DE202019105945U1 - Recoverable floor construction with tiles - Google Patents

Abstract

Recoverable floor structure (1; 1 '), comprising:
a fixing layer (20; 20 ') arranged on a floor;
sheeting (30) disposed on the fixing layer (20; 20 ');
tile adhesive (40) disposed on the sheeting (30); and
tiles (50) arranged on the tile adhesive (40);
wherein the web material (30) consists predominantly of rubber and in particular of rubber granules bound with elastomer and further in particular of rubber granules bound with polyurethane and a material thickness of between 1 mm and 5 mm and in particular between 2 mm and 4 mm and
further in particular of between 2.5 mm and 3.5 mm and further in particular of 3 mm; and
wherein the fixing layer (20; 20 ')
between 2.5% and 30% and in particular between 5% and 20% of the area of the floor is covered and is formed by a double-sided adhesive tape which is arranged on the floor in parallel tracks or in a grid; or
between 2.5% and 30% and in particular between 5% and 20% of the floor is covered and formed by a non-hardening adhesive.

Description

The present invention relates to a removable floor structure comprising tiles. In this context, a floor structure with tiles that can be resumed is understood to mean a floor structure in which tiles can be removed from a floor carrying the tiles without the floor being damaged in the process.

In the context of this application, a “tile” is understood to mean a plate-shaped body made of ceramic, stone, stone powder, stone granulate or concrete, which cannot be deformed plastically or elastically in a non-destructive manner. Furthermore, in the context of this application, a “floor” is understood to mean a stable and largely level subsurface which is either a floor without a floor covering (for example screed, terrazzo, parquet, sub-floor construction such as floor panels, etc.) or a floor with Flooring (for example tile, linoleum, PVC, carpet, wood etc.) can act. In this context, “largely flat” means that the floor should not have any major unevenness, with the exception of joints and local damaged areas. “Large unevenness” can be understood to mean, in particular, unevenness over ± 2.5 mm. As an alternative or in addition, “large bumps” can be understood to mean those bumps where the floor has to be smoothed with a leveling compound before laying the floor covering.

Before laying tiles on a floor without a floor covering, extensive preparations must be made. These concern, for example, noise protection measures, waterproofing against moisture and leveling / smoothing of the floor. It is therefore desirable if these preparations do not have to be repeated when the tiles that provide the actual wear layer are replaced. In the case of rental properties, tenants also often want a floor covering that differs from the floor covering provided by the landlord. Therefore, even when a floor is covered with tiles, it is desirable if the tiles can, if necessary, be removed from the floor covering provided by the landlord without damaging the floor covering provided by the landlord.

Based on this, the object of the present invention is to provide a removable floor structure with tiles in which the tiles can be reliably removed from an existing floor without damaging the existing floor.

The above object is achieved by combining the features of the independent claims. Preferred developments can be found in the subclaims.

Embodiments of a removable floor structure have a fixing layer arranged on a floor, sheet material arranged on the fixing layer, tile adhesive arranged on the sheet material and tiles arranged on the tile adhesive. The web material consists predominantly of rubber and in particular of rubber granules bound with elastomer and further in particular of rubber granules bound with polyurethane and the web material has a material thickness of between 1 mm and 5 mm and in particular between 2 mm and 4 mm and further in particular between 2 and 5 mm. 5 mm and 3.5 mm and further in particular from 3 mm.

According to a first variant, the fixing layer covers between 2.5% and 30% and in particular between 5% and 20% of the area of the floor and the fixing layer is formed by a double-sided adhesive tape which is arranged in parallel tracks or in a grid on the floor. According to one embodiment, the distance between the parallel tracks is less than 2 meters and a grid dimension is less than 2 meters x 2 meters.

According to a second variant, the fixing layer covers between 2.5% and 30% and in particular between 5% and 20% of the floor and the fixing layer is formed by a non-hardening adhesive.

