FR3137691A1 - Braiding machine with spindles with removable support - Google Patents

Abstract

Braiding machine with spindles with removable support The invention relates to a braiding machine comprising: - a plurality of spindles (30) for supplying wire connected to guide supports (51) and movable along a path of guidance (100) so as to participate in braiding, all or part of the spindles (30) being integral with a positioning element (35) cooperating with a corresponding guide support (51) and removable relative to the latter, - a plurality of reserve supports (52) located outside the guide path (100), said reserve supports (52) being adapted to receive spindles (30) for feeding wire placed in reserve so as to interrupt their participation in braiding, the positioning elements (35) being able to cooperate with the reserve supports (52) to achieve this reserve. Figure for abstract: Fig. 1

Description

Braiding machine with spindles with removable support

The present invention relates to braiding machines allowing the production of braided structures, and more particularly braided tubular structures having strong variations in section.

A braiding machine conventionally comprises a plate having circuits, called guide paths, which intersect each other and along which yarn feed spindles connected to a drawing point of the machine are moved. These thread feed spindles therefore intersect regularly to create a braid. Generally speaking, the formation of the braid can be carried out on a form, called a conformation mandrel, which moves during the formation of said braid: we then speak of “over-braiding”. The movement of the spindles along the guide paths is conventionally carried out by means of notched wheels driven in rotation and preferably arranged in one or more concentric circles. Such braiding machines are for example described in documents FR 2 804 133 and US 8 347 772.

When we wish to manufacture a braided structure having strong variations in section with a machine of the prior art, we note that the braided structure obtained does not have uniform braiding. Indeed, in the areas of the braid having a large section, the density of wires is lower or even insufficient, or the angles between the braided wires are greater, in comparison with the areas of the braid of smaller section.

The present invention aims to remedy the aforementioned drawbacks by proposing a braiding machine capable of producing a uniform braided structure despite strong variations in section. For this purpose, the invention proposes a braiding machine comprising:

- a plurality of wire feed spindles connected to guide supports and movable along a guide path so as to participate in braiding, all or part of the spindles being integral with a positioning element cooperating with a support corresponding and removable guide relative to the latter,

- a plurality of reserve supports located outside the guide path, said reserve supports being able to receive wire feed spindles placed in reserve so as to interrupt their participation in braiding, the positioning elements being able to cooperate with the reserve media to achieve this reserve.

Thus, the use of spindles capable of cooperating with movable guide supports along the guide path makes it possible to easily remove or add spindles to the braiding, without requiring complex operations such as dismantling the plate of the braiding machine.

Such a system of cooperation between the positioning elements and the guide supports therefore makes it possible to easily vary the number of wire supply spindles participating in the braiding of the braided structure. Thus, the number of bobbins participating in the braiding can be adapted to the section of the structure to be braided in order to obtain a constant thread density and angle values between the threads despite variations in section.

Thus, when it is desired to reduce the section of the braided structure, spindles are removed from the guide path in order to interrupt their participation in braiding, by separating the positioning elements of said spindles from the guide supports. The number of braided wires is therefore reduced, which makes it possible to avoid a notable increase in the density of wires, or even an undesired reduction in the angles between the braided wires, at the level of the area of smaller section. On the contrary, when it is desired to increase the section of the braided structure, spindles are added to the main guide path, by mounting the positioning elements of said spindles with the guide supports present on the guide path. We therefore increase the number of braided wires, which makes it possible to avoid a notable reduction in the density of wires, or even an undesired increase in the angles between the braided wires, at the level of the area of lower section. The braiding weave therefore remains identical and uniform throughout the braided structure thus obtained.

The use of reserve supports makes it possible to easily store the spindles in a reserve area, in particular the spindles which have been removed from the guide path in order to interrupt their participation in the braiding, and/or the spindles which are intended to be added on the guide path to participate in braiding.

According to a particular embodiment of the invention, the machine comprises a reserve support drive system capable of driving at least part of the reserve supports circumferentially to the guide path.

The reserve supports go around the outer edge of the guide path, or go around the inner edge of the guide path.

