EP0411653A2 - Sport-hall flooring - Google Patents

Abstract

In the case of a sports-hall flooring, in particular for gymnasiums, having a flexible layer applied on an underflooring or naked flooring of screed or the like, on which layer an impact-absorbing and force-absorbing layer is arranged, if appropriate with a film of plastic or the like in between, the impact-absorbing and force-absorbing layer comprises at least two plies of polyolefin sheets. The polyolefin sheets of at least one ply have on their surface facing the other ply a nonwoven fabric and are bonded to the other ply with the nonwoven fabric being incorporated. <IMAGE>

Description

The invention relates to a sports hall floor according to the preamble of claim 1 and a method for producing a sports hall floor.

The basic structure of sports hall floors is described in DIN 18 032. In such sports hall floors, an elastic layer on a sub or raw floor, for. B. screed applied. The elastic layer, for. B. in the form of an elastic mat, which can be made of foam, glued to the screed. On the upward-facing surface, the elastic mat is covered with a fabric, e.g. B. from glass fibers, polyester fibers or the like. Provided. This fabric can either be laminated onto the elastic mat or is glued to the elastic mat on site. Subsequently, a liquid plastic with a thickness of 2 to 3 mm is applied and cured to produce a pressure distribution plate on the fabric-reinforced elastic mat. After curing thus a hard, rigid plate as a pressure distribution plate on the elastic layer. Finally, a wear layer is glued onto the hardened pressure distribution plate either in the form of a liquid or in the form of conventional floor coverings made of PVC, plates or the like. The above-mentioned manufacture of the pressure distribution plate by pouring and distributing a synthetic resin has various problems. On the one hand, there is the possibility that the reaction mixture is not mixed with one another in the correct ratio; on the other hand, there is no guarantee that the reaction mixture will sufficiently soak the tissue located on the elastic layer. Furthermore, when applying a liquid plastic layer, there is the problem of evenly applying this layer. Another disadvantage is that when using a polyurethane two-component casting compound as the basis for the pressure distribution plate to be cured, this mass under the influence of moisture, for. B. humidity, gases, such as carbon dioxide, cleaves, which leads to the formation of bubbles in the plastic layer and affects the mechanical strength of the pressure distribution plate to be produced.

When using an elastic mat with laminated fabric there is a further disadvantage that in the area of the joints of the mat the liquid plastic of the pressure distribution plate to be created penetrates into the butt joint and forms a ridge that leads to damage to the sports hall floor and also deviations in the otherwise uniform effect of the sports hall floor in the area of shock training.

A method for producing a sports hall floor is known from DE-PS 26 23 321, in which an elastic layer is placed seamlessly on a sub-floor, after which to form a load distribution layer consisting of a first and a second plastic layer, the first plastic layer on the elastic layer hung up and then using of a pressure sensitive adhesive, the second plastic layer is applied to the first plastic layer and glued to it, and in which an upper covering is subsequently arranged on the second plastic layer by means of an adhesive, the separation points between adjacent layers or layers being offset from one another. Two plastic layers made of PVC or hard polyethylene joined together by a pressure sensitive adhesive serve as the load distribution layer. A load distribution layer formed in this way has the disadvantage that it has a high coefficient of thermal expansion, which is 200 ^× 10 ^{−¾ / °} for polyethylene and 80 × 10 ^{−¾ / °} when using polyvinyl chloride. The use of such materials for the load distribution layer has the consequence that the floor reacts sensitively to temperature fluctuations and warping in the area of the load distribution layer with respect to the sub-floor or possibly also to the top covering cannot be ruled out. Another problem can arise with the known floor through the use of the pressure sensitive adhesive which is to be applied to the respective layers or layers at the construction site and which is undesirable on the one hand because of its solvent content and on the other hand does not guarantee the required adhesive strength.

DE-PS 22 21 761 describes a sports floor or a vibrating floor in which two layers of chipboard are used as the load distribution layer, which are glued to one another over the entire surface and receive an upper covering on the top. The chipboard is glued to the elastic layer.

The invention has for its object to improve a sports hall floor of the type mentioned in such a way that the above difficulties and disadvantages are eliminated.

This object is achieved by the features in the characterizing part of claim 1.

Further designs of the sports hall floor result from the subclaims.

