EP1458052A1 - Unfoldable electromagnetic reflector - Google Patents

Abstract

A device forming an electro-magnetic reflector, comprising an unfoldable support frame carrying at least one fabric element which unfolds to form a reflector surface, has an unfoldable support frame that includes at least one unfoldable, telescopic arm (120).

Description

The present invention relates to the field of reflectors electromagnetic.

It concerns all potential applications of reflectors electromagnetic, such as, and not limited to, use in the form of locating beacons, for example for mobile vehicles.

Numerous means have already been proposed forming a reflector electromagnetic.

Reference may be made, for example, to documents FR-A-2 723 263, EP 0 182 274, FR 1 226 263, GB 913 547, US 3 217 325, US 3 041 604, US 3,115,631, US 3,568,191, GB 2,188,783, GB 2,189,079, FR 2,073,370, US 4,119,965, US 4,096,479, US 4,072,948, US 3,660,843, US 3,276,017.

For example, in document FR-A-2 723 263, devices comprising a deployable support frame which carries a plurality of fabric segments designed to form in combination, in the state deployed, reflective polyhedra.

The present invention now aims to provide new means with greater efficiency than the prior art.

This object is achieved in the context of the present invention, thanks to a reflector electromagnetic comprising a support armature which carries a plurality elements of canvas designed to form, in combination, polyhedra reflectors, characterized in that it further comprises means for aerodynamic behavior control capable of imposing an orientation of the support frame such as this has at least one external edge horizontal.

The Applicant has determined that this characteristic is important to get a high level average response.

According to another advantageous characteristic of the present invention, the horizontal external edge is a lower edge of the reinforcement support.

According to an advantageous characteristic of the present invention, such orientation and rotation control means comprise at least a lift sail.

• la figure 1 représente une vue générale schématique en perspective d'un dispositif conforme à la présente invention,
• la figure 2 représente une vue partielle d'une armature support conforme à la présente invention, en partie déployée,
• la figure 3 représente la même armature support conforme à la présente invention, en position repliée,
• les figures 4, 5 et 6 représentent schématiquement le dispositif conforme à la présente invention à trois étapes successives de sa phase de déploiement,
• la figure 7 représente une courbe illustrant la montée en pression des gaz d'un générateur pyrotechnique assurant le déploiement, en fonction du temps,
• la figure 8 représente schématiquement un agencement préférentiel de moyens pyrotechniques propres à générer des gaz de déploiement, conformes à l'invention,
• les figures 9, 10, 11 et 12 représentent des moyens de verrouillage d'un mât télescopique conforme à la présente invention lors de quatre étapes successives du déploiement,
• la figure 13 représente une vue partielle d'un élément de toile conforme à l'invention au niveau de l'un de ses angles radialement externes coopérant avec un bras et une élingue,
• la figure 14 représente une vue de détail d'une toile dans sa zone angulaire radialement interne coopérant avec deux bras, à proximité du noeud central,
• la figure 15 représente un fil guipé utilisé de préférence dans le cadre de l'invention pour la réalisation de la toile,
• la figure 16 représente schématiquement les mailles d'une toile tricotée conforme à l'invention, et
• la figure 17 illustre schématiquement le dispositif conforme à la présente invention en position déployée, notamment équipé de moyens de contrôle du comportement aérodynamique.

Other characteristics, aims and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings, given by way of nonlimiting example, and in which:

• FIG. 1 represents a general schematic perspective view of a device according to the present invention,
• FIG. 2 represents a partial view of a support frame in accordance with the present invention, partially deployed,
• FIG. 3 represents the same support frame in accordance with the present invention, in the folded position,
• FIGS. 4, 5 and 6 schematically represent the device according to the present invention at three successive stages of its deployment phase,
• FIG. 7 represents a curve illustrating the rise in pressure of the gases of a pyrotechnic generator ensuring deployment, as a function of time,
• FIG. 8 schematically represents a preferred arrangement of pyrotechnic means suitable for generating deployment gases, in accordance with the invention,
• FIGS. 9, 10, 11 and 12 represent means for locking a telescopic mast in accordance with the present invention during four successive stages of deployment,
• FIG. 13 represents a partial view of a fabric element in accordance with the invention at one of its radially external angles cooperating with an arm and a sling,
• FIG. 14 represents a detail view of a fabric in its radially internal angular zone cooperating with two arms, near the central node,
• FIG. 15 represents a wrapped yarn preferably used in the context of the invention for the production of the canvas,
• FIG. 16 schematically represents the stitches of a knitted fabric according to the invention, and
• FIG. 17 schematically illustrates the device according to the present invention in the deployed position, in particular equipped with means for controlling aerodynamic behavior.

