SE526596C2 - Floating floor with mechanical locking system that allows movement between the floorboards - Google Patents

Abstract

Floorboards with a mechanical locking system that allows movement between the floorboards when they are joined to form a floating floor.

Description

20 25 30 35 526 596 2 which consists of melamine impregnated paper which is compressed under pressure and heat. "Horizontal plane" means a plane that is parallel to the outer part of the surface layer. "Vertical plane" means a plane perpendicular to the horizontal plane.

The outer parts of the floorboard at the edge of the floorboard between the front and the back are called "joint edge".

“Joint” or “locking system” refers to cooperating coupling means, which connect the floorboards vertically and / or horizontally. By "mechanical locking system" is meant that joining can take place without glue. In many cases, mechanical locking systems can also be joined with glue. "Vertical locking" means locking parallel to the vertical plane. Vertical locking usually takes place with a tongue that interacts with a groove. "Horizontal locking" means locking parallel to the horizontal plane. By "joint opening" is meant a groove which is delimited by two joint edges of two joined floorboards and which is open to the floor surface. "Joint gap" means the minimum distance between two joint edge portions of two joined floorboards within an area bounded by the floor surface and the upper part of the spring closest to the floor surface. "Visible joint gap" refers to a joint gap that is visible to the naked eye from the front when a person walks on the floor.

Background of the Invention Traditional laminate and parquet floors are usually laid floating on an existing subfloor. The joint edges of the floorboards are joined together to form a floor surface and the entire floor surface can move in relation to the subfloor. As the floorboards shrink or swell in connection with the relative humidity RH varying during the year, the entire floor surface will change shape.

Floating floors of this type are usually joined by means of glued tongue / groove joints. During installation, the boards are brought together horizontally, wherein a projecting tongue along the joint edge of a board is inserted into a tongue groove along the joint edge of an adjacent board. The tongue / groove joint positions and locks the floorboards vertically and the glue locks the boards horizontally. The same method is used on both the long and short side, and the discs are usually laid in parallel rows long side to long side and short side to short side.

In addition to such, traditional floating floors, which are joined together by means of glued tongue and groove joints, floorboards have been developed in recent years, which do not require the use of glue but which are instead joined mechanically by means of so-called mechanical locking systems. These systems contain locking means that lock the discs mechanically horizontally and vertically without glue. The mechanical locking systems can be formed by machining the core of the disc.

Alternatively, parts of the locking system can be formed of a separate material which is integrated with the floorboard, i.e. joined to the floorboard already in connection with the manufacture of this in the factory. The floorboards can be connected mechanically, through various combinations of angular movement, snapping, vertical position change and insertion along the joint edge.

Wood and laminate floors are also joined together by gluing or nailing to the subfloor. This gluing / nailing counteracts moisture movements and keeps the floorboards joined together. The movement of the floorboards takes place around a center point in each floorboard. Swelling and shrinkage can take place by only changing the respective floorboard and thus not the entire floor surface.

Floor panels that are joined with gluing / nailing do not need to have any locking systems at all. However, they may have traditional tongue / groove joints that facilitate vertical positioning. They can also have mechanical locking systems that lock and position the floorboards vertically and / or horizontally in connection with laying.

Known technology and problems with this The advantage of floating floors is that deformation due to different humidity RH can take place hidden under skirting boards and the floorboards can, despite swelling and shrinking, be joined without visible joint cracks.

Installation can, especially with mechanical locking systems, be done quickly and easily and the floor can be picked up and re-laid on another site. The disadvantage is that the continuous floor surface must generally be limited even in cases where the floor consists of relatively dimensionally stable floorboards such as, for example, laminate floors with a fibrous core or wooden floors composed of several layers with different fiber directions.

The reason is that such dimensionally stable floors usually have a dimensional change that is about 0.1% corresponding to about 1 mm per meter as RH varies between 25% winter time and 85% summer time. Such a floor will, for example, shrink and swell about 10 mm over a distance of ten meters. A large floor area must be divided into smaller areas with expansion strips of, for example, every ten or fifteen meters. If such a division does not take place, there is a risk that the floor will shrink in the event of shrinkage so that it is no longer covered by skirting boards. The load on the locking system also becomes large because large loads must be moved when a large continuous surface moves.