The invention provides a sports hall floor, in particular for gyms, which consists of an elastic layer, preferably loosely laid on the subfloor or bare floor, onto which layers of prefabricated plastic plates in the form of glass fiber reinforced plyolefin plates are laid. According to a preferred embodiment, two such layers of polyolefin sheets are applied, according to a further embodiment three layers of polyolefin sheets are applied, the layers being placed floating on the elastic. Adjacent layers of polyolefin sheets are glued together over their entire surface using a preferably waterproof adhesive.

According to a further embodiment, the individual plates of the different layers are laid on the elastic layer in such a way that the joints of layers lying one above the other are offset from one another.

In order to achieve a high level of adhesive strength between the layers of layers lying one above the other, the plates of at least one layer are provided with a fleece on their surface facing the next layer, which is preferably pressed or introduced into the plate surface during the manufacture of the plates. This fleece practically contributes to an increase in surface roughness and enables full-surface, firm bonding of layers lying one above the other.

When using the polyolefin sheets, preferably in the form of polypropylene sheets, which are prefabricated and placed on the elastic layer at the construction site, there are no difficulties with regard to an uneven material layer. Due to the weight of the panels plus the top covering to be applied, the sports floor, consisting of the individual layers of polyolefin panels, lies floating and flat on the elastic layer.

Another advantage is that polyolefin sheets can be disposed of easily and in an environmentally friendly manner.

Another advantage is the fact that polyolefin sheets are inexpensive to produce.

According to the invention, a method is to be created with which a sports hall floor that is largely unaffected by temperature fluctuations, but is nevertheless inexpensive, can be produced.

Further refinements of the method and a sports hall floor produced by the method result from the subclaims.

The invention provides a method for producing a sports hall floor, the coefficient of thermal expansion of which is significantly reduced in that the plastic layers used, preferably made of polypropylene, are reinforced with glass mats. The integration of glass mats in the plastic layers reduces the coefficient of thermal expansion compared to pure polypropylene to around 1/5.

According to a first embodiment, one of the glass mat-reinforced plastic layers forming the load distribution layers is prefabricated in that a pressure-sensitive adhesive layer is applied by lamination or preferably with the aid of a press. This ensures that a desired intimate connection between the two layers forming the load distribution layer is achieved and the manufacture of the sports hall floor at the construction site makes the use of liquid, optionally solvent-containing pressure sensitive adhesive unnecessary. To connect the two layers forming the load distribution layer, the film serving as a carrier film for the pressure-sensitive adhesive needs to be removed from the prefabricated plastic layer only on the respective side, after which a "gluing" takes place by pressing the prefabricated plastic layer onto the layer already provided.

According to a further preferred embodiment, the entire load distribution layer is prefabricated according to the invention, ie the load distribution consisting of the two plastic layers layer. In this method, after the pressure-sensitive adhesive layer has been applied to one of the two glass mat-reinforced plastic layers, the carrier film holding the pressure-sensitive adhesive layer is removed, and the two plastic layers are then pressed together by a press, sandwiching the pressure-sensitive adhesive layer. In this embodiment, individual parts of a load distribution layer to be assembled at the construction site are obtained in such a way that the upper or lower plastic layer on the edge protrudes from the other plastic layer and, before assembly, the carrier film for the pressure-sensitive adhesive layer located on the above edge must be removed before the load distribution layer on the Construction site is assembled by overlapping assembly of such pieces.

According to a further preferred embodiment of the method according to the invention, the two glass mat-reinforced plastic layers are joined instead of using a pressure-sensitive adhesive layer to form prefabricated pieces of the load distribution layer in that the mutually opposite or at least one of the two surfaces of the plates resulting in the individual plastic layers are flamed and after softening Surfaces the associated plates are placed on one another under pressure. Such prefabricated pieces of the load distribution layer are also formed so that one of the two plastic layers on the edge protrudes over the other plastic layer. Before assembling such prefabricated pieces of the load distribution layer, the respective surface is flamed by the edge-projecting section of the one plastic layer and thereby brought into a softened state before it is brought into connection with an equally flamed edge section of another piece and pressed together. The prefabrication of individual sections of the load distribution layer is preferably carried out by means of a flame laminating device in such a way that the plates of the upper and lower plastic layer forming the individual sections are fed to the flame laminating device other opposite or at least one of the two surfaces are softened by flaming and then connected by applying pressure.

