SE522217C2 - Floorboard for floating floor constructions, has surface comprising flexible fibres - Google Patents

Abstract

The floorboard has a surface comprising flexible fibres. An Independent claim is also included for a method for laying a floor using these floorboards.

Description

25 30 522 217 2 also from wooden floors which are glued to the substrate. One reason is that these floors can be laid easily and quickly on a subfloor that does not need to be completely smooth or flat.

They can move freely from the subfloor. Shrinkage and swelling occur under the baseboards and the joints between the floorboards are tight. A floating floor with a mechanical joint system can easily be picked up and laid back. Individual floorboards can be replaced, the subfloor is accessible for renovation and the entire floor can be moved to another space.

Plastic floors and textile carpets that are glued to the subfloor require a very even subfloor. The laying is difficult and the floor cannot be taken up without it being destroyed. The advantage of these floors is that they can be delivered in widths of, for example, 4 meters. The number of joints is few.

The plastic floors are waterproof and both plastic floors and textile floors are soft and provide a lower noise level than laminate and wood floors.

Floating floors thus have many advantages over floors that are glued to the subfloor. However, a major disadvantage of these floating floors with a hard surface of wood or laminate is that they provide a high noise level when people walk on the floor. The noise level can be troublesome especially in public spaces such as offices, hotels, business premises where many people stay and walk on the floor.

Floating floors could be used more if the noise level could be reduced.

Definition of certain terms In the following text, the visible surface of the pre-assembled floorboard is referred to as "front", while the opposite side of the floorboard, facing the subfloor, is referred to as "back". When the core is coated The sheet-shaped starting material used with a surface layer closest to the front and preferably also forms a semi-finished product called "floor panel" or "panel blank" in the case where the semi-finished product is divided into a number of the above-mentioned floor panels. When a balance layer closest to the back, in a subsequent operation, the floor panels are edged so that they have obtained their final shape with the joint system, they are called "floorboards".

By "surface layer" is meant all layers which are applied to the core closest to the front and which preferably cover the entire front of the floorboard. "Decorative surface layer" means a layer which is mainly intended to give the floor. "Wear layer" means a layer which is primarily intended to improve the wear resistance of the front. its decorative appearance.

"1 laminate flooring" means floors that are on the market under this name. The wear layer of the laminate floor usually consists of a transparent paper that is impregnated with melamine resin mixed with alumina.

The decorative layer consists of a melamine-impregnated decorative paper. The core is usually a wood fiber-based board. "HBF" refers to board material that is marketed under the name high density fiberboard. HDF consisting of ground wood fibers bonded with binder. When a HDF board is manufactured with a lower density, it is called MDF (medium density fiberboard) The outer parts of the floorboard at the edge of the floorboard between the front and the back are called "joint edge". The joint edge usually has several "joint surfaces" which can be vertical, horizontal, available on different materials, such as laminate, wood fiber boards, angled, rounded, bevelled, etc. These joint surfaces are wood, plastic, metal (especially aluminum) or sealing. "Joint" or "locking system" means cooperating coupling means, which connect the floorboards vertically and / or horizontally. By "mechanical locking system" is meant that joining can take place without glue horizontally parallel to the surface and vertically perpendicular to the surface. Mechanical 10 15 20 25 30 35 522 217 4 joint systems can in many cases also be joined with glue.

By "floating floor" is meant floors with floorboards that are only joined with their respective joint edges and thus the joint remains tight. Moisture movement takes place in the outer areas of the floor around not glued to the subfloor. consists of oil-based man-made fibers or natural fibers joined together to form a rug or blanket. The floor covering is usually produced in a width of about 4 m and a length that can be several hundred meters. The floor covering is delivered from the factory, usually in roll form, and is usually installed by gluing to a subfloor. "Needle felt" refers to a fiber-based felt that goes on the market under the name needle felt mat. This floor consists of oil-based fibers of, for example (PP), (PA) (PES) joined together into a felt. The joining is done by using polypropylene nylon or polyester as a fiber mat punched with hooked needles.The back is usually coated with foam which may consist of latex and chalk.

Prior Art and Problems Therewith To facilitate the understanding and description of the present invention and the understanding of the problems underlying the invention, a description of the prior art follows. Floor tiles which are hereinafter referred to as rectangular with long sides and short sides can also be square.

Hard floors with a surface of laminate or wood provide a high noise level. The high noise level occurs mainly when people walk on the hard laminate or wood surface. The sound generated at the surface creates a high noise level in the room. The sound also goes through the floor and into the floor.

To solve this problem, floating floors have been installed on a base of cardboard, felt, foam or similar material. The noise reduction thus takes place on the back of the floorboard by means of special substrate materials which are applied between the floating floor and the subfloor.

