SU1053054A1 - Mirror - Google Patents

Abstract

A MIRROR containing alternating layers of optically transparent and reflective materials, which is so that, in order to expand the range of its operation to the melting temperature of the layer of reflective material, distinct layers are made in the layers of reflective material (Holes and layers of optically transparent material through the latter and by iperimeter are interconnected.: l CAD o: e 4; & k

Description

The invention relates to optics, 8 particularly to mirrors for solar and heat protection devices.

A mirror is known, containing alternating layers of optically transparent and reflective materials, which serve to increase the reflection of several spectral bands of radiation ij.

However, the operating range of a known mirror is limited by the melting point of the layer of reflective material.

The aim of the invention is to expand the range of operation of the mirror.

The P-left target is achieved by the fact that mismatched holes are made in the mirror containing alternating layers of optically transparent and reflective materials, the layers of the reflecting material are interconnected through the latter and along the perimeter.

Figure 1 shows the mirror view. from above; figure 2 - the same cross. section, in fig. 3 - examples of use ;; of a mirror in helioelectric power stations: as a reflecting layer of a concentrator and thermal insulation of pipelines and a battery.

The mirror contains alternating layers 1 and 2 (figure 1) Optically transparent and reflective materials, respectively. Non-coincident holes 3 are made in the layers 2 of the reflecting material, and layers 1 (the optically transparent material of FIG. 2 are interconnected through the holes 3 and along the perimeter. Holes 3 with a diameter of | 50 MKW are evenly distributed in the caudary layer 2 of the reflective material mainly of aluminum foil with a thickness of 4-5 µm, forming a square grid with a side of 150-180 µm. As layers 1 of an optically transparent material, polycrystalline films from DS 0 can be used obtained by spraying in a vacuum on a mobile substrate.

When the mirror is made five-layered and containing three layers 1 (figure 2) of a polycrystalline film of 0 and two layers of aluminum foil sealed between them, holes 3 of one of the layers 2 are located against the centers of the square grid. Formed by the holes 3 of the other layer 2.

In the manufacture of n psLoynogo, mirrors are pre-punched

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two rolls of aluminum foil, then one of the rolls of the set is poured in a vacuum sputtering chamber, where successively two-sided application of a film of .ACjO-j is carried out on the foil of this roll, after which the foil protected with APjOj films is rewound together with the foil of the other roll while applying AEjO films. For best adhesion of aluminum foil and A6 films. Oz. The heat during spraying is up to.

The mirror can be used in solar power plants as a reflective coating 4 (fig. 3) of concentrators 5 and b and heat insulation 7 of pipelines 8 and heat accumulator 9 made of two concentric spheres with a vacuum gap 10 between them. The solar power plant also includes a Radiation 11 receiver installed in the focal zone of the concentrators 5 and b, piping 8 hydraulically connected to the heat accumulator 9 filled with liquid helium, pump 12, heat exchanger 13, turbine 14 and electric generator 1..

Mirror works as follows. ,; ; ; , , ,,

The radiation incident on the mirror passes through the detecting layer 1 of the film and is reflected by the first layer 2 of aluminum foil. Part of the radiation, the passage through the holes 3 of the first layer 2 of aluminum foil and the intermediate layer 1 of the film ARG Od y are reflected by the second layer 2 of aluminum foil. The reflectivity of the mirror increases when its operating temperature exceeds the melting point of the aluminum foil.

The hermetic arrangement of the layers 2 of the reflective material between the layers 1 of the optically transparent material and the connection of the latter between them along the perimeter and through the apertures 3, previously made of aluminum foil (layers 2), makes it possible to reach working temperatures exceeding the melting temperature of the layers 2 reflecting material, without the separation of the mirror, which in turn increases the range of the work of the mirror and increases its optical efficiency. Increasing the optical efficiency is also achieved by performing in layers 2 of the reflective material adayuschih holes.

2

Claims (1)

MIRROR containing alternating layers of optically transparent and reflective materials, which consists in the fact that, in order to expand the range of its operation to the melting temperature of the layer of reflective material, mismatching openings are made in the layers of the reflecting material, and the layers are optically transparent. of material through the latter and along the perimeter are interconnected.