The load becomes particularly large during passages between different room units.

Unstable floors, such as homogeneous wooden floors, can show even greater changes in shape. The factors that mainly affect the shape change of homogeneous wood floors are fiber direction and type of wood. A homogeneous oak floor is very stable along the fiber direction, i.e. in the longitudinal direction of the floorboard. In the width direction, the movement can be 3% corresponding to 30 mm per meter or more as RH varies during the seasons. Other types of wood show even greater changes in shape. Floor tiles that show large deformations can generally not be installed floating. Although such an installation would be possible, the continuous floor space must be considerably limited.

The advantage of gluing / nailing is that large continuous floor surfaces can be achieved without expansion strips and the floor can have a large load. Another advantage is that the floorboards do not need to have any vertical and horizontal locking systems and they can then be installed in advanced patterns with, for example, long sides joined together against short sides. However, this installation method with attachment to the subfloor has a number of significant disadvantages. The main disadvantage is that when the floorboards shrink, a visible joint gap occurs between the boards.

This joint gap can be relatively large, especially since the floorboards are made of moisture-sensitive wood materials.

Homogeneous wooden floors that are nailed to a subfloor can have joint gaps of 3 - 5 mm. The distance between the discs can be unevenly distributed with several small and some large gaps and these gaps are not always parallel.

The joint gap can thus vary over the length of the floorboard.

The large joint cracks contain a lot of dirt that penetrates into the spring and prevents the floorboards from taking up their original position during swelling.

The installation methods are time consuming and often the subfloor must be adapted for gluing / nailing to take place. It would therefore be a great advantage if it were possible to achieve a floating floor without the above-mentioned disadvantages and then especially a floating floor which: a) can consist of a large continuous surface without expansion strips, b) can consist of moisture-sensitive floorboards that show large dimensional changes as RH varies during the year.

Summary of the invention The present invention relates to locking systems, floorboards and floors which enable floating floors to be installed in large continuous surfaces and with floorboards which show large dimensional changes in the event of changes in the relative humidity (RH).

A first object of the present invention is to provide a floating floor of rectangular floorboards with mechanical locking systems in which the floorboard floor format, laying pattern and locking system interact and enable movements between the floorboards.

According to the invention, the individual floorboards can be changed in shape after installation, ie. shrinkage and swelling due to changes in relative humidity. This can be done in such a way that the shape change of the entire floor surface can be reduced or preferably eliminated at the same time as the floorboards remain locked to each other without large visible joint cracks.

A second object is to provide a locking system that enables significant movement between floorboards without large and deep dirt-collecting joint cracks. Such locking systems are especially suitable for moisture-sensitive materials such as wood, but even when large floating floors are installed with wide and / or long floorboards. 10 15 20 25 30 526 596 7 The terms long side and short side are used in the description to facilitate understanding. According to the invention, the discs can also be square or alternately square and rectangular, and possibly also have different patterns and angles between opposite sides.

It should be emphasized in particular that the combinations of floorboards, locking systems and laying patterns that appear in this description are only examples of suitable embodiments. A variety of options are possible.

All the embodiments suitable for the first purpose of the invention can be combined with the embodiments describing the second object of the invention. All locking systems can be used separately in long sides and / or short sides and in different combinations on the long and short sides. The locking systems having horizontal and vertical locking means can be joined by angling and / or snapping.

The geometries of the locking systems and the operative horizontal and vertical locking means can be designed by machining the edges of the floorboard or by forming separate materials or machining before or after joining with the joint edge portion of the floorboard.

These objects are achieved in whole or in part according to the following requirements.

