WO2002020348A1 - Device and method for hooking a band of flexible material to a securing device - Google Patents

Abstract

The invention concerns an anchoring device to be hooked to a securing element (11) comprising a pair of distal stops (23, 33), a pair of proximal stops (24, 34), an intermediate stop (32). The method consists in forming an end winding (25) with each strip (12) of the band (4) to be anchored, and in wedging said end winding (25) between an outgoing portion (16) of the strip (12) and the intermediate stop (32).

Description

 DEVICE AND METHOD FOR ANCHORING A FABRIC OF FLEXIBLE MATERIAL TO A MOORING ELEMENT.

The invention relates to a device and a method for anchoring a sheet of flexible material to an element, called an anchoring element, having a curved cross-section free of sharp edges over at least one angular sector greater than 180 degrees. opposite to a direction in which the sheet is intended to extend, and adapted to retain at least one loop formed by at least one strip of at least one layer of the sheet. The invention is in particular applicable for the polar closure of a symmetrical envelope of revolution of a pressurized aerostatic balloon.

US Pat. No. 3,686,721 describes a circular clamp for closing a balloon envelope comprising a amanage ring and two pinching rings which are pressed against each other to pinch the loops formed by the bands of the envelope around of the mooring ring. The two pinching rings thus form, for each band of the envelope, a blocking flange for a loop of this band.

This anchoring device may suffice in the case of small and / or weakly pressurized balloons, but is not sufficient to withstand significant forces.

However, in certain applications, it is necessary to be able to anchor a sheet of flexible material while resisting very high tensile forces, which can range up to several million newtons. This is in particular the case of envelopes of large pressurized balloons (up to several hundred meters high) and / or highly pressurized (cf. for example FR-2 472 971 or US-4 711 416).

The study of these anchoring devices is all the more important since these envelopes of symmetrical shape of revolution - notably generally cylindrical with lobes - constitute the basic architecture of large-volume balloons, capable of transporting large loads. For this purpose, the gas retention structure of these balloons must be able to withstand very high overpressures in order to allow their aerostatic control by variation of their gas mass. These balloons (US Pat. No. 4,711,416) may consist of an external envelope guaranteeing resistance to overpressure and of one or more internal envelopes serving as a reservoir of helium or air under pressure. The tensions developed by the overpressure are taken up by the external envelope, by networks of longitudinal and circumferential reinforcements and by an interpolar link connecting the two poles of the envelope. The distribution of forces between these different elements thus makes it possible to achieve very high overpressures of the order of 500 to 600 millibars. The absence of significant mechanical connections outside the pole pieces allows structural behaviors very close to theoretical results and therefore the possibility of working with realistic safety factors, provided however that polar anchoring devices of the envelope can be produced. very reliable, and capable of ensuring the recovery of longitudinal tensions stressing the external envelope.

US-4,911,380 has proposed a device for attaching an envelope allowing the recovery of forces while ensuring the tightness of the envelope. This device nevertheless proves to be complex and difficult to implement. In addition, he drives,. for large balloons, the production of metal annular parts that are far too heavy and incompatible with the production of an aerostatic balloon. The invention therefore aims to overcome these drawbacks by proposing a device and a method for anchoring a sheet of flexible material such as an outer envelope of a balloon, resistant to considerable tensile forces which can in particular reach several million newtons. .

The invention also aims to allow a uniform distribution of the forces over the entire width of the ply, that is to say over the entire length of the anchoring element. The invention also aims in this respect to minimize the stresses in the constituent elements of the anchoring device.

The invention also aims to propose an anchoring device allowing modifications of relative orientation, without effort, of the sheet relative to the anchoring element. Indeed, in the case for example of an external balloon envelope, its inclination at the poles must be able to vary according to the inflation status of the balloon which varies during inflation at launch, but also during changes in altitude of the balloon.

The invention further aims to provide an anchoring device as light as possible - in particular compatible with its incorporation in a large aerostatic balloon (typically a generally cylindrical balloon with a diameter between 5m and 50m) -, of simple manufacture and inexpensive, and an anchoring method easy to implement.

The invention thus relates to a device for anchoring a sheet of flexible material to an element, known as a mooring element, having a curved cross section free of sharp edges on at least one angular sector greater than 180 ° opposite to a direction, in which the ply is intended to extend, this anchoring element being adapted to retain at least one loop formed by at least one strip of at least one layer of the ply, this device comprising at least one flange for blocking a loop formed around the anchoring element by a strip of at least one layer of the ply having a free end, this device being characterized in that each blocking flange comprises:

- a pair of stops, called distal stops,

- a pair of stops, called proximal stops, - at least one stop, called an intermediate stop,

- means for assembling the distal, proximal and intermediate stops adapted so that:

. the distal stops are spaced from each other by a distance allowing the passage between them of a thickness of the strip,. the proximal stops are spaced from each other by a distance allowing the passage of two thicknesses of the band forming the loop, the proximal stops being closer to the drive element than the distal stops,

. the intermediate stop is arranged between the two pairs of distal and proximal stops, so that an end winding of the strip can be formed with a portion, called end return portion, of the strip extending between the anchoring element and the free end of the strip, and that this end winding can be wedged between this intermediate stop and a portion, called the forward portion, formed by the strip from the distal stops to the proximal stops, this outward portion being extended towards the anchoring element by the loop and the end return portion,. the distal, proximal and intermediate stops are arranged in relation to each other so that:

- the end winding is applied against the intermediate stop under the effect of a longitudinal tension of the strip,

- the end winding cannot escape, neither between the distal stops, nor between the proximal stops.

