Layer material and method for producing a layer material

专利摘要:
The invention relates to a method for producing a layer material and a layer material which has a backing layer (1) and a layer (2) made of polyurethane connected thereto, a leather, a textile material, a leather fiber material or a microfiber fleece being used as the backing layer (1) and is connected to the layer (2), at least one layer of PU whipped foam being applied to the carrier layer (1) as the layer (2). According to the invention, it is provided that the PU whipped foam is produced with a PU dispersion mixture, the individual PU dispersions used to produce the PU dispersion mixture in the dried state showing different softening points that one or more PU dispersions with heat-activatable melt are used to produce the PU dispersion mixture. or contact adhesive properties and with a softening point in the dried state higher than 40 ° C to the extent of 18 to 52% by weight of the finished PU dispersion mixture and one or more PU dispersions without hot melt or contact adhesive properties and with a softening point higher than 95 ° C to the extent of 39 to 73% by weight of the finished PU dispersion mixture are mixed so that the PU dispersion mixture for the layer (2) is applied to the carrier layer (1) with a thickness such that it has a thickness of 0.075 in the dried state up to 0.450 mm, that before or at the same time with a structure ization of the PU whipped foam, a further layer (3) is applied to the layer (2) from a non-foamed PU dispersion that is a mixture of several PU dispersions, and that the carrier layer (1) has the further layer (3) and the layer (2) is pressed together with a contact pressure of 4 to 48 kg / cm² and connected and structured with a die (4).
公开号:AT521907A1
申请号:T50354/2019
申请日:2019-04-18
公开日:2020-06-15
发明作者:
申请人:Schaefer Philipp；
IPC主号:

专利说明:

The invention relates to a method for producing a layer material according to the preamble of patent claim 1.
Furthermore, the invention relates to a layer material according to the preamble of claim 11 and objects obtainable according to the method or using a layer material according to the invention.
EP 1644539-B1 describes continuous capillaries through a PU coating. The coating is structured on a matrix made of silicone rubber. The polyurethane dispersion or mixture for the structuring layer is applied to the negatively structured matrix and dried and solidified by means of heat. The die itself does not absorb any water, so that the water can only be removed via and / or through the surface of the coating. The same applies if the structuring takes place on a negatively structured release paper. The structuring takes place in-situ during the drying and solidification of the polyurethane dispersion top layer. It is networked and can no longer be restructured after a storage period of 48 hours. Since the trouble-free drying, in particular of thicker dispersion mixtures, is complicated, that is, if no moisture can be removed into the temporary carrier, the drying must take place with increasing temperature. This requires a lot of energy because not only does the dispersion layer have to be heated, but also the temporary underlay when it is heated. The evaporation of the applied layer also removes heat from the surface, which has to be added again and again. An essential object of the invention is the saving of energy and the related
Emission reduction.
The formation of capillaries is only possible with thin coatings. Their number per unit area and their diameter are difficult to control because they form as holes in the coating when the PU dispersion solidifies on the die, which holes have to communicate with holes or thin spots in the adhesive layer. The coating is cross-linked and cannot be restructured, and even if this were possible, the capillaries would close under the high pressure required for embossing. These coatings show a uniform structure in the surface. The same applies to so-called corrected scar liver with a foamed polyurethane coating. The invention has among others the
The production of the matrices in the 3D process, for example for surfaces with technical functions, is digitally simple and quick for small matrices
perform.
A further object of the invention is to coat a leather in such a way and to structure the cut-out parts in such a way that only die-related waste arises, because the parts of the skin with low thickness and loose grain, which normally represent waste, also match the material Structure can be provided.
According to the task, only energy for format blanks and stamped parts should be required for the structuring, which likewise represents a considerable energy saving. It is also part of the task to extend the lifespan of silicone rubber matrices, since the structuring matrices should not come into contact with polyurethane dispersions containing wet polyisocyanate as crosslinking agent. It is also an object of the invention to structure dies and stamped parts in addition to using silicone rubber matrices and also matrices with textile surfaces. Textile matrices are not suitable for wet application of dispersion coatings.
In the known processes in which the structuring takes place in large areas in situ, the residence time of the dispersion or of the dispersion mixtures for the structuring surface is between 2 and 5 minutes. According to the task, this time
can be reduced to a few seconds. Known materials or coatings that were produced on reversing dies,
consist of several layers. Layer separations are therefore preprogrammed. A layered structure also creates a so-called plywood effect, i.e.
According to the invention, soft layer materials are to be created with a homogeneous-looking surface and which, during hot stamping - due to their foam structure provided according to the invention - prevent the full temperature of the die from being passed on to the carrier layer during pressing. Higher temperatures are perceived as stress in both microfiber fleece and leather, and the carrier materials harden and lose strength, especially when moisture,
Heat and pressure work together on the base layer.
The essential task of the invention is to create a layer material that is easy to manufacture and store, that permits exact surface structuring, in particular of format blanks and stamped parts, that has the best mechanical and physical properties, and that is economically producible and processable. The layer should be built up from a single layer of aqueous PU dispersions and should not have any voids, sink marks, bubbles or cracks that arise during drying, even with a thickness of more than 0.4 mm. Furthermore, the wet coating should not lose its full water content in thickness during drying or water removal.
Another essential object of the invention is to provide a layer material with a flat, structureless, two-dimensional coating surface in such a way that the coating can be shaped economically with any individual structuring even after a storage period of more than six months without loss of quality and a three-dimensional structure accepts or maintains. The embossing of the layer material should therefore be possible after a longer period of time after the layers have been created.
In order to be able to react to technical changes quickly, easily and inexpensively, especially regardless of time and place, it is possible according to the invention, e.g. in a shoe factory or other companies processing layer material, to cut or punch a format part out of the layer material and by means of a die, preferably created in a 3D printing process, with the required structure
to provide.
Another object of the invention is to create a layer material, the layers of which can be created with PU dispersions on a purely aqueous basis.
According to the invention, a method of the type mentioned at the outset is characterized by the features stated in the characterizing part of claim 1.
In this procedure, a layer material is obtained in which a carrier layer carries a surface-structurable layer, which can be optimally processed even after prolonged storage. To do this, it is only necessary to thermally activate the surface-structurable layer and to thermoplastic it above its softening point with a die under heat and pressure. The layer retains its structure after deduction from the die. The pressurization results in a practically inseparable layer material that reproduces the die true to form. The layer of PU impact foam applied to the carrier layer and the further, non-foamed layer are structured. The consistency of the backing is not adversely affected by the pressurization. The pressure range according to the invention takes into account the consistency of the PU whipped foams used and structured, without essentially that
Change foam structure.
It is advantageous if the layer is dried after being applied to the carrier layer before structuring to a water content of less than 1.5% by weight, preferably less than 0.5% by weight, in particular until it is water-free. This is advantageous for the application of the further layer. An aqueous PU dispersion mixture based on aliphatic and / or aromatic polyether and / or polyester and / or polycarbonate polyurethane is used to produce the PU whipped foam. The PU whipped foam is also produced with a PU dispersion mixture in which the individual PU dispersions used to produce the PU dispersion mixture show different temperatures of their softening point in the dried state. The PU dispersions are selected so that the PU dispersion mixture after drying and any crosslinking, which, however, is only a subcrosslinking, and also after its embossing or structuring
has thermoplastic contact adhesive properties.
The softening point and the adhesive properties of the whipped foam can not only be determined by choosing the softening point of the individual PU dispersions, but can also be controlled by adding crosslinking agents. 0 to 4.2% by weight of crosslinking agent, based on the total weight of the PU foam, is advantageously used. A crosslinker of this type is, for example, the crosslinker XL80 from Lanxess AG.
PU dispersions are advantageously used which have a softening point in the dried, uncrosslinked or undercrosslinked state which is above 45 ° C. and which thus become soft and sticky above this temperature. The softening point can also be above 95 ° C when using crosslinkers. Before and after the crosslinking, the dried PU dispersion mixture should have thermoplastic properties and the PU dispersion mixture is flowable under pressure above the softening point and can be permanently deformed. For embossing, the layer of whipped foam should be honey-like, viscous but not thin, in order to be able to adopt the structure of the die precisely and quickly. Depending on the application of the layer material, the softening point and the adhesive property can be set or selected.
Several PU dispersions can also be used in each case for the production of the proportion of the PU dispersion mixture with hot melt or contact adhesive properties and for the proportion of the PU dispersion mixture without such properties, which two parts are mixed to produce the PU whipped foam , the
each have the desired properties.
Anhydrous polyacrylate-based thickeners with a viscous consistency or foam additives containing ammonia, such as e.g. Millio shape, used. Polyacrylate-based thickeners which stabilize the PU whipped foam are used to an extent of 1.5 to 5% by weight of the total weight of the PU whipped foam.
structurable PU whipped foam to give a desired surface structure.
The PU dispersions used to produce the PU whipped foam advantageously each contain 35 to 52% by weight of PU solid, based on the respective weight of the PU dispersion used, including its additives. The individual PU dispersions are then mixed or mixed into the PU dispersion mixture and the PU dispersion mixture used to produce the PU whipped foam contains 65 to 91% by weight of such PU dispersions, based on the total weight of the PU whipped foam together with all additives .
According to the invention, particularly good properties with regard to the adhesion of the layer to the carrier layer are achieved if a PU dispersion mixture is used which contains between 18 and 52% by weight, based on the finished PU dispersion mixture, of a commercially available PU dispersion based on polyester with a Contains a solid content of approx. 40%, such as that offered by BASF as a heat-activated industrial contact adhesive under the name Luphen. The remaining 39 to 73% by weight are formed by a PU dispersion also containing approx. 40% solids with a softening point above 125 ° C, e.g. a PU dispersion with the designation DLV-N from Lanxess AG. This mixture leads to exceptionally high adhesion properties, especially in the case of microfiber nonwovens and sanded grain leather, without the finished product being worth mentioning
to harden.