The use of a reserve zone comprising at least one movable part in rotation circumferentially to the guide path makes it possible to limit the appearance of singularities in the braiding. Indeed, when a spindle has just been removed from the guide path in order to interrupt participation in the braiding of the thread coming from said spindle, the thread coming from said spindle is still in the process of intertwining. When the thread is being intertwined, it is neither braided and tightened with the other threads, nor free. There is therefore a transition stage in which the thread no longer participates in the braiding, but is still in the process of intertwining, so that part of the thread is completely braided and tightened with the other threads, part of the thread is being intertwined and part of the thread is free. This transition stage ends when the part of the thread which was being intertwined is completely braided and tightened with the other threads, that is to say that the thread only includes a completely braided and tightened part, and a free part that is not braided and not intertwined.

If the spindle removed from the guide path is directly positioned on a fixed reserve support in relation to the movable guide supports, the wire coming from said spindle is suddenly stopped while it may be in the process of intertwining, this which can lead to unwanted tensions in the threads or to singularities in the braiding. In order to support the thread during the transition stage, that is to say when it is still in the process of intertwining while it no longer participates in braiding, the spindle from which said thread comes can be positioned on a mobile reserve support. Said mobile reserve support thus makes it possible to extend the movement of the spindle in the clockwise or counterclockwise direction, until at least the end of the transition stage. When the transition step is completed, the movement of the movable reserve support can be interrupted, the spindle can be moved to a fixed part of the reserve zone and/or the thread coming from said spindle can be cut.

According to another particular embodiment of the invention, the drive system for the reserve supports comprises at least a first ring circumferential to the guide path and capable of rotating in a first direction of rotation and at least a second ring circumferential to the guide path and capable of rotating in a second direction of rotation opposite to the first direction of rotation, each first or second crown carrying one or more reserve supports.

The first and second rings surround the outer edge of the guide path, or go around the inner edge of the guide path.

Thus, it is possible to simultaneously support in their transition stage threads from spindles which rotated clockwise on the guide path and threads from spindles which rotated counterclockwise.

According to another particular embodiment of the invention, the reserve supports are present around the guide path.

By placing the reserve zone, and any circumferential reserve rings, on the periphery of the guide path, we facilitate access to the spindles present in the reserve zone.

According to another particular embodiment of the invention, the machine further comprises a shaping mandrel on which the braiding is intended to be carried out.

The presence of a shaping mandrel makes it easier to braid the structure, the shape of the shaping mandrel providing support on and around which the wires can be braided with the desired section.

According to another particular embodiment of the invention, the machine comprises an overall drive system comprising the reserve support drive system and a guide support drive system, the overall drive system being configured so that the angular speed of at least part of the reserve supports is a function of the angular speed of at least part of the guide supports so that the movement of at least part of the reserve supports accompanies the movement of 'at least part of the guide supports.

According to another particular embodiment of the invention, the overall drive system comprises a transmission system configured to transmit the movement of a guide support drive system to the reserve support drive system.

Preferably, the drive system of the reserve supports is a rack and pinion system. Preferably, the guide support drive system is a system of notched wheels driven in rotation by a gear train. Preferably, the transmission system is a belt system connecting the gear train of the guide support drive system to the pinion/rack system of the reserve support drive system. Indeed, this overall drive system has the advantage of being robust and allowing high braiding speeds.

According to another particular embodiment of the invention, the machine further comprises a robotic arm configured to move at least one spindle between a guide support and a reserve support.

According to another particular embodiment of the invention, the machine further comprises a cutting device configured to cut a wire coming from a feed spindle whose positioning element cooperates with a reserve support.

The invention also relates to a method for braiding a braided structure comprising a first zone having a first section and a second zone having a second section different from the first section, the method using a machine according to the invention and comprising:

- braiding the first zone of the braided structure with a first number of wire feed spindles movable along the guide path, and

- braiding the second zone of the braided structure with a second number of wire feed spindles movable along the guide path, the second number of spindles being different from the first number of spindles thanks to the movement of spindles between the supports guide and the reserve supports by cooperation of the positioning element of said spindles moved with the guide or reserve supports.