• Fig. 1 eine Schnittansicht durch einen Sporthallenboden,
• Fig. 2 eine Teilschnittansicht einer erfindungsgemäß ver­wendeten Polyolefinplatte,
• Fig. 3 eine weitere Ausführungsform eines Sporthallenbodens zur Erläuterung der grundsätzlichen Struktur des Aufbaus unter Verwendung glasmattenverstärkter Kunststofflagen zur Bildung einer Lastverteilungs­schicht,
• Fig. 4 eine im Schnitt dargestellte Teilperspektivansicht eines vorgefertigten Abschnittes einer Lastvertei­lungsschicht,
• Fig. 5 eine Teilschnittansicht entsprechend Fig. 4, und
• Fig. 6 eine weitere Abwandlung des Sporthallenbodens.

In the following the sports hall floor is described with the aid of the drawing to explain further features. Show it:

• 1 is a sectional view through a sports hall floor,
• 2 is a partial sectional view of a polyolefin sheet used in the present invention;
• 3 shows a further embodiment of a sports hall floor to explain the basic structure of the structure using glass mat-reinforced plastic layers to form a load distribution layer,
• 4 shows a partial perspective view, shown in section, of a prefabricated section of a load distribution layer,
• Fig. 5 is a partial sectional view corresponding to Fig. 4, and
• Fig. 6 shows a further modification of the sports hall floor.

A sports hall floor, in particular for use in gyms, has a sub-floor or bare floor 1 according to FIG. 1, which consists of concrete or the like. On the preferably moisture-insulated bare floor 1, an elastic layer 2 is applied, for example made of foam or foam mats, which in turn - although not necessary - is covered with a film made of plastic or the like to prevent moisture from passing upwards or downwards to avoid further construction to be described. The elastic layer 2 by individual mats can be formed from different foam materials, wherein the layer 2 is either fixed by gluing to the sub-floor 1 or is preferably loosely arranged on the sub-floor 1.

According to FIG. 1, at least two layers 3, 4 of plastic plates are placed on the elastic layer 2. Each layer 3, 4 consists of a large number of plastic sheets on polyolefin. The polyolefin plates are glass fiber reinforced and, according to a preferred embodiment, have a thickness of 2 mm.

In order to be able to firmly connect the two layers 3 and 4 to one another, an adhesive layer is provided between the layers 3, 4, preferably made of waterproof adhesive, in order to achieve a full-surface bonding of the layer 3 to the layer 4.

Sheets of polyolefin or preferably polypropylene have an extremely smooth surface, i. H. a surface with low roughness and therefore with low adhesion. In order to improve the adhesiveness, it is provided that the plates of layer 3 or the plates of layer 4 or also the plates of both layers 3, 4 are at least provided with a fleece on the surface which is opposite the other layer. 2 shows a partial view of such a polyolefin or polypropylene plate 10 in cross section with a nonwoven 12 embedded in the surface. The nonwoven is preferably inserted or pressed into the surface of the plate 10 by more than half its thickness, this process being carried out during manufacture the plate 10 takes place. The other half protrudes above the surface 10a of the plate 10 by the remaining half of the fleece thickness and serves to hold the adhesive layer.

1, a plurality of plates 10 of the type shown in FIG. 2 are preferably placed on the layer 2, so that the fleece 12 is arranged on the upper surface of the plate 10. Plates 10 of the type shown in FIG. 2 are also advantageously used for the layer 4, however, in such a way that the fleece 12 comes to rest on the underside, as a result of which the fleece layers 12 of the layers 3, 4 lying one above the other are possible. The layers 3, 4 can thus be firmly connected to one another due to the use of the nonwoven layer protruding from the plate, and a pressure distribution plate consisting of two layers results, which is arranged floating on the elastic layer 2, ie that the lower surface of the layer 3 is not is firmly connected or glued to the elastic layer 2.

According to a further embodiment of the sports hall floor, 4 plates are used for the layer, which are provided with a fleece 12 on both the upper and the lower surface in the manner described compared to the representation according to FIG. 2. The upward-facing nonwoven layer 12 of the layer 4 pursues the purpose of ensuring a firm connection to a floor covering, for example PVC covering or the like, by means of a corresponding, preferably waterproof adhesive layer.

According to a further modification of the sports hall floor according to the invention, not two but three layers with plates made of polyolefin or polypropylene are provided compared to the representation according to FIG. 1, so that the pressure distribution plate consists of a total of three layers and all three layers in the manner described by an adhesive over the entire surface are interconnected. A floor covering of the usual type is then applied to the top layer, as described.