The heat-activated polyurethane of PU dispersions which can be used advantageously has
at least a partially linear and / or at least partially crystalline structure and is in
7748
PU dispersion mixtures are primarily used to adjust or optimize the resistance to hydrolysis, adhesion, softness and embossability of the whipped foam and to different
Adapt use cases.
The PU dispersions for the PU dispersion mixture to create the PU whipped foam have a pH of 6 to 9.5.
It is advantageous for longer storage if the dried PU whipped foam is water-free and not cross-linked or under-cross-linked and softens or becomes sticky at a temperature of 110 to 160 ° C or melts highly viscously and flows under the intended pressure around the Structure of the matrix.
The PU whipped foam is produced by introducing a gas, preferably air or nitrogen, into a PU dispersion or a PU dispersion mixture, with enough gas being introduced or hammered into one liter of the PU dispersion mixture that one liter of the starting material is incorporated Volume from 1.10 to 1.70 I, preferably 1.20 to 1.50 I, assumes.
The procedure according to the invention is simple and economical. It is possible for the PU whipped foam to be sprayed onto the backing layer, in particular airless, or applied using the screen printing process or with at least one roller or doctor blade in the same thickness. In this way it is easy to set the desired thickness of the layer of PU foam to be applied.
For special purposes, it can be advantageous if, prior to or simultaneously with the structuring of the PU whipped foam with the application of pressure, with the die onto the layer directly or through its previous application onto the warm die, a further layer of a PU which may have a different color. Dispersion is applied or bound. After solidification or drying, this layer has a thickness of 0.015 to 0.060 mm, preferably 0.020 to 0.045 mm. In this way, in addition to a protective effect for the foam layer, a different coloring for the surface of the layer material can be achieved. Are parts of the applied further layer e.g. removed by lasers and
to transfer them.
The carrier layer or the layer material provided with the layer of dried PU impact foam can be produced in sheets or in the form of blanks and can be stored well after the PU impact foam has dried.
According to the invention, in order to produce a surface-structured layer material, the dried layer, if appropriate simultaneously or together with the further layer, is pressurized with a structured die and, if appropriate, reduced in thickness. The connection of the layer with the carrier layer is thus further improved. This is advantageously done at a temperature of 110 to 160 ° C. A contact time of 2 to 28 s, preferably 6 to 18 s, and a contact pressure of 6 to 48kg / cm "are maintained. The layer made of PU whipped foam can, for structuring, optionally simultaneously or together with the further layer, to a temperature of 110 to 160 ° C, e.g. with IR radiation, can be pressurized and structured and, if necessary, reduced in thickness.
It can be provided that the PU whipped foam contains additives, e.g. gas-filled hollow microspheres and / or pigments and / or polyacrylate dispersions and / or silicones and / or matting agents and / or thickeners and / or crosslinking agents and / or flame retardants. Based on the total weight of the PU whipped foam, 1.5 to 3.5% by weight of hollow microspheres or 2 to 12% by weight of pigments or 1.8 to 4.5% by weight of polyacrylates can be used as thickeners and foam stabilizers or 1 to 4 wt .-% silicones are added.
According to the invention, it can be provided that the PU whipped foam is created in such a way that
that the layer after the structuring with the matrix has a density of 0.80 to 1.05 g / cm * ®. The density depends largely on the type and amount of pigments. A
a black whipped foam.
In addition, it can be provided that crosslinking agents of up to 4.2% by weight and / or 8 to 25% by weight each of a 40 to 60% acrylate dispersion are added to the PU whipped foam. The weight specifications refer to the total weight of the PU whipped foam. In any case, the PU whipped foam is not or not completely crosslinked and remains after an initial structuring process
thermoformable.
The additional layer applied to the surface of the dried PU impact foam need not be thermoplastic and is heat-resistant and resistant to MEK and isopropanol. The further layer takes over the structure of the PU foam layer and the die, even if it is not thermoplastic. Above all, however, the color pigments used with the further layer can have different colors than the layer.
For the creation of a layer material in which a textile material, e.g. a woven or knitted fabric is used, it has proven to be particularly advantageous if, before the layer of PU impact foam is applied to one of a textile material, e.g. Woven or knitted fabric, the backing layer formed on the surface of the textile material as a pre-coating, a thin layer of PU impact foam or of optionally foamed soft PVC, each with a thickness of 0.25 to 0.40 mm, or of an equally strong, crosslinked PU dispersion impact foam layer or a polyacrylate foam layer. The backing layer is thus coated with a layer of foamed soft PVC or a cross-linked PU foam or a polyacrylate layer.
A layer material according to the invention is characterized by the features stated in the characterizing part of claim 11. Such a layer material can be surface-structured even after a long storage period at elevated temperature and simultaneous application of pressure, since it is not cross-linked or created without cross-linking agent or is under-cross-linked and is therefore thermoplastic deformable and remains.
The PU impact foam of the layer material has a specific weight of 0.8 to
1.05 kg / dm®. The layer of PU whipped foam has a thickness of 0.030 to 0.450 mm, preferably 0.075 to 0.450 mm. Polyurethanes are used for the layer,
advantageously aliphatic or aromatic polyurethanes based on polyether or polyester or polycarbonate. The PU foam layer can contain pigments and / or crosslinking agents and / or polyacrylates and / or hollow microspheres. The layer of solidified, dried PU impact foam advantageously has a Shore A hardness of 28 to 68. A structuring is formed or embossed on the surface of the layer and the further layer applied to the layer. The structured layer, even if it contains crosslinkers, i.e. is undercrosslinked, is and remains thermoplastic. The layer of PU whipped foam has a thickness which is only 2 to 18%, preferably 3 to 9%, thicker than a layer which is formed from an equal weight amount of non-foamed PU dispersion or non-foamed PU dispersion mixture of the same composition after this amount has been spread over an area of the same size as the PU whipped foam.
The Shore A hardness is measured in such a way that a large number of the layers to be examined are made and stacked from the respective material, preferably from solidified or dried or structured PU impact foam, and thus a test specimen with a thickness of 5 mm based on to the DIN ISO 7619-1 standard
which is then measured.
The usability and processability of the layer material is optimized or a surface protection of the structured PU impact foam is achieved if, in the case of a carrier layer formed by a textile material, there is a thin layer of foamed soft PVC or of a cross-linked PU between the surface of the textile material and the layer. Dispersion or a crosslinked PU dispersion mixture, preferably made of aliphatic polyurethane based on polyester or polyether or polycarbonate or of a polyacrylate dispersion, which layer has a thickness of 0.25 to 0.40 mm and a connecting layer for the layer to be applied PU impact foam, the two layers possibly forming a total thickness of 0.35 to 0.60 mm.
Advantageously, a thin heat-structurable, non-foamed, further layer of a dried PU dispersion with a thickness of 0.0150 to 0.060 mm, preferably 0.020 to 0.0450 mm, is applied or bonded to the layer, wherein a structure corresponding to the structure embossing in the layer is formed or embossed in the further layer of PU impact foam. The further layer advantageously has a greater Shore A hardness than the layer made of PU impact foam or has a hardness of more than 70 Shore A and
optionally contains 1 to 4 wt .-% polysiloxanes. The further layer preferably consists of more than 45% by weight of polyether-polyurethane based on polycarbonate, such as the product Aquaderm Finish HW2 from Lanxess AG.
If leather is used as the backing layer, it has proven to be advantageous if the grain leather is a full-grain cowhide, preferably cowhide split leather, calf leather, goat leather or kangaroo leather, in which leather the grain layer is advantageously mechanically removed by at least 5% to a maximum of 60% is. A leather fiber material can contain shredded punching waste from upper leather and / or synthetic fibers.
If a microfiber fleece is provided as the carrier layer, it is advantageous if the fibers of the microfiber fleece consist of polyester or polyamide, the cavities between the fibers being impregnated or filled with a plastic, preferably based on polyurethane, which has a foam structure or a coagulated microcell structure having.
The PU whipped foam can advantageously have an open-cell structure and / or be permeable to air and / or a water vapor permeability of more than 0.050 mg / cm “/ h, preferably more than 0.12 mg / cm“ / h, in accordance with DIN EN ISO 14268
exhibit.
According to the invention, the layer material is particularly advantageous for the production of objects such as Cuts, stamped parts, shoe parts, sports and work shoes, shoe insoles, bags, leather goods, steering wheel covers, upholstery covers, interior wall cladding and seat covers for motor vehicles and partially coating for the protective area of textiles, uniforms, work clothing, safety clothing.
The objects created according to the invention have a surface of any shape by means of a die, in which grain leather structures, textile structures, geometric structures, names, logos and surface areas of different structure and / or different roughness can be formed. All that is required is to design the structure-giving surface of the matrix from silicone rubber or silicone resin accordingly. The surfaces of the die can be designed by molding, for example a textile, mechanically or by laser ablation or in a 3D printing process. It doesn't necessarily have to be the one for structuring
surface used in the production of layer material have been processed, but the matrix used can also be a negative matrix
originally created positive matrix.
