RU2171877C2 - Building panel joining system - Google Patents

Abstract

FIELD: joining building panels especially thin rigid floating or unfastened floors. SUBSTANCE: adjacent edges at junction of two panels are joined together to form first mechanical joint that secures juncture edges in first direction (D1) perpendicular to main surface of panels. Strip built integral with one juncture edge is provided in addition in each joint and projects beyond other juncture edge. Strip has upward projecting locking member and enters locking slot on rear side of other juncture edge to form second mechanical joint that secures panels in second direction (D2) parallel to main surface of panels and at right angle to joint. Both first and second mechanical joints allow for displacement of joined panels in direction of juncture. EFFECT: enlarged functional capabilities. 8 cl, 13 dwg

Description

 The invention relates generally to a system for joining along adjacent adjacent edges of two building panels, especially floor panels.

 More specifically, the joint of the invention is such that adjacent joint edges form a first mechanical joint fastening the edges of the joint to each other in a first direction at right angles to the main plane of the panels, and where the locking device forms a second mechanical joint fastening the panels to each other in the second parallel to the main plane and at right angles to the joined edges, the locking device contains a locking groove that runs parallel and spaced from the connection edge one oh of the panels, and it is open on the back of this panel.

 The invention is preferably used for joining floor panels, in particular thin multilayer floors. However, it should be noted that the invention can also be used to connect conventional wooden floors, as well as other types of building panels.

 A joint of the type mentioned is known, for example, from Swedish patent N 450141. The first mechanical joint is achieved by connecting edges having tongues and grooves. The locking device for the second mechanical connection contains two inclined locking grooves, with one groove on the back side of each panel and a plurality of spaced spring clips that are distributed along the joint, while their legs are clamped in the grooves and which are displaced so as to firmly clamp flooring panels together. This joining method is particularly suitable for joining thick floor panels to form surfaces of considerable length.

 Thin floor panels with a thickness of approximately 7–10 mm, especially for multi-layer floors, constituted a significant market share in a short period of time. All thin panels used for floors are laid in the form of "floating decks" without fixing them to the supporting structure.

 As a rule, floor panels have a size of 200 x 1200 mm, with long and short sides performed with tongues and grooves. Traditionally, the floor is laid by applying glue into the groove and squeezing the panels together. Then the tongue is glued into the groove of another panel.

 As a rule, a multilayer floor consists of an upper decorative wearing plastic layer having a thickness of about 1 mm, an intermediate aggregate of a particleboard or other plate and a base layer to balance the structure.

 Aggregate has substantially worse properties than laminate, for example with respect to its hardness and water resistance, but nevertheless it is necessary mainly for the formation of a tongue and groove for assembly. This means that the total thickness should be at least about 7 mm. However, these known multilayer floors using glued tongue and groove joints have several disadvantages.

 Firstly, there is a requirement that the total thickness is at least about 7 mm, which entails an undesirable restriction in connection with the laying of the flooring, since it is easier to cope with low thresholds if thin floor panels are used, and the door often needs to be adjusted in height so that it opens freely. In addition, factory-wide overheads are directly related to material consumption.

 Secondly, the aggregate must be made of moisture-absorbing material so that water-based adhesives can be used during flooring. Thus, it is not possible to manufacture thinner floors using the so-called compact laminate due to the lack of appropriate methods for bonding such non-moisture-absorbing aggregate materials.

 Thirdly, since the plastic layer in multilayer floors is highly wear-resistant, wear of the tool is a major problem in surface treatment during sheet pile formation.

 Fourth, the strength of the joint based on glued tongue and groove joints is limited by the properties of the filler and adhesive, as well as the depth and height of the groove. The amount of flooring depends mainly on bonding. In case of poor bonding, the joint will open as a result of tensile stresses that occur, for example, due to changes in air humidity.

 Fifth, flooring strips with glued tongue-and-groove joints is a time-consuming operation, since glue must be applied to each panel on both its long and short sides.

 Sixth, a laid and glued floor cannot be dismantled without breaking the joints. Therefore, removed floor panels cannot be reused. This is a drawback, especially in rental houses where a particular apartment needs to be returned to its original pre-rental state.

 Damaged or worn panels cannot be replaced without excessive force, but such replacement is especially desirable in communal homes and other areas where parts of the flooring are subject to significant wear.

