RU2358075C2 - System of floor covering and locking, equipment of, for example batten manufacture - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: battens are manufactured with mechanical locking system enabling their displacement for producing floating floor.

EFFECT: locking of battens avoiding significant visible clearances.

24 cl, 12 dwg

Description

The invention generally relates to the field of technology associated with fixing systems for floorboards. The invention relates, on the one hand, to fixation systems for floorboards that can be mechanically connected, and, on the other hand, floorboards and floor systems provided with such a fixation system, and also relates to a method for manufacturing such floorboards. More specifically, the invention primarily relates to fixing systems that make it possible to lay mainly floating floors with large continuous coatings and to lay floorboards that show significant changes in shape after laying.

The present invention is particularly suitable for use in floating wood floors and laminate floors, for example solid wood floors, parquet floors, veneered floors, laminate floors with a surface layer of a high pressure laminate or directly from a laminate and the like.

The following description of the prior art, problems of known systems, as well as the objectives and features of the invention, therefore, with non-limiting examples will be directed mainly to this field of application. However, it should be emphasized that the invention can be used in relation to any floorboards that are designed to be connected to various patterns through a mechanical fixation system. Thus, the invention can also be applied to floors that are glued or nailed to a subfloor, or floors with a core and with a surface of plastic, linoleum, cork, with a varnished surface of a particleboard, etc.

In the following text, the visible surface of the installed floorboard is called the “front side”, while the opposite side of the floorboard facing the subfloor is called the “back side”. The term "floor surface" means the main outer flat part of the floorboard, which is opposite to the rear side and which is located in one single plane. Chamfers, grooves and similar decorative elements are parts of the front side, but they are not parts of the floor surface. The term “laminate flooring” means a floor having a surface that consists of melamine-impregnated paper that is pressed under pressure and when exposed to heat. The term "horizontal plane" means a plane that extends parallel to the outside of the floor surface. The term "vertical plane" means a plane perpendicular to the horizontal plane.

The outer parts of the floorboard at the edge of the shallow board between the front side and the rear side are called “connecting edges”. The term "part of the connecting edge" means a part of the connecting edge of the floorboard. The terms “connection” or “fixation system” mean cooperative connecting means connecting floorboards vertically and / or horizontally. The term "mechanical fixation system" means that the connection can be made without the use of glue. In many cases, mechanical fixation systems can also be implemented using glue. The term "vertical fixation" means fixation parallel to a vertical plane. As a rule, with vertical fixation, a tongue is used, which interacts with the groove for the tongue. The term "horizontal fixation" means fixation parallel to the horizontal plane. The term "opening of the seam" means a groove that is bounded by two connecting edges of two connected floorboards and which is open to the front side. The term "joint gap" refers to the minimum distance between two parts of the connecting edges of two connected floorboards within an area that is bounded by the front side and the top of the tongue near the front side. The term "open joint gap" means a joint gap that is open to the front side. The term "visible joint gap" means a joint gap that is visible to the naked eye from the front for a person walking on the floor, or a joint gap that is larger than the joint gaps defined in accordance with the industry's general requirements for joint gaps for floors of various types. The term "continuous floating floor covering" means a floor covering that is laid entirely without expansion joints.

Traditional laminate and parquet floors are usually laid floating on the existing black floor. The connecting edges of the floorboards are joined to form a floor covering, and the entire floor covering can move relative to the subfloor. Since shrinkage or swelling of the floorboards will occur due to relative humidity that changes throughout the year, the entire floor covering will change its shape.

Floating floors of this kind are usually joined by means of adhesive sheet piles. When laying boards, they are brought together horizontally and a protruding tongue along the connecting edge of one board is inserted into the groove along the connecting edge of the adjoining board. The tongue-and-groove connection provides the installation of floorboards in a predetermined position and their fixing vertically, and the adhesive fixes the boards horizontally. The same method is used for both the long edge and the short edge, and the boards are usually laid in parallel rows with both long edges and short edges lying side by side.

In addition to such traditional floating floors, which are joined by means of adhesive tongue-and-groove joints, floorboards have been created in recent years which do not require the use of glue, but which are instead mechanically joined by so-called mechanical fixing systems. These systems contain fixing means that mechanically fix the boards horizontally and vertically without the use of glue. The vertical fixation tool is usually formed in the form of a tongue that interacts with the groove for the tongue. The horizontal locking means consists of a locking element that interacts with the locking groove. The locking element could be formed on the protrusion extending from the bottom of the groove under the tongue, or could be formed on the tongue. Mechanical fixation systems can be formed by machining the core of the board. On the other hand, parts of the fixation system, for example a tongue and / or tongue, can be made of a separate material that is combined with the floorboard, i.e. already connected to the floorboard in connection with its manufacture in the factory.

The floorboards can be mechanically connected through various combinations of the methods of tilting, snapping, vertically changing the position, the so-called vertical folding, and pasting along the connecting edge. With all these methods of laying, with the exception of vertical folding, it is required that one edge of the floorboard — a long or short edge — can move in a fixed position. Many locking systems available on the market are made with a slight play between the locking element and the locking groove in order to facilitate movement. The goal is to produce floorboards that can be moved and which are at the same time connected to each other with a fit that is as tight as possible. A very small movement backlash, for example 0.01-0.05 mm, is often sufficient to significantly reduce the friction between the wood fibers. According to the European standard EN 13329 on laminate floors, the opening of the joints between the floorboards should be on average ≤0.15 mm and maximum ≤0.20 mm. The goal of all manufacturers of floating floors is to reduce joint openings as much as possible. Some floors are even pre-stretched in cases where the protrusion with the locking element in a fixed position is bent back to the subfloor and when the locking element and the locking groove tightly press the panels against each other. Such a floor is difficult to lay.

In addition, wooden and laminate floors are connected by gluing or nailing to the subfloor. Such gluing or nailing prevents movement due to moisture and keeps the floorboards connected. The movement of the floorboards occurs near the center in each floorboard. Swelling and shrinkage can occur only in the corresponding floorboards and, thus, do not lead to a change in the shape of the entire floor covering.

The floorboards, which are connected by gluing or nailing the subfloor, do not need any fixing systems at all. However, they may have traditional tongue and groove joints that facilitate installation in a predetermined vertical position. In addition, they may have mechanical fixation systems that fix and install floorboards in a predetermined vertical and / or horizontal position when laid.

The advantage of floating floors is that a change in shape due to different values of relative humidity can occur covertly under the skirting boards and that floorboards, although they swell and shrink, can be joined without visible joint gaps. Flooring - especially when using mechanical fixation systems - can occur quickly and easily, and the floor can be raised and laid again in another place. The disadvantage is that a solid floor covering, as a rule, should be limited even in cases where the floor consists of relatively stable floorboards, for example a laminate floor with a chipboard core or wooden floors consisting of several layers with different fiber directions. The reason is that such dimensionally stable floors generally have a size change of about 0.1%, which corresponds to about 1 mm / m, when humidity varies from 25% in winter to 85% in summer. Such a floor will, for example, undergo shrinkage at a distance of ten meters and swell by an amount equal to about 10 mm. A large floor covering should be divided by elastic gaskets into smaller coverings, for example, every tenth or fifteenth meter. In the absence of such a separation, there is a risk that the floor during shrinkage will change in shape so much that it will no longer be covered with skirting boards. In addition, the load on the fixation system will be large, since when moving a large continuous coating large loads must be transmitted. The load will be especially large in the aisles between different rooms.