Both in a two-layer and in a three-layer pressure distribution layer, the arrangement of the individual plates 10 is advantageously made such that the joints 15 of the lower layer 3 are offset from the joints 18 of the layer 4, etc. This results in the use 1 at least two layers 3, 4 of plates 10 with a joint overlapping laying a massive material thickness at the joint 15 of 2 mm with a plate thickness of 2 mm and with a three-layer laying of plates a massive material thickness of 4 mm above the joint 15 and to the side of the joint 18.

Although the weight of the individual plates 10 is low due to the production from polyolefins, preferably polypropylene, in comparison with other plastic plates of a general type, the overall structure of the pressure distribution plate with two layers 3, 4 or more such layers results in such a large weight that the Pressure distribution plate floating and flat on the elastic layer 2 rests.

The plates 10 made of polyolefin, preferably polypropylene, are preferably glass fiber reinforced and the proportion of glass fibers per plate 10 is advantageously 35%. This ensures that each plate 10 has high rigidity and also ensures the lowest possible linear expansion coefficient.

The sports hall floor described with reference to FIGS. 3 to 5 relates to a so-called mixed-elastic sports hall floor, in which in addition to an elastic layer which rests on the sub-floor and is preferably formed by a foam layer, a load distribution layer consisting of two layers of glass mat-reinforced plastic is used, which can be easily connected to one another at the construction site, in particular without the use of solvent-based adhesive or the like. According to a preferred embodiment of the invention it is provided that at least one of the two glass mat-reinforced plastic layers is provided on its two surfaces with a pressure-sensitive adhesive, the carrier film of which remains on the glass mat-reinforced plastic layer, so that the film can only be removed if necessary, in order to be bonded with a to reach neighboring layer. The prefabrication of such a glass mat-reinforced plastic layer provided on at least one of its two surfaces with pressure-sensitive adhesive, in particular using a laminator or preferably a press, ensures that the adhesive layer such an intimate connection with the glass mat reinforced plastic layer results in that a later solution between the prefabricated glass mat reinforced plastic layer and the pressure sensitive adhesive layer is excluded.

The proportion of the glass mat in relation to the respective plastic layer is preferably 30%, in a further embodiment with a reduction in the coefficient of thermal expansion to less than 1/5 compared to a pure polypropylene layer about 45%.

A rubber-based pressure-sensitive adhesive has proven to be particularly suitable, which therefore eliminates the known problems with solvent-containing adhesives, in particular excludes health damage in the production of such a sports hall floor, and also has a high adhesive force compared to the plastic layer after it has been applied to the glass mat-reinforced plastic layer under pressure.

The pressure-sensitive adhesive layer can be applied on one side or on both sides to the one, upper glass mat-reinforced plastic layer under pressure. For example, the upper glass mat-reinforced plastic layer can only carry the pressure-sensitive adhesive with its carrier film on its surface facing downward in the assembled state of the sports hall floor, and after the load distribution layer has been assembled, a conventional, preferably solvent-free adhesive is applied to the upward-facing surface of the load distribution layer formed in this way becomes a permanent fixture for the top covering.

According to a first embodiment of the method according to the invention, an elastic layer 32 is placed on a sub-floor 31, for example a concrete or screed layer, which preferably consists of foam material and is optionally designed without joints. If desired, the elastic layer 32 is firmly connected to the underbody 31 by an adhesive or is fixed in some other way relative to the underbody 31. Between the underbody 31 and the elastic layer 32, if necessary, a moisture-impermeable film can be provided, which is not shown in the drawing. If necessary, a first layer 33 made of glass mat reinforced plastic is arranged on the elastic layer 32 using a pressure sensitive adhesive or the like, alternatively an adhesive connection is provided either between the glass mat reinforced plastic layer 33 and the elastic layer 32 or between the elastic layer 32 and the underbody 31. The second glass mat-reinforced plastic layer 34 is placed thereon, which is already provided with a pressure-sensitive adhesive layer 35 by prefabrication. The pressure-sensitive adhesive layer 35 is applied to the glass mat-reinforced plastic layer 34 by means of a laminator or in another way, but in such a way that an intimate connection between the pressure-sensitive adhesive layer 35 and the glass mat-reinforced plastic layer is ensured.

This intimate connection is preferably achieved by using a press. In this case, the pressure-sensitive adhesive layer 35 is rolled up by means of pressurized rollers or the like for application to the surface of the glass mat-reinforced plastic layer 34 which later faces downward, the pressure-sensitive adhesive layer 35 being supplied on a carrier film, not shown, and the carrier film remaining on the glass mat-reinforced plastic layer. The carrier film is only removed at the construction site before the plastic layer 34 with the pressure-sensitive adhesive layer 35 pointing downward is pressed onto the already existing glass mat-reinforced plastic layer 33.

