FR2933075A1 - DEPLOYABLE MATTER WITH REPLACED DEPLOYABLE FRAMEWORK LOCKING BY CONSTRUCTION IN THE DEPLOYED STATE - Google Patents

Abstract

The invention relates to a deployable mast comprising an expandable folded frame formed of a succession of articulated stages each comprising at least three plates (5) articulated in pairs, and adapted to be placed in a folded state where the stages are folded over each other in an accordion, in an expanded state where each plate (5) is curved, the adopting framework, because of its geometry and its assembly, a stable shape extending around the axis rigid axial compression, with a locking effect buckling prohibiting inadvertent folding of the plates (5) and stages relative to each other under the effect of an axial compressive force exerted along the axis of deployment.

Description

DEPLOYABLE DEPLOYABLE MOLDING DEPLOYABLE MAST BY CONSTRUCTION IN DEPLOYED STATE

The invention relates to a deployable mast, and in particular to a deployable space mast intended to be embedded in a space system (for example an artificial space satellite, a space probe, a space vehicle, etc.). A space mast can be used for example to carry a sensor (magnetometer, laser, camera, transmitter, receiver ...) at its distal end, so as to move it away from the main body of the space system, to make measurements on this body main and / or out of its influence (especially of electromagnetic nature (parasites), optical (masking), gravitational or inertial). A space mast can also be used, for example, for the deployment of mechanical members such as: a braking sail of a satellite making it possible to adjust the orbit, or telescope baffle, or a large deployable light structure. For reasons of space, such a mast, whose length must be several meters, must be folded at launch and deployed only when the space system is in space -particularly in orbit- in position of use of the mast . Such a deployable mast may also be used in terrestrial applications in which the same problems may arise: support at camera height, detector, transmitter, receiver, various sensors, etc. For example, such a deployable mast may also be used in the manufacture of foldable / deployable structures, for example temporary shelters, tents, marquees, etc. There are mainly two distinct categories of deployable masts.