According to the building rules established by the Organization of European Laminate Floor Manufacturers / EPLF /, expansion joint profiles should be installed on coatings greater than 12 m in the length direction of individual flooring elements and on coatings greater than 8 m in the width direction. Such profiles should also be installed in doorways between rooms. Manufacturers of floating floors with wooden floors use similar guidelines for flooring. The profiles of expansion joints are usually aluminum or plastic profiles, fixed to the floor covering between two separate elements of the floor structure. They collect dirt, have an undesirable appearance and are quite expensive. Due to these restrictions regarding maximum floor coverings, laminate floors occupy only a small market share in commercial applications, such as hotels, airports and large retail areas.

Unstable floors, such as homogeneous wooden floors, may show even greater changes in shape. Factors that primarily affect the change in the shape of homogeneous wood floors are the direction of the fibers and the type of wood. The homogeneous oak floor is very dimensionally stable in the direction of the fibers, i.e. in the longitudinal direction of the floorboard. With a change in relative humidity over the course of the year, the transverse movement can be 3%, which corresponds to 30 mm / m or more. Other wood species show even greater changes in shape. Flooring, showing large changes in shape, as a rule, can not be laid floating. Even if such installation were possible, it would be necessary to significantly limit the continuous flooring.

The advantage of gluing or nailing the subfloor is that more continuous floor coverings can be created without the use of expansion joint profiles, and the floor can withstand heavy loads. An additional advantage is that the floorboards do not need any vertical and horizontal fixing systems and that they can be fitted with improved designs, for example, with long edges joined with short edges. However, this method of laying, associated with fastening to the subfloor, has several significant disadvantages. The main disadvantage is that when the floorboards shrink, a visible joint gap between the boards occurs. The joint gap can be relatively large, especially when manufacturing floorboards from moisture-sensitive wood materials. Homogeneous wooden floors that are nailed to the subfloor may have 3-5 mm joint gaps. The distance between the boards can be unevenly distributed in the presence of several small gaps and a certain number of large gaps, and these gaps are not always parallel. Thus, the joint gap can vary along the length of the floorboard. Large joint gaps may contain a lot of dirt, which penetrates down to the tongue and prevents floorboards from assuming their initial position when swelling. These methods of flooring are time-consuming, and in many cases it is necessary to adjust the black floor to be able to glue or nail it.

Therefore, it would be a great advantage if you could create a floating floor that eliminates the above disadvantages, in particular a floating floor, which:

a) may consist of a large continuous coating without profiles of expansion joints,

b) may consist of moisture-sensitive floorboards, which exhibit a large change in size with a change in relative humidity throughout the year.

The present invention relates to fixation systems, floorboards and floors, which make it possible to lay floating floors with large continuous coatings and floorboards that exhibit a large change in size with a change in relative humidity. In addition, the invention relates to methods and equipment for the production of such floors.

The first objective of the present invention is the creation of a floating floor from rectangular floorboards with mechanical fixation systems, in which the size, pattern of the flooring and the fixation system of the floorboards interact and allow movement between the floorboards. According to the invention, individual floorboards can change in shape after being laid, i.e. shrink and swell due to changes in relative humidity. This can occur in such a way that a change in the shape of the entire floor covering can be reduced or preferably eliminated, while at the same time the floorboards remain fixed to each other without large visible joint gaps.

A second object of the present invention is to provide locking systems that allow significant movement between floorboards without large and deep dirt-collecting joint gaps and / or where open joint gaps could be excluded. Such fixing systems are particularly suitable for moisture-sensitive materials, such as wood, as well as for laying large floating floors using wide and / or long floorboards.

In this specification, the terms “long edge” and “short edge” are used to facilitate understanding. According to the invention, the boards can also be square or alternately square and rectangular and, optionally, can also have different profiles and angles between opposite edges.

It should be emphasized that combinations of floorboards, fixation systems and flooring patterns, which are presented in this description of the invention, are only examples of suitable embodiments of the invention. Perhaps a large number of options. All embodiments of the invention that are suitable for the first objective of the invention can be combined with the embodiments of the invention that are described in connection with the second objective of the invention. All fixing systems can be used separately on long edges and / or short edges and also in various combinations on long edges and short edges. Fixation systems having horizontal and vertical fixation means may be tilted and / or snapped together. The geometric shapes of the fixation systems and the active means of horizontal and vertical fixation can be formed by machining the edges of the floorboard or from separate materials formed or, on the other hand, machined before or after joining with a part of the connecting edge of the floorboard.

These tasks are fully or partially solved according to the attached claims.

According to a first aspect of the present invention, there is provided a floating floor consisting of rectangular floorboards connected by a mechanical fixation system. The connected floorboards have a horizontal plane that is parallel to the floor surface and a vertical plane that is perpendicular to the horizontal plane. The fixing system has mechanically interacting fixing means for a vertical connection parallel to a vertical plane, and for a horizontal connection parallel to a horizontal plane, the first and second connecting edges. The vertical fixing means is made of a tongue that interacts with the groove, and the horizontal fixing means is made of a fixing element with a fixing surface that interacts with the fixing groove. The floor is characterized in that the format, the pattern of the flooring and the fixing system of the floorboards are made in such a way that a floor covering of 1 × 1 meter can change in shape in at least one direction by at least 1 mm when the floorboards squeezed together or stretched to the sides. This change in shape can occur without visible joint gaps.

According to a second aspect of the present invention, there is provided a locking system for mechanically joining floorboards, in which the joined floorboards have a horizontal plane that is parallel to the floor surface and a vertical plane that is perpendicular to the horizontal plane. The fixing system has mechanically interacting fixing means for a vertical connection parallel to a vertical plane, and for a horizontal connection parallel to a horizontal plane, the first and second connecting edges. The vertical fixation means consists of a tongue that interacts with the groove, and the horizontal fixation means consists of a fixation element with a fixing surface that interacts with the fixation groove. The first and second connecting edges have upper and lower parts of the connecting edges located between the tongue and the floor surface. The upper parts of the connecting edges are closer to the floor surface than the lower parts. The locking system is characterized in that when the floorboards are connected and pressed against each other, the two upper parts of the connecting edges are spaced apart, and one of the upper parts of the connecting edges in the first connecting edge overlaps the lower part of the connecting edge in the second connecting edge.

According to several preferred embodiments of this invention, it is advantageous for the floor to consist of rather small floorboards and numerous compounds that could compensate for swelling and shrinkage. The tolerances for processing should be quite small, since to create a high-quality floor according to the invention requires well-defined backlash and opening joints.

However, it is difficult to manufacture small floorboards with the necessary tolerance, as they tend to rotate in an uncontrolled manner during machining. The main reason why small floorboards are harder to make than large floorboards is because the large floorboard has a much larger area that comes in contact with the chain and tape during the machining of the edges of the floorboards. This large contact area keeps the floorboards attached with a tape to the chain so that they cannot move or rotate relative to the feed direction, which may occur in the case of a small contact area.

The manufacturing process of the floorboards essentially consists in the fact that the group of cutting tools and the workpiece of the floorboard are moved relative to each other. The group of cutting tools preferably consists of one or more milling cutters that are positioned and dimensioned so that the machining produces a fixing system in a manner known to those skilled in the art.