 Seventh, the known multi-layer flooring is unsuitable when their use is associated with a significant risk of moisture penetrating into the moisture sensitive aggregate.

 Eighth, modern solid “floating” or non-fixed flooring requires, prior to the flooring of the panels on a hard black floor, laying a separate underlying layer of plates, felt, polystyrene or the like, which should drown out the sounds from impacts and make the floor more pleasant for walking. Laying the underlayer is a difficult operation, since the underlayer must be placed edge to edge. Various underlying layers affect the properties of the floor.

 Thus, to eliminate the aforementioned disadvantages of the known technical solutions, felt is needed. However, it is not possible to apply the known joining methods by means of glued tongues and grooves for very thin floors, for example with a thickness of about 3 mm, since the joining based on the tongue and groove joint will not be strong enough, and it is practically impossible to form for such thin decks.

 For such thin floors, any other known joining methods are not acceptable. Another cause of problems in the manufacture of thin decks, for example, from compact laminate, is that the thickness tolerances of the panels are about 0.2-0.3 mm for a panel with a thickness of about 3 mm. A 3 mm panel made of compact laminate having such a thickness tolerance will have, if sanded to a uniform thickness on its rear side, an asymmetric arrangement, which will entail the risk of bloating. In addition, if the panels have different thicknesses, this will also mean that the connection will be subjected to excessive load.

 The mentioned problems cannot be eliminated also when using double adhesive tape or the like. on the underside of the panels, since such a connection will immediately adhere and it will not allow subsequent adjustment, as is the case with the conventional gluing method.

The use of U-shaped clamps of the type described in the aforementioned Swedish patent N 450141, or similar methods to eliminate these disadvantages is not an acceptable solution. Movable clamps of this type are not particularly suitable for joining panels of such a small thickness, such as, for example, 3 mm. Typically, floor panels cannot be dismantled without access to their undersides. This known technology, based on the use of clamps, has additional disadvantages:
- the subsequent adjustment of the panels in their longitudinal direction is a complex operation in connection with their flooring, since the clamps make the panels pressed tightly against each other;
- flooring strips using clamps requires time;
- this method can be used only in cases where floor panels lie on the auxiliary beams located below from below with clamps located between them. For flooring of thin floors on a continuous flat supporting structure, such clamps cannot be used;
- floor panels can only be joined together on their long sides. On the short sides there is no clamp connection.

 Thus, the object of the invention is to eliminate these drawbacks and create a system for joining together building panels, especially panels for solid loose ("floating") floors, which allows the use of floor panels of reduced thickness than modern floor panels.

A specific objective of the invention is the creation of a system for connecting panels, which allows a simple, cheap and rational way:
- to form a connection between the floor panels without the need for glue, and especially a connection based mainly only on mechanical joints between the panels;
- to connect floor panels that are thinner than modern multilayer floors and, due to the use of various aggregate materials, have superior properties than modern floors even with a thickness of even 3 mm;
- allows you to create a connection between thin floor panels that eliminates any unevenness in the joint due to tolerances on the thickness of the panels;
- allows you to connect all the edges of the panels;
- reduces tool wear in the manufacture of floor panels with solid surface layers;
- allows re-disassembly and assembly of previously laid strips without damaging the panels, while ensuring high quality flooring;
- allows you to get moisture resistant floors; eliminate the need for precise separate placement of the underlying layer or base to the flooring of the floor panels; and
- significantly reduces the time for connecting panels.

 These and other objectives of the invention are achieved with a system for connecting panels having the features disclosed in the attached claims.

Thus, the invention relates to a system for forming a joint along adjacent connecting edges of two building panels, especially floor panels, according to which:
adjacent edges of the joint form together the first mechanical joint fastening the joint edges to each other in the first direction at right angles to the main plane of the panels,
wherein the locking device located on the rear side of the panels forms a second mechanical connection fastening the panels to each other in the second direction parallel to the main plane and at right angles to the joint, the locking device containing a locking groove that runs parallel to the spacing from the joined edge of one of panels called a panel with a groove, and which is open on the back of the panel with a groove,
moreover, the system is characterized in that: the locking device further comprises a strip made integrally with another panel, called a panel with a strip, and the strip extends essentially along the entire length of the connecting edge of the panel with the strip and is equipped with a locking element protruding from the strip in this way that when the panels are joined together, the bar protrudes on the rear side of the panel having a groove with its locking element received by the locking groove on the panel with the groove;
the panels, when they are joined together, can occupy a relative position in the second direction, in which there is a gap between the locking groove and the fixing surface on the locking element, which faces the connection edges and is effective in the second mechanical connection;
the first and second mechanical connections allow the panels to be mutually displaced in the direction of the edges of the connection, and that the second mechanical connection is made so that it allows the locking element to leave a locking groove if the panels with the groove are rotated around its connection edge at an angle to the side of the bar.