We will first describe the structure of the support frame deployable 100 according to the present invention.

This frame 100 is designed to serve as a support for 200 elements of reflective fabric. The frame 100 is further adapted for authorize rapid and autonomous deployment of the reflector device according to the invention preferably having the general shape of an octahedron. This frame 100 is adapted to guarantee excellent precision geometric (orthogonality of the faces formed by the canvas elements 200 between them), as well as a good flatness of each panel composed by these elements, to guarantee the efficiency of the reflector.

Essentially, the deployable support frame 100 conforms to the present invention includes a central node 110 which carries six arms intended, after deployment, to be positioned respectively orthogonal two by two from central node 110.

More precisely still, according to the preferred embodiment illustrated in the appended figures, the deployable support frame 100 thus comprises a telescopic central mast 120 linked to the node 110 and four arms 130 articulated on the node 110.

Thus, as can be seen in the attached FIG. 1, in position deployed the device according to the present invention defines a structure to six orthogonal arms two by two distributed in three orthogonal planes between them each coinciding with four of said arms.

More precisely still, according to the preferred embodiment illustrated in the appended figures, the central mast 120 is formed of two telescopic elements 122, 124. Element 122 consists of a rod or tube main external of the mast 120 which internally slides a rod secondary, of smaller section, making up the telescopic element 124.

The elements 122, 124 are rectilinear and substantially the same length.

Furthermore, the auxiliary arms 130 are also rectilinear and of length substantially equal to that of the above-mentioned elements 122, 124.

The element 122 of the telescopic mast 120 is fixed by one end on node 110, by its end at which the element emerges 124.

The node 110 is formed of a part having a through channel 112.

This channel 112 slidably receives the telescopic element 124 of the mast which is coaxial to it.

The node 110 also carries on its outer periphery four yokes 114 on which the pivoting arms are respectively articulated 130, around axes 116.

The axes 116 are transverse to the longitudinal axis of the mast 120 and of the channel 112. The yokes 114 are equally distributed around the axis of the channel 112, 90 ° from each other.

Thus, the axes 116 of the yokes 114 are oriented in a general peripheral direction with respect to the axis of channel 112 and the axis longitudinal of mast 120.

The axes 116 of the yokes 114 are parallel and orthogonal respectively two by two.

Each pair of arms defined by the mast 120 and the auxiliary arms 130 carries an element 200 of canvas of general triangular geometry.

Thus, the device according to the present invention defines eight concave cube corners, as seen in Figure 17, when deployed. Thus, the device according to the present invention corresponds to a octahedron.

By way of nonlimiting example, the length of each arm 130 and elements 122, 124 of the telescopic mast is of the order of 900 mm.

Furthermore, in the folded state, as illustrated in FIG. 3, the device according to the present invention occupies a cylindrical volume with a length of the order of 1 m and a diameter of the order of 55 mm.

Preferably, the device according to the present invention is associated with a deployment means comprising a gas generator base of a pyrotechnic material.

For this purpose, a seal, such as an O-ring 142 is placed between the two telescopic elements 122, 124. And the element main 122 of mast 120 is associated with a gas generator of the type pyrotechnic 180, which opens into the internal volume of the element 122.

Such a generator 180 can be formed of a structure known as itself under the name of igniter plug, fixed on the second end of the element 122, namely that opposite to the support node 110.

The general structure of a gas generator 180 being known from those skilled in the art, this will not be described in detail below.

Those skilled in the art will understand that such a generator 180 generates gas under pressure in element 122 of the telescopic mast. The generation of gas thus applies pressure to element 124 and tends to deploy it telescopically like a cylinder or piston.

For the most part, the generator 180 preferably comprises a body 182 which carries at least one pyrotechnic composition 184 associated with a primer 186 capable of being initiated by a striker 188 himself associated with a control lever or spoon 189.

The use of a pyrotechnic gas generator allows benefit from an excellent onboard energy / congestion ratio.

As can be seen in the attached figures, the gas generator 180 is integrated inside the telescopic central mast 120.

The gases from combustion are released in the central mast 120 which is elongated (deployment of the element 124 relative to the section of base 122) under the effect of pressure (cylinder effect).

