RU2321872C2 - Unit for fitting and adjusting astronomic mirror in telescope tube - Google Patents

Abstract

FIELD: optical instrument engineering.

SUBSTANCE: unit for fitting and adjusting mirrors with diameter up to 300 mm without worsening shape of surface. Unit for fitting and adjusting astronomic mirror in telescope mirror provides ability of inclination of mirror relatively its center and it has split bushing glued into mirror. Split bushing is connected with movable bushing of convex spherical mirror of hinge. Split bushing moves inside concave spherical hinge of back flange of telescope tube by means of clamp bolts which bolts go through openings of flange into stop ring put onto bead of convex spherical mirror. Deformation of surface of mirror can be excluded due to fact that edge of split bushing , which edge is opposite to lobes, is provided with rest cylindrical bead which is attached with bushing of movable spherical hinge by means of thread ring. Ring spacers are mounted at both sides of bead. Rings rest against bead by three symmetrical protrusions disposed one in opposition to other. Ring spacers are fixed to avoid turn onto bushing of concave spherical hinge by means of stop hinges.

EFFECT: ability of adjustment without worsening shape of surface.

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Description

The invention relates to optical instrumentation and can be used in serial small-sized telescopes for mounting and aligning main mirrors having a central hole.

Known mount the main mirror with a Central hole using a sleeve for the edges of the Central hole, which allows to reduce the deformation of the working surface when exposed to dynamic loads and temperature differences and allowing the possibility of alignment of the mirror [1].

The well-known mirror mount with a central hole is applicable for devices with reduced image quality requirements. Its main drawback when used in small-sized astronomical telescopes, where the root-mean-square error of the mirror surface shape should not exceed RMS = 0.05-0.07λ, are the residual deformations of the mirror surface, which occur both during hardening of the sealant and when stresses of the clamping element are released during drops temperatures. In addition, the elastic fasteners do not allow, with the specified tolerance on the shape of the surface of the mirror, to maintain its alignment in the system with an accuracy of 20 "-40" (as required by some high-aperture optical systems of telescopes) under dynamic loads arising during transportation of the telescope. Therefore, a laborious adjustment of the mirror mount after transportation is required.

A known mounting unit of the main mirror with a Central hole adjacent to the inner surface of the rear cover and containing a stationary supporting sleeve of a spherical hinge and a sleeve with pronounced elastic petals, on which the main mirror is rigidly mounted [2, 3].

The known site allows you to mount and align the mirrors of small telescopes with a diameter of up to 200 mm, but when mounting mirrors of larger diameter there are significant residual surface deformations, the cause of which is the transmission of the longitudinal tightening force of the threaded joint of the split sleeve and the convex spherical hinge sleeve to the elastic petals of the split sleeve, and, therefore, the mirror, which is the main disadvantage of the known site.

The proposed mirror mount in the telescope makes it possible to get rid of the residual deformations of the mirror surface that occur when the split sleeve and the sleeve of the movable convex spherical hinge are connected.

This is ensured by the fact that the end face of the split sleeve opposite the petals is provided with a persistent cylindrical collar to which the sleeve of the movable spherical hinge is fastened with a threaded ring, and spacer rings are mounted on both sides of the flange, abutting the flange with three radially symmetrical protrusions located opposite each other other, and the spacer rings are fixed from rotation on the sleeve by locking screws. In this case, the compression force and the reaction of the support that occur when the threaded ring is tightened are distributed at the points of contact of the radially symmetric protrusions of the spacer rings and the shoulder, and, practically, are applied at the same points, which does not cause deflection of the persistent shoulder and the transfer of stress to the elastic petals split sleeve.

The authors are not aware of the attachment points of the astronomical mirrors with a central hole, having features similar to those that distinguish the proposed attachment point of the astronomical mirror from the prototype, therefore, this attachment point of the astronomical mirror has significant differences.

The proposed invention is illustrated by the following graphic materials.

Figure 1 - The mount of the astronomical mirror with a Central hole in the tube of the telescope.

Figure 2 - Interferograms 256 mm mirrors glued into it with a split sleeve.

Figure 3 - Interferograms 256 mm of the mirror of figure 2, locked in the inventive mounting node.

4, 6 - Interferograms 256 mm mirrors.

5, 7 - Interferograms of 256 mm mirrors of FIGS. 4 and 6, blocked in the claimed mount.