Advantageously and according to the invention, the device is characterized in that the assembly means comprise two rigid side plates integral spaced from one another by a distance corresponding to the width of the strip to allow the passage of the strip between the side plates, and in that the distal, proximal and intermediate stops extend between the two side plates in which they are engaged, so that the side plates keep the stops in position relative to each other at least in the longitudinal direction of the strip.

Advantageously and according to the invention, a side plate is interposed between each pair of adjacent strips. Thus, the blocking flanges follow one another along the width of the ply, a single side plate between two strips serving for two adjacent blocking flanges.

Advantageously and according to the invention, each locking flange comprises means for rigid association of the two side plates with respect to each other at least in a direction parallel to the width of the strip. These rigid association means can be formed in whole or in part by one or more stops, or on the contrary, by specific fixing means such as bolts.

Advantageously and according to the invention, the side plates are provided with reinforcements in excess thickness adapted so as not to prevent the passage and the engagement of the strip in the blocking flange. To ensure the application of the end winding against the intermediate stop, the outward portion of the strip must be separated, by this end winding, from the plane passing through the contact lines of the outward portion of the strip with the distal stop and the proximal stop with which it is in contact. It is therefore sufficient that the end winding is sufficiently thick. To promote this effect, advantageously and according to the invention, the intermediate stop has a contact face with the end winding which is located at least in part on the same side as the outward portion of the strip relative to a tangent plane at the two distal and proximal stops in contact with this forward portion of the strip.

Each of the distal, proximal and intermediate stops can be produced in any form capable of providing the abovementioned stop functions. The distal and proximal stops must prevent the passage of the end winding under the effect of the tension of the strip. The intermediate stop must hold the end winding compressed against it by the tension of the forward portion of the strip.

Advantageously and according to the invention, each of these stops is formed by at least part of a rigid member extending transversely relative to the loop, that is to say generally orthogonally to its main longitudinal direction. The ^'length of the rigid member conespond to at least the width of the strip, so that it extends continuously at least opposite to the entire width of the strip, between the two longitudinal free edges of the strip. The strip therefore comes into contact with the stops along a line or a contact surface extending continuously over the entire width of the strip.

Advantageously and according to the invention, at least one distal and / or proximal and / or intermediate stop is formed by a rigid straight or curved strip. As a variant or in combination, advantageously and according to the invention, at least one distal and or proximal and or intermediate stop is formed by a bundle of rods, in particular of the piano strings type.

These stops must be sufficiently rigid and resistant to withstand the forces induced by the longitudinal tension of the strip, the value can be very high. They are advantageously made of high strength steel. The advantage of making the stops in the form of bundles of rods is to allow torsional deformations and deformations of the shape of the cross section of the stops according to the value of the forces, so that this shape in section adapts spontaneously in the state of least stress. Advantageously and according to the invention, the distal, proximal and intermediate stops have a generally convex cross section free of sharp edges at least in their sector intended to come into contact with the strip. Advantageously and according to the invention, the device is characterized in that the intermediate stop, one of the distal stops and one of the proximal stops are all three formed from a single bane or from a single bundle of rods, and in that the other distal stop and the other proximal stop are formed by separate strips or rod bundles. The device then comprises three strips or three bundles of rods of which: a bane or bundle of proximal rods forming a proximal stop in contact with the forward portion of the strip, a bane or bundle of distal rods forming a distal stop in contact with the portion go from the strip, and a bane or a bundle of intermediate rods forming the intermediate stop and the two other proximal and distal stops.

The sheet may include several adjacent strips, gathered or not, whose relative orientation depends on the shape which must be given to the sheet, which itself depends on the shape of the anchoring element. Advantageously and according to the invention, the anchoring device comprises a locking flange for each loop, that is to say for each strip.

Advantageously and according to the invention, in the case of several bands, the anchoring device is characterized in that it comprises several adjacent locking bands for several loops, and in that at least one of the distal stops, proximal or intermediate of the different blocking flanges is formed by one and the same bane or one and the same bundle of rods which extends with regard to the different bands of the web. Advantageously and according to the invention, each of the stops of the different flanges blocking device is formed by a single bane or a single bundle of rods. Each bane or bundle of rods of the device according to the invention therefore crosses the side plates of the various successive locking flanges to act as stop (s) for each locking flange. The shape of the anchoring element is dictated by that which must be given to the sheet, and can be arbitrary. In the case in particular of the anchoring of a polar end of a sheet forming a symmetrical envelope of revolution such as a pressurized balloon envelope, the anchoring element is annular. Advantageously and according to the invention, the beams or strips forming the distal, proximal and intermediate stops are then also annular and with the same axis of symmetry (this axis of symmetry being common to the stops and to the drive element).

Advantageously and according to the invention, each blocking flange comprises a rigid core adapted to receive the end winding. Advantageously and according to the invention, the rigid core has a recess formed in a hollow adapted to receive an end hem of the strip. Advantageously and according to the invention, the housing is formed on one face of the rigid core oriented towards the intermediate stop, and offset from the side of the proximal stops. Advantageously and according to the invention, the rigid core has a thickness greater than the distance separating the two distal stops from one another and greater than the distance separating the two proximal stops from one another

The width of each strip, and therefore of each blocking flange, and the number of blocking flanges is defined on the one hand according to the curvature of the drive element, and on the other hand according to the tensile forces on the tablecloth. Indeed, the resistance of each blocking flange increases when its width decreases. The resistance of the amanage device increases with the number of blocking flanges and side plates retaining the stops. Advantageously and according to the invention, each blocking flange has a width of between 1cm and 10cm.