There is a three-dimensional view of a braiding machine according to the invention.

There is a top view detail of the braiding machine of the .

There is an exploded schematic view of a spindle cooperating with a guide support.

There is a schematic view of the mechanisms of operation of the braiding machine of Figures 1 and 2.

There is a schematic view of the machine of Figures 1 and 2 during braiding of a part of braid of large section.

There is a schematic view of the machine of Figures 1 and 2 during braiding of a portion of braid of progressive section.

There is a schematic view of the machine of Figures 1 and 2 during braiding of a portion of braid of small section.

Figures 1 and 2 schematically illustrate an example of a braiding machine according to the invention making it possible to produce a braided structure.

The braiding machine comprises a plate 1 and a plurality of wire feed spindles 30. The plate 1 is preferably horizontal, in order to facilitate its maintenance and that of the wire feed spindles 30. However, we do not leave the framework of the invention if the plate 1 is vertical or inclined.

The plate 1 comprises a braiding zone 10. The braiding zone 10 comprises a guide path 100 and a plurality of guide supports 51 capable of cooperating with said guide path 100, and therefore capable of moving along the path guide 100. Preferably, the guide path 100 is machined in the mass of the plate 1 in the form of grooves, having for example a substantially rectangular section, open towards the outside, and inside which the supports move guide 51.

Each guide support 51 comprises a guide face 51a and a mounting face 51b opposite the guide face 51a. The guide face 51a is capable of cooperating with the guide path 100. In particular, the guide face 51a of the guide support 51 comprises a projecting relief configured to move inside the groove of the guide path 100 Preferably, all the guide supports 51 present in the braiding zone 10 are identical.

Preferably, the braiding machine comprises a conforming mandrel 5, which is a shape on which the intertwined threads come to rest to form the tight braid. In this case, the braiding machine makes it possible to carry out so-called “over-braiding” processes. The braiding machine according to the invention is particularly interesting in the case where it is desired to produce a braid having significant variations in section, and more precisely a braid whose perimeter of the section varies significantly. Unless otherwise stated, the sections are taken perpendicular to a longitudinal axis of the braided structure. Consequently, the advantages provided by the braiding machine according to the invention are particularly remarkable when said braiding machine comprises a conformation mandrel 5 whose shape has strong variations in thickness.

The braiding machine further comprises at least one drawing point located at a distance from the plate 1, and to which the wires coming from the supply spindles 30 movable along the guide path 100 are connected.

The braiding machine also includes a reserve zone 20 circumferential to the braiding zone 10, which comprises a plurality of reserve supports 52. In the example illustrated in Figures 1 and 2, the reserve zone 20 is present around the outer edge of the braiding zone 10, which allows easier access to said reserve zone 20. However, we do not depart from the scope of the invention if the reserve zone 20 goes around the inner edge of the braiding zone braiding 10. Preferably, the reserve zone 20 is located in the same plane as the braiding zone 10. Preferably, the reserve zone 20 is adjacent to the guide path 100.

The reserve zone 20 is presented here in the form of several circumferential and concentric rings 21, 22, 23. Each crown 21, 22, 23 comprises at least one reserve support 52. Each reserve support 52 comprises a mounting face 52b. Preferably, all the reserve supports 52 present in the reserve zone 20 are identical.

As illustrated on the , each wire supply spindle 30 comprises a holding portion 34 intended to accommodate a spool of wire, extended by a positioning element 35. The positioning element 35 is integral with the spindle 30. The positioning element 35 is configured to cooperate with the guide supports 51 and with the reserve supports 52. In particular, the positioning element 35 comprises a mounting face 35b opposite the holding portion 34, which is configured to cooperate with the mounting face 51b of the guide supports 51 and with the mounting face 52b of the reserve supports 52.

In particular, the mounting face 35b of the positioning element 35 may comprise a groove, and the mounting faces 51b and 52b of the guide supports 51 and reserve 52 may comprise a projecting relief, the groove of the mounting face 35b of the positioning element 35 being configured to cooperate with the projecting relief of the mounting faces 51b and 52b of the guidance supports 51 and 52. The reverse is also possible.