The most used equipment is a tenoner, double or single, in which the chain and tape are used to move the floorboard with great accuracy along a well-defined feed direction. In many applications, pressure shoes and support elements are used in conjunction with the chain and belt, mainly to prevent vertical deflections. Horizontal deflection of the floorboard is only prevented by means of a chain and tape.

In many applications, the problem is that this is not enough, especially when the panels are small.

The third objective of the present invention is to provide equipment and manufacturing methods that make it possible to produce tenoning boards and mechanical fixation systems, but with better accuracy than that which is possible using known technology. Therefore, the present invention also relates to equipment for the manufacture of building panels, especially floorboards. The equipment consists of a chain, tape, pressure shoe and a group of cutting tools. The chain and tape are configured to move the floorboard relative to the group of cutting tools and the pressure shoe in the feed direction. The pressure shoe is adapted to be pressed against the rear side of the floorboard. A group of cutting tools is configured to form an extreme portion of the floorboard when the floorboard is moved relative to the group of cutting tools. One of the cutting tools in the group of cutting tools forms a guide surface in the floorboard. The pressure shoe has a guide device that interacts with the guide surface and prevents deviations in a direction perpendicular to the feed direction and parallel to the rear side of the floorboard.

As you know, a groove could be formed on the back of the floorboard and a ruler could be inserted into the groove to guide the floorboards when they are moved by a tape that moves the boards across the table. It is not known that special guiding surfaces and guiding devices can be used in a tenon saw, in which the pressure shoe interacts with the chain.

A fourth object of the present invention is to provide a large semi-floating floor from rectangular floorboards with mechanical fixation systems in which the format, pattern of the flooring and the fixation system of the floorboards are designed such that a large semi-floating solid floor with a length or width of more than 12 m can be laid without expansion joints .

The invention is illustrated in the drawings, where:

on figa-b shows floorboards with a fixing system,

on figa-2f shows the fixing system and patterns of flooring,

on figa-3e shows the fixing system,

on figa-4C shows the fixing system,

5a-5d show connected floorboards and test methods,

on figa-6e shows the fixing system,

on figa-7e shows the fixing system,

on figa-8f shows the locking system,

on figa-9d shows the locking system,

on figa-10d shows the production equipment,

on figa-11d shows the production equipment,

12a-12c show locking systems.

Figs 1a-b show floorboards which are of the first type A and second type B according to the invention and whose long edges 4a and 4b in this embodiment have a length that is 3 times the length of the short edges 5a, 5b. The long edges 4a, 4b of the floorboards have vertical and horizontal connecting means, and the short edges 5a, 5b of the floorboards have horizontal connecting means. In this embodiment, the floorboards of the two types are the same, except that the arrangement of the fixing means is mirror-reverse. The fixing means make it possible to connect the long edge 4a to the long edge 4b by at least tilting inward and the long edge 4a to the short edge 5a by tilting inward, and also to connect the short edge 5b to the long edge 4b by means of vertical movement. In this embodiment, the connection of both the long edges 4a, 4b and the short edges 5a, 5b with a "Christmas tree" pattern or parallel rows can only occur by angular movement around the long edges 4a, 4b. The long edges 4a, 4b of the floorboards have connecting means, which in this embodiment of the invention consist of a protrusion 6, a tongue groove 9 and a tongue 10. Short edges 5a also have a protrusion 6 and a tongue groove 9, while the short edges 5b have no tongue 10. There are many possible options. The floorboards of the two types do not have to be of the same format, and the fixing means can also have different shapes, provided that, as indicated above, they can connect the long edge to the short edge. The connecting means may be made of the same material or of different materials, or may be made of the same material, but with different material properties. For example, the connecting means may be made of plastic or metal. They can also be made of the same material as the floorboard, but be subjected to processing that changes their properties, such as impregnation, etc. The short edges 5b may have a tongue, and in this case, the floorboards can be joined in a manner known in the art to a transverse pattern through various combinations of angular movement and snap movement. The short edges could also have a separate flexible tongue that could be horizontally offset during fixation.

On figa shows the connecting means for two floorboards 1, 1 ', which are connected to each other. In this embodiment, the floorboards have a surface layer 31 of laminate, a core 30 of, for example, high density fiberboard, which is softer and more compressible than surface layer 31, and a balancing layer 32. Vertical fixation of D1 is provided by a tongue groove 9, which interacts with the tongue 10. The horizontal locking D2 is provided by the protrusion 6 with the locking element 8, which interacts with the locking groove 12. This locking system can be connected by tilting inward around the upper connecting x edges. It could also be modified in such a way that it could be fixed with a horizontal snap. The locking element 8 and the locking groove 12 have interacting locking surfaces 15, 14. When connecting the floorboards and pressing them against each other in the horizontal direction D2, they can assume a position in which there is a play 20 between the locking surfaces 14, 15. As shown in FIG. .2b, when the floorboards stretch in opposite directions and when the fixing surfaces 14, 15 are completely in contact and pressed against each other, there is a joint gap 21 on the front side between the upper connecting edges. According to the invention, the play between the locking surfaces 14, 15 is defined as equal to the movement of the upper connecting edges when these edges are pressed together and stretched to the sides as described above. This backlash in the fixation system is the maximum movement of the floor that occurs when the floorboards are pressed together and stretched to the sides by compressive and tensile forces, which are permissible considering the strength of the end parts and the fixation system. According to this definition, floorboards with hard surface layers or edges that are only slightly compressed together when compressed together will have a play that is essentially equal to or slightly larger than the joint gap. Floorboards with softer edges will have a play that is significantly larger than the joint gap. According to this definition, the play is always equal to or greater than the joint gap. Backlash and joint clearance can be equal, for example, 0.05-0.10 mm. Seam clearances of about 0.1 mm are considered acceptable. They are difficult to distinguish, and ordinary dirt particles are too large to penetrate the fixation system through such small joint gaps. In some applications, joint gaps up to 0.20 mm could be tolerated with a play of, for example, 0.25 mm, especially if play and joint gaps were measured using significant compressive and tensile forces. This maximum joint gap will only occur under extreme conditions, when the humidity is very low, for example below 20%, and when the floor load is very high. Under normal conditions and applications, the joint gap in such a floor could be 0.10 mm or less.

Figure 2b shows a typical laminate floor with floorboards measuring 1.2 x 0.2 m, which are laid in parallel rows. Such a laminate floor has shrinkage and swelling in the amount of about 1 mm / m. If the fixation system has a backlash of about 0.1 mm, then five joints in the transverse direction D2 B will allow swelling and shrinkage in the amount of 5 × 0.1 = 0.5 mm / m. This only compensates for half the maximum swelling or shrinkage of 1 mm. In the longitudinal direction D2 A, there is only one connection per 1.2 m, which allows movement of 0.1 mm. Thus, the play 20 and the joint gap 21 in the fixation system only slightly reduce the shrinkage or swelling of the floor in the direction D2 parallel to the long edges. To reduce the floor movement to half this movement, which usually occurs in the floor without backlash 20 and joint gap 21, it is necessary to increase the backlash 20 to 0.6 mm, and this leads to too large joint gap 21 at the short edge.