Furthermore, advantageously and according to the invention, the device comprises means forming a contact stop for each flange of blocking against the drive element. Advantageously and according to the invention, the means forming a contact stop against the amanage element comprise at least one protective pad interposed between the edges of the proximal side plates of each locking flange, and the amanage element. The invention also extends to a method of anchoring a sheet of flexible material to an element, called an anchoring element, having a cross-section of curved shape free of sharp edges on at least one upper angular sector. at 180 ° opposite to a direction in which the ply is intended to extend, this anchoring element being adapted to retain at least one loop formed by at least one strip of at least one layer of the ply, in which:

- at least one loop is formed around the anchoring element, with at least one strip of at least one layer of the ply having a free end, - each loop is blocked using a flange blocking, characterized in that:

- the free end of the strip is passed successively between a pair of stops, called distal stops, of the blocking flange, then between a pair of stops, called proximal stops, of the blocking flange, closer to the element as the distal stops, so that a portion, called the forward portion, is formed by the strip between the distal stops and the proximal stops, then around the anchoring element, then again between the proximal stops , so as to form the loop around the anchoring element, with a portion, called the end return portion, of the strip between the anchoring element and the free end of the strip,

- An end winding of the strip is then carried out with the end return portion, and this end winding is inserted and wedged between a stop, said intermediate stop, of the locking flange and the outward portion of the band, and in that a blocking flange is used, the distal, proximal and intermediate stops of which are assembled and arranged with respect to each other so that: . the loop and the end winding can thus be produced,

. the end winding is applied against the intermediate stop under the effect of a longitudinal tension of the strip,. the end winding cannot escape either between the distal stops, or encroach on the proximal stops.

Advantageously and according to the invention, the end winding is produced with a total thickness greater than the distance separating the two distal stops. In this way, the end winding cannot pass through the space between the distal stops. Similarly, advantageously and according to the invention, the end winding is produced with a total thickness greater than the distance separating the two proximal stops, so that the end winding cannot pass through the space between the proximal stops. Advantageously and according to the invention, the end winding is produced around a rigid core. Advantageously and according to the invention, a hem is produced at the end of the strip which is placed in a recess formed in the hollow in the rigid core. Advantageously and according to the invention, the rigid core is placed with the housing oriented towards the intermediate stop, and offset towards the proximal stops. Advantageously and according to the invention, a rigid core is used which is thicker than the distance separating the two distal stops from one another, and greater than the distance separating the two proximal stops from one another.

Advantageously and according to the invention, the end winding is produced in a winding direction adapted so that the tension of the forward portion of the strip tends to wind the end winding on itself. To do this, the end winding is produced so that the end return portion coming from the anchoring element first comes into contact with the outward portion before coming into contact with the intermediate stop. Advantageously and according to the invention, the method is characterized in that the sheet of flexible material is cut into a plurality of strips in a direction at least substantially perpendicular to one of its end edges, and in that there is formed with each strip a loop around the anchoring element which is blocked by means of a blocking flange and an end winding of this bandaged.

Advantageously and according to the invention, a longitudinal gathering of each loop is carried out before forming the mouth and blocking it. In this case, each loop is formed of a plurality of layers of the flexible material constituting the ply folded over one another. The shirring rate is chosen according to the desired shrinkage of the sheet towards the anchoring element. Advantageously and according to the invention, each strip is produced so that it comprises longitudinal fibers having a rate of elasticity before breakage of less than 3%. Advantageously and according to the invention, each strip is produced with a width of between 1cm and 10cm.

Advantageously and according to the invention, the strip is positioned in the blocking flange so that the blocking flange abuts against the drive element. Advantageously and according to the invention, at least one protective pad is interposed between the proximal portions of the blocking flange and the anchoring element - in particular between the proximal edges of the side plates and the anchoring element. Furthermore, the invention more generally extends to a mooring process characterized in that a mooring device according to the invention is used.

The invention also relates to an amanage device and method characterized in combination by all or some of the characteristics mentioned above or below.

The invention makes it possible to obtain, in practice in a simple manner, an anchoring resistant to tensile forces of extremely high values which can range up to several million newtons. It also makes it possible to ensure uniform anchoring, with a uniform distribution of the stresses on the anchoring element, including when the latter is of curved or complex shape, and minimizes the stresses in the locking flanges. Other objects, characteristics and advantages of the invention appear from the following description which refers to the appended figures representing preferential embodiments given only by way of nonlimiting examples in the case of the polar anchoring of an envelope external of pressurized balloon, and in which:

- Figure 1 is a schematic perspective view illustrating the structure of an aerostatic assembly comprising three balloons equipped with polar anchoring devices according to the invention, the envelopes being shown transparent for purposes of illustration, - Figure 2 is a schematic perspective view partially anachimized of an upper polar anchoring device according to the invention of one of the balloons of the aerostatic assembly of FIG. 1,

- Figure 3 is a schematic partial perspective view of detail of the anchoring device of Figure 2, - Figure 4 is a schematic view from above illustrating two adjacent locking flanges of an anchoring device of Figure 2 ,

- Figure 5 is a schematic view in axial section of detail along the line NN of Figure 4 illustrating a locking flange of the anchoring device according to the invention, - Figure 6 is a schematic view from above illustrating a method of manufacturing the clamps of the anchoring device of FIG. 2,

- Figures 7a and 7b are partial schematic views illustrating two stages of a method according to the invention, - Figure 8 is a partial schematic view in perspective illustrating an alternative embodiment of the locking flanges of an anchoring device according to the invention.

