WO2023144321A1 - Method for producing floorboards, and method for sealing connection regions of a floor covering - Google Patents

Abstract

The invention relates to a method for producing floorboards for a floor covering with at least partly coated end faces. A plurality of floorboards are provided, each of which has multiple end faces, and at least one of the end faces of the plurality of floorboards is at least partly coated with a material which can be biologically grown or a component of a material which can be biologically grown in order to form a respective at least partly coated end face. The invention additionally relates to a method for sealing connection regions of a floor covering which has multiple floorboards, wherein multiple floorboards are produced for a floor covering with at least partly coated end faces using an aforementioned method for producing floorboards, and the floorboards are arranged on an underlying surface such that one of the coated end faces of the floorboards contacts a respective other end face of another floorboard of the floorboards while at least partly forming a connection region. The material which can be biologically grown or a material which is made of the aforementioned component can be biologically grown is biologically grown, and the connection region between the coated end face and the other end face is sealed.

Description

Method for manufacturing floorboards and

Method of sealing joint areas of a floor covering

The invention relates to a method for producing floorboards for a floor covering with end faces that are coated at least in sections. Furthermore, the invention relates to a method for sealing connection areas of a floor covering.

When laying a floor covering formed from floorboards, it is usually necessary to seal connecting areas between the floorboards in order to prevent unwanted penetration of liquids between the laid floorboards. Without such a seal, there is, for example, the risk that leaking water will penetrate the floor covering at a joint between two floorboards. As a result, the floor may swell or mold may develop.

It is known in the prior art to seal the floor covering in the laid state by applying a sealing agent, as is described, for example, in the publications US 2021/0363759 A1, US 2013/0295368 A1 and DE 295 06 043 U1. This procedure involves a lot of work. In addition, those surface sections of the floorboards that have already been sufficiently sealed by painting are coated again. As a result, the consumption of sealing agent is increased unnecessarily and the visual appearance of surface sections that have already been painted may be impaired.

As an alternative to sealing when laid, it is also known to coat the end faces of the floorboards, which are connected to one another during laying, with a sealing agent. This method can prevent unwanted penetration of liquids at the contact points of the end faces. However, it has turned out to be disadvantageous that a seal can only be reliably obtained if the end faces of the floorboards are pressed against one another with sufficient force. If after laying - for example due to manufacturing tolerances - a gap remains between the end faces of the floorboards, liquids can penetrate into deeper areas of the floor covering despite the sealing agent applied to the end faces of the floorboards. Against this background, the task arises of enabling a floor covering formed from floorboards to be sealed with little effort and little use of sealing agent, which is robust to manufacturing tolerances.

To solve the problem, a method is proposed for producing floorboards for a floor covering with end faces that are coated at least in sections, a plurality of floorboards being provided, each of which has a plurality of end faces, with at least one of the end faces of a plurality of floorboards being coated at least in sections with a biologically growing material or is coated with a component of a biologically growing material in order to form an at least partially coated end face.

In the method, multiple floorboards are provided. The floorboards each have a plurality of end faces which can each be brought into contact with an end face of another floorboard during later laying. According to the invention, the floorboards are treated before installation, whereby a coating of a biologically growing material or with a component of a biologically growing material is applied to at least one face of each floorboard. In this respect, a quantity of floorboards is obtained by the method according to the invention, each of which has an end face which is coated with a biologically growing material or with a component of a biologically growing material. When the floorboards are being laid, this end face, which is coated at least in sections, can be brought into contact with a further end face of another of the floorboards in order to form a connection region. The biologically growing material or a biologically growing material formed from the component can grow biologically and seal the connection area between the coated face and the further face. Due to the biological growth, gaps between the end faces of adjacent floorboards can be closed in such a way that a complete sealing of the connection area is obtained. A seal can thus be obtained which is robust with respect to manufacturing tolerances. Since the sealant can be applied prior to laying the floorboards, it is possible to use coating methods known in the art to apply the bio-growth material or bio-growth material component, so that the Workload and the amount of sealing agent used can be kept low.