Fig. 2c shows floorboards with, for example, a chipboard core 30, for example high-density chipboard, and a surface layer of laminate or veneer, which has a maximum dimensional change of about 0.1%, i.e. 1 mm / m. The floorboards are laid in parallel rows. In this embodiment, they are narrow and short with a size of, for example, 0.5 × 0.08 m. If the play is 0.1 mm, then 12 floorboards with their 12 joints on the floor length of one meter will allow movement in the transverse direction, D2 V is 1.2 mm, which is larger than the maximum change in floor dimensions. Thus, all movement can occur by moving the floorboards relative to each other, and the external dimensions of the floor can be unchanged. In the longitudinal direction D2 A, two joints of short edges can only compensate for a movement of 0.2 mm / m. In a room that has, for example, a width of 10 m and a length of 40 m, in contrast to the currently recommended laying methods, laying can be suitably done with the long edges of the floorboards parallel to the width direction of the room and perpendicular to its length direction. According to this preferred embodiment of the invention, large continuous coatings of floating floors without large visible joint gaps can thus be created with narrow floorboards that have a locking system with play and which are connected in parallel rows perpendicular to the direction of the length of the flooring. According to the invention, the fixation system, floorboards and flooring pattern must therefore be selected so that a 1x1 m floor covering can expand and contract about 1 mm or more in at least one direction without damaging the fixation system or floorboards . The mechanical fixation system in a floating floor, which is laid in the living room, must withstand tensile loads and compression corresponding to at least 200 kg per meter of floor length. More specifically, it is preferable to be able to achieve the aforementioned change in shape without visible joint gaps when the aforementioned floor covering is subjected to a compressive or tensile load of 200 kg in any direction and when the floorboards are at a normal relative humidity of about 45%.

The strength of the mechanical fixation system is important for large continuous floors of floating floors. Such large continuous coatings are defined as floor coverings with a length and / or width exceeding 12 m. Very large continuous coatings are defined as floor coverings with a length and / or width exceeding 20 m. There is a risk that unacceptable joint gaps or that the floorboards will slide apart if the mechanical fixation system is not strong enough in a larger floating floor. Dimensionally stable floorboards, such as laminate flooring boards, which have an average joint gap of more than 0.2 mm, with a tensile load of 200 kg / m, are usually not suitable for use in large, high-quality floating floors. This invention could be used for laying solid floating floors with a length and / or width exceeding 20 m or even 40 m. In principle, there are no restrictions. According to the invention, solid floating floors with a surface area of 10,000 m ² or more could be laid.

Such floating floors of new types, in which the bulk of the floating movement in at least one direction occurs between the floorboards and in the mechanical fixation system, are hereinafter referred to as semi-floating floors.

Fig. 5d shows a suitable test method to ensure that the floorboards are sufficiently movable in the joined state and that the fixation system is strong enough to be used in a large continuous floor covering in cases where the floor is a semi-floating floor. In this example, 9 samples with 10 joints and with a length L of 100 mm (10% of 1 meter) were joined along their respective long edges so as to correspond to a floor length TL of about 1 meter. The number of compounds — in this example there are 10 compounds — is designated as Nj. The boards are subjected to a compressive and tensile load using a force F corresponding to 20 kg (200 N), which is 10% of 200 kg. It is necessary to measure the change in floor length TL, hereinafter referred to as ΔTL. The average backlash, hereinafter referred to as AP, or floor movement per one connection is defined as AP = ΔTL / Nj. For example, if ΔTL = 1.5 mm, then the average backlash is AP = 1.5 / 10 = 0.15 mm. With this test method, the change in size of the floorboard will also be measured. For most floorboards, this change in size is extremely small compared to backlash. As mentioned earlier, due to the compression of the upper edges and, ultimately, some very small changes in the size of the floorboard, the average joint gap will always be less than the average backlash AP. This means that in order to be sure that the floor movement is sufficient (ΔTL) and that the average gaps of 21 joints do not exceed the stipulated maximum levels, it is only necessary to measure and control ΔTL, since ΔTL / Nj is always equal to the average gap 21 a seam or more of it. The size of the actual average joint gap 21 in the floor when a tensile force F is applied, however, could be directly measured, for example, using a number thickness group or a microscope, and the actual average joint gap = AAJG could be calculated. The difference between AP and AAJG is defined as floorboard flexibility = FF (FF = AP-AAJG). In a laminate floor, ΔTL should preferably exceed 1 mm. For the selection of floorboards, flooring patterns and fixing systems that could be used in semi-floating floors, a lower or greater force F could be used. In some applications, for example in an environment of dwellings with normal humidity conditions, an F of 100 kg would be sufficient / m (1000 N / m). In very large floating floors, a force F of 250-300 kg or more could be used. Mechanical fixation systems could be made with a clamping force of 1000 kg or more. In such fixation systems, the joint gap could be limited to 0.2 mm even when a force F of 400-500 kg was applied. The recoil caused by the locking element 8, the locking surfaces 15, 14 and the locking protrusion 6 could be measured by increasing and decreasing the force F in steps of, for example, 100 kg. The recoil is high if ΔTL is essentially the same when F increases from 0 to 100 kg (= ΔTL) and from 0 to 200 kg and then decreases back to 100 kg (= ΔTL2). A high-impact mechanical fixation system is advisable in semi-floating floors. ΔTL1 should preferably be at least 75% of ΔTL2. In some cases, even 50% could be sufficient.

On fig.2d shows the floorboards according to figs, which are laid with a transverse pattern. With this method of laying, there are 7 connections per running meter in both directions D2 A and D2 B of the floor. In this case, a backlash of 0.14 mm can fully compensate for swelling and shrinkage of 0.1, since 7 connections lead to a total mobility of 7 × 0.14 = 1.0 mm.

Figure 2e shows one square meter of floor covering, which consists of the floorboards described above, laid with a Christmas tree pattern upon contact of a long edge with a short edge and in a position where, for example, in the summer they swell to their maximum size. On fig.2f shows the position of the floorboards, when they, for example, underwent shrinkage in winter. In this case, the locking system with its inherent play leads to the formation of gaps 21 seams between all the connecting edges of the floorboards. Since the floorboards are laid with a “Christmas tree” pattern, backlash of long edges will help reduce floor changes in all directions. As also shown in FIG. 2f, the critical directions are the diagonal directions D2 C and D2 D of the floor, in which 7 joint clearances must be adjusted so as to withstand shrinkage at a distance of 1.4 m. This can be used to determine the optimal direction of laying in large the floor. In this example, a 0.2 mm joint gap will completely eliminate floor movement in all directions. This makes it possible to attach the outer parts of the floating floor to the subfloor, for example by gluing, which, when shrinking, prevents the floor from moving outside the skirting boards. In addition, the invention makes it possible to attach wall partitions to a fitted floating floor, which can reduce installation time.