Since the web material consists predominantly of rubber, it can adapt well to the shape of the floor and, due to the material thickness of the web material, compensate for small unevenness and, for example, unevenness of up to ± 2.5 mm. In addition, the sheeting has a high coefficient of friction with respect to the ground. In fact, adhesion often occurs between the sheeting and conventional floors. As a result, the sheet material used allows, instead of full-surface gluing to the floor by means of a cementitious adhesive, only locally limited adhesion to the floor by means of double-sided adhesive tape or locally limited adhesion with a non-hardening adhesive (which is then not based on cement) to be provided. As a result, the floor structure can be removed from a floor without destroying the floor. Thus, the floor structure can be taken up again. Resuming the floor structure by detaching the fixing layer from the floor is associated with significantly less time and effort than conventional removal of tiles by mechanical chipping / chiseling off. Since the soil does not have to be reconditioned before a new occupation, there are no prior to a new occupation Waiting times required. In addition, resumption is associated with less dust and dirt than mechanical chipping / chiseling off. As a result, short renovation cycles (such as for a carpet or laminate floor) become realistic and fashion trends in the ceramic industry can be quickly and easily understood despite the fundamental durability of tiles. The floor structure according to the invention has a thickness that is only increased by a maximum of 5 mm compared to laying the tiles directly on the floor due to the use of the sheeting material. Another advantage of the floor structure described can be seen in the improved footfall sound insulation of up to 17 dB (depending on the building construction) due to the sheeting. Due to the sheeting, tiles can also be laid on floors that are cracked or at risk of cracking, without the need for an expensive resin renovation of the floor beforehand. Finally, the sheeting avoids the transmission of undesirable interactions (for example due to thermal expansion) between the floor and the tiles. For example, a still young cement screed can be covered with the floor structure according to the invention without residual moisture measurement, without the otherwise associated encapsulation effects and a calcium sulphate screed can also be covered at a much earlier period and with higher residual moisture without the tiles coming off. Finally, the resumable floor structure according to the invention has a load-bearing capacity which is comparable to that of conventional non-recoverable floor structures and is significantly higher than conventional recoverable floor structures.

According to one embodiment, the resumable floor structure furthermore has a joint compound which fills the joints remaining between the tiles. The grout is based on epoxy resin (instead of the usual cement-based). Alternatively, the grout can be based on cement, but be plasticized. A joint formed from plastic-modified cement mortar is also referred to as a plastic-modified cementitious joint. Such a joint compound has a higher elasticity and a higher flank adhesion to tiles than a cement-based joint mortar that is not plasticized. This is useful because the web material has a certain elasticity. Due to the strong adhesive bond between the tiles, the floor structure can also withstand horizontal loads.

According to one embodiment, in the first variant, the adhesive of the double-sided adhesive tape is selected so that a maximum tensile load of the double-sided adhesive tape with respect to the floor (and thus an adhesion between the adhesive tape and the floor) is lower than a maximum tensile load of the double-sided adhesive tape with respect to the sheeting (and thus an adhesion between the adhesive tape and the sheeting). As an alternative or in addition, in the first variant the adhesive of the double-sided adhesive tape is chosen so that layers of the double-sided adhesive tape do not delaminate when it is peeled off the floor. As a result, the double-sided adhesive tape can be peeled off the floor together with the sheeting when the floor structure is to be picked up again and thus removed.

According to one embodiment, in the second variant, the non-hardening adhesive is selected such that a maximum tensile load against the floor is less than a maximum tensile load against the sheet material.

According to one embodiment, the tile adhesive has liquid polymers. Such tile adhesives have greater elasticity than cement-based tile adhesives and, due to their highly flexible mortar matrix, have a stress-relieving effect. In addition, such tile adhesives can be hardened quickly. According to one embodiment, liquid polymers are added to the tile adhesive during mixing, which are no longer redispersible after curing.

According to one embodiment, the sheet material has a density of between 700 kg / m ³ and 1,300 kg / m ³ and in particular of between 900 kg / m ³ and 1,100 kg / m ³ and thus a relatively high density. Because of this high density, the sheeting rests on the floor with high slip resistance even if it is only partially fixed by the fixing layer.

According to one embodiment, the tile has a thickness (also referred to as a thickness) of at least 6 mm and in particular of at least 10 mm. According to one embodiment, the tile has a thickness of not more than 80 mm and in particular not more than 50 mm. With such thicknesses, the tiles are usually able to distribute point loads over an area without breaking.

A method for erecting a re-absorbable floor structure, in particular a re-absorbable floor structure as described above, comprises successively the steps of gluing a fixing layer to a floor, arranging sheeting material on the fixing layer, applying tile adhesive to the sheeting material and arranging tiles on the Tile glue on. The sheeting consists mainly of rubber and in particular from rubber granules bound with elastomer and further in particular from rubber granules bound with polyurethane and the sheet material has a material thickness of between 1 mm and 5 mm and in particular between 2 mm and 4 mm and further in particular between 2.5 mm and 3.5 mm and further in particular from 3 mm. Furthermore, according to a first variant, the fixing layer covers between 2.5% and 30% and in particular between 5% and 20% of the area of the floor and the fixing layer is formed by a double-sided adhesive tape which is arranged in parallel tracks or in a grid on the floor. According to an alternative second variant, the fixing layer covers between 2.5% and 30% and in particular between 5% and 20% of the floor and the fixing layer is formed by a non-hardening adhesive.

A floor structure with the layer structure described above can be used well for providing a re-absorbable floor structure.