The present invention comprises a floating floor consisting of rectangular floorboards which are joined by a mechanical locking system. 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 locking system has mechanically cooperating locking means for vertical joining parallel to the vertical plane and for horizontal joining parallel to the horizontal plane of a first and a second joint edge. The vertical locking means consist of a spring which cooperates with a groove and the horizontal ones of a locking element with a locking surface which cooperates with a locking groove. The floor is characterized in that the floorboards' format, installation pattern and locking system are designed so that a floor area of 1 * 1 meter can be deformed in at least one direction at least 1 mm when the floorboards are compressed or pulled apart with a force corresponding to 200 N per 100 mm joint length. occurs without joint cracks exceeding approx. 0.1 mm. This shape change can take place without visible joint cracks.

In an embodiment of the locking system for mechanical joining of floorboards to a floating floor, the first and the second joint edge have upper and lower joint edge portions located between the spring and the floor surface. The upper joint edge portions are closer to the floor surface than the lower ones. The locking system is characterized in that when the floorboards are joined and compressed against each other, the two upper joint edge portions are spaced apart and one of the upper joint edge portions in the first joint edge overlaps a lower joint edge portion in the second joint edge.

Brief description of the drawings Figures 1a-b show floorboards.

Figs. 2a ¥ 2f show locking systems and laying patterns Figs. 3a-3b show locking systems Figs. 4a-4c show locking systems.

Figs. 5a-5e show joined floorboards, and a test method Figs. 6a-6e show locking systems Figs. 7a-7e show locking systems and a tool for forming a joint edge Figs. 8a-8f show locking systems Figs. 9a-9d show locking systems Description of embodiments Figures 1a-b show floorboards which are of a first type A and a second type B, respectively, and whose long sides 4a and 4b in this embodiment have a length which is 3 times the length of the short sides 5a, Sb. The long sides 4a, 4b of the floorboards have vertical and horizontal coupling means and the short sides 5a, 5b of the floorboards have horizontal coupling means. The two types are identical in this embodiment except that the location of the locking means is mirror-inverted. The locking means enable joining of long side 4a to long side 4b by at least angling and long side 4a to short side 5a by angling and short side 5b to long side 4b by a vertical movement. Joining both long sides 4a, 4b and short sides, 5a, 5b in a herringbone pattern or in parallel rows can in this embodiment take place by only an angular movement around the long sides 4a, 4b. The long sides 4a and 4b of the floorboards have coupling means which in this embodiment consist of a strip 6, groove 9 and spring 10. The short sides Sa also have a strip 6 and groove grooves 9 while the short sides 5b lack spring 10. A number of variants may occur. The two types of floorboards do not have to be of the same format and the locking means can also have different shapes, provided that they can be joined long side to short side as above. The coupling means may be formed of the same material or of different materials or may be formed of the same material but with different material properties. For example, the coupling means can be made of plastic or metal. They can also be made of the same material as the floorboard, but have been subjected to a property-modifying treatment, such as impregnation or the like. The short sides 5b can have a spring and the floorboards can then join in a known manner in a grid pattern through different combinations of angular movement and snap movements. Fig. 2a shows the coupling means in two floorboards 1, 1 'which are joined together. In this embodiment, the floorboards have a surface layer 31 of laminate, a core 30 of, for example, HDF, which is softer and more compressible than the surface layer 31, and a balance layer 32. The vertical reading D1 consists of a groove 9 which cooperates with a spring 10. the horizontal locking D2 consists of a strip 6, with a locking element 8 which cooperates with a locking groove 12. This locking system can be joined by angling around the upper joint edges. The locking element 8 and the locking groove 12 have cooperating locking surfaces 15, 14. The floorboards can, when joined together and pressed against each other in horizontal direction D2, assume a position where there is a clearance 20 between the locking surfaces 14, 15. When the floorboards are pulled apart in in the opposite direction, a joint gap 21 arises between the upper joint edges. The clearance and the joint gap can, for example, be 0.05 - 0.10 mm. ' Joint cracks that are about 0.1 mm are considered acceptable. They are difficult to see and normal dirt particles are too large to penetrate into the locking system through such small joint cracks.