The invention makes it possible to save material on the polyurethane to be used, since the PU dispersions are foamed and the amount of polyurethane required is thus reduced by the air bubbles contained in the PU foam. This results in a lower weight for the layer made of PU foam. Only water-based PU dispersions are used, which means that the production process is environmentally friendly and harmful or environmentally harmful process residues are avoided. Finally, it is possible to quickly change different matrices, making it easy to individually manufacture objects. It is particularly advantageous if the carrier layer is used in the form of blanks which have been coated with PU impact foam using the screen printing method. There is then no need to dispose of waste from the backing layer, or the PU whipped foam is only applied to the blank, and remnants of backing layers provided with PU whipped foam do not occur. It is particularly advantageous and economical if small format parts or stamped parts are cut out and embossed from a large-area layer material coated with PU impact foam. Such stampings
can be stored well before embossing.
In accordance with the invention, the structuring of format parts and stamped parts is easy to handle, in contrast to entire leather skins or sheet goods. For individual design of the surface, the format or stamped parts, e.g. in a shoe factory, are fed to and removed from a color printing machine and / or an embossing device by means of a computer-controlled tool. In contrast to large matrices, small matrices can be structured easily and inexpensively using digital control. Energy can be saved because the matrix is or remains hot during the structuring process. The structuring process takes only a few seconds. The production of the die with a silicone or textile surface is extremely cost-effective and, unlike stamping tools made of metal or stamping rollers, can be carried out within a day
to be created.
The invention is explained in more detail, for example, with reference to the drawings.
1 schematically shows a section through a layer material constructed according to the invention. 2 schematically shows the structuring process. The
Layer material according to the invention is created in such a way that a layer 2 of a PU foam is attached or applied to the surface of a carrier layer 1. If the backing layer 1 is a textile material, then this textile material can be used as a base layer for precoating on the surface with a layer 5 made of a soft PVC or a PU impact foam, made from a PU dispersion or PU dispersion mixture or from a polyacrylate Dispersion can be provided in order to be able to combine the layer 2 made of PU foam with the possibly coarse textile material. When embossing the layer 2 with the die 4, the layer 2 is deformed, but does not penetrate into the carrier layer 1.
Before it is structured, a layer 3 made of a non-foamed PU dispersion or a non-foamed PU dispersion mixture is applied to the layer 2 made of PU impact foam. With a die 4 shown schematically in FIG. 1, the indicated surface structure 7 can be given to the layer 2 or the layer 3 present thereon. With appropriate presses and when using heating devices, e.g. Infrared emitters - Fig. 2 - the base layer 1 and the die 4 are pressed together. The die 4 can be heated to the required temperature for the embossing process in order to bring the PU whipped foam to the desired softening temperature. If a cold or insufficiently heated die 4 is used, the layer 2 can be heated before it comes into contact with the die 4
be, for example with an infrared heater.
Before embossing, the surface of layer 2 or further layer 3 is smooth and flat.
Compared to non-foamed coatings, the use of a PU whipped foam has the advantage that the surface-structured PU whipped foam is compressible and deformable when embossed under temperature and pressure. Air and moisture that are present when placed on the layer 2 on the die 6 can escape, so that there is no blowholes and bubbles.
When the PU whipped foam has dried, the layer material can be punched into blanks before further processing and the blanks are then independently of one another embossed or surface structured under pressure and
Subjected to temperature.
The layer 3 can either be applied directly to the PU whipped foam layer 2 or it is applied to the die 4 and dried on the die in an anhydrous or virtually water-free manner and, if appropriate, pre-crosslinked or undercrosslinked such that it can be stripped there and hot can be inseparably connected to the PU foam layer 2 during embossing; the embossed layer material no longer shows how layer 3 was applied.
When PU dispersions are hot-dried, hairline cracks and cavities can occur, which, however, are healed during structuring by plasticizing the layer, in particular due to the selected prints, and no longer cause problems.
The procedure according to the invention advantageously uses only non-toxic materials that can be processed economically and safely even by unskilled workers. Furthermore, the embossing of an already dried PU whipped foam is gentle on the die, since the crosslinker contained in the PU whipped foam is not wet and does not come into contact with the die to the same extent as with conventional coatings, because crosslinkers act aggressively on silicone dies and corrode them.
When calculating the specific weight of the PU whipped foam, it must be taken into account that it can contain pigments or additives which have different specific weights depending on the application. For example, titanium dioxide as a white additive for coloring is very heavy, whereas pigments of a different color can have a significantly lower specific weight. If the open-cell PU impact foam also contains gas-filled microspheres, which are known to be closed cells, these must be taken into account when calculating the density by deduction.
The foamed and thermoplastic layer 2 made of PU impact foam is compressed by means of heat and pressure to adopt the negative structure of the die 4. The microfoam is compressed in such a way that part of the microcells is lost and the PU whipped foam still has an open-cell microfoam structure, which then only has a weight of 0.80 to 1.05 kg / dm *. In contrast, a non-foamed, compact layer produced with the same formulation has a density of 1.050 to 1.120 kg / dm®. According to the invention, this gives an advantage in terms of weight and material saved. The compression of the PU foam, which can be controlled during embossing, can also be used in contrast to non-foamed coatings
represent deeper structures at low pressure and it is surprising that the softness is retained.
The fact that the layer 2 is permeable to water vapor and air means that expanding gas or any residual water vapor which arises during hot pressing is discharged through the layer 2 into the carrier layer 1 and there are no voids, bubbles and cracks. When placing the dry layer 2 on the hot or heated die, it is important that the air or residual gases that expand when heated and cannot escape in or through the die, through the open-cell PU foam or through the carrier layer 1 can be dissipated. If the layer did not have an open-cell microstructure, defects would appear in the grain valleys of the matrices, which would present themselves as undesirable pores and gilants.
With the preferred thickness, the thin, harder, non-foamed layer 3 is also air-permeable under pressure, so that the air that is in the grain valleys of the die 4 can also escape.
Structured surfaces by hot pressing are mainly used for shoes, steering wheels, bags, leather goods, etc. According to the invention, format parts e.g. in the dimensions of 0.35 to 0.9 m can be easily produced by punching out sets of format parts from the carrier layer 1 used with little punching waste. A format part can be so large that it covers the shaft parts for a pair of shoes, for example.
The complete PU dispersion mixture advantageously contains up to 4.2% by weight of crosslinking agent, based on the total weight of the PU dispersion mixture, before foaming. Accordingly, the dried PU dispersion mixture is undercrosslinked and remains thermoplastic. The respective PU dispersion mixtures can advantageously contain 8 to 25% by weight of a 40 to 50% acrylic dispersion, which is advantageously combined with isocyanate, to improve the resistance to hydrolysis
can be crosslinked.
If a 50% PU dispersion, i.e. 50 parts of solid and 50 parts of water, as a film of, for example, 0.15 mm thickness, is applied to a support, this film shrinks or collapses when dried by heat by about 50% due to water loss. In addition, the film will crack when dried (e.g. in a heat drying duct) at 120 ° C,
because a skin forms on the surface, which makes it difficult to remove water from the film under the skin. Drying must therefore take place slowly and at a low temperature below 80 ° C over a longer period of time, which is uneconomical. The advantage of the invention is that the whipped foam is not applied directly to the final carrier layer as in the reversal process, so that part of the water is absorbed by the carrier and escapes at temperatures of 100 to 120 ° C in less than two minutes, without cracks and voids arise that are incurable when structuring.
It should be noted that during hot pressing or structuring, the die advantageously lies at the bottom and the layer material with the layer 2 of PU impact foam is placed or arranged on it with the layer facing downward. If matting agents such as TS 100 are used or used, the formation of cracks can be reduced. Even with a layer thickness of 0.25 mm and at a drying temperature of 120 ° C, there are no or no incurable cracks during drying.
Furthermore, a compact PU material cannot easily be embossed at low temperatures, since the material is compressed during the embossing and must be able to flow. Here, the easily deformable and after its softening at the pressures specified according to the invention, foam which is easy to shape offers considerable advantages.
Layer 2 behaves thermoplastic at the time of the surface design and becomes so plastic under pressure and heat that it also molds the finest microstructures of the die surface in layer 3, unless this is also thermoplastic. Nevertheless, the carrier layer 1 with the structured layers 2, 3 can be removed from the die 4 immediately after the embossing, that is to say when the layers 2, 3 are still hot.
The respective PU dispersion mixture (s) contain / contain foaming agents for foaming and for stabilizing the whipped foam, in the simplest case an ammonia-containing foaming agent in an amount of 0.5 to 2% by weight (based on the total weight of the PU dispersion mixture with additives Thickeners, for example based on acrylic (Wesopret A2), can each of the PU dispersion or the PU dispersion mixture in an amount of 1 to 4 wt .-% (based on the total weight of the respective PU dispersion with supplements.
The PU whipped foam is formed by stirring in gas or air using stirrers known per se, similar to a stirrer for producing whipped cream or egg whites.
The PU dispersions used are aqueous PU dispersions.
The softening point is measured and checked on the Kofler Bank.
According to the invention, particularly good deformation properties for the design of the surface and excellent connections between the carrier layer 1 and the foamed layer 2 are achieved if the PU dispersion mixture comprises 18 to 52% by weight of a PU dispersion in the form of a heat-activated contact adhesive or a mixture of contains such PU dispersions, the PU dispersions or the mixture having a PU solids content of 40 to 50% and being heat-activatable and becoming pasty and sticky at a temperature of 45 ° C. Such PU dispersions are heat-activated PU dispersion contact adhesives based on polyurethane, such as the product Luphen from BASF or KECK-DIS 779 from Keck Chemie GmbH or Köracoll 3350 from Kömmerling Chemische Fabrik GmbH. When a crosslinking agent, such as Aquaderm XL 80 from Lanxess AG in Cologne, is added and becomes effective, the softening point of such PU dispersions is shifted to higher temperatures. However, the PU dispersion mixture, which contains the heat-activable contact adhesive, does not lose its thermoplastic properties, even if the dried, water-free layer 2 made of PU whipped foam when the surface is shaped by means of heat and pressure to a temperature of above 110 ° C., preferably above 145 ° C. , has been brought. The PU whipped foam either contains no crosslinker or is undercrosslinked in such a way that its thermoplastic properties or its thermoplastic deformability are retained.
