Apparatus for laying fiber tapes

An apparatus for laying fiber tapes includes a deflection guide for the fiber tapes made up of pressure plates for the deflection of the tapes, which pressure plates are arranged adjacent to one another perpendicularly to the deflection axis and are resiliently supported in the pressing direction, and a frame, which is displaceable in the laying direction, for accommodating the pressure plates. The pressure rollers form grooved pulleys which engage in circumferential bearing receivers, are axially guided on each other and between lateral guide stops, and are held in bearing engagement with the bearing receivers by elastic endless belts which are guided about a bearing roller mounted in lateral retainers. The bearing receivers are resiliently supported independently from each other in the pressing direction on an abutment provided between the lateral retainers.

CROSS REFERENCE TO RELATED APPLICATIONS

Applicant claims priority under 35 U.S.C. §119 of Austrian Application No. A50832/2013 filed Dec. 16, 2013, the disclosure of which is incorporated by reference.

FIELD OF THE INVENTION

The invention relates to an apparatus for laying fiber tapes, comprising a deflection guide for the fiber tapes consisting of pressure plates for the deflection of the tape, which pressure plates are arranged adjacent to one another perpendicularly to the deflection axis and are resiliently supported in the pressing direction, and comprising a frame, which is displaceable in the laying direction, for accommodating the pressure plates.

DESCRIPTION OF THE PRIOR ART

Laying heads with a deflection guide for the fiber tapes are usually used for producing fiber structures, which laying heads are pressed against the already laid fiber layers by means of the adjacently arranged pressure plates which form the deflection guide. The fiber tapes, which comprise an adhesive tape carrying a fiber layer, are drawn off a supply roll to the extent of the forward feed movement of the laying head and supplied to the deflection guide in order to press the fiber layer to the already laid fiber layers on the one hand and to draw off the adhesive tape from the fiber layer on the other hand, which requires a comparatively small deflection radius. Since the individual fiber layers of the fiber structure are to be placed tightly on each other with no trapped air in between, a respective pressurization of the fiber tapes by the deflection guide must be ensured. It is known for this purpose (EP 0 371 289 B1) to mount the pressure plates arranged in an assembly next to one another in a displaceable manner independently of each other in the pressing direction in a frame and to apply pressure to the same by a membrane, so that the individual pressure plates are also able to follow an uneven progression of the already laid fiber layers as a result the flexibility of the membrane.

In order to reduce the friction produced during pressing of the fiber tapes against the already laid fiber layers between the pressure plates and the adhesive tape of the fiber tapes, it is further known (U.S. Pat. No. 4,351,688 A, US 2007/044 922 A1) to replace the pressure plates by pressure rings which are rotatably mounted on the bearing discs that are displaceably guided in the pressing direction. Irrespective of whether the pressure rings mounted on the resiliently supported bearing discs are respectively pressurized via pressure rollers (U.S. Pat. No. 4,351,688 A) or whether the bearing discs are supported on pressure cylinders (US 2007/044922 A1), these pressure rings come with the disadvantage that the displaceable bearing of their pressure discs requires comparatively large diameters of the pressure rings, which has a disadvantageous effect not only on the pressing pressure that is exerted on the fiber tape, but also on the removal of the adhesive tape from the fiber layer of the fiber tapes.

SUMMARY OF THE INVENTION

The invention is thus based on the object of providing a deflection guide for the fiber tapes in an apparatus for laying fiber tapes, which deflection guide, under advantageous frictional conditions, allows good pressing of the fiber tapes against the already laid fiber layers on the one hand and secure removal of the adhesive tape from the fiber layer on the other hand, without giving rise to the likelihood that the fiber layer is partly lifted from the fiber structure again during the removal of the adhesive tape.

On the basis of an apparatus of the kind mentioned above, this object is achieved in accordance with the invention in such a way that the pressure rollers form grooved pulleys which engage in circumferential bearing receivers, are axially guided on each other and between lateral guide stops and are held in bearing engagement with the bearing receivers by means of elastic endless belts which are guided about a bearing roller mounted in lateral retainers, and that the bearing receivers are resiliently supported independently from each other in the pressing direction on an abutment provided between the lateral retainers.

By providing grooved pulleys which are held by means of elastic endless belts in bearing receivers, which belts guide said grooved pulleys over a circumferential section, a bearing of the grooved pulleys on a shaft can be avoided, so that no bearings for such shafts are required. This provides constructional prerequisites so as to enable selecting the diameter irrespective of a shaft accommodating the groove pulleys. The possibility of resilient support in the pressing direction is still maintained because the bearing receivers themselves are resiliently supported independently from each other in the pressing direction on an abutment which is provided between the lateral retainers. In addition to the radial guidance of the grooved pulleys via the bearing receivers, it is further necessary to ensure a respective axial guidance. For this reason, the grooved pulleys which are laterally guided on each other are accommodated between lateral guide stops which fix the axial position of the groove pulleys without preventing their radial displacement. The elastic endless belts, with which the grooved pulleys are individually held in bearing engagement with the bearing receivers, must be provided with sufficient expansion behavior in order to ensure the displacement of the groove pulleys within the scope of the pretensioning of the resilient support of the bearing receivers. The apparatus in accordance with the invention thus comprises a deflection guide for the fiber tapes which utilizes the advantages of pressure rollers without having to take into account their disadvantages.

Especially advantageous guiding conditions are obtained for the grooved pulleys when the bearing receivers comprise rolling bodies engaging in the grooved pulleys, because in this case an axial guide component can be applied to the grooved pulleys via the rolling bodies.

