FR3131466A1 - Antenna membrane - Google Patents

Abstract

The invention relates to a deployable membrane for an antenna (2) capable of assuming a first folded state (32) in which the size of the membrane is reduced and a second deployed state (31) in which the membrane has an optimum geometry for the 'antenna. According to the invention, the membrane comprises at least one arm secured to the membrane, said arm comprising a shape memory material. Figure for abstract: Fig. 3

Description

Antenna membrane Technical field of the invention

The present invention generally relates to antennas, and in particular to radio frequency antennas.

Technical background

An antenna is a device used to radiate (transmitter) or capture (receiver) electromagnetic waves. The antenna is a key element in a radio system. It is characterized in particular by its efficiency, gain, and radiation diagram. These parameters directly influence the quality and range performance of the system.

In microwaves, we are particularly familiar with reflector antennas. These antennas can notably use planar or parabolic reflectors.

The parabolic antenna is best known for its use in satellite television or for space applications.

The parabolic antenna conventionally comprises a parabolic reflector which is responsible for concentrating the waves received or emitted towards a source of the antenna. Conventionally the source is placed at the focus of the parabola.

The source can be a transmitter in the case of an antenna used for transmission or a receiver in the case of an antenna used for reception.

There are also planar antennas comprising a radiating element in the form of a flat sheet which can take the shape of a rectangle, a square or a strip.

In the space domain, the weight and size of the antenna are essential, particularly during the launch of a satellite, a space vehicle or any other object. Thus, deployable antennas have been developed. Some use rigid folding petals that can be deployed to form a dish or planar antenna. However, this type of antenna has the disadvantages of being heavy and complex to manufacture and implement (which leads to increased risks of failure). Other deployable antenna technologies use a foldable metal array or metallized plastic film.

The disadvantages of these technologies remain the weight and the risk of failure due to the complexity of their mode of operation.

Based on this problem, the present invention therefore has the task of developing a new technology making it possible to produce antennas which are lighter. Another objective of the present invention is to obtain antennas which are less bulky. Another objective of the present invention is to obtain antennas which are less expensive and simpler to implement. Another objective of the present invention is to produce antennas which are more reliable.

The invention relates in particular to an elastic membrane for an antenna, the membrane comprising it comprises an entanglement of one or more non-woven conductive wire(s) secured in a matrix of an elastic material . In the context of the present invention, by entanglement is meant any grouping or grouping or entanglement or interlacing of at least one thread(s).

In the context of the present invention, by wire is meant an element having a shape extending longitudinally. For example, a ribbon (or a long rectangle) must also be considered as a thread within the meaning of the present invention. A wire can have any diameter, even large ones, such as a rope or a cylinder.

Advantageously, at least one of the conductive wire(s) of the entanglement is a wire comprising a first strand made of an electrically conductive material and a second strand made of a deformable thermoformable material, said first and second strands being intertwined. Of course, the thermoformable material can be rigid or even elastic.

Advantageously, the thermoformable material is a silicone.

Advantageously, the matrix is obtained from the thermoformable material of the second strand.

Advantageously, the interweaving of the first and second strands is obtained by wrapping. Of course, the interlacing can be obtained by any other technique for binding strands or threads such as for example weaving, knitting or by at least partial melting or fusion of at least one of the strands. According to an embodiment of the present invention, the membrane is a deployable membrane for an antenna which can take a first folded state (or folded or compressed or crumpled or with reduced bulk) in which the bulk of the membrane is reduced and a second deployed state (or unfolded or decompressed or smoothed or with larger dimensions) in which the membrane has an optimal geometry for the antenna.

According to the invention, the membrane may comprise at least one arm secured to the membrane, said arm comprising a shape memory material.

According to one embodiment of the invention, at least one of the arm(s) comprises a wire comprising a first strand made of a shape memory material and a second strand made of an electrically conductive material, said second strand being wound around the first strand .

According to at least one embodiment of the invention, at least one of the arm(s) comprises a wire made of an alloy of a shape memory material and an electrically conductive material.

The invention also relates to a reflector antenna whose reflector comprises a membrane as previously described.

The invention also relates to a planar antenna comprising a radiating panel which itself comprises a membrane as previously described.

The invention also relates to a deployable membrane for an antenna which can take a first folded state (or folded or compressed or crumpled or with reduced bulk) in which the bulk of the membrane is reduced and a second deployed state (or still unfolded or even decompressed or even smoothed or even with larger dimensions) in which the membrane has an optimal geometry for the antenna.

