EP0469558A1 - Formable textil material and the shape of the mould obtained - Google Patents

Abstract

There is described an isotropic, readily deep-drawable nonwoven which has been formed as a filament nonwoven and consists of low-orientation, coarse-denier filaments to an extent of not less than 30% by weight and which has been consolidated mechanically only. Furthermore, a resinated, sheetlike prepreg produced from the nonwoven; a three-dimensional shaped textile structure produced using the resinated or unresinated deep-drawable nonwoven; and a sandwich material with a core comprising said three-dimensionally shaped, resinated textile structure. There are also described processes for manufacturing the abovementioned objects. <IMAGE>

Description

The present invention relates to a thermoformable nonwoven fabric, a resinous sheet-like prepreg made therefrom, a three-dimensionally deformed textile structure produced using the non-resinous or resinous thermoformable nonwoven fabric, and a sandwich material with a core made from said three-dimensionally deformed resinous textile structure. The invention further relates to methods for producing the above-mentioned objects.

EP-A-247 232 describes nonwovens made from filaments of low pre-orientation, which shows an elongation at break of over 100% or a birefringence of 0.01 to 0.07. These nonwovens are thermally pre-consolidated by hot embossing rollers, moistened and then thermally fixed under tension. This results in solidified embossing points, which greatly limit the mobility of the filaments in the nonwoven, and the subsequent fixation under tension results in an anisotropy of the thermomechanical properties, which severely impairs the deformability of such nonwovens, at least in the direction of tension.

From DE-A-30 29 752 a method is known for producing a deep-drawn molded part from a staple fiber fleece in which a staple fiber fleece is used which contains at least 10% by weight stretchable fibers with an elongation at break at 150 ° C. below the melting point contains at least 100%, which is solidified by needles and which is deep-drawn at a temperature between 150 ° C and the melting point of the stretchable fibers.

The fleece can be additionally reinforced by a thermoplastic or thermosetting binder. The staple fibers used for this material can consist of a wide variety of synthetic polymers and, as shown in the examples, have staple lengths of approximately 50-80 mm and single-filament titer of 1.5 to 20 denier.

The molded parts are suitable as self-supporting filters. However, they are mechanically less resilient due to the exclusive use of staple fibers. The publication gives no indication that a deep-drawn nonwoven could also be constructed from continuous fibers; rather, the person skilled in the art is led to assume that the deep-drawing ability of this known fleece results from the use of short-cut fibers, which can slide past one another relatively easily in the deep-drawing process.

DE-B 1 560 797 discloses a deformable spunbonded fabric which consists exclusively of partially stretched, endless synthetic fibers. The fiber material of these nonwovens can consist of polyamides, polyesters or polyolefins. For consolidation, this fleece is compacted in a pattern and impregnated with locally varying binder concentrations. According to the information in this document, this special type of consolidation is of crucial importance for the deformability of the fleece. Similar to the point-shaped consolidation carried out according to EP-A-247 232, however, there is also an anisotropy in the mobility of the filaments within the nonwoven, which impairs the three-dimensional deformability of the nonwoven.

It is also known from EP-A-250 005 to produce three-dimensional structures deformed from fabrics and normal nonwovens by deep drawing. According to the information in this document, the gain in area occurring during the deep-drawing process should only result from the constructional stretch of these fabrics and is accordingly low.

The present invention provides an isotropic, deep-drawing nonwoven fabric which, under normal processing conditions, in particular during the impregnation process, exhibits a very good dimensional stability and which at the same time enables a deep-drawing ratio which is sufficiently large for all practical applications.

The isotropic, deep-drawing nonwoven according to the invention is designed as a filament nonwoven and is characterized in that it consists of at least 30% by weight of slightly oriented, coarse-titer filaments with a titer of more than 7 dtex and that it is mechanically consolidated.

The mechanical strengthening can be carried out in any manner known per se, e.g. by needles or by hydrodynamic means by fluid jets, as has been described, for example, in EP-A-0 108 621.