Figure 1 shows the proposed mount of the astronomical mirror with a central hole in the telescope tube. The assembly contains: a main mirror 1 with a central hole, a split sleeve 2, a movable sleeve of a convex spherical hinge 3, gaskets 4 and 5, a threaded ring 6, locking screws 7 and 8, a fixed concave hinge 9, which is also the rear flange of the telescope pipe, locking ring 10 and clamping bolts 11.

The principle of operation of the proposed attachment of an astronomical mirror with a central hole is as follows.

The main mirror 1 is rigidly glued to the supporting areas of the elastic petals of the split sleeve 2, while the axis of the sleeve is perpendicular to the base plane of the supporting platform of the rear side of the mirror 1 (Fig. 1). The split sleeve 2 is connected through a stop collar with a movable sleeve of a convex spherical hinge 3 (on the collar of which a snap ring 10 is previously put on) using spacer rings 5, 4 and a threaded ring 6. Each spacer ring is provided with three radially symmetrical protrusions, which during assembly sequentially mounted on the sleeve 3 opposite each other by thrust pads and fixed from mutual movement by the locking screws 8 and 7, after which the threaded ring 6 is tightened and the installation is assembled block into the concave spherical hinge 9 of the rear flange of the telescope pipe. The final tightening of the clamping bolts 11 is in the process of aligning the mirror in the telescope.

The supporting protrusions of the rings are 8-10 mm wide, they are ground and adjusted in thickness with a tolerance of 0.01 mm. The angular movements of the mirror 1 around its center during the adjustment of the telescope are carried out by moving the sleeve of the convex spherical hinge 3 in the fixed concave spherical hinge 9 of the rear flange of the telescope pipe with the help of clamping bolts 11, passed through the holes of the flange 9 into the retaining ring 10, worn on the shoulder of the movable spherical sleeve hinge 3.

Empirically, on a vibrating stand, when modeling the dynamic load on the proposed mirror mount with a diameter of 256 mm, which occurs during road transportation of the telescope in a rigid container without shock absorbers, it was found that to exclude angular movements of the mirror of the order of 20 "-40" in a fully tightened polished spherical hinge the width of the polished bearing pads of the spacer rings 8-10 mm, the required tightening torque of the threaded ring 6 is 3-5 kg / m. The tightening force of the threaded joint of the elements 6 and 3 applied to the shoulder of the split sleeve 2 is distributed within the supporting areas of the spacer ring 4 the more uniformly, the more accurate they are, as well as the sides of the thrust shoulder of the split sleeve 2, processed and the higher the cleanliness of processing. Since the spacer ring 5 between the collar of the split sleeve 2 and the collar of the sleeve of the spherical joint 3 is mounted by supporting platforms opposite to the supporting areas of the spacer ring 4, the reaction of the support acting on the collar of the sleeve 2 will be distributed within the supporting areas of the spacer ring 5 and applied to the shoulder in those in the same places as the compressive forces acting on it, so they will not cause bending moments that could lead to deformation of the thrust collar of the split sleeve 2, and hence the mirror 1. However, considering that the bearing pads of rings 4 and 5 have finite dimensions, to completely eliminate the residual deformations of the mirror surface, which can nevertheless occur from the uneven distribution of the tightening force of the threaded connection of elements 3 and 6 at the points of contact of the supporting pads of the spacer rings 4, 5 with the shoulder of the split sleeve 2, high purity of processing and adjustment of the thickness of the supporting areas of the spacer rings and flange are necessary.

Let us justify the possibility of mounting an astronomical mirror with a central hole in the proposed site without significantly changing the shape of the optical surface using the example of mirror blocking with a diameter of 256 mm.

Figure 2 shows the interferograms of a 256 mm mirror (mutually perpendicular strips and rings) with an 80 mm central hole into which a heat-treated steel split sleeve with 15 polished elastic petals is glued to a heat-resistant elastic glue [2]. Interferograms were obtained from the center of curvature of the mirror on a Fizeau type interferometer. In the upper right corner of FIG. 2, the value of the mean square error of the wavefront RMS obtained as a result of digital analysis, measured from the center of curvature of the mirror (doubled surface shape error related to the wavelength λ = 632.8 nm), is shown. In the upper left corner of Fig. 2, for reference, the maximum deviation of the wavefront from the nearest comparison sphere PV is shown.