Thus, each spindle 30 can be mounted on a guide support 51, by making the mounting face 35b of said spindle 30 cooperate with the mounting face 51b of said guide support 51, and can be mounted on a reserve support 52, in causing the mounting face 35b of said spindle 30 to cooperate with the mounting face 52b of said reserve support 52. Preferably, all the spindles 30 can be mounted on all the guide supports 51 and on all the reserve supports 52. Preferably , the mounting faces 51b of the guide supports 51 and the mounting faces 52b of the reserve supports 52 are identical.

The spindles 30 mounted on the guide supports 51 in the braiding zone 10 can participate in braiding, that is to say that the thread or threads coming from the bobbins of said spindles 30 mounted on the guide supports 51 can be braided. Thus, the spindles 30 mounted on the guide supports 51 are movable along the guide path 100.

The guide path 100 is configured to be traveled in a first direction of rotation, for example in the clockwise direction, by a first plurality of spindles 30 and in a second direction of rotation, for example in the counterclockwise direction, by a second plurality of bobbins 30 in order to carry out the braiding. Thus, a first plurality of guide supports 51 is configured to be movable at least in the clockwise direction and a second plurality of guide supports 51 is configured to be movable at least in the counterclockwise direction.

In the example illustrated in Figures 1 and 2, the guide path 100 comprises two sub-guide paths 110 and 120 which intersect regularly, the first sub-guide path 110 being configured to be traversed by the first plurality of guide supports 51 on which the first plurality of spindles 30 are mounted and the second sub-path 120 being configured to be traversed by the second plurality of guide supports 51 on which the second plurality of spindles 30 are mounted. of course not within the scope of the invention if the guide path comprises more than two sub-paths, for example if one wishes to produce a braided structure comprising several layers or having a complex binding weave, such as for example interlock braiding .

The braiding machine according to the invention comprises in a well-known manner a system for driving the guide supports 51. Preferably and in a well-known manner, the braiding zone 10 of the plate 1 comprises a plurality of notched wheels 11 configured to be rotated in order to circulate the wire feed spindles 30 along the guide path 100, as illustrated in Figures 1 and 2. Each notched wheel 11 preferably comprises four notches. The notched wheels 11 are preferably rotated in a well-known manner via gear trains controlled by one or more motors, the gear trains being preferably located on the face of the plate 1 opposite the face comprising the guide path 100 and the notched wheels 11. For example, the reserve area 20 does not include notched wheels, and the reserve supports 52 are not driven by notched wheels.

The braiding machine according to the invention preferably comprises a system for driving the reserve supports 52, capable of driving at least part of the reserve supports 52 circumferentially to the guide path 100. In the example illustrated in Figures 1 at 4, the rotation drive system of the reserve supports 20 comprises at least one circumferential ring 21, 22 movable in rotation circumferentially to the braiding zone 10, that is to say movable in rotation along the inner edge or exterior of the guide path 100. The reserve zone 20 further preferably comprises at least one fixed circumferential ring 23.

Preferably, the reserve zone 20 comprises at least a first circumferential ring 21 movable in a first direction of rotation, for example movable in the clockwise direction, and at least one second circumferential ring 22 movable in a second direction of rotation opposite to the first direction of rotation, for example movable counterclockwise.

The first circumferential ring(s) 21 movable in the clockwise direction can accompany the movement of the first plurality of guide supports 51 movable on the guide path 100 in the clockwise direction, and consequently the movement of the first plurality of spindles 30 mounted on the first plurality of guide supports 51 and therefore movable clockwise. Consequently, if one wishes to remove from the braiding a spindle 30 movable in the clockwise direction to place it in the reserve zone 20, for example to produce a portion of the braided structure of smaller section, but without risking that the wire from said movable spindle 30 does not create a singularity in the braiding or an undesired tension, it is possible to arrange said spindle 30 on the first crown 21 movable in the clockwise direction by making the positioning element 35 of said spindle 30 cooperate with a reserve support 52 present on the first crown 21. Thus, the thread coming from said spindle 30 will remain mobile in the clockwise direction in order to accompany the end of its braiding to the braided structure in progress, even if the spindle 30 has been removed from the braiding area and no longer participates in braiding.