As practical experiments show, a floor with a veneer or laminate flooring and a chipboard core, for example, dimensionally stable high-quality chipboard with high density, can be installed with high dimensional stability and with a maximum resizing s of about 0, 5-1.0 mm. Such semi-floating floors can be installed in rooms of unlimited sizes, and the maximum backlash can be limited to about 0.1 mm also in cases where floorboards have a width of preferably about 120 mm. Obviously, even smaller floorboards, for example, 0.4 x 0.06 m in size, are nevertheless preferable and can cover large surfaces also when they are made of materials that are less stable in shape. Thus, according to a first embodiment of the invention, there is provided a new type of semi-floating floor in which individual floorboards are capable of moving and whose external dimensions should not be changed. This can be achieved by the optimal use of the size of the boards, the mobility of the fixation system using a small play and a small joint gap, and the pattern of the floorboards. Thus, according to the invention, a suitable combination of play, joint clearance, flooring size, flooring pattern and laying direction of the floorboards can be used to completely or partially prevent movements in the floating floor. Much larger solid floating floors can be laid out than is currently possible, and the maximum floor movement can be reduced to about 10 mm, which is acceptable for modern technology, or can be completely eliminated. All this can happen with a joint gap, which is practically invisible and which, in terms of moisture and dirt penetration, does not differ from the joint gap in traditional floating floorboards with a width of 0.2 m, which are connected in parallel rows by pre-tensioning or with a very small movement gap, which does not provide sufficient mobility. By way of non-limiting example, it can be mentioned that in dimensionally stable floors, the play 20 and the joint gap 21 should preferably be about 0.1-0.2 mm.

A particularly preferred embodiment of the invention is a semi-floating floor with the following characteristics: the surface layer is a laminate or wood veneer; the core of the floorboard is a wood-based board, for example medium-density chipboard or high-density chipboard; the change in floor length ΔTL is at least 1.0 mm when using a force F of 100 kg / m; the change in floor length ΔTL is at least 1.5 mm when using a force F of 200 kg / m; the average joint gaps do not exceed 0.15 mm with a force F of 100 kg / m and 0.20 mm with a force F of 200 kg / m.

In terms of function and joint quality, such semi-floating floorboards will be similar to traditional floating floorboards when humidity conditions are normal and floor surface sizes are within the generally recommended range. Under extreme climatic conditions or when laying on a much larger continuous floor surface, such semi-floating floorboards will outperform traditional floorboards. For the design of a semi-floating floor for various applications, other combinations of the force F, changes in the floor length ΔTL and the joint gap 21 could be used.

Fig. 3a shows a second embodiment of the invention that can be used to solve problems caused by movements in floating floors due to humidity. In this embodiment, the floorboard has a direct laminate coating 31 and a high density chipboard core. Under the laminate coating there is a layer 33, which consists of melamine impregnated wood fibers. This layer is formed when the surface layer is deposited on high-density chipboard and when melamine penetrates the core and connects the surface layer to the core of high-density chipboard. The high density particleboard core 30 is softer and more compressible than the laminate 31 and melamine impregnated layer 33. According to the invention, the laminate surface layer 31 and, if appropriate, also the entire melamine impregnated layer 33 or parts thereof under the surface layer can be removed as follows so that a decorative groove 133 is formed in the form of a shallow opening of the seam JO 1, the opening of the seam resembles a large gap of the seam in homogeneous wooden floors. A groove 133 can only be made on one connecting edge, and it can be painted, coated or impregnated so that the joint gap becomes less visible. Such decorative grooves or openings of seams can have, for example, a width of JO 1, for example, 1-3 mm and a depth of 0.2-0.5 mm. In some applications, the width of JO 1 could preferably be quite small, amounting to about 0.5-1.0 mm. When the floorboards 1, 1 ′ are pressed against each other, the upper connecting edges 16, 17 can be compressed. In high density particleboard, this compression can be 0.1 mm. This compression capability may replace the aforementioned play and may allow movement in the absence of a joint gap. The aforementioned chemical treatment may also alter the properties of a portion of the connecting edge and contribute to improving compression capabilities. Of course, the first and second embodiments of the invention can be combined. With a backlash of 0.1 mm and the possibility of compression of 0.1 mm, a total movement of 0.2 mm can be achieved with a visible gap of only 0.1 mm. Compression can also be used between the active fixing surfaces 15, 14 in the fixing element 8 and in the fixing groove 12. Under normal climatic conditions, the separation of the floorboards is prevented when the fixing surfaces 14, 15 are in contact with each other and there is no significant compression . The fixing surfaces will shrink when they are subjected to additional tensile stress under extreme climatic conditions, for example, when the relative humidity drops below 25%. This compression is facilitated if the contact surface CS of the fixing surfaces 14, 15 is small. It is advisable that with a typical floor thickness of 8-15 mm, this contact surface CS is about 1 mm or less. With this technique, floorboards can be made with a backlash and a joint gap of about 0.1 mm. Under extreme climatic conditions, when the relative humidity drops below 25% or exceeds 80%, compression of the upper connecting edges and fixing surfaces can make it possible to move, for example, by 0.3 mm. The above technique can be applied to floors of various types, for example, floors with a surface layer of high pressure laminate, wood, veneer, plastic and similar materials. This technique is particularly suitable for floorboards, which make it possible to increase the compression of the upper connecting edges by removing part of the upper part 16 and / or 17 of the connecting edge.

3b shows a third embodiment of the invention. On figs and 3d shows enlarged views of the connecting edges in fig.3b. The floorboard 1 'in place on the connecting edge, which is determined by the upper parts of the tongue 10 and the groove 9 and the floor covering 31, has an upper part 18 of the connecting edge and a lower part 17 of the connecting edge, and the flooring board 1 in the corresponding place has the upper part 19 of the connecting edge and the lower part 16 of the connecting edge. When the floorboards 1, 1 ′ are compressed together, the lower portions 16, 17 of the connecting edges will come into contact with each other. This is shown in fig.3d. The upper parts 18, 19 of the connecting edges are spaced apart, and one upper part 18 of the connecting edge of one floorboard 1 ′ overlaps the lower part 16 of the connecting edge of the other floorboard 1. In this compressed position, the locking system has a play 20, for example 0.2 mm between the fixing surfaces 14, 15. If the overlap is 0.2 mm when the position is pressed together, then when the boards are stretched to the sides, they can be separated by 0.2 mm from each other in the absence of a joint gap visible from the surface. In this embodiment, there will be no open joint gap since the joint gap will be closed by the overlapping portion 18 of the connecting edge. This is shown in FIG. 3c. It is advisable that the locking element 8 and the locking groove 12 are made such that separation is possible, i.e. backlash was slightly less than the overlap. A slight overlap, for example 0.05 mm, should preferably exist in the joint, even when floorboards are stretched to the sides and tensile force F is applied to the joint. This overlap will prevent moisture from entering the joint. The connecting edges will be stronger since the lower part 16 of the edge will support the upper part 18 of the edge. Decorative groove 133 can be made very shallow, and all dirt collected in this groove can be easily removed with a vacuum cleaner during normal cleaning. No dirt or moisture can penetrate into the fixation system and down to the tongue 12. This technique, which consists in overlapping portions of the connecting edges, of course, can be combined with two other embodiments of the invention on the same edge or on the long and short edges floorboards. The long edge of the floorboard could have, for example, a fixing system according to the first embodiment of the invention, and the short edge of the floorboard could have a fixing system according to the second embodiment of the invention. For example, the visible and open joint gap could be 0.1 mm, the compression 0.1 mm and the overlap 0.1 mm. In this case, the possible movement of the floorboards will be a total of 0.3 mm, and this significant movement can be combined with a small visible open gap of the seam and a limited horizontal extent of the overlapping portion 18 of the connecting edge, which should not be a weakening of the connecting edge. This is due to the fact that the overlapping portion 18 of the connecting edge is very small and, moreover, is made in the strongest part of the floorboard, which consists of a laminate flooring and melamine-impregnated wood fibers. Such a fixing system, which thus allows significant movement without visible joint gaps, can be used in all the above applications. In addition, this fixing system is especially suitable for use in wide floorboards at their short edges when floorboards are laid. parallel rows, etc., i.e. in all cases of their use, when greater mobility in the fixation system is required to neutralize changes in floor dimensions. It can also be used at the short edges of the floorboards, which make up the FR frame or frieze around the floor laid "in the Christmas tree" according to figs. In this embodiment of the invention shown in FIGS. 3b-3d, the vertical extent of the overlapping portion of the connecting edge, i.e. the depth GD of the disclosure of the seam, less than 0.1 part of the thickness T of the floor. A particularly preferred embodiment of the invention is a semi-floating floor with the following characteristics: the surface layer is a laminate or wood veneer; the core of the floorboard is a wood-based board, for example medium-density chipboard or high-density chipboard; the thickness T of the floor is 6-9 mm and the overlap OL is less than the average play AP when using a force F of 100 kg / m. As an example, it could be mentioned that the depth GD of the opening of the seam could be 0.2-0.5 mm (= 0.02 × T-0.08 × T). At the long edges of the boards, the overlap OL could be equal to 0.1-0.3 mm (= 0.01 × T-0.05 × T). An overlap of OL at the short edges of the boards could be equal to an overlap at the long edges of the boards or more.