The anchoring device 10 according to the invention shown in the figures is integrated into a polar connection device 1 of a pressurized balloon 2. These polar connection devices 1 make it possible not only to ensure the general cohesion of the balloon 2, but also the connection of several balloons 2 (FIG. 1) making it possible to produce an aerostatic assembly formed of a plurality of balloons 2 connected to each other by their respective upper and lower polar connecting devices 1 to which connecting beams 45 hang. The polar connecting devices of the same balloon 2 are connected to each other at inside the balloon 2 by an interpolar link 3 formed of at least one flexible cable under tension under the effect of the pressure in the balloon. The connecting beams 45 can also be formed from pressurized balloons.

Each balloon 2 is for example of the type described by US-4420130 or US-4711416. Each of the envelopes constituting the balloon 2 is anchored to each of the polar connection devices 1 of the balloon 2. The anchoring device according to the invention is used in particular to anchor an external envelope 4 to each of the polar connection devices 1. This the outer casing 4 has the function of resisting the pressure forces developed by the pressurized gases contained in the sealed inner casings of the balloon 2, and of defining the general shape, generally cylindrical in the example shown, of the balloon 2. At the level of the devices polar link 1, the tension forces supported at the end of the outer casing 4 are considerable, generally greater than several million newtons. Each polar connecting device 1 has a generally biconical shape with two opposite vertices. This general shape is obtained from a central cylinder 5, rigid at least in axial compression, now separated from one another two connecting pieces 6, 7, forming the tops of the bicone, and which are fixed at the ends of the central cylinder 5. One 6 of the two connection pieces allows the connection with a neighboring balloon, while the other 7 allows the connection inside the balloon 2 to the interpolar link 3, and the fixing of each internal envelope . The central cylinder 5 can itself be formed from a cylindrical balloon pressurized by air or a gas lighter than air (for example helium) and / or filled with a rigid padding material in compression such as foam in a block or in divided form. The padding material may be placed in an envelope of the balloon prior to inflation. The anchoring device 10 according to the invention is connected to each end connection piece 6, 7, at least substantially in the middle part of the central cylinder 5, on each side, by a conical network 8, 9 of cables extending uniformly outside the central cylinder 5 between each connection piece 6, 7 and the anchoring device according to the invention of generally annular shape around the central cylinder 5.

The two networks 8, 9 stretched by the central cylinder 5 make it possible to hold the anchoring device 10 in place at least substantially halfway between the connection pieces 6, 7. It should nevertheless be noted that the invention is just as although applicable to a device for anchoring an external casing 4 enabling this casing to be closed at each of these poles, without this anchoring device 10 being itself connected to another structure. In other words, the annular anchoring device could be left free and simply allow the polar end of the outer casing 4 to be closed by supporting the stresses generated by the tension of this outer casing 4 under the effect of the pressurization of the balloon. .

The anchoring device 10 makes it possible to anchor the outer casing 4 to an element, called the amanaging element 11, formed of an O-ring surrounding the central cylinder 5, coaxial with the central cylinder 5, but spaced from this central cylinder 5. The actuating element 11 extends according to a diameter greater than that of the central cylinder 5 and that of the connection parts 6, 7. In the example shown, the transverse (radial) cross section of the element amanage 11 is therefore circular. However, it should be noted that the invention is equally applicable with any other form of cross section of non-circular drive element, since this section is curved free of sharp edges over at least one angular sector greater than 180 ° opposite to a direction in which the outer casing 4 is intended to extend. Indeed, a section having sharp edges would inevitably cause damage to the loops of the envelope passed around the anchoring element 11.

The outer envelope 4 of the balloon is of generally cylindrical shape, the end edges of which must be anchored to the anchoring element 11 by the anchoring device 10. To do this, the outer envelope 4 is cut longitudinally. a plurality of longitudinal strips 12 parallel to each other (before anchoring) perpendicular to its end edge, over a length sufficient to allow to form, with each strip 12, a loop 18 around the drive element 11, and to block this loop by means of a blocking flange 13 as described below.

To allow the diameter of the outer casing 4 to be reduced to the diameter of the fitting element 11 (which is less than that of the current diameter of the outer casing 4), a longitudinal gathering of each strip is carried out before forming the loop 18 around the anchoring element 11 and blocking this loop. "Longitudinal gathering" means a gathering formed by folds of the strip 12 placed one on top of the other and formed along longitudinal fold lines (parallel to the main direction of the strip). Consequently, each of the bands 12 is formed in practice of several layers of the ply of flexible material forming the outer envelope 4. Furthermore, each band 12 has a free end 14, to which a hem 15 is produced by folding and gluing and / or welding.

Each strip 12 is passed around the anchoring element 11 to form a loop 18 thereby defining a portion, called the forward portion

16, extending to the anchoring element 11, then, after passing around the amanaging element 11, a portion, called the return end portion 17, extending to the end free 14 of strip 12.

Each locking flange 13 has the function of blocking the return end portion 17 relative to the outward portion 16, so that the loop 18 thus formed around the drive element 11 cannot slip.