This can provide a significant attenuation of the sound level between two floors. The noise reduction that can be achieved in the room is of limited scope.

Another way to reduce the noise level is to glue the floorboards to the subfloor. This provides some noise reduction in the room and the sound frequency is perceived as more pleasant. The costs are high and the laying quality is poor with many and large joint cracks. A third way is to provide the surface of the floorboard with a surface layer of, for example, cork. This material is softer than wood and laminate and reduces the noise level. However, a cork floor has a number of disadvantages. Abrasion resistance and impression strength are relatively low, the cost is high and the noise reduction may be insufficient.

SUMMARY OF THE INVENTION An object of the present invention is to provide floorboards which can be mechanically joined to a floating floor which has a low noise level. Such a floor must at the same time have an attractive appearance and be able to be manufactured rationally with high precision.

The invention is based on a first insight that a low noise level should primarily be achieved with a surface layer which does not produce a high noise level during blows with hard materials against its surface.

The invention is based on a second insight that floorboards with a soft surface layer which has a low density have a lower noise level than floorboards with surface layers which are hard and which have a high density. The invention is based on a third insight that it is possible to provide a surface layer at a low cost and which is both sound-absorbing and which has a high wear resistance and impact resistance. Such a surface layer should consist of fibers which are flexible and which can be compressed when the floor is loaded, for example when people walk on the floor surface. These fibers can be made of materials which have a relatively high density and which are very durable, for example man-made fibers or natural fibers such as wool. When the fibers are thin and joined to a blanket or mat of air between the flexible fibers, a surface layer is created which is soft and has a low density.

The thickness of the fibers can be, for example, 0.05 - 0.10 mm. The volume density of the surface layer can be less than 400 kg / m 3 and it can preferably have a density of 150 - 300 kg / m2.

This is significantly lower than wood, laminate and cork and the noise level is significantly lower than for all these materials.

The invention is based on a fourth and very surprising insight that a fiber-based surface layer with low density, for example in the form of a needle felt mat, can be applied by, for example, gluing to a core of, for example, a wood fiber board. The core can, for example, be a chipboard. MDF or HDF. This panel blank can be divided by, for example, sawing into floor panels which are machined with, for example, a combination of rotating knives and diamond tools so that they form floorboards in a floating floor. The upper joint edges can be designed so that at the surface they predominantly consist of free fibers and closest to the core of fibers joined to the core. The surface layer can then be manufactured with high accuracy and without loose fibers. The fibers closest to the core can be joined by mixing in a flexible material. This gives the surface layer a better, for example, latex. stability and facilitates cleaning as dirt cannot penetrate into the lower parts of the surface layer. Thin surface layers can be more easily handled if they are integrated with a core.

The invention is based on a fifth insight that these floorboards can be joined together with a mechanical joint system which partly positions the floorboards with high accuracy against each other and which at the same time keeps the upper joint edges in close contact. The joints between the floorboards become very tight and they can be made so that they are basically invisible to the eye.

The invention is based on a sixth insight that a floating floor with a fiber surface can be installed quickly and rationally and at a cost which does not have to exceed the cost of filling the subfloor and gluing and cutting a textile mat. Attractive patterns can be achieved by, for example, floorboards with different formats and with different colors on the surface layer being joined together with an exact fit. Attractive patterns can, for example, be created with a surface of needle felt that normally does not allow for any major pattern variation. The thin fibrous layers, for example 1-2 mm, which are integrated with a smooth core can give a completely smooth floor. When, for example, a needle felt mat is glued to a fibreboard, the surface becomes very dimensionally stable. This facilitates, for example, the printing of advanced patterns on the fiber surface. Abrasion resistance increases if the surface is flat without elevations.

The invention is based on a seventh insight that a floating floor with a sound-absorbing fiber surface and with a mechanical joint system is easy to pick up. Such a floor is especially suitable for temporary exhibitions, business premises and the like where floors are often replaced and in rooms with high wear. Floor panels at, for example, 10 15 20 25 30 522 217 8 entrance areas where wear and dirt are high can easily be replaced.

Finally, the invention is based on an eighth insight that floors with different surface layers can be provided with mechanical joint systems so that they can be joined together.

In this way, combination floors can be provided which, for example, consist of laminate floors and needle felt floors, if the floorboards have a similar thickness, the floor will be smooth. In walkways, such a floor may have a needle felt surface to attenuate the sound level. Other surfaces can, for example, consist of floorboards with a surface of laminate, linoleum, wood or plastic. These surfaces are easy to clean and suitable material combinations can provide an attractive design.

The above thus means that according to the invention it is possible to provide a floor which has all the advantages that a liquid laminate or wooden floor has at the same time as one of the main disadvantages can be eliminated with a surface layer of fibers which does not produce a high noise level.

