RU180328U1 - TELESCOPE MIRROR MOUNTING DEVICE - Google Patents

Abstract

The utility model relates to telescope engineering, a device for mounting mirrors of large-sized telescopes, in particular space ones. The device comprises a base with three holders uniformly spaced around the circumference with hinges with spherical heads, the centers of which are located in a plane perpendicular to the axis of the mirror and passing through its center of mass. The mirror does not have through holes for mounting holders with hinges, which are mounted to move in corresponding directions relative to the base using six pairs of spherical washers and are equipped with three spring washers on the back of the base to select the play and adjust the force causing the holders to move relative to the base . Effect: compensation of temperature deformations of a mirror made of a composite material and a supporting structure made of another composite material, without reducing the strength of the mirror. fixed in these bushings with liners with a spherical surface. The centers of the spherical heads of the hinges are located in a circle whose radius is equal to the radius of the points of maximum deflection of the mirror in a plane perpendicular to its axis under the influence of axial load. Thanks to the presence of three holders with hinges with spherical heads installed with the possibility of movement in the corresponding directions relative to the base at the temperature deformations in the temperature range of ± 50 ° C. The proposed technical solution ensures the absence of temperature deformations by creating the possibility of free movement of the mirror and the base relative to each other when the temperature field changes. In addition, the proposed design is simple, and therefore its manufacture does not cause special difficulties. 1 s.p. f-ly, 3 ill.

Description

Telescope for mounting mirrors of large-sized telescopes, in particular space ones.

The device is primarily intended for large-sized space telescopes, the optical and structural elements of which are made of different composite materials with different temperature coefficients of linear expansion, and the mirrors are made using an open relief structure on the back side.

State of the art

Known analogues:

A device for mounting a telescope mirror is known [certificate for a utility model of the Russian Federation No. 34761 class. G02B 7/18 publ. 2003], containing a base with three racks and supports evenly spaced around the circumference in the form of shafts with spherical heads located in a plane perpendicular to the axis of the mirror and passing through its center of mass. The device is additionally equipped with three pairs of springs kinematically connected with a mirror and corresponding sliders. The axes of the three springs are located in a plane perpendicular to the optical axis of the mirror, and the axes of the other three springs are parallel to the optical axis of the mirror. The racks are rigidly fixed to the base, and the axes of the supports installed on them are in the same plane and intersect it at a point that coincides with the center of mass of the mirror.

The disadvantage of this solution is the method of mounting the mirror on the side surface by making blind or through holes for bearings in this surface, which reduces the strength of the mirror and its ability to withstand the load directed along the axis of the mirror.

In addition, the method of mounting the mirror on the side surface cannot be used for large-sized large-diameter mirrors made of composite materials using an open relief structure on the back side. With this method of fastening, the probability of mirror destruction under the influence of a load directed along its axis is high.

The closest in its technical essence to the claimed utility model is a device for mounting a telescope mirror [RF patent No. 2035759 class. G02B 7/18, publ. 1995].

A telescope mirror attachment device comprising a base with three spherical bearings uniformly spaced around the circumference and perpendicular to the axis of the mirror. The supports are rigidly mounted on sliders, which have the ability to move in respective directions due to balls installed between the slide and its corresponding guides, rigidly connected to the base.

The axes of the guides intersect at one point lying on the axis of the mirror, and are located in the same plane perpendicular to the axis of the mirror. The centers of the spherical heads of the ball bearings are located around a circle in a plane passing through the center of mass of the mirror and perpendicular to the axis of the mirror.

The disadvantage of this solution is the presence in the working surface of the mirror of through holes for bushings for ball bearings, which decreases the area of the working surface of the mirror and its rigidity as the ability to withstand the load directed along the axis of the mirror.

In addition, the method of mounting the mirror using through holes can not always be used for large-sized large-diameter mirrors made of composite materials using an open relief structure on the back side. With this method of fastening, it is necessary to add additional reinforcing elements to the structure of the relief structure, which will lead to an increase in the mass of the mirror.

Disclosure of Entity

The main objective of the utility model is to compensate for temperature deformations of a mirror made of a composite material using an open relief structure on the back side and caused by the difference in the temperature coefficients of the linear expansion of the mirror and the base of the supporting structure made of another composite material, without reducing the strength of the mirror.

To solve this problem, a telescope mirror mounting device is proposed, which, like the one closest to it, selected as a prototype, contains a base with three holders evenly spaced around the circumference with hinges with spherical heads, and the centers of the spherical heads of the hinges are located in a plane passing through the center of mass of the mirror and the perpendicular axis of the mirror are additionally installed with the ability to move in the appropriate directions using six pairs of spherical washers, through The other holders are fixed to the base with nuts. To select the play and adjust the force that causes the holders to move relative to the base, spring washers are installed between the pairs of spherical washers located on the back of the base and the surface of the base, the compression ratio of which is regulated by the tightening force of the nuts, with which the holders are fixed to the base.

Holders with hinges with spherical heads are connected to the mirror by means of bushings glued into sockets specially provided for by the design of an open relief structure and fixed in these bushings by inserts with a spherical surface. The centers of the spherical heads of the hinges are located in a circle whose radius is equal to the radius of the points of maximum deflection of the mirror in a plane perpendicular to its axis under the influence of axial load.

The essence of the utility model lies in the fact that due to the presence of three holders with hinges with spherical heads installed with the possibility of movement in the corresponding directions relative to the base using six pairs of spherical washers, as well as the fact that the centers of the spherical heads of the hinges are located in a plane passing through the center the masses of the mirror and the perpendicular axis of the mirror and the centers of the spherical heads of the hinges are located on a circle whose radius is equal to the radius of the points of maximum deflection mirrors in a plane perpendicular to its axis, under the influence of axial load, and for selecting backlash and adjusting the force causing the movement of the holders and hinges, the device is equipped with a spring washer with a nut on the base side and bushings with a threaded sleeve on the mirror side, which has no through holes for installation of holders with hinges, which is especially important for solving the problem of compensating for temperature deformations in the temperature range of ± 50 ° С.