Fig. 2b shows a common laminate floor 1.2 * with floorboards which have a format of 0.2 m and which are installed in parallel rows. Such a laminate floor shrinks and swells about 1 mm per meter. If the locking system has a clearance of approx. 0.1 mm, the five joints in the width direction D2 B will enable a swelling and shrinkage of 5 * 0.1 = 0.5 mm per meter. This only compensates for half the maximum swelling or shrinkage of 1 mm. In the longitudinal direction D2 A there is only one joint per 1.2 meters which enables a movement of 0.1 mm. The clearance 20 and the joint gap 21 in the locking system thus contribute only marginally to reducing shrinkage and swelling of the floor in the direction DZA parallel to the longitudinal sides. In order to reduce the movement of the floor to half of the movement that normally takes place in floors without clearance 20 and joint gap 21, it is necessary to increase the clearance 20 to 0.6 mm and this gives an excessive joint gap 21 on the short side.

Fig. 2c shows floorboards, with for example a core 30 of wood fibers such as HDF and surface layers of laminate or veneer, which have a maximum dimensional change of about 0.1%, i.e. 1 mm per meter. The floorboards are installed in In this embodiment, they are narrow and * 0.08 meters. If the clearance is 0.1 mm, 12 floorboards will come with their parallel rows. short with a format that can be, for example, 0.5 12 joints over a floor length of one meter to enable a movement in the width direction D2 B of 1.2 mm, which is more than the floor's maximum dimensional change. The entire movement can thus take place by the floorboards moving relative to each other and the outer dimensions of the floor can be unchanged. In the longitudinal direction D2 A, the two short-side joints can only compensate for a movement of 0.2 mm per meter. In a room that is, for example, 10 meters wide and 40 meters long, an installation can suitably take place with the long sides of the floorboards parallel to the width of the room and perpendicular to its length. Thus, according to this preferred embodiment, a large continuous floating floor surface without large visible joint cracks can be provided with narrow floorboards which have a locking system with winches and which are joined in parallel rows perpendicular to the length of the floor surface. The locking system, the floorboards and the installation pattern according to the invention should thus be adapted so that a floor area of 1 * 1 m can expand and be compressed by about 1 mm or more in at least one direction without damaging the locking system or the floorboards. A mechanical locking system in floating floors that is installed in a normal home environment should have a mechanical locking system that can withstand a tensile load and compression corresponding to at least 200 kg per meter of floor length. More specifically, the above deformation without visible joint cracks should preferably be achieved when the floor surface above is pressurized or tensile loaded with 200 kg in any direction and when the floorboards are conditioned in normal relative humidity of about 45%.

Fig. 5d shows a suitable test method to ensure that the floorboards have a sufficient mobility in the joined condition. In this example, 9 test pieces with a length L of 100 mm (10% of 1 meter) have been joined to their respective long sides so that they correspond to a floor length TL of about 1 meter. The discs are tensile and pressure loaded with a force F corresponding to 20 kg (200 N) which is 10% of 200 kg. The TL length change of the floor length must then amount to at least 1 mm. Fig. 5e shows how a corresponding test can be done in a floor installed in herringbone pattern. The force F must then be adapted to the distance L between the short sides of the discs. If this distance is, for example, 0.6 meters, the force F must be 0.6 times 200 = 120 kg Fig. 2d shows floorboards according to Fig. 2c which are installed in a grid pattern. This installation method gives 7 joints per running meter in both directions of the floor D2 A and D2 B. A clearance of 0.14 mm can then completely eliminate a swelling and shrinkage of 0.1%, since 7 joints give a total movement possibility of 7 * 0, 14 = 1.0 mm.

Fig. 2e shows a m2 floor area consisting of the floorboards described above installed in a herringbone pattern long side to short side and shows the position of the floorboards when, for example, they have swelled to their maximum dimension in summer. Fig. 2f shows the position of the floorboards when they have shrunk during the winter, for example. The locking system with the built-in clearance then provides a joint slot 21 between all the joint edges of the floorboards. Since the floorboards are installed in a herringbone pattern, the long sides' play will help to reduce the floor's dimensional changes in all directions. Figure 2f also shows that the critical direction is the diagonal directions D2 C and D2 D of the floor, where 7 joint cracks must be adapted so that they can withstand a shrinkage of a distance of 1.4 meters. This can be used to determine the optimal laying direction in a large floor. In this example, a joint gap of 0.2 mm will completely eliminate the movement of the floor in all directions. This enables the outer parts of a floating floor to be attached to the subfloor by, for example, gluing which prevents the floor from moving outside the baseboards when shrinking.