Comparably, the second circumferential ring(s) 22 movable in the counterclockwise direction can accompany the movement of the second plurality of guide supports 51 movable on the guide path 100 in the counterclockwise direction, and consequently the movement of the second plurality spindles 30 mounted on the second plurality of guide supports 51 and therefore movable in the counterclockwise direction. Consequently, if one wishes to remove from the braiding a spindle 30 movable in the counterclockwise direction to place it in the reserve zone 20, for example to produce a portion of the braided structure of smaller section, but without risking that the wire from said movable spindle 30 does not create a singularity in the braiding or an undesired tension, it is possible to arrange said spindle 30 on the second movable crown 22 in the counterclockwise direction by making the positioning element 35 of said spindle 30 cooperate with a reserve support 52 present on the second crown 22. Thus, the thread coming from said spindle 30 will remain mobile in the counterclockwise direction in order to accompany the end of its braiding to the braided structure in progress, even if the spindle 30 has been removed from the braiding area and no longer participates in braiding.

Thus, preferably, the movable circumferential crowns 21 and 22 are preferably intended to accommodate the spindles 30 temporarily and for a short duration, before said spindles 30 are arranged on the fixed crown(s) 23 for a longer duration. . The movable circumferential crowns 21 and 22 then correspond to a transition zone between the braiding zone 10 and the fixed parts of the reserve zone 20. Preferably, the arrangement of a spindle 30 on one of the movable crowns 21, 22 is therefore only provisional, for a duration preferably corresponding to the duration necessary for the thread coming from said spindle, which is in the process of intertwining with the other threads at the moment when said spindle is removed from the braiding zone, is entirely braided to the braided structure to be created. This greatly reduces the risk of singularities in the final braided structure.

As illustrated in the example of , the machine according to the invention preferably comprises an overall drive system which comprises on the one hand the drive system 71 of the guide supports 51 and on the other hand the drive system 73, 74, 76, 21 , 22 of the reserve supports 52.

In the example illustrated in Figures 1 to 4, the rotation drive system of the movable crowns 21 and 22, which belongs to the reserve support drive system 52, can be mechanically linked to the rotation drive system notched wheels 11, which belongs to the drive system of the guide supports 51. For example, as illustrated in the , the rotational drive system 71 of each notched wheel 11, preferably in the form of gears, is connected by a belt 72 to a pinion 73 belonging to the reserve zone 20. The movable crowns 21, 22 comprise each a circumferential rack 74, 76 actuated directly or indirectly by the pinion 73. Thus, in the example illustrated on the , the movement of the drive system 71 of the guide supports 51 is transmitted to the drive system 21, 22, 73, 74, 76 of the reserve supports 52 by means of a movement transmission system in the form of 'a belt 72.

Preferably, in order to further limit the risk of singularity in the braiding following a change in the number of spindles 30 participating in the braiding, the overall drive system is configured so that the angular speed of at least part of the braid supports reserve 52 is a function of the angular speed of at least part of the guide supports 51, so that the movement of at least part of the reserve supports 52 accompanies the movement of at least part of the guide supports 51. Preferably, the angular speed of at least part of the reserve supports 52 is equal to the angular speed of at least part of the guide supports 51, that is to say that at least part of the supports reserve 52 travels the same angular extent relative to the central axis of the machine as at least part of the guide supports for a given duration. The central axis of the machine can be defined for example as the axis passing through the draw point or through the center of the shaping chuck of the machine, and passing through the center of the main guide path. The angular velocity is expressed in radians per second and the angular extent in radians, the reference center being a point on the central axis of the braiding machine.

Thus, at least part of the guide supports makes a complete turn along the guide path 100 when at least part of the guide supports 51 makes a complete turn of the guide path 100.