• 1 schematisch eine erste Ausführungsform eines wiederaufnahmefähigen Bodenaufbaus; und
• 2 schematisch eine zweite Ausführungsform eines wiederaufnahmefähigen Bodenaufbaus.

Embodiments of the invention are explained in more detail below with reference to figures. Here shows

• 1 schematically a first embodiment of a removable floor structure; and
• 2 schematically a second embodiment of a removable floor structure.

In the following with reference to 1 a method for the construction of a re-absorbable floor structure 1 and the floor structure 1 described himself.

The starting point is a largely level surface in the form of a floor 10 . In the embodiment shown, it is a conventional screed.

On the ground 10 becomes a fixing layer in a first step 20th in the form of a grid with the ground 10 glued double-sided tape arranged. In the embodiment shown, a conventional carpet adhesive tape with a width of 10 cm is used and the grid dimension is 1 meter x 1 meter. As a result, 10% of the area of the floor is with the fixing layer 20th covered.

The second step is on the floor 10 with the fixing layer 20th a sheeting 30th arranged, which in the embodiment shown consists of rubber granules bound with polyurethane and can be obtained under the name "Sopro TEB 664" from Sopro Bauchemie GmbH in Wiesbaden. The webs of sheeting 30th have a width of 1 meter, a thickness of 3 millimeters, a length of 10 meters and a weight per unit area of 3.1 kg / m ² (and thus a density of around 1.00 kg / m ³ ) and are thus on the fixing layer 20th arranged that butts the webs of sheeting 30th come to rest in the middle of the adhesive tape strip.

In a third step, the sheeting is applied 30th tile glue 40 applied, which has a liquid polymer for curing. A corresponding tile adhesive can be obtained from Sopro Bauchemie GmbH in Wiesbaden under the name “SopromegaFlex S2 turbo”.

Subsequently, on the not yet hardened tile adhesive 40 Ceramic tiles 50 with a thickness of 10 mm arranged after the tile adhesive has hardened 40 with a grout 60 based on epoxy resin. A corresponding joint compound can be obtained under the name "SoproFugenEpoxi plus" from Sopro Bauchemie GmbH in Wiesbaden.

As an alternative to using a grout based on epoxy resin, a grout based on cement, which is plasticized, can also be used. A joint formed from this material is called a plastic-modified cementitious joint.

In the first embodiment, the adhesive of the double-sided tape is like this on the floor 10 and the sheeting 30th matched that a maximum tensile load of the double-sided adhesive tape against the floor 10 is less than a maximum tensile load of the double-sided adhesive tape against the sheeting 30th and that layers of the double-sided tape do not delaminate when peeled from the floor, but all layers of the tape on the sheeting 30th stick.

A floor structure as formed above 1 can be used well as a re-absorbable floor structure, as the sheeting material 30th with the tiles arranged on it 50 and the one with the sheeting 30th glued fixing layer 20th made of double-sided tape just off the floor 10 can be deducted.

In the following, with reference to the 2 a second embodiment of a retractable floor structure 1' described. Only differences to the above first embodiment are discussed in more detail and otherwise reference is made to the explanations relating to the first embodiment.

The second embodiment differs from the first embodiment described above only in that it acts as a fixing layer 20 ' instead of the only partially provided double-sided adhesive tape, a layer of non-hardening adhesive is provided which covers the bottom 10 also only covered to a limited extent locally. In the embodiment shown, the adhesive became the fixing layer 20 ' applied in strips with a width of 25 cm each. The grid size between the strips of adhesive is 1 meter by 1 meter, measured from the center of the adjacent strips. As a result, 25% of the area of the floor is covered with the fixing layer 20 ' covered. The non-hardening adhesive is so on the floor 10 and the sheeting 30th tuned that a maximum tensile load against the floor 10 is less than a maximum tensile load on the sheet material 30th .

Next is in the second embodiment between the sheet material 30th and the tile adhesive 40 an additional functional layer 70 intended. This is a thin-layer, water-impermeable and crack-bridging layer made of polypropylene webs, which is bonded to the web material by means of a suitable adhesive - not shown in the figure 30th is glued. A corresponding sheet material can be obtained under the name "AEB Abdichtungs- und EntkopplungsBahn - AEB 640" and a corresponding adhesive under the name "Fixier- & DichtKleber - FDK 415" from Sopro Bauchemie GmbH in Wiesbaden. The arrangement of such a functional layer 70 allows the required water exposure classes to be adhered to. In this way, for example, a floor that can be re-used could be built on a listed parquet floor, which allows the installation of a bathroom. The provision of a sealing functional layer is not only useful in bathrooms, but wherever there is a risk of water in liquid form on the floor. For this it is not absolutely necessary that a tap is available; rather, this can already be the case with larger aquariums.