The invention also makes it possible for partitions to be attached to a laid floating floor, which can reduce the laying time.

Practical tests show that floors with a surface of veneer or laminate and with a core of a wood fiber-based board, for example a dimensionally stable high-quality HDF, can be manufactured so that they are very dimensionally stable and with a maximum dimensional change in a normal home environment of about 0.5 - 1 .0 mm per meter. Such floors can be installed in unlimited large spaces and the maximum clearance can be limited to about 0.1 mm even in cases where the floorboards have a width of preferably about 120 mm. Even smaller floorboards, for example 0.4 * 0.06 meters, are of course even more favorable and can handle large areas even when they are made of less dimensionally stable materials. Thus, according to a first embodiment, the invention provides a new type of floating floor where the individual floorboards have the possibility of movement and where the outer dimensions of the floor do not need to be changed. This can be achieved by an optimal utilization of the format of the tiles, the possibility of the locking system with the use of a small clearance and a small joint gap and the installation pattern of the floorboards.

According to the invention, a suitable combination of clearance, joint gap, floor tile format, laying pattern and laying direction can thus be used to completely or partially eliminate movement in a floating floor. Much larger continuous floating floors can be installed than is possible today and the floor's maximum movement can be reduced to the approximately 10 mm that applies to current technology or completely eliminated. All this can be done with a joint gap which in practice is not visible and which does not differ from floors which are joined with prestress or a very small play which does not provide a sufficient possibility of movement. As a non-limiting example, it can be mentioned that the clearance 20 and the joint gap 21 in dimensionally stable floors should suitably be about 0.1 -0.2 mm.

Fig. 3a shows a second embodiment that can be used to counteract the problems of moisture movements in floating floors. In this embodiment, the floorboard has a surface 31 of direct laminate and a core of HDF. Below the laminate surface there is a layer 33 consisting of melamine impregnated wood fibers. This layer occurs when the surface layer is laminated to HDF and when melamine penetrates into the core and joins the surface layer with the HDF core. The HDF core 30 is softer and more compressible than the laminate surface 31 and the melamine layer 33. According to one embodiment, the surface layer 31 of laminate and, if applicable, also parts or the entire melamine layer 33 below the surface layer can be removed so that a decorative groove 133 is formed in the form of a shallow joint opening. 1. This joint opening mimics a large joint gap between homogeneous wooden floors. The groove 133 can be made on only one joint edge and it can be colored, coated or impregnated in such a way that the joint gap becomes less visible. Such decorative grooves or joint openings may, for example, have a wide JO 1 of, for example, 1-3 mm and a depth of 0.2-0.5 mm. When the floorboards 1, 1 'are compressed against each other, the upper joint edges 16 can be compressed. In HDF, this compression can be 0.1 mm. Such a compression option can replace the above-mentioned game and can enable movement without any joint crack.

A chemical treatment as above can also change the properties of the joint edge portion and help to improve the compression possibilities. Of course, the first and second embodiments can be combined. With a clearance of 0.1 mm and a compression possibility of 0.1 mm, a total movement of 0.2 mm can be achieved with a visible joint gap of only 0.1 mm. Compression can also be 14 in the locking element 8 and in the locking groove 12. In normal climates between the active locking surfaces 15, conditions are prevented from separating the floorboards when the locking surfaces 14, 15 are in contact with each other and no significant compaction takes place. With additional tensile load in extreme climatic conditions, for example when RH falls below 25%, the locking surfaces are compressed. This compression is facilitated if the contact surface CS of the locking surfaces 14, 15 is small. It is an advantage if this contact surface in normal floor thicknesses 8-15 mm is about 1 mm or less. With this technology, floorboards can be manufactured with a clearance and joint gap of about 0.1 mm. In extreme climatic conditions when RH is less than 25% and exceeds 80%, compression of the upper joint edges and locking surfaces can enable a movement of, for example, 0.3 mm. The above technique can be applied to many different types of floors, for example on floors with a surface of high-pressure laminate, wood, wood veneer and plastic and the like. The technique is particularly suitable in floorboards where it is possible to increase the compression of the upper joint edges by felling a part of the upper joint edge portion 16.

