EP2208836A1 - Concrete forming board, method for its manufacture and application thereof - Google Patents

Abstract

The panel has a textile sheet material e.g. mineral non-woven fabric fleece, evenly applied on a side of a carrier e.g. oriented strand board, and hardened using a B-stage compatible binder. Function materials are applied on an upper side of the hardened textile sheet material. A surface weight of the sheet material ranges between 15 and 500 g per meter square. A surface of the sheet material includes three-dimensional structures in form of grooves and/or knots. An auxiliary barrier layer is formed between the carrier and the sheet material. An independent claim is also included for a method for manufacturing a shuttering to manufacture a concrete mold. The textile sheet material is made of fibers of synthetic polymers, ceramic fibers, mineral fibers or glass fibers.

Description

The invention relates to a novel concrete formwork, which is suitable for the production of one-sided or two-sided concrete formwork, concrete forms containing such concrete formwork and methods for producing the concrete formwork panels.

By means of the concrete formwork according to the invention, patterned or structured as well as very smooth concrete surfaces can be produced.

In the manufacture of concrete, it is usually cast using a concrete mold, the concrete taking the form of the concrete form. For this, the wet, unconsolidated concrete is poured into or onto the concrete mold, after hardening and removal of the concrete panel, the newly exposed concrete surface is a negative impression of the inner surface of the concrete form. For example, if wooden board panels are used as formwork, the concrete takes on the appearance of the wooden board grain.

The concrete mixture often contains large amounts of air, and usually more water than is necessary for the setting. The air contained in the concrete mixture and the water present make the concrete mix more fluid and thus facilitate handling and casting.

Concrete formwork has long been known from the prior art. So that describes US Patent 4730805 a mold for forming concrete using a support and at least two layers of fabric on the support. The carrier may have tabs for spacing the sheet from the carrier, wherein the sheet layers and tabs aid in draining the water from the hardening concrete. The carrier may have drainage holes for removing excess water and air. The sheet is bound to the carrier and immovable to it.

From the U.S. Patent 4,856,754 is a concrete form using double-woven fabrics on a support plate with holes for the Drainage known. One web is adhered to the board while the other web is sewn to the first.

Out EP-A-0429752 is a pattern for patterned concrete or concrete surfaces with a support means, a grid with interconnected spacers forming in the grid holes with a single surface of at least 0.25 cm ² , at least a part of which rests on the support means, and a porous, textile Sheet, which is arranged next to the grid and spaced by the grid from the carrier, known. The sheet generally has a pore size of 10 to 250 μm on each side, so that a number of small concrete particles (typically 30 to 90 μm) can penetrate and fill the open spaces of the sheet. Furthermore, excess water and air can pass through, so that drainage is given.

Fine concrete particles typically fill the larger pores of the sheet, especially when excessive concrete compaction occurs. If enough fine concrete particles have penetrated into the structure of the sheet and sufficient concrete hardening has taken place, usually the release of the sheet from the hardened concrete becomes very difficult or even impossible without damaging the concrete surface. Furthermore, the concrete facing side of the concrete formwork is unusable.

The previously known concrete form liners or concrete formwork can only be realized with great difficulty or can only be used to a limited extent, so that there was a need for easily realizable concrete formworks.

It has now been found that concrete formwork with a special glass fleece finishing or surface coating are outstandingly suitable for the production of single-sided and / or two-sided concrete formworks and furthermore surface structures in the concrete surface can be produced in a simple manner or concrete surfaces with high quality can be produced to let.

In addition, the special glass fleece finish or surface finish of the formwork enables it to be reused much more often than concrete formwork.

In addition, the special glass fleece finish or surface finish of the formwork is cost-effective and available in commercial quantities. Also the material recycling after intended use is possible.

On the one hand, the special glass fleece finish or surface finish of the formwork according to the invention makes it possible to produce very smooth concrete surfaces as well as patterned concrete surfaces, such as are required, in particular, in exposed concrete or as structural concrete.