The orientation of the low-orientation, coarse-titer filaments contained in the nonwovens according to the invention is expediently set so that it corresponds to a maximum tensile strength elongation of at least 80%, preferably of at least 100%. An upper limit for the maximum tensile strength expansion of the low-orientation, coarse-titer filaments is basically only given by their manufacturability. However, it is advantageous to adjust the orientation of these filaments so that there is a maximum tensile elongation between 100 and about 350%. It is particularly preferred to adapt the degree of orientation of the slightly oriented, coarse-titer filaments, that is to say their maximum tensile force extension, to the intended use, that is to say to the three-dimensional deformation to be achieved by deep-drawing, in such a way that the coarse-titer filaments cannot tear in the stretched areas, but also not too large Have more stretchability. It is therefore particularly preferred to use the orien tion of the coarse-titer filaments, ie to adjust their maximum tensile strength so that after the deep-drawing deformation of the fleece according to the invention, the coarse-titer filaments in the stretched areas still have a residual drawability of about 10 to 50%, in particular 10 to 30%.

The coarse-titer filaments contained in the nonwovens according to the invention generally have individual titers of 7 to 30 dtex, preferably 10 to 25 dtex. Titers outside of these expedient titer limits are also possible, provided that care is taken to ensure that the conditions for the orientation of the filament material described in more detail above can be met.

For special areas of application, the deep-drawable nonwovens according to the invention consist 100% of the slightly oriented, coarse-titer filaments. However, it has been shown that it is surprisingly possible to also produce nonwovens which can be deep-drawn and which contain up to 70% other fibers.

These "other fibers" can correspond to any known type of fiber suitable for nonwoven manufacture. They preferably have a normal to high degree of orientation and can accordingly be normal to highly tear-resistant and they can be in the form of staple fibers or, preferably, in the form of continuous fibers. Therefore, in the following description, the term "other fibers" is intended to encompass all of these types of fibers.

It is surprising that such nonwovens according to the invention, which have only about 30% of low orientation, have coarse titer filament, can still be deep-drawn, while known nonwovens have only a moderate deep-drawing ability and tear in the stretched zones at higher deep-drawing ratios. The deep-drawing ability of nonwovens according to the invention with a predominant proportion of other fibers is likely to be attributed to the fact that the proportion of slightly oriented, coarse-titer filaments contained in the nonwoven takes on a surprisingly good support and stabilizing function which surprisingly effectively prevents tearing of the other fiber components of the nonwoven according to the invention. Preferred nonwovens according to the invention contain a proportion of 40 to 85% by weight of the low-orientation, coarse-titer filaments or, as already stated above, they consist of 100% of low-orientation, coarse-titer filaments.

Neither the low-orientation, coarse-titer filaments nor the other fibers of the nonwoven according to the invention all have to have the same titer. Rather, two or more groups of low-orientation, coarse-titer filaments with different titers above 7 dtex can also be contained in the same nonwoven or the titer of the low-orientation, coarse-titer filaments can be statistically distributed in a range above 7 dtex as long as their orientation is only Maximum tensile strength expansion of at least 80%. The same naturally also applies to the other fibers of the nonwoven fabric according to the invention. These can also be contained in one and the same nonwoven fabric in different titers or in a titre spectrum in which the titers are statistically distributed, although the titer limitation to values above 7 dtex does not apply to them.

The titers of these "other fibers" can therefore also be smaller than 7 dtx and are usually 1 to 30 dtex.

By choosing the titer mixture of the filaments and fibers, the character of the nonwovens according to the invention can be varied within very wide limits. For example, a higher proportion of coarse-titer filaments and fibers leads to increased stiffness and less area coverage; a higher proportion of fine titers below 10 dtex is particularly preferred if the area coverage of the nonwoven fabric according to the invention is to be made more uniform and / or denser.