Thus, the combination of the above features allows us to solve the problem.

The proposed device for mounting a mirror made of composite material using an open relief structure on the back side and used in a space telescope is illustrated by the drawings shown in FIG. 1-3.

Blueprints

In FIG. 1 shows a general view of a telescope mirror made of composite material using an open relief structure from the back, from the side of an open relief structure; in FIG. 2 is a section AA in FIG. 1 and a section of the base with installed support; in FIG. 3 is a view B in FIG. 2 - design of a holder with a hinge with a spherical head.

In FIG. 2 and 3 show the proposed telescope mirror mount device comprising a mirror 1, a base 2, three bushings 3, three hinges 4, three holders 5, six spherical washers 6, six spherical washers 7, three liners 8, three liners 9, three bushings 10 , three bushings 11, three washers 12, three spring washers 13, three nuts 14, six screws 15.

Mirror 1 (Fig. 1, 2) is installed on the base 2 (Fig. 2) using three holders 5 with hinges 4, which are evenly spaced around a circle whose radius is equal to the radius of the points of maximum deflection of mirror 1 in a plane perpendicular to its axis, under the influence of axial load.

In mirror 1, three bushings 3 (Fig. 3) are glued into specially provided in the ribs of the open relief structure of the socket 1 (Fig. 1), into which the hinges 4 are mounted. The spherical heads of the hinges 4 directly contact their spherical surface with the spherical surfaces of the liners 8 and 9 located in the bushings 3 through which the joints 4 are connected to the mirror 1.

The centers of the spherical heads of the hinges 4 are located in a plane passing through the center of mass of the mirror 1 and perpendicular to its axis, and are separated from the center of the mirror 1 by a distance equal to the radius of the circle along which the points of maximum deflection of the mirror are located in the plane perpendicular to its axis, under the influence of the axial load.

The clearance between the hinges 4 and the bushings 8 and 9 and the adjustment of the force causing the hinge 4 to move relative to the bushings 8 and 9 are selected by tightening the sleeve 10, screwed into the sleeve 3 and locked with screws 15 after adjustment is complete.

The holders 5 are rigidly connected to the hinges 4 (Fig. 3) by means of a threaded connection. The holders 5 are mounted to move in corresponding directions relative to the base 2 using pairs of spherical washers 6 and 7 and are fixed to the base 2 with nuts 14 through spring washers 13.

Pairs of spherical washers 6 and 7 provide movement of the holders 5 with hinges 4 along the spherical surface of the washers 6 and 7 relative to the base 2.

The device operates as follows.

During operation of the telescope, a change in the temperature field occurs. In this case, the dimensions of the mirror 1 made of a composite material and the base 2 made of another composite material vary differently due to different values of the temperature coefficients of linear expansion. The coefficient of linear expansion of the base material is less than the coefficient of linear expansion of the material of the mirror.

For example, as the temperature rises, mirror 1 and base 2 heat up and their linear dimensions increase, but by a different amount. In this case, the hinges 4 begin to rotate in the liners 8 and 9 relative to the bushings 4, rigidly connected with the mirror 1. The centers of the spherical heads of the hinges 4 are located in the plane passing through the center of mass of the mirror 1 and perpendicular to the axis of the mirror, and at equal intervals around a circle whose radius equal to the radius of the location of the points of maximum deflection of the mirror in a plane perpendicular to its axis, under the influence of axial load.

In turn, the holders 5, rigidly connected with the hinges 4, when the hinges 4 are rotated, begin to move in corresponding directions relative to the base 2 using spherical washers 6 and 7.

The clearance between the hinges 4 and the bushings 8 and 9 of the bushings 3 glued into the mirror 1 is selected and the force causing the hinges 4 to move relative to the bushings 8 and 9 is adjusted by tightening the bush 10 screwed into the bush 3.

The selection of play and the adjustment of the force causing the movement of the holders 5 relative to the base 2, is achieved by using spring washers 13 from the back of the base 2.

Thus, there is a movement of the mirror 1 relative to the base 2, caused by a change in the temperature field. In this case, there is no deformation of the mirror 1 when changing the linear dimensions of the mirror 1 and base 2.

A similar process occurs when the temperature decreases.

The proposed technical solution ensures the absence of temperature deformations by creating the possibility of free movement of the mirror and the base relative to each other when the temperature field changes, and the mirror is mounted on three hinges with holders, the centers of the spherical heads of which are evenly spaced around a circle whose radius is equal to the radius of the points of maximum deflection of the mirror in a plane perpendicular to its axis, under the influence of axial load, provides the necessary rigidity second mirror mount design. In addition, the proposed design is simple, and therefore its manufacture does not cause special difficulties.

Claims (2)

1. A device for attaching a telescope mirror, containing a base with three holders evenly spaced around with hinges with spherical heads, the centers of which are located in a plane perpendicular to the axis of the mirror and passing through its center of mass, characterized in that the mirror does not have through holes for mounting holders with hinges that are mounted to move in appropriate directions relative to the base using six pairs of spherical washers and provided with three spring washers on the back side of the base to select the backlash and adjust the force, causing the movement of the holders with hinges relative to the base. 2. The device according to claim 1, characterized in that the centers of the spherical heads of the hinges are located on a circle whose radius is equal to the radius of the points of maximum deflection of the mirror in a plane perpendicular to its axis under the influence of axial load.

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