DE3632128A1 - Dielectric protective cap for covering microwave antennas - Google Patents

Abstract

Either a fixed foam panel (4) or a plastic mat supporting a honeycomb structure, having a very low relative dielectric constant, is inserted in the region of relatively high radiation density as an intermediate layer (3) between two very thin outer layers (1, 2) of the cap (8), which outer layers are formed from thermoplastic synthetic material, and is bonded in with the aid of a flexible adhesive, while in contrast, the other regions of the cap (8), the space between the outer layers (1, 2) is filled with plastic resin foam material (5) which cures after foaming in. The protective cap according to the invention is particularly suitable for use as a radome for the aperture cover of high-power aerials. <IMAGE>

Description

The invention relates to a self-supporting, low reflection dielectric protective cover (radome) in Sandwich construction to cover microwave antennas, consisting of two thin outer layers made of plastic material and one between the two outer layers lying thicker intermediate layer made of softer dielectric material, e.g. B. hard plastic foam or Honeycomb structure material, with a very low relative Dielectric constant.

It is known that microwave antennas against mechanical and climatic environmental influences must be protected. A dielectric protective cover is usually used for this, a so-called radome is used. The structure of a Such protective hood must be designed so that the High frequency radiation reduces the radome as much as possible and can penetrate without reflection, so that the electrical Properties of the antenna remain as unaffected as possible. From DE-PS 12 73 023 protective covers made of glass fiber reinforced polyester and epoxy resins known due to their high strength properties themselves can be carried load-bearing, but a high Di have electricity constant so that the electrical Characteristics of the antenna through such hoods strong deteriorate. From the same patent known a one-piece radar hood made of polyurethane foam,  which is made in such a way that the polyurethane on an inflated, the dimensions of the radar hood speaking balloon envelope is sprayed on. After opening foam and harden the polyurethane will the balloon cover removed again. The dimensions of such radar hoods are relatively small. They also have hoods the shape of a hemisphere, so that an adaptation to the Construction conditions are not possible. A ver Mechanical strength can be improved if a polyurethane integral rigid foam structure is used, the surfaces of which are compacted. Everything However, there are certain difficulties with this application with powerful microwave emitters that use their high radiation density in the radome structure can generate partial warming that leads to the material destruction leads.

From DE-PS 28 30 516 a cover is known whose surface elements are made of spherically curved ones load-bearing sandwich parts with a core made of rigid foam and cover layers made of glass fiber reinforced plastic consist. Even with such a structure, there is a risk the material destruction when used in connection with powerful spotlights.

DE-AS 24 41 540 describes a self-supporting low reflection dielectric cover for microwaves antennas known in sandwich construction, in which two thin solid layers with high dielectric constant a thick layer of soft material, e.g. B. made of rigid foam material or honeycomb structure. Also this creates difficulties in use such a cover with powerful emitters, the one with its high radiation density in the radome structure  can generate partial warming.

The object of the invention is to cover one Dielectric protective hood in Form sandwich construction so that its electrical Properties remain largely unaffected, when used on high-performance spotlights, those with their high radiation density in the radome structure can generate partial warming.

According to the invention, which relates to a protective hood of the type mentioned, this object is achieved in that the intermediate layer lying between the outer layers made of thermoplastic synthetic material in an area in which there is a higher radiation density, either from a solid plastic foam plate or consists of a honeycomb plastic mat, which is glued between the two outer layers with the aid of a flexible adhesive and whose relative dielectric constant ε _{r is} close to ε _r = 1 of air, and that the remaining areas of the intermediate layer consist of plastic rigid foam material, which after foaming in the cavity between the outer layers is cured.

A major advantage of the invention formed protective cover is that by Insert foam sheets or plastic mats with honeycomb structure in the area of the higher beam dense irregularities and material consumption seals that could arise during the foaming process, be avoided with certainty.

Advantageously, polycarbonate (PC) thin-plate material is provided as the thermoplastic material for the two outer layers, which preferably have a wall thickness less than 1 mm. This material is in the "Kunststoff-Lexikon", C. Hanser Verlag, 1973, page 292.

The foamed-in foam sheet is a material which has a relative dielectric constant ε _r close to ε _r of air, preferably foamed acrylic resin in the form of polymethacrylimide (PMI) rigid foam (trade name "Rohacell"), described in the "plastic lexicon" on page 302. The foamed material also has good dielectric properties and is, for. B. polyurethane foam.

To seal the plastic hood watertight and on training screwable is a convenient prefabricated frame, e.g. B. made of plastic material with provided a circumferential groove in which the Protective hood with its edge glued in to make it waterproof is. The frame itself then has holes for receiving Screws for screwing the hood to the micro wave antenna on. The protective hood is more appropriate wise on its outer surface with a thin protective instruction dash, e.g. B. a camouflage paint for military installations or a paint to prevent ozone damage by sun exposure.

An advantageous method of making a protection Hood according to the invention is characterized in that according to the intended operating frequency the total layer thickness of the hood has been determined the two outer layers made of thermoplastic be produced in the hot forming process so that results in an inner and an outer shell. Here you can special shapes, such as B. calottes, taken into account  will. PC thin plate material can preferably be used be applied. After the inner and outer shells before are made in the cavity between these two shells, and only in the area of the high beam density, the solid foam sheet or the honeycomb structured plastic mat inserted and with Glued in with the help of a flexible adhesive. Subsequently will be after attaching supports and spacers directions on the shells the remaining cavity between the two shells with the plastic foam material, e.g. B. by pressing in with the help of a foaming machine, filled out. This means that even complicated radome shapes, e.g. B. with beads, can be realized. After that the finished hood with its edge in the groove of a pre finished frame glued in a waterproof manner. In the end the hood outer surface can optionally be included Apply a thin coat of outer paint to the frame.