Figure 3 shows the interferograms of the same mirror located in the fully assembled claimed mount, the spacer rings 4 and 5 were not specially adjusted. The threaded ring 6 is clamped with a torque of 5 kg / m, and the quotation bolts 10 are fully tightened. The interferograms of FIG. 3 are obtained in the same control scheme as the interferograms of FIG. 2.

Comparing the root-mean-square error of the RMS wavefront shown in FIGS. 2 and 3, it can be seen that the shape of the surface of the mirror installed in the proposed mount, and the shape of the surface of the mirror with the split sleeve glued into it do not differ significantly. The difference in RMS is 0.016λ. The assembly and control of two dozens of experimental sets of similar attachment points for 256 mm mirrors showed that, on average, without fitting the parts of the attachment point, the changes in the shape of the mirrors do not exceed the specified value, and with careful grinding and adjustment of the support areas of the gasket rings 4,5 and the collar of the split sleeve 2 (FIG. 1) can be reduced to RMS = 0.01λ or less.

As an example of how small the changes in the shape of the surface of the mirror can be with careful refinement of the details of the proposed mirror mount, the interferograms of Figures 4-7 are shown, obtained for two 256 mm mirrors of the same parameters and under the same control conditions. The interferograms of FIG. 4 and FIG. 6 correspond to unlocked mirrors without split sleeves glued into them, and the interferograms of FIG. 5 and FIG. 7 correspond to the same mirrors assembled into the proposed fastener assembly with carefully polished and fitted spacer rings in thickness. Comparing the data of calculating the wavefront errors in the interferograms of FIGS. 4, 5 and 6, 7, it can be seen that the difference in the mean square error RMS for a blocked and not blocked mirror does not exceed 0.003λ, and the difference PV does not exceed 0.05λ and is outside precision digital interferometry. This makes it possible to assert that the astronomical mirror locked into the proposed attachment site with careful tuning of the attachment site details practically does not change the shape of its surface.

Thus, it can be considered justified that the proposed mount and alignment unit of the astronomical mirror allows you to mount mirrors with a diameter of 256 mm in the telescope without significant deformation of their surface. This is ensured by a new set of distinctive features: the end face of the split sleeve, opposite the petals, is equipped with a persistent cylindrical collar, to which the sleeve of the movable spherical hinge is fastened with a threaded ring, and spacer rings are mounted on both sides of the collar, abutting the collar with three radially symmetrical protrusions, located opposite each other, and the spacer rings are fixed from rotation on the sleeve by locking screws.

The proposed attachment and adjustment unit of the astronomical mirror, implementing the method of attachment of the prototype, retains all its design advantages, such as: effective unloading of the mirror from its own weight, simplification of the design of the attachment unit of the mirror, the possibility of alignment and maintaining its stability under dynamic loads, reducing dimensions and weight of the telescope tube, low sensitivity of the instrument to fluctuations in ambient temperature. In addition, thanks to the new combination of distinctive features, it is possible to predict an increase in the diameter of the blocked mirror to at least 300 mm, as well as a significant improvement in the quality of blocking mirrors of smaller diameter, which should reduce the percentage of rejects in the assembly according to residual deformations of the shape of the mirror surface.

LITERATURE

1. V.P. Trushkin, G.A. Rodionov, R.X. Garifullina "Frame for an optical element with a central hole". USSR copyright certificate SU No. 1697038 A1, Bulletin No. 45, 1991.

2. Klevtsov Yu.A. "A method of mounting an astronomical mirror in a telescope tube." Patent for the invention of the Russian Federation RU No. 2201608 C2, Bulletin No. 9, 2003.

3. I.V. Kucher, Yu.A. Klevtsov, L.V. Parko "The device of a catadioptric telescope." Description of the utility model RU No. 23508 U1, Bulletin No. 17, 2002.

Claims (1)

An attachment and adjustment unit for an astronomical mirror in a telescope tube, comprising a split sleeve connected to a movable sleeve of a convex spherical hinge that can move inside the concave spherical hinge of the rear flange of the telescope pipe using clamping bolts passed through the holes of the flange into the circlip worn on bead of a convex spherical hinge, characterized in that the end face of the split sleeve, opposite the petals, is provided with a thrust cylindrical bead to which the thread ovym ring bushing mounted movable spherical hinge, and on it on both sides of the bead set prokladnye ring abutting a shoulder three radially symmetric protrusions arranged opposite to each other, wherein prokladnye ring secured against rotation on the hub locking screws.

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