A deployable mast according to the first known category is formed of a structure comprising a plurality of articulated rigid segments (see for example EP 0858946) and / or telescopic (see for example US 5315795), or a helically deployed strip, this structure being associated with a motorized deployment device. Such a mast generally has the disadvantage of a weight and a bulk, even in the folded state, relatively large, a certain complexity and high cost. A deployable mast according to the second known category is formed of an inflatable tube (see for example FR 2876984 or US 2004/0046085). Such a mast has the advantage of greater lightness, greater simplicity, low cost. It nevertheless has the disadvantage of poor control of its dimensions and its rigidity in the deployed state, and this in both flexion and axial compression. The invention therefore aims to overcome all these drawbacks by proposing a deployable mast which, simultaneously, is of great lightness, has a low weight and minimum bulk in the folded state, and which, in the state deployed, that is of great rigidity in bending and in axial compression and has precisely determined dimensions. The invention also aims to propose such a deployable mast which is of a low cost, easy and reliable to deploy, can be produced in materials compatible with a spatial application, but can also be the subject of terrestrial applications. To do this, the invention relates to a deployable mast according to a longitudinal deployment axis comprising: a framework formed of a succession of stages articulated to each other two by two in extension of each other along the axis of deployment said framework being adapted to be placed either in a folded state where the stages are folded over each other longitudinally and occupy a minimum axial space, or in an expanded state where they define a predetermined shape, a device for deployment drive associated with said framework so as to cause its longitudinal deployment in the deployed state from the folded state, characterized in that: the stages are articulated to each other and adapted so that, in the state When folded, the framework is folded into accordion, each stage of the framework comprises at least three plates articulated two by two, and extends n General shape of the ring around the axis of deployment, the plates of each floor of the frame and the links of articulation of the plates between them and between the stages are adapted so that, in the expanded state of the frame : each wafer has a cross section of curved shape around the axis of deployment, the frame adopts because of its geometry and its assembly, a stable shape generally extending around the axis of deployment - including symmetrical around the axis of deployment - rigid in axial compression, with a locking effect buckling prohibiting inadvertent folding of platelets and stages relative to each other under the effect of an axial compression force. Such a framework which has a stable shape and locks by construction to the deployed stall by forming a buckling lock can be the subject of various embodiments. A mast according to the invention is also advantageously characterized in that said deployment driving device comprises an inflatable tube (or bladder) extending along the framework, and having a proximal end connected to a gas source. compressed, and a distal end connected to a distal axial end of the framework. Thus, a mast according to the invention comprises in combination an expandable folded frame formed of articulated plates, and an inflatable tube for deploying this framework. Preferably, the inflatable tube extends within the framework, and is connected to the internal interstage hinges. Alternatively and according to the invention, the inflatable tube extends outside the framework, and is connected to the external interstage hinges. In a preferred embodiment and according to the invention, two adjacent plates of the same stage are articulated to each other by a pivot connection, called inter-wafer link, of axis contained in a plane containing the deployment axis. In addition, each plate of a stage is articulated to a wafer of each adjacent stage by hinge, said inter-stage hinge, forming a pivot link axis orthogonal to the axis of deployment, each interstage hinge being adapted for ability to flex elastically along its axis during deployment. Advantageously and according to the invention, inter-wafer connections of the same stage are interposed between two inter-stage hinges, one internal, the other external in the folded state. In this embodiment, advantageously, the width L of each wafer taken in the theoretical direction passing through the two inter-wafer links of this wafer is greater than or equal to the axial length f 1, f 2 of each interstage hinge of this wafer. Advantageously and according to the invention, the axial length f 1 of each internal interstage hinge is less than or equal to the axial length f 2 of each external interstage hinge. Furthermore, advantageously and according to the invention, the plates of each stage are adapted so that the stage has, in the deployed state, a section of generally symmetrical shape of revolution about the axis of deployment, the frame having also, in the deployed state, a symmetrical general shape of revolution around the axis of deployment. Preferably, the different stages all have the same number of platelets of the same dimensions, the frame having a generally cylindrical shape, in particular cylindrical of revolution, in the deployed state. Nothing prevents, as a variant, however, to provide that the framework has, in the expanded state, another shape that is generally tubular cylindrical in revolution, for example a frustoconical type of shape, the number of platelets and / or the dimensions pads of each stage may vary along the axis of deployment. In particular, in a variant according to the invention, the wafers have a variable width, increasing or decreasing, from one stage to another -particularly each wafer has a variable width from its proximal part to its distal part. , so that the framework has a generally non-cylindrical shape - particularly frustoconical of revolution - in the deployed state. Each wafer constitutes, in the expanded state of the framework, a constituent element of the framework which gives it its shape and its mechanical properties, in particular in terms of rigidity and strength. Throughout the text, the term wafer includes any element in one piece having a dimension (thickness) substantially lower than the others (including extending normally at least substantially in a main plane), that is to say not only a solid plate portion of small size, but also any equivalent structure from the point of view of its mechanical behavior, for example an assembly of several rods and / or bars and / or bands. Advantageously and according to the invention, each plate is in one piece, rigid in flexion in a longitudinal direction contained in a longitudinal plane passing through the axis of deployment, but flexible in a direction, said transverse direction, orthogonal to the direction longitudinal. In other words, each plate is rigid and can not be substantially flexed longitudinally, but can be flexed transversely (by bending around the longitudinal direction). Preferably, a mast according to the invention is also characterized in that each wafer is at least substantially flat in the folded state, and in that the axis of each interstage hinge extends in the plane of the connected wafers. by this link. Each wafer may be formed of a single piece or of several pieces rigidly joined to each other. It can be full or more or less hollow. In an advantageous embodiment and according to the invention, each inter-stage hinge is formed of a hinge selected from the group formed by hinges of the flexible film type, hinges of the flexible bridge type, hinges of the piano type and hinges. hinges formed from at least two hinges. Furthermore, advantageously and according to the invention, the axis of each inter-wafer link is at least substantially normal to each wafer connected by this link. Furthermore, advantageously, a mast according to the invention comprises a receptacle adapted to contain the framework in the folded state, and having a distal end forming an opening through which the frame can be deployed longitudinally, and in that distal end of the receptacle is provided with at least three flexible tongues extending radially inwards and cooperating with the folds of the frame so as to slow down the deployment and to give it a direction.

