DE3027095A1 - Aerial with large surface area parabolic reflector - consists of parallel carbon fibre reinforced plastic slats fed from horns, for marine radar - Google Patents

Abstract

The aerial with a reflector has a relatively large surface area. It is formed from slats mounted parallel with slits in between every two parallel slats. It is used in marine radar systems, can be swiftly swept through large angles, and is mounted on the top of a mast. The slats (6) are made from plastic reinforced with carbon fibres. The reflector (3) is fed by a system of linearly extending horns (7). The horns are fed from a common wave guide (8). The reflector has a parabolic shape with single curvature.

Description

The invention relates to antennas, and more particularly to antennas

with relatively large reflectors. Antennas of this type are commonly used used for purposes such as marine radar systems and are usually scannable. One The difficulty encountered with such antennas is that due to their Size and due to the fact that they are necessarily in an exposed position, e.g. at the top of a mast in the case of a marine radar antenna and thus a considerable wind load occurs.

This wind load on the antenna makes it susceptible to mechanical ones Damage.

It is known the effects of wind load as well as weight reduce the antenna by not making the reflector from a solid panel reflective material, but in the form of a framework using a A large number of leading strips is built up.

A typical antenna of this type is shown schematically in FIG Figure 1 shown.

The antenna shown in Figure 1 is a marine radar antenna, as it is arranged at the top of a mast 1 and in azimuth accordingly the indicated arrow 2 can rotate. A major part of the antenna is made up of the reflector 3 formed, which in this case is designed as a simply curved parabolic reflector is. The reflector 3 consists of a frame 4 which is connected to the support structure 5 is. From the framework 4 is a series of horizontally extending Strips 6 carried, each of which - as shown in Figure 2 - from one in cross section rectangular aluminum tube.

In this way, the wind loads on the antenna are greatly reduced, due to the air gap between the individual strips, which are the reflective Form surface. The electrical design of such a reflector is general known, and its reflection performance depends on the air gap between the strips 6, the depth of the strips 6, the electrical properties of the strip material and the relative direction of the strips 6. The reflector formed by the strips 6 is fed by means of a straight line of horn antennas 7, which are mounted so that they rotate together with the reflector. For the Last 6 is usually pipe material instead of solid material in rod form used for reasons of weight saving.

A major disadvantage resulting from the use of aluminum pipes for this purpose is that the resistance to rupture of such aluminum pipes is relatively low and thus the entire reflector becomes relatively fragile, and even if a strong rear support structure is provided.

The object of the invention is to improve antennas of the type described and at least to alleviate the difficulties identified, preferably however to be completely eliminated.

According to the invention, an antenna with a relatively large reflector surface is provided made up of a large number of conductive strips with air gaps between them, these strips are made of carbon fiber reinforced plastic material.

The reflector preferably has the shape of a single curved one parabolic reflector, and the ledges are straight and extend in Axial direction.

The invention is particularly suitable for use in marine radar antennas, which are scannable and adapted to be mounted on a mast top can be.

It was found that not only the reflective properties of the Reflector of an antenna according to the invention are fully satisfactory, but that compared to an equivalent reflector of known type in which fixed or tubular aluminum strips are used, the thickness of the strips made with carbon fibers reinforced plastic material can be reduced significantly, so that a Significant reduction in the draft or the stress that occurs when there is wind load results. Compared to strips made of tubular aluminum or solid aluminum however, becomes the strength of the lasts provided by the present invention significantly improved and increased.

According to a feature of the invention, the load-bearing and shaping Frame to which the strips are attached, also made of reinforced with carbon fibers Plastic material made.

Preferably the framework consists of a plurality of shaped Back panels that extend transversely to the ledges, these molded back panels Have surfaces to which the strips are attached and these surfaces are shaped as required with regard to the desired reflector shape.

Conveniently, the molded back plates are mechanically independent connected by the strips by at least two elements that are in extend in the same direction as the strips and with each of the molded back panels are connected.

Preferably the aforementioned are at least two elements designed as tubular elements, which at least alternately by the shaped Back plates are guided.

According to a further special feature of the invention, the reflector is with its load-bearing and shaping framework on an aluminum support structure attached, which forms part of the base of the antenna, via a Material (e.g. titanium or stainless steel) that has the effects of electrolytic Reduced corrosion compared to the effects that would otherwise occur when the carbon fiber reinforced plastic material of the supporting and shaping Framework would be connected directly to the aluminum support structure.