In the example illustrated in Figures 1 to 4, the movable rings 21, 22 make a complete revolution around the guide path 100 when at least part of the spindles 30 make a complete revolution of the guide path 100. Thus, the spindles 30 present on the first crown 21 movable in the clockwise direction follow the movement of the spindles 30 movable in the clockwise direction on the guide path 100, and the spindles 30 present on the second crown 22 movable in the counterclockwise direction follow the movement spindles 30 movable in the counterclockwise direction on the guide path 100. The reduction ratio between the rotation of the notched wheels 11 and the rotation of each circumferential ring 21, 22 must therefore preferably correspond to half the value of the number of notched wheels 11 per circumferential row. In the example illustrated on the , the braiding machine comprises a single row of notched wheels 11 comprising sixteen notched wheels 11. Thus, the value of the reduction ratio between the rotation of each gear 71 of said notched wheels 11 and the rotation of the rack 74, 76 of each movable crown 21, 22 will be eight.

The transfer of the spindles 30 between the braiding zone 10 and the reserve zone 20, or between the different parts or circumferential crowns 21, 22, 23 of the reserve zone 20, can be carried out manually or by one or more robotic arms 8 including a hooking and unhooking clip. These robotic arms 8 are for example fixed around the braiding zone 10 and the reserve zone 20.

The braiding machine can also include a cutting system 9 configured to cut the threads coming from the spindles 30 arranged in the reserve zone 20, and in particular the threads coming from the spindles 30 arranged in the fixed parts of the reserve zone 20, in order to avoid any risk of entanglement of one of the threads not participating in braiding with the threads participating in braiding.

We will now describe in relation to schematic figures 5 to 7 an example of a braiding process according to the invention for producing a braided structure 300 having significant section variations, and more precisely significant variations in the perimeter of the section. . Thus, the braided structure 300 to be produced comprises in its length a first zone having a first section perimeter, a transition zone, and a second zone having a second section perimeter, the second perimeter being different from the first perimeter. In the example illustrated in Figures 5 to 7, the first perimeter is greater than the second perimeter and the transition zone presents a section whose perimeter decreases regularly between the first zone and the second zone.

In the example illustrated in Figures 5 to 7, the braiding is carried out on a conformation mandrel 5 which generally has the shape of the braided structure 300 to be produced. Of course, we do not go beyond the scope of the invention if the braiding is not carried out on a conforming mandrel. The threads from the spools of the thread feed spindles are attached to a pulling point.

We begin by producing the first zone of the braided structure 300 by circulating a first number of thread supply spindles 30 along the guide path 100, inside the braiding zone 10. Thus, the threads 31 from the coils carried by this first number of spindles 30 intertwine around the conforming mandrel 5 so as to produce the first zone of the braided structure 300, as illustrated in the .

In order to produce the transition zone of the braided structure 300 whose perimeter of the section decreases while maintaining a density of threads and angles between the threads similar to the density of threads and the angles between the threads of the first zone of the braided structure 300, wire supply spindles 30 are gradually taken out of the braiding zone 10 to put them in the reserve zone 20. Thus, these supply spindles 30 are removed from the guide path 100 manually, or from automatic way. Preferably, as illustrated in the , a robotic arm 8 as described above grasps a spindle 30 to be removed from the guide path 100 and separates it from the guide support 51 on which it was mounted by separating the positioning element 35 of said spindle 30 from the mounting surface 51b of the guide support 51. Then, the robotic arm 8 moves the spindle 30 towards the reserve zone 20, to mount it with one of the reserve supports 52 present in the reserve zone 20 by assembling the positioning element 35 of said spindle 30 with the mounting face 52b of said reserve support 52.

In the example illustrated on the , in order to produce the transition zone then the second zone of the braided structure 300, the robotic arms 8 gradually remove part of the spindles 30 movable in the clockwise direction on the guide path 100 and part of the spindles 30 movable in the direction counterclockwise on the guide path 100. The spindles 30 movable in the clockwise direction which are removed are then arranged on the reserve supports 52 of the first crown 21 movable in the clockwise direction and the spindles 30 movable in the counterclockwise direction which are removed are then arranged on the reserve supports 52 of the second crown 22 movable in the counterclockwise direction. When a part of the spindles 30 is arranged on the movable crowns 21 and 22, the threads 32 coming from said spindles 30 arranged on the movable crowns 21 and 22 no longer participate in the braiding but are in a transition stage, that is to say say that they are still in the process of intertwining with other threads without yet being completely braided and tightened. The rotation of the movable crowns 21, 22 makes it possible to accompany this transition step of the threads 32 coming from the spindles 30 coming out of the guide path 100 and the braiding zone 10.