This PU dispersion with melt or contact adhesive properties is mixed with a PU dispersion or several PU dispersions to the extent of 39 to 73% by weight, based on the total weight of the PU dispersion mixture, the softening point of which is higher than 125 ° C. but these PU dispersions or the mixture of such PU dispersions themselves have no melt or contact adhesive properties.
The invention also eliminates the known disadvantage that coatings made with PU dispersions on hydrophobic substrates only achieve insufficient adhesion or bonding. A hydrophobic carrier prevents PU dispersion, which usually contains more than 40% water, from entering the surface of the carrier. This disadvantage of PU dispersions for coating, which is known in the leather industry, is improved according to the invention because, after drying, the PU foam used according to the invention behaves like a heat-activatable hot-melt adhesive when structured, which under pressure ipHeinste-depressions-of the mattress -— deintHage —- uned -—- in — the same way — can also penetrate into the finest recesses of a wearer. The PU whipped foam anchors in the backing like a hot melt adhesive and improves adhesion.
To determine whether a PU dispersion mixture or a PU foam made with it is suitable for structuring, the properties required for hot stamping, such as thermoplasticity, stickiness and flow behavior under heat and pressure, are tested. This is done in such a way that a layer with a thickness of 1.0 mm is formed from a dried, not yet crosslinked PU foam and which has a 0.02 mm non-thermoplastic, non-foamed layer and this in the heating oven or on the Kofler bench at a temperature , in particular from 90 ° C. to 165 ° C., preferably from 110 to 150 ° C., with regard to the properties mentioned. If the result is positive, this layer of PU impact foam is pressed in a press with a silicone rubber matrix with the desired surface structure, which has a Shore A hardness of 75, at temperatures of 110 ° C to 165 ° C and press times of 2 to 18 s and a pressure of 4 to 48 kg / cm pressed. At these temperatures, the PU foam film has to be highly viscous sticky, but must not be thin, must optimally map the die and must be easily removable from the die without deformation, without changing the structure formed. As a rule, the commercial PU dispersions mentioned meet this requirement. A suitable mixing ratio of such commercially available PU dispersions enables adjustments to be made to different applications or different surface structures and different stresses
the softening and embossing temperature can be set or specified. In general, 4 are commercially available for the creation of the matrices
Silicone rubber impression compounds or silicone resins are used, the matrices having a Shore A hardness of 25 to 98. The density of the matrices is more than 1,150
g / cm * ® and are cross-linked by condensation or addition. The matrices created can be engraved by laser or mechanically or can be produced in a 3D printing process
become.
A matrix for structuring a format part cut out of the layer material can, if this matrix was produced in the 3D printing process, also consist of a material other than a silicone polymer. In this case, the melting point of this material must be above 185 ° C and still have the same hardness at this temperature and only a maximum of 5% different than at 20 ° C. For example, epoxy and polyester resins or low-melting metal alloys come into question. It is also possible to form webs and extensions or spikes in such matrices or materials in order to form capillaries in the layers 2, 3 with simultaneous structuring.
The invention is explained in more detail below with the aid of examples.
EXAMPLE 1:
The three-dimensional structure of a braiding material, consisting of 5 mm wide leather straps with depressions between the leather straps of 0.6 to 0.9 mm, was transferred to a die by molding with a silicone rubber compound. The die has a thickness of 2.2 mm and a hardness of 86 Shore A and shows exactly the structure in the negative.
A mixture for a layer 2 was prepared, consisting of:
300 g Köracoll 3350 with a solids content of approx. 48% and an activation temperature of approx. 45 ° C from Kömmerling Chemische Fabrik GmbH.
650 g Cerfan Expert Soft with a solids content of approx. 50%, cannot be activated by heat, from HELCOR-LEDER-TEC GmbH
20 g crosslinker XL 80 from Lanxess AG
10 g Melio Foam AX-03 from Stahl
5g TS 100
5 g micro hollow spheres with a diameter of 20-40 y dry
15 g thickener acrylic dispersion with approx. 60% solids
30 g pigment black
After stirring for 5 minutes, the mixture had a viscosity of 45 seconds in an 8 mm diameter Ford cup.
Then 1 liter of this mixture was foamed to 1.25 liters by blowing in air.
Using an engraved, counter-rotating roller, 390 g was applied to split leather as backing layer 1.
The wet dispersion surface looked homogeneous.
Drying was carried out in a heating oven with air at 105 ° C. in 2.5 minutes to a water content of 0.8%. The thickness of the dried foam layer was then 0.27 mm.
The surface showed fine hairline cracks after drying, but was otherwise flat and free of bubbles.
A further application of a dispersion mixture as layer 3 consisting of:
600 g Aquaderm HW2 from Lanxess AG
350 g DLV-N from Lanxess AG
25 g crosslinker XL 80 from Lanxess AG
100 g water
30 g pigment black
150 g matting agent from HELLER-LEDER GmbH
15 g of handle means HW 283 from Stahl
This mixture had a viscosity of 25 seconds in a Ford cup with a diameter of 4 mm. Using a spray application, 70 g were applied wet and dried to water-free at a temperature of 110 ° C. and air in 1 minute. The fine hairline cracks were visible. The dry layer was 0.025 mm thick. After a storage period of 48 hours, shoe and bag parts were cut out of the layer material with a flat surface and structured in three dimensions. The silicone rubber matrix with its negative structure had a temperature of 145 ° C. The pressure on the part to be structured was 9 kg / cm . He was held up for 10 seconds. The part was then removed from the hot die 4 without effort and pulled off the die without errors. The hairline cracks in the foam layer were closed or removed during plasticization under pressure. The three-dimensional surface had the same appearance and structure as the braiding material made of leather straps. Cross-sections of the coating showed no hairline cracks or voids in the foam layer when magnified 50 times. After structuring, the finished part was as soft as before and was only 0.02% thinner than before
structuring.
EXAMPLE 2:
A format blank for a bag 22 x 28 cm was cut out of the same coated surface material as in Example 1 and embossed three-dimensionally with a textile structure, namely at a temperature of 140 ° C. and a pressure of 8 kg / cm and a dwell time of 7 seconds. The textile material was a self-patterned grid-like polyester fabric with a thickness of 0.6 mm and was connected to a 1.0 mm thin aluminum plate. The three-dimensionally structured part showed the textile structure exactly negative. Removal from the textile matrix was easy and possible without gluing, because the thin, non-foamed layer 3 adapted to the layer 2 and the structuring textile surface without becoming tacky.
EXAMPLE 3
The grain side of a cow grain leather was sanded down by 0.05 mm with 180 grit sandpaper. A PU impact foam with a thickness of 0.220 mm was applied to the ground side to form layer 2 by means of an opposing roller. At a temperature of 110 ° C and circulating air, the water content was reduced to 1.3% by weight in the course of 2.5 minutes. The PU whipped foam only lost 0.06 mm in thickness during drying.
The whipped foam was created from 420 g PU dispersion called KECKDIS 779 from Keck Chemie GmbH with heat-activated contact adhesive properties with a solids content of approx. 40% and 480 g polyurethane dispersion with a high softening point of over 140 ° C and without adhesive properties with an amorphous structure based on polyester and a solids content of approx. 40% with the designation DLV-N from Lanxess AG as well as 20 g meliofoam paste, 30 g thickener, 50 g pigment.
After drying in the heating cabinet, the PU dispersion mixture had a softening point or range which allowed excellent embossing at a temperature of 125 ° C.
This mixture had a volume of 1.07 | and was made with a standard foam beater to a volume of 1.35 | opened or expanded by blowing in air. The whipped cream, which has a whipped cream-like consistency, was applied to the sanded side of the grain leather with a thickness of 0.220 mm and
dried. The embossing took place after 48 hours, the water content of the PU whipped foam being less than 1% by weight.
The embossing was carried out with a die temperature of 125 ° C and a pressure of 8 kg / cm®. The pressure was maintained for 11 seconds.
The structure of the carrier or leather was not visible through the whipped foam or layer 2. The connection or the layer formation was free of voids and bubbles; no idea occurred.
When a further layer 3 was formed on the layer 2 made of PU impact foam, which, as previously stated, was created, the water vapor permeability was 0.8 mg / cm “/ h. In order to create this further layer 3, a layer of PU dispersion mixture, which was not foamed, was formed in a thickness of 0.020 mm after drying on the die 4 used for structuring. Based on their total weight, this PU dispersion mixture was prepared with 60 g PU dispersion based on polycarbonate ether with the designation Aquaderm Finish HW2 from Lanxess AG with a solids content of approx. 35% by weight. 40 g of polyester-based PU dispersion with a solids content of 40% by weight and the designation DLV-N from Lanxess AG were mixed. This PU dispersion also contained 1.8 g of XL 80 from Lanxess AG as a crosslinker, 5 g of pigment paste black, 3 g of polysiloxane, 1 g of matting agent TS 100 and 20 g of water. A dried layer of such a PU dispersion has a Shore A hardness of more than 75.
This PU dispersion mixture with the specified additives was applied to the die 4 without foaming 10 minutes before the structuring process. It was dried to less than 1% water content. The connection of this further layer 3 to the layer 2 of PU foam, which is located on the carrier 1 and was given above, was carried out in the course of contacting the layer 2 with the die 4 at the above-mentioned stamping temperature and stamping pressure. This further layer 3 was inseparably connected to the layer 2 made of PU foam. This layer 3 has a hardness of 75 Shore-A.