As described above, the glass mat-reinforced plastic layer 34 is provided with the pressure-sensitive adhesive layer 35 on at least one surface, leaving the carrier film, and is delivered to the construction site in this state.

Depending on the structure and nature of the top covering 36 to be provided, the second glass mat-reinforced plastic layer 34 can also be provided on both sides with a pressure-sensitive adhesive layer, as is shown in the drawing by the reference numerals 35 and 37 is indicated, the respective carrier film remaining until the surface in question is to be glued to the adjacent layer. In this exemplary embodiment, after the first glass mat-reinforced plastic layer 33 has been applied, the backing film of the second glass mat-reinforced plastic layer 34 covering the pressure-sensitive adhesive layer 35 is pulled off and the second glass mat-reinforced plastic layer 34 is pressed onto the lower or first glass mat-reinforced plastic layer 33. Only then can the carrier film covering the pressure-sensitive adhesive layer 37 be removed before, in this exemplary embodiment, the top covering 36 is placed on the second glass mat-reinforced plastic layer 34. In addition to the pressure-sensitive adhesive layer, the back of the top covering 36 can be provided with an adhesive for two-sided bonding.

Instead of a pressure-sensitive adhesive layer 37, another, preferably solvent-free, adhesive can alternatively be used, which is then applied mechanically or by hand to the upward-facing surface of the second glass mat-reinforced plastic layer 34 if the layer 34 on its upward-pointing surface does not correspond to the pressure-sensitive adhesive layer 35 Has received a pressure-sensitive adhesive layer as part of the prefabrication. The adhesive layer then to be applied should have a thickness such that an intimate connection of the adhesive layer applied in this way to the top covering 36 is ensured.

The two layers 33, 34 resulting in the load distribution layer consist exclusively of glass mat-reinforced plastic material which, due to the glass mat reinforcement, obtains a relatively low coefficient of thermal expansion of, for example, 30 X 10 ^{-¾ / °} . For comparison, the coefficient of ^{linear expansion} of pure polyethylene with 200 X 10 ^{-¾ / °} , of polyvinyl chloride with 80 X 10 ^{-¾ / °} and of polypropylene with 150 X 10 ^{-¾ / ° should be mentioned} . This comparison shows that with respect to polypropylene, the glass mat reinforcement reduces the coefficient of linear expansion to about 1/5 compared to polypropylene without glass mat reinforcement, and is therefore one of them tiger sports floor is largely independent of temperature fluctuations.

After the top covering 36 has been applied, the sports floor is preferably rolled for the purpose of exerting a pressure of at least 40 kp on the top covering.

The sports hall floor produced in the manner described above consists, from bottom to top, of an elastic layer 32 resting on a sub-floor 31, followed by the load distribution layer consisting of a first glass mat-reinforced plastic layer 33 and a second glass mat-reinforced plastic layer 34, which is intimately connected to the first one by a pressure sensitive adhesive 35 glass mat reinforced plastic layer 33 is connected. Above the second glass mat-reinforced plastic layer 34, an upper covering 36 is arranged by an adhesive.

The essential advantages of the present invention, in particular a low coefficient of thermal expansion and an intimate connection between the two glass mat-reinforced plastic layers 33, 34, are obtained when using glass mat-reinforced polypropylene, which can be produced inexpensively and nevertheless due to the pressure-sensitive adhesive layer 35 applied under pressure or with the aid of a press at least one surface of the second glass mat-reinforced plastic layer 34 ensures a secure and permanent connection between the two layers 33, 34. As experiments have shown, this advantage is not achieved by using a double-sided adhesive tape, since the adhesive effect of such a double-sided adhesive tape on the two glass mat-reinforced plastic layers 33, 34 is not sufficient to ensure a permanent, firm connection between the two layers 33, 34. For this reason, the plastic layer 34 is pretreated or prefabricated for the purpose of use in a sports hall floor, in the sense that the pressure-sensitive adhesive layer is pressed onto the layer 34 together with its carrier film.

In the sports hall floor described, either the elastic layer 32 can be glued to the sub-floor 31 or the elastic layer 32 is connected to the glass mat-reinforced plastic layer 33 located above it via an adhesive layer (not shown), preferably also a pressure-sensitive adhesive layer. Finally, if necessary, both the elastic layer 32 with the underbody 31 and the layer 33 with the elastic layer 32 can be firmly connected to one another by adhesive.

