RU164302U1 - RADIO TRANSPARENT ANTENNA SHELTER - Google Patents

Abstract

A radiolucent antenna cover containing a three-layer sheath with fiberglass inner and outer sheaths and an intermediate layer of fiberglass and made without flanges with the same shell wall thickness, characterized in that the shell is composite and consists of three equal spherical-shaped segments interconnected by gluing elements into each other at the seams using resin without the use of fasteners, while the upper part contains a cover and a ventilation well.

Description

Technical field

The utility model relates to radio engineering and can be used as a radiotransparent shelter to protect various radio engineering complexes from adverse external influences. The technical result consists in reducing the weight of the structure compared to known analogues while maintaining stiffness characteristics.

State of the art

Spherical cylindrical radiotransparent shelters are known. With monolithic radiotransparent walls, described, for example, in the monograph by I.G. Gurtovnik et al. Radiolucent fiberglass products / Ed. ed. IN AND. Sokolova. - Moscow: Mir, 2002 - 368 p. However, their common drawback is the large mass.

A multilayer radiotransparent shelter for antennas is known, described in patent RU 2314609 C1 IPC H01Q 1/42. The disadvantage of this shelter is the complexity of the design, a very strong dependence of the design parameters on the specific manufacturing process. In addition, honeycomb fillers are used in the shelter design, the water resistance of which under severe operating conditions is significantly reduced.

Known RF patent for the invention 2358362 C1 IPC H01Q 1/02, publ. 06/10/2009, where the subject of the invention is a radiolucent dome designed to protect the antennas of the microwave range of radio waves from adverse weather and other factors. The disadvantage of this design is its bulkiness and the need for constant maintenance.

A patent is known for utility model RU 145402 U1 IPC H01Q 1/00, where the subject of the invention is a radiotransparent shelter for a repeater. The disadvantage of this design is the presence of bolted joints, which reduce the rigidity of the structure as a whole.

The closest technical solution is a radiotransparent shelter for antennas, described in patent for invention RU 2419927 C1 IPC H01Q 1/42. The invention relates to radio engineering and can be used as radiotransparent shelters and fairings to protect antennas, including satellite communication stations, from the influence of mechanical and climatic factors of the invention. Creation of a mechanically durable moisture-resistant radiotransparent shelter for spherical-shaped antennas having the same wall thickness along the entire contour, with the outer and inner layers of composite materials, an intermediate layer of fiberglass panels filled with syntactic foam, over which the fiberglass is located, while simplifying the technology of its manufacture and mounting is a technical result of the invention. The radiotransparent shelter is made in layers along the inner contour on one rigid forming tooling. At the same time, the radiotransparent shelter is made without flanges, has an integral structure with a metal adapter in the form of a frame connected to the inner surface of the multilayer fiberglass plastic shell with screws, "snake-like", in combination with epoxy glue, the frame is attached to the supporting platform by a threaded connection.

The disadvantage of this invention is the use of syntactic foam as a placeholder for fiberglass panels, which significantly increases the weight of the structure, which makes it difficult to install in position. Another drawback is the integral design, which makes it impossible to install shelters without special lifting mechanisms, and also complicates the process of laying out materials in the manufacture of the product by contact vacuum molding.

Utility Model Disclosure

The utility model relates to radio engineering and can be used as a radiotransparent shelter to protect various radio engineering complexes from adverse external influences. The technical result consists in reducing the weight of the structure compared to known analogues while maintaining stiffness characteristics. The claimed result is achieved due to the fact that the radiotransparent shelter of a spherical cylindrical shape consists of three equal segments interconnected by gluing elements into each other at the seams using resin without the use of connecting bolts. This allows you to achieve equal thickness of the shelter over the entire surface and the ability to assemble at a position without the use of lifting mechanisms.

Brief Description of the Drawings

In FIG. 1 shows the antenna cover assembly, where

1 - section;

2 - cover;

3 - ventilation well;

In FIG. 2 shows a spherical cylinder panel - part of the shell

Utility Model Implementation

The obtained technical result is achieved due to the fact that the radiotransparent shelter (see Fig. 1) is made up of three identical panels, as well as a cover and a ventilation shaft that protects the process hole from precipitation entering the product without interconnecting elements by gluing each other into other panels using resin.

The panels are made by vacuum vacuum molding in the following sequence: on a matrix made of composite materials, the inner surface of which repeats the outer surface of the product, several layers of release agent are applied. Spread on the matrix the required number of layers of prepreg (fiberglass impregnated with a binder), at different angles (0 ° / 90 °) to form the outer skin. The honeycomb of the required height is laid over the entire surface. The required number of prepreg layers are stacked on the honeycomb core at various angles to form the inner skin. The blank is covered with a sacrificial fabric, a perforated film, a drainage layer and a vacuum film fixed to the edges of the matrix with a high-temperature sealant. Through hoses connected to the vacuum bag using fittings, create a vacuum and place the workpiece in a heating cabinet, where at the curing temperature of the binder occurs a vacuum system. The form with the bag in place is placed in a heating cabinet or autoclave, where the product is molded at the polymerization temperature of the resin, the product cures. To improve the surface quality of the product from the side of the vacuum cover, tsulagia is used - a solid intermediate layer of thin fiberglass, which is located between the vacuum cover and the molded product and has a shape that matches the contour of the product. This method allows to obtain strong segments of the required thickness with a given surface curvature.

Claims (1)

A radiolucent antenna cover containing a three-layer sheath with fiberglass inner and outer sheaths and an intermediate layer of fiberglass and made without flanges with the same shell wall thickness, characterized in that the shell is composite and consists of three equal spherical-shaped segments interconnected by gluing elements into each other at the seams using resin without the use of fasteners, while the upper part contains a cover and a ventilation well.

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