The biologically growing material preferably forms a water-impermeable coating.

The biologically growthable material or the component of the biologically growthable material is preferably designed to change, in particular to reduce, the surface tension of the end face that is coated at least in sections. By reducing the surface tension of the end face that is coated at least in sections, it is possible to prevent liquids from wetting it. Liquids whose surface tension is greater than the surface tension of the end face that is coated at least in sections form droplets and do not wet the end face. The end face, which is coated at least in sections, then behaves in a water-repellent manner. The risk of undesired inflow of liquids into gaps between end faces of adjacently arranged floor elements can also be reduced in this way. More preferably, the biologically growing material or component of the biologically growing material is adapted to reduce the surface tension such that it is less than the surface tension of water at 20°, for example less than 72.75 mN/m.

According to an advantageous embodiment of the invention, it is provided that the biologically growing material has a fungal mycelium. For the purposes of the invention, a fungal mycelium is understood to mean the entirety of all hyphae, ie filamentous cells, of a fungus. Mushroom mycelium can grow into a mass within a few hours or days that may completely close any existing gaps between the front sides of adjacent floor coverings. The mushroom mycelium can take on the consistency of a sticky mass. In addition, mushroom mycelium has the ability to bond with natural materials such as wood. In this respect, floorboards formed in particular from natural materials such as wood can be sealed.

An advantageous embodiment of the invention provides that the component of the biologically growing material has fungal spores. A fungal mycelium can be formed from fungal spores by adding another component or a nutrient, for example water. The above fungal mycelium may be a fungal mycelium of a fungus mentioned below and/or the fungal spores mentioned above may be fungal spores of a fungus mentioned below. This fungus is selected from the fungi of the departments Ascomycota (Ascomycetes), Basidiomycota (Upright Mushrooms), Entorrhizomycota, Chytridiomycota (Potty Fungi), Neocallimastigomycota, Blastocladiomycota, Microsporidia and Glomeromycota.

According to an advantageous embodiment of the method according to the invention it is provided that at least one further end face of the floorboards is at least partially coated with a nutrient for the biologically growing material in order to form a further end face which is at least partially coated. During subsequent installation of the floorboards to form a floor covering, a face of a first floorboard coated with the bio-growth material can then be brought into contact with a face of a second floorboard coated with the nutrient. The nutrient can then enable and/or enhance the growth of the biologically viable material. As a result of the growth, the connection area between the two end faces of the first and second floorboard can be sealed by the biologically growing material. The nutrient can be, for example, a malt, in particular a malt extract, or a vegetable oil, in particular linseed oil.

According to an advantageous embodiment, it is provided that the further end face that is coated at least in sections is arranged opposite the one end face that is coated at least in sections. Such a configuration brings with it the advantage that several floorboards can be obtained, which can be connected to one another. The floorboards can be joined such that a first face of bio-growing material abuts a second face of nutrient so that the joint areas can be sealed by the bio-growing material.

According to an advantageous embodiment, it is provided that the biologically growing material or the component of the biologically growing material is provided in liquid form for the coating. The coating can take place, for example, by means of a transfer wheel, via which the biologically growing material provided in liquid form is applied to the section of the end face. For this purpose, the biologically growing material can be picked up from a container by the transfer wheel. The transfer wheel may have a chamfer, the chamfer being parallel aligned with the portion of the face to be coated. The layer thickness of the biologically growing material on the transfer wheel can be adjusted using a scraper. The transfer wheel, in particular the bevel, is spaced apart from the end face of the floorboard by a gap during application. The biologically growing material is preferably applied from the transfer wheel to the front side by means of adhesive forces.

According to an advantageous embodiment, it is provided that after the coating, the floorboards are irradiated with electromagnetic radiation, in particular UV radiation, in order to activate growth of the biologically growing material. The UV radiation can cover a wavelength range from 380 nm to 100 nm.