Fig. 3b shows a third embodiment. The floorboard 1 'has within an area in the joint edge bounded by the upper parts of the spring 10 and the groove 9 and the floor surface 31 an upper joint edge portion 18 and a lower joint edge portion 17 and the floorboard 1 has in a corresponding area an upper joint edge portion 19 and a lower joint edge portion 16. When the floorboards 1, 1 'are pressed together, the lower joint edge portions 16, 17 come into contact with each other. The upper joint edge portions 18, 19 are spaced apart and one upper joint edge portion 18 of one floorboard 1 'overlaps the lower joint edge portion 16 of the other floorboard 1. In this compressed position there is in the locking system a clearance 20 of e.g. 0.2 mm between the locking surfaces 14, 15. If the overlap in this compressed position is 0.2 mm, the discs can be separated from each other by 0.2 mm when they are pulled apart without any visible joint gap being visible from the surface. The decorative groove 133 can be made very shallow and all dirt that ends up in the groove can then be easily removed with a vacuum cleaner in connection with normal cleaning. No dirt or moisture can penetrate into the locking system and down towards the spring 12. This technology with overlapping joint edge portions can of course be combined with the other two embodiments. For example, the visible joint gap can be made 0.1 mm, the compression 0.1 mm and the overlap 0.1 mm. The possibility of movement of the floorboards then becomes a total of 0.3 mm and this considerable movement can be combined with a small visible joint gap and a limited horizontal extension of the overlapping joint edge portion 18 which does not have to constitute a weakening of the joint edge. This is due to the fact that the overlapping joint edge portion 18 is partly very small and partly formed in the strongest part of the floorboard which consists of the laminate surface and melamine-impregnated wood fibers. Such a locking system which can thus provide a significant possibility of movement without visible joint cracks can be used in all the applications described above.

In addition, it is especially suitable for use in wide floorboards, on the short sides, as the floorboards are installed in parallel rows and the like, ie. in all the applications that require great mobility in the locking system to counteract the floor's dimensional change.

It can also be used in the short sides of floorboards which form a frame FR or frieze around a floor installed in a herringbone pattern according to Fig. 5c. In this embodiment, the vertical extent of the overlapping joint edge portion is ie. the depth of the joint opening DG less than 0.1 times the floor thickness T.

Figs. 4a and 4b show how a locking system can be designed so that it enables a floating installation of floorboards consisting of a moisture-sensitive material. In this exemplary embodiment, the floorboard consists of homogeneous wood.

Fig. 4a shows the locking system in the tension-loaded position and Fig. 4b shows the locking system in the compressed position. In order for the floor to have an attractive appearance, the relative size of the joint openings should not deviate too much from each other.

To ensure that the visible joint openings do not deviate too much during the floor movements, the smallest joint opening JO 2 should be greater than half the largest joint opening JO 1. Furthermore, the depth GD should preferably be less than 0.5 * TT where TT is the distance between the floor surface and upper parts of tongue / note. In the case where a tongue is missing, the DG should be less than 0.2 times the floor thickness T. This facilitates cleaning of the joint opening. It is also an advantage if JO 1 is about 1-5 mm, which corresponds to normal cracks in homogeneous wooden floors. According to one embodiment, the overlapping joint edge portion should preferably be close to the floor surface. This enables a shallow joint opening at the same time as the vertical reading can take place with a spring 10 and groove 9 which are located substantially in the middle parts of the floorboard between the front and the back where the core 30 has a good stability. An alternative way of providing a shallow joint opening which enables movement is shown in Fig. 4c. The upper part of the spring 10 has been moved up towards the floor surface. The disadvantage of this solution is that the upper joint edge portion 18 over the spring 10 becomes too weak.