The resulting high adhesion of PU dispersion-based layers with hydrophobic
Straps, especially with hydrophobized leathers in combination with the water vapor permeability, is especially for safety shoes of the class S1 and S2
Prerequisite and is easily met with the layer material according to the invention depending on the thickness of layer 2.
It was also found that when using a carrier precoated with a foamed soft PVC, it is preferable to prepare the layer of PU foam only with PU dispersions based on polyester or polycarbonate. In the case of PU dispersions based on _polyether, plasticizer migration could possibly occur in the PU foam.
Commercial PU dispersions are used as PU dispersions to create the PU whipped foam for layers 2 and 5. These commercially available PU dispersions are based on aliphatic or aromatic polyester or polyether or polycarbonate polyurethanes. Such PU dispersions have a solids content of 35 to 52. The pH of such PU dispersions is between 6.5 and 9.5. After removal of water or drying, the film which forms has an elongation at break of 500 to 1100%.
These PU dispersions are crosslinkable, e.g. with XL 80.
The hardness of a dried and crosslinked, non-foamed film or the layer 3 of PU dispersion mixtures which can be used is 45 to 95 Shore-A, preferably 70 to 80 Shore-A. The layers formed are odorless and free of inadmissible chemicals.
It is very advantageous that the thin layer 3 made of non-thermoplastic, non-foamed polycarbonate based on polyether, the wear behavior or
Abrasion behavior and the bending strength of layer 2 improved.
A crosslinker was not added to the layer 2 PU foam in the present example.
After embossing, the following values were obtained for layer 2 provided with layer 3
determined:
1. Wear resistance or abrasion DIN EN ISO 17076-1 H22 1000x: no wear
2, bends DIN EN ISO 540L 125 000 FLEXE: no wear
24/48
3. Liability DIN EN ISO 11644: 24N
In general, 4 commercially available silicone rubber impression compounds or silicone resins are used to create the matrices, the matrices having a Shore A hardness of 25 to 98. The density of such matrices is more than 1.150 g / cm * and is cross-linked by condensation or addition. The matrices created can be engraved using a laser or mechanically.
EXAMPLE 4
A PU dispersion mixture was created with:
460 g _ commercially available PU contact adhesive dispersion with _ heat-activated contact adhesive properties and with a solids content of approx. 40% by weight.
510 g of commercially available PU dispersion based on aliphatic polyether with a solids content of 40% with a softening point of a dried layer (0.5% by weight of water) of 155 ° C. and a hardness of 55 Shore-A in the dried state, 40 g Pigment paste black,
2 g thickener in the form of polyacrylate,
15 g foam paste Melio Foam,
20 g cross-linked,
10 g polyacrylate dispersion with a solids content of 50% by weight,
5 g hollow microspheres with a diameter of 20 u
One liter of one of these PU dispersion mixtures was opened to 1.25 |.
A layer of 0.25 mm was applied to a microfiber fleece with an oppositely driven application roller and dried within 2 minutes in a circulating air dryer at a temperature of 115 ° C. to a water content of 1.0% by weight. After 3 hours, the layer 3, as in Example 3, was applied directly to this layer 2, in an amount such that the dry layer 3 has a thickness of 0.02 mm and at a temperature of 135 ° C and a pressure of 8 kg / cm ”for 15 seconds with a surface-structured silicone matrix and structured.
Then stamped parts are made from it. The stamped parts show the positive exactly the structure of the negative matrix, which had the appearance of kangaroo leather. Layer 2
had a thickness of 0.100 mm and the adhesion between the support and the layer 2 was 38 N / cm.
EXAMPLE 5
A PU whipped foam according to Example 2 was applied to a kangaroo leather with ground scars by means of a roller in a thickness of 0.24 mm and dried at a temperature of 95 ° C. to 1% by weight of water. Afterwards, shoe uppers were punched out for soccer shoes and, as shown in Example 4, structured. A layer 3, as created in Example 3, was applied to the layer 2 using the screen printing method, specifically in such a way that the layer 3 had a thickness of 0.018 mm when dry. The thickness of layer 2 was 0.110 mm and the adhesion between support 1 and layer 2 was 22 N / cm.
EXAMPLE 6
A mixture of PU dispersions, but in the color white containing 12 g of titanium oxide, was foamed in accordance with Example 4 and the PU foam foam was applied airless to form layer 2 with a thickness of 0.22 mm wet on a microfiber fleece and at a Temperature of 120 ° C dried to less 1 wt .-% water for 2 minutes. The dried layer 2 has a thickness of 0.10 mm. Then shoe uppers are punched out. A 0.025 mm thick, non-foamed PU dispersion mixture, which had a thickness of 0.020 mm when dried, was applied to an unstructured die. The solids content of this PU dispersion mixture was 35% by weight. Furthermore, this PU dispersion contained 5% by weight of red pigment paste. The stamped parts were placed on the layer 3 on the die 4 and, as described in Example 2, pressed, the layers 2 and 3 being inseparably connected to one another and the textile structure of the die being transferred negatively to the embossed part.
EXAMPLE 7
A carrier made of textile material was precoated with a soft PVC foam and another carrier made of textile material was coated with PU foam as a sheet material with a thickness of 0.30 mm and a composition corresponding to Example 4 as used to form a layer 2 was used, but contains 5 wt .-% crosslinker. On each of these pre-coated substrates, a heat-structurable layer 2 made of PU impact foam by means of a doctor blade in a thickness of
0.15 to 0.45 mm applied and dried to a water content of less than 1 wt .-%. An unfoamed layer 3 of a PU dispersion mixture with a thickness of 0.035 mm was applied to this layer 2. This PU dispersion mixture had a solids content of 35% by weight and a crosslinker content of 3% by weight. After layer 3 had dried, the blank or layers 2 and 3 were structured at a temperature of 155 ° C. and firmly connected to one another and to layer 5.
The invention is particularly advantageous for the production of format and blank parts, e.g. for shoes or steering wheels. The result is an all-over good connection between the respective carrier material 1 and the layer 2. At the same time, there is a temperature resistance up to 125 ° C. The requirement is met that up to these temperatures can be stored for 24 hours, the structure of the surface, its color and the degree of gloss or an intended mattness must not change or not significantly change. Extreme requirements arise in the molding of matrices which have a surface structure which have been obtained by molding a fabric made of fabric fibers or in the molding of surfaces of carbon fiber fabrics. The structure molded on the layer 2 corresponds exactly to the matrix structure in its three-dimensionality as well as the degree of gloss and mattness.
Precise three-dimensional imaging is achieved particularly well if a thin PU dispersion with a thickness of 0.025 to 0.06 mm from a cross-linked PU dispersion with a softening point of more than 125 ° C. is applied to the die 4 before the layer 2 is applied is applied. This PU dispersion contains polycarbonate-based polyurethanes, e.g. Aquaderm Finish HW2 from Lanxess AG, and / or aliphatic polyester and / or polyether and has a hardness after crosslinking of more than 75 Shore-A. PU dispersion mixtures of this type contain a solids content of 25 to 35% by weight and, as an additive, 2 to 3% by weight of crosslinking agent, up to 6% by weight of pigments, 1 to 3% by weight of polysiloxane and matting agents. This layer 3 is applied to the dried PU layer 2 in the manner already described.
Especially for layer material in the form of sheet goods, in particular with a textile carrier 1 made of woven or knitted fabric, a pre-coating is carried out with a layer 5 made of foamed soft PVC or a cross-linkable PU impact foam or a cross-linkable polyacrylate dispersion. It is advantageous here to apply the whipped foam layer 2 to the layer 5 by means of a doctor blade. After drying this layer is on
this layer 2, the layer 3, preferably applied with a pressure roller. The applied PU layers 2 and 3 are dried on the web-shaped carrier 1 with the layer 5 in the continuous dryer. The three-dimensional structuring is carried out in such a way that format parts and blanks having the layers 5 and 2 or 3 on the carrier layer 1 are punched out of the sheet material. The layer 2 made of PU impact foam and the non-foamed layer 3 are brought to a temperature, in particular from 145 to 165 ° C., by means of the heated die 4 or infrared radiators.
In the case of a carrier 1 precoated with soft PVC, it is advantageous to choose the temperature and / or the embossing speed and / or the pressure such that the PVC layer is at least slightly co-structured.
For the structuring, the PU whipped foam should not be thin, but pasty and easy to shape under pressure, so that the fine structures of the die can be reproduced.
An advantageous consistency of the PU whipped foam of layer 2 is when the PU whipped foam has a melt viscosity similar to that of soft PVC at a temperature of 160 to 180 ° C., that is to say it is flowable and deformable under pressure. This also applies if a further layer 3 is applied to this layer 2 before the structuring of layer 2.
The formation of a corresponding degree of softening or a desired deformation consistency can be controlled via the amount of crosslinking agent used and / or via the mixing ratio of PU dispersions with a low or higher softening point or softening range.
Matting agents, in particular the TS100 matting agent from Evonik Degussa GmbH used for layers 2 and 3, improve haptics, facilitate drying, lead to a dry grip and improve water vapor permeability.
Layer 2 is dried under heat in a dryer or continuous dryer. It is advantageous to dry as far as possible, preferably to be free of water.
The required temperature and the required residence time are easy to determine empirically. Because the water content of PU dispersions or PU foam
is exactly known, e.g. Weighing can also be used to determine how much water has already evaporated when drying. You can also see that it is water-free if no disturbing water vapor evaporates during structuring.