According to an advantageous embodiment, it is provided that the floorboards are packaged after the coating, and in particular after exposure to electromagnetic radiation, in particular packaged in such a way that the biological growth of the material capable of biological growth is inhibited. In this way, premature growth of the biologically growing material can be inhibited until the floorboards are removed from the packaging for installation.

According to an advantageous embodiment, it is provided that the material capable of biological growth grows biologically on the end face and forms a compressible coating. The formation of a compressible coating makes it possible to close gaps between the individual floorboards during installation, for example caused by manufacturing tolerances, the floorboards being pressed against one another, the compressible coating being compressed and sealing the connection area being made possible.

To achieve the above-mentioned problem, a method for sealing connecting areas of a floor covering having a plurality of floorboards is also proposed, with a method described above for the production of floorboards being used to produce a plurality of floorboards for a floor covering with end faces that are coated at least in sections, with the floorboards having such a are arranged on a substructure such that one of the coated end faces of the floorboards is at least partially in contact with another end face of another of the floorboards, forming a connection area, wherein the bio-growth material or a bio-growth material formed from the component bio-grows and seals the junction area between the coated face and the further face.

With the method for sealing connection areas of a floor covering, the same advantages can be achieved as have already been described in connection with the method for producing floorboards.

According to an advantageous embodiment of the invention, it is provided that the end faces of the floorboards each have a tongue element or a groove element and when they are arranged on the substructure, a tongue and groove connection is formed in the connection area. The tongue and groove connection allows a form-fitting connection between two floorboards to be formed. At the same time, there is little effort involved in laying and connecting the floorboards.

According to an advantageous embodiment of the invention, it is provided that the end faces of the floorboards each have a mechanical coupling element and when they are arranged on the ground, a non-positive connection of two coupling elements is formed in the connection area. In this way, a non-positive connection of two floorboards can be made possible. The mechanical coupling elements are preferably designed as a click-connection coupling element. When connecting, the click connection coupling elements of two floorboards can snap into each other. Snapping is often accompanied by a clicking sound.

According to an advantageous embodiment, it is provided that the floorboards are removed from a packaging before they are arranged on the subsurface, in particular from a packaging that inhibits the biological growth of the biologically growth-capable material. The packaging can, for example, prevent the floorboards from coming into contact with moisture, in particular atmospheric moisture or water. The floorboards are preferably packed in the packaging after production, in particular after the coating of their end faces, so that the growth of the biologically viable material is inhibited between the coating process step and the laying process step. Growth can then begin after removal from the packaging and the floorboards arranged on the substructure can be sealed in their connection areas. According to an advantageous embodiment, it is provided that a nutrient and/or a growth-promoting substance, in particular water, is placed on the floorboards and/or the connection areas in order to activate and/or promote the growth of the biological material. Any gaps and/or cracks in the connection area can be closed by the growth and the respective connection area can be sealed.

In this connection it is particularly advantageous if the nutrient and/or the growth-promoting substance is/are applied to the floorboards and/or the connection areas after the floorboards have been arranged on the substructure. The application of the nutrient and/or the growth-promoting substance can take place after the floorboards have been placed on the substrate. For example, the floor covering formed from the floorboards can be provided with the nutrient and/or the growth-promoting substance, in particular over the entire surface. The floor covering is preferably wiped with a damp cloth. The nutrient and/or growth-promoting substance can penetrate into the joint areas of the floorboards and activate and/or promote the growth of the biologically viable material located there. Any gaps and/or cracks in the connection area can be closed by the growth and the respective connection area can be sealed.

Alternatively, it is particularly advantageous if the nutrient and/or the growth-promoting substance is added to the floorboards, in particular to the end faces of the floorboards, preferably to the coated end faces of the floorboards, before the floorboards are arranged. For example, before they are laid, the end faces of the floorboards can be treated with the nutrient and/or the growth-promoting substance, e.g. As water, are provided. The growth of the biologically growing material is thereby activated and/or promoted, so that the biologically growing material grows when the floorboards are arranged on the subsurface and seals the connection area formed when the floorboards are arranged on the subsurface.