The joint edge portion 18 can easily crack or deform.

Fig. 5a and Sb show the long side joint of three floorboards 1, 1 'and 1 "with the width W. Fig. 5a shows the floorboards when RH is low and Fig. 5b shows when RH is high. JO2 should suitably be at least about 1% of the floor width W. 100 mm wide floorboards will then have a minimum joint opening of at least 1 mm. especially in wooden floors where different types of wood and different climatic conditions place special demands.

Fig. 6a shows a wooden floor consisting of several layers of wood. The floorboard may, for example, consist of an upper layer of hardwood, for example oak, which constitutes the decorative surface layer 31. The core 30 may, for example, consist of plywood which is built up of other types of wood or of corresponding types of wood but of a different quality. Alternatively, the core may consist of wooden slats. The upper layer 31 generally has a different fiber direction than a lower layer. In this embodiment, the overlapping joint edges 18 and 19 have been formed in the upper layer. The advantage is that the visible joint opening JO 1 will consist of the same type of wood and fiber direction as the surface layer 31 and the appearance will be identical to a homogeneous wooden floor.

Figs. 6b and 6c show an embodiment where there is a small clearance 22 between the overlapping joint edge portions 16, 18 which facilitates horizontal movement in the locking system. Fig. 6c shows joining with an angular movement and with the upper joint edge portions 18, 19 in contact with each other.

The clearance 20 between the locking surface 15 of the locking element 8 and the locking groove 12 substantially facilitates joining by angling, especially in wooden floors which are not always straight.

In the above preferred embodiments, the overlapping joint portion 18 is formed in the spring side, i.e. in the joint edge which has a spring 10. This overlapping joint portion 18 can also be formed in the groove side, ie in the joint edge which has a groove 9. Figs. 6d and 6e show such an embodiment. In Fig. 6d the discs are compressed in their inner position and in Fig. 6e they are extended to their outermost position.

Figs. 7a-7b show that it is an advantage if the upper joint edge 18 which overlaps the lower 16 is on the spring side 4a. The groove side 4b can then be joined by a vertical movement with a side 4a which lacks a spring according to Fig. 7b. Such a locking system is especially suitable on the short side. Fig. 7c shows such a locking system in the joined and compressed position. Figs. 7d and 7e show how the horizontal locking means, for example in the form of a strip 6 and a locking element 8 and an upper and lower joint portion 19, 16 can be formed with only one tool TO which has a horizontally working tool axis HT and which can thus form the entire joint edge . Such a tool can for instance be mounted on a circular saw and with the aid of a guide rail a high-quality joint system can be designed.

The tool can also saw off the floorboard 1. In the preferred embodiment, only a partial division of the floorboard 1 takes place at the outer portion 24 of the strip 6. The final division takes place by breaking the floorboard. This reduces the risk of the tool TO being damaged by it coming into contact with a subfloor of, for example, concrete.

This technique can be used to provide a frame or free FR in a floor which is, for example, installed in a herringbone pattern according to Fig. 5c. The tool can also be used to manufacture a locking system of the traditional type without overlapping joint edge portions. Figs. 8a-8f show different embodiments. Figs. 8a-8c show how the invention can be used in locking systems where the horizontal reading consists of a spring 10 with a locking element 8 which cooperates with a locking groove 12 formed in a groove 9 bounded by an upper 23 lip and where the locking groove 12 is located in the upper lip 23. The groove also has a lower lip 24 which can be removed to allow joining with vertical movement. Fig. 8d shows a locking system with a separate strip 6 which is for instance formed of an aluminum plate. Fig. 8e shows a locking system having a separate strip 6 which may be formed in a wood fiber-based material or in plastic, metal and the like.

Fig. 8f shows a locking system that can be joined by horizontal snapping. The spring 10 has a groove groove 9 'which enables its upper and lower part with the locking elements 8, 8' to bend towards each other in connection with a horizontal displacement of the joint edges 4a and 4b towards each other. In this embodiment, the upper and lower lip 23, 24 of the groove 9 need not be resilient. The invention can of course also be used in conventional snap systems where the lips 23, 24 can be resilient.