This object is achieved in whole or in part with floorboards and a method of manufacture as set out in the independent claims. The dependent claims state particularly preferred embodiments of the invention.

According to a first aspect, the present invention comprises rectangular or square floorboards for forming a floating floor covering, which floorboards are mechanically lockable and have along their edge portions pairwise opposite coupling means for locking adjacent floorboards in both vertical and horizontal direction (D1 and D2 respectively). surface layers consist of flexible and bendable fibers. According to a preferred embodiment of this first aspect, the floorboards can be provided with a surface layer consisting of needle felt with a density of less than 400 kg / m 3.

Several variants of the invention are possible.

The floorboards can be equipped with all known mechanical joint systems. Such floorboards can be laid by various combinations of angling, horizontal snapping, vertical snapping and insertion along the joint edge.

The floorboards can also have mirror-inverted joint systems that enable the joining of long sides to short sides or optional sides if the boards are square.

According to a second aspect of the present invention, there is provided a method of rationally manufacturing floorboards as described above. According to this method, a surface layer consisting of flexible fibers is joined together with a core to form a panel blank. The joining can be done, for example, by gluing and the core can consist of a wood fiber-based material such as HDF, MDF, chipboard, Plywood, etc. This panel blank is then sawn up and processed with rotating tools into a floorboard.

The manufacturing technique is thus characterized in that the surface layer is formed by cutting machining in connection with the joint edges of the floor panel being machined.

The invention will be described in more detail in the following with reference to the accompanying schematic drawings, which for exemplary purposes show presently preferred embodiments of the invention according to its various aspects.

Brief description of the drawings Figures 1a-d show the manufacture of a floorboard according to the invention. Figures 2a-d show examples of mechanical joint systems that can be used in the invention.

Figures 3a-c show an embodiment of the invention.

Figures 4a-f show the representation of the joint edge portion according to the invention.

Figures 5a-c show a floor consisting of floorboards with different surface layers according to the invention.

Figures 6a-6d show examples of floors according to the invention.

Description of preferred embodiments Figs. 1a-d show the manufacture of a floorboard according to the invention. A surface layer 31, which in this embodiment consists of needle felt, is joined together, for example, by gluing to a core 30. This core can for instance consist of chipboard, wood fiber board such as MDF, HDF, plywood or the like. A lower layer, for example a balance layer 32, can be applied to the back to prevent cupping.

This backing layer can also be a soft material such as foam, needle felt, cardboard or the like which evens out unevenness in the subfloor and which improves the sound reduction. This lower layer is not necessary in some applications. The panel blank 3, which may, for example, have a thickness of 5-20 mm, is then divided into a plurality of floor panels 2. These panels are then machined and joint edge portions are formed so as to form a mechanical joint system 7,7 '. Examples of such a joint system on the long sides 4a and 4b are shown in Fig. 1d.

Figures 2a-2d show examples of mechanical joint systems that can be used in the invention. The joint system according to Fig. 2a can be joined by vertical snapping. In the joint system according to Figs. 2b and 2c, a groove 36 and a spring 38 form a strip 6, the vertical joint D1. a locking element 8 10 15 20 25 30 522 217 11 and a locking groove 14 form the horizontal joint D2.

These locking systems can be joined with angles and horizontal snaps. If upper joint edges 41, 42 are compressible, joint systems in Fig. 2c can be locked with vertical snapping. A surface layer 31, which consists of, for example, a needle felt, can be compressed and this facilitates vertical snapping. Fig. 2d shows another embodiment that can be joined with angling and snapping. Upper joint edges 41,42 have a bevel in this embodiment.

Figures 3a-c show a floorboard which in this embodiment has a core 30 of a relatively soft material such as MDF or chipboard. The locking system has been adapted to the soft core in that the locking element 8 has a horizontal extent which is about 0.5 times the thickness of the core 30.

The surface layer 31 has an outer joint edges 40, 41 which in this embodiment project past the outer parts of the core 30. This projection can be a few 10-part millimeters. The outer parts of the surface layer are compressed in connection with laying and the floorboards have very tight joints. The mechanical locking system guides the floorboards in precise positions and ensures a high laying quality. The core 31 can have a thickness of, for example, 6-7 mm and the surface layer 31 can have a thickness of 1-2 mm. The total thickness of the floorboard can thus in this embodiment be about 7-9 mm and the floor can then be joined with ordinary laminate floors which have a thickness of about 7-8 mm.

Figs. 4a-4f show how joint edge portions can be machined.

We have discovered that a soft surface layer of fibers cannot be processed accurately with cutting rotary tools that are normally used in connection with the manufacture of laminate and wood floors and the most common wood-based core materials in these contexts.