The foregoing has been made in relation to 2 a floor structure described in which the functional layer 70 has a waterproof property. However, the present invention is not limited to this. As an alternative or in addition, the functional layer can also have, for example, a leveling, height-compensating and / or load-distributing property. Then, for example, filler compound can be used for the functional layer, into which, for example, a fabric made of glass fibers is also inserted for reinforcement. A corresponding filler and a corresponding reinforcement mesh can be found under the name “Sopro VarioFlieSpachtel - VS 582 ‟And“ Sopro PG-X 1188 - PanzerGewebe eXtra ”from Sopro Bauchemie GmbH in Wiesbaden. Such a functional layer can increase the protection of the floor. In addition, tiles can then also be laid on very uneven floors, where the unevenness is, for example, more than ± 2.5 mm.

Several functional layers with different properties can also be provided between the web material and the tile adhesive.

It is emphasized that the thicknesses in the figures are only schematic and in no way represent real relationships. For example, the tiles are drawn too thin in relation to the sheeting.

Claims (9)

Recoverable floor structure (1; 1 '), comprising: a fixing layer (20; 20 ') arranged on a floor; sheeting (30) disposed on the fixing layer (20; 20 '); tile adhesive (40) disposed on the sheeting (30); and tiles (50) arranged on the tile adhesive (40); wherein the web material (30) consists predominantly of rubber and in particular of rubber granules bound with elastomer and further in particular of rubber granules bound with polyurethane and a material thickness of between 1 mm and 5 mm and in particular between 2 mm and 4 mm and further in particular of between 2.5 mm and 3.5 mm and further in particular of 3 mm; and wherein the fixing layer (20; 20 ') between 2.5% and 30% and in particular between 5% and 20% of the surface of the floor is covered and is formed by a double-sided adhesive tape which is arranged in parallel tracks or in a grid on the floor; or between 2.5% and 30% and in particular between 5% and 20% of the floor is covered and formed by a non-hardening adhesive. Recoverable floor structure (1; 1 ') according to Claim 1 , further comprising a joint compound (60) which fills the joints remaining between the tiles (50), the joint compound (60) being based on epoxy resin or on the basis of plastic-modified cement mortar. Recoverable floor structure (1; 1 ') according to Claim 1 or 2 , wherein the adhesive of the double-sided adhesive tape is selected such that a maximum tensile load of the double-sided adhesive tape against the floor (10) is less than a maximum tensile load of the double-sided adhesive tape against the sheet material (30); and / or wherein the adhesive of the double-sided adhesive tape is selected such that layers of the double-sided adhesive tape do not delaminate when it is peeled off the bottom (10). Recoverable floor structure (1; 1 ') according to Claim 1 or 2 wherein the non-hardening adhesive is selected such that a maximum tensile load against the floor (10) is less than a maximum tensile load against the sheet material (30). Recoverable floor structure (1; 1 ') according to one of the Claims 1 to 4th wherein the tile adhesive (40) comprises a liquid polymer. Recoverable floor structure (1; 1 ') according to one of the Claims 1 to 5 wherein the sheet material (30) has a density of between 700 kg / m ³ and 1,300 kg / m ³ and in particular of between 900 kg / m ³ and 1,100 kg / m ³ . Recoverable floor structure (1; 1 ') according to one of the Claims 1 to 6th , further comprising a functional layer (70) arranged between the sheet material (30) and tile adhesive (40), the functional layer (70) having a leveling, height-compensating, load-distributing and / or water-sealing property. Recoverable floor structure (1; 1 ') according to one of the Claims 1 to 7th wherein the tiles (50) each have a thickness of between 6 mm and 80 mm or of between 10 mm and 50 mm. Use of a fixing layer (20; 20 ') that can be glued to a floor; sheet material (30) which can be arranged on the fixing layer (20; 20 '); tile adhesive (40) which can be applied to the sheet material (30); and tiles (50) which can be arranged on the tile adhesive (40); for providing a floor structure (1; 1 ') that can be taken up again, in particular a floor structure (1; 1') that can be taken up again according to one of the Claims 1 to 8th The web material (30) consists predominantly of rubber and in particular of rubber granules bound with elastomer and further in particular of rubber granules bound with polyurethane and a material thickness of between 1 mm and 5 mm and in particular between 2 mm and 4 mm and further in particular between 2 , 5 mm and 3.5 mm and further in particular of 3 mm; and wherein the fixing layer (20; 20 ') covers between 2.5% and 30% and in particular between 5% and 20% of the area of the floor and is formed by a double-sided adhesive tape which is arranged in parallel tracks or in a grid on the floor ; or between 2.5% and 30% and in particular between 5% and 20% of the floor is covered and formed by a non-hardening adhesive.

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