1. a) mindestens einen Träger,
2. b) mindestens ein auf mindestens einer der beiden Seiten des Trägers flächig aufgebrachtes textiles Flächengebilde welches mit mindestens einem B-stage fähigen Binder verfestigt worden ist,
3. c) ggf. ein oder mehrere auf die Oberseite des mit dem B-stage Binder verfestigten textilen Flächengebildes aufgebrachte oder in das textile Flächengebilde eingebrachte Funktionsmaterialien.

The subject of the present invention is a concrete formwork panel comprising:

1. a) at least one carrier,
2. b) at least one textile fabric applied flat on at least one of the two sides of the support which has been consolidated with at least one B-stage-capable binder,
3. c) if appropriate, one or more functional materials applied to the upper side of the fabric consolidated with the B-stage binder or introduced into the textile fabric.

The support used according to the invention is preferably wood-based materials, such as panels, which may have additional wood-material constructions, such as frames, grids or three-dimensional reinforcing structures, so-called honeycombs, which further reinforce the wood-based materials.

The wood-based materials are plate-shaped or strand-shaped wooden materials which are produced by mixing the various forms of wood particles with natural and / or synthetic binders in the course of hot-pressing. The wood-based materials used in accordance with the invention preferably comprise barrier or plywood, chipboard material, in particular chipboard and OSB (Oriented Strand Boards), wood fiber material, in particular porous wood fiber boards, diffusion-open wood fiber boards, hard (high density) wood fiber boards (HDF) and medium-density wood fiber boards (MDF), and Arboform. Arboform is a thermoplastically processable material made of lignin and other wood components.

The wood-based materials used according to the invention may be formed as one or more layers and preferably comprise several layers of barrier or plywood and / or wood-chip materials. To increase the stability of these layers can be glued together.

The choice of the carrier is essentially not limited but rather determined by the type of formwork, i. whether it is a wall formwork, column formwork, beam formwork, staircase formwork, slip formwork, frame formwork, carrier formwork or lost formwork.

The textile fabrics used according to the invention are all structures which are produced from fibers and from which a textile surface has been produced by means of a surface-forming technique.

The fiber-forming materials are preferably fibers of synthesized polymers, ceramic fibers, mineral fibers or glass fibers, which may also be used in the form of mixtures. In the presence of fiber mixtures, these may also contain cellulose or natural fibers. Textile surfaces are understood as meaning fabrics, scrims, knits, knitted fabrics and nonwovens, preferably nonwovens.

The textile fabrics used according to the invention preferably have a sufficient water or moisture barrier effect towards the wearer. Optionally, there may also be a separate additional barrier layer (eg film) between the nonwoven and the carrier.
The textile fabric may additionally have a reinforcement of fibers, threads, or filaments. This is particularly useful when the textile fabric is exposed to high mechanical requirements. Preferred reinforcing threads are multifilaments or rovings based on glass, polyester, carbon or metal. The reinforcing threads can be used as such or in the form of a textile fabric, for example as a woven fabric, scrim, knitted fabric, knitted fabric or fleece. Preferably, the reinforcements consist of a parallel bundle of threads or a scrim.

The textile surfaces of mineral and ceramic fibers are aluminosilicate, ceramic, dolomite wollastonite fibers or, preferably, fibers of volcanics, preferably basalt, diabase and / or melaphyre fibers, in particular basalt fibers. Diabase and melaphyre are collectively referred to as paleo-basalts and Diabas is often referred to as greenstone.

The mineral fiber fleece can be formed from filaments, ie infinitely long fibers or from staple fibers. The average length of the staple fibers in the nonwoven fabric of mineral fibers used according to the invention is between 5 and 120 mm, preferably 10 to 90 mm. In a further embodiment of the invention, the mineral fiber fleece contains a mixture of continuous fibers and staple fibers.
The average fiber diameter of the mineral fibers is between 5 and 30 microns, preferably between 8 and 24 microns, more preferably between 8 and 15μ.

The basis weight of the textile fabric of mineral fibers is between 15 and 500 g / m ² , preferably 40 and 250 g / m ² , which refers to a sheet without binders.