Furthermore, it is the extension of the central mast 120 which ensures the deployment of the structure by pulling on the peripheral arms 130 by through slings 140.

Indeed, as can be seen in the appended figures, provision is made a sling 140 between each pair of adjacent vertices of the device, that is to say between the ends of the arms 130 and the ends of the mast telescopic 120.

Thus, each of the six vertices of the device is connected to the four adjacent peaks via a respective sling 140.

The device thus comprises a total of twelve slings 140.

The slings 140 are preferably formed from a material to be low elongation such as Kevlar (registered trademark).

The length of each sling 140 is equal to the length which separates two adjacent vertices of the structure, in the deployed position, from so that the slings are tensioned in the deployed state of the structure and hold the arms 120 and 130 precisely with precision.

Preferably, in the context of the present invention, the gas generator 180 is suitable for defining two successive regimes of distinct operation: a slow phase, then a fast phase.

The initial slow phase allows a slow pressure rise in the telescopic mast 120, to ensure the deployment of the structure without damage. Typically, the effort during this first phase is the order of a few tens of newtons.

The following rapid phase corresponds to the tensioning of the reflective and requires a greater effort, typically of the order of 300 newtons.

The increase in pressure is shown diagrammatically in FIG. 7 appended.

To obtain such operation in two successive sequences, the gas generator 180 can comprise, for example, as illustrated in FIG. 8, a composition packaged in the form of two sets separate 190, 192.

The first set 190 whose combustion ensures the first phase, slow, consists of a single compressed cylindrical block conditioned so as to present a relatively slow operating regime (combustion known as "in cigarette").

The second assembly 192 is formed from a plurality of blocks (five for example) of compressed composition which is characterized by a fast burning regime.

The telescopic mast 120, as well as the peripheral articulated arms 130 can be made of any suitable material. Preferably, they are made of metal or based on composite material.

As previously indicated, the deployment of the structure is operated during the displacement of the auxiliary rod 124, by through the traction then exerted on the pivoting arms 130 by the slings 140.

However, preferably, means are provided to assist the deployment of the pivoting arms 130, in the form of spring elements 170.

According to the embodiment illustrated in the appended figures, these spring elements 170 are interposed between the base element 122 of the mast telescopic 120 and respectively each of the oscillating arms 130.

More precisely still, according to the particular embodiment given in the appended figures, an elastomer block 170 is thus provided, near the central support node 110, between the telescopic mast 120 and each swinging arm 130.

In the folded position as illustrated in FIG. 3, the blocks 170 elastomers are compressed.

The deployment of the device according to the present invention is shown schematically in Figures 4, 5 and 6.

In Figure 4, we can see the device in the folded position, the arms oscillating 130 being joined along the base element 122 of the mast telescopic 120 and the auxiliary rod 124 being retracted in the element of base 122.

In FIG. 5, the beginning of the deployment of the structure, the rod 124 starting to be deployed on the outside of the base element 122 and the four arms 130 starting to pivot, due to the traction exerted by the slings 140, assisted in this by the elastomeric springs 170.

Finally, we see in Figure 6 the structure according to the present invention in the deployed state, the four oscillating arms 130 then being coplanar in a plane orthogonal to the axis of the central mast 120 and the twelve slings 140 being placed in the stretched position.

Preferably, the device according to the present invention further includes an arm locking device 130 in position deployed.

Such a locking system can be the subject of many embodiments.

Such a locking device obviously has the function to preserve geometric precision.

Such a locking system also makes it possible to overcome effects of the pressure drop inside the telescopic mast 120 following the decrease in gas temperature.

In the context of the present invention, preferably, the means above locking devices are formed on the basis of a metal rod 160 designed to interfere, once the device is placed in the deployed position, with grooves 123, 125 formed respectively on the base element 122 and the telescopic element 124 of the mast 120.

This results in a locking of the telescopic mast 120 in the both directions.

The structure of such a locking means as well as its operation are illustrated in Figures 9 to 12 attached.

We can see in these figures the central support node 110 provided with yokes 114 as well as the ends of the base element 122 and of the element telescopic 124 of the mast 120.

At rest, the metal rod 160 is placed in the node 110. At rest, the rod 160 has a diameter greater than that of the outer tube telescopic 124. The rod 160 is thus placed in the groove 123 of the element base 122. Thus, there is no friction between the rod 160 and the tube 124 of the telescopic mast.