When the thread 32 coming from a spindle 30 placed on a movable ring 21 or 22 has completed the transition step, that is to say it is no longer in the process of intertwining, the spindle 30 can be removed from the movable crown 21 or 22 to be placed on the fixed circumferential crown 23, manually or automatically. Preferably, as illustrated in the , the robotic arm 8 grasps a spindle 30 to be removed from a movable crown 21 or 22 and separates it from the reserve support 52 on which it was mounted by separating the positioning element 35 of said spindle 30 from the mounting surface 52b of the reserve support 52. Then, the robotic arm 8 moves the spindle 30 towards the fixed crown 23, to mount it with one of the reserve supports 52 present on said fixed crown 23 by assembling the positioning element 35 of said spindle 30 with the mounting face 52b of said reserve support 52 of the fixed crown 23. The wires 33 coming from the spindles arranged on the fixed crown 23 can be cut by the cutting device 9, in order to avoid any risk of tangling of the one of the wires 33 not participating in braiding with the wires 31 participating in braiding.

When the braiding of the transition zone of the structure 300 is completed, there remains only a second number of spindles 30 movable along the guide path 100, inside the braiding zone 10. In the example illustrated in Figures 5 to 7, the second number of movable spindles 30 is less than the first number of movable spindles 30 during braiding of the first zone.

The second number of spindles 30 movable on the guide path 100 then makes it possible to braid the second zone of the braided structure 300, the wires 31 coming from the coils carried by this second number of spindles 30 intertwining around the conforming mandrel 5 as illustrated on the to create the braided structure 300.

In a variant not illustrated, it is possible to produce a braided structure having in its length a first zone having a first section perimeter, a transition zone and a second zone having a second section perimeter, as in the example illustrated in the figures 5 to 7, but further comprising a second transition zone and a third zone having a third section perimeter. The third perimeter of the third section is here greater than the second perimeter of the second section, and may also be less than or greater than the first perimeter of the first section. We do of course not depart from the scope of the invention if the third section perimeter is less than the first and second section perimeters.

In this variant, the first zone, the transition zone and the second zone are produced as described previously. In order to produce the second transition zone of the braided structure, located in the extension of the second zone and whose perimeter of the section increases, while maintaining a density of threads and angles between the threads similar to the density of threads and at the angles between the threads of the first zone and the second zone already braided, spindles supplying threads present in the reserve zone are gradually transferred to the braiding zone to make them participate in braiding.

Thus, these supply spindles are removed from the fixed crown of the reserve zone manually, or automatically. Preferably, a robotic arm as described above grasps a spindle to be removed from the fixed crown and separates it from the reserve support on which it was mounted by separating the positioning element of said spindle from the mounting surface of the reserve support. Then, the robotic arm moves the spindle towards one of the movable parts of the reserve zone, to mount it with one of the reserve supports present on the first or the second movable crown by assembling the positioning element of said spindle with the mounting face of said reserve support. In our variant example, in order to create the second transition zone then the third zone of the braided structure, the robotic arms place part of the spindles present on the fixed crown on the movable crown in the clockwise direction and part of the spindles present on the fixed crown on the movable crown counterclockwise.

When the threads coming from the spindles positioned on the movable crowns accompany the movement of the threads during braiding, the robotic arm(s) gradually move the spindles arranged on the movable crown in a clockwise direction on the guide sub-path(s) traveled by guide supports in the clockwise direction, and the spindles arranged on the movable ring in the counterclockwise direction on the guide sub-path(s) traversed by the guide supports in the counterclockwise direction, by mounting the positioning element of said spindles with the mounting faces of said guide supports not carrying spindles. Thus, the threads coming from the spindles mounted on the guide supports participate in the braiding.

The prior passage of the thread supply spindles over moving parts of the reserve zone before their participation in braiding makes it possible to facilitate the introduction into the braiding of the threads from said added spindles.