According to an advantageous embodiment, it is provided that energy, in particular thermal energy, is introduced into the floorboards and/or the connection areas in order to activate and/or promote the growth of the biologically growing material. Such an embodiment is particularly advantageous when the biologically growing material shows little or no growth under typical ambient conditions, for example a temperature of 20° C. and an air pressure of 1013.25 hPa. In this context it is advantageous if the energy is introduced by means of hot air and/or thermal radiation. Such an introduction of the energy offers the advantage that it can take place without contact.

An embodiment of the method according to the invention has proven to be advantageous, in which the energy is introduced into the floorboards and/or the connection areas after the floorboards have been arranged on the subsurface. The energy introduced can activate and/or promote the growth of the biologically viable material arranged there. Any gaps and/or cracks in the connection area can be closed by the growth and the respective connection area can be sealed.

According to an advantageous embodiment, it is provided that during the coating the end faces of different floorboards are coated at least in sections with different components of a biologically growing material, and when the floorboards are arranged on the subsurface in the connection area different components of the biologically growing material are brought into contact with one another are and form the biologically growing material. In such an embodiment, the biological growth of the biologically viable material is only initiated and/or promoted when the two components are in contact with one another. This offers the advantage that the biological growth required to seal the connection area is mainly carried out when the floorboards are already laid out on the substructure.

The advantageous configurations and features described in connection with the method for producing floorboards can also be used alone or in combination in the method for sealing connection areas of a floor covering.

Further details and advantages of the invention are to be explained below with reference to the exemplary embodiments shown in the figures. Herein shows:

1 shows a floor covering in a perspective representation;

2A/B end faces of an exemplary floorboard in a side view; 3 shows a connection area of two floorboards in a sectional view;

4 shows a schematic flowchart to explain a first and a second exemplary embodiment of a method according to the invention for sealing connection areas of a floor covering;

5 shows a schematic flowchart to explain a third and a fourth exemplary embodiment of a method according to the invention for sealing connection areas of a floor covering; and

6 shows a schematic flowchart to explain a fifth exemplary embodiment of a method according to the invention for sealing connection areas of a floor covering.

The representation in FIG. 1 shows a floor covering 5, which is formed from several floorboards 4, which are arranged lying against one another on a subsurface. The floorboards 4 can be made of wood or of a laminate comprising wood, for example. The floorboards 4 are connected to one another in connection areas 1 . In the connection areas 1 one end face of a first floorboard 4 is in contact with one end face of a second floorboard 4 .

The illustrations in Figures 2A and 2B show two side views of end faces 2 of an exemplary floorboard 4. A first end face 4 is designed in the manner of a spring side, see Figure 2A. A second end face 4, which is arranged opposite the first end face on the floorboard 4, is designed in the manner of a groove side, see Fig. 2B.

In order to form the floor covering, the floorboards 4 are arranged on the subsurface, that is to say “laid” in such a way that a tongue side is brought into contact with a groove side. A sectional view of a corresponding connection area 1 with a groove side and a tongue side is shown in FIG. It can be seen that the end faces 2 rest against one another. The end faces 2 each have a bevel 3 on an upper edge, so that a joint between two floorboards 4 lying against one another is formed on the upper edge.

According to a modification of the floorboards 4 shown in FIGS. 2 and 3, the end faces 2 of the floorboards 4 can each have a mechanical coupling element, for example a click connection coupling element. When contacting these coupling elements, ie when arranging the floorboards 4 on a substructure, a non-positive connection of two coupling elements can be formed in the connection area 1 .

Various configurations of a method for sealing connection areas of a floor covering according to the invention will be explained below with reference to the conditions of the floor covering 5 shown in FIGS.