FIG. 3e shows an embodiment of the invention in which the opening of the joint JO 1 is very small or does not exist at all when the floorboards are compressed together. When the floorboards are stretched to the sides, the joint JO 1 will open. This joint opening will be essentially the same size as the average backlash AP. The decorative groove could, for example, be suitably painted in accordance with the surface of the floor, and the play would not cause an open joint gap. A very small OL overlap of only about 0.1 mm (0.01 × T-0.02 × T) and a slightly smaller average backlash AR could provide sufficient floor movement, and this could be combined with a moisture-resistant, high-quality compound. Backlash will also facilitate fixation, release from fixation and movement in a fixed position. Such overlapping portions of the edges could be used in all known mechanical fixation systems to improve the functioning of the mechanical fixation system.

Figures 4a and 4b show how a fixing system can be implemented to enable floating flooring of floorboards, which are composed of a moisture-sensitive material. In this embodiment, the floorboard is made of uniform wood.

Fig. 4a shows a fixation system in a state when it was subjected to a tensile load, and Fig. 4b shows a fixation system in a compressed state so that the floor has an attractive appearance, the relative dimensions of the joint openings should not differ significantly from each other. In order to ensure that the visible openings of the joints do not differ significantly from one another when moving the floor, the smallest joint opening JO 2 should be greater than half the largest joint opening JO 1. In addition, the depth GD should preferably be less than 0.5 × TT, where TT is the distance between the floor surface and the upper parts of the tongue / groove. In the case where there is no sheet pile, GD should be less than 0.2 part of the floor thickness T. This helps to clean the opening of the seam. In addition, it is advisable if JO 1 is about 1-5 mm, which corresponds to the usual gaps in homogeneous wooden floors. According to the invention, the overlapping portion of the connecting edge should preferably be located close to the floor surface. This makes it possible to form a shallow opening of the seam, while vertical fixation can be carried out simultaneously using a tongue 10 and a groove 9, which are located essentially in the central parts of the floorboard between the front side and the rear side of the floor board, where the core 30 has good stability. Fig. 4c shows an alternative method for creating a shallow opening of a seam that allows movement. The upper part of the tongue 10 is moved towards the floor surface. The disadvantage of this technical solution is that the upper part 18 of the connecting edge above the tongue 10 will be excessively weak. Part 18 of the connecting edge can easily break off or deform.

Figures 5a and 5b show the connection along the long edges of three floorboards 1, 1 'and 1' 'wide. Fig. 5a shows floorboards at low relative humidity, and Fig. 5b shows the same floorboards at high relative humidity. For the similarity of the floor to homogeneous floors, wide floorboards should preferably have wider joint gaps than narrow floorboards. JO 2 should suitably comprise at least about 1% of the floor width W. In this case, floorboards with a width of 100 mm will have the smallest opening of the seam equal to at least 1 mm. Corresponding joint openings, for example, in boards with a width of 200 mm, should be at least 2 mm. Of course, other combinations can also be used, especially in wooden floors, which are subject to special requirements, taking into account different types of wood and different climatic conditions.

On figa shows a wooden floor, which consists of several layers of wood. The floorboard may contain, for example, a top layer of fine wood, such as oak, which makes up the decorative surface layer 31. The core 30 may consist, for example, of plywood, which is made of other types of wood or of corresponding species of wood, but of a different quality. On the other hand, the core may consist of thin wooden plates. The top layer 31 typically has a different fiber direction than the bottom layer. In this embodiment, the overlapping connecting edges 18 and 19 are formed in the upper layer. An advantage is that the visible opening of the joint JO 1 will take place in the same wood species and in the same fiber direction as in the surface layer 31, and the appearance will be the same as the appearance of a uniform wooden floor.

Figures 6b and 6c show an embodiment of the invention in which there is a small play 22 between the overlapping portions 16, 18 of the connecting edges, which facilitates horizontal movement in the locking system. On figs shows the connection by angular displacement and in contact with each other of the upper parts 18, 19 of the connecting edges. The play 20 between the fixing surface 15 of the locking element 8 and the locking groove 12 greatly facilitates the connection by tilting inward, especially in wooden floors, which are not always straight.

In the above preferred embodiments of the invention, the overlapping part 18 of the connection is made on the side of the tongue, i.e. in the connecting edge having a tongue 10. This overlapping part 18 of the connection can also be made on the side of the groove, i.e. in the connecting edge having a groove 9. Figures 6d and 6e show such an option. In Fig. 6d, the boards are compressed together in their shifted arrangement, and in Fig. 6e, they are stretched to the sides to their apart arrangement.

Figures 7a-7b show that it is advisable that the upper part 18 of the connecting edge, which overlaps the lower part 16 of the connecting edge, is on the tongue-grooving side 4a. As shown in FIG. 7b, the groove positioning side 4b may be vertically connected to the side 4a, which has no tongue. This locking system is especially suitable for the short edge of boards. Fig. 7c shows such a locking system in a connected and compressed state. Figures 7d and 7e show how horizontal fixing means, for example, in the form of a protrusion 6 and a fixing element 8 and, in addition, the upper and lower parts 19, 16 of the connecting edge can be performed with only one tool, which has a horizontally acting shaft NT tool and which, thus, can form the entire connecting edge. Such a tool can be mounted, for example, on a circular saw, and a high-quality connection system can be made by means of a guide rod. The tool can also cut the floorboard 1. In a preferred embodiment of the invention, only partial separation of the floorboard 1 is made at the outer part 24 of the protrusion 6. The final separation of the floorboard is carried out by breaking it off. This reduces the risk of damage to the maintenance tool due to its contact with the subfloor, such as concrete. This method can be used to make a FR frame or frieze in the floor, which is laid with a Christmas tree pattern, as shown in Fig. 5c. The tool can also be used to make a traditional type of fixation system without overlapping portions of the connecting edges.

