optical axis. 2 Il.

Description

The invention relates to measuring equipment and can be used in optical instrumentation.

The purpose of the invention is the expansion of the reflector's functionality by ensuring its operation also with a non-collimated beam of an autocollimator,

In FIG. 1 shows a schematic diagram of a reflector; in FIG. 2 - the course of the fuchsia through the reflector.

The reflector comprises a housing 1, in which the first lens 2, the second lens 3, and a flat mirror 4, located te the rear focal plane of the second lens 3 are sequentially mounted.

The second lens 3 and a flat mirror 4 are located in the frame 5 and are mounted with the possibility of linear movement along the optical axis of the reflector. The front focal plane of the second lens 3 is aligned with the image plane of the first lens 2.

The reflector works as follows.

A beam of rays (collimated or converging) is directed to the first lens 2, which builds its image in a plane aligned with the front focal plane of the second lens 3. The second 3 ^ lens converts the incident beam onto it in a collimated one (Fig. 2). The collimated beam is reflected from the planar mirror 4 and again directed to the second lens 3, which builds the image of the reflected beam in the same plane as for the beam in direct motion. The first lens 2 converts the beam in reverse motion into a beam similar to a beam incident on it in direct motion (collimated or converging).

If there is an angle between the direction of the beam entering the lens 2 and the optical axis of the reflector, then the angle between the direction of the beam emerging from the first lens 2 in the reverse stroke and the reflector optical axis is (- </). The angular displacement between the beams in the forward and reverse motion is equal to 2d.

When the reflector is working with a converging beam of beams, the second lens 3, together with a flat mirror 4, is moved in the frame 5 along the optical axis of the reflector until its front focal plane is aligned with the image plane formed by the first lens 2, as a result of which a sharp image of its mark is formed in the field of view of the autocollimator both for collimated and for converging radiation beams.

Claims (1)

Claim An autocollimation reflector comprising a body and a first lens in series, a second lens, the front focal plane of which is aligned with the image plane of the first lens, and a flat mirror mounted in the rear focal plane of the second lens, characterized in that, in order to expand the functionality by its work also with a non-collimated beam of an autocollimator, the second lens and a flat mirror are mounted with the possibility of linear movement in the housing along its axis and.