There are various possibilities for distributing the low-oriented, coarse-titer and the other fibers in the deep-drawable nonwovens according to the invention. The slightly oriented, coarse titer, filaments and the other fibers can be present in the deep-drawable nonwovens in a practically homogeneous mixture, i.e. that on average the distribution of poorly oriented, coarse titer and other fibers is approximately the same in every spatial element of the fleece. However, the deep-drawable nonwoven fabric according to the invention can also have a layer structure in which the low-orientation, coarse-titer filaments and the other fibers are contained in different layers. Layers with slightly oriented, coarse titer filaments and layers with other fibers alternate with each other. It is preferred that at least one outer side of the layered nonwoven fabric, but in particular both outer sides, layers consist of slightly oriented, coarse-titer filaments. The layers of such a nonwoven fabric according to the invention are also advantageously mechanically z. B. connected by needles.

The excellent support capacity of the deep-drawable nonwovens according to the invention can also be used in such a way that a nonwoven according to the invention is combined with other known nonwovens and is connected at points or over the entire surface. Here, too, a layer structure is formed which, due to the presence of at least one layer of a nonwoven fabric according to the invention, has good thermoformability. When combining an inventive Laminate with other known laminates, the number of layers is in principle not limited, but is determined by the intended use. Such a combination generally has alternating nonwovens according to the invention and customary ones and can have an inventive or a conventional nonwoven on one or both sides as the outer layer.

The basis weight of the nonwovens according to the invention is also essentially determined by the intended use of the material and is generally in the range from 50 to 500 g / m ² , preferably from 100 to 300 g / m ² .

The excellent deformability of the nonwoven fabric according to the invention is based not only on the good deformability of the low-orientation, coarse-titer filaments contained therein, but also on the good mobility of the filaments in the purely mechanically consolidated nonwoven fabric. The higher volume of mechanically bonded nonwovens compared to thermally bonded ones is also advantageous for many applications.

The coarse-titered individual filaments contained in the nonwoven fabric according to the invention result in good intrinsic stability of the deep-drawn molded articles even if they contain no or no stabilizing resin.

The deep-drawable spunbonded nonwoven according to the invention is produced in a manner known per se by depositing the filaments on a moving sieve base to form a tangled nonwoven and is characterized in that at least 30% by weight of slightly oriented, coarse-titered filaments with a titer of more than 7 dtex are deposited. The blowing nozzles for the filament take-off are adjusted in such a way that these coarse-titer filaments receive a relatively low pre-orientation, which corresponds to a maximum tensile force elongation of at least 80%, preferably at least 100%. It is particularly advantageous to set the take-off nozzles in such a way that, depending on the intended use of the deep-drawable nonwoven according to the invention, the slightly oriented, coarse-titer filaments have maximum tensile strength expansions in the range from 100 to 350%. The individual titer of the coarse-titled, slightly oriented filaments is preferably selected in the range between 8 and 30 dtex and their share in the total weight of the nonwoven between 80 and 100% by weight. The amount of filaments deposited per m ² is measured according to the criteria given above, usually 50 to 500 g, preferably 100 to 300 g, of filaments are deposited per m ² .

The filament is preferably deposited using a rotating baffle plate and in particular with a downstream guide surface as described, for example, in German Patent Specification 27 13 241. To produce the deep-drawable spunbonded nonwovens according to the invention with the preferred layer structure, in which low-orientation, coarse-titer filaments and other fibers are contained in different layers, the filament is laid down by several rows of storage elements one behind the other in the direction of movement of the screen support, from which alternately low-orientation, coarse-titer, Filaments and other fibers are deposited. The freshly deposited spunbonded web is consolidated in a manner known per se by mechanical means, for example by needles or by hydrodynamic consolidation by means of fluid jets as described, for example, in EP-A-0 108 621.

The filaments and fibers of the thermoformable spunbonded nonwoven according to the invention can in principle consist of all spinnable polymer materials. However, the polymer material from which the low-orientation, coarse-titer filaments are produced must allow the production of filaments which have a maximum tensile elongation of at least 80, preferably 100, in particular 100 to 350%. There are no such restrictions for the other fibers possibly contained in the nonwovens according to the invention.