In the case of the textile surfaces made of glass fibers, in particular nonwovens are preferred. These are made of filaments, i. infinitely long fibers or staple fibers. The average length of the staple fibers is between 5 and 120 mm, preferably 10 to 90 mm. In a further embodiment of the invention, the glass fiber fleece contains a mixture of continuous fibers and staple fibers.

The average diameter of the glass fibers is between 5 and 30 .mu.m, preferably between 8 and 24 .mu.m, particularly preferably between 10 and 21 .mu.m.

In addition to the above-mentioned diameters, so-called glass microfibers can also be used. The preferred average diameter of the glass microfibers here is between 0.1 and 5 microns. The microfibers forming the textile surface can also be present in mixtures with other fibers, preferably glass fibers. It is also a layered one Structure of microfibers and glass fibers possible or the setting of a gradient at which the content of microfibers, to the side facing away from the carrier of the textile fabric, increases. As a result, a drainage effect can be adjusted.

The weight per unit area of the textile fabric of glass fibers is between 15 and 500 g / m ² , preferably 40 and 250 g / m ² , these details referring to a sheet without a binder.

Suitable glass fibers include those made from A-glass, E-glass, S-glass, C-glass, T-glass or R-glass.

The textile surface can be produced by any known method. For glass webs, this is preferably the dry or wet laid process.

Of the textile surfaces made of fibers of synthetic polymers are nonwovens, in particular so-called spunbonds, i. Spun nonwovens produced by a disposition of melt-spun filaments are preferred. They consist of continuous synthetic fibers made of melt-spinnable polymer materials. Suitable polymeric materials include, for example, polyamides, e.g. Polyhexamethylenediadipamide, polycaprolactam, aromatic or partially aromatic polyamides ("aramids"), aliphatic polyamides, e.g. Nylon, partially aromatic or wholly aromatic polyesters, polyphenylene sulfide (PPS), polymers having ether and keto groups, e.g. Polyether ketones (PEK) and polyetheretherketone (PEEK), polyolefins, e.g. Polyethylene or polypropylene, cellulose or polybenzimidazoles. Besides the above-mentioned synthetic polymers, those polymers which are spun from solution are also suitable.

The spunbonded nonwovens preferably consist of melt-spinnable polyesters. Suitable polyester materials are in principle all known types suitable for fiber production. Particular preference is given to polyesters which contain at least 95 mol% of polyethylene terephthalate (PET), in particular those of unmodified PET.

The individual titres of the polyester filaments in the spunbonded web are between 1 and 16 dtex, preferably between 2 and 10 dtex.

In a further embodiment of the invention, the spunbonded nonwoven fabric can also be a meltbond-bonded nonwoven fabric which contains carrier and hot-melt adhesive fibers. The carrier and hot melt adhesive fibers can be derived from any thermoplastic fiber-forming polymers. Such meltbond-solidified spunbonded nonwovens are, for example, in EP-A-0,446,822 and EP-A-0,590,629 described.

In addition to continuous filaments (spunbond process), the textile surfaces can also be composed of staple fibers or mixtures of staple fibers and continuous filaments. The individual titres of the staple fibers in the nonwoven amount to between 1 and 16 dtex, preferably 2 to 10 dtex. The staple length is 1 to 100 mm, preferably 2 to 50 mm, more preferably 2 to 30 mm. The textile fabric can also be constructed of fibers of different materials in order to achieve special properties.

The filaments and / or staple fibers constituting the nonwovens may have a practically round cross-section or also have other shapes, such as dumbbell, kidney-shaped, triangular or tri- or multilobal cross-sections. It is also possible to use hollow fibers and bicomponent or multicomponent fibers. Furthermore, the hotmelt adhesive fiber can also be used in the form of bi- or multicomponent fibers.

The fibers forming the textile fabric may be modified by conventional additives, for example by antistatic agents such as carbon black.

The basis weight of the textile fabric of synthetic polymer fibers is between 10 and 500 g / m ² , preferably 20 and 250 g / m ²

The textile fabrics can be produced without chemical binders. In order to achieve the required strength for further processing of the fabrics, it is also possible to introduce thermoplastic binder polymers and / or use known needling methods. Besides the possibility of mechanical solidification, e.g. by calendering or needling, mention should be made here in particular of hydrodynamic needling.

