SU1712780A1 - Device for centering object - Google Patents

Abstract

The invention relates to a control and measuring technique and can be used in mechanical engineering. The purpose of the invention is to expand the functional possibilities by building mutually perpendicular directions on a given plane. A beam of light from a laser passes through a beam shaper and a series of optical elements, where it is divided into two beams, one of which sets the first direction, the second beam refracted in a prism sets the second direction. For fixing the directions with reference points, the corresponding mirrors are fastened. First of all, the first direction is fixed, which coincides with the propagation of the beam by the laser radiation, then by adjusting the position of the object, two coincidence of two spots into one are achieved. The magnitude of the angular position of the object is determined indirectly. 1 oril. The invention relates to instrumentation engineering and can be used in mechanical engineering and aircraft construction. The purpose of the invention is to extend the functionality by sending also mutually perpendicular directions on a given plane. The drawing shows a device for centerpieces% 1i, a diagram The device contains a laser 1, a shaper 2 of an annular beam structure, a case 3 with a base 4 unit, located in the case 3 an optical element in the form of a cubic prism 5 with a beam-splitting coating on a diagonal surface and a mirror coating on one of its faces from the side of the base 4 and frosted glass 6 with a grid opposite (: tori, and a flat mirror 7, located during radiation perpendicular to the mirror surface, and a magnifying glass 8, located outside the body 3 on the side opposite to the mirror face, the second body 9 bonded to the first 3 with the possibility of changing the relative position, the second cube-prism 10 with a beam-splitting coating on a diagonal surface and a translucent coating on two mutually perpendicular p faces parallel to the optical axis, and the first 11 and third 12 mirrors installed in the second housing 9 are sequentially oriented with reflecting surfaces parallel to the faces of the second cube prism 10 with a translucent coating and optically connected with them, three reference frames 13- 15, Designed to bond with each of the respective mirrors. The cube prisms 5 and 10 are oriented so that their diagonal surfaces are parallel to each other. The device works as follows. ^ VGOVI00o

Description

A beam of light from laser 1 passes through the forg head 2 of the beam and hits the cubicle 10, where it is divided into two beams. One of them passes through the prism 10 and hits the cube-prism 5, where, in turn, it also divides into two beams, one of which passes through the prism 5, setting the first direction, and the second refracted on the frosted glass 6 and turns out in the field of view of a magnifying glass 8. The second beam of light, refracted in prism 10, emerges from it at a right angle, setting a second direction. Partially refracted on the translucent face of the prism 10, the second part of this beam propagates in the opposite direction, which allows you to specify a second direction, perpendicular to the first, to both sides of the cubicle 10. For fixing these directions, the corresponding mirrors are attached to the reference points.

First of all, the first direction is fixed, which coincides with the propagation of the radiation beam of the laser 1. To do this, the mirror 7 is mounted on the frame 13 and, by adjusting the position of the reference frame 13, a coincidence lens 8 is achieved in the field of view of the loop 8 on the ground glass of the two beams. Further, by adjusting the position of the frame 15, in the field of view of a magnifying glass 8, on a frosted glass, 6 images of two beams are achieved. Then, rotating body 9 with a prism

10, aligning the beams of the second direction with a predetermined plane is achieved using frame 14 and 15.

Fix the second direction. At the same time a beam of light reflected from the mirror

11, falls on the beam-splitting surface of the prism 5 and 10 and, having refracted on it, falls on the frosted glass 6 or plate. A beam of light reflected from the mirror

11, hits the translucent layer and, partially reflected in the direction of the prism 10, hits the frosted glass 6. In this case, three light beams are in the field of view of the magnifying glass 8. For their alignment, they overlap one of the directions and, turning the corresponding frame, achieve the alignment of the light spots into one. To control the angular deviation from a given direction, flat mirrors 11 and 12 fix

on controlled objects (not shown). In this case, the course of the rays in this case does not differ from the departure of the rays from these mirrors when mounted on the respective frames 13-15. By adjusting the position of the objects, two spots in one are achieved. The magnitude of the angular position of the object is determined indirectly, namely by measuring the distance to the object and the magnitude of the displacement between the centers of the spots, which is determined by means of a measuring grid,

Claims (1)

Claims An apparatus for centering an Object, comprising successively located laser, a shaper of an annular beam structure, a housing with a base assembly, an optical element in the housing in the form of a cube-prism with a beam-splitting coating on a diagonal surface and a mirror coating on one of its edges from the base assembly side and frosted glass with a grid on the opposite side, and a flat mirror, located during the course of radiation perpendicular to the face with a mirror coating, and a magnifying glass, outside the body from the side opposite to the mirror face, characterized in that, in order to expand the functionality by building mutually perpendicular directions on a given plane, it is provided with a second body bonded to the first with the possibility of changing the relative position, the second cube-prism a light-splitting coating on a diagonal surface and a semi-transparent coating on two mutually perpendicular faces, parallel to the optical axis, and installed in the second building but the first second and third flat mirrors, oriented reflective surfaces parallel to the edges of the second cube-prism with a translucent coating and optically connected with them, and three reference points, designed to bond with each of the respective mirrors, and the cube-prisms are oriented so that their diagonal surfaces are parallel to each other. t