These elastic tongues, preferably uniformly distributed around the deployment axis and adapted to be able to exert equal and balanced radial forces, also have the function of imposing the direction of deployment of the mast (guiding function). The invention also relates to a deployable mast characterized in combination by all or some of the features mentioned above or below. Other objects, features and advantages of the invention will appear on reading the following description which refers to the appended figures, representing, by way of nonlimiting example, a preferred embodiment of the invention, and in which FIG. 1 is a diagrammatic profile view of a mast according to the invention in the deployed state, FIG. 2 is a schematic perspective view of a mast according to the invention being deployed, FIG. a schematic cross-sectional view of a mast according to the invention in the deployed state, FIG. 4 is a diagrammatic cross-sectional view of a mast according to the invention in the folded state, FIG. schematic axial section of a mast according to the invention in the folded state, Figure 6 is a detailed diagram illustrating the kinematics of the frame of a mast according to the invention in the deployed state. The deployable mast according to the invention shown in the figures is an inflatable deployable mast comprising: a frame 1 folded accordion and formed of a plurality of stages 2, 3 articulated to each other in pairs, succeeding one another in extension the each other two to two stacked along a longitudinal axis 4 of the frame 1 which constitutes an axis 4 of deployment of this frame 1 and niat, each stage 2, 3 being itself formed of a plurality of articulated plates 5 two by two, and a deployment drive device comprising an inflatable tube 6 extending along the deployment axis 4 and extending along the frame 1.

The inflatable tube 6 is formed of a lubular pocket of a gas-tight film of dimensions similar to those of the frame 1 so as to be deployed with this frame 1 and cause the deployment of the latter. The inflatable tube 6 extends inside the frame 1.

The mast also includes a receptacle 7 which contains the frame 1 and the tube 6 in the folded state. This receptacle 7 is in the general shape of a cylindrical sleeve and has a base 8 fixed to a not shown frame of the apparatus which receives the mast (for example the platform of a satellite). Throughout the text, the term proximal and its derivatives denote portions located on the side of the receptacle 7 of the frame to which it is connected, whereas the term distal and its derivatives designate on the contrary portions on the side of the end of the mast. further away from the receptacle 7 in the expanded state. The receptacle 7 forms a generally cylindrical housing and has, opposite the base 8, a deployment opening 9 provided with flexible tongues 11 extending radially inwardly from the cylindrical wall of this receptacle 7. receptacle 7 is provided at its base 8 with an inlet 10 of compressed gas adapted to be connected to a source of compressed gas, not shown. This inlet 10 of compressed gas communicates with a pipe 12 extending inside the receptacle 7 and penetrating inside the tube 6, by its proximal end 13, and to which it is connected in a gastight manner, so that that the inflation of the tube 6 can be caused by a gas inlet under pressure in the inlet 10, the pipe 12, and therefore inside the tube 6. Preferably, the pipe 12 extends inside the tube 6 over a certain length of the latter in the folded state, especially over most of its length, without nevertheless reaching the distal end 14 of the tube 6 so as not to be plugged by the latter. For each stage 2, 3 of the frame 1, the plates 5 are connected in pairs, two adjacent plates 5 being articulated to each other by a pivot connection, called inter-wafer connection 18, of axis 19. contained in a plan containing the deployment axis 4. The axis 19 of each inter-wafer link 18 is oriented (also

8 well in the folded state in the deployed state) in a direction normal to each plate 5 connected by this link 18 inter-wafers. Each inter-wafer link 18 may be formed for example by a rivet, a bolt, an ankle ... connecting the two wafers. Each plate 5 of a stage 2, 3 is articulated to a plate 5 of each stage 3, 2 adjacent by a hinge, said hinge 20, 21 inter-stages, forming a pivot connection axis 22, 23 orthogonal to the 4 deployment axis, that is to say, contained in a plane transverse to the axis 4 of deployment, and extending in the plane of each plate 5 connected by this hinge. Each hinge 20, 21 inter-stages is further adapted to be able to undergo a certain elastic flexion along its axis during deployment. Inter-wafers 18 of the same stage 2, 3 are contained in the same transverse plane, and for each wafer 5, are interposed between two hinges 20, 21 inter-stages connecting this wafer 5 to adjacent stages, to namely, an inner interstage hinge 20, and an outer interstage hinge 21.