FIG. 4 shows a flow chart of a first exemplary embodiment of a method for sealing connection areas of a floor covering according to the invention. First, a method 10 for producing floorboards for a floor covering with end faces that are coated at least in sections is carried out in order to obtain floorboards. In a first method step 11, a plurality of floorboards are provided, each having a plurality of end faces.

In a coating step 12, one or more end faces of these floorboards are coated at least in sections with a biologically growing material or with a component of a biologically growing material, here with fungal spores or with a fungal mycelium. The fungal spores or mycelium can be applied, for example, to the grooved sides of the floorboards. Another of the end faces of the floorboards is coated at least in sections with a nutrient for the biologically growing material, for example with a malt or a vegetable oil, in particular linseed oil. This is preferably an end face which is arranged on the floorboard opposite the end face coated with the biologically growing material or the component. When the mushroom spores or mycelium are placed on the groove sides, the tongue sides can be coated with the nutrient. For coating in the coating step 12, the biologically growing material or the component of the biologically growing material is provided in liquid form. This offers the advantage that conventional coating methods for liquid paints can be used for coating.

The floorboards coated in sections are then packaged in a packaging step 13, in particular packaged in an airtight and liquid-tight manner, so that the biological growth of the biologically growing material is inhibited.

Shortly before the floorboards 4 are actually laid, they are removed from the packaging in a removal step 14 . The floorboards 4 are then arranged on a substrate in a laying step 15 in such a way that one of the coated end faces 2 of the floorboards 4 is at least partially in contact with a further end face 2 of another of the floorboards 4 , forming a connection area 1 . The components of the biologically growing material come into contact or the biologically growing material comes into contact with the nutrient. As a result, the biologically viable material grows biologically and thereby seals the connecting area 1 between the coated end face 2 and the further end face 2.

A second exemplary embodiment of a method for sealing connection areas of a floor covering according to the invention can be explained on the basis of the flow chart shown in FIG. 4 . In a first method step 11, multiple floorboards are provided, each having multiple end faces. In this case, in the coating step 12, the same biologically growing material, for example a fungal mycelium, is applied either to only one end face 2 of the floorboards 4 or to several, in particular all, end faces 2 of the floorboards 4. The biologically growing material is capable of growing to a certain extent and forms a compressible and water-impermeable coating on the end faces 2 of the floorboards. The growth can start immediately after the coating step 12 and last at least until the floorboards 4 are packed in a packing step 13, in particular in an airtight and gas-tight manner.

After removing the floorboards 4 from the packaging in the removal step 14, the laying follows. In the laying step 15, the end faces 2 of the floorboards 4 are brought into contact with one another in such a way that the compressible and water-impermeable coating is compressed and a gap between the end faces and/or a joint edge on the bevel 3 is completely closed.

FIG. 5 shows a flowchart of a third exemplary embodiment of a method for sealing connection areas of a floor covering according to the invention. First, a method 10 for producing floorboards for a floor covering with end faces that are coated at least in sections is carried out in order to obtain floorboards. In a first method step 11, a plurality of floorboards are provided, each having a plurality of end faces. In the subsequent coating step 12, either only one end face 2 of the Floorboards 4 or applied to several, in particular all, end faces 2 of the floorboards 4 the same biologically growing material, for example a mushroom mycelium.

The floorboards 4 are packed in a packing step 13, in particular airtight and gas-tight. In the packed state, the floorboards 4 can be brought to their place of installation and unpacked there in a removal step 14 . At the laying site, the floorboards 4 are laid in a laying step 15 , one of the coated end faces 2 of the floorboards 4 coming into at least partial contact with another end face 2 of another floorboard 4 and forming a connection region 1 .

After laying, a nutrient, for example malt or a malt extract or a vegetable oil, in particular linseed oil, and/or a growth-promoting substance, in particular water, is then applied to the floorboards 4 and/or the connecting areas 1 in an activation step 16 . This activates and/or promotes the growth of the biological material. The biologically growing material grows into a water-impermeable mass and seals the connection area 1 between the floorboards 4.