Preferably, however, the fabrics are preconsolidated with a chemical binder. The binders used preferably come from the group the B-stage binder compatible binder systems. The binder content is at most 25 wt .-%.

The textile fabric used according to b) was finished or solidified by means of a so-called B-stage binder.

B-stage binders are binders or binder systems which are used stepwise, i. only partially solidified or hardened and still a final consolidation, for example, by thermal treatment can learn.

Suitable B-stage binders or binder systems are in US-A-5,837,620 . US-A-6,303,207 and US-A-6,331,339 described in detail. The B-stage binders disclosed there can also be used in the context of the present invention.

In a preferred embodiment of the invention, the amount of final solidified B-stage binder and chemical binder together is min. 30 wt .-%, in particular min. 35 wt .-%, more preferably min. 40 wt .-%, wherein the weight indication also optionally present in the binder system aids such. Filler and / or stabilizers, and refers to the total weight of the fabric.

B-stage binders or B-stage-capable binders are preferably binders based on furfuryl alcohol-formaldehyde, phenol-formaldehyde, melamine-formaldehyde, urea-formaldehyde and mixtures thereof. Preferably, they are aqueous systems. Other preferred binder systems are formaldehyde-free binders. B-stage binders are characterized by the fact that they can be subjected to two- or more-stage curing, i. after the first curing or the first hardenings still have a sufficient binder effect to use this for further processing.

Typically, such binders are finally solidified after addition of a catalyst at temperatures of about 175 ° C (about 350F).

To form the B-stage, such binders are cured, if appropriate after addition of a catalyst. The curing catalyst content is up to 10 wt .-%, but preferably 0.05 to 7 wt .-% (based on the total binder content). As the curing catalyst, for example, ammonium nitrate, as well as organic, aromatic acids, e.g. Maleic acid and p-toluenesulfonic acid, since this can reach the B-stage state faster. In addition to ammonium nitrate, maleic acid and p-toluenesulfonic acid are all materials suitable as a curing catalyst, which have a comparable acidic function. Depending on the process control and further processing, however, the addition of a catalyst can also be dispensed with altogether.

To achieve the B-stage, the textile fabric impregnated with the binder can be dried under the influence of temperature without effecting complete curing of the binder.
The required process parameters depend on the selected binder system.

The B-stage-capable binders used according to the invention allow variable process control.

In a preferred process, the first stage of solidification of the B-stage capable binder serves to stabilize the fabric in its manufacture, if not otherwise preconsolidated, e.g. through other chemical binders. Subsequently, the textile fabric preconsolidated with the B-stage binder is fixed on the support, e.g. obtained by pressing / lamination, and the composite of carrier and textile fabric. In the above fixing, the B-stage binder is finally solidified, whereby any structuring desired, e.g. by structured press plates or rollers, is generated and fixed.

In a further preferred process control, the textile fabric is already pre-consolidated elsewhere in the production of the formwork or formwork panels according to the invention, for example by other chemical binders. Thus, the first stage of solidification of the B-stage capable binder for attachment or fixation of the fabric on the support. Subsequently, a desired structuring, for example by structured press plates or rollers, or else a particularly smooth surface, for example, by particularly smooth press plates or rollers, are generated.

In addition, in a further preferred process variant, it is also possible to apply and press the textile material which has been preconsolidated with the B-stage binder directly in the production of the wood-based material. Simultaneously or subsequently by a separate step, a desired structuring, e.g. by structured press plates or rolls, or else a particularly smooth surface, e.g. be produced by particularly smooth press plates or rollers.

By means of the present invention, the stability of the concrete formwork, in particular when using wood-based material carriers, can be further increased, as a result of which more compact and also lighter formwork panels are accessible, which considerably facilitates their handling.

The lower as well as the upper temperature limit can be influenced by choice of the duration or by addition or avoidance of larger or more acidic curing catalyst or optionally by using stabilizers.