Preferred polymer raw materials for the production of the deep-drawable nonwovens according to the invention are polyesters, polyamides and polyacrylonitrile. Particularly preferred are polyesters and in particular those which are composed of at least 80% terephthalic acid and ethylene glycol units. In particular, preference is given to a polymer raw material made from pure polyethylene terephthalate or containing at most 5% modifying components.

Polyester building blocks, which can be contained in the polyesters to be used in addition to terephthalic acid and ethylene glycol, are usually used in spinnable polyesters, e.g. Isophthalic acid, sulfoisophthalic acid, naphthalene carboxylic acids, aromatic hydroxycarboxylic acids, for example p-hydroxybenzoic acid, aliphatic dicarboxylic acids with about 4 to 10 C atoms, for example adipic acid, glycols with 3 to 10 C atoms, diglycol, triglycol or polyglycol.

The present invention also relates to a thermoformable nonwoven of the type described above, which is additionally impregnated with a thermoplastic or thermosetting resin. The thermoplastic or thermosetting resin used is preferably one that stiffens the nonwoven fabric so that it becomes self-supporting. A nonwoven fabric according to the invention is particularly preferred which is impregnated with a known, thermosetting resin, in particular a phenol or melamine resin. The resin pad, ie the pro m ^{2 of} the amount of resin applied depends on the area of application and is preferably dimensioned such that an essentially open-pore nonwoven network results.

An open-pore nonwoven network is to be understood as a material which has essentially retained the open-pore structure of the original nonwoven, in which the resin thus only completely or partially encases the individual filaments and forms binding points at the filament crossing points. Suitable application amounts of the resin are in the range from 20 to 80, preferably from 40 to 50,% by weight of the semi-finished product. Within the specified ranges, the amount of resin can be expediently adapted to the m ² weight of the nonwoven according to the invention. If a heavy nonwoven fabric according to the invention is used, work is preferably carried out in the upper half of the range specified, for light textiles in the lower half. For special applications it can also be advantageous to increase the amount of resin applied so that a resin film remains between the threads of the nonwoven network even in the stretched state.

The described resin-impregnated deep-drawable nonwovens according to the invention can be produced without any problems by subjecting the above-described nonwoven to a conventional resin impregnation process. The resin can be applied in the usual way by brushing, brushing, knife coating, slapping or by dipping. The nonwoven fabric loaded with resin is then expediently squeezed onto the desired resin holder by a pair of squeeze rollers.

In a preferred embodiment, the resin is applied by a "reverse process" in which the resin is first applied evenly to a carrier material. The thermoformable nonwoven fabric according to the invention is then brought into close surface contact with the resinous carrier, the nonwoven fabric sucking the resin from the carrier through its capillary forces.

It is by no means necessary for the application of resin to be uniform over the entire area of the nonwoven fabric. Rather, the resin can also be applied in the form of a regular pattern or in an irregular but statistically uniform distribution. However, it should be noted here that the non-resinous surfaces do not become too large, so that the entire non-deformed or three-dimensionally deformed flat structure is still adequately stiffened.

An effective statistical resin distribution results, for example, if the resin is applied to a nonwoven fabric according to the invention by the reverse process described above, which shows a layer structure in which there are mostly coarse, slightly oriented filaments, on the other hand predominantly fine titered, normal or strongly oriented filaments . The resin transfer takes place from the coarse-titer side and the coarse-titer filaments draw the majority of the resin and form a particularly effective stiffened support network after the thermoforming and curing of the resin.

Thermoplastic resins are expediently applied in the form of solutions or preferably emulsions for the impregnation process; thermosetting resins are expediently in the commercially available form as highly concentrated aqueous solutions or dispersions.

The inventive, optionally resin-impregnated, deep-drawable nonwoven fabric can be used with particular advantage for the production of three-dimensionally deformed textile fabrics. These three-dimensional structures are also the subject of the present invention.