Each locking flange 13 comprises two rigid metal side plates 19 spaced from each other by a distance ^' corresponding to the width of the strip 12 to allow the passage of the strip 12 within them. These plates 19 are plates of rigid material, in particular of thin steel, in particular of the order of minus 2 mm. The locking flanges 13 succeed one after the other along the drive element 11 to block the different loops 18 formed by the different strips 12 of the outer casing 4. In the embodiment shown, advantageously and according to the invention, a side plate 19 is interposed between each pair of adjacent strips 12, so that the same side plate 19 is used to two blocking flanges 13 located on either side of this side plate 19. The different side plates 19 are identical and provided with three openings crossed by rod bundles 20, 21, 22, the cross sections of which are shown in the figure 5. The anchoring device 10 according to the invention shown in the figures is that of the upper polar connecting device 1 and is described with the orientation of this upper polar connecting device. It should however be understood that the orientation in space of the anchoring device 10 does not matter. Consequently, the terms "low", "high", "upper", "lower" are only used for clarity and not as absolute references.

A first bundle of rods, called upper distal bundle of rods 20, receives the outward portion 16 of the strip 12 at its entry into the blocking flange 13 and has a convex curved surface oriented downwards coming into contact with the strip 12. A second bundle of rods, called upper proximal rod bundle 21, receives and guides the outward portion 16 of the strip 12 at its exit from the locking flange 13 in the direction of the actuating element 11 in order to form the loop. 18. Also, this upper proximal rod bundle 21 defines a convex curved contact surface generally oriented downwards towards the outward portion 16. The bundles of upper distal 20 and proximal upper rods 21 have a cross section which is preferably curved. convex, for example in the form of a half-disc, with median axes of symmetry of these two transverse straight sections which are inclined with respect to each other at an angle of the order of 90 °.

Between the two upper distal and proximal rod bundles 20, 21, a third rod bundle, called the intermediate rod bundle 32, has a generally rectangular section. The intermediate rod bundle 22 is slightly offset downward relative to the two upper distal and proximal rod bundles 20, 21.

The distal end 23 (that is to say the end remote from the drive element 11) of the intermediate rod bundle 22 extends opposite the upper distal rod bundle 20, so that this end distal 23 and a portion 33 opposite this upper distal bundle 20 define a pair stops, said distal stops 23, 33, spaced from each other by a distance allowing the passage between them of a thickness of the strip 12 at least. Similarly, the proximal end 24 of the intermediate rod bundle 22 extends opposite the upper proximal rod bundle 21, so that this proximal end 24 and a portion 34 opposite this upper proximal rod bundle 21 define a pair of stops, called proximal stops 24, 34, spaced from one another by a distance allowing the passage between them of at least two thicknesses of the strip 12 forming the loop 18, these proximal stops 24, 34 being closer to the drive element 11 than the distal stops 23, 33.

Between its two distal 23 and proximal 24 ends, the intermediate rod bundle 22 defines a stop, called an intermediate stop 32, against which an end winding 25 of the strip 12 is applied. This winding exfrémité 25 is formed with the back end portion 17 of the ^'band 12 and is stuck enfre the upper face 36 of the intermediate bundle of rods 22 forming the intermediate stop 32, and the outward portion 16 extending enfre the upper distal rod bundle 20 and the upper proximal rod bundle 21. The end winding 25 is applied against the intermediate stop 32 under the effect of the longitudinal tension of the strip 12. The rod bundles 20, 21 , 22 are adapted so that the spaces between the distal stops 23, 33, and the proximal stops 24, 34, allow the passage of the outward portion 16 and the return end portion 17 of the strip 12, but prohibit the passage of the end winding 25 between these distal stops 23, 33, and proximal 24, 34. The rod bundles 20, 21, 22, and therefore the distal stops 23, 33, proximal 24, 34, and intermediate 32, extend between the two lat plates Rales 19 crossed by these beams 20 to 22, the side plates 19 holding the different beams in position relative to each other, and therefore the different stops relative to each other, at least in the longitudinal direction of the strip 12. The side plates 19 are provided with reinforcements 26a, 26b,

27 in excess thickness adapted so as not to prevent the passage of the strip 12 through the locking flange 13 and to reinforce the inertia and the resistance of the side plate in the longitudinal direction of the strip 12 in order to avoid any bending, buckling, tearing, of the side plate 19. These reinforcements 26a, 26b, 27 are provided on each of the faces of the plates 19. Two upper reinforcements 26a, 26b , namely a distal upper reinforcement 26a and a proximal upper reinforcement 26b- extend in the upper part of the side plate 19 and are spaced from each other so as to provide a cavity allowing the insertion of the end winding 25 encloses them. A lower reinforcement 27 is provided under the intermediate rod bundle 22. Each of the reinforcements 26a, 26b, 27 is fixed to the plate 19 according to a plurality of fixing points by bolts, rivets or studs 28, 29.