An internal interstage hinge 20 is folded radially inward and moves radially outwardly during deployment. An outer interstage hinge 21 is folded radially outward and moves radially inwardly during deployment. Thus, the frame 1 is folded accordion and unfolds like an accordion.

In the embodiment shown, each wafer is a solid flat plate portion of constant thickness made of a synthetic material, which may be advantageously a thermoplastic, thermosetting, or composite or metallic polymeric material, and the hinges 20, 21 stages are hinges of film type or flexible bridge, that is to say each formed of a flexible strip of lesser thickness connecting the two wafers considered, this band may be derived from machining, in thickness decrease, platelets (the various plates 5 connected to each other successively by hinges 20, 21 inter-stages constituting a continuous strip extending parallel to the axis of deployment), or after molding or otherwise reported glued on each plate . In the latter case, the hinge strip is not necessarily formed of the same material as the wafers. It may in particular be formed of a portion of sheet or a metal film, for example aluminum foil. The interstage hinges 20, 21 may also each consist of at least two coaxial hinges. Other embodiments are possible.

The frame 1 comprises two types of floors. A stage 2 according to a first type comprises an inner intermediate hinge 20 on the proximal side, and an outer interstage hinge 21 on the distal side. A stage 3 according to the second type comprises an external interstage hinge 21 on the proximal side, and an inner interstage hinge 20 on the distal side.

The frame 1 has, at its proximal end 15, a stage which, in the embodiment shown in FIG. 5, is a stage 3 of the second type (but with h 2 = 0, h 2 being the distance separating the theoretical direction 24 connecting the inter-plate links 18 of the external interstage hinge 21 of a plate 5) integral with the base 8. The frame 1 is provided, at its distal end 16, with an end cover 17 connected to the distal end 14 of the tube 6. The axes 22, 23 of the interstage hinges 20, 21 and the theoretical direction 24 which connects the points of intersection of the axes 19 of the links 18 inter-platelets of a wafer 5 are parallel and orthogonal to the deployment axis 4. In addition, the two inter-plate links 18 connecting a same wafer 5 to two wafers 5 of the same stage, respectively on each side, are interposed between the two interstage hinges 20, 21 respectively connecting this wafer 5 to the two adjacent stages. In other words, the theoretical direction 24 passing through the links 18 inter-plates is interposed between the two hinges 20, 21 inter-stages of the wafer 5.