They consist of a three-dimensionally shaped, open-pore nonwoven fabric, which is characterized in that at least 30% by weight of the filaments are low-orientation, coarse-titered filaments, which, even in the deformed areas, only stretch to below their maximum tensile strength, i.e. are not torn.

They contain a relatively coarse-pored support network, which is formed by low-orientation, coarse-titer filaments, which are more stretched in the area of the deformations, and which is optionally additionally stiffened by a thermoplastic or thermosetting resin.

In the three-dimensionally deformed textile fabrics according to the invention, which do not consist exclusively of the slightly oriented, coarse-titer filaments, the possibly coarse-meshed porous nonwoven fabric with its countless fine openings extends from the relatively coarse openings of the support network, possibly made of other fine-titer filaments .

In a special, but less preferred embodiment because of the higher weight, the pores of the deformed nonwoven fabric can also be filled with the thermosetting or thermoplastic resin.

FIG. 1 schematically shows a possible shape for a three-dimensionally deformed flat structure (3) according to the invention with a large number of “cups” (5) pulled out of a textile base area (4) (nonwoven fabric).

FIG. 2 shows schematically an enlarged representation of one of the “cups” (5) of the structure of FIG. 1.

In FIGS. 1 and 2, for reasons of clarity and clarity, only that from the slightly oriented, coarse-titer filaments is shown schematically formed support network and in each case only the structure of the faces of the "wells" facing the viewer, but not the rear sides visible through the open-pore nonwoven structure.

FIG. 2 schematically shows the open fiber interspaces of the open-pore nonwoven structure particularly clearly.

In an embodiment specified particularly with regard to the further use as core material for the production of laminates, the three-dimensionally deformed sheet-like textile material according to the invention has a large number of elevations on a base surface in a regular arrangement. In a further embodiment, the three-dimensionally deformed material according to the invention has a plurality of elevations and depressions in a regular arrangement on the level of the base surface. The elevations and depressions can take the form of cups with a round or angular base surface or e.g. of webs, which expediently have a flat plateau or a flat bottom, which are preferably all in one plane and parallel to the base surface.

The three-dimensionally deformed sheet-like textile material according to the invention is produced either by subjecting a resin-coated nonwoven fabric according to the invention to a deep-drawing process known per se, or by deep-drawing an un-resinated non-woven fabric according to the invention and then treating the resulting three-dimensionally deformed structure, or by using an resin-free nonwoven fabric together with a resin film appropriate weight per unit area is subjected to the deep-drawing process.

Another object of the present invention is a sheet-like sandwich molded body consisting of two outer solid cover layers which are connected via a core consisting of the three-dimensionally deformed, resin-reinforced sheet-like textile material according to the invention described above. The connection between the cover layers and the plateau surfaces of the elevations or the bottom surfaces of the depressions of the core material according to the invention can be achieved by conventional lamination processes using adhesives, in particular cold or heat-curing adhesives such as e.g. Epoxy resins or thermosetting resins are used. Due to the large contact area between the core material and the cover layers, the bond proves to be extremely stable. Despite the open-pore nonwoven structure of the core material according to the invention, the sandwich moldings produced therewith have a surprisingly high compressive strength with extremely low weight. They are therefore ideal as a material for the interior of vehicle, especially airframe. Here, three-dimensionally deformed textile nonwovens made of flame-retardant filament material are particularly preferred.

FIG. 3 shows a sandwich construction (6) with the top surfaces (7) and (8) and a core (9) made of a three-dimensionally deformed flat structure according to the invention.

Claims (22)