Each bundle of rods 20 to 22 may be formed from a winding of a plurality of turns of a wire of material with high shear resistance, in particular of a steel wire of the piano string type. As can be seen in FIG. 3, the different rods forming a same bundle at the level of a locking flange 13 thus extend at least substantially parallel to one another. Such a bundle of rods follows the shape of the openings in the side plates 19 in which they are engaged, but this shape may undergo some modifications or variants depending on the relative forces applied in torsion to the bundle. To manufacture each of these bundles 20 to 21, it is possible to proceed as shown for example in FIG. 6. From a coil 30 of the metal wire, the free end of the wire is passed through the openings opposite the different side plates 19, then, after passing around idler rollers 31, this free end is brought back to join it to the wire at the outlet of the coil 30 so as to form a starting loop forming the first turn. The side plates 19 of the anchoring device are brought together in groups against each other upstream of the deflection rollers 31. The deflection rollers 31 being motorized, the reel 30 is unwound by winding the wire as and when around the deflection rollers and through the slots in the plates 19 until a suitable number of turns is obtained. The wire is then cut to length and it is dissociated from the deflection rollers 31 to obtain annular bundles. We thus produces the different beams 20 to 22, then the different side plates 19 are distributed on the periphery of the different annular beams.

It should be noted that in place of the various bundles of rods 20 to 22, the distal, proximal and intermediate stops can be formed by simple rigid metal strips.

The amanage element 11 may also be formed similarly by resistant son, especially metal son or any other synthetic material with very high toughness (KENLAH ^{®, ®} DYΝEEMA 'NECTRAΝ ^® ...) with a sleeve external protection which is gathered axially to allow the production of the various turns forming this anchoring element 11, then deployed around the turns, over the entire periphery of the anchoring element 11.

The distal 23, 33, proximal 24, 34, and intermediate 32 stops thus have a generally curved transverse cross section free of sharp edges at least in the sector intended to come into contact with the strip 12. The intermediate stop 32 has a contact face 36 with the end winding 25, and this contact face 36 is located wholly or at least in part (in a variant not shown where it would be curved convex), on the same side as the outward portion 16 of the strip 12 relative to a plane 37 tangent to the two distal 33 and proximal 34 stops in contact with the outward portion 16. In this way, the tension exerted on the strip 12 applies the end winding 25 against this intermediate stop 32 .

Another alternative embodiment of the abutments is shown in FIG. 8 which combines bundles of upper distal 50, proximal upper 51, and intermediate 52 rods passing through the longitudinal slots 54 of the semi-cylindrical chambers 53 nested one inside the other. Each oven 54 has a length corresponding to the distance between two side plates 19, has a male end 55 and a female end 56. Two adjacent oven 54 are in axial extension of one another, the male end 55 being engaged in the female end 56 with sufficient play to allow relative movements in bending corresponding to the curvature to be given to the device anchor 10 and to the anchoring element 11, a flexible elastic joint 57 being interposed between the two furnaces at the crossing of the side plates 19.

The annular drive element 11, and the annular beams or bananas forming the distal 23, 33, proximal 24, 34, and intermediate 32 annular stops are of the same axis of symmetry, and this axis of symmetry corresponding to the axis of symmetry of the central cylinder 5 and the balloon 2.

The various locking flanges 13 are applied against the drive element 11 by means of a protective pad 38 made of shock-absorbing material, in particular rubber. This pad 38 can be formed by an annular pad provided with slots for the insertion of the proximal edges of the different side plates 19. It therefore has not only the function of forming a contact stop for each blocking flange 13 against the element. amanage 11, but also to maintain the different side plates 19 at a distance from each other, the proximal edge 39 of each side plate 19 being engaged in one of the slots of the annular pad 38.

Each locking flange 13 comprises a rigid core 40 adapted to receive the end winding 25. This rigid core 40 extends along the width of the strip 12, and preferably has a transverse cross section of oblong shape, with a convex curved outline free of sharp edges. The rigid core 40 also has a recess 41 formed hollow in its lower face 42 oriented towards the contact face 36 of the intermediate stop 32, to receive the end hem 15 of the strip 12. This recess 41 is offset on the proximal side, that is to say on the side of the proximal stops 24, 34. In addition, the rigid core 40 has a thickness greater than the distance separating the two distal stops 23, 33 from one another , and also greater than the distance separating the two proximal stops 24, 34 from one another. In this way, it is ensured that the end winding 25 cannot pass into the space separating the distal stops 23, 33, or into the space separating the proximal stops 24, 34. To set up and anchor the 'outer casing 4 with an anchoring device 10 according to the invention, the procedure is as follows. First of all, the different bands 12 are cut at the end of the envelope 4. The different bands 12 are gathered and the hems 15 are produced. Furthermore, the anchoring device 10 itself is produced. , that is to say the actuating element 11 and the various locking flanges 13 with their distal, proximal and intermediate stops as described above.

Each of the bands 12 is then associated with a corresponding locking flange 13. To do this, the free end 14 of the strip 12 is passed successively between the distal stops 23, 33, then between the stops

^• 10 proximals 24, 34, then around the anchoring element 11, then again between the proximal stops 24, 34, and the free end 14 of the strip 12 is released.

(Figure 7a) to make the end winding 25 around the core 40. Once this winding 25 made around the core 40 (Figure 7b), insert the core

40 and the winding 25 between the distal and proximal stops, and between the stop

15 intermediate 32 and the forward portion 16 of the strip 12 previously passed through the blocking flange 13. The strip 12 and its forward portion 16 are made to slide until the blocking flange 13 comes into contact with the element of amanage

11 by means of the buffer 38. The networks 8, 9 are then connected to the locking flange 13. It should be noted in this regard that the upper reinforcements 26 of the

20 side plates 19 have anchor points 43, 44 for the cables of the networks 8, 9 upper and lower.