To determine the water content in the dried PU dispersion or PU dispersion mixture when exposed to heat, it can also be determined how large the residual water content is after certain different residence times in the drying oven. It is therefore easily possible to achieve a desired residual water content or to set the required temperature and residence time for it. Freedom from water can also be achieved in this way, and the parameters required for production can thus be determined. The water is advantageously removed completely or almost completely.
The reduction in the thickness of the layer 2 is particularly suitable for sanded grain leather and carrier 1 made of microfiber fleece and for leather fiber materials from which format or. Stamped parts for shoes and leather goods are created that are to be structured on the surface. When the layer 2 is compressed, the resilience, abrasion resistance and the bending behavior of the layer 2 are improved.
The structuring or the design of the surface by means of heat and pressure and a silicone rubber matrix or a matrix made of textile material can also be carried out in a vacuum process, that is to say under negative pressure. For example, matrices with textile surfaces can be used, or the space between the press plates is evacuated. Such pressing processes using vacuum or vacuum
are known.
When structuring the PU impact foam or the layer 2, it is possible according to the invention to place reinforcement and / or molded parts for the layer material on the die 4 and / or on the layer 2. In the pressing process taking place under pressure and at elevated temperature, these parts are firmly connected to layer 2 and layer 3. These reinforcement or molded parts can be designed as desired and have the shape of strips, circles, stars, geometric or other figures, etc. The main materials that can be used are plastic films that connect to layer 3, especially those made of thermoplastic PUR.
The Köracoll 3350 contact adhesive is also a PU dispersion with heat-activated hot-melt adhesive properties to create the PU dispersion mixture
Kömmerling Chemische Fabrik GmbH, Germany, and DIS type 779 adhesive from Jakob KECK Chemie GmbH, Germany.
Due to the permanent thermoplasticity of layer 2 and the thin thickness of layer 3, embossing of the layer material, in particular stamped parts, can also take place after prolonged storage, e.g. of 6 months, without loss of quality.
According to the invention, it is advantageous if blanks are formed or punched out of the coated carrier layer 1 and these blanks are subjected to the embossing or structuring process, if appropriate after intermediate storage. These blanks have a flat two-dimensional surface that can be deformed accordingly during structuring and then a three-dimensional structure
having.
It is possible, before structuring onto the flat two-dimensional surface of the format blanks or blanks or stamped parts 30 onto the layer 3 e.g. in a shoe factory, to print with the desired color or to print color pads, foils 6 with motifs or color foils and thus to color layer 3 for format parts or to provide them with motifs. Colors can be applied, for example, in the Panton or screen printing process. After the color prints have dried, the embossing process can be started to form the three-dimensionality. These printed color layers preferably have a composition similar to that of layer 3.
For structuring, it is advantageous if the matrix made of silicone rubber material or silicone resin has a Shore-A hardness of 25 to 98. The die is thus designed to be pressure-elastic and can compensate for unevenness, such as can occur in the backing layer 1 if it is a natural material such as leather. The same also applies to matrices with a textile surface, especially if the textile surface has a thickness of more than 0.5 mm. The silicone rubber matrices and the matrices with textile surfaces can be supported with a heatable metal base 20 and via this to the for the
Structuring process provided temperature can be heated. It has proven to be advantageous if between the carrier layer 1 of the stamped part 30
and the press plate 12, i.e. a metal plate, the press used for the structuring process is a pressure-elastomeric support part 10, which has a thickness of
about 1 to 8 mm, preferably 2 to 6 mm, has a foamed structure and a Shore-A hardness that is comparable to the Shore-A hardness of the silicone rubber matrix 4. Thickness fluctuations in the carrier layer 1 can thus be fully compensated for, so that the embossed area of the stamped part or the stamped part has the same stamping structure everywhere. Furthermore, any partial hardening of the carrier layer 1 is completely ruled out, although the carrier layer 1 can have thickness fluctuations of 5 to 10%.
It is also possible to use Astacin Finish PS from BASF for the PU coating dispersions used in layer 2, which still have no stickiness or adhesive properties at 125 ° C. The product Aquaderm Finish HW2 from Lanxess AG has proven to be very advantageous for thin layer 3.
It is economically important that large amounts of material can be saved with the procedure according to the invention, since the shoe and leather goods industry is supplied with blanks or punched parts which are cut or punched out of the layer material and these themselves with the desired color and / or can print desired gloss level and / or the desired pattern. It is therefore no longer necessary to keep large-area leather skins and minimum quantities per color as well as sheet goods and thus large quantities of waste material for the production of blanks and stamped parts, only the blanks that are already required for the embossing process, which are then stored by the product manufacturer with a color print, structured and at the same time
can be provided with a logo and a brand at the same time.
Even if the layer 2 is not cross-linked or under-cross-linked and the layer 3 is completely cross-linked or under-cross-linked, a firm, inseparable connection occurs between the layers 2, 3. The layer 2 remains thermoplastic and the further layer 3, which is thinner and harder than the layer 2 and possibly not thermoplastic, cannot separate after three-dimensional structuring has taken place
be embossed several times or additionally structured with other embossments.
2 schematically shows a device for structuring blanks 30. The blank 30 comprises a carrier layer 1 and any layer 5 that may be present, which is advantageously formed on a structured fabric. Layer 2 is applied to carrier layer 1 and further layer 3 is applied to this layer 2. A finish layer 6 applied to the layer 3 can be a colored layer or a colored or
Be color pattern film that has about the same thickness as the layer 3. The finish layer 6 can, for example, also be a printed or sprayed-on leather paint.
For structuring, a stamped part or the blank 30 is applied to the die 4 with its surface structure 7.
The die 4 rests on a heatable or temperature-controllable base or metal plate 8 which can be heated with a heating unit (not shown). Between the press die 12 and the carrier layer 1 there is an insert 10 made of elastomeric material which is carried by the press die 12. This elastomeric material serves to unevenness in the carrier layer 1, which is a natural product,
balance.
13 designates an airtight envelope of the press unit 11, which can be evacuated via an outlet 14, which is shown schematically, in order to trap air from the blank 30 or from the space between the blank 30 and the die 4
to be able to remove.
The color or finish layer 6 is always applied to the further layer 3 before structuring and assumes the same structure as the layer 3. The color and / or the degree of gloss and / or the embossing for individual blanks can thus be regulated individually in the desired areas. This enables individual production that only requires a few meters of layer material. For custom-made products, it is currently necessary to manufacture or accept a few hundred meters of layer material. There is thus the possibility of high savings
to be able to make or minimize a waste of resources.
In order to prevent or complicate counterfeiting or imitation of products and brands, 4 symbols and / or brands and / or marks can be formed in the silicone rubber matrix, which are transferred to the stamped part or blank when structuring.
Protection against copying can also be achieved if the further layer 3 and / or any color print applied to this layer 3 deviate in color from the color of layer 2. Furthermore, the further layer 3 and / or the color print can be removed by means of a laser, in particular pixel by pixel, so that
the color of layer 2 becomes visible. In the course of laser processing, continuous capillaries can also be formed in the layers 2, 3, with which the water vapor permeability of the layer material or a region of the object produced, which was created with the stamped part, is set to a desired value.
The carrier layer 1 is not visible through the PU impact foam of the layer 2, and different carrier layers can thus be given the same appearance by structuring the surface of the layers 2, 3 in the same way.
The PU dispersions are all aqueous dispersions.
To form the PU dispersion mixture, one or more PU dispersions with hot melt or contact adhesive properties and one or more PU dispersions without such properties can be used or mixed.
The heat-activatable PU dispersions are made of aliphatic polyurethane based on polyether or polyester and can also contain adhesive resins. The PU dispersions have a pH of 6 to 9 and
are miscible with each other.
The PU dispersion mixture has a pH value of 6 to 9 in the uncrosslinked state and an elongation at break of 550 to 1100% in dried or solidified form. The hardness is between 28 and 75 Shore-A.
The non-thermoplastic PU dispersions are made from aliphatic polyester, polyether, polyurethane or polycarbonate polyurethanes. They are also fully miscible with one another. However, they do not have any adhesive properties between 95 and 125 ° C. As a rule, like the heat-activated PU dispersions, they have a solids content of 35 to 52% by weight.
A mixture approach for layer 2 for a PU dispersion mixture preferably contains one to three PU dispersions with heat-activated adhesive properties and one to four PU dispersions with different hardness without adhesive properties. According to the invention, the properties of layer 2 such as hardness, density, thermal embossability, adhesive properties, M softness, permanent bending behavior,
Resistance to hydrolysis and the connection of the layers to one another optimally
be adapted to the respective purpose.
Layer 2, which is advantageously thermoplastic and thus can be shaped independently of time, offers considerable production-related, technical advantages.
The combination of layers 2 and 3 is important according to the invention. Layer 2 is thermoplastic and therefore only insufficiently resistant to abrasion when exposed to heat and also has an insufficient resistance to MEK or isopropanol. This disadvantage is made up for by layer 3, which is composed of polyether, polyester, preferably polycarbonate-polyurethane, such as the product HW2, and which both contain 2 to 5% by weight of crosslinking agent and can also be fully crosslinked. In the event that the limit of 4.2% by weight crosslinker is exceeded, layer 3 is no longer thermoplastic. Surprisingly, a cross-linked layer 3 is not an obstacle to embossing, although it is not thermoplastic, since due to its small thickness it is completely adapted when structuring the surface shape given to the thicker layer 2 and completely adopts the structures of the die 4.
The thermal abrasion resistance shows no damage at an ambient temperature of 50 ° C based on DIN EN ISO 17076-1 H18 1000g 500x.