According to the invention, the membrane may comprise at least one arm secured to the membrane, said arm comprising a shape memory material. In the context of the present invention, the term “connected” means a direct or indirect connection (for example connected via another element). In the context of the present invention, shape memory material means any material which, once deformed, is capable of at least partially returning to a shape, size, geometry or configuration under certain conditions. A material with shape reversibility or material with a reversible state is also to be considered as a shape memory material according to the invention.

Thus, according to one embodiment of the invention, the deployment of the membrane can be activated by an internal action or an external action, for example thermal heating.

Advantageously, at least one of the arm(s) comprises a wire comprising a first strand made of a shape memory material and a second strand made of an electrically conductive material, said second strand being wound around the first strand.

According to one embodiment of the invention, at least one arm comprises an assembly of at least two constituents: a constituent based on a material with a reversible state of shape and another constituent based on another material which is electrical conductor. For example, if the arm is a wire, it could be the assembly of wires performing these functions.

Advantageously, at least one of the arm(s) comprises a wire made of an alloy of a shape memory material and an electrically conductive material. According to one embodiment of the invention, the electrically conductive material is such that, through its physicochemical properties, it allows thermal heating.

Advantageously, the deployable membrane has the shape of a parabola in the deployed state and in that it comprises several arms secured to the internal surface of the parabola and extending from the center of the parabola towards the periphery of the parabola when in the state. deployed.

Advantageously, the deployable membrane has the shape of a strip in the deployed state and in that it comprises at least one arm secured parallel to the strip when in the deployed state.

Advantageously, the membrane is an elastic membrane.

According to one embodiment of the invention, the membrane comprises an entanglement of one or more non-woven conductive thread(s) secured in a matrix of an elastic material.

Advantageously, at least one of the conductive wire(s) of the entanglement is a wire comprising a first strand made of an electrically conductive material and a second strand made of a deformable thermoformable material, said first and second strands being intertwined. Of course, the thermoformable material can be rigid or even elastic.

Advantageously, the thermoformable material is a silicone.

Advantageously, the matrix is obtained from the thermoformable material of the second strand.

Advantageously, the interweaving of the first and second strands is obtained by wrapping. Of course, interlacing can be obtained by any other technique for binding strands or threads such as for example weaving, knitting or by at least partial melting or fusion of at least one of the strands.

The invention also relates to a reflector antenna comprising a reflector comprising a membrane as previously described.

The invention also relates to a planar antenna comprising a radiating panel comprising a membrane as previously described.

The invention further relates to a method for manufacturing a reflector for an antenna, in particular a reflector for a membrane antenna according to the invention as previously described. The invention also relates to a method for manufacturing an antenna comprising such a reflector.

The invention further relates to a method for manufacturing a radiating panel for a planar antenna, and in particular a radiating panel comprising a membrane according to the invention as previously described.

Brief description of the figures

Other characteristics and advantages of the invention will appear during reading of the detailed description which follows, for the understanding of which we will refer to the appended drawings in which:

shows schematically and in an isometric view, an exemplary embodiment of a membrane according to the invention;

schematically shows a reflector antenna according to an exemplary embodiment of the invention;

schematically shows a deployable reflector antenna according to an exemplary embodiment of the invention.

Detailed description of the invention

Different aspects of different embodiments of antenna reflector according to the invention are described in more detail below, with reference to the accompanying drawings.

On a functional level, the main characteristics of an antenna include: the frequency range covered, the radiation characteristics including the radiation pattern, the gain, the directivity, and the efficiency (which is linked to intrinsic losses) and the impedance matching. The latter is often obtained by comparing the energy transmitted to the antenna and the energy reflected on the injection by the antenna.

It should be noted that it is difficult to obtain antennas with both good performance and small dimensions. Indeed, the wavelengths of the frequency range covered by the antenna generate antenna sizing constraints. On the other hand, the antenna gain is generally also related to the dimensions of the antenna (e.g. for a reflector involving the square of the surface).

It is also notable that the condition of the reflector surface also influences the performance of the antenna. Indeed, typically, irregularities or imperfections whose dimensions are greater than a tenth or a twentieth of the operating wavelength of the antenna affect the performance of the antenna.