The end winding 25 having a total thickness greater than the distance separating the two distal stops 23, 33, and also greater than the distance separating the two proximal stops 24, 34, this winding 25 cannot be escape when a traction, even of very great value, is exerted on the strip 12. The end winding 25 is moreover preferably carried out in a winding direction adapted so that the tension of the outward portion 16 of the strip 12 tends to wind this end winding 25 on itself. In other words, if we follow the return end portion 17 from the drive element 11, this return end portion 17 comes into contact with the outward portion 16 before coming into contact with the face 36 of the intermediate stop 32. Advantageously, each strip 12 has a width of between 1 cm and 10 cm, and the same applies to the locking flanges 13. Each strip 12 is also produced so that it comprises longitudinal fibers having a rate of elasticity before breakage of less than 3%.

Claims

1 / - Device for anchoring a ply (4) of flexible material to an element, known as an anchoring element (11), having a curved cross-section free of sharp edges on at least one angular sector greater than 180 ° opposite to a direction in which the ply (4) is intended to extend, this anchoring element (11) being adapted to retain at least one loop (18) formed by at least one strip (12) of at least at least one layer of the ply (4), this device comprising at least one locking flange (13) of a loop (18) formed around the drive element (11) by a strip (12) of at least at least one layer of the ply (4) having a free end (14), this device being characterized in that each locking flange (13) comprises:

- a pair of stops, called distal stops (23, 33),

- a pair of stops, called proximal stops (24, 34), - at least one stop, called an intermediate stop (32),

- Means (19) for assembling the distal (23, 33), proximal (24, 34) and intermediate (32) stops adapted so that:

. the distal stops (23, 33) are spaced from each other by a distance allowing the passage between them of a thickness of the strip (12),

. the proximal stops (24, 34) are spaced from each other by a distance allowing the passage between them of two thicknesses of the strip (12) forming the loop (18), the proximal stops (24, 34) being closer to the drive element (11) than the distal stops (23, 33),. the intermediate stop (32) is arranged between the two pairs of distal (23, 33) and proximal (24, 34) stops, so that an end winding (25) of the strip (12) can be formed with a portion, called the end return portion (17) of the strip (12), extending between the drive element (11) and the free end (14) of the strip (12), and that this end winding (25) can be wedged between this intermediate stop (32) and a portion, called the forward portion (16), formed by the strip (12) from the distal stops (23, 33) to the proximal stops (24, 34), this one-way portion (16) being extended towards the anchoring element (11) by the loop (18) and the return end portion (17),

. the distal (23, 33), proximal (24, 34) and intermediate (32) stops are arranged in relation to each other so that:

- the end winding (25) is applied against the intermediate stop (32) under the effect of a longitudinal tension of the strip (12),

- the end winding (25) cannot escape, neither between the distal stops (23, 33), nor between the proximal stops •

(24, 34).

2 / - Device according to claim 1, characterized in that the assembly means (19) comprise two rigid side plates (19) integral spaced from one another by a distance corresponding to the width of the strip ( 12) to allow the passage of the strip (12) between the side plates (19), and in that the distal (23, 33), proximal (24, 34) and intermediate (32) stops extend between the two side plates (19) in which they are engaged, so that the side plates (19) hold the stops (20 to 24) in position relative to each other at least in the longitudinal direction of the strip (12).

3 / - Device according to claim 2, characterized in that it comprises a side plate (19) interposed between each pair of adjacent strips (12).

4 / - Device according to one of claims 2 and 3, characterized in that each locking flange (13) comprises means (38) of rigid association of the two side plates (19) one relative to the other at least in a direction parallel to the width of the strip (12).

5 / - Device according to one of claims 2 to 4, characterized in that the side plates (19) are provided with reinforcements (26a, 26b, 27) in excess thickness adapted to not prevent the passage and engagement of the band (12) in the locking flange (13). 6 / - Device according to one of claims 1 to 5, characterized in that the intermediate stop (32) has a contact face (36) with the end winding (25) which is located at least in part of the same side as the outward portion (16) of the strip (12) relative to a tangent plane (37) to the two distal (20) and proximal (21) stops in contact with this outward portion (16) of the strip (12 ).

7 / - Device according to one from claims 1 to 6, characterized in that the distal (23, 33), proximal (24, 34) and intermediate (32) stops have a generally convex cross section free of sharp edges at least in their sector intended to come into contact with the strip (12).

8 / - Device according to one of claims 1 to 7, characterized in that at least one distal (23, 33) and / or proximal (24, 34) and / or intermediate (32) stop is formed of a rigid straight or curved strip. 9 / - Device according to one of claims 1 to 8, characterized in that at least one distal (21, 23) and / or proximal (24, 34) and / or intermediate (32) stop is formed of a bundle (20, 21, 22) of rods - in particular of the piano strings type.

10 / - Device according to one of claims 1 to 9, characterized in that at least one distal stop (23, 33) and / or proximal (24, 34) and / or intermediate (32) is formed of a bundle of rods (50, 51, 52) engaged in an axial slot of a semi-cylindrical barrel (53).

11 / - Device according to one of claims 1 to 10, characterized in that the intermediate stop (32), one (23) of the distal stops and one (24) of the proximal stops are all three formed of one and the same bane or one and the same bundle of rods (22, 52), and in that the other distal stop (33) and the other proximal stop (34) are formed by rods or rod bundles (20, 21, 50, 51) separate.