Loose fibers, especially in corner sections, give a crispy joint edge. Plastics used in the production of synthetic fibers generally have a melting point of around 120 - 160 degrees C. At high processing speeds, the fibers melt. These problems can be solved by cutting off the surface layer with, for example, knives. These TPla and TPlB knives can be rotary. The angle of engagement of the knives is shown by the arrows R1a and R1b in Figs. 4a, 4b. The knives, which may have angles other than the shown 90 degrees, cut towards the core 30 and the cut is in this embodiment placed outside the upper and outer part of the core in the finished floorboard. Figs. 4c-f show that the whole joint system can be formed with only 4 which process milling tools TP2a, TP2B, TP3A and TP3B, the core. The joint system in the embodiment shown is made in one piece with the core. It is also possible to manufacture all or parts of the joint system from material other than the core of the floorboard. The strip 6 can for instance be made of aluminum or of a sheet-shaped blank which is processed into a strip and mechanically fastened to the joint edge.

Figures 5a-c show floorboards with two surface layers.

The floorboards 1, 1 'may, for example, have a surface layer of laminate or wood and the floorboards 2, 2' may have a surface layer of, for example, needle felt, linoleum, plastic or other suitable material. More material combinations may also occur. Figures 5b and 5c show that joining can take place with outer upper parts which lie substantially in the same plane. No transition lists are necessary.

Figures 6a-6d show examples of floors which can be achieved according to the invention. In Fig. 6a, the floorboards 2, 2 'have a surface of needle felt. They can be square, for example 40 * 40 cm. The floorboards 1, 1 'can have a surface of laminate, wood, cork linoleum, plastic, etc. They can, for example, have a width of 10 cm and a length of 40 cm. In Fig. 6b, the panes are offset. If the harder floorboards 1, 1 'are at a slightly lower level than the softer floorboards, the hard floorboards will not give a high noise level as they will to a limited extent be in contact with shoes which produce sound. The invention thus also relates to a set of floorboards with at least two different surface layers to provide a floor.

Figs. 6c and 6d show floors consisting of two different floorboards with surface layers of flexible fibers that differ with respect to color, surface structure, etc. In Fig. 6c, the floorboards have been joined to form a herringbone pattern. They have mirror-inverted mechanical locking systems that enable the joining of the long side to the short side with angling and / or snapping. The long sides can also be joined by angling and / or snapping.

It is obvious that all known parquet and tile patterns can be produced with floorboards according to the invention. The sides of the floorboards do not have to be perpendicular. The soft surface enables the thickness to be varied between different floorboards. If the core is made of a moisture-proof material such as plastic or compact laminate, floorboards with a fiber surface that resembles artificial grass can be produced. Such floorboards can be laid directly on ground or concrete and they can, for example, form tees in golf courses, balcony floors, etc. Before winter, the boards can be picked up and stored under a roof.

Claims (8)

10 15 20 25 30 522 217 14 PATENT REQUIREMENTS Floorboards (1, 1 ') having a surface layer (31) and a core (30), for forming a liquid floor covering, which floorboards are mechanically lockable and which along their edge portions have pairwise opposite coupling means for locking the like, adjacent floorboards with each other in both vertical and horizontal directions (D1 and D2, respectively), characterized in that the surface layer 31 consists of bendable resilient fibers. Floorboards according to claim 1, characterized in that the core (30) of the floorboard contains wood fibers. Floor panels according to one of the preceding claims, characterized in that the surface layer (31) is made of needle felt. Floor boards according to one of the preceding claims, characterized in that the surface layer has a density of less than 400 kg / m 3. Floor panels according to one of the preceding claims, characterized in that they are rectangular or square and that two opposite sides can be joined by angling with the upper joint edges in contact with each other. Floor panels according to any one of the preceding claims, characterized in that the upper adjacent joint edge portions of the floorboards are compressible and can be deformed in connection with joining 15 522 217 15 Method for the manufacture of floorboards (1, 1 ') with a surface layer (31) (30), a liquid floor covering, which floorboards are mechanical and a core for forming lockable and which along their four edge portions have pairwise opposite coupling means for locking of adjacent floorboards with each other in both vertical and horizontal directions (D1 and D2, respectively), to provide a floating floor with mechanically lockable floorboards, characterized by the steps of joining a surface layer 31 of bendable and resilient fibers with a wood fiber core 30 to panel panel core (3) that the panel blank (3) and a tool set for machining the joint edges of the panel blank are displaced linearly to provide at least a part of the upper joint edges of the floor panel. Method according to claim 7, characterized in that the tool set consists of a knife set and a set of rotary milling tools.