FR2679487A1 - Process for continuous manufacture of long profiles (sections) made of composite materials using a hot (heating) die and device for the implementation of the process - Google Patents

Abstract

A pregelling tunnel (8) heated to a temperature theta 1 by resistance heating elements (resistors) (9) is followed by at least one preforming diaphragm, and, following this zone, there is provision for a long hot die (12) housed inside a polymerisation tunnel (13) heated to a temperature theta 2 by resistance heating elements (14), the said tunnel being followed by a post-curing tunnel placed upstream of the mechanism for driving the polymerised profile. Application to the manufacture of long strips made of composite material.

Description

Process for the continuous production of profiles of very long composite materials by a heating die and device for carrying out the process.

 The invention which is situated in the field of the manufacture of composite materials relates more precisely to a process for the continuous production of profiles of very long length, in particular using a heating die, as well as the device and installation for implementing said process.

 To produce wires or rods in composite material, it is well known to use pultrusion techniques by which we know how to calibrate a material by passing it through a die of precise internal section. In some cases, a profiled die is used formed from a simple thin diaphragm, through which a wick of fibers is pulled by force to be calibrated after impregnation in a resin bath. In other cases the wire thus prepreg is wound on a mandrel of rectangular section so that each prepreg rectilinear cord stretched on one side of the mandrel can after polymerization and cutting constitute a composite rigid rod. These discontinuous manufacturing methods best provide profiles of short length and are not adaptable to industrial applications seeking to produce profiles, calibrated with the greatest precision, and of great length. Indeed, the known techniques do not allow the reproducibility of forming and section since the gelling of the material is carried out discontinuously and is not strictly carried out identically from one operation to another. In addition, these known techniques impose numerous manual interventions linked to a frequent stuffing of small fibers or fibrils at the inlet of the dies, and which require significant cleanings imposing the stopping of the machine and causing a loss of time in particular to replace the thread in the die. In addition, with the diaphragm dies, the profiles obtained are not perfectly regular, and can be flattened or deformed. This is due to - among other things - an irregular polymerization ~ of the resins used.

 Pultrusion techniques consisting in calibrating a profile through a die, by pulling said profile, have made it possible to improve the products obtained. It is known that a pultrusion bench generally consists of a station for continuously unwinding dry wires, followed by a tank for impregnating composite material with resin, said material then being moved by a traction mechanism in continuous inside a heating die which ensures the shaping of the product and its polymerization.

A cutting device for cutting the profile to length is finally provided at the end of this bench. Such continuous production by this pultrusion technique, however, requires a passage time in the heating die, which is relatively large if one wishes to obtain a complete and correct polymerization of the resin and without deformation of the profile, for example without twisting, and this is done at the expense of production speed. In addition, the die is insufficient to ensure the total elimination of volatile products from the resin. Finally, the existence of a single forming die does not completely eliminate the stuffing, at the entry, of fibrils of composite material.

 These drawbacks have led the Applicant to imagine a new process for manufacturing composite material, based on this pultrusion technique which makes it possible to produce rods of long composite material, perfectly homogeneous, and calibrated with precision, rods which can be of section relatively weak and thus suitable as a basic constituent for the production of a woven composite material, for example of the three-dimensional type.

 A first object of the present invention therefore consists in a process for the continuous production of profiles of composite materials of very long length by pultrusion using a heating die ensuring the shaping and the polymerization of oriented filaments and prepregs of resin, which are drawn to the end of the production line by a drive system and then cut to be put to the correct length, a process which involves passing the resin prepreg filaments through a first resin pregelling zone for the initiation of the Exothermic reaction, then in a preforming zone for the dewatering of the excess resin, before passing through the polymerization zone essentially consisting of a long heating die for the calibration and the forming of the profile, and at then passing said profile through a post-baking zone which completes its polymerization.

 According to particular features of the invention, steps are taken to bring the resin which impregnates the filaments from a state of viscosity T \ A to a state of viscosity Nc in the first pregelling zone during which the chemical reaction, and it also ensures that the polymerization in the zone of the heating die is ensured by the pultrusion of the material through said die and by the additional energy supply of the exothermic reaction of the resin used.

 Another particular object of the invention consists in ensuring the complete polymerization of the profile in the last quarter of the heating die, in a narrow forming zone corresponding to an equally narrow viscosity range.