12 / - Device according to one of claims 1 to 11, characterized in that it comprises several adjacent locking flanges (13) for several loops (18), and in that at least one of the distal stops ( 23, 33), proximal (24, 34) or intermediate (32) of the different locking flanges (13) is formed by a single bane or a single bundle of rods (20, 21, 22, 50, 51, 52) which extends in relation to the different bands (12) of the sheet

(4).

13 / - Device according to one of claims 1 to 12, characterized in that the drive element (11) being annular, the beams or strips forming the distal stops (23, 33), proximal (24, 34) and intermediate (32) are annular and of the same axis of symmetry.

14 / - Device according to one of claims 1 to 13, characterized in that each locking flange (13) comprises a rigid core (40) adapted to receive the end winding (25).

15 / - Device according to claim 14, characterized in that the rigid core (40) has a recess (41) formed in a hollow adapted to receive a hem (15) end of the strip (12).

16 / - Device according to claim 15, characterized in that the housing (41) is formed on one face (42) of the rigid core (40) oriented towards the intermediate stop (32), and offset from the side of the proximal stops (24 , 34).

17 / - Device according to one of claims 14 to 16, characterized in that the rigid core (40) has a thickness greater than the distance separating the two distal stops (23, 33) from one another, and greater than the distance separating the two proximal stops (24, 34) from one another.

18 / - Device according to one of claims 1 to 17, characterized in that each locking flange (13) has a width between 1cm and 10cm.

19 / - Device according to one of claims 1 to 18, characterized in that it comprises means (38) forming a contact stop for each locking flange (13) against the drive element (11).

20 / - Device according to claims 2 and 18, characterized in that the means (38) forming a contact stop against the actuating element (11) comprise at least one protective pad (38) interposed between the proximal edges ( 39) side plates (19) of each locking flange

(13) and the amanage element (11). 21 / - Method for anchoring a sheet (4) of flexible material to an element, known as an anchoring element (11), having a cross-section of curved shape free of sharp edges on at least one upper angular sector at 180 ° opposite to a direction in which the ply (4) is intended to extend, this actuating element (11) being adapted to retain at least one loop (18) formed by at least one strip (12) d '' at least one layer of the sheet (4), in which:

- at least one loop (18) is formed around the anchoring element (11), with at least one strip (12) of at least one layer of the ply (4) having a free end (14),

- each loop (18) is blocked using a blocking flange (13), characterized in that:

- the free end (14) of the strip (12) is passed successively between a pair of stops, called distal stops (23, 33), of the locking flange (13), then between a pair of stops, said stops proximal (24, 34), of the blocking flange (13), closer to the drive element (11) than the distal stops (23, 33), so that a portion, called the forward portion (16 ), is formed by the strip (12) between the distal stops (23, 33) and the proximal stops (24, 34), then around the drive element (11), then again between the proximal stops ( 24, 34), so as to form the loop (18) around the anchoring element (11) with a portion, called the end return portion (17) of the strip (12) between the element amanage (11) and the free end (14) of the strip

(12), - an end winding (25) of the strip (12) is then produced with the end return portion (17), and this end winding (25) is inserted and wedged between a stop, called intermediate stop (32), of the blocking flange (13) and the outward portion (16) of the strip (12), and in that a blocking flange (13) is used, the distal stops of which ( 23, 33), proximal (24, 34) and intermediate (32) are assembled and arranged with respect to each other so that:

. the loop (18) and the end winding (25) can thus be produced,

. the end winding (25) is applied against the intermediate stop (32) under the effect of a longitudinal tension of the strip (12),. the end winding (25) cannot escape either between the distal stops (23, 33), or between the proximal stops (24, 34).

22 / - Method according to claim 21, characterized in that the end winding (25) is produced with a total thickness greater than the distance separating the two distal stops (23, .33). 23 / - Method according to one of claims 21 and 22, characterized in that the end winding (25) is produced with a total thickness greater than the distance separating the two proximal stops (24, 34).

24 / - Method according to one of claims 21 to 23, characterized in that one carries the end winding (25) around a rigid core (40).

25 / - Method according to claim 24, characterized in that a hem (15) is produced at the end of the strip (12) which is placed in a housing (41) formed hollow in the rigid core ( 40).

26 / - Method according to claim 25, characterized in that the rigid core (40) is placed with the housing (41) oriented towards the intermediate stop (32).

27 / - Method according to one of claims 24 to 26, characterized in that a rigid core (40) of thickness greater than the distance separating the two distal stops (23, 33) is used, one of the other, and greater than the distance separating the two proximal stops (24, 34) from one another.

28 / - Method according to one of claims 21 to 27, characterized in that the end winding (25) is carried out in a winding direction suitable for the tension of the outward portion (16) of the strip (12) - tends to wind the end winding (25) on itself. 29 / - Method according to one of claims 21 to 28, characterized in that the sheet (4) of flexible material is cut into a plurality of strips (12) in a direction at least substantially perpendicular to one of its end edges, and in that with each strip (12) a loop (18) is formed around the anchoring element (11) which is blocked with a flange blocking (13) and an end winding (25) of this strip (12).

30 / - Method according to one of claims 21 to 29, characterized in that a longitudinal gathering of each strip (12) is carried out before forming the loop (18) and blocking it.

31 / - Method according to one of claims 21 to 30, characterized in that the strip (12) is positioned in the blocking flange (13) so that the blocking flange (13) abuts against the 'amanage element (11).

32 / - Method according to one of claims 21 to 32, characterized in that a device according to one of claims 1 to 20 is used.