Installation and a method for needling a fiber preform while controlling the contact pressure of the stripper

Abstract

A needling installation includes a rotary support on which a fiber texture is wound to form a fiber preform, the rotary support being mounted on a frame that is movable along a second axis Y perpendicular to the first axis X; a stripper including one plate including perforations; a needling module having a needle board carrying needles; a contact force application system connected to the stripper; a contact force sensor for providing information representative of the contact force with which the outside face of the plate of the stripper makes contact against the fiber preform, and a controller to control the contact force application system to apply a force to the plate of the stripper that is predetermined as a function of information provided by each contact force sensor and as a function of a target value for a predetermined contact force.

Claims

1. A needling installation comprising: a rotary support extending along a first axis X and on which a fiber texture can be wound so as to form a fiber preform for a body of revolution, the rotary support being mounted on a frame that is movable along a second axis Y perpendicular to the first axis X; a stripper comprising at least one plate extending at least along the first axis X and including a plurality of perforations, the plate presenting an inside face and an outside face, the outside face being present beside the rotary support; a needling module having a needling head and a needle board carrying a plurality of needles, the needle board facing the inside face of the plate of the stripper, the needles being in alignment with the perforations present in the plate of the stripper, the needling head having a drive system configured to drive the needle board to impart reciprocating motion to the needles along the second axis Y relative to said plate of the stripper; a contact force application system connected to the stripper; at least one contact force sensor for providing information representative of a contact force with which the outside face of the plate of the stripper makes contact against the fiber preform; and a controller that is configured to control the contact force application system so as to apply a force to the plate of the stripper that is predetermined as a function of information provided by each contact force sensor and as a function of at least one target value for a predetermined contact force.

2. The installation according to claim 1, wherein the stripper is connected to the needling head by arms, each including an oleopneumatic actuator, at least one of the arms further including a contact force sensor.

3. The installation according to claim 1, wherein a target value for a contact force lies in the range 10 N to 1000 N.

4. The installation according to claim 1, wherein the needling module is configured to move along the first axis X.

5. The installation according to claim 1, wherein the outside face of the plate of the stripper presents concave curvature.

6. The installation according to claim 1, wherein the contact force application system includes a plurality of oleopneumatic actuators configured to cause the outside face of the plate of the stripper to apply the contact force against the exposed face of a fiber preform for needling.

7. The installation according to claim 1, wherein the drive system includes a plurality of pistons configured to drive the needle board.

8. A method of needling a fiber preform in a needling installation including a rotary support extending along a first axis X and on which a fiber texture is wound so as to form a fiber preform for a body of revolution, the rotary support being mounted on a frame that is movable along a second axis Y perpendicular to the first axis N; a stripper comprising at least one plate extending at least along the first axis X and including a plurality of perforations, the plate presenting an inside face and an outside face, the outside face being present beside the rotary support; a needling module having a needling head and a needle board carrying a plurality of needles, the needle board facing the inside face of the plate of the stripper, the needles being in alignment with the perforations present in the plate of the stripper, the needling head having a drive system configured to drive the needle board to impart reciprocating motion to the needles along the second axis Y relative to said plate of the stripper; a contact force application system connected to the stripper; and at least one contact force sensor for providing information representative of the force with which the outside face of the plate of the stripper makes contact against the fiber preform, the method comprising: putting the outside face of the plate of the stripper into contact with the exposed face of the fiber preform and needling said preform; and controlling the contact force applied by the plate of the stripper on the fiber preform, by controlling the contact force application system so as to apply a force to the plate of the stripper that is predetermined as a function of information provided by each contact force sensor and as a function of at least one value for a predetermined contact force.

9. The method according to claim 8, wherein the stripper is connected to the needling head by arms, each including an oleopneumatic actuator, at least one of the arms further including a contact force sensor.

10. The method according to claim 8, wherein a target value for a contact force lies in the range 10 N to 1000 N.

11. The method according to claim 8, wherein the needling module is configured to move along the first axis X.

12. The method according to claim 8, wherein the outside face of the plate of the stripper presents concave curvature.

13. The method according to claim 8, wherein the contact force application system includes a plurality of oleopneumatic actuators configured to cause the outside face of the plate of the stripper to apply the contact force against the exposed face of a fiber preform for needling.

14. The method according to claim 8, wherein the drive system includes a plurality of pistons configured to drive the needle board.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention can be better understood on reading the following description given by way of non-limiting indication and with reference to the accompanying drawings, in which:

(2) FIGS. 1 and 2 are diagrammatic perspective views of a needling installation in an embodiment of the invention;

(3) FIGS. 3A and 3B are plan views of the FIG. 2 needling installation showing the needles of the needling head respectively in a retracted position and in a deployed position;

(4) FIG. 4 is a diagram of a regulator loop used in the needling installation of the invention; and

(5) FIG. 5 is a diagrammatic perspective view of a needling installation in another embodiment of the invention.