Other characteristics are important when using an antenna. For example, the mass and dimensions of the antenna impact its portability or pointing methods.

Its mechanical characteristics and in particular its deformation under the effect of wind or any other constraint generally result from a performance/mass compromise.

Another important characteristic of the antenna and particularly in a space context is its ability to be confined in order to reduce its bulk (notably during the launch of a satellite) when it is not in operation and therefore also to be able to be deployed upon activation (for example in space).

In the context of the application in a spatial context, among the important characteristics, we find the mass, the possibility of confining the antenna and deploying it as well as its dimensions/size.

A membrane conforming to the present invention can be applied in any type of reflector antenna, whether for a terrestrial application or a space application. It can be applied to a parabolic, convex or planar antenna. It can take any shape and any size.

The membrane of the present invention can also be applied in any type of planar antenna, whether for a terrestrial application or a space application. It can be applied to a planar antenna whose radiating panel has any shape (rectangle, strip, square, polygon, disk, etc.). It can be planar or three-dimensional, for example convex or concave. It can take any shape and any size.

A membrane conforming to the present invention can also be applied in any other type of antenna.

We present in relation to the an elastic membrane 1 for an antenna according to a first embodiment of the invention.

In the context of the present invention, the term elastic membrane or elastic material means a membrane or material which has a hardness less than 95 Shores A measured according to the ASTM D2240-15 standard. In the remainder of the description, when we mention a hardness value in Shores A, we mean a hardness value in Shores A measured according to the ASTM D2240-15 standard. According to one embodiment, a material is said to be elastic if it has a hardness less than or equal to 75 Shores A.

Thus, an elastic membrane according to the invention can be any elastic or plastic membrane, for example having a variable geometry structure which retains its shape integrity even when deformed by mechanical action, crumpled or folded and reversibly allowing the return to a predefined shape. established by the unfolding device.

Thus, an elastic membrane according to the present invention can for example be a deformable membrane, capable of going from a state with reduced surface area to a state with extended surface area, while maintaining an isomorphism between the two structures. Such a membrane can be obtained by all wire bonding techniques and even by fused lane techniques.

In the case of a transition from a wrinkled shape to a smoothed shape, this deployed structure can retain its shape integrity even when deformed by mechanical action. This structure can reversibly allow the return to a crumpled shape by the unfolding device.

According to the present embodiment of the invention, the membrane 1 comprises an entanglement of one or more non-woven conductive wire(s) secured in a matrix of a flexible material.

Of course, the tangle of wire(s) can be made from a single wire or portion of wire or from several wires or portions of wire.

Thus, the present invention can implement technical threads. For example wires with high electrical conductivity. For example, electrical conductivity can be modulated by varying the mixtures of constituents. It can, for example, be combined with structural forming materials (carbon structures, thermoformable materials, etc.) and materials for electrical conduction (for example based on metals such as copper, silver, stainless steel, etc.). aluminum or any other metal or alloy or any conductive structure).

Thus, for example and as illustrated by the , to obtain the membrane 1, an entanglement 11 is produced, of which at least one of the conductive wire(s) of the entanglement is a wire 111 comprising a first strand made of an electrically conductive material and a second strand made of a deformable thermoformable material. For example, the first and second strands are intertwined. Of course, some of the yarns according to the invention can comprise any number of strands (for example, a third textile strand can be added to the first and second strands in the interweaving). Some other threads may consist of only one strand. According to alternatives of the present embodiment of the invention, some or all of the first and second strands may not be intertwined but only linked or associated or even arranged close to each other. According to other alternatives of the present embodiment of the invention, some or all of the wires comprise a first strand (core) around which the second strand forms a sheath. In the context of this embodiment, each of the wires used to make the membrane comprises a first copper strand and a second silicone strand.

Of course, in accordance with the invention, any heat-melting material or any mixture of heat-melting materials integrating a metallic electrically conductive substrate or any other electrical conductor such as, for example, carbon can also be used.

Of course, any elastic material compatible with thermoforming could be used in the context of the present invention such as polymers (for example polypropylene or "PP" ), filled polymers, doped polymers, copolymers whose hardness or The elasticity can be modulated, resins, ethylene vinyl acetate (EVA), polystyrene (PS), polyethylene (PE), polypropylene (PP), polycarbonate (PC), acrylonitrile butadiene styrene (ABS), polyvinyl chloride (PVC), polymethyl methacrylate (PMMA), high impact polystyrene (SB), ...