 The term "back side", as used here, includes any side of the panel located behind or under the front side of the panel. Thus, the opening plane of the locking groove in the panel having the groove can be placed at a distance from the rear surface of the panel lying on the supporting structure.

 In addition, the strip, which extends in accordance with the invention along substantially the entire length of the connecting edge of the panel with the strip, should be considered as covering both cases, that is, when the strip is a solid, continuous element and when the strip consists of several parts in its longitudinal direction covering together the main part of the connecting edge.

 It should also be noted that (i) it is the first and second mechanical joints that themselves allow mutual displacement of the panels in the direction of the edges of the joint and that (ii) the second mechanical joint as such allows the locking element to leave a locking groove if the panel with the groove is rotated around its edge connections at an angle to the side of the bar.

 Means, for example, glue, and mechanical devices can also be provided within the scope of the invention to counteract or eliminate such displacement and / or placement at an upward angle.

 The system according to the invention makes it possible to achieve an accurate secret locking of both short and long sides in hard thin floors. Floor panels can be quickly and conveniently disassembled in the reverse order of flooring without any risk of damage to the panels, while at the same time high quality flooring is ensured. Panels can be assembled and disassembled much faster than with known systems, and any damaged or worn panels can be replaced by removing and re-laying parts of the floor.

 In accordance with a particularly preferred embodiment of the invention, there is provided a system for precisely connecting thin floor panels having, for example, a thickness of the order of 3 mm, and at the same time forming a smooth upper surface, regardless of tolerances, at the connection point.

 For this purpose, the bar is placed in a balancing groove, which is recessed on the rear side of the panel with the bar and has an exact predetermined distance from its lower part to the front side of the panel with the bar. The part of the strip that extends beyond the panel with the groove enters the corresponding balancing groove, which is recessed on the rear side of the panel with the groove and has the same exact and predetermined distance from its lower part to the front side of the panel with the groove.

 In this case, the thickness of the strip will be at least so large that the back side of the strip is flush and preferably protrudes slightly below the rear side of the panels. In this embodiment, the panels will always lie at the junction point with their balancing grooves on the bar.

 This allows you to align tolerances and communicate the required strength to the joint. The plank transfers forces directed horizontally and up to the panels, and forces directed down to the existing subfloor.

 Preferably, the plank may consist of a material that is flexible, resilient and durable and can be sawn. The preferred material for the strap is aluminum sheet. In the aluminum strip, sufficient strength can be achieved with a strip thickness of the order of 0.5 mm.

 In order to be able to remove previously laid and connected floor panels in a simple way, a specific embodiment of the invention is characterized in that when the panel with a groove is pressed against the panel with the strip in the second direction and rotated at an angle to the side of the strip, the maximum distance between the axis the rotation of the panel with the groove and the locking surface of the locking groove closest to the edges of the joint is such that the locking element can leave the locking groove without contact with the locking surface of the locking groove. Such dismantling can be achieved even if the aforementioned gap between the locking groove and the fixing surface does not exceed 0.2 mm.

 In accordance with the invention, the locking surface of the locking element is capable of providing a sufficiently strong fastening even at a very small height of the locking surface. An effective connection of 3 mm thick floor panels can be achieved with a fixing surface having a height as small as, for example, 2 mm.

 A locking surface with a height of even 0.5 mm can provide sufficient fastening. The term "locking surface", as used here, refers to the part of the locking element included in the locking groove for the formation of the second mechanical connection.

 For optimal performance of the invention, the bar and the locking element must be made with high accuracy on the panel with the bar. In particular, the locking surface of the locking element should be located at an appropriate distance from the joined edge of the panel with the bar.

 In addition, the contact length in floor panels should be kept to a minimum, as it reduces floor strength.

 The bar can be made with a locking pin by known methods, for example, by extruding aluminum or plastic into an appropriate profile, which is then glued to the floor panel or inserted into special grooves.