The second stage of solidification of the binder in the B-stage state thus serves to fix the textile fabric to the support or insofar as the fabric is preconsolidated by other methods and the fabric is fixed to the support by means of the first stage of solidification of the binder for producing and fixing three-dimensional structures which were produced on the surface of the composite of carrier and textile fabric, or special smoothing, which generates on the surface of the composite of carrier and textile fabric on the concrete facing side of the concrete formwork were to fix. For this purpose, the surface can be processed by means of heated molds or heated press / rolling tools, eg structured press plates or structured press rolls, so that the structures present in the molds and tools are transferred to the textile fabric and after cooling or final solidification of the Binders are permanently present

Insofar as the carrier is formed from a wood material, the semi-finished product of carrier and textile fabric can also be processed together as described above. In this case, the textile fabric is pressed into the upper layer of the carrier and additionally with this or this connected, so that an excellent strength can be achieved at the same time low weight.

The lamination or second stage of the solidification takes place under the action of pressure and heat in such a way that the existing B-stage binder is largely finally solidified. The lamination can be carried out by means of batch or continuous pressing or by rolling, e.g. Calender, done. Depending on the B-stage binder used, the parameters pressure, temperature and dwell time are selected individually.

Insofar as an extremely smooth surface of the concrete formwork is to be achieved, the second stage of solidification can also be used for further smoothing and fixing the surface of the formwork.

The application of the B-stage capable binder on the fabric can be done using all known methods. In addition to impregnation and pressing the binder can also be applied by means of coating or foam application. In foam application, a foaming foam is produced with the aid of a foaming agent in a foam mixer, which is applied to the nonwoven by suitable coating units.

The B-stage capable binder may contain other adjuncts, such as e.g. Fillers and / or stabilizers. In particular, materials for increasing the abrasion and scratch resistance play a role in the fillers. For the surface treatment to improve the abrasion and hardness, particles of SiC and / or SiO 2, corundum (AL 2 O 3) or similar materials are preferably used, grain sizes of less than 1 mm are used, whereby a very hard surface can be produced. The proportion of these fillers can be up to 40% by weight.

In a preferred embodiment of the invention, the concrete formwork has a three-dimensional structure on the surface of the textile fabric or the composite of support and textile fabric.

The structures may be regular or irregular. Particular preference is given to regular structures, in particular regular ones and symmetrical, in particular repetitive structures such as grooves, diamonds and knob-shaped structures or self-cleaning structures.

The three-dimensional structures preferably have a connection to one another, so that drainage is possible as a result. It is particularly preferred if the three-dimensional structures have a preferred direction, which favor a drainage of the water from the concrete. It has been found that groove-shaped structures which have a substantially vertical or vertical preferred direction, are particularly well suited. These groove-shaped structures have a depression or increase of up to 3 mm, in particular of up to 1 mm. The width of the structures is up to 3mm, especially up to 1mm.

Pimple-shaped structures are needed in particular for improving the skid resistance of concrete surfaces.

In addition to these structures, other decorative structures are possible.

In a further embodiment of the invention, the concrete formwork according to the invention may have a further, additional textile fabric, preferably a nonwoven or spunbonded fabric, with a special surface quality and porosity, which allows use as formwork for the production of Luncker-free concrete surfaces. In particular, concrete surfaces which must withstand a special load, e.g. The surfaces of dams, as well as overflow and discharge channels of hydroelectric power plants, or water treatment or sewage treatment plants, concrete pipes for the passage of liquids, must have a sufficient durability. By a corresponding surface quality of the concrete this is particularly well suited for the above purpose.

The additional textile fabric has a pore size (cross-section) of 10 to 80 .mu.m, preferably 10 to 60 .mu.m, determined by means of a Coulter Porometer in porofil.

The additional textile fabric has an air permeability of up to 2501 / m ² s at 200 Pa (determined according to DIN 53887) and a water-tightness of 40 to 300 mm water column (determined according to DIN 53886)

Inasmuch as the additional textile fabric is not firmly or flatly connected to the composite of carrier and textile fabric, it can also be stretched over a composite of carrier and textile fabric. For this purpose, it is advantageous if the additional textile fabric measures a maximum tensile force of at least 400 N, preferably 400 to 600 N (in the longitudinal direction) and at least 300 N, preferably 300 to 500 N (in the transverse direction), measured on a 5 cm wide strip according to DIN EN 290733.

