DEVICE AND METHOD FOR MOULDING AND CONSOLIDATING A TEXTILE PREFORM

Abstract

A device to cure/consolidate a textile preform pre-impregnated with polymer. A matrix, without any heating or cooling means, includes a molding face that reproduces the shape of the textile preform and an assembly interface. A sealed bagging of the preform on the matrix. A vacuum pump to apply vacuum inside the sealed bag having the textile preform. A thermal unit includes an induction heater and a receiving interface that cooperates with the matrix assembly interface to position the matrix and to transfer heat between the matrix and the thermal unit.

Claims

1-10. (canceled)

11. A device to cure/consolidate a textile preform pre-impregnated with polymer, comprising: a matrix, without any heater or cooler, comprising a molding face that reproduces a shape of the textile preform and an assembly interface; a sealed bagging comprising the textile preform on the matrix; a vacuum pump to apply vacuum inside the sealed bagging comprising the textile preform; and a thermal unit, comprising an induction heater and a receiving interface that cooperates with the matrix assembly interface to position the matrix and to transfer heat between the matrix and the thermal unit.

12. The device according to claim 11, wherein the thermal unit comprises a cooler.

13. The device according to claim 11, comprising a sealed enclosure and an assembly to lock the sealed enclosure on the matrix; and a pump to raise pressure inside the sealed enclosure.

14. The device according to claim 12, wherein the thermal unit comprises a support comprising the receiving interface and a heating interface; a thermal accumulator, heated using the induction heater; and wherein the thermal accumulator expands to bring the thermal accumulator in contact with the heating interface to transmit heat from the thermal accumulator to the support.

15. The device according to claim 14, wherein the thermal accumulator comprises a phase changing material.

16. The device according to claim 14, wherein the cooler comprises channels to circulate a heat-transfer fluid in the support.

17. The device according to claim 16, wherein the cooler comprises conduits to circulate the heat-transfer fluid around the thermal accumulator.

18. The device according to claim 14, wherein the heating interface comprises a conformation sheet.

19. The device according to claim 11, wherein the matrix assembly interface comprises a conformation sheet.

20. A method of curing or consolidating a textile preform pre-impregnated with polymer, implementing the device according to claim 13, comprising steps of: bagging the textile preform laid up on the matrix; applying a vacuum to inside of the sealed bagging; transferring the matrix and the sealed bagged textile preform on the thermal unit; and applying a thermal cycle of curing and consolidation to the textile preform by regulating a temperature of the textile preform by heating and cooling the thermal unit.

21. The method according to claim 20, between the steps of transferring and applying, comprising a step of increasing the pressure in the sealed enclosure.

Description

[0031] The invention is described below in its preferred embodiments, which are not limitative in any way, by reference to FIG. 1, representing sectional views of the device according to the invention in an embodiment that brings together all the optional characteristics of the device. FIG. 1A shows the cooling phase and FIG. 1B shows the heating phase.

[0032] In this exemplary embodiment, the device according to the invention comprises a matrix (110) on which a textile preform (100) is laid up, which preform consists in a layered structure of fibrous plies pre-impregnated with thermosetting or thermoplastic polymer. Said preform (100) is bagged on the matrix (110) by means of a vacuum cover (120), using sealing means (121) so that the space between the matrix (110) and the vacuum bag comprising the preform (100) is sealed. In this exemplary embodiment, the matrix (110) comprises conduits (111) opening into said space, which conduits are connected to a vacuum pump (not shown) so as to apply a vacuum to that space. A sealed enclosure (130) that enfolds the preform is locked to the matrix by appropriate assembly means (132). Said enclosure comprises a conduit (132) connected to a pump in order to increase the pressure in said enclosure. Thus, this upper assembly comprising the matrix (110), the bagging means and the sealed enclosure constitutes an independent assembly that makes it possible to implement the pressure cycle corresponding to the consolidation/curing of the textile preform.

[0033] The thermal consolidation/curing cycle of the textile preform is brought about by placing the upper assembly on a thermal unit, which thermal unit comprises, in this embodiment: [0034] a support (140) made of material with high thermal conductivity, for example an aluminum alloy; [0035] a base (150) preferably made of refractory material that is transparent to magnetic field, for example concrete or ceramic; [0036] a thermal accumulator (160) made of material that is suitable for induction heating.

[0037] The base comprises an induction circuit comprising one or more inductors (151) circulating in cavities made in said base, and connected to a high-frequency current generator, typically ranging between 10 kHz and 100 kHz.

[0038] The support (140) comprises channels (141) for the circulation of a heat-transfer fluid that can cool said support. The matrix is connected to the support (140) by means of an interface with a standard profile, so that a plurality of upper assemblies corresponding to the same shape or different shapes can be positioned on the thermal unit. The matrix assembly surface, which positions said matrix on the receiving surface of the support (140), advantageously comprises a conformation sheet (112). Said conformation sheet is for example brazed on the assembly surface of the matrix and is made of material that shows high thermal conductivity but is malleable, such as copper or nickel, so that said conformation sheet makes up for slight differences in shape between the assembly surface of the matrix and the receiving surface of the support (140).

[0039] On the side opposite the receiving side, the support comprises a heating surface that is liable to come in contact with the thermal accumulator. Advantageously, the heating surface comprises a conformation sheet (142), brazed to said heating surface, and suitable for compensating for slight differences in shape between said accumulator (160) and the heating surface of the support (140). In FIG. 1A, in the absence of heating, the accumulator (160) is not in contact with the heating surface. However, said accumulator (160) is however maintained at a temperature known as the holding temperature through inductors. The contact resistance between the accumulator (160) and the heating surface is high and thermal transfer between the thermal accumulator (160) and the support (140) is small.

[0040] In FIG. 1B, when heating is in progress, the temperature of the accumulator is increased, so that it is thermally dilated and comes in contact with the heating surface of the support (140). The contact resistance drops, and the thermal accumulator transfers its heat to the support. Said thermal accumulator (160) does not have a structural function in the device according to the invention.

[0041] Its composition is thus selected to optimize its response to induction heating and its capacity to transfer its heat to the support (140).

[0042] In one particular embodiment, detail Z, said accumulator has a cellular structure, where each cell (165) is filled with phase-change material with latent transition heat. Advantageously, the phase-change material is selected so that its transition temperature is close to the holding temperature of the thermal accumulator. As an example, if the holding temperature is of about 200 C., the phase-change material is for instance organic material such as a polyol. If the holding temperature is higher, for example about 400 C. or more, the phase-change material is for example a salt. In these examples, the phase-change material changes from the solid state at a low temperature to a liquid state at a higher temperature by absorbing latent transition heat. As it changes from the high-temperature phase to the low-temperature phase, the phase-change material solidifies and gives back said latent transition heat. The combination of the cellular structure and the presence of phase-change material makes it possible to increase the apparent thermal inertia of the thermal accumulator (160) when it is maintained at the holding temperature, while retaining the ability to rapidly heat up to the heating temperature.

[0043] The matrix, and therefore the preform, are cooled by circulating heat-transfer fluid in the channels (141) of the support. Advantageously, the base (150) comprises conduits (152) for the supply of heat-transfer fluid around the thermal accumulator (160) so as to speed up cooling to the holding temperature after the phase of heating and maintaining the matrix at the required temperature.