 However, these and other traditional methods do not provide optimal performance and an optimal level of savings. To obtain a system for connecting panels in accordance with the invention, a strip is made of aluminum sheet, respectively, and mechanically attached to a panel with a strip.

 The flooring of the panels can be done by first placing the panel with the bar on the black floor and then moving the panel with the groove with its long side facing up to the long side of the panel with the bar at an angle between the main plane of the panel with the groove and the black floor. When the joined edges are brought into contact with each other to form the first mechanical connection, the panel with the groove is placed at an angle downward so that the locking element fits into the locking groove.

 Flooring can also be done by first placing the panel with the bar and the panel with the groove in a flat position on the black floor and then connecting the panels parallel to their main planes, while bending the bar down until the locking element clicks into place in the locking groove.

 This method of flooring strips provides, in particular, the mechanical connection of both the short and long sides of the floor panels. For example, the long sides can be joined together using the first method of flooring a panel having a groove pointing downward at an angle, while the short sides are joined together by moving the panel with the groove in its longitudinal direction until its short side is pressed and closed on the short side of an adjacent panel of the same row.

 In connection with their manufacture, the floor panels can be provided with a base layer or substrate, for example of a floorboard, polystyrene or felt. The base layer should preferably close the bar so that the joint between the lower layers is offset from the joint between the floor panels.

 Mentioned and other features and advantages of the invention will become more apparent from the attached claims and the following description of embodiments of the invention.

 The invention will now be described in more detail with reference to the attached drawings.

 FIG. 1 and 2 show schematically, in two stages, joining together two floor panels of different thicknesses in a "floating" or loose position in accordance with the first embodiment of the invention.

 FIG. 3, 4, 5 show, in three stages, a method for mechanically joining two floor panels in accordance with a second embodiment of the invention.

 FIG. 6-8 show, in three stages, another method for mechanically joining the floor panels of FIG. 3-5.

 FIG. 9 and 10 show a floor panel according to FIG. 3-5, as seen from below and above, respectively.

 FIG. 11 shows in perspective a method of flooring and joining floor panels in accordance with a third embodiment of the invention.

 FIG. 12 shows, in perspective and from below, a first embodiment of mounting a plank on a floor panel.

 FIG. 13 shows a sectional view of a second embodiment of mounting a bar on a floor panel.

 FIG. 1 and 2 show the first floor panel 1, which will be called the panel with the bar, and the second floor panel 2, hereinafter called the panel with the groove.

 The terms “panel with a bar” and “panel with a groove” are intended simply to simplify the description of the invention, while in practice panels 1 and 2 are usually the same. Panels 1 and 2 can be made of compact laminate and have a thickness of about 3 mm with a tolerance of about ± 0.2 mm. Given this tolerance, the thickness of panels 1, 2 is shown as having different thicknesses (Fig. 2), moreover, panel 1 with a bar has a maximum thickness (3.2 mm), and panel 2 with a groove has a minimum thickness (2.8 mm).

 In order to be able to mechanically connect the panels 1, 2 on oppositely located connected edges, usually indicated in positions 3 and 4, the panels are provided with grooves and slats, as will be described below.

 FIG. 1 and 2 and FIG. 9 and 10 show the basic construction of floor panels from below and from above, respectively.

 From the edge 3 of the connection of the panel 1 with the strip, that is, one long side, the strip 6 protrudes at the factory on the lower side of the panel 1 with the strip and runs along the entire edge 3 of the connection.

 The bar 6, which is made of flexible and resilient aluminum sheet, can be mechanically attached using glue or any other suitable method. In FIG. 1 and 2 show that the strip 6 is glued, while in FIG. 9 and 10, it is installed using a mechanical connection, which will be described in more detail.

 Other plank materials can be used, for example sheets of other materials, as well as aluminum and plastic profiles. Or, the bar 6 can be performed in one piece with the panel 1 with the bar. In any case, the strip 6 should be made integrally with the panel 1 having the strip, that is, it should not be installed on the panel 1 with the strip during flooring. By way of non-limiting example, the bar 6 may have a width of about 30 mm and a thickness of about 0.5 mm.

 As can be seen in FIG. 9 and 10, a similar, albeit shorter strip 6 ′, is also formed on one shorter side 3 ′ of the panel 1 with the strip. However, the shorter strip 6 ′ does not extend over the entire shorter side 3 ′, but it is usually identical to the strip 6 and therefore is not described in detail here.