As FIG. 3 shows, the separation points within the elastic layer 32 are offset from the separation points of the layer 33 located above. The separating points of the layer 33 are also offset from the separating points of the layer 34. This ensures that a full-area uniform elasticity of the entire sports floor is achieved and there is a bridging of the respective separating points necessary in layers.

According to a preferred embodiment, the glass mat-reinforced plastic layers 33, 34 are each made of plates with a size of e.g. 1.00 X 1.40 m formed.

According to a preferred embodiment, a rubber-based adhesive is used as the pressure-sensitive adhesive.

As shown in FIG. 3, in the final state, the glass mat-reinforced plastic layer 33 consists of a plurality of plates 33a, 33b, etc. lying next to one another, and the glass mat-reinforced plastic layer 34 also consists of a number of plates 34a, 34b, etc. lying next to one another.

According to a second embodiment of the method according to the invention, the load distribution layer consisting of the plastic layers 33, 34 is prefabricated in larger pieces, so that sections of the load distribution layer are obtained which have a size of, for example, 1.00 × 1.40 m. The prefabrication of such sections of the load distribution layer 33, 34 er follows in such a way that plates 34a, 34b etc. of the upper glass mat-reinforced plastic layer 34 are assembled with the corresponding plates 33a, 33b etc. of the glass mat-reinforced plastic layer 33 with the interposition of the pressure-sensitive adhesive layer, in such a way that the joints of the lower glass mat-reinforced plastic layer 33 are offset with respect to the joints the upper glass mat-reinforced plastic layer 34. Load distribution layer sections are obtained as shown in FIG. 4 and in which one of the two layers protrudes laterally. According to FIG. 4, the plastic layer 34 projects beyond the end of the plastic layer 33 at the edge. The plastic layers 33, 34 are intimately connected to one another with the interposition of the pressure-sensitive adhesive layer 35 and with the aid of a press, the carrier film being removed before the connection of the two plastic layers 33, 34 and remaining only in the region of the edge section designated 39a and 39b.

5 shows a partial view of the edge region 39a with the film 40 forming the carrier film. This film 40 remains in the case of load distribution layer sections prefabricated in this way until it is transported to the construction site and is only removed there for the purpose of assembling individual load distribution sections of this type. It is hereby achieved that the overlapping edge sections 39a, 39b of adjacent load distribution layer sections are firmly connected to one another by the existing pressure-sensitive adhesive layer 35. By exerting pressure on the edge sections 39a, 39b, after the assembly of such sections, the strength of the connection with respect to the edge section of the adjacent load distribution section is ensured.

As the perspective view of FIG. 4 shows, such prefabricated sections of the load distribution layer, each consisting of the plastic layer 33 and 34, are formed from several individual plates per layer and are delivered to the construction site, for example, in a size of 2.00 × 1.40 m . The advantage of this method is that the load distribution layer sections are already joined together under pressure before delivery to the construction site and there is an intimate connection between the two plastic layers 33 and 34 with respect to the load distribution layer sections supplied and thus the measures to be carried out at the construction site regarding the lateral joining of the sections in the region of the projecting edges 39a, 39b are reduced.

A third preferred embodiment of the method according to the invention is explained below. This method can essentially be used with reference to FIG. 3 and 4 achieve the construction of a sports hall floor, but without using the pressure-sensitive adhesive layer 35 connecting the glass mat-reinforced plastic layers 33 and 34. According to this method, prefabricated load distribution sections are produced which consist of the glass mat-reinforced plastic layers 33 and 34, which in turn consist of several individual plates 33a, 33b etc. or 34a, 34b etc. are composed. Instead of using a pressure-sensitive adhesive layer, the plastic layer 33 is connected to the plastic layer 34 by a flame treatment method, preferably by means of a flame laminating device. With such a device, the individual plates of the plastic layers 33 and 34 are fed simultaneously, in such a way that one or both of the surfaces of the plates forming the layers 33 and 34 to be facing one another are treated with a flame, which leads to a softening of the surface (n ) leads. The softening of the surfaces ensures, in particular in the case of a material such as polypropylene, the subsequent connection of the layer 33 to the layer 34 using a pressure, so that an intimate connection between the two plastic layers 33, 34 is brought about after the surfaces softened by flame treatment have cooled and the otherwise necessary gluing as an additional process step is omitted. It is essential in this process that after the opposite surfaces of the two plastic layers 33, 34 have been flamed, these layers or the associated individual plates 33a, 33b etc. on the one hand and 34a, 34b etc. on the other hand under pressure are held together until the softened surface has hardened again and has bonded to the opposite softened surface during the hardening process. The flame temperature with which the two opposing or one of the two surfaces of the plastic layers 33, 34 are treated is, depending on the feed speed to the flame laminating device, in the range between preferably 1200 ° C. and 1400 ° C.