When the braiding of the second transition zone of the structure is completed, there is therefore a third number of spindles, greater than the second number of spindles, movable along the guide path, inside the braiding zone.

The third number of mobile spindles on the guide path then makes it possible to braid the third zone of the braided structure, the threads coming from the spools carried by this third number of spindles intertwining around the shaping mandrel.

The term “yarn” used in the present application can designate a single thread or a single fiber, but can also designate a wick or a braid.

In particular, the threads may be carbon fibers, ceramic fibers, or a mixture of carbon fibers and ceramic fibers. The braided structure according to the process of the invention can be a fibrous structure, which could possibly be consolidated or densified by a matrix in order to form the fibrous reinforcement of a part made of composite material. The braided structure according to the process of the invention can thus form, for example, all or part of the fibrous reinforcement of a part made of composite material for the automobile, aeronautics or space industries. In particular, the braided structure obtained could form, for example, the fibrous reinforcement of a divergent or a rocket engine nozzle.

The braided structure according to the process of the invention can also allow the formation of straps or ropes.

Claims (10)

Braiding machine including:
- a plurality of wire feed spindles (30) connected to guide supports (51) and movable along a guide path (100) so as to participate in the braiding, all or part of the spindles (30) being integral with a positioning element (35) cooperating with a corresponding guide support (51) and removable relative to the latter,
- a plurality of reserve supports (52) located outside the guide path (100), said reserve supports (52) being capable of receiving spindles (30) for feeding wire placed in reserve so as to interrupt their participation in braiding, the positioning elements (35) being able to cooperate with the reserve supports (52) to achieve this reserve. Machine according to claim 1, said machine comprising a drive system (73, 74, 76, 21, 22) of the reserve supports (52) capable of driving at least part of the reserve supports (52) circumferentially to the path of guidance (100). Machine according to claim 2, in which the drive system (73, 74, 76, 21, 22) of the reserve supports (52) comprises at least a first crown (21) circumferential to the guide path (100) and capable to rotate in a first direction of rotation and at least one second crown (22) circumferential to the guide path (100) and capable of rotating in a second direction of rotation opposite to the first direction of rotation, each first or second crown (21, 22) carrying one or more reserve supports (52). Machine according to any one of claims 1 to 3, in which the reserve supports (52) are present around the guide path (100). Machine according to any one of claims 2 to 4, said machine comprising an overall drive system comprising the drive system (73, 74, 76, 21, 22) of the reserve supports (52) and a system of drive (71) of the guide supports (51), the overall drive system being configured such that the angular speed of at least a part of the reserve supports (52) is a function of the angular speed of at least one part of the guide supports (51) so that the movement of at least part of the reserve supports (52) accompanies the movement of at least part of the guide supports (51). Machine according to claim 5, wherein the overall drive system comprises a transmission system (72) configured to transmit movement of a drive system (71) from the guide supports (51) to the drive system ( 73, 74, 76, 21, 22) of the reserve supports (52). Machine according to any one of claims 1 to 6, said machine further comprising a shaping mandrel (5) on which the braiding is intended to be carried out. Machine according to any one of claims 1 to 7, said machine further comprising a robotic arm (8) configured to move at least one spindle (30) between a guide support (51) and a reserve support (52). Machine according to any one of claims 1 to 8, said machine further comprising a cutting device (9) configured to cut a wire (32, 33) coming from a feed spindle (30) whose positioning (35) cooperates with a reserve support (52). Method for braiding a braided structure (300) comprising a first zone having a first section and a second zone having a second section different from the first section, the method using a machine according to any one of claims 1 to 9 and including:
- braiding the first zone of the braided structure (300) with a first number of wire feed spindles (30) movable along the guide path (100), and
- braiding the second zone of the braided structure (300) with a second number of wire feed spindles (30) movable along the guide path (100), the second number of spindles being different from the first number of spindles thanks to the movement of spindles (30) between the guide supports (51) and the reserve supports (52) by cooperation of the positioning element (35) of said spindles moved with the guide supports (51) or reserve (52).