 The edge of the strip 6, facing away from the edge of the connection 3, is made with a locking element 8 extending across the entire strip 6. The locking element 8 has a locking surface 10 facing the edge of the connection 3 and having a height of, for example, 0.5 mm. The locking element 8 is designed so that when the floor is laid and the panel 2 with a bar shown in FIG. 1, press it with the edge 4 of the joint (connecting edge 4) to the edge 3 of the joint (connecting edge 3) of the panel 1 with the bar and place it at an angle on the black floor 12, as shown in FIG. 2, it enters the locking groove 14 formed on the lower side 16 of the panel 2 with the groove 2, extending in parallel and spaced from the edge 4 of the joint.

 As shown in FIG. 1, the locking element 8 and the locking groove 14 together form a mechanical connection securing the panels 1, 2 to each other in the direction D2. More specifically, the locking surface 10 of the locking element 8 serves as an abutment with respect to the surface of the locking groove 14 closest to the edge 4 of the joint.

 When panels 1 and 2 are joined together, they can, however, occupy a relative position in direction D2, where there is a small gap Δ between the fixing surface 10 and the locking groove 14. This mechanical connection in direction D2 allows the panels 1, 2 to be mutually displaced in the direction joint (connection), which greatly simplifies the laying of floors and allows you to connect together the short sides due to fixing due to the snap action.

 As seen in FIG. 9 and 10, each panel in the system has a bar 6 on one long side 3 and a locking groove 14 on the other long side 4, as well as a bar 6 on one short side 3 and a locking groove 14 on the other short side 4.

 In addition, the edge 3 of the junction of the panel 1 with the strap has a groove 20 on its lower side 18, which runs along the entire edge of the joint 3 and forms, along with the upper surface 22 of the strap b, a transverse open recess 24. The connecting edge 4 of the panel 2 with a groove has on its upper side 26, a corresponding recess 28, forming a locking protrusion 30, which should go into the recess 24 to form a mechanical connection, fixing the edges 3, 4 of the junction with each other in the direction D1.

 This connection can be achieved with other designs of the edges 3, 4 of the junction, for example, by beveling them so that the edge 4 of the junction of the panel 2 with the groove extends obliquely downward under the edge 3 of the junction of the panel 1 with the bar for fixing it between this edge and the bar 6.

 Panels 1, 2 can be removed in the reverse order of their location, and without any risk of damage to the connection, and re-lay them.

 The strap 6 is placed in the leveling tolerance of the groove 40 formed on the lower side 18 of the panel 1 with the strap adjacent to the edge 3 of the joint. In this embodiment, the width of the alignment groove 40 is approximately equal to half the width of the strip 6, that is, it is approximately 15 mm.

 Thanks to the leveling groove 40, it is ensured that between the upper side 21 of the panel 1 and the lower part of the groove 40 there will always be a precisely defined distance E, which is slightly less than the minimum thickness (2.8 mm) of the floor panels 1, 2. The panel 2 with the groove has a corresponding leveling tolerance surface or a groove 42 on the lower side 16 of the edge 4 of the joint.

 The distance between the leveling surface 42 and the upper side 26 of the panel 2 with the groove is equal to the exact distance E. In addition, the thickness of the strip 6 is selected so that the lower side 44 of the strip is located to the left below the lower sides 18 and 16 of the floor panels 1 and 2, respectively.

 Thus, the entire joint will lie on the bar 6, and all vertical downward forces will be transmitted to the sufficiently black floor 12 without creating any stress on the joined edges 3, 4. Due to the presence of leveling grooves 40, 42, a completely uniform connection will be achieved on the upper side, despite the tolerances on the thickness of panels 1, 2 without any grinding or the like. operations on all panels. This especially eliminates the risk of damage to the bottom layer of the compact laminate, which can lead to swelling of the panels.

 Now, the embodiment of FIG. 3-5, showing successively substantially the same flooring method as in FIG. 1 and 2. The embodiment shown in FIG. 3-5, differs from the embodiment of FIG. 1 and 2 mainly by the fact that the strip b is attached to the panel 1 with the strip by means of mechanical connection, and not glue.

 To obtain this mechanical connection, shown in more detail in FIG. 12, a groove 50 is formed on the lower side 18 of the panel 1 with the bar at a distance from the recess 24. The groove 50 can be formed either in the form of a continuous groove extending along the entire length of the panel 1, or in the form of several separate grooves.