The lateral guide stops for the grooved pulleys can also be used for pressing the fiber tape against the already laid fiber layers when the grooved pulleys are combined into individual pressure elements between the pressure plates, which comprise a sliding surface for tape deflection which is curved according to the belt pulleys and which form the lateral guide stops, wherein the retainers arranged laterally on the pressure elements displaceably engage in the pressing direction in recesses of the pressure plates. These recesses in the pressure plates are required in order to enable the connection of the pressure plates in a directly axial manner to the pressure elements formed by the individual grooved pulleys on the one hand and to ensure on the other hand a mutual displacement of the pressure plates and the pressure elements in the pressing direction. In order to optimally press thicker fiber tapes in particular onto the already laid fiber structure, the pressure elements and the pressure plates can be displaceably mounted in a frame in the pressing direction in order to pressurize the pressure elements and the pressure plates independently from each other via a common membrane with a pressure medium.

If the pressure plates form sliding shoes which are resilient in the pressing direction and are separated by recesses from the remaining plate body, individual pressurization of the individual pressure elements and pressure plates can be omitted because the sliding shoes, as a result of the resilient pretensioning which is comparable to the resilient pretensioning of the groove pulleys, are already able to follow the surface progression of the already laid fiber layers within the scope of the spring-elastic pretensioning without having to displace the pressure plate itself.

In order to obtain a finely graduated subdivision of the sliding shoes of the pressure plates which is adjusted to the grooved pulleys, the sliding shoes can be subdivided into mutually independent resilient sliding segments which are parallel to the plane of the plates.

DESCRIPTION OF THE PREFERRED EMBODIMENT

In accordance with the embodiment according toFIGS. 1 and 2, the apparatus comprises a laying head with a deflection guide1for the fiber tapes2which comprise an adhesive tape4carrying a fiber layer3. Said fiber tapes2are drawn off a supply roll and pressed by means of the deflection guide1against the already laid fiber layers5of a fiber structure to be formed, wherein the adhesive tape4is drawn off the fiber layer3of the fiber tape2, which occurs at a comparatively small deflection radius. The deflection guide1is composed of a plurality of pressure rollers in form of belt pulleys6which are arranged next to one another perpendicularly to the deflection axis and which are axially guided between lateral guide stops7. The grooved pulleys6engage in bearing receivers8, which are provided with rolling bodies9which guide the grooved pulleys6via their grooves. For radial fixing within the bearing receivers8, the grooved pulleys6are supported via an elastic endless belt10against a bearing roller11, which is mounted in lateral retainers12which form the guide stops according toFIGS. 1 and 2, so that the grooved pulleys6which are guided axially between the guide stops are held in engagement with the bearing receivers8in the radial direction by the elastic endless belt10and the bearing roller11. The bearing receivers8themselves are respectively resiliently supported via the spring elements13in the pressing direction on an abutment14, which is arranged between the lateral retainers12.

Since the lateral retainers12are fixed to a pressure element15and the pressure element15is clamped according toFIG. 1in a non-displaceable way in a frame16, the belt pulleys6are applied with a respective pressing force under resilient pretensioning of the spring elements13to the fiber layers5in the case of pressurization of the frame16, so that the respective fiber tape2guided about the grooved pulleys6is pressed against the fiber layers before the adhesive tape4is drawn off the fiber layer3which is pressed against the already laid fiber layers5. The individual grooved pulleys6can therefore be displaced independently from each other in the pressing direction within the scope of the pretensioning of the associated spring elements13, which allows a finely graduated adjustment of the deflection guide1to the surface progression of the already laid fiber structure.

In contrast toFIGS. 1 and 2, the guide stops7are not formed by the lateral retainers12but by separate pressure plates17according to the embodiment according toFIGS. 3 and 4, which pressure plates displaceably accommodate individual pressure elements15with grooved pulleys6between themselves in the pressing direction according toFIGS. 1 and 2. For this purpose, the pressure plates17are provided with recesses18, in which the lateral retainers12engage with a respective play of movement in the pressing direction, so that the lateral retainers12cannot impair the axial guidance of the grooved pulleys6between the pressure plates17as the guide stops7. As a result of the arrangement of the pressure elements15with the grooved pulleys6between the pressure plate17with sliding surfaces19which are adjusted to the belt pulleys6for the deflection of the tape, the pressure plates17and the pressure elements15can be pressurized mutually independently from each other via a common membrane20by means of a pressure medium. The pressure plates17and the pressure element15must be displaceably mounted in the frame16in the pressing direction, as is shown inFIG. 3, in which the membrane is arranged in form of a pressure hose21which rests on a frame wall22on the circumferential side which is opposite of the pressure plate17and the pressure elements15.

Such individual pressurization of the pressure plate17is not mandatory however when the pressure plates17form a sliding shoe23producing the sliding surface19, which is connected via a resilient web24to the remaining plate body and can therefore be pressurized in the pressing direction according to the grooved pulleys6with resilient pretensioning. As a result, the sliding shoe23, which is simultaneously used as a lateral guide stop7for the grooved pulleys6, can also individually follow the surface progression of the already laid fiber layers5in the laying direction like the grooved pulleys6, so that a separate pressurization of the individual pressure plate17and pressure elements15can be omitted under certain circumstances.

The sliding shoes23of the pressure plates17can be subdivided into mutually independent, spring-loaded sliding segments by means of slits5which are parallel to the plane of the plate, as is indicated inFIG. 4by the dot-dash line. This allows a finely graduated tracking of the sliding shoes17also in the region of the pressure plate17, which tracking follows the fiber structure surface in the laying direction and which is comparable to the grooved pulleys6.

The provision of the rotatably mounted grooved pulleys6reduces the frictional resistance caused by the deflection of the tape about the deflection guide1. This frictional resistance can additionally be decreased when the bearing roller11is driven via a shaft26for the elastic endless belt10according toFIG. 1, which produces a respective drive of the grooved pulleys via the endless belt10.