Polymers or resins can be loaded with EVA to modulate the elasticity of the wire or strand.

The interweaving of the first and second strands to form a thread can, for example, result from a wrapping technique. The Filix company, for example, offers such threads. It can result from any other technique. Alternatively, the strands can for example be intertwined (manually or by machine) so as to form one or more braids.

Thus, the present invention, according to certain variants, makes it possible to benefit from the great flexibility linked to the characteristics of the textile threads (when such threads or strands are used). According to certain embodiments of the invention, more or less stiffened and more or less flexible or more or less stretchable (stretch) wires can be used.

According to one embodiment of the invention, the entanglement of the wire(s) can be obtained manually, for example a user can distribute the wire(s) on a surface or in a mold 122 so, for example that the entanglement obtained presents a certain homogeneity. Alternatively, entanglement can be achieved using a machine. Of course, the entanglement of the wire(s) can be obtained by any material assembly technique (such as polymers, metals, etc.), whether by molten methods or traditional techniques (for example , fibril binding, or more complex techniques of assembled wires such as wrapping, are some examples.

According to variants of the present invention, some of the thread(s) may be woven or knitted or non-woven over a portion or the entire surface of the membrane.

According to one embodiment of the invention, the matrix of an elastic material is for example obtained by pouring or even fusing an elastic material (for example silicone made liquid or at least malleable) on or within the entanglement . According to another embodiment, the elastic material matrix can be obtained by applying heat (for example by thermoforming) to the tangle of wire(s) 11 previously placed in a mold 122 so that the thermoformable material of the wire(s) second strand(s) of the wire(s) take the shape of the mold which is that of the membrane 1 that we wish to obtain. Optionally, mechanical pressure and/or pressure can be added to the entanglement of the wire(s) during thermoforming. Thus, the tangle of non-woven conductive threads is finally united in a matrix of an elastic material.

The membrane may have a two-dimensional shape such as a disc or a three-dimensional shape such as a parabola or any other two- or three-dimensional shape as previously indicated.

Thus, in accordance with the present invention, the membrane can be shaped for example by thermoforming and an application of mechanical pressure such as entangling. Thus, in accordance with the present invention, the membrane can have a three-dimensional shape or structure after thermoforming.

The structure of the surface of the membrane can be either solid or meshed in the sense of the antennas, that is to say perforated while respecting the constraints linked to the working wavelength.

Such a membrane can for example be used as a reflector in a reflector antenna. For example, such a membrane can be used in a parabolic antenna. Such a membrane can for example be used as a radiating panel in a pan antenna, for example a radiating strip.

We present in relation to the , a reflector antenna 2 according to an exemplary embodiment of the invention.

For example, antenna 2 is a parabolic antenna comprising a source 21 placed at the focus of antenna 2.

For example, the reflector is the membrane 1 previously described which has a conductive and radiating or wave-reflecting surface due to the entanglement of conductive wire(s).

Thus, it is possible to obtain, thanks to the invention, improved electrical and mechanical properties of the reflector (for example the membrane) thanks to the pooling of materials.

Thus, the radiating or reflective conductive surface can be an assembly or entanglement of at least one thermoformed conductive wire(s) (for example conductive associated with thermoformable). In accordance with the invention, the structure of the membrane can optionally be reinforced by the addition of at least one complementary reinforcing element(s), for example at least one strand or wire, for example in thermoformable carbon. inserted into the entanglement.

It is also possible to optionally provide the membrane locally or over its entire surface with one or more additional heating elements, for example at least one strand or wire, for example made of an electrically conductive material inserted in the entanglement which makes it possible to provide locally or over the entire surface or volume of the membrane a thermal rise by the effect of Ohm's law or Joule effect.

The surface quality of the antenna as well as the precision in its structure can be mechanically managed to obtain, for example, very good surface regularity by using a mold and by exerting hot pressure on the wire structure (or entanglement) which will conform to the shape it is pressed into.

The present invention relates, in at least one of its embodiments, to a deployable membrane for an antenna which can take a first folded state (or even folded or even crumpled) in which the bulk of the membrane is reduced and a second deployed state ( or even unfolded or even smoothed) in which the membrane has an optimal geometry for the antenna. According to one embodiment of the invention, the membrane comprises at least one arm secured to the membrane, said arm comprising a shape memory material. The membrane may comprise a single arm or several arms.