 The groove 50 forms, along with the recess 24, a gripping edge 52 in the form of a dovetail, the lower side of which has an exact alignment distance E to the upper side 21 of the panel 1 with the bar. The aluminum strip 6 has a plurality of stamped and curved protrusions 54, as well as one or more edges 56, which are bent around opposite sides of the gripping edge 52 in fixing engagement with them. This connection is shown in detail from below in perspective in FIG. 12.

 Or, a mechanical connection between the strip 6 and the panel 1 with the strip can be formed, as shown in FIG. 13, a sectional view in partial cutaway of a panel 1 with a bar turned upside down. As shown in FIG. 13, the mechanical connection comprises a dovetail recess 58 on the lower side 18 of the panel 1 with the bar, and protrusions / edges 60 punched and curved from the bar 6 and pressed against the opposing inner sides of the recess 58.

 The construction shown in FIG. 3-5, further differs in that the locking element 8 of the strip 6 is made in the form of an element bent from an aluminum sheet and having a working fixing surface 10 protruding at a right angle from the front side 22 of the strip 6 to a height, for example, 0.5 mm, and rounded a guide surface 34 facilitating the insertion of the locking element 8 into the locking groove 14 when the panel 2 with the groove is set at an angle downward to the side of the black floor 12 (Fig. 4), as well as the part 36, which is inclined towards the black floor 12 and which is not involved in the flooring method shown ohm in FIG. 3-5.

 Also in FIG. 3-5, you can see that the edge 3 of the junction of the panel 1 with the bar has a small bevel 70, which interacts with the corresponding upper bevel 72 of the edge 4 of the junction of the panel 2 with the groove during flooring so that the panels 1 and 2 are forced to move vertically to the side to each other when their joined edges 3, 4 are moved towards each other, and the panels are pressed together horizontally.

 Preferably, the fixing surface 10 is positioned in this way with respect to the edge 3 of the joint, so that when the panel 2 has a groove starting from the connection position shown in FIG. 5, they are pressed horizontally in the direction D2 to the panel 1 with the bar and rotated at an angle from the bar 6, the maximum distance between the axis of rotation A of the panel 2 with the groove and the locking surface 10 of the locking groove is such that the locking element 8 can leave the locking groove 14 without contact with him.

 FIG. 6-7 show another joining method for mechanically joining together the floor panels of FIG. 3-8. The method shown in FIG. 3-8 is based on the fact that the plank 6 is resilient and is particularly suitable for joining together the short sides of floor panels that are already joined along one long side, as seen in FIG. 3-5.

 The method shown in FIG. 6-8, is carried out by first placing two panels 1 and 2 in a flat position on the black floor 12 and then moving them horizontally towards each other according to FIG. 7. In this case, the inclined portion 36 of the locking element 8 serves as a guide surface that guides the edge 4 of the junction of the panel 2 with a groove to the upper side 22 of the strip 6.

 Then, the strip 6 will be prompted to shift downward, while the locking element 8 slides along the leveling surface 42. After the joined edges 3, 4 are set horizontally in full contact with each other, the locking element 8 will snap into the locking groove 14 (Fig. 8 ), thereby providing the same fastening as shown in FIG. 3.

 The same fastening method can also be applied when placing, in the initial position, the edges 4 of the panel junction with a groove with a leveling groove 42 on the locking element 10 (Fig. 6). In this case, the inclined portion 36 of the locking element 10 does not work. Thus, this method allows you to fix the floor panel mechanically in all directions, and repeating the installation of panels, you can lay the entire floor without the use of any glue.

 The invention is not limited to the specific embodiments described and shown in the drawings, since several variations and modifications are possible within the scope of the appended claims. The bar 6 can be divided into small sections covering most of the length of the connection.

 In addition, the thickness of the strip 6 can vary over its entire width. All the slats, locking grooves, locking elements and recesses are made of such a size that the flooring of the floor panels can be carried out with flat upper sides lying on the bar 6 in connection.

 If the floor panels are made of pressed laminate and if siloxane or other sealing material is used, then a rubber strip or any other sealing means is applied to the panel flooring between the flat protruding part of the strip 6 and the panel 2 with a groove and / or into the recess 26 and obtain a moisture resistant floor .