DETAILED DESCRIPTION

(6) FIGS. 1 and 2 are diagrams showing a needling installation 100 in accordance with an embodiment of the invention. The installation 100 comprises a stationary frame 101 having a carriage platform 110 mounted thereon. The carriage platform 110 stands on rails 102 and is connected to an actuator 103, in this example a motor with a wormscrew, serving to move the carriage platform 110 along an axis Y that is parallel to the rails 102. The installation 100 also has a rotary support or mandrel 113 carried on a rotary spindle (not shown in FIGS. 1 and 2) and supported by two spindle holders 111 and 112, at least one of which includes a motor (FIG. 1) for driving the mandrel 113 in rotation in the direction represented by arrow SR in FIGS. 1 and 2. The spindle holders 111 and 112 are fastened on the carriage platform 110. A fiber texture 10 in the form of a strip is wound progressively onto the mandrel 113 so as to constitute a fiber preform 20 that is in the form of a body of revolution once it has been needled.

(7) The installation 100 also has a needling module 120 constituted by a needling head 121 fastened on a needling frame 104, itself fastened on the stationary frame 101, a needle board 122 mounted on the needling head and carrying a plurality of needles 123, and a stripper 130. The stripper 130 comprises at least one plate 131 extending at least along an axis X perpendicular to the axis Y and including a plurality of perforations 1310, the plate 131 having an inside face 131a and an outside face 131b, the outside face 131b being present beside the mandrel 113.

(8) As shown in FIGS. 3A-B and 4, the stripper 130 is connected to the needling head 121 by a first arm 140 including an actuator 141 and a second arm 150 including an actuator 151. In the presently-described example, the actuators 141 and 151 are oleopneumatic actuators. As explained below, the actuators 141 and 151 constitute a contact force application system for causing the outside face 131b of the plate 131 of the stripper 130 to apply a contact force against the exposed face 20a of a fiber preform 20 for needling.

(9) The needle board 122 faces the inside face 131a of the plate 131 of the stripper 130, the needles 123 being in alignment with the perforations 1310 present in the plate 131 of the stripper. The needling head 121 includes a drive system configured to drive the needle board, which drive system is constituted in the presently-described example by two pistons 124 and 125 serving to move the needle board 122, and consequently the needles 123 so they perform reciprocating or back-and-forth motion M along the axis Y relative to the plate of the stripper. During actuation of the pistons 124 and 125, the needles 123 pass in alternation from a retracted position in which they do not project from the outside surface 131b of the plate 131 of the stripper 130 (FIG. 3A) to a deployed position in which they project from the outside face 131b of the plate 131 in order to penetrate into the fiber preform 20 to a determined depth (FIG. 3B).

(10) In the presently-described example, the needle board 122 carries a plurality of rows of needles 123 arranged one above another along an axis Z (FIG. 1), each row of needles extending over a determined width along the axis X. The perforations 1310 present in the plate 131 of the stripper are arranged in corresponding manner so as to be in alignment with the needles 123, i.e. over a plurality of rows that are located one above the other along the axis Z, and in each row, they are arranged over a determined width along the axis X. Nevertheless, the needle board could equally well have only one row of needles, with the arrangement of the perforations present in the plate of the stripper being adapted accordingly.

(11) In accordance with an embodiment of the invention, the needling installation 100 is also suitable for controlling the contact force application system so that the plate of the stripper applies a force that is predetermined as a function of force measurement information and of at least one target value for a predetermined contact force. For this purpose, the installation includes at least one contact force sensor or compression force sensor suitable for providing information that is representative of the force with which the outside face of the plate of the stripper is making contact against the preform. In the presently-described example, the first arm 140 connecting the plate 131 of the stripper to the needling head 121 includes a first contact force sensor 142 interposed between the actuator 141 and the needling head 121, the sensor 142 in this example corresponding to a digital load cell, while the second arm 150 connecting the plate 131 of the stripper to the needling head 121 includes a second contact force sensor 152 interposed between the actuator 151 and the needling head 121, the sensor 152 in this example corresponding to a digital load cell.

