RU2108645C1 - Sealed housing protecting reflector-type antenna - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: sealed housing protecting reflector-type antenna, specifically, apertures of various types of reflector-type antennas against atmospheric precipitation. Cylindrical blister of housing with flange is produced in the form of blister flanging directed inwards and has shape of truncated cone. Flange and protrusion manufactured in the form of ring embracing blister forms barrel that houses radioparent screen. Vertex of truncated cone is flanged towards screen. Embracing band with legs is made elastic and has sealing spacer on its internal surface. One of legs is fabricated in the form of truncated cone directed with vertex towards screen and contacts it, another leg contacts protrusion. EFFECT: simplified design, improved operational reliability. 1 cl, 4 dwg

Description

 The invention relates to radio engineering and is intended to protect the openings of the types of mirror antennas from the effects of precipitation.

 A known device is a radome antenna, made in the form of a shell of radiolucent material, mounted on the edge of the mirror with braces and a large number of additional structural elements [1].

 A large number of tension elements of the cowl shell, the need for their adjustment, as well as the presence of additional elements is the reason for the considerable complexity.

 A device is known for protecting an antenna of a radio-relay line from climatic precipitations, comprising a cone-shaped shell, the lower part of which is movably fixed to the base with springs located around the circumference, and the apex is rigidly attached to the mast of the transoscopic antenna [2].

 The need for a mast of the cross-over antenna for suspension of the cone and complex spring braces reduces the widespread use of this design.

 Known sealed housing of the antenna, containing a cylindrical body with an outer flange, on which is installed a radiotransparent screen, fixed with an annular washer and bolts [3].

 The need to adjust and tighten the bolts to ensure sealing during assembly-disassembly of the case in order to repair the nodes in the antenna aperture is not only not technologically advanced, but also laborious during repair work.

 The noted disadvantages can be eliminated by making the device in the form of a cylindrical body closed by a radiolucent screen with a sealing gasket and an element fixing the screen.

 Of these devices, the closest in technical essence and the achieved results to this invention is a device [4].

 The device comprises a casing with an outer flange mounted on it with a rubber sealing gasket, a radio-transparent screen in the form of a film; a rim with shelves, one of which is made with alternating protrusions and depressions, forming rectangular petals. Sealing is provided by installing the rim on the flange of the casing, followed by bending of the tabs-petals for the flange of the casing.

The disadvantages of this device are:
a) low sealing due to the fact that it is provided only on one surface of the casing - the front, since it has a rubber ring-gasket with a small contact area;
b) significant laboriousness during assembly-disassembly due to the need for uniform load on the shelf of the ring and the rubber gasket with deformation of the latter for alternately bending the tabs of the petals on the housing flange;
c) low maintainability due to the impossibility of multiple bending and bending of the petals of the ring when it is used again after replacing the film and repairing the nodes in the aperture of the antenna.

 The objective of the invention is to increase the tightness and reduce the complexity during assembly-disassembly of the housing.

 To solve this problem in the proposed design of a sealed enclosure for a mirror antenna, the casing is made with a flanging directed inside the casing, having the shape of a truncated cone.

 A protrusion made in the form of a ring is fixed on the casing, covering the casing and forming a glass with the flanging of the casing for placing a radiotransparent screen made in the form of a panel, while the top of the truncated flanging cone is directed towards the screen.

 The rim with shelves is made elastic with a sealing gasket on the inner surface.

 One of the shelves has the shape of a truncated cone directed by the apex inside the rim, and is in contact with the screen, and the other shelf is in contact with the protrusion.

 Figure 1 shows a section of a sealed enclosure of a mirror antenna in a plane perpendicular to a radiotransparent panel; in FIG. 2 - section of the casing assembly; in FIG. 3 - section of the elastic rim; in FIG. 4 is a general view of a mirror antenna.

 The hermetic housing for the mirror antenna (Fig. 1) contains a casing of cylindrical shape 1 with a protrusion fixed in the form of a ring 2, a radio-transparent screen 3, an elastic rim 4 with a sealing gasket 5.

 The casing 1 (figure 2) is made with a flange 6, directed inside the cylinder. Flanging is made in the form of an elastic truncated cone 7.

 The protrusion 2 in the form of a ring covering the casing 1 is fixed on it in such a way that the end surface 8 protrudes beyond the base 9 of the flange cone 7 and forms a glass 10 with the last, designed to accommodate a radiotransparent screen 3 (Fig. 1).

 The elastic rim 4 (figure 3) is made with shelves 11, 12. Shelf 11 is made in the form of a reverse truncated cone, apex facing the inside of the rim, forming an angle α with inner surface 13 and contacts surface 14 with panel 3 (figure 1), and the shelf 12 is in contact with the surface 15 (figure 2) of the protrusion 2.

 On the surface 14 of the shelf 11 and the surface 13 is placed a sealing gasket 5 (figure 1), the element 16 (figure 4) is designed to tighten the rim 4, and the sealed housing assembly 17 is mounted on the antenna reflector 18 with screws 19 and nuts 20.

 The device operates as follows: on the inner surfaces 13, 14 of the elastic rim 4 we place a sealing gasket 5, in the glass 10 we install a radiotransparent screen 3.

 We place the rim 4 and embrace the protrusion 2, while exerting pressure on the screen 3, through which we transmit the force to the elastic conical flange 6. Moreover, its shape of the truncated cone takes a 1-shape with a surface perpendicular to the inner surface of the rim.

 When the rim covers the protrusion 2, the shelf 12 interacts with the surface 15, excluding the axial movement of the rim in the direction of the cup 10 (in the direction of arrow A).

 The shelf 11 through the gasket 5 is in contact with the outer surface of the screen 3. Due to the elasticity of the shelf 11, the cone angle changes from angle α to angle β (angle α is less than angle β), shelf 11 uniformly presses screen 3 to the bottom of glass 10, creating a tight connection between the shelf 11 and screen 3.

 Tightening the rim 4 with the element 16, we compress the sealing gasket 5 around the protrusion 2, ensuring the tightness of the connection between the protrusion and the rim on the surface 13, which together with the inclined shelf 11 provides sealing of the aperture cavity of the mirror antenna during multiple assembly-disassembly of the housing, and the presence of one mounting element 16 provides the efficiency of assembly-disassembly of the housing during repair work.

Claims (2)

 1. A sealed enclosure for a mirror antenna, comprising a flange, a sealing gasket mounted on it, a radiotransparent screen and covering a rim with shelves, fixing the sealing gasket, and a radiotransparent screen, characterized in that the cylindrical casing is inserted, and the flange is made in the form of a flanging of the cylindrical casing, directed inside the cylindrical casing, the flange and the protrusion, made in the form of a ring covering the cylindrical casing, form a glass in which is placed a radiotransparent screen covering with shelves made resilient, and the sealing gasket is placed on the inner surface of one of the flanges of the female rim is formed as a truncated cone, the vertex directed towards the radiotransparent screen and in contact with it, and the other is contacted with the protrusion.  2. The housing according to claim 1, characterized in that the flanging of the cylindrical casing has the shape of a truncated cone directed by the apex towards the screen.

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