The additional textile fabric may also have reinforcements of fibers, filaments or filaments. As reinforcing threads, multifilaments or rovings based on glass, polyester, carbon or metal are preferably used. Preferably, the reinforcements consist of a parallel bundle of threads or a scrim.

To improve the drainage effect, a spacer can additionally be installed between additional textile fabrics and the composite of carrier and textile fabric. Suitable spacers are grids, nets, perforated sheets, etc, which allow drainage of the water from the concrete. The spacers should advantageously have openings or free areas of at least 0.25 cm ² (single area).

Insofar as the textile fabric used according to the invention does not have sufficient water or moisture barrier effect towards the backing, an additional barrier layer can be formed between the backing and the textile fabric. The barrier layer may also be applied to the carrier in the form of additional equipment, in particular on the side of the carrier facing the textile fabric.

The barrier layer prevents swelling of the support insofar as the support, taken alone, does not possess sufficient resistance to water and / or moisture. The durability of the wearer is i.a. depending on which binder was used in the production of the carrier.

The barrier layer causes the concrete-facing side or surface of the formwork according to the invention, comprising the textile fabric and the Barrier layer, a sufficient water or moisture barrier effect towards the wearer out.

The barrier layer can be obtained or applied, for example, by incorporating a corresponding polymer film, flocking with thermoplastic polymer materials or applying hydrophobic materials to the side of the backing facing the textile fabric.

As a barrier layer, films are preferably used. Preferably, films of B-stage capable materials are used. B-stage-capable materials are preferably furfuryl alcohol-formaldehyde, phenol-formaldehyde, melamine-formaldehyde, urea-formaldehyde and mixtures thereof. Films based on formaldehyde-free materials are also preferred.

The functional material used according to c) are preferably materials which facilitate the shuttering and are customary in concrete technology or formwork technology. As examples of such functional materials or auxiliaries its here called release agent, water repellents, scarf oils, this list is not exhaustive.

With the help of the formwork according to the invention in particular high-quality concrete surfaces can be realized, this is in particular exposed concrete or structural concrete surfaces, or their formwork forms. In addition, nanostructured concrete surfaces can be produced with the help of the formwork according to the invention, which have special properties due to the self-cleaning effect. For this purpose, only the complementary structure in the surface of the formwork according to the invention must be present.

1. a) Zuführen eines Trägers,
2. b) Flächiges Aufbringen eines textilen Flächengebildes auf mindestens einer Oberfläche des Trägers, wobei das textile Flächengebilde mindestens einen Binder im B-Stage Zustand aufweist,
3. c) Laminieren des gemäß Schritt b) erhaltenen Aufbaus unter Einwirkung von Druck und Wärme, so dass der im B-stage vorliegenden Binder endverfestigt wird und
4. d) gegebenenfalls Aufbringen mindestens eines Funktionsmaterials und Trocknung.

Another object of the present invention is a process for producing a formwork for producing a concrete form (variant I):

1. a) feeding a carrier,
2. b) surface application of a textile fabric to at least one surface of the support, wherein the textile fabric has at least one binder in the B-stage state,
3. c) laminating the structure obtained according to step b) under the action of pressure and heat, so that the binder present in the B-stage is finally solidified, and
4. d) optionally applying at least one functional material and drying.

Insofar as the concrete formwork according to the invention is to have a structured or smoothed surface, the structuring or smoothing of the surface can take place during step c).

Insofar as the functional material is to be applied in step e), this is done by means of known coating, printing, spraying or painting technologies. The drying takes place depending on the selected system. The application of the functional material can also be done on site, i. during or after the construction of the concrete form, done before filling the concrete.

In a variant of the above method (variant III), the support is first formed in step a) or the textile fabric is already applied flat during the production of the support.
The pressing of the carrier formed takes place together with the finished textile fabric, wherein the textile fabric is introduced into the pressing or drying device for the carrier accordingly. The preparation of the composite of carrier and textile fabric can be continuous or discontinuous. In particular, in the production of deep structures, it is advantageous to feed the textile fabric already in the formation of the wood material carrier and pressing. As a result, in particular, the said three-dimensional structures can be produced well.