Preferably, a number of the shaped or

curved back panels beyond the strips in the direction of the support structure, and the support structure has an equal number of rods that correspond to the curved Back panels are aligned and extend towards these panels, wherein the rods and the protruding curved back plates together by tabs are connected from the intermediate material.

Usually it is provided that the reflector by an arrangement is fed by horn antennas, which are parallel to a longitudinal edge of the reflector extend and are arranged adjacent to this longitudinal edge, in this case preferably a series of other strips of progressively decreasing length extend from this longitudinal edge extends from so that a curtain is formed, the tendency of which is - the space shield that would otherwise be between the arrangement of horn antennas and the longitudinal edge of the reflector would be present, whereby radiated interference effects are reduced.

The invention is described below with reference to FIGS. 4a and 4b of the drawing explained in more detail.

Fig. 3 shows a bar made of carbon reinforced plastic material, as used in the present invention to make tubular aluminum strips 6 to replace antennas of the type shown in FIG.

Figures 4a and 4b represent front and side views of one, respectively practically executed antenna according to the invention.

The embodiment of the reflector shown in Fig. 3 is electrical Conventional, and its reflective performance depends in the usual way from the air gap between the bars, the depth of the bars, the electrical ones Properties of the molding material and the reflecting direction of the molding. However, it was found that for the same electrical performance as them can be achieved with a reflector equipped with aluminum strips, the strips made of carbon fiber reinforced plastic material as provided according to the invention are considerably thinner than corresponding aluminum strips (tubular or solid) could be. In this case, a significantly increased strength at a low Weight, and in addition the draft is considerably reduced, and due to the reduced thickness of the strips.

Tests carried out have shown that the strips are made of carbon fiber reinforced Plastic material very resistant to climatic influences and smoke gases are commonly emitted by marine vehicles.

There are a number of carbon fiber reinforced plastic materials available available, but in the embodiment described in connection with FIG a material available from Courtaulds under the trademark "Grafil Pultrusions" is manufactured and sold.

The reflector according to FIGS. 4a and 4b again consists of strips 6 made of carbon fiber reinforced plastic material.

The reflector 3 is arranged in a straight line by means of Horn antennas fed as they are identified by the reference numeral 7 and extend along the reflector 3. The horn radiators 7 are via a common Feed waveguide 8 fed in such a way that the feed of the horn antenna 7 takes place in phase. In the right part of Fig. 4a, the strips 6, the horn radiators 7 and the common feed line 8 omitted, so that the reflector supporting and its shape-defining framework 4 can be seen.

The framework 4 consists of a number (in the present case from 14) shaped or curved back plates 9, 9 'to which the strips 6 are attached are. The shape of the back plates 9,9 'is such that the required simple parabolic curved shape for the reflector 3 is obtained.

In the longitudinal direction, two tubular ones extend through the back plates 9, 9 ' Elements 10, which are firmly united with the plates 9, 9 ', so that a rigid structure is formed.

The four curved back plates, denoted by the reference numeral 9 ' are thicker than the back plates identified by the reference numeral 9 and extend downwardly as shown to provide attachment of the reflector 3 to ensure a support structure 5.

The support structure 5 is made of aluminum, while the entire reflector 3 with the strips 7, the curved back plates 9 (including 9 ') and the tubular ones Elements 10 made of carbon fiber reinforced plastic material.

The aluminum support structure 5 has four upright Rods or beams 11 connected to the downwardly extending curved back plates 9 'aligned and of similar thickness to this. The type of connection of the curved back plates 9 with the upright rods 11 is for a rod can be seen in the detail display 12. As shown, each back plate 9 'is with their corresponding support rod 11 connected by two bracket plates 13 made of titanium or jammed. The ends of the back plates 9 'and the rods 11 do not abut each other, but are in each case separated by a pad of titanium, as shown in the The detailed representation is identified by the reference numeral 14.

The aim of fixing the reflector made of reinforced with carbon fiber Plastic material in this way is to make contact between the aluminum the support structure 5 and the carbon fiber reinforced plastic material of the reflector 3, since such contact can cause electrolytic corrosion could.