However, the telescopic tube 124 is provided at its end internal to the base element 122 of a cone 126 flared in the direction of its end. The aforementioned O-ring 140 is preferably provided at this flared cone 126.

The outer diameter of the cone 126 is greater than the diameter internal at rest of the rod 140.

Thus, during the movement of the telescopic element 124, the cone 126 presses and opens the rod 140. The cone 126 of the element telescopic 124 is provided with the aforementioned groove 125, on its external surface.

When the groove 125 of the piston 124 arrives opposite the rod 140, as seen in figure 11, the ring closes inside the groove 125, by elasticity, causing blocking of the mast.

The locking device thus formed has inter alia the following advantages: reduced number of parts, reliability and efficiency of the locking, good temperature resistance, no friction during mast movement, and good aging.

According to an alternative embodiment in accordance with this invention, each of the tubes 130, and therefore the base member 122 and the element 124 itself of the mast 120 are each telescopic, that is to say each formed of at least two elements capable of relative sliding along their axis to ensure an increase in length.

This variant allows both to have a structure deployed of great amplitude and a reduced storage volume.

As indicated above, the support frame deployable aforementioned 100 is associated with several canvas elements forming reflector.

More precisely still, the support frame 100 carries twelve triangular panels 200 suitable for forming eight concave cube corners in octahedron.

These panels 200 are designed to reflect waves electromagnetic in a certain frequency range.

The panels 200 are fixed four to four on hems or textile sheaths 210 which provide the structure structure interface in covering the arms 130 of the frame.

The edge of the panels 200 adjacent to the telescopic mast 120 is also equipped with a common hem or scabbard with four panels. The latch fitted to the telescopic part 122 is however wider for allow the tube to slide.

In the folded position, this hem is gathered on the folded part.

The hem placed on the base element 122 of the telescopic mast is preferably made of a material resistant to temperature rise of skin following the operation of the gas generator 180.

As seen in Figure 13, each of the panels triangular 200 is provided at its radially outer free edge a small hem 220 in which one of the slings 140. Each sling 140 can slide in the associated hem 220.

During deployment, the gas pressure generated by the gas generator 180 results in a thrust in the axis of the central mast 120 which is distributed in the slings 140 and thus allows the tensioning reflective fabrics 200.

FIG. 14 illustrates the radially internal angle of a panel 200.

Preferably each panel 200 is provided with a reinforcement 230 at the level of each of its angles.

Each reflector element 200 is preferably formed on the basis 240 knitted yarn.

In the context of the invention, it is preferably a knitting 7 gauge jersey made with 242 polyester yarn covered with nickel yarn 244 as illustrated in Figure 15 (i.e. a thin strip of nickel 244 is spirally wound around polyester wire 242.

The metric number of the wire is 22 (22000 m of wire weighs 1 kg).

The diameter of the polyester thread 242 is typically between 200 and 250 µm.

The density of the fabric is typically between 80 and 85 gr / m ² .

Furthermore preferably, the covering yarn 244 has a cross section general oblong, for example almost rectangular, to allow a good electrical contact at each point of contact between two sections of wire 240.

This solution is used in the context of the invention because it allows to have a very conductive wire, to improve the quality of the contacts elementary wire to wire while using a wire having good characteristics mechanical.

In addition, the jersey knitting mode allows a realization simple and inexpensive in raw material for a mesh size given.

Of course, the present invention is not limited to the mode of particular embodiment which has just been described for each triangular panel 200.

For example, 242 polyester base wire can be replaced by any equivalent material, for example polyamide.

In addition, the covering wire 244 in nickel can be replaced by any equivalent material, for example steel or copper plus nickel.

According to yet another variant, each triangular panel reflector 200 can be formed on the basis of metallized polyester tulle.

Such a panel based on metallized polyester tulle can be formed on the basis of cotton, silk, thermoplastic material or equivalent, arranged in a network of blocked meshes, for example generally hexagonal. Metallization can be obtained by depositing nickel, for example with a thickness of the order of 1 μm. The diameter of the base wire is typically of the order of 200 μm and the density of the panel of the order of 30 to 40 gr / m ² .

As previously suggested, preferably, the device according to the present invention comprises means 300 designed to control the aerodynamic behavior of the reflector during its fall free.

More specifically, these means 300 have the function of controlling both the orientation and the possible rotation of the reflector during its fall free.