When 1 g of MEK was applied to layer 3, which was inseparably connected to layer 2, under normal ambient conditions in an area size of 100 x 100 mm, this amount evaporated in 3 minutes without damaging the surface. The same amount of MEK applied directly to a layer 2 under the same conditions showed that the MEK penetrated into layer 2 and caused strong swelling, which, however, receded after evaporation. The combination of the layers 2 and 3 takes advantage of the property of the thermoplastic layer 2 and the disadvantages of a thermoplastic layer compared to chemical solvents are exerted by the layer 3, even if it is not thermoplastic
is avoided. Layer 3 is 0.015 to 0.060 mm thick and is always thinner and harder than that
Layer 2 formed. Layer 3 consists of a PU dispersion mixture, which is preferably composed of more than 45% by weight of polycarbonate polyurethane.
In order for the layer 3 to be subordinate to the structuring of the thermoplastic layer 2 regardless of its degree of crosslinking and its hardness, it is important that it is always significantly thinner than the layer 2 and does not become sticky even at temperatures of 125 to 165 ° C.
The specified thicknesses for layers 2, 3 apply to dry layers.
When applying, enough PU dispersion must be applied that after drying a layer 2 thickness of 0.075 to 0.45 mm is created. Layer 3 has a thickness of 0.015 to 0.060 mm; this strength is also always to be understood dry.
Important critical points were examined, namely the adhesion between the backing layer and the layer 2 as well as the wear resistance or abrasion and the fatigue behavior, or it was examined how the material behaves at elevated temperatures, e.g. 50 ° C, in use at normal temperatures, e.g. 22 ° C, and what happens if solvents, e.g. MEK or isopropanol.
The adhesion of the coating was tested based on DIN EN ISO 11644. No changes were found between normal temperature and an ambient temperature of 50 ° C. The layer material tested at 50 ° C had about 6% higher values than the layer material tested at normal temperature. Ground kangaroo leather served as the backing layer 1. All results were above the setpoint of 12 N.
The wear resistance and abrasion were tested in the Taber based on DIN EN ISO 17076-1 at normal temperature and at 50 ° C, with the H22 friction wheel, 1 kg,> 1,000 tours. After 500 tours, all test specimens were in order and the standard test was fulfilled.
The permanent bending behavior was tested based on DIN EN ISO 5402 at 50 ° C. After 100,000 tours, all test specimens were still in order.
The term "fully cross-linked" means that the PU material has no thermoplastic properties, and when heated, the destruction point is usually reached before the melting point. “Fully crosslinked PU dispersions” are understood here to mean that 50 g of XL 80 isocyanate crosslinker are added to 1 kg of PU dispersion with a solids content of 40%. The products networked in this way are e.g. MEK or isopropanol insoluble, but may swell through
Absorption of these solvents slightly. The thermoplastic, foamed, crosslinker-free or low-crosslinker layer 2 also absorbs like a sponge due to its foam structure, swells and becomes sticky. In combination with the further layer 3, especially if this contains a high proportion of polycarbonate based on polyether, e.g. the product Aquaderm Finish HW2 from Lanxess AG, this thin additional layer 3, although it also contains only 2 to 4% crosslinker, prevents swelling and dissolving of layer 2. If e.g. If 1 g of MEK is applied to an area of 100 x 100 mm, the surface does not swell or does not interfere. When evaporating, the embossing shows the previous grain structure again. Only a slight shine remains. Acetone behaves similarly. Isopropanol does not dissolve, swell or shine the surface.
If layer 2 is to have a softness of less than 55 Shore-A, it is possible within the scope of the invention to add 5 to 20% by weight of the total mixture of a soft PU dispersion with the name Epotal FLX 3621 from the company to the total PU dispersion mixture To add BASF. After solidification, this Epotal FLX 3621 PU dispersion has a hardness of less than 28 Shore-A. The amount added is subtracted from the non-thermoplastic PU dispersions.
The structured silicone rubber layer of the die 4 is advantageously connected to a metal plate 20, preferably an aluminum plate. It is also advantageous if a non-woven material based on polyester with a basis weight of 80 to 150 g / m In the silicone rubber material on the back of the silicone rubber is embedded to prevent the thermal expansion of the silicone rubber. The same applies to a matrix with a textile surface. The silicone rubber with the embedded fleece advantageously has a thickness of 0.8 to 2.0 mm. The connection to the metal plate 20 favors the heat transfer from the heating plate 8 via the metal plate 20 to the silicone rubber of the die 4. This aluminum plate, if provided, has a thickness of 0.8 to 4.0 mm. It can have thorn-like webs 19 to approximately 1.5 mm in length. The distances between the webs 19 can be filled with silicone rubber, in such a way that during embossing the tips protruding from the silicone rubber penetrate the layer 3 and the layer 2 and leave visible indentations in the layer material when they are pulled off.
When structuring, these spikes or webs 19 only penetrate through layers 2 and 3
and advantageously penetrate up to a maximum of 0.4 mm into the carrier 1. So that can
Breathability of the layer material can be improved without the backing layer 1
to weaken significantly.
The webs or thorns can have a round cross-section but also any other shape. The distances between the individual webs are 4 to 12 mm.
The metal plates with the thorns or webs 19 can be prefabricated. The thickness of the silicone rubber matrix can be used to specify how deep the webs penetrate the layers 2, 3 or penetrate into the carrier layer 1. In Fig. 3, such a die 4, which is penetrated by webs or projections and tips 19, is shown schematically.
If the stamped part to be embossed is to be provided with a textile structure, the spaces between the thorn-like webs 19 can also be covered or filled with a textile material with any surface structure. When embossing, the depressions and a surface with a textile appearance are created. Here, textile material takes the place of the structured silicone rubber material. Instead of silicone rubber material, the plate 20 carries a temperature-resistant structure or a temperature-resistant textile material, from which the surface is molded.
The invention relates not only to a method for producing a surface-structured layer material, but also to a method for structuring layers which have been created or cut out from the layer material according to the invention
or punched out format parts.

权利要求:
Claims (17)
[1]
1. A process for producing a surface-structured layer material which has a backing layer (1) and a layer (2) of polyurethane connected to it, the backing layer (1) being a leather, preferably a ground grain leather, preferably a split cowhide leather, a textile material , preferably a woven or knitted fabric, a leather fiber material or a microfibre fleece, is used and connected to the layer (2), at least one, preferably a single, layer of PU impact foam being applied to the carrier layer (1) as layer (2) is characterized by
that the PU whipped foam is produced with a PU dispersion mixture, the individual PU dispersions used to produce the PU dispersion mixture showing different softening points in the dried state,
- That to create the PU dispersion mixture one or more PU dispersions with heat-activated hot melt or contact adhesive properties and with a softening point in the dried state higher than 40 ° C, preferably higher than 45 ° C, to the extent of 18 to 52 wt .-% of finished PU dispersion mixture and one or more PU dispersions without melt or contact adhesive properties and with a softening point higher than 95 ° C, preferably higher than 125 ° C, mixed to the extent of 39 to 73 wt .-% of the finished PU dispersion mixture become,
that the PU dispersion mixture for the layer (2) is applied to the carrier layer (1) with a thickness such that it has a thickness of 0.075 to 0.450 mm in the dried state,
- that before or at the same time as structuring the PU whipped foam, a further layer (3) is applied to the layer (2) from a non-foamed PU dispersion which is a mixture of several PU dispersions, and
- That the carrier layer (1), the further layer (3) and the layer (2) with the application of a contact pressure of 4 to 48 kg / cm , preferably from 18 to 25 kg / cm , pressed together and connected and with a die (4) structured
become.
2, Method according to claim 1, characterized in that the layer (2) after its application to the carrier layer (1) and before the structuring to a water content of less than 1.5% by weight, preferably
less than 0.5% by weight, in particular until water-free, is dried, and / or
- The PU dispersions are selected so that the PU dispersion mixture has thermoplastic properties after drying and also after any sub-crosslinking, and / or
- That the PU dispersion mixture used to form the PU whipped foam contains 65 to 91% by weight, based on the total weight of the PU dispersion mixture, PU dispersions, each 35 to 52% by weight, based on the weight of the respective PU dispersion, contain solids, and / or
- That the polyurethane of the PU dispersions used, which have heat-activated adhesive properties, at least partially has a linear and / or at least partially crystalline structure and / or is thermoplastic, and / or
- That the composition of the PU dispersion mixture is chosen so that the layer (2) has a hardness of 28 to 68 Shore-A after drying and structuring, and / or
- That the PU whipped foam for the layer (2) is created in such a way that the layer 2 has a density of 0.80 to 1.05 g / cm® in the dried or almost water-free state, and / or
- That the PU foam for the layer (2) with a thickness is applied to the carrier layer (1), that it has a thickness of 0.075 to 0.45 mm in the dried state, and / or
- That the PU dispersion mixture for layer 2 between 1 and 5 wt .-% thermoplastic plastic particles are added to the structuring or at the temperature for structuring in the layer
[2]
2 hollow microspheres with one
Form diameters up to 40 µm.
[3]
3. The method according to claim 1 or 2, characterized in that the PU whipped foam is created by introducing a gas or gas bubbles, preferably air or nitrogen, into the PU dispersion or the PU dispersion mixture, with one liter of the PU dispersion or PU dispersion mixture is introduced or hammered in so much gas that a liter assumes a volume of 1.10 to 1.70 liters, preferably 1.20 to 1.50 liters.
[4]
4. The method according to any one of claims 1 to 3, characterized in
- That a matrix (4) made of silicone rubber material is used as the material, which is in each case applied to a metal plate (20), with the metal plate (20) optionally penetrating the silicone rubber material or the textile fabric or projecting into its structural cavities, preferably 0 , 5 to 1.2 mm long, needle-like or thorn-like extensions or webs with a diameter or a width of 0.8 to 1.5 mm, preferably with a tapering cross-sectional area, and / or
- That a PU whipped foam is used, which can be surface structured after drying.