On figa-8f shows other embodiments of the invention. On figa-8c shows how the invention can be used in fixing systems, where horizontal fixing is carried out by means of a tongue 10 with a locking element 8, which interacts with the locking groove 12, made in the groove 9 and located in the upper protrusion 23, which limits the groove 9. In addition, this groove is bounded by a lower protrusion 24, which can be omitted to allow connection by vertical movement. On fig.8d shows the locking system with a separate strip 6, which is made, for example, of sheet aluminum. On fig.8e shows a fixing system, which has a separate strip 6, which can be made of a material based on chipboard or of plastic, metal and similar materials.

Fig. 8f shows a locking system that can be connected by a horizontal snap movement. The tongue 10 has a groove 9 ', which makes it possible to bend to each other its upper and lower parts with locking elements 8, 8' in connection with the horizontal movement of the connecting edges 4a and 4b to each other. In this embodiment, the upper and lower protrusions 23, 24 at the groove 9 are not elastic. Of course, the invention can also be used in conventional snap-in systems in which the protrusions 23, 24 are resilient.

9a-9d show alternative embodiments of the invention. When the boards are pulled to the sides, separation of the interacting fixing surfaces 14 and 15 is prevented. When the boards are compressed together, several alternative parts can be used in the fixing system to establish a closed position. Fig. 9a shows the closed position in which the outer part of the locking element 8 and the wall of the locking groove 12 are located. Fig. 9b shows the interaction of the outer part of the tongue 10 and the wall of the groove 9. Fig. 9c shows the interaction of the front and lower parts of the tongue 10 with the wall of the groove 9. On fig.9d shows the interaction of the locking element 10 'on the lower part of the tongue 10 with the locking element 9' on the protrusion 6. Obviously, in accordance with these principles, you can use several other parts in the locking system to establish closed on the position of the floorboards.

Figure 10 shows the production equipment and manufacturing methods according to the invention. The tenon cutter ET has a chain 40 and a belt 41 that move the floorboard 1 in the feed direction FD relative to the group of cutting tools, which in this embodiment of the invention has five cutting tools 51, 52, 53, 54 and 55, and pressure shoes 42. The tenon cutter could also have two chains and two ribbons. 10b shows an enlarged view of a first cutting position of a cutting tool. The first cutting tool 51 in the group of cutting tools makes a guide surface 12, which in this embodiment of the invention is a groove and which is mainly formed as a fixing groove 12 of the locking system. Of course, other grooves could be formed, preferably in that part of the floorboard where a mechanical fixation system would be formed. The pressure shoe 42 'has a guiding device 43' that interacts with the groove 12 and prevents deviations from the feed direction FD and in a plane parallel to the horizontal plane. In Fig. 10c, a tenon cutter is shown in a view from the feed direction when the floorboard passes by the first cutting tool 51. In this embodiment of the invention, the locking groove 12 is used as a guiding surface for the guiding device 43, which is attached to the pressure shoe 42. In Fig. 10d shows that the same groove 12 could be used as a guide surface at all machining positions of the cutting tool. 10d shows how a tongue could be formed with cutting tool 54. The machining of a certain part of the floorboard 1 can be carried out when this part is simultaneously guided by the guide device 48. Fig. 11 shows another embodiment of the invention in which the guide device is attached inside the pressure shoe. The disadvantage is that the board will have a groove on its back side. 11b shows another embodiment of the invention in which one or both of the outer edges of the floorboard is used as a guide surface for the guide device 43, 43 ′. In this embodiment, the tenon cutter has support members 44, 44 ′ that cooperate with the pressure shoes 42, 42 ′. On the other hand, a guide device could be attached to these support elements 44, 44 '. Figures 11c and 11d show how the floorboard could be processed in two stages. In the first stage, a tongue 10 is formed. In the second stage (Fig. 11d), in which the groove 9 is formed, the same guide groove 12 is used. Such a tenon cutter will be very readily adaptable. The advantage is that floorboards of different widths, smaller or larger than the width of the chain, could be made.

12a-12c show a preferred embodiment of the invention which ensures that the semi-floating floor is laid in a normal position, which is preferably a position in which the actual joint gap is about 50% of the maximum joint gap. If, for example, all floorboards are laid with touching edges 16, 17, then problems can occur near the walls when the floorboards swell to their maximum size. According to the invention, the locking element and the locking groove could be made in such a way that the floorboards are automatically guided to the optimum position during laying. As shown in FIG. 12 c, the locking element 8 in this embodiment of the invention has a locking surface with a large locking angle LA close to 90 ° to the horizontal plane. This fixing angle LA is larger than the angle of the tangent line TL to the circle C, which has a center at the upper connecting edges. As shown in FIG. 12b, such a joint geometry will push the floorboard 4a toward the floorboard 4b during tilting and bring it into the aforementioned preferred position with a play between the locking element 8 and the locking groove 12 and the joint gap between the upper edges 16, 17.

Claims (24)