In any position of the frame 1 corresponding to a folded or partially folded state, the axes 19 of the inter-plate links 18 are not perpendicular to the deployment axis 4, so that the different plates 5 can pivot in pairs relative to each other to adopt relative positions where they retain at least substantially their initial shape at rest, without residual elastic bending stress. In particular, in the embodiment shown in which the plates 5 are all flat, the plates 5 remain at least substantially flat in any folded state of the frame 1. On the other hand, a discontinuity of geometry occurs when the framework 1 goes to the deployed state. Indeed, in the deployed state, the axes 19 of the inter-plate links 18 5 are perpendicular to the deployment axis 4, so that the different plates 5 of the same stage can no longer pivot relative to each other. other two by two around these axes 19 to generate the curvature necessary for the shaping of the frame 1. The various plates 5 and their hinges 20, 21 inter-stages must then undergo an elastic flexion in a direction, said direction Transverse, orthogonal to the longitudinal direction of the wafer. 5 which is contained in a longitudinal plane passing through the deployment axis 4, and which. in the deployed state, is parallel to this deployment axis 4. As a result, in the deployed state, each plate 5 is the seat of residual elastic bending stresses in the transverse direction, which gives a locking effect of the frame 1 in the deployed state, and 15 construction, a very high stability of this frame 1 in the deployed state. In addition, in the deployed state, the plates 5 of the different stages are aligned with each other in their longitudinal direction parallel to the axis 4 of deployment and, because of the bending curvature they present to the expanded state mentioned above, form longitudinal uprights 20 of the frame 1, each upright thus formed having a cross section curved cross section producing a locking effect buckling prohibiting inadvertent folding of the plates 5 and stages by relative to the others under the effect of a possible axial compressive force that can be exerted parallel to the axis 4 of deployment. Thus, the curvature of the plates 5 and hinges 20, 21 in the expanded state forms a tiling effect which, combined with the geometrical discontinuity during the transition to the expanded state and the residual elastic bending stress of the platelets 5 , produces a very high buckling strength of the frame 1 in the deployed state and a blocking of the frame 1 in the deployed state. Thus, in a mast according to the invention, the frame 1 in the folded state 30 can be deployed under the effect of the inflation of the tube 6, but a return to the folded state is normally impossible, without emptying the tube 6, so the deployment is irreversible. In an atmospheric environment, after emptying the tube 6, the hydrostatic pressure forces of the surrounding atmosphere transmitted to the frame from the inflatable tube tend to fold the mast into its initial position. On the other hand, in the space vacuum, this phenomenon does not occur and the folding of the mast does not take place spontaneously, and is therefore normally irreversible or would require specific manipulations. The frame 1 adopts, in the deployed state, by the simple fact of its geometry and its construction, a stable shape (with residual stresses of elastic return within the plates 5 ensuring this stability), generally symmetrical around the deployment axis 4, in particular globally cylindrical of revolution, and is rigid in longitudinal axial compression and in flexion. The frame 1 then determines the shape and dimensions of the mast. Each stage comprises a number N of platelets 5, preferably constant for all stages over the entire length of the frame 1. N is greater than or equal to three, and is advantageously between five and ten, for example equal to six. This number N and the distance d between the inter-wafer links 18 of each wafer 5, which is also preferably constant, that is to say the same for all wafers 5, at least within a stage, and preferably for all stages, determine the radial dimension of the frame 1 in the deployed state. Thus, in the case of normally flat platelets which are elastically flexible in the transverse direction orthogonal to the longitudinal direction so as to be able to bend elastically in the transverse direction in the general shape of tile when the frame 1 arrives in the deployed state we have: dx N = 2nRd, Rd being the radius of the cylindrical frame 1 of revolution in the deployed state.

Furthermore, to allow the initial conditioning of the frame 1 folding accordion, for each wafer 5, the internal hinge 20 inter-stages has a length f1 less than the distance d between the two links 18 inter-wafers of this wafer 5 This length {1 also depends on the distance hl which separates the internal interstage hinge 20 from the theoretical direction 24 connecting the inter-wafer links 18, determining the internal radial dimensions of the frame 1 in the folded state allowing the Passage of the inflatable tube 6. We must have N xf 1 <2itRi, Ri being the radius of the theoretical cylinder inscribed inside the plates in the folded state, which depends on h1 and Rd. The free space, materialized by this inner inscribed cylinder may serve as a receptacle for a possible harness consisting of supply and / or measurement cables extending from the proximal portion to the distal portion of the mast. The buckling strength of the frame 1 in the expanded state is determined by the smallest cross-section of the uprights formed by the succession of platelets 5 of the different stages along the frame 1. This smaller cross section is determined by the length f 1 of the internal interstage hinges 20. Indeed, it is not advantageous to provide that the length f2 of the external interstage hinges 21 is smaller than the length t1 of the internal interstage hinges 20, which would unnecessarily decrease the buckling resistance. Whatever the embodiment of the plates 5, preferably, they comprise a continuity of material between the hinges 20, 21 inter-stages, at least over a width (in the transverse direction) corresponding to the length and so as to to transmit the axial buckling stresses on a section corresponding to this length f 1. Consequently, in a mast according to the invention, preferably, f2> _ 1. In view of the above, the bending stresses of each wafer 20 5 producing a blocking in the deployed state being imparted from inter-wafer links 18, it is advisable to choose the dimensions and characteristics of each wafer 5 and hinges 20, 21, in particular f1, f2, d, its thickness and its modulus of elasticity so that each plate 5 effectively undergoes bending deformation (tilting). For this purpose, a length 2 of the order of the distance d separating the two inter-platelet links (f2d) is preferably chosen. In an embodiment not shown, 2 may be of the same order as the width L of the wafer 5 taken in the direction 24 through the links 18 inter-wafers (f2 L). In the embodiment shown, 2 <L and 2. d.