The deployable membrane can be an elastic membrane of the type previously described or even any other type of membrane, for example a metal sheet or a metallized sheet. The deployable membrane can also be made from super elastic metal.

A deployable membrane in accordance with the present invention can be applied in any type of reflector antenna, whether for a terrestrial application or a space application. It can be applied to a parabolic, convex or planar antenna. It can take any shape and any size.

The deployable membrane of the present invention can also be applied in any type of planar antenna, whether for a terrestrial application or a space application. It can be applied to a planar antenna whose radiating panel has any shape (rectangle, strip, square, polygon, disk, etc.). It can be planar or three-dimensional, for example convex or concave. It can take any shape and any size.

A deployable membrane in accordance with the present invention can also be applied in any other type of antenna.

According to one embodiment, at least one of the arm(s) comprises a wire comprising a first strand made of a shape memory material and a second strand made of an electrically conductive material, said second strand being wound around the first strand.

According to another embodiment of the invention, each of the arm(s) comprises a wire made of an alloy of a shape memory material (for example enabling the deployment of the antenna) and an electrically conductive material .

For example, a shape memory material according to the invention is a shape memory material controllable by thermal effect, for example Nitinol (which is an alloy based on nickel and titanium).

According to a first embodiment of the invention, the membrane has the shape of a parabola in the deployed state and in that it comprises several arms secured to the internal surface of the parabola and extending from the center of the parabola towards the periphery. of the dish when in the deployed state. The invention according to this first embodiment also relates to a reflector antenna comprising a reflector comprising the membrane.

Thus, the dish membrane can be folded mechanically by a user or by a machine so that it takes the folded state. Once in the folded state of the membrane, the application of electrical energy to the arm(s) of the membrane goes through the Ohm effect into the electrical conductor (for example into the electrically conducting strand of the arm or into the conductive material electric of the alloy of each arm) of each arm, generate heat which will be applied to the shape memory material (activatable by heat) of each arm. Thus, each arm will return to its equilibrium shape by passing the membrane into its deployed state (corresponding to the parabola). This will therefore allow the deployment of the membrane.

According to a second embodiment of the invention, the membrane has the shape of a strip in the deployed state and in that it comprises at least one arm secured parallel to the strip when in the deployed state. The invention according to this first embodiment also relates to a planar antenna comprising a radiating panel comprising the membrane.

Thus, the membrane of the headband can be folded mechanically by a user or by a machine so that it takes the folded state. Once in the folded state of the membrane, the application of electrical energy to the arm(s) of the membrane goes through the Ohm effect into the electrical conductor (for example into the electrically conducting strand of the arm or into the conductive material electric of the alloy of each arm) of each arm, generate heat which will be applied to the shape memory material (activatable by heat) of each arm. Thus, each arm will return to its equilibrium shape by passing the membrane into its deployed state (corresponding to the headband). This will therefore allow the deployment of the membrane.

We present in relation to the , a deployable reflector antenna according to an exemplary embodiment of the invention. For example, the antenna is the antenna 2 previously described and the reflector comprises a membrane as previously described.

The wires or other constituents of the reinforcement structure can then be associated (for example by producing a covering with a thermoformable multi-strand carbon wire) with a shape memory alloy wire, thus making it possible to produce a wire structure of variable conductivity and therefore associating electrical conduction.

The present invention allows the pooling of wires or strands having various functionalities such as shape memory using for example wires of shape memory alloys which can be controlled for example by thermal effect.

Thus, in certain membranes according to the invention, the Ohm's law characteristics make it possible to control the deployment of the antenna membrane electrically. Indeed, the control of the electrical energy 311 provided to the electrically conductive strand or to the electrically conductive material of the alloy of the arm(s) (comprising a shape memory material) makes it possible to locally create a thermal release by ohm law and thus activate the deployment of the arm(s) (and therefore of the membrane and therefore of the antenna) from a folded state 32 to a deployed state 31.

It can be chosen in the context of the present invention, an electrical conductivity that can be adjusted by an action on the mixtures of constituents and a mix of structural forming materials (carbon structures, thermoformable materials) and conduction materials (for example based on metal such as one of copper, silver, stainless steel, aluminum or other). Indeed, in certain cases it may be advantageous to reduce the conductivity to increase the joule effect through greater heat dissipation.

