RU128018U1 - TRANSFORMABLE REFLECTOR OF THE PARABOLIC ANTENNA - Google Patents

Abstract

Transformable reflector of a parabolic antenna, consisting of a set of rigid ribs mechanically connected to the net-blade and fixed in the deployed position by means of a locking mechanism, characterized in that the rigid ribs at the base are interconnected into a packet by a flexible metal tape like a fan with the possibility of 360 ° rotation one locking rib relative to another locking rib, and the locking mechanism is removable and is a pipe, at the ends of which are rigidly connected to the pipe and serving minutes for basing rigid ribs basic disk and the pressure disk having the ability to move along the tube, the position of the pressing disc on the tube is adjusted by means of nuts.

Description

The utility model relates to radio engineering, in particular to terrestrial folding parabolic antennas and can be used in radio communication systems and information transfer.

A class of parabolic umbrella antennas with rigid ribs is known. Umbrella antenna designs are considered in the monograph Gryanik M.V., Loman V.I. "Umbrella type deployable reflector antennas." M .: Radio and communication. 1987 (p. 7-9). The reflectors of such antennas contain ribs with a given profile, located radially relative to the central hub and pivotally connected to it. These ribs form a frame supporting the surface of the reflector made of an elastic radio-reflecting net-sheet. When coagulating, the ribs add up to the axis of symmetry of the reflector.

The disadvantages of umbrella antennas include the complexity of the disclosure mechanism, which includes a large number of movable links and articulated joints, which leads to the need to align each rib separately.

Closest to the claimed technical solution is the antenna reflector described in US patent 4030103, H01Q 15/20. The radio-reflecting surface of the reflector is formed by an elastic net-sheet mechanically connected to the ribs. The ribs are individually shaped and each of them is pivotally attached to a semicircular support. The base of the ribs are mechanically connected with torsion springs installed in the support, which create the necessary moment for the reflector to open. When deploying the antenna, the ribs move apart in the aperture plane. The vertices of two adjacent ribs are interconnected by flexible inextensible ribbons that limit the rotation of the ribs and serve as elements for fixing the ribs in the deployed position. This technical solution is taken as a prototype.

The main disadvantage of the prototype is the low accuracy of the reflective surface of the reflector. Long ribs increase profile errors at the edge of the reflector from the ideal. Each rib is attached to the base through a hinge assembly, which increases the dimensional chain of positioning the ribs in the open position of the reflector and, therefore, reduces the accuracy of the reflecting surface.

The objective of the utility model is to increase the accuracy of the reflective surface of the reflector with the minimum size when folded.

The problem is achieved in that in the reflector of a parabolic antenna, consisting of a set of rigid ribs mechanically connected to the net-blade and fixed in the deployed position by means of a locking mechanism, according to the technical solution, the rigid ribs at the base are interconnected into a packet with a flexible metal tape like a fan with the ability to rotate 360 ° of one locking rib relative to another locking rib, and the locking mechanism is removable and is a pipe, at the ends of which are installed JCOMM coupled to the tube and serving as a base for the ribs and base disc presser drive having the ability to move along the tube, wherein the pressure disc position on the tube is adjusted by means of nuts.

The essence of the utility model is illustrated by drawings.

Figure 1 shows a General view of the reflector in the deployed position.

Figure 2 is a General view of the reflector in a collapsed position (setoplotnogo not shown).

Figure 3 is a schematic diagram of a package of ribs in the expanded position (only the bases of the ribs are conventionally shown).

Figure 4 is a schematic diagram of a package of ribs in a collapsed position.

Figure 5 - fixing mechanism.

6 is a General view of the reflector with the locking mechanism assembly.

Transformable parabolic reflector consists of a package of rigid ribs 1, mechanically connected to the radio-reflecting net-sheet 2 and a removable mechanism for fixing the ribs in the deployed position.

The ribs 1 are pulled together at the base with a metal tape 3, which allows the reflector to be opened like a fan by rotating one locking rib 5 360 ° relative to the other locking link. Each rib has a stop 4, which serves to position the ribs in the deployed position of the reflector and prevent them from turning in the plane of disclosure. The thickness of the closing ribs 5 is equal to half the thickness of the remaining ribs 1, which ensures uniform distribution of the ribs around the circumference. In the unfolded position, the closing edges of the reflector along the connection line are rigidly fastened together by locks (not shown in the drawing) forming a single rib. On the bases of the rigid ribs 1 and the closing ribs 5, cutouts are made, the shape of which corresponds to the shape of the profile of the base 6 of the locking mechanism disk. The surfaces A and B of the cutouts are used to base the ribs on the base disk when the reflector is opened.

The fixing mechanism (Fig. 5) consists of a pipe 7, two disks — a base 6 and a clamp 8 and a nut 9. The base disc 6 is rigidly connected to the pipe 7. The clamp disc 8 can be moved along the pipe 7 with the nut 9. To open the reflector the package of ribs is manually wrapped around the pipe 7 360 ° like a fan. The locking ribs are connected together and fixed with locks among themselves. Using the nut 9, press the clamping disk 8 against the stop. The ribs are based on the surfaces A and B of the cutouts on the base disk 6 and their fixation. The folding of the package of ribs is also performed manually in the reverse order.

Currently, according to the technical solution proposed by the authors, a prototype reflector with a diameter of 1.3 meters has been manufactured. The reflector contains 30 ribs. Dimensions when folded: 800 × 210 × 125 (mm).

An increase in reflector accuracy is expected due to the minimum dimensional chain of positioning the ribs in the assembly.

Claims (1)

Transformable reflector of a parabolic antenna, consisting of a set of rigid ribs mechanically connected to a net-blade and fixed in the deployed position by means of a locking mechanism, characterized in that the rigid ribs at the base are interconnected into a packet by a flexible metal tape like a fan with the possibility of 360 ° rotation one locking rib relative to another locking rib, and the locking mechanism is removable and is a pipe, at the ends of which are rigidly connected to the pipe and serving minutes for basing rigid ribs basic disk and the pressure disk having the ability to move along the tube, the position of the pressing disc on the tube is adjusted by means of nuts.

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