In any case, there is generally no need for the length f2 of the external interstage hinges 21 to be greater than the width L of the plates 5 taken along the direction 24 passing through the two links 18 inter-platelets. Consequently, in a mast according to the invention, preferably, f 2 <L. Thus, the width L of a wafer 5 taken in the direction 24 passing through the two inter-wafer links 18 is greater than or equal to the axial length. fl, f2 of each hinge 20, 21 inter-stages. In any case, we must have N x f2 <2rtRe, Re being the radius of the theoretical cylinder circumscribing the platelets in the folded state. The distance h2 separating the theoretical direction 24 connecting the inter-plate links 18 of the external interstage hinge 21 of a wafer 5 determines the overall external radial space requirement of the frame 1 in the folded state and, for a same axial length of the frame 1 in the deployed state, the total height of this frame 1 in the folded state. The larger the h2, the greater the overall external radial size of the frame 1 in the folded state (ie the radius Re) is large and its height in the folded state is low. Thus, h2 determines the overall dimensions of the receptacle 7. Preferably, one chooses h1 = h2, that is to say that the theoretical direction 24 passing through the links 18 inter-wafers is halfway away from the two hinges 20 , 21 inter-floors. Indeed, this geometry makes it possible to give the receptacle 7 a compact footprint having a minimum form factor (ratio of its largest dimension to its smallest dimension). Preferably, the last distal stage of the framework 1 forming its distal end 16 is a stage 2 of the first type, but for which h 2 = 0, that is to say which terminates at the level of the links 18 platelets where it is closed by the lid 17.

Moreover, the resilient tongues 11 of the receptacle 7 which slow down and guide the deployment of the framework 1 during inflation so that this deployment is progressive, extend radially over a distance such that their radial free internal ends provide an opening of radius less than the radius Re determining the external radial size of the frame 1 in the folded state and greater than the radius Ri determining the internal radial size of the frame 1 in the folded state.

A deployable mast according to the invention has the advantage in combination of being particularly simple, inexpensive, easy deployment and reliable, low mass, small footprint in the folded state, to have precisely defined dimensions and shape and mechanical properties of excellent flexural and buckling strength, and to be able to be achieved in a manner compatible with its boarding on a space system. The invention may be the subject of numerous variants with respect to the preferred embodiment shown in the figures and described above. In particular, it is possible to provide that the frame extends inside the inflation tube; that the various plates are formed not portions of solid plates, but of several pieces rigidly joined to each other, for example strips, rods, bars ...

Claims (1)