 According to another main characteristic of the invention, the device for implementing said manufacturing process essentially consists of a pregelling tunnel brought to a temperature e1 by heating resistors, which is followed by at least one preforming diaphragm, device according to which, after this zone is provided a heating die housed inside a polymerization tunnel brought to a temperature 62 by heating resistors, said tunnel being followed by a post-baking tunnel heated by heating resistors , arranged upstream of the drive mechanism of the polymerized profile.

 Advantageously, the long heating die of the polymerization tunnel is an external metal tube ensuring mechanical strength, enclosing a sheath of polytetrafluoroethylene bonded to said tube, the internal section of which is profiled to the shape of the product to be obtained, said tube being equipped with stops.

 On the other hand the drive mechanism consists of several pairs of rollers, each lower roller is a drive roller bearing against an upper roller, the drive rollers being driven in rotation by a drive belt.

Other particular characteristics and advantages of the invention will appear on reading the description which follows of exemplary embodiments, in which reference is made to the appended drawings which represent
Figure 1 a schematic sectional view of a manufacturing facility by pultrusion
Figure 2 a partially cutaway perspective view of the drive mechanism
Figure 3, a schematic elevational view of the mounting of a curvature sensor
Figures 4 and 5 of the evolution curves of the polymerization process
Figure 6 a schematic view on a larger scale of a heating die.

 The pultrusion manufacturing installation shown diagrammatically in FIG. 1 comprises at the start of the chain a plurality of coils 2 for the emission of several dry wires 1 which are grouped together on a distribution pulley 3, which collects and directs the wires in one single homogeneous sheet 4. The sheet 4 then enters a impregnation tank 5 filled with a resin 6 and after passing over another pulley 3, it passes through a wringing die 7. The next station is constituted by a tunnel of pre-gelation 8 of a length L1, brought to a temperature eî using the heating resistors 9. At the exit of this first heating zone 8, the ply 4 crosses a preforming zone consisting of one or more preforming diaphragms 11. Further on, the sheet reaches a long heating die 12 housed inside a polymerization tunnel 13 with a length L2, brought to a temperature 62 using the heating resistors. es 14.

This polymerization zone is followed by a postcuring zone of length L3 also consisting of a tunnel 15 heated by the resistors 14 to perfect the polymerization of the profile. The sheet which has become the profile 23 is pulled into these various zones by a drive mechanism 16 which exerts on it a tensile force.
FR oriented in the direction of the arrow. Finally a cutting system 17, located at the end of the production line distributes profile segments to the desired length. The preforming zone 11 mentioned above may consist of a tray receiving several polytetrafluoroethylene diaphragms drilled to different diameters.

These diaphragms ensure the dewatering of the excess resin and participate in the preforming of the profile and in its longitudinal orientation.

 The long heating die 12 of the polymerization tunnel 13 is advantageously in the form of an external metal tube, for example made of copper, which provides mechanical resistance and thermal transmission, enclosing an extruded sheath of polytetrafluoroethylene bonded to the tube, which promotes sliding. of the profile. The internal section of the sheath is shaped to the shape of the product to be obtained. The tube is fitted with stops to avoid its untimely movement in the furnace 13 when the ply 4 is pulled.

 As a variant, these polymerization 13 and postcooking zones 15 could be produced by two independent ovens powered by separate heating modes which can provide different temperatures.

 The drive mechanism 16 is shown in more detail in Figure 2. I1 consists of three pairs of rollers 18 each of which lower roller 18a is a drive roller bearing against an upper roller 18b. The profile 23 is pinched between the rollers, a toothed drive belt 19 ensuring their rotation by means of a motor not shown. The rollers are mounted in a drive housing 20 and they are provided with a mechanism for adjusting their mutual contact pressure. For this purpose, and advantageously the housing 20 is in two parts, an upper part carrying the rollers 18b and a lower part carrying the rollers 18a, screws making it possible to bring the two parts more or less together to adjust the bearing pressure of the rollers . It is understood that this plurality of drive rollers promotes traction without slipping and without deformation of the profile. It will be noted that the tensile force FR applied to this profile is variable as a function of the resistance to advancement exerted by the ply when it passes through the diaphragms and the long heating die. To ensure this force control, a curvature sensor 21 is used - represented in FIG. 3 which comes to bear on the profile 23 between the aftercook tunnel 15 and the drive rollers 18. The sensor 21 is a grooved wheel 24 having a certain mass secured to the axis of a straight potentiometer 22. The deflection taken by the profile, that is to say the vertical travel of the potentiometer depends on the tensile force FR exerted and on the tension of the profile . This traction force-tension control is important because in the context of the continuous operation of this installation, it makes it possible to avoid blockages of the sheet.