1. A semi-floating floor consisting of rectangular floorboards (1, 1 ') connected by a mechanical fixation system in which the connected floorboards have a horizontal plane (HP) parallel to the floor surface (31) and a vertical plane (VP) perpendicular to the horizontal planes, the fixing system having mechanically interacting fixing means for a vertical connection parallel to a vertical plane, and for a horizontal connection parallel to a horizontal plane, the first and second connections edges (respectively 4a and 4b), while in the fixing system the vertical fixing means consists of a tongue (10) interacting with the groove (9) under the tongue, and the horizontal fixing means consists of a fixing element (8) with a fixing surface (15) interacting with the fixing groove (12), characterized in that the format, the pattern of the flooring and the fixing system of the floorboards are made in such a way that the floor covering 1 × 1 m in size changes in length (ΔTL) in at least one direction by, at least 1 mm when floorboards are subjected to a compressive or tensile load in the horizontal plane (HP), and the change in length (ΔTL) occurs without visible gaps (21) of the joints, the surface layer is made of laminate or wood veneer, the core of the floorboard is made of wood-based panels, as for example, medium density particleboard or high density particleboard, the change in floor length (ΔTL) is at least 1.0 mm when using a force (F) of 100 kg / m of the connecting edge, the change in floor length (ΔTL) is at least 1.5 mm when used and forces (F) of 200 kg / m of the connecting edge, the average joint clearances do not exceed 0.15 mm when using forces (F) of 100 kg / m of the connecting edge and they do not exceed 0.20 mm when using force (F) in 200 kg / m of connecting edge. 2. A semi-floating floor consisting of rectangular floorboards (1, 1 ') connected by a mechanical fixation system in which the connected floorboards have a horizontal plane (HP) parallel to the floor surface (31) and a vertical plane (VP) perpendicular to the horizontal planes, the fixing system having mechanically interacting fixing means for a vertical connection parallel to a vertical plane, and for a horizontal connection parallel to a horizontal plane, the first and second connections edges (respectively 4a and 4b), while in the fixing system the vertical fixing means consists of a tongue (10) interacting with the groove (9) under the tongue, and the horizontal fixing means consists of a fixing element (8) with a fixing surface (15) interacting with the fixing groove (12), characterized in that the format, the pattern of the flooring and the fixing system of the floorboards are made in such a way that the floor covering 1 × 1 m in length changes (ΔTL) in at least one direction by, at least 1 mm when floorboards odvergayutsya compressive or a tensile load in a horizontal plane (HP), wherein the change in length (ΔTL) occurs without visible gaps (21) joints. 3. The semi-floating floor according to claim 2, characterized in that the width of the floorboards does not exceed about 120 mm. 4. Semi-floating floor according to claim 2 or 3, characterized in that the fixing system has an average play (AR) of at least about 0.1 mm when the boards are subjected to compressive and tensile loads in the horizontal plane (HP). 5. Semi-floating floor according to claim 2 or 3, characterized in that the floorboards are connected by a long edge to a short edge. 6. A semi-floating floor according to claim 2 or 3, characterized in that the floorboards have a surface layer (31) of laminate, while parts of the surface layer (31) are removed on at least one connecting edge. 7. The semi-floating floor according to claim 1, characterized in that the format, the pattern of the flooring and the fixing system of the floorboards are made and combined in such a way that a large semi-floating continuous coating 12 m long or wide is layered without expansion joints. 8. The semi-floating floor according to claim 7, characterized in that the floor surface is a continuous floor covering having a length or width of more than 20 m. 9. The semi-floating floor according to claim 7 or 8, characterized in that the floorboards have a width not exceeding 100 mm. 10. A fixing system for mechanically joining floorboards (1, 1 ′), in which the connected floorboards have a horizontal plane (HP) parallel to the floor surface and a vertical plane (VP) perpendicular to the horizontal plane, the fixing system having mechanically interacting means fixation for a vertical connection parallel to the vertical plane, and for horizontal connection parallel to the horizontal plane, the first and second connecting edges (4A, 4b), while in the fixation system the vertical fixation means consists of a tongue (10), which interacts with the groove (9) under the tongue, and the horizontal fixation means consists of a locking element (8) with a locking surface (15), which interacts with the locking groove (12), characterized in that the first (4a) and second (4b) connecting edges have upper (18, 19) and lower (16, 17) parts of the connecting edges, which are both between the tongue (10) and the floor surface (31), while the upper parts ( 18, 19) of the connecting edges are located closer to the surface (31) of the floor than the lower parts ty (16, 17) of the connecting edges, and in the fixing system, when the floorboards (1, 1 ') are connected and pressed against each other, one of these upper parts (18, 19) of the connecting edges in the first connecting edge (4a) overlaps one of the lower parts (16, 17) of the connecting edges in the second connecting edge (4b), while in the fixing system, when the floorboards (1, 1 ') are connected and pressed against each other, the two upper parts (18, 19) of the connecting edges are located at a distance from each other, and in the fixation system floorboards have a surface layer (31) of a laminate or wood veneer and a core (30) of a material based on chipboard, and the fixation of the upper overlapping part (18) of the connecting edge is formed in this surface layer and in the upper parts of the core near the surface layer, while the vertical extent (GD) of the overlapping part is less 0.1 parts of the thickness (T) of the floor. 11. A fixing system for mechanically joining floorboards (1, 1 ′), in which the connected floorboards have a horizontal plane (HP) parallel to the floor surface and a vertical plane (VP) perpendicular to the horizontal plane, the fixing system having mechanically interacting means fixation for a vertical connection parallel to the vertical plane, and for horizontal connection parallel to the horizontal plane, the first and second connecting edges (4A, 4b), while in the fixation system the vertical fixation means consists of a tongue (10), which interacts with the groove (9) under the tongue, and the horizontal fixation means consists of a locking element (8) with a locking surface (15), which interacts with the locking groove (12), characterized in that the first (4a) and second (4b) connecting edges have upper (18, 19) and lower (16, 17) parts of the connecting edges, which are both between the tongue (10) and the floor surface (31), while the upper parts ( 18, 19) of the connecting edges are located closer to the surface (31) of the floor than the lower parts ty (16, 17) of the connecting edges, and in the fixing system, when the floorboards (1, 1 ') are connected and pressed against each other, one of the upper parts (18, 19) of the connecting edges in the first connecting edge (4a) overlaps one from the lower parts (16, 17) in the second connecting edge (4b), while in the fixing system, when the floorboards (1, 1 ') are connected and pressed against each other, the two upper parts (18, 19) of the connecting edges are located on distance from each other. 12. The fixing system according to claim 11, characterized in that there is an overlap (OL) when the floorboards (1, 1 ') are subjected to a tensile load (F). 13. The fixing system according to item 12, characterized in that there is an overlap (OL) when the tensile load (F) is 100 kg / m of the connecting edge. 14. Fixation system according to any one of claims 11 to 13, characterized in that there is an average play (AR) of at least 0.1 mm when the floorboards are subjected to a compressive or tensile load of 200 kg / m horizontal plane (HP ) 15. A fixation system according to any one of claims 11 to 13, characterized in that the upper overlapping part (18) of the connecting edge is made near the floor surface (31) and has a lower part that is closer to the floor surface than the upper part of the tongue ( 10). 16. The fixation system according to clause 15, wherein the minimum opening of the seam (JO 2) is more than half the maximum opening of the seam (JO 1). 17. The fixation system according to claim 11, characterized in that the surface layer (31) consists of wood, and the upper overlapping portion (18) of the connecting edge is made in a wear layer. 18. The fixing system according to claim 11, characterized in that the depth (GD) of the opening of the seam is 0.02-0.08 thickness (T) of the floorboards, the first connecting edge (4a) on the long edge of the board overlaps one of the lower parts (16, 17) connecting edges on the long edges of the boards, available in the second connecting edge (4b), 0.01-0.05 thickness (T) of the floorboards. 19. Equipment for the manufacture of building panels, especially floorboards, having a horizontal plane (HP) parallel to the panel, the equipment comprising a chain (40), tape (41), pressure shoe (42) and a group of cutting tools (51-55), while the chain and the tape are arranged to move the floorboard (1) relative to the group of cutting tools and the pressure shoe in the feed direction (FD), the pressure shoe is made to be pressed against the back side (32) of the floorboard; and the group of cutting tools is configured to form the outermost part of the floorboard when the floorboard is moved relative to the group of cutting tools, characterized in that one of the cutting tools in the group of cutting tools is configured to form a guide surface (12) in the floorboard, while pressing the shoe has a guiding device (43) that interacts with the guiding surface (12) and prevents deviations in the direction perpendicular to the feed direction (FD) and the parallel Yelnia horizontal plane (HP). 20. The equipment according to claim 19, characterized in that the construction panel is a floorboard with a mechanical fixation system, the fixation system comprising a locking element (8) that interacts with the fixing groove (12) and horizontally fixes the floorboards parallel to the horizontal plane (HP) while the guide surface (12) is made in the form of a groove open to the rear side of the floorboard; and the groove is located at the extreme part of the floorboard, where some parts of the fixation system are located. 21. The semi-floating floor, consisting of rectangular floorboards (1, 1 '), connected by a mechanical fixation system, according to any one of claims 1 to 18, characterized in that the format, pattern of the flooring and the fixation system of the floorboards are made and combined in such a way that a large semi-floating continuous coating with a length or width of more than 12 m is layered without expansion joints. 22. The semi-floating floor according to item 21, wherein the floor surface is a continuous floor covering with a length or width of more than 20 m 23. The semi-floating floor according to item 21 or 22, characterized in that the floorboards have a width not exceeding 120 mm. 24. Semi-floating floor according to item 21 or 22, characterized in that the floorboards have a width not exceeding 100 mm.

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