Alternatively, the nutrient and/or the growth-promoting substance can be added to the floorboards 4, in particular to the end faces 2 of the floorboards 4, before the laying step 15, i.e. before the floorboards 4 are arranged on the subsoil.

A fourth exemplary embodiment of a method for sealing connection areas of a floor covering according to the invention can be explained with reference to the flowchart shown in FIG. Reference is therefore made to the explanations relating to the third exemplary embodiment. In contrast to the third exemplary embodiment, the activation or promotion of the growth of the biological material takes place in the activation step 16 by the introduction of energy, in particular thermal energy. This energy input preferably takes place in the floorboards 4 and/or in the connection areas 1 after the floorboards have been arranged on the subsurface. Alternatively, the energy can be introduced before laying 15 . The thermal energy can be introduced, for example, by means of hot air and/or thermal radiation.

FIG. 6 shows a flow chart of a fifth exemplary embodiment of a method for sealing connection areas of a floor covering according to the invention. First, a method 10 for producing floorboards for a floor covering with end faces that are coated at least in sections is carried out in order to obtain floorboards. In a first method step 11, a plurality of floorboards are provided, each having a plurality of end faces. In the subsequent coating step 12, the same biologically growing material, for example a fungal mycelium, is applied either to only one end face 2 of the floorboards 4 or to several, in particular all, end faces 2 of the floorboards 4. In an activation step 17 following the coating 12, the floorboards 4 are irradiated with electromagnetic radiation, in particular UV radiation, in order to activate growth of the biologically viable material.

The floorboards 4 are then packed in a packing step 13, in particular in an airtight and gas-tight manner. In the packed state, the floorboards 4 can be brought to their place of installation and unpacked there in a removal step 14 . At the laying site, the floorboards 4 are laid in a laying step 15, with one of the coated end faces 2 of the floorboards 4 coming into at least partial contact with another end face 2 of another floorboard 4 or at most through a small gap (e.g. 0.05 mm). is separated from the other end face 2 and forms a connection area 1 .

After laying, a further activation step 16 can optionally be carried out. As described above in connection with the other exemplary embodiments, a nutrient, for example malt or a malt extract or a vegetable oil, in particular linseed oil, and/or a growth-promoting substance, in particular water, can be added to the floorboards 4 and/or the connecting areas 1. Alternatively, energy, in particular thermal energy, can be introduced in the activation step 16 to promote the growth of the biological material.

In the exemplary embodiments of the method according to the invention discussed above, the biologically growing material and/or the component of the biologically growing material and/or the nutrient and/or the growth-promoting substance can be applied as a coating on an end face 2 of the floorboards 4 . Advantageously, these materials or substances are provided in liquid form, so that the coating can take place by means of a transfer wheel, via which the biologically growing material provided in liquid form is applied to the section of the end face. For this purpose, the respective material or the respective substance can be picked up from a container by the transfer wheel. The transfer wheel may have a chamfer, the chamfer being aligned parallel to the portion of the face to be coated. The layer thickness of the material to be applied or the substance to be applied can be adjusted by a scraper. The transfer wheel, in particular the bevel, is spaced apart from the end face of the floorboard by a gap during application. The application of the material or the substance from the transfer wheel to the end face is preferably carried out via adhesive forces.

Reference sign:

1 connection area

2 front side

3 chamfer to form a joint

4 floorboard

5 floor covering

10 methods of manufacturing floorboards

11 Deployment Step

12 coating step

13 packaging step

14 extraction step

15 laying step

16 activation step

17 activation step

Claims

Patent Claims:

1. A method for producing floorboards (4) for a floor covering (5) with end faces (2) coated at least in sections, wherein a plurality of floorboards (4) are provided which each have a plurality of end faces (2), wherein at least one of the end faces (2 ) several of the floorboards (4) are coated at least in sections with a biologically growing material or with a component of a biologically growing material in order to form an end face (2) that is coated at least in sections.