• une position d'équilibre sur une arête comme on le voit sur la figure 17 (au moins une arête externe horizontale),
• une vitesse de rotation donnée et régulière du réflecteur sur lui-même autour d'un axe vertical,
• une bonne stabilité autour de la position d'équilibre,
• une durée de stabilisation la plus faible possible (phase de retournement),
• une vitesse de chute la plus faible possible, et
• une dérive la plus faible possible (pas de portance aérodynamique).

More precisely still, in the context of the invention, the means 300 are advantageously designed to control:

• an equilibrium position on an edge as seen in FIG. 17 (at least one horizontal external edge),
• a given and regular speed of rotation of the reflector on itself around a vertical axis,
• good stability around the equilibrium position,
• the shortest possible stabilization period (reversal phase),
• the lowest possible fall speed, and
• the smallest possible drift (no aerodynamic lift).

As a variant, the means 300 can be adapted to control an equilibrium position not on a horizontal edge as illustrated on Figure 17, but on three horizontal edges.

It seems important indeed, within the framework of the invention, to avoid an equilibrium position on an angle, i.e. an orientation of the reflector with a downward angle, i.e. one of the arms 130 or 120 vertical mast.

Different means of orientation can be used for this purpose.

In the context of the present invention, preferably, the means orientation 300 include a canvas dome 310 in the form of a parachute. This canvas 310 can be formed for example of a square of very light canvas and very porous connected to the two upper peripheral nodes 150, 152 and at both ends of the telescopic central mast 120 as seen in the figure 17. According to this figure, the fabric 310 is fixed directly on the nodes upper 150, 152. The fabric 310 is also connected to the ends of the telescopic central mast 120 by slings 312, 314.

Typically, the canvas 310 is 1060 x 1060 mm and the slings 312, 314 connecting the fabric 310 to the ends of the central mast 120 have a length of the order of 500 mm.

The use of a porous material to make the canvas 310 allows to remove the lift in favor of the drag without harming at falling speed.

Furthermore, as can be seen in FIG. 17, preferably the control means 300 include elements 320 designed to print a rotational movement, along a vertical axis, during the fall of the reflector.

These means 320 have symmetry with respect to an axis vertical through the center of node 110 and the middle of one of the edges defined by a sling 140.

More precisely still, preferably, these means 320 are formed of two small triangles of very light and non-porous fabric 322, 324, arranged on the upper inclined panels respectively disposed at end of the central mast 120 and symmetrical with respect to the central node 110, that is to say disposed respectively between the two sections 122, 124 of the telescopic mast 120 and the two arms 130 located coplanar in a plane vertical, directed upwards from the central node 110.

These two small sails, generally adjacent to the top of the octahedron allow to print the rotational movement around the axis vertical previously mentioned.

Of course, the present invention is not limited to the modes of particular embodiments which have just been described but extends to any variant conforms to his spirit.

For example, the previously described reflective octahedron can be associated with metallic or metallized glitter (chaff in terminology Anglo-Saxon).

In addition, we can associate several octahedra, for example typically from 3 to 10, including octahedra of different sizes.

According to other alternative embodiments, provision may be made for complete or replace the canvas triangles 322, 324 ensuring the rotation by symmetrical or asymmetrical holes formed in the panels reflectors.

Furthermore, the present invention is not limited to the realization of an octahedron, but extends to the realization of any polyhedron.

Claims (39)

