SU756336A1 - Device for adjusting optical elements - Google Patents

Description

The invention relates to optical instrumentation and can be used in those systems that require precise installation of a given position of optical elements in the space of objects (for example, in optical locators, scanning devices, etc.).

A device for alignment of optical elements is known, which contains a non-movable base with a ball placed in a socket, a movable flange connected with a base by means of a spring hinge and having a slot for installing an adjustable element and 15 an adjustment mechanism [1].

Closest to the present invention is an adjustable mirror assembly comprising a mirror rigidly mounted on the end of the trunnion, the other end 20 of which is fixed by means of an adjusting assembly in a fixed housing. Adjusting the tilt of the mirror is a pair of screws. One of the screws shifts the trunnion, and the other screw, after 25 of the installation of a given tilt of the mirror, secures the position of the trunnion, resting against it from the opposite side (2).

The disadvantage of this device is the low accuracy of adjustment for kai $ _ 2

house from directions, due to the fact that the adjustment of the mirror in two mutually perpendicular directions cannot be done independently of each other. When adjusting the mirror in one direction, the adjusting screws in the other direction must be partially unscrewed to fasten the trunnion, while the adjustment in this direction is broken.

The aim of the invention is to improve the accuracy of independent adjustment in two mutually perpendicular planes.

This goal is achieved by the fact that the device is provided with a shaft mounted inside the axle and rigidly connected with it, connected via a spherical bearing with a fixed body, and an adjustment unit in the form of a ring with two diametrically placed cylindrical tips and two axially arranged between the body and the axle , with holes for the adjusting screw passing through the threaded hole made in the trunnion and through the guides additionally made in the housing

756336

grooves, and the ring with the trunnion mounted for movement along the axis of the lugs.

FIG. 1 shows a diagram of the proposed adjustment device) in FIG. 2 is a section A-A in FIG. in fig. 3 - view of the device from the side of the adjusting unit.

The device for alignment of optical elements contains a metal mirror 1 rigidly fixed on the end of the shaft 2 connected to the fixed case 3 by means of a spherical bearing 4, the shaft is mounted in the axle 5 and fixed with a pin 6. Therefore the mirror 1, the shaft 2 and the axle 5 is a single rigid construction.

The other end of the pin 5 is installed inside FIG. 2 rings 7c with two ’diametrically arranged cylindrical tips 8 and 9, which enter the holes (grooves) of the housing 3.

At the end of the tip 8 there is a thread on which the movable nut 10 is screwed, which is installed in the groove of the housing with the aid of the lining 11 so that it can freely rotate around the axis of the tip 8.

At the end of the tip 9 mounted split clamp 12, mounted on the housing. The screw 13 serves to secure the tip 9 (FIG. 3) after setting the mirror in a predetermined position.

Perpendicular to the axis of the lugs on the ring, there are two through holes in which a screw 14 is installed through the trunnion 5 (it has a through screw hole). In this case, the screw 14 can freely rotate around its axis. At the end of the screw 14, the sleeve 15 is worn and fastened with a pin 16 (in the housing, under the screw head 14 and the sleeve 15, guide grooves are made with a radius equal to the distance between the bearing 4 and the ring 7),

In the center of the trunnion 5, a longitudinal slit is made at its rear end parallel to the axis of the screw 14. Perpendicular to this slit, at the end of the trunnion 5, there is a Hole (through in one part of the trunnion and threaded on the other) for the screw 17 serving to lock the screw 14.

The adjustment of the device in two mutually perpendicular directions is as follows.

When the screw 14 is rotated around its axis, the rear end of the trunnion is displaced relative to the center of the ring 7. At the same time, the trunnion with the mirror fixed on it rotates around the spherical bearing relative to the fixed case.

Thus, the rotation of the screw 14 regulates the tilt of the mirror in one direction. The accuracy of the tilt adjustment depends on the pin length and

screw thread pitch 14. After adjusting the tilt of the mirror, the position of the screw 14 locks, tightening the cut parts of the trunnion with the screw 17.

Adjusting the tilt of the mirror in the perpendicular direction is done by rotating the nut 10 around its axis, causing displacement along the axis of the ring together with a pin fixed inside it. At the same time, the axle with the mirror rotates around the spherical bearing 4 relative to the fixed case 3. The accuracy of the adjustment is also determined by the axle length and step size nut threads 10.

After adjusting the tilt of the mirror in this direction, the position of the ring is locked, tightening the screw 13 of the split clamp 12.

Thus, the adjustment of the tilt of the optical element in the proposed device is carried out by moving the rear end of the trunnion relative to the ring in one direction and moving the entire ring together with the trunnion relative to the body in the other perpendicular direction. In this case, the front part of the trunnion with the mirror rotates around the spherical bearing to the desired position in two mutually perpendicular directions.

Claims (1)

Claim Device for aligning optical elements, such as mirrors, Containing an optical element rigidly mounted on the end of the trunnion, the other end of which is fixed by means of an adjusting node in a fixed case, characterized in that, in order to improve the accuracy of independent adjustment in two mutually perpendicular planes, it is provided with inside the trunnion and the shaft rigidly connected with it, connected through a spherical bearing with a stationary body, and the adjusting unit is made as placed between the body and pin rings with two diametrically placed cylindrical tips and with two perpendicular to their axis, holes for the adjusting screw passing through the threaded hole made in the pin, and through the guide grooves additionally made in the housing, with the pin with the axle mounted for movement along the axis tips