With the prefabrication of load distribution layer sections described above, such sections are achieved as described in connection with FIG. 4, but without the use of the pressure-sensitive adhesive layer. This means that one of the two plastic layers 33, 34 protrudes at the edge from the other plastic layer, corresponding to the edge sections 39a, 39b and at the construction site the edge section 39a, 39b is flamed with respect to the surface facing the adjacent plastic layer before the load distribution layer section is also exposed to the same the flamed edge section 39a, 39b of the adjacent section is connected and held by applying a contact pressure until the flamed surface has cooled again.

After the production of the load distribution layer, in a method according to the second and third embodiment, the top covering, for example in the form of a PVC covering, is applied either using an adhesive or, for example, after flaming the upward-facing surface of the upper plastic layer 34.

According to the invention, instead of the integration of glass mats in the plastic layers, the introduction or reinforcement of the plastic layer by glass fibers can be provided if a lower than the above-described reduction in the coefficient of thermal expansion is desired or permissible.

The term “glass mat” is to be understood as a flexible fleece or flexible fabric formed by glass fibers.

Although the invention has been described above in relation to a load distribution layer consisting of two plastic layers, the load distribution layer can also be formed by three glass mat-reinforced plastic layers with higher stability requirements. The third plastic layer is applied in the same way as described above with regard to the two plastic layers.

FIG. 6 shows a further embodiment of a sports hall floor, in which glass mat-reinforced plates made of polyolefin or preferably polypropylene are used, as are described with reference to the embodiments explained above. In the embodiment according to FIG. 6, a further adhesive layer 35 'is provided compared to the embodiment according to FIG. 5, which is formed between the elastic layer 32 on the one hand and the plastic layer 33 on the other hand and ensures a firm connection between the layers 33 and 32. A pressure-sensitive adhesive layer is preferably used as the adhesive layer.

According to the invention, the plastic layers are preferably made of polypropylene, i.e. a plastic from the group of polyolefins, manufactured and used.

Claims (23)