[5]
5. The method according to any one of claims 1 to 4, characterized in
- That the PU whipped foam is sprayed onto the carrier layer (1), in particular airless, or is applied in the screen printing process or with at least one roller or a doctor blade in the same thickness, and / or
that when a microfiber fleece is used as the carrier layer (1), the spaces between the fibers of the fleece with coagulated or foamed plastic foam,
preferably based on polyurethane, are at least partially filled.
[6]
6. The method according to any one of claims 1 to 5, characterized in that before the structuring of the surface of the layer (2) made of PU foam on the structuring matrix (4), the further, optionally a different color than the layer (2) Layer (3) made of a non-foamed PU dispersion, preferably a PU dispersion based on polyether polycarbonate or polyester, or such PU dispersion mixture in a thickness of 0.015 to 0.060 mm, preferably 0.020 to 0.045 mm, which is a maximum of 1.5% by weight .-%, preferably a maximum of 0.5% by weight, contains water, in particular has been dried anhydrous, has no adhesive properties at least up to a temperature of 110 ° C. and is solidified and / or crosslinked to such an extent that it is separated from the structured matrix (4th ) can be removed without sticking, and that this layer (3) on the die (4) heated to a temperature of 90 to 145 ° C. is brought into contact with the layer (2), pressurized > and is connected to the layer (2) during the structuring which takes place at the same time, wherein
[7]
7. The method according to any one of claims 1 to 6, characterized in that the further layer (3) is applied to the layer (2) by directly before the structuring of the layer (2) with a die (4), the further layer ( 3) from a PU dispersion or PU dispersion mixture, which may have a different, preferably greater, hardness and / or color, is applied to the layer (2) and bonded to it in the course of structuring, the further layer (3) being provided by one non-foamed PU dispersion or PU dispersion mixture is formed and is applied in a thickness such that after drying it has a thickness of 0.015 to 0.060 mm, preferably 0.020 to 0.045 mm, optionally with a water content of at most 1.5% by weight .-%, preferably at most 0.5% by weight, water, in particular water-free, is dried.
[8]
8. The method according to any one of claims 1 to 7, characterized in that - for structuring, the die is heated to a temperature of 110 to 165 ° C, a contact time of 2 to 18 s being maintained for a heated die (4) , and / or the layer (2), with the layer (3), to a temperature of 110 to 165 ° C, for example with IR radiation, and pressurized and structured with a die (4), which is optionally heated to 110 to 145 ° C.
[9]
9. The method according to any one of claims 1 to 8, characterized in
- That additives, preferably gas-filled hollow microspheres and / or pigments and / or polyacrylate dispersions and / or silicones and / or matting agents and / or thickeners and / or crosslinking agents and / or foaming agents and / or flame retardants, are added to the PU dispersion or PU dispersion mixture be, and / or
- The PU impact foam is subjected to heat and pressure such that the layer (2) after structuring with the die (4) has a density of 0.80 to 1.050 g / cm®, preferably 0.810 to 0.970 g / cm®, owns, and / or
- That the PU dispersion mixture crosslinkers in the amount of 0 to 4.2 wt .-%, preferably 0.9 to 3.2 wt .-%, based on the total weight of the PU foam, are added and also after a pressure and temperature
structuring continues to be thermoplastic, and / or
- That PU dispersion mixtures are used for the creation of the PU whipped foam, in which after a drying process a dry layer of the PU whipped foam produced therewith with an area of 1 m * and a thickness of 1.0 mm before structuring 0.800 to 1.050 kg weighs, and / or
- That from a large area, coated with PU foam foam (1) format parts or stamped parts are separated and embossed, and / or
- That, after the PU whipped foam has dried, the not yet structured backing layer (1) with the layers (2, 3) is punched into blanks before further processing or before its structuring, and the blanks are then embossed or structured independently of one another be subjected to pressure and temperature, and / or
- That the layer (2) and the further layer (3) are formed with a different composition and / or pigmentation or color, in particular with a different content of crosslinking agent, and exhibit thermoplastic behavior, and / or
- That a color or finish layer (6) is applied to the further layer (3) prior to structuring, this color or finish layer having been advantageously printed on and, if appropriate, of one adhering to the layer (3) or connectable to it Color or colored layer or colored or colored pattern plastic film is formed, and / or
- That stamped parts or format parts 30 worked out of the layer material
structured under the specified pressure and temperature.
[10]
10. The method according to any one of claims 1 to 9, characterized in that before applying the layer (2) made of PU foam on one of a textile material, e.g. Woven or knitted fabric, carrier layer (1) formed on the surface of the textile material, a thin layer (5) of optionally foamed soft PVC or of a foamed or non-foamed, crosslinkable PU dispersion or a non-foamed, crosslinkable PU dispersion mixture of aliphatic and / or aromatic polyurethane based on polyester or polyester is applied to a crosslinkable polyacrylate dispersion, which is a connecting layer for the layer (2) of PU impact foam to be applied and has a thickness of 0.25 to 0.40 mm after drying.
[11]
that the layer (2) is formed by at least one, preferably a single, layer of a non-crosslinked or undercrosslinked, PU impact foam, which optionally has a maximum water content of 1.5% by weight, preferably 0.5% by weight, has, in particular is anhydrous, the layer (2) has a softening point above 90 ° C and is tacky at a temperature of 110 to 165 ° C, has thermoplastic properties and is flowable and deformable under pressure, and - that a further layer ( 3) applied to the layer (2) from a non-foamed PU dispersion and connected to this layer (2).
[12]
12. Layer material according to claim 11, characterized in
- That the PU foam of the layer (2) has a specific weight of 0.800 to 1.050 g / cm *, and / or
- That the layer (2) of PU foam has a thickness of 0.075 to 0.450 mm, and / or
- That the polyurethanes used for the layer (2) are aliphatic polyurethanes based on polyether or polyester or polycarbonate, and / or
- That the layer (2) made of PU impact foam contains pigments and / or crosslinking agents and / or polyacrylates and / or hollow microspheres and / or matting agents, and / or
- That the layer (2) of solidified, dried PU impact foam has a ShoreA hardness of 28 to 68, and / or
- That the layer (2) contains 0 to 4.2% by weight, based on the total weight of the layer (2), of crosslinking agent, and / or
- That the layer (3) at temperatures of 125 to 165 ° C is not or not yet sticky.
[13]
13. Layer material according to claim 11 or 12, characterized in that in the case of a carrier layer (1) formed by a textile material between the textile material and the layer (2), a thin layer (5) made of foamed soft PVC or of a crosslinked foam layer made of PU dispersion or a polyacrylate dispersion is formed, which layer (5) has a thickness of 0.25 to 0.45 mm and a connecting layer for the layer (2) made of PU
[14]
14. Layer material according to one of claims 11 to 13, characterized in that the thin, heat-structurable, non-foamed layer (3) applied or bonded to the layer (2) from a PU dispersion or PU dispersion mixture on aliphatic polyether polycarbonate and / or polyester base, has a thickness of 0.0150 to 0.060 mm, preferably 0.020 to 0.0350 mm, wherein in the layer (2) made of PU foam a structure corresponding to the structure embossing in the layer (3) is formed or embossed and wherein the layer (3) advantageously has a greater Shore A hardness than the layer (2) or a hardness of more than 70 Shore A and optionally contains 1 to 4% by weight of polysiloxanes.
[15]
15. Layer material according to one of claims 11 to 14, characterized in
- That the grain leather is a full-grain cowhide, preferably cowhide split leather, calf leather, goat leather or kangaroo leather, in which leather the grain layer is advantageously mechanically removed by at least 5%, and / or
- That the fibers of the microfiber fleece consist of polyester or polyamide, the cavities between the fibers being impregnated or filled with a plastic, preferably based on polyurethane or polyester, which has a foam structure or a coagulated microcell structure, and / or
- That the leather fiber material contains between 13 and 48 wt .-% synthetic fibers, and / or
- that the PU whipped foam has a micro-microcellular structure and / or is permeable to air and / or a water vapor permeability of more than 0.50 mg / cm “/ h, preferably more than 0.12 mg / cm“ / h, according to DIN EN ISO 14268
having.
[16]
16. Objects produced using a layer material according to one of claims 11 to 15, in particular obtainable by a method according to one of claims 1 to 10, such as sheet goods, cuts, stampings, shoe parts, sports and work shoes, shoe insoles, bags, leather goods, steering wheel covers , Upholstery covers, interior wall cladding of vehicles and seat covers for motor vehicles, the surface of the objects or the layer (2) and the layer (3) having a structural embossing.
[17]
17. Objects according to claim 16, characterized in
44/48
- That on punching or shape blanks 30 on the further layer (3) a color or. Finished layer (6) is applied, which is preferably of a different color and is formed from a colored PU mixture and optionally has the same strength and / or hardness and resistance as the layer (3).

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATA51107/2018A|AT521908A1|2018-12-13|2018-12-13|Layer material and method for producing a layer material|US17/312,338| US20220040946A1|2018-12-13|2019-07-19|Layered material and method for producing a layered material|

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CA3122879A| CA3122879A1|2018-12-13|2019-07-19|Layered material and method for the production of a layer material|

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PCT/EP2019/069529| WO2020119961A1|2018-12-13|2019-07-19|Layered material and method for producing a layered material|

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EP19742584.6A| EP3894624A1|2018-12-13|2019-07-19|Layered material and method for producing a layered material|

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CN201980091647.0A| CN113423886A|2018-12-13|2019-07-19|Layered material and method for producing a layered material|