CLAIMS1 / - Mast deployable according to a longitudinal deployment axis (4) comprising: a frame (1) formed of a succession of stages (2, 3) articulated to each other two by two in extension of each other according to the deployment axis, said framework (1) being adapted to be placed, either in a folded state where the stages (2, 3) are folded over each other longitudinally and occupy a minimum axial size, or in an expanded state where they define a predetermined shape, a deployment driver associated with said frame (1) so as to be able to cause its longitudinal deployment in the deployed state from the folded state, characterized in that the stages ( 2, 3) are articulated to each other and adapted so that, in the folded state, the frame (1) is folded accordionally, each floor of the frame (1) comprises at least three plates (5) hinged two to two, and extends in the general shape of a ring around the deployment axis, the plates (5) of each stage (2,3) of the framework (1) and the links (18, 20, 21) d articulation of the plates (5) between each other and between the stages (2, 3) are adapted so that, in the expanded state of the framework (1): each plate (5) has a cross section of curved shape around of the axis (4) of deployment, the frame (1) adopts because of its geometry and its assembly, a stable form extending around the axis (4) of deployment, rigid in axial compression, with a buckling locking effect preventing inadvertent folding of the plates (5) and stages (2, 3) relative to one another along the axis of deployment. 2 / - Mast according to claim 1, characterized in that said deployment driving device comprises an inflatable tube (6) extending along the framework (1), and having a proximal end (13) rel a compressed gas source, and a distal end (14) connected to a distal axial end (16) of the framework (1). 3 / - Mast according to claim 2, characterized in that the inflatable tube (6) extends inside the framework (1), and is connected to the internal interstage hinges 20. 4 / - Mast according to claim 2, characterized in that the tube (6) inflatable extends outside the frame (1), and is connected to the hinges 21 external interstage. 5 / - Mast according to one of claims 1 to 4, characterized in that two plates (5) adjacent the same stage are hinged to each other by a pivot connection, said link (18) inter- plates, axis (19) contained in a plane 15 containing the axis (4) of deployment. 6 / - Mast according to claim 5, characterized in that each plate (5) of a stage (2, 3) is articulated to a plate (5) of each adjacent floor by a hinge, said hinge (20, 21) interstage, forming an axis pivot connection (22, 23) orthogonal to the axis of deployment, each interstage hinge being adapted to be resiliently flexed along its axis during deployment. 7 / - Mast according to claims 5 and 6, characterized in that the links (18) inter-plates of the same stage are interposed between two hinges (20, 21) inter-stages, one (20) internal, the other (21) external in the folded state. 8 / - Mast according to claim 7, characterized in that the width (L) of each wafer (5) taken in the theoretical direction (24) passing through the two links (18) inter-wafers of this wafer (5) is greater than or equal to the axial length (f 1, f 2) of each interstage hinge (20, 21) of this plate (5). 9 / - Mast according to one of claims 1 to 8, characterized in that the plates (5) of each stage (2, 3) are adapted so that the stage has, in the deployed state, a section of shape generally symmetrical of revolution about the deployment axis (4), the frame (1) also having, in the deployed state, a symmetrical general shape of revolution about the axis (4) of deployment. 10 / - Mast according to one of claims 1 to 9, characterized in that the different stages (2, 3) all have the same number of platelets (5) of the same dimensions, the frame (1) having a general shape cylindrical of revolution in the deployed state. 11 / - Mast according to one of claims 1 to 9, characterized in that the plates (5) have a variable width from one stage to another, the frame (1) 10 having a generally non-cylindrical shape to the deployed state. Mast according to one of claims 1 to 11, characterized in that each plate (5) is in one piece, rigid in flexion in a longitudinal direction contained in a longitudinal plane passing through the axis (4) of deployment, but flexible in one direction, said transverse direction, orthogonal to the longitudinal direction. 13 / - Mast according to claim 12, characterized in that each plate (5) is at least substantially flat in the folded state, and in that the axis (22, 23) of each hinge (20, 21) inter stages extends in the plane of the plates (5) connected by this connection. 20 / - - Mast according to one of claims 1 to 13, characterized in that each hinge (20, 21) inter-stages is formed of a hinge selected from the group formed of flexible film type hinges, hinges flexible bridge type, hinges of the piano type and hinges formed of at least two hinges. 25 15 / - Mast according to claim 4 and one of claims 1 to 14, characterized in that the axis (19 ) of each inter-wafer link (18) is at least substantially normal to each wafer (5) connected by this link (18). 16 / - Mast according to one of claims 1 to 15, characterized in that it comprises a receptacle (7) adapted to contain the frame (1) in the folded state, and 30 having a distal end forming an opening through which the frame (1) can be extended longitudinally, and in that the distal end of the receptacle (7) is provided with at least three flexible tongues (11) extending radially inwards and cooperating with the folds of the frame (1) so as to guide and slow the deployment.