In the case of a reflector or radiating surface type antenna structure, the unfolding (or folding) sub-functionality can be ensured thanks in particular to the following effects:

i) the natural tendency to return to the shape initiated during thermoforming and creation by the flexibility and constitution of the structure (for example with carbon reinforcements on a proofreader offering stability to the mechanical structure);

ii) the distribution of the wire structure described above which exerts, during the rise in temperature by Joule effect and Ohm's law, a controlled and pre-calculated mechanical action to achieve by action of the shape memory the targeted configuration (unfolded reflector , folded, radiant band rolled up, unrolled or other).

The present invention thus allows, in at least one of its embodiments, the use of an entanglement of non-woven materials or threads assembled by thermoforming and mechanical pressure, with a combination of electrical conduction and physicochemical properties combining several materials or wires forming a membrane with conductive or radiating surface to produce strip-type antennas or deformable antenna systems with focusing by reflector and source produced with this same approach.

The present invention thus allows, in at least one of its embodiments, the production of antennas of the unfoldable or foldable reflector type using in its structure pooling of wires with shape memory and conductive wires, for example with heat dissipation, thus achieving a wire to allow, under the action of electrical power, a modification from the folded to unfolded configuration or vice versa.

The present invention thus allows, in at least one of its embodiments, the production of unfoldable or foldable radiating strip type antennas using in its structure pooling of shape memory wires and conductive wires, for example, with heat dissipation thus producing a wire to allow, under the action of electrical power, a modification from the folded to unfolded configuration or vice versa.

The present invention thus allows, in at least one of its embodiments, the use of a shape memory material in a deployable antenna reflector to activate the deployment or folding of the reflector.

The present invention thus allows, in at least one of its embodiments, the use of a shape memory material in a deployable radiating strip type antenna to activate the deployment or folding of the strip.

The invention also relates to a reflector antenna whose reflector comprises a membrane as previously described.

The invention also relates to a planar antenna comprising a radiating panel which itself comprises a membrane as previously described.

The invention further relates to a method for manufacturing a reflector for an antenna, in particular a reflector for a membrane antenna according to the invention as previously described. The invention also relates to a method for manufacturing an antenna comprising such a reflector.

The invention further relates to a method for manufacturing a radiating panel for a planar antenna, and in particular a radiating panel comprising a membrane according to the invention as previously described.

List of reference signs

1 membrane

11 Tangle of Wires

111 thread

122 mold

2 antenna

21 sources

31 deployed state

32 folded state

311 electrical energy

Claims (10)

Deployable membrane (1) for an antenna (2) capable of taking a first folded state (32) in which the bulk of the membrane is reduced and a second deployed state (31), characterized in that it comprises at least one arm secured to the membrane, said arm comprising a shape memory material. Deployable membrane (1) according to claim 1, characterized in that at least one of the arm(s) comprises a wire comprising a first strand made of a shape memory material and a second strand made of an electrically conductive material, said second strand being wrapped around the first strand. Deployable membrane (1) according to any one of claims 1 and 2, characterized in that at least one of the arm(s) comprises a wire made of an alloy of a shape memory material and an electrically conductive material . Deployable membrane (1) according to any one of claims 1 to 3, characterized in that the membrane has the shape of a parabola in the deployed state and in that it comprises several arms secured to the internal surface of the parabola and is extending from the center of the dish towards the periphery of the dish when in the deployed state. Deployable membrane (1) according to any one of claims 1 to 3, characterized in that the membrane has the shape of a strip in the deployed state and in that it comprises at least one arm secured parallel to the strip when in the deployed state. Membrane (1) according to any one of the preceding claims, characterized in that it comprises an entanglement (11) of one or more non-woven conductive thread(s) secured in a matrix of an elastic material. Membrane (1) according to claim 6, characterized in that at least one of the conductive wire(s) of the entanglement is a wire (111) comprising a first strand made of an electrically conductive material and a second strand made of a deformable thermoformable material , said first and second strands being intertwined. Elastic membrane (1) according to any one of claims 6 and 7, characterized in that the matrix is obtained from the thermoformable material of the second strand. Reflector antenna (2) characterized in that it comprises a reflector comprising a membrane (1) according to any one of claims 1 to 4 and 6 to 8. Planar antenna characterized in that it comprises a radiating panel comprising a membrane according to any one of claims 1 to 3 and 5 to 8.