Electromagnetic reflector device, comprising a support frame (100) which carries a plurality of fabric elements (200) designed to form reflective polyhedra in combination, characterized in that it further comprises means for controlling aerodynamic behavior (310, 322, 324) capable of imposing an orientation of the support frame such that it has at least one horizontal external edge. Device according to claim 1, characterized in that the support frame (100) is deployable. Device according to one of claims 1 or 2, characterized in that the support frame (100) comprises at least one deployable telescopic arm (120). Device according to one of claims 1 to 3, characterized in that the fabric (200) is formed from a knitted fabric. Device according to one of claims 1 to 4, characterized in that the deployable support frame (100) comprises a central node (110) which carries at least the telescopic deployable arm. Device according to one of claims 1 to 5, characterized in that the support frame (100) comprises a telescopic mast (120) linked to the central node (110) and several central pivoting arms mounted at articulation on the central node ( 110). Device according to one of claims 1 to 6, characterized in that the support frame (100) comprises a telescopic mast (120) comprising a main section (122) which slidably receives at least one auxiliary section (124), characterized in that the main section (122) is fixed to the central node (110) by its opening end through which emerges the auxiliary arm (124). Device according to one of claims 1 to 7, characterized in that the support frame (100) comprises a telescopic mast (120) and four pivoting arms (130). Device according to one of claims 1 to 8, characterized in that each arm (120, 130) of the support frame (100) is telescopic and linked to a central node (110). Device according to claim 9, characterized in that the deployable support frame (100) comprises six telescopic arms. Device according to one of claims 1 to 10, characterized in that it comprises means (170) capable of urging pivoting arms (130) in extension. Device according to claim 11, characterized in that the means for urging the pivoting arms (130) comprise slings (140). Device according to one of claims 11 or 12, characterized in that the means for biasing the pivoting arms (130) comprise elastomer blocks (170). according to one of claims 1 to 13, characterized in that it further comprises means (160) capable of ensuring the locking of the telescopic arm (120) in the deployed position. Device according to claim 14, characterized in that the locking means comprise an elastic ring (160). Device according to one of claims 14 or 15, characterized in that one of the elements (124) of the telescopic deployable arm is provided with a cone (126) adapted to ensure the extension of a locking rod ( 160) during the deployment of the telescopic deployable arm, so that the rod (160) once expanded interferes with grooves provided respectively on the two elements capable of relative telescopic movement. Device according to one of claims 1 to 16, characterized in that it defines eight cube corners in the form of an octahedron. Device according to one of claims 1 to 17, characterized in that the fabric (200) is formed of a gauge jersey knit 7. Device according to one of claims 1 to 17, characterized in that the fabric (200) is formed of metallized polyester tulle. Device according to one of claims 1 to 19, characterized in that the fabric (200) is formed from a thermoplastic wire, for example based on polyester, covered with metal, for example nickel. Device according to one of claims 1 to 20, characterized in that the fabric comprises a metallic covering wire (244) of elongated section. Device according to one of Claims 1 to 21, characterized in that the fabric (200) is mounted on the arms (120, 130) of the deployable support frame (100) by means of formed hems (210) at the edges of the fabric (200). Device according to one of claims 1 to 22, characterized in that it comprises means for controlling the aerodynamic behavior which comprise a lift sail (310). Device according to claim 23, characterized in that the lift web (310) is formed of a porous fabric. Device according to one of claims 23 or 24, characterized in that the lifting sail (310) is hung on the one hand on two vertices (150, 152) of the deployable support frame (100), and on the other hand, by means of slings (312, 314) on the two ends of a telescopic mast (120). Device according to one of claims 1 to 25, characterized in that it comprises means for controlling the aerodynamic behavior comprising symmetrical means (322, 324) capable of imposing a rotation of the structure around a vertical axis. Device according to claim 26, characterized in that the rotation control means comprise two symmetrical fabrics (322, 324). Device according to Claim 26, characterized in that the rotation control means comprise orifices formed in the fabrics of the device. Device according to claim 27, characterized in that the two fabrics (322, 324) are fixed between a telescopic mast (120) and the slings (140). Device according to Claims 1 to 29, characterized in that it comprises means for controlling the aerodynamic behavior (310, 322, 324) capable of imposing an orientation of the deployable support frame such that it has at least one horizontal lower edge. Device according to one of Claims 1 to 30, characterized in that it comprises aerodynamic behavior control means (310, 322, 324) capable of ensuring an orientation of the deployable support structure (100) so that that -this includes three lower edges in a horizontal plane. Device according to one of rev 1 to 31, characterized in that it comprises control means comprising a pyrotechnic generator (180) of gas. Device according to one of claims 1 to 32, characterized in that the pyrotechnic generator is designed to define two phases: a first phase of slowly increasing pressure followed by a phase of increasing pressure. Device according to one of claims 1 to 33, characterized in that the pyrotechnic generator comprises two buns of pyrotechnic composition (190, 192) having different combustion properties capable of defining two successive phases, the initial one rising slow pressure, the other pressure build up faster. Device according to one of claims 1 to 34, characterized in that it comprises slings (140) fixed between two vertices of the deployable structure (100). Device according to claim 35, characterized in that the slings (140) are placed in hems formed on the edges of the fabric (200). Device according to one of claims 1 to 36, characterized in that it comprises twelve slings (140). Device according to one of claims 1 to 37, characterized in that the support frame (100) comprises at least one sling (140) which ensures optimal deployment of the fabric (200). Device according to claim 38, characterized in that the sling (140) is arranged along an edge of the fabric element (200).

Images