 The resin polymerization process in said installation, which depends on time t and temperature 0, varies abruptly from a critical point specific to each resin. The temperature O depends on the amount of heat provided by the heating systems 9, 14 and by the exothermic polymerization reaction of the resin. This exothermic reaction is a chemical reaction which varies abruptly and occurs from a critical point specific to each resin. FIG. 4 illustrates the evolution of this polymerization process, the curves of which, for different temperatures, of the variation of the coefficient of dynamic viscosity n due to the resin have been represented, as a function of time t, knowing that Ti = f (6 , t). A first zone I of descent of the curves corresponds to the initiation phase of the reaction which takes place by the passage of wire impregnated with resin in the pregelification tunnel 8. This first heating phase makes it possible to initiate the chemical reaction by bringing about the resin from an initial state TiA to a state Tic close to the critical zone at the outlet of this first tunnel. The second zone II corresponds to a polymerization phase carried out, on the one hand by the pultrusion of the material through the heating die 12, and this with the additional energy supply of the exothermic reaction and on the other hand by the passage of the profiled in the postcooking tunnel 15 which completes the hardening. Various tests have made it possible to determine the ideal conditions for forming the material in the die.

It will be noted that the correct functioning of this process is ensured when the profile reaches a certain degree of polymerization in the last quarter of the heating die. The position of the die is shown diagrammatically in FIG. 5 with respect to a viscosity curve extracted from FIG. 4. If the degree of polymerization is obtained too early in the die - that is to say on the side of its upstream entry, at the start of zone II, there is a risk of blocking the entry of the die due to poor sliding of the non-pultruded material. By cons if this polymerization occurs too late especially outside the die, the forming will be insufficient and the profile may be deformed during the postcuring phase, the resin being soft and flowing. It therefore appears that this narrow forming zone C at the end of the die, which lies between the polymerization times t1 and t2 corresponds to a viscosity range (Tiî (2) also narrow. This means that this operating range requires very precise adjustment parameters at the heating time t determined by the speed of drive of the profile through the heating zones I and II, as well as at the temperatures of the pregelification tunnels 8 and the polymerization tunnel 13. In fact, the polymerization process of a thermosetting resin is a function of time and temperature, and diagrammatically shown in FIG. 6 is the heating die 12 visible in FIG. 5. The different zones generating the resistant forces have been noted therein. length depends on the state of evolution of the viscosity of resin and the time of passage of the material in the die for a given temperature. have due to viscous shearing effects, and adhesion effects, dry friction effects and dynamic friction effects due to behavior 1, expansion-contraction "in the composite material. Three areas of resistant forces have been determined. A first entry zone A which is a viscous sliding zone, a second central zone B which is an adhesion zone, and finally zone C which is a dry sliding zone from which the profile comes out correctly polymerized and non-deformable . Of course, these resistive forces vary as a function of the viscosity of the resin, the temperatures of the zones and the speed of drive of the profile. Anyway, it is confirmed that the ideal forming point that can give the product the desired quality is indeed in zone C of the sector. The value of the pultrusion forces has been recorded experimentally for several operating points.

To maintain a degree of polymerization which corresponds to a constant quality of the material used, the heating time must be constant and requires having a regulation of the drive speed so that in zone C the resin reaches a sufficient hardness. It will be noted that for a characteristic of the constant resin, the viscosity changes as a function of the speed within a range sufficient to obtain correct forming. We can play on the slowing down of the chemical reaction by reducing the heating time by increasing the speed of passage or vice versa. The main thing is to bring the ideal forming point PO - as we said - in the end zone of the die.