Figures 9a-9d show alternative embodiments of the invention. When the discs are pulled apart, separation of the cooperating locking surfaces 14 and 15 is prevented. When the discs are compressed, several alternative parts of the locking system can be used to define the inner position. In Fig. 9a the inner position of the outer part of the locking element 8 and the locking groove 10 is determined. According to Fig. 9b the outer part of the tongue 10 and the groove 9 cooperate. on the lower part of the tongue 10 with a locking element 9 'on the strip 6. It is obvious that several other parts of the locking system can be used according to these principles to define the inner position of the floorboards.

Claims (10)

10 15 20 25 30 526 596 22 PATENT REQUIREMENTS Floating floor consisting of rectangular floorboards (1, 1 ') joined by a mechanical locking system, in which floor the joined floorboards have a horizontal plane (HP) parallel to a floor surface (31) and a vertical plane (VP) perpendicular to the horizontal plane (HP), which locking system has mechanically cooperating locking means for vertical joining of the floorboards a first (VP) and for horizontal joining of the floorboards in a second direction (D1) parallel to the vertical plane direction (D2) parallel with the horizontal plane (HP) of the floorboards and perpendicular to a first and a second joint edge (4a and 4b respectively), and in which locking system the vertical locking means consist of a spring (10) cooperating with a groove (9) and the horizontal of a locking element ( 8) having a first locking surface (15), which cooperates with a locking groove (12) as (14), the floorboards having joint edge portions (17, 18; having a second locking surface 16, 19), which are located above said vertical locking means, characterized in that the format and locking system of the floorboards are designed so that a floor area of 1 * 1 meter is deformable in at least one direction, at least 1 mm when the floorboards are compressed or pulled apart with a force corresponding to 200 N per 100 mm joint length, whereby the deformation occurs without joint cracks exceeding approx. 0.1 mm. 10 15 20 25 30 35 526 596 23 Floating floor according to claim 1, characterized in that the width of the floorboards does not exceed about 120 mm. Floating floor according to claim 1 or 2, characterized in that there is a play between the locking surface (15) and the locking groove (12) of at least about 0.05 mm when the boards are pressed together Floating floors according to claims 1 - 3, characterized in that the floorboards are joined long side to short side. Floating floor according to claim 1 or 4, characterized in that the floorboards have a surface layer (31) of laminate and that parts of the surface layer (31) on at least one joint edge are felled. Floating floors according to any one of the preceding claims, 1 ') are designed such that said joint edge portions comprise upper (18, (16, 17) above said vertical locking means and the floor surface (31), the floorboards (1, 19) and lower joint edge portions , all of which are located, the upper joint edge portions (18, 19) being closer to the floor surface (31) than the lower joint edge portions (16, 17), wherein, when the floorboards are pressed against each other in (D2), the two lower joint edge portions (16, said horizontal direction 17) abut each other, the two upper joint edge portions (18, 19) are spaced apart, and one of the upper joint edge portions (18) of a first joint edge (4a) projects above and overlaps a lower joint edge portion ( 16) at a second, adjacent joint edge (4b) 10 15 20 25. (526 596 24 Floating floor according to claim 6, wherein the upper overlapping joint edge portion (18) has a lower limitation whose distance to the floor surface (31) is less than its distance to the upper part of the spring (10). Floating floor according to claim 7, wherein a minimum width (JO 2) of the joint gap is greater than half of a maximum width (JO 1) of the joint gap. Floating floor according to claim 8, wherein the surface layer (31) is made of wood and that the upper overlapping joint edge portion (18) is formed in its entirety by the surface layer. A floating floor according to claim 7, wherein the floorboards have a surface layer (31) of laminate and a core (30) of a wood fiber-based material, the upper joint edge portion (18) being formed in said surface layer and in the upper portions of the core closest to the surface layer, the vertical extent (DG) of the overlapping portion is less than 0.1 times the floor thickness (T).