1. Isotropic, good thermoformable nonwoven fabric, characterized in that it is designed as a filament nonwoven fabric which contains at least 30% by weight of slightly oriented, coarse-titered filaments with a titer of more than 7 dtex and is only mechanically consolidated. 2. Nonwoven fabric according to claim 1, characterized in that the orientation of the low-orientation, coarse-titer filaments corresponds to a maximum tensile strength extension of at least 80%, preferably of at least 100%. 3. Nonwoven fabric according to at least one of claims 1 and 2, characterized in that the slightly oriented, coarse-titer filaments have individual titers of 7 to 30 dtex. 4. Nonwoven fabric according to at least one of claims 1 to 3, characterized in that the nonwoven fabric consists of 40 to 85 wt.% Of the slightly oriented, coarse-titer filaments. 5. Nonwoven fabric according to at least one of claims 1 to 4, characterized in that it consists exclusively of coarse-titer filaments of low orientation. 6. Nonwoven fabric according to at least one of claims 1 to 5, characterized in that the low-orientation, coarse-titer filaments and other filaments are present in a practically homogeneous mixture. 7. Nonwoven fabric according to at least one of claims 1 to 5, characterized in that the low-orientation, coarse-titer filaments and other filaments are predominantly present in different layers of the nonwoven fabric, which are mechanically interconnected. 8. Nonwoven fabric according to at least one of claims 1 to 7, characterized in that the basis weight of the nonwoven fabric in the area from 50 to 500 g per m ² , preferably from 100 to 300 g per m ² . 9. Nonwoven fabric according to at least one of claims 1 to 8, characterized in that the nonwoven fabric is additionally combined with another known nonwoven fabric and is connected at points or over the entire surface. 10. A process for producing the spunbonded web of claim 1 by depositing the filaments into a random web in a manner known per se, characterized in that at least 30% by weight of slightly oriented, coarse-titer filaments are deposited, the individual titer of which is above 7 dtex and the solidification of the Fleece is made purely mechanically. 11. The method according to claim 10, characterized in that the filament deposition is carried out by a plurality of rows of storage elements which are arranged one behind the other in the direction of movement of the fleece transport device and which alternately deposit slightly oriented, coarse-titer and other filaments. 12. Isotropic, good thermoformable nonwoven fabric according to at least one of claims 1 to 9, characterized in that it is additionally impregnated with a thermoplastic or thermosetting resin. 13. Thermoformable nonwoven fabric according to claim 12, characterized in that the resin layer is dimensioned so that there is a substantially open-pore nonwoven fabric network. 14. A method for producing the thermoformable resin-impregnated nonwoven fabric of claim 12, characterized in that a thermoformable nonwoven fabric is produced according to claim 10, and then impregnated with a thermoplastic or thermosetting resin. 15. Three-dimensionally deformed, open-pore nonwoven fabric, characterized in that at least 30% by weight of the filaments are low-orientation, coarse-titer filaments, which are only stretched in the deformed areas to below their maximum tensile strength. 16. Three-dimensionally shaped open-pore nonwoven fabric according to claim 15, characterized in that it is additionally stiffened with a thermoplastic or thermosetting resin. 17. A method for producing the three-dimensionally deformed nonwoven fabric of claim 15, characterized in that a thermoformable nonwoven fabric of claim 1 is provided by a deep-drawing process with a regular arrangement of a plurality of elevations and depressions. 18. A method for producing the three-dimensionally deformed resin-reinforced nonwoven fabric of claim 16, characterized in that a thermoformable nonwoven fabric of claim 1 is provided together with a resin film by a deep-drawing process with a regular arrangement of a plurality of elevations and depressions. 19. A method for producing the three-dimensionally deformed nonwoven fabric of claim 16, characterized in that a three-dimensionally deformed nonwoven fabric is produced by the method of claim 17, and then impregnated with a thermoplastic or thermosetting resin and optionally cured. 20. A method for producing the three-dimensional deformed nonwoven fabric of claim 16, characterized in that a thermoformable resin-impregnated nonwoven fabric of claim 12 is provided by a deep-drawing process with a regular arrangement of a plurality of elevations and depressions. 21 sheet-shaped sandwich molded body consisting of two outer solid cover layers which are connected by a core made of light material, characterized in that the core consists of the three-dimensionally deformed, resin-stiffened fleece of claim 16. 22. A process for the production of the sandwich molding of claim 21, characterized in that a three-dimensionally deformed, resin-stiffened fleece is produced according to one of claims 17 to 20, and the cover layers are then laminated onto this on both sides in a manner known per se.

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