 This so-called "long" sector mentioned above, avoids the proliferation and poor forming of the impregnated wick, since it makes it possible to attenuate the excess resin then to keep it in shape during the heating until the polymerization of the skin. of the profile. If it is desired to obtain a high pultrusion speed, the length of the die can be increased, which has the effect of keeping a heating time sufficient to polymerize without it being necessary to increase the heating temperature too much.

 To control the manufacturing process according to the various chemical and mechanical disturbances, it appeared necessary to automate the pultrusion bench to compensate for their influence. These are thermal disturbances: the temperatures must then be kept constant by temperature regulation loops of each of the heating zones. For mechanical disturbances, the regulation of the drive speed will ensure a controlled passage time, whatever the disturbing forces on the motor speed. If the resistance force passing through the die increases, it is necessary to increase the running speed to avoid blocking and to maintain the operating point PO in the admissible zone of good operation ensuring a constant profile quality.

On the other hand, the physico-chemical disturbances are manifested by a variation in the additional energy supply, which modifies the resistive forces of the resin passing through the die. Consequently, a pultrusion force detector will give the image of the disturbances. Finally, to compensate for the variation in the additional energy supply due to the polymerization reaction, we have seen that a corrective action could be carried out on the passage time, that is to say the speed of unwinding to bring back the pultrusion point. in the die forming area.

 The device makes it possible to obtain calibrated profiles in the form of rods of great length of round or square or other cross section of approximately for example 1.4 mm on a side, and this without twisting of the rod which also has a surface state excellent.

 The invention is not limited to the example of installation installation according to FIG. 1, but also encompasses other variants such as the grouping of several pultrusion lines in the same tunnel or tunnels.

Claims (9)

 1.- Process for the continuous production of profiles of very long composite materials by pultrusion using a heating die ensuring the shaping and polymerization of oriented filaments and prepregs of resin, which are driven to the outlet production line by a drive system and then cut to be put to the correct length, characterized in that it consists in passing the resin prepreg filaments in a first resin pregelification zone for the initiation of the exothermic reaction of the resin used, then in a preforming zone for the dewatering of the excess resin, before passing through the polymerization zone essentially consisting of a long heating die for the calibration and the forming of the profile, and passing then said profile in a post-cooking zone which completes its polymerization.  2.- Manufacturing process according to claim 1, characterized in that one makes sure to bring the resin which impregnates the filaments from a state of viscosity nA to a state of critical viscosity Tic in the first pregelification zone I during which the chemical reaction is initiated.  3.- Manufacturing process according to claims 1 and 2, characterized in that the polymerization in zone II of the heating die is ensured by the pultrusion of the material through said die and by the contribution energy complementary to the exothermic reaction.  4.- Manufacturing process according to claim 1, characterized in that it consists in ensuring the complete polymerization of the profile in the last quarter of the heating die, in a narrow forming zone corresponding to a viscosity range (Til - tri2 ) narrow.  5. A manufacturing method according to claim 4, characterized in that a first entry zone A of the heating die is a viscous sliding zone, that a second central zone B is a zone of adhesion, and that the final zone C of forming the profile is a dry sliding zone.  6.- Device for implementing the manufacturing process according to any one of claims 1 to 5 characterized in that a pregelling tunnel (8) brought to a temperature Oi by heating resistors (9) is followed by '' at least one preforming diaphragm, in that after this zone is provided a long heating die (12) housed inside a polymerization tunnel (13) brought to a temperature 62 by heating resistors (14), and in that this tunnel is followed by a postcooking tunnel heated by heating resistors, arranged upstream of the drive mechanism (16) of the polymerized profile.  7.- Device according to claim 6, characterized in that the long heating die (12) of the polymerization tunnel (13) is an outer metal tube ensuring mechanical strength, containing a sheath of polytetrafluoroethylene bonded to said tube whose inner section is profiled to the shape of the product to be obtained, said tube being equipped with stops.  8.- Device according to claim 6, characterized in that the drive mechanism (16) consists of several pairs of rollers (18) each of which lower roller (18a) is a motor roller bearing against a roller (18b) , the drive rollers being driven in rotation by a drive belt (19).  9.- Device according to claims 6 and 8, characterized in that to measure the driving force of a profile, using a curvature sensor (21), including a grooved wheel (24) resting on said profile is secured to a straight potentiometer (22).