By attaching the reflector 3 by means of four upright Rods or carrier 11 provides a certain degree of lateral flexibility, one certain elastic movement of the reflector 3 in the longitudinal direction with respect to the carrier 5 allows.

The base frame 1'5 for the carrier unit 5 is true in some details shown, but is not described in detail since it is necessary to understand the Invention is not necessary.

In this particular case it is designed so that rotation of the carrier 5 carrying the reflector 3 in the horizontal plane with stabilization is guaranteed.

Looking at the right-hand part of FIG. 4a, there is a series of to see further strips 6 ', which are arranged so that they are starting from the lower longitudinal edge of the reflector formed by the bar 6 "under training an apron or a curtain and screen off the room that would otherwise between the horn radiators 7 and between the horn radiators 7 and the reflector 3 would exist. The purpose of this measure is to reduce disruptive scattered radiation. It can also be seen that the length of the strips 6 'progressively decreases, so that the width of the apron formed decreases downwards starting from the reflector.

Claims (15)

Antenna Patent Claims Antenna with a relatively large surface reflector from a multitude of conductive thin strips with air gaps between them, in that the strips (6) are made from reinforced with carbon fibers Consist of plastic material. 2. Antenna according to claim 1, characterized in that the reflector is a simply curved, parabolic reflector, and that the strips are linear and extend in an axial direction. 3. Antenna according to claim 1, characterized in that g e k e n n z e i c h n e t used as a marine radar antenna, attached to a mast head and scannable is. 4. Antenna according to one of the preceding claims, characterized in that g e -k It is noted that a support and shaping frame on which the strips are attached, also consists of plastic material reinforced with carbon fibers. 5. Antenna according to claim 4, characterized in that g e k e n n z e i c h n e t the frame consists of a plurality of shaped back panels that extend transversely to extend the ledge, these curved back plates having surfaces, to which the strips are attached, the surfaces of the panels so shaped are that the desired shape of the reflector results. 6. Antenna according to claim 5, characterized in that g e k e n n z e i c h n e t the molded back panels mechanically independent of the strips by means of at least two elements are connected, facing in the same direction as the ledges extend, these two elements being connected to each of the curved back plates are. 7. Antenna according to claim 6, characterized in that g e k e n n z e i c h n e t the at least two elements consist of tubular elements which at least pass through alternate panels of the molded back panels. 8. Antenna according to one or more of the preceding claims, in that the reflector with its supporting and shaping frame is attached to an aluminum support structure, which has a Forms part of the base of the antenna with the interposition of a material, which reduces the effects of electrolytic corrosion compared to the effects that would otherwise arise if the plastic material reinforced with carbon fibers of supporting and shaping frame directly connected to the aluminum support structure would be. 9. Antenna according to claim 8, characterized in that g e k e n n z e i c h n e t the intermediate material consists of titanium. 10. The antenna of claim 8, characterized in that it is e k e n n z e i c h -n e t that the intermediate material is stainless steel. 11. Antenna according to one of claims 8 to 10, characterized in that g e -k e n Note that a number of the molded back panels extend over the ledges also extends in the direction of the support structure, and that the support structure a has equal numbers of rods aligned with the back plates and extend to these molded back plates, with the rods and the protruding molded back panels are attached to one another by means of tabs made from the intermediate material are. 12. The antenna of claim 11, characterized in that it is e k e n n z e i c h -n e t that the adjoining ends of the molded back plates and the rods are bare are spaced. 13. Antenna according to claim 11, characterized in that g e k e n n z e i c h -n e t, that between each end of a molded backplate and the corresponding end of one Rod a pad is provided, which acts as a border to the intermediate material. 14. Antenna according to one or more of the preceding claims, in that the reflector is designed in such a way that that it is fed by an arrangement of horn antennas, which are parallel to extend a longitudinal edge of the reflector and are arranged adjacent thereto. 15. Antenna according to claim 14, characterized in that it is e k e n n z e i c h -n e t that there are a number of other ridges of progressively decreasing length from the Long edge extends away, so that a curtain is formed, the tendency of which is to to shield the space that is otherwise between the arrangement of horn antennas and the Longitudinal edge of the reflector would be present in order to prevent scattered radiation to reduce.