1. Sports hall floor, in particular for gyms, with an elastic layer applied to a sub-floor or raw floor made of screed or the like, on which an impact and force-absorbing layer is optionally arranged with the interposition of a plastic film or the like,
characterized,
that the shock and force-absorbing layer consists of at least two layers (3, 4) of polyolefin plates (10), and that the plates (10) are glass fiber reinforced or reinforced by glass mats. 2. Sports hall floor according to claim 1, characterized in that the glass mats in the form of a fleece are arranged at least in one layer (3 or 4) on their surface facing the other layer (4 or 3) and both layers including the fleece (12) are glued together. 3. Sports hall floor according to claim 1, characterized in that the plates (10) consist of polypropylene. 4. Sports hall floor according to one of the preceding claims, characterized in that the plates (10) of a layer (3, 4) are provided on both sides with a fleece (12). 5. Sports hall floor according to one of the preceding claims, characterized in that the plates (10) of one layer (3) to the plates of the other layer (4) are laterally offset such that there is a lateral displacement of the plate joints (15, 18th ) results. 6. Sports hall floor according to at least one of the preceding claims, characterized in that two or three layers (3, 4) on plates (10) are provided. 7. sports hall floor according to at least one of the preceding claims, characterized in that on the top layer (4) a floor covering or the like is glued. 8. sports hall floor according to at least one of the preceding claims, characterized in that the plates (10) of the uppermost layer (4) are provided on their upward-facing surface with a fleece (12). 9. sports hall floor according to at least one of the preceding claims, characterized in that the fleece (12) is at least partially embedded in the surface during the manufacture of the plates (10). 10. Sports hall floor according to at least one of the preceding claims, characterized in that the layers (3, 4) are glued to one another over the full area and are arranged in a floating manner on the elastic layer (2). 11. Sports hall floor according to at least one of the preceding claims, characterized in that each plate (10) has between 30 and 45%, preferably 35% glass fiber content. 12. Sports hall floor according to at least one of the preceding claims, characterized in that a pressure-sensitive adhesive layer (35 ') is provided between the elastic layer (31) and the plastic layer (3, 32) located thereon. 13. Sports hall floor according to at least one of the preceding claims, characterized in that a pressure-sensitive adhesive layer with or without a carrier is provided between the layers (3, 4) and optionally between the elastic layer and the layer arranged above it. 14. Process for producing a sports hall floor,
in which an elastic layer is placed seamlessly on an underbody,
after which to form a load distribution layer consisting of a first and a second plastic layer, the first plastic layer is placed on the elastic layer and then the second plastic layer is applied to the first plastic layer and bonded to it using a pressure sensitive adhesive,
an upper covering is then arranged on the second plastic layer by means of an adhesive, the separation points between adjacent layers or layers being offset from one another,
characterized by
that the first and second plastic layers are made of glass mat reinforced plastic,
that on at least one surface of at least the second glass mat-reinforced plastic layer, a pressure-sensitive adhesive located on a film as a carrier is applied, such that the film remains on the respective surface of the second glass mat-reinforced plastic layer so that the film is applied to the first glass mat-reinforced plastic layer before the second glass mat-reinforced plastic layer is applied The plastic layer on the side facing the first glass mat-reinforced plastic layer is peeled off from the second glass mat-reinforced plastic layer and then the two glass mat-reinforced plastic layers are connected to one another, and that, if appropriate, an adhesive is applied to those facing upwards Surface of the second glass mat-reinforced plastic layer is attached to attach the top covering. 15. The method according to claim 14, characterized in that the pressure-sensitive adhesive layer is applied to the plastic layer by means of a press, a laminator or the like. 16. The method according to claim 14, characterized in that the second glass mat-reinforced plastic layer is provided on both sides by means of a laminator and / or a press with a pressure sensitive adhesive located on a film as a carrier and that the film removes the upward-facing pressure sensitive adhesive layer before the top coating is applied becomes. 17. Process for producing a sports hall floor,
in which an elastic layer is placed seamlessly on an underbody,
after which a load distribution layer, consisting of a first and a second plastic layer, is placed on the elastic layer,
an upper covering is then arranged on the second plastic layer by means of an adhesive, the separation points between adjacent layers or layers being offset from one another,
characterized by
that the first and second plastic layers are made of glass mat reinforced plastic,
that a pressure-sensitive adhesive located on a film as a carrier is applied to at least one surface of one of the two glass mat-reinforced plastic layers, and that the film is removed,
that the other plastic layer is then placed on the pressure-sensitive adhesive layer and the two plastic layers are connected to one another by a press or the like, including the pressure-sensitive adhesive layer,
that sections produced in this way, forming the load distribution layer, are placed one after the other on the elastic layer and in the region of edge sections with one another be connected, and
that, if necessary, an adhesive is applied to the upward-facing surface of the second glass mat-reinforced plastic layer for fastening the top covering. 18. Process for producing a sports hall floor,
in which an elastic layer is placed seamlessly on an underbody,
after which a load distribution layer, consisting of a first and a second plastic layer, is placed on the elastic layer,
an upper covering is then arranged on the second plastic layer by means of an adhesive, the separation points between adjacent layers or layers being offset from one another,
characterized by
that the first and second plastic layers are made of glass mat reinforced plastic,
that plates of the first and second plastic layers are simultaneously fed to a device which flames one or both of the opposite surfaces of the plates of the two plastic layers for softening, after which the plates of the two plastic layers are joined together under pressure by means of a press or the like and until the softened has cooled Surfaces are held together, and
that the plastic layers forming a load distribution layer and firmly connected to one another are placed on the elastic layer as units divided into sections and are connected to one another in the region of edge sections, and
that, if necessary, an adhesive is applied to the upward-facing surface of the second glass mat-reinforced plastic layer for fastening the top covering. 19. The method according to claim 17, characterized in that the protruding edge region provided with the pressure-sensitive adhesive layer is freed from the film located there, be before the individual sections of the load distribution layer are assembled. 20. The method according to claim 18, characterized in that the respective projecting edge sections are flamed before being assembled with the other sections forming the load distribution layer in order to soften the surface. 21. The method according to any one of the preceding claims, characterized in that the first glass mat-reinforced plastic layer is placed loosely or by means of an adhesive on the elastic layer. 22. The method according to at least one of the preceding claims, characterized in that glass mat reinforced polypropylene is used as the first and second plastic layer. 23. Sports hall floor according to at least one of the preceding claims, characterized in that the elastic layer is arranged in alignment or offset with the overlying plastic layer.

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