1. a) Bildung eines Trägers,
2. b) Flächiges Aufbringen eines textilen Flächengebildes auf mindestens einer Oberfläche des Trägers, wobei das textile Flächengebilde mindestens einen Binder im B-Stage Zustand aufweist, wobei die Zuführung auch bereits während der Bildung des Trägers erfolgen kann,
3. c) Laminieren, ggf. unter gleichzeitigem Strukturieren bzw. Glättung der Oberfläche, des gemäß Schritt b) erhaltenen Aufbaus unter Einwirkung von Druck und Wärme, so dass der im B-stage vorliegenden Binder endverfestigt wird, und
4. d) gegebenenfalls Aufbringen mindestens eines Funktionsmaterials und Trocknung.

Another object of the present invention is thus a method for producing a formwork for producing a concrete form (variant III):

1. a) formation of a carrier,
2. b) surface application of a textile fabric to at least one surface of the support, wherein the textile fabric has at least one binder in the B-stage state, wherein the supply can take place already during the formation of the support,
3. c) lamination, optionally with simultaneous structuring or smoothing of the surface, of the structure obtained according to step b) under the action of pressure and heat, so that the binder present in the B-stage is finally solidified, and
4. d) optionally applying at least one functional material and drying.

In a variant of the above process (variant II), the textile fabric supplied in accordance with step b) is already used in some other pre-consolidated manner, e.g. through other chemical binders. The fabric is provided with an additional B-stage capable binder and bonded to the backing, with the first stage of consolidation of the B-stage capable binder resulting in attachment or fixation of the fabric to the backing. Subsequently, a desired structuring, e.g. by structured press plates or rolls, or else a particularly smooth surface, e.g. is produced and fixed by means of particularly smooth press plates or rolls. In the above fixation, the B-stage binder is finally solidified.

1. a) Zuführen eines Trägers,
2. b) Flächiges Aufbringen eines textilen Flächengebildes auf mindestens einer Oberfläche des Trägers, wobei das textile Flächengebilde mittels eines nicht B-Stage-fähigem Binder oder Bindersystems vorverfestigt ist, und das textile Flächengebilde zusätzlich mindestens einen B-Stage-fähigen Binder aufweist,
3. c) Laminieren des gemäß Schritt b) erhaltenen Aufbaus unter Einwirkung von Druck und Wärme, so dass der im B-stage-fähige Binder zumindest teilweise verfestigt wird,
4. d) Strukturierung bzw. Glättung der Oberfläche des gemäß Schritt c) erhaltenen Aufbaus und Fixierung durch Endverfestigung des im B-Stage vorliegenden Binders,
5. e) gegebenenfalls Aufbringen mindestens eines Funktionsmaterials und Trocknung.

Another object of the present invention is thus a method for producing a formwork for producing a concrete form (variant II):

1. a) feeding a carrier,
2. b) surface application of a textile fabric to at least one surface of the support, wherein the fabric is preconsolidated by means of a non-B-stage capable binder or binder system, and the fabric additionally comprises at least one B-stage capable binder,
3. c) laminating the structure obtained according to step b) under the action of pressure and heat, so that the B-stage-capable binder is at least partially solidified,
4. d) structuring or smoothing of the surface of the structure obtained according to step c) and fixation by final consolidation of the binder present in the B-stage,
5. e) optionally applying at least one functional material and drying.

As carrier, textile fabric, B-stage binder and functional material, the aforementioned materials are suitable. The disclosed within the context of the formwork according to the invention preferred embodiments also apply to its production.

Insofar as an additional barrier layer between the support and the textile fabric is required, it may already be present as equipment on the support supplied in accordance with step a), or it may be incorporated in an additional step between step a) and b). The barrier layer can be present both in the form of an independent layer or as a coating on the support.

Insofar as additional textile fabric is required, it will be provided on site, i. during or after the construction of the concrete form and before the filling of the concrete installed.