2. The method according to claim 1, characterized in that the biologically growing material or the component of the biologically growing material is designed to change, in particular to reduce, the surface tension of the at least partially coated end face (2).

3. The method according to any one of the preceding claims, characterized in that the biologically growing material comprises a fungal mycelium.

4. The method according to any one of the preceding claims, characterized in that the component of the biologically growing material comprises fungal spores.

5. The method according to any one of the preceding claims, characterized in that at least one further of the end faces (2) of the floorboards (4) is coated at least in sections with a nutrient for the biologically growing material in order to each have a further end face (2) coated at least in sections to build.

6. The method according to claim 5, characterized in that the further at least partially coated end face (2) is arranged opposite the at least partially coated end face (2).

7. The method according to any one of the preceding claims, characterized in that the biologically growing material or the component of the biologically growing material is provided in liquid form for the coating. Method according to one of the preceding claims, characterized in that the floorboards (4) after the coating (12) are irradiated with electromagnetic radiation, in particular UV radiation, in order to activate growth of the biologically viable material. Method according to one of the preceding claims, characterized in that the floorboards (4) after the coating (12), and in particular after exposure to electromagnetic radiation, are packaged (13), in particular packaged in such a way that the biological growth of the biologically viable Material is inhibited. Method according to one of the preceding claims, characterized in that the biologically growing material on the end face (2) grows biologically and forms a compressible coating. Method for sealing connecting areas (1) of a floor covering (5) having a plurality of floorboards (4), with a method according to one of Claims 1 to 8 a plurality of floorboards (4) for a floor covering (5) with end faces (2) coated at least in sections are produced, the floorboards (4) being arranged on a substrate in such a way that one of the coated end faces (2) of the floorboards (4) each connects to a further end face (2) of another of the floorboards (4) at least partially, forming a connection area (1) is in contact, whereby the biologically growing material or a biologically growing material formed from the component biologically grows and seals the connection region (1) between the coated face (2) and the further face (2). Method according to one of the preceding claims, characterized in that the end faces (2) of the floorboards (4) each have a tongue element or a groove element and a tongue and groove connection is formed in the connection area (1) when they are arranged on the substructure. The method according to claim 11, characterized in that the end faces (2) of the floorboards (4) each have a mechanical coupling element, in particular a click connection coupling element, and when arranging on the Subsoil a non-positive connection of two coupling elements in the connection area (1) is formed. A method as claimed in any one of claims 11 to 13, characterized in that the floorboards are removed from a package before being placed on the substructure, in particular from a package which inhibits the biological growth of the biologically viable material. Method according to any one of claims 11 to 14, characterized in that a nutrient and/or a growth-promoting substance, in particular water, is added to the floorboards and/or the connection areas in order to activate and/or promote the growth of the biological material. Method according to Claim 15, characterized in that the nutrient and/or the growth-promoting substance is added to the floorboards and/or the connection areas after the floorboards have been arranged on the substructure. Method according to Claim 15, characterized in that the nutrient and/or the growth-promoting substance is added to the floorboards, in particular to the end faces of the floorboards, preferably to the coated end faces of the floorboards, before the floorboards are arranged. Method according to any one of claims 11 to 14, characterized in that energy, in particular thermal energy, is introduced into the floorboards and/or the connection areas in order to activate and/or promote the growth of the biologically viable material. Method according to Claim 18, characterized in that the energy is introduced by means of hot air and/or thermal radiation. Method according to one of Claims 18 or 19, characterized in that the energy is introduced into the floorboards and/or the connection areas after the floorboards have been arranged on the substructure. The method according to any one of claims 11 to 14, characterized in that during the coating, the end faces of different floorboards are coated at least in sections with different components of a biologically growing material, and during the arrangement of the floorboards on the subsurface in the connection area, different components of the biologically growing material are brought into contact with one another and form the biologically growing material.