An embodiment of a protective hood according to the Er In the following he will find the invention using two figures purifies. Show it

Fig. 1 is a partially cut side view of this protective hood, and

Fig. 2 is a plan view of this protective cover, just in case partially cut open.

In Figs. 1 and 2, a self-supporting, reflexions poor protective cover (Radom) 8 in a sandwich construction is shown to cover the aperture of a microwave antenna not shown specifically. The hood 8 consists of two thin outer layers 1 and 2 made of plastic material and a lying between the two outer layers 1 and 2 thicker intermediate layer 3 made of softer plastic material. The total wall thickness of the hood is determined in dependence on the frequency and is z. B. in the X-band approx. 9 mm. The material of the two outer layers 1 and 2 is an electrically and mechanically high-quality thermoplastic, e.g. B. PC plastic, the wall thickness is less than 1 mm and that is made in the hot forming process. In the prefabricated state, the two outer layers 1 and 2 are then fixed inner and outer layers. The intermediate layer 3 consists in an area in which there is a higher radiation density, either from a solid plastic foam plate 4 or from a honeycomb structure-containing plastic mat 4 ', which is glued in each case with the aid of a flexible adhesive between the two outer layers 1 and 2 . The remaining areas of the intermediate layer 3 consist of plastic hard foam material 5 , which is cured after foaming into the cavity between the two solid outer layers 1 and 2 . The foamed plastic hard foam material 5 is such a material that has a favorable relative dielectric constant, for. B. polyurethane foam. The inserted plastic foam sheet 4 is made of a material with a relative dielectric constant ε _r at ε _r = 1 of air, e.g. B. foamed acrylic resin.

The protective hood 8 is glued watertight with its edge 9 into a groove 7 which is provided all around in a prefabricated frame 6 . This frame 6 has holes 10 for receiving screws with which the hood 8 together with the frame 6 can be attached to the microwave antennas. The hood outer surface is thinly provided with a coat of paint 11 , which can be a camouflage paint for military installations or a coat of paint to prevent ozone damage from sun exposure. Beads or Kalottenverformungen, behind which there may be additional emitters, are designated by 12 .

Characterized in that in the area of higher radiation density in the cavity between the outer layers 1 and 2, a foam sheet 4 or a plastic mat 4 'with honeycomb structure is inserted and glued in with the aid of a flexible adhesive, irregularities and material densifications that would otherwise occur when foaming in this area avoided.

Claims (12)

1. Self-supporting, low-reflection dielectric protective hood (radome) in sandwich construction for covering microwave antennas, consisting of two thin outer layers made of plastic material and a thicker intermediate layer between the two outer layers made of softer dielectric material, e.g. As plastic foam or honeycomb material, consistent with a very low relative dielectric, characterized in that in the in the range, there is a higher radiation density between the group consisting of thermoplastic plastic material outer layers (1, 2) intermediate layer lying (3), either consists of a solid plastic foam plate ( 4 ) or a honeycomb-containing plastic mat ( 4 '), which is glued between the two outer layers with the aid of a flexible adhesive and whose relative dielectric constant ε _{r is} close to ε _r = 1 of air, and that the remaining areas of the intermediate layer consist of plastic rigid foam material ( 5 ), which is cured after foaming into the cavity between the outer layers. 2. Protective hood according to claim 1, characterized in that the wall thickness of the two outer layers ( 1 , 2 ) is in each case less than 1 mm. 3. Protective hood according to claim 1 or 2, characterized in that polycarbonate (PC) -dämmplattenma material is provided as the thermoplastic material for the two outer layers ( 1 , 2 ). 4. Protective hood according to one of the preceding claims, characterized in that the foamed plastic hard foam material ( 5 ) is a material which has a low relative dielectric constant, for. B. polyurethane foam. 5. Protective hood according to claim 5, characterized in that the material of the plastic foam sheet ( 4 ) is foamed acrylic resin (trade name "Rohacell" = PMI (polymethacrylimide) rigid foam). 6. Protective hood according to one of the preceding claims, characterized in that a frame ( 6 ) with a circumferential groove ( 7 ) is provided in which the protective hood ( 8 ) with its edge ( 9 ) is glued in a watertight manner. 7. Protective hood according to claim 6, characterized in that the frame ( 6 ) has holes ( 10 ) for screwing to the micro wave antenna. 8. Protective hood according to one of the preceding claims, characterized in that its outer surface is provided with a thin protective coating ( 11 ). 9. Protective hood according to one of the preceding claims, characterized by beads or dome deformations ( 12 ), behind which additional radiators can be arranged. 10. A method for producing a protective hood according to one of the preceding claims, characterized in that after depending on the intended operating frequency he followed definition of the total layer thickness of the hood ( 8 ), the two outer layers ( 1 , 2 ) made of the thermoplastic material in the hot forming process are, so that there is an inner and an outer shell that after this prefabrication of the thermoplastic inner and outer shell in the cavity between the two shells, and only in the area of high radiation density, the solid foam sheet ( 4 ) and the Honeycomb-containing plastic mat ( 4 ') is glued in with the aid of a flexible adhesive, and that after the attachment of support and spacing devices, the remaining cavity between the inner and outer shell with the plastic foam material ( 5 ) z. B. is filled in by pressing with the help of a foaming machine. 11. The method according to claim 11, characterized in that the finished hood ( 8 ) with its edge ( 9 ) in the groove ( 7 ) of a prefabricated frame ( 6 ) is glued in a water-tight manner. 12. The method according to claim 11 or 12, characterized in that the hood outer surface optionally including the frame ( 6 ) is thinly provided with an outer coating ( 11 ).