 As shown in FIG. 12, the base or the underlayer 46, for example of a floorboard, foam or felt, can be placed on the underside of the panels during their manufacture. In one embodiment, the underlying layer 46 closes the strip 6 to the locking element 8, so that the joint between the underlying layers 46 becomes offset from the joint between the joined edges 3 and 4.

 In the construction shown in FIG. 11, the bar 6 and its locking element 8 are made in one piece with the panel 1 with the bar.

Claims (8)

 1. The method of laying and mechanical joining of rectangular building panels, especially floor panels, in rows, said panels being provided with means for mechanically joining their long edges and their short edges in the first direction (D1) at right angles to the main plane of the panels, characterized the fact that the panels are connected, each of which is provided on its rear side with (i) a locking strip on one long edge and one short edge, wherein each locking strip is made or as a separate element, connected with the panel, or in the form of a continuation of the lower part of the connecting edge, extending essentially along the entire length of the corresponding edge and provided with a locking element protruding from the strip, (ii) and a locking groove on the opposite long edge and on the opposite short edge for receiving the locking element of an adjacent panel, each locking groove extending parallel and at a distance from the corresponding edge and open on the rear side of the panel, and that said method includes the following two main docking stations S1 and S2 for laying a new panel: S1: mechanically connect the long edge of the new panel with the long edge of the first panel laid in front of it so that the new panel and the first panel are mechanically joined to each other in the first direction as a result of the first docking step S1 (D1), as well as in the second direction (D2) parallel to the specified main plane and at right angles to the joined long edges, while the first docking stage S1 at the end includes either the substation of placing a new panel in the second row adjacent the specified first row of the long edge of the new panel, equipped with a locking groove located on top and in contact with the locking strip on the adjacent long edge of the first panel, while holding the new panel at an angle to the main plane of the first panel and at a distance from its final longitudinal position relative to that laid before the second panel in the specified second row, as well as the substage of the sequential downward slope of the new panel to place the locking element of the specified strip of the first panel in the locking groove a new panel, or the substation of placing a new panel in the second row adjacent to the specified first row so that the locking strip on the long edge of the new panel fits under the adjacent long edge of the first panel, provided with a locking groove, while holding the new panel at an angle to the main plane the first panel and at a distance from its final longitudinal position relative to the previously laid second panel in the second row, and a substage in which the new panel is turned down to accommodate the locking element the strips of the new panel in the locking groove of the first panel, and S2: mechanically connect the short edge of the new panel with the short edge of the previously laid second panel in the second row to ensure that the short edges of the panels are mechanically joined to each other in the first direction (D1), as well as parallel to the main plane and at right angles to the short edges, while the second main docking stage S2 is carried out by linearly moving the new panel in its longitudinal direction relative to the first panel to achieve the final longitudinal position until the locking protrusion of the strip on one short edge fits into the locking groove of the other short edge, so that the new panel in the final laying position is in two directions mechanically attached with its long edges to the first panel and its short edges to the second panels.  2. The method according to claim 1, characterized in that as a result of the linear displacement of the new panel, the locking strip, located on the short edges to be joined, bends down until the locking element enters with a snap into the locking groove.  3. The method of laying the floor according to claim 1 or 2, characterized in that the short edge of the new panel to be joined with the short edge of the second panel has a locking groove for engagement with the locking element of the second panel.  4. The method according to claim 3, characterized in that the new panel is tilted down to a position where the end part of the new panel facing the second panel is located above and in contact with the locking strip on the short edge of the second panel.  5. The method according to p. 1 or 2, characterized in that the short edge of the new panel to be docked with the short edge of the second panel has a locking strip with a locking element for engaging with the locking groove of the second panel.  6. The method according to any one of claims 1 to 5, characterized in that the indicated substage of tilting down the new panel is carried out by holding the upper corner of the long edge of the new panel in contact with the upper corner of the long edge of the first panel.  7. The method according to any one of claims 1 to 6, characterized in that the new panel after laying and mechanical connection with the first and second panels is raised by jointly tilting the new panel and the second panel upward relative to the first panel and gradually separating the new panel from the second panel by tilting and / or linearly offsetting the new panel with respect to the second panel.  8. The method according to claim 7, characterized in that said step of tilting the new panel and the second panel together with respect to the first panel is performed by holding the upper corner of the long edge of the new panel in contact with the upper corner of the long edge of the first panel.

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