Another object of the present invention is a formwork form for concrete, which is produced from the formwork according to the invention or at least partially. The formwork according to the invention can also be offered in the form of formwork panels, which are also the subject of the present invention.

In addition, the present invention also includes the use of the formwork, formwork panels and molds according to the invention for the production of concrete moldings and for the production of concrete surfaces.

Claims (18)

Concrete formwork panel comprising: a) at least one carrier, b) at least one textile fabric applied flat on at least one of the two sides of the support which has been consolidated with at least one B-stage-capable binder, c) if appropriate, one or more functional materials applied to the upper side of the fabric consolidated with the B-stage binder or introduced into the textile fabric. Concrete formwork panel according to claim 1, characterized in that the carrier is a wood material, preferably a plate-shaped or strand-shaped wood materials. Concrete formwork panel according to claim 2, characterized in that the wood material is a barrier or plywood, wood chipboard, in particular chipboard and OSB (Oriented Strand Boards), wood fiber material, in particular porous wood fiber boards, hard (high-density) wood fiber boards (HDF), medium-density wood fiber boards ( MDF) and / or Arboform. Concrete formwork panel according to claim 2 or 3, characterized in that the wood material is expanded one or more layers. Concrete formwork panel according to claim 1, characterized in that the textile fabric comprises fibers of synthesized polymers, ceramic fibers, mineral fibers or glass fibers, and mixtures thereof. Concrete formwork panel according to claim 1, characterized in that the textile fabric is a mineral fiber fleece whose surface weight is preferably between 15 and 500 g / m ² . Concrete formwork panel according to claim 1, characterized in that the textile fabric is a glass fiber fleece, the basis weight of which is preferably between 15 and 500 g / m ² . Concrete formwork panel according to claim 1, characterized in that the textile fabric is a nonwoven fabric of synthetic polymers, preferably a spunbonded nonwoven, whose basis weight is preferably between 10 and 500 g / m ² . Concrete formwork panel according to claim 1, characterized in that the amount of final consolidated B-stage binder, based on the total weight of textile fabric and dried binder, min. 30% by weight, preferably min. 35 wt .-%, is, wherein the weight statement also includes optionally present in the binder system aids. Concrete formwork panel according to claim 1, characterized in that the B-stage capable binder is a binder based on furfuryl alcohol-formaldehyde, phenol-formaldehyde, melamine-formaldehyde, urea-formaldehyde and mixtures thereof, these preferably being used as aqueous systems become. Concrete formwork panel according to claim 1, characterized in that the B-stage capable binder is formaldehyde-free. Concrete formwork panel according to claim 1, characterized in that the surface of the textile fabric has a three-dimensional structure, preferably in the form of grooves and / or nubs. Concrete formwork panel according to claim 12, characterized in that the three-dimensional structures have a connection to each other, whereby a drainage is made possible, preferably, the three-dimensional structure is groove-shaped and has a recess or increase of up to 3 mm and / or a width of up to 3mm. Method for producing a formwork for producing a concrete form comprising the measures: a) feeding a carrier, b) surface application of a textile fabric to at least one surface of the support, wherein the textile fabric has at least one binder in the B-stage state, c) lamination of the structure obtained in step b) under the action of pressure and heat, so that the binder present in the B-stage is finally solidified and d) optionally applying at least one functional material and drying. A method according to claim 20, characterized in that in step c) structuring or smoothing of the surface takes place. A method according to claim 20, characterized in that in step a) the carrier first formed or during the manufacture of the carrier already the textile fabric is applied flat. A method for producing a formwork for producing a concrete form comprising the measures a) feeding a carrier, b) surface application of a textile fabric to at least one surface of the support, wherein the fabric is preconsolidated by means of a non-B-stage capable binder or binder system, and the fabric additionally comprises at least one B-stage capable binder, c) laminating the structure obtained according to step b) under the action of pressure and heat, so that the B-stage-capable binder is at least partially solidified, d) structuring or smoothing of the surface of the structure obtained according to step c) and fixation by final solidification of the binder present in the B-stage, optionally also simultaneously with step c), e) optionally applying at least one functional material and drying. Shuttering form for concrete containing at least one concrete formwork panel according to claims 1 to 13.