(12) The needling installation includes a control device or controller having a calculation system or any known programmable device (not shown in FIGS. 1, 2, 3A, or 3B). As shown in FIG. 4, the calculation system or the like are programmed to implement a regulator loop that receives firstly a signal Ic corresponding to information representative of the contact force between the outside face of the plate of the stripper and the preform, the signal Ic being delivered in this example by the contact force sensors 142 and 152, and secondly a signal Ec corresponding to a target value for a predetermined contact force. The calculation system determines the difference between the signal Ic and the signal Ec. If the value of the signal Ic is greater than the value of the signal Ec, then the calculation system performs correction and generate a control signal Sc for the actuators 141 and 151, which respond to this signal by reducing the contact force between the plate of the stripper and the exposed face of the preform in order to reach the target value for the contact force. If the value of the signal Ic is less than the value of the signal Ec, then, after performing correction, the calculation system generates a control signal Sc for the actuators 141 and 151, which respond to this signal by increasing the contact force between the plate of the stripper and the exposed face of the preform in order to reach the target value for the contact force. Finally, if the value of the signal Ic is equal to the value of the signal Ec, then the calculation means generate a zero control signal Sc, which leads to no modification to the contact force applied by the actuators 141 and 151. The target value of a contact force between the outside face of the plate of the stripper and the exposed face of the fiber preform may lie in the range 10 N to 1000 N.

(13) In an embodiment, the calculation system includes various hardware components for performing its intended functions. In addition or alternatively, the calculation system may also include a non-transitory computer readable medium encoded with machine-readable instructions for performing the above-described operations.

(14) At the beginning of needling the preform 20, the carriage platform 110 is moved forwards, i.e. towards the needling module 120, so as to place the exposed face 20a of the fiber preform 20 in contact with the outside face 131b of the plate 131 of the stripper 130 (FIG. 2). Under such circumstances, the regulator loop of FIG. 4 is activated, and this continues until the end of needling, during which the carriage platform 110 is regularly moved rearwards, i.e. away from the needling module 120, in order to adjust the positioning of the stripper plate relative to the fiber preform 20, which is of thickness that increases progressively as the fiber texture 10 is wound onto the mandrel 113.

(15) According to an optional characteristic of the invention, the needling module 120 is suitable for moving along the axis X (FIGS. 1 and 2). The needling module may be moved along the axis X by moving the needling frame 104 on which the needling module 120 is fastened, the frame 104 being mounted by way of example on rails that are fastened on the stationary frame 101 (not shown in FIGS. 1 and 2). The needling module 120 may also be mounted on the needling frame 104 via an actuator device (not shown in the FIGS. 1 and 2) enabling the module 120 to be moved relative to the frame 104 along the axis X. The movement or the needling module 120 along the axis X serves in particular to needle the entire width of a fiber preform should it present a width that is greater than the zone covered by the needles of the needling head in the direction of the axis X.

(16) FIG. 5 shows another embodiment of a needling installation 200 that differs from the above-described needling installation in that the outside face of the plate of the stripper presents concave curvature. More precisely, and as shown in FIG. 5 and as applies likewise for the above-described installation 100, the installation 200 comprises a needling module 220 constituted by a needling head 221, a needle plate 222 mounted on the needling head and carrying a plurality of needles 223, and a stripper 230. The stripper 230 comprises a plate 231 extending at least along a perpendicular axis X and including a plurality of perforations 2310, the plate 231 presenting an inside face 231a and an outside face 231b, the outside face 231b being present beside a mandrel 213 having a fiber texture 30 wound thereon in order to form a needled preform 40. In this embodiment, the outside face 231b of the plate 231 of the stripper presents concave curvature. This concave curvature enables it to fit more closely to the shape of the fiber preform 40 and consequently to improve the contact between the outside face 231b of the plate 231 of the stripper 230 and the exposed face 40a of the fiber preform 40. The concave curvature of the outside face of the stripper plate preferably presents a radius of curvature that is similar to the radius of curvature of the portion of the mandrel 213 that the plate faces.

(17) With a plate 231 that presents an outside face 231b with concave curvature, the size of the needles 223 is adapted depending on their position on the needle plate 222 along the axis Z in order to ensure a uniform penetration depth for the needles in the thickness of the preform, the needles being longer in the vicinity of the bottom and top ends 222a and 222b of the needle plate 222 along the axis Z than the needles present in the vicinity of the middle portion 222c of the needle plate along the axis Z.

(18) The other elements of the needling installation 200 are identical to those of the above-described installation 100 and they are not described herein once more for reasons of simplification.

(19) A system other than oleopneumatic actuators could be used for adjusting the contact force between the outside face of the plate of the stripper and the exposed face of the preform. In particular it is possible to use hydraulic or electrical actuators. Likewise, sensors other than load cells could be used for measuring the contact force or the compression force between the outside face of the plate of the stripper and the exposed face of the preform. In particular, sensors using strain gauges or pressure probes could be used.