SU915054A1 - Honeycomb mirror - Google Patents

Description

The invention relates to an optical instrument and can be used, in particular, in telescopes. _

Cellular mirrors are known, comprising a mirror plate and a substrate having a honeycomb structure.

The honeycomb structure of the substrate of such mirrors is formed by drilling or milling from the back of a monolithic disk of relief holes of various configurations [11.

However, such structures are difficult to manufacture, do not provide high relief and stiffness compared to conventional monolithic mirrors.

The closest technical solution to the invention is a mirror containing a plate of a mirror 20 (p plate substrate made of optical glass and a honeycomb package [2].

The honeycomb structure of such structures is formed from tubular or other shaped sections of elements welded to each other, with the elements made of the same material as the plates of the mirror and the substrate. Such constructions mirrors about 30

2

They offer higher rigidity, but the degree of relief is limited by the technological capabilities of their manufacture.

The purpose of the invention is to increase the degree of simplification of the structure while maintaining the thermal stability of the reflecting surface of the mirror.

This goal is achieved by the fact that in a honeycomb mirror, mainly for a telescope containing a plate-mirror and a plate-substrate made of optical glass, and a honeycomb bag, the honeycomb bag is made of metal foil, and the ratio of thickness 1 of the cell wall of the bag to diameter in the inscribed in the cell of a circle is selected from the ratio ί: B g0.01.

FIG. 1 shows the proposed mirror; in fig. 2 - the same, longitudinal section; in fig. 3 is one of the methods for manufacturing the honeycomb structure of a metal foil substrate.

The honeycomb mirror contains a plate-mirror 1, a honeycomb package 2 of

metal foil plate substrate 3.

915054

The manufacturing technology of the blank of such a mirror is as follows.

The strips 4 are cut from the metal foil, then they are joined (by welding, soldering or gluing) in series with each other at equal intervals along the length along sections 5 (Fig. 3). After that, holes 6 are drilled, communicating the cells between themselves and the environment, and the resulting packet is stretched in the direction indicated by the arrows in FIG. 3. At the same time, a honeycomb structure of a hexagonal or quadrangular shape is formed (depending on the type of connection of the strips). The ratio of the thickness b of the walls of the cell package to the diameter inscribed in the cell; the circle is chosen from the ratio b: b is less than or equal to 0.01. The resulting honeycomb structure is cut by the diameter of the mirror and, if necessary, processed on the end surfaces in accordance with the shape of the mating surfaces of the plates of the mirror and the substrate. The final stage of the preparation of the workpiece is the connection (by sintering or gluing) the honeycomb package with the mirror plate and the substrate plate. This is followed by the usual operations of processing the plate-mirror (grinding and polishing) in order to obtain a reflective surface.

In the proposed mirror, heterogeneous materials are combined, therefore, to preserve the quality of the reflective surface during thermal exposure, which may deteriorate due to differences in thermal linear expansion coefficients of the plate material and honeycomb structure, the rigidity of the structure in the radial direction is reduced by reducing the thickness ratio of 7 stand cells ( foil thickness) to the diameter B of the circle inscribed in the cell of the cellular package ^. The smaller the ratio And in, the less influence of the cellular structure on the deformation of the mirror as a whole. The limiting minimum value of this ratio is limited by the stability of the cell walls during the optical processing of the reflecting surface when it is under the influence of the processing tool.

The invention (the manufacture of a cellular package from metal foil and the above-described selection of the ratio of the cell wall thickness to the cell size) ensures that the quality of the reflecting surface of the mirror is preserved under thermal influence while significantly reducing the weight of the whole structure as compared to air cushions made entirely of optical glass or metal.

For example, a mirror with a diameter of 2.4 m with a honeycomb structure of aluminum: a foil and plates of fused silica deform 2-2.5 times less compared to the known mirrors entirely of fused silica with the same thermal effect. In this case, the mass of the proposed mirror is several times less than the mass of the known.

Claims (1)

Claim A cellular mirror, mainly for a telescope, containing a plate mirror and a wafer substrate made of optical glass, and a honeycomb bag, characterized in that, in order to increase the degree of ease of construction while maintaining the thermal stability of the reflecting surface of the mirror, the honeycomb bag is made of metal foil , moreover, the ratio of the thickness g of the cell walls of the bag to the diameter B of the circle inscribed in the cell is selected from the ratio £: B 4 0.01