WO2011012104A2

WO2011012104A2 - Covering comprising panels that can be connected to each other mechanically

Info

Publication number: WO2011012104A2
Application number: PCT/DE2010/000803
Authority: WO
Inventors: Guido Schulte; Franz Eschlbeck
Original assignee: Guido Schulte; Franz Eschlbeck
Priority date: 2009-07-27
Filing date: 2010-07-10
Publication date: 2011-02-03
Also published as: DE102009034902B4; PL2459818T3; BR112012001893A2; BR112012001893B1; CN102482886B; DE102009034902A1; CN102482886A; WO2011012104A3; US20120124932A1; EP2459818A2; EP2459818B1

Abstract

The invention relates to a covering comprising panels that can be connected to each other mechanically, and having the following characteristics: - adjacent first and second panels (1, 2) each having a groove (6, 14) on the sides (5, 21) thereof that are complementary to each other, - the grooves (6, 14) each have upper and lower groove sides (7, 8; 17, 26) having different lengths, - in one of the grooves (6, 14) a spring (9, 9a, 9b, 9c, 9d) is arranged that can be moved relative to the panel (1, 2) at least in parts, said spring is suitable for engaging in the corresponding groove (6, 14) of the adjacent panel (1, 2) when the adjacent panels (1, 2) are connected, - the spring (9, 9a, 9b, 9c, 9d) has at least one projection (16, 33, 42, 43), which points in the direction of the area of the longer groove sides (7, 17) of the other groove (6, 14) that protrudes relative to the shorter groove sides (8, 26), - the projection (16, 33, 42, 43) is intended to be moved transversely to the laying plane ( ) of the panels (1, 2) in the event of contact with said area of the groove side (7, 17), wherein the projection (16, 33, 42, 43) is operatively connected to a locking section (13, 29, 32, 35, 41, 47) of the spring (9, 9a, 9b, 9c, 9d), said locking section can be moved in the direction of the groove (6, 14) of the adjacent panel (1, 2) as a result of the motion of the projection (16, 33, 42, 43).

Description

Surface made of mechanically interconnectable panels

The invention relates to a covering of mechanically interconnectable panels.

Wall, ceiling and floor coverings, such as prefinished parquet, real wood floors or laminate flooring, consist of several rows of predominantly rectangular panels in their configuration. Conventionally, the panels have on a longitudinal side and on a head side continuous grooves and on the respective opposite longitudinal side or head side continuous springs, which are adapted to the grooves form-fitting manner. By connecting tongue and groove the panels are laid, the panels of the second adjacent rows are offset from one another.

It is known to form mechanical locking means on the grooves and springs, which engage with one another in a floor covering adjacent panels in latching engagement. As a result, a joint formation in the laid floor covering by expansion or shrinkage operations should be avoided. At the tongue and groove of the panels are adapted to each other locking elements in the form of recesses, recesses or projections to connect floor panels in the assembled situation to keep it glueless. In general, the panels are rotated along their longitudinal sides into each other or clicked and then moved laterally, so that locking strips on the head sides engage. In order to facilitate this, light hammer blows can be applied from the opposite side of the head with the aid of an impact pad. There is a risk that damage to the floor panels may occur even during the most careful work.

There are also solutions in which the abutting head sides are joined together by a spring which can be displaced in its longitudinal direction. This eliminates the manual hammering by means of a hammer. The springs are pre-assembled, eliminating the need for subsequent insertion. Such a floor covering is the subject of WO 2008/017301. In this case, a projecting end of a spring is displaced into a head-side groove in order to partially displace the spring from one groove into the corresponding groove of the adjacent panel. In this way, the panels are locked together.

So that the displaceability of the spring is even possible, it must be kept with a certain amount of play and inserted into the correspondingly precisely aligned opposite groove of the complementary panel. This game is preferably as small as possible so that it does not come to a height offset in the area of the butt joint of two panels. Due to the principle, however, a particular game can not be avoided.

The invention is based on the object to show a covering of mechanically interconnectable panels, in particular a floor covering, wherein the height offset in the region of the butt joint is minimal.

This object is achieved in a covering with the features of claim 1.

The subclaims relate to advantageous developments of the invention. The panels of the flooring according to the invention are intended and adapted to be mechanically connected to other similar panels. The connection is made via arranged on the complementary sides of the panels connecting elements in the form of tongue and groove joints. The adjacent panels each have a horizontal groove on their mutually complementary sides. In one of the grooves, a relative to the panel at least in parts relatively displaceable spring is arranged. The spring engages in connecting the adjacent panels in a groove of the adjacent panel, thus blocking the adjacent panels against vertical displacement against each other. The spring has a holding portion which is disposed in the groove of the spring-holding panel.

The spring has at least one projection. The projection jumps transversely to the laying plane, i. towards the top or bottom of the panels. A projection is given when the projecting portion of the spring is wider than the groove width measured in the region of the projection transversely to the laying plane in the locking position. The projection therefore projects in particular in relation to the holding section of the spring, which is matched to the groove width.

For the orientation of the grooves and thus also the springs arranged there, it is noted that the grooves preferably horizontal, i. in laying level, are oriented. But it is also possible, the grooves and thus the springs inclined, i. at an acute angle to the laying level.

The grooves each have different long upper and lower groove cheeks, so that opposite to the shorter groove cheeks protruding portions of the longer groove cheeks in parallel spaced from each other. These projecting portions of the groove cheeks serve as support surfaces for the projection. Namely, the projection is intended, when in contact with this projecting region of the groove cheek, transversely to the laying plane, that is to say generally perpendicular to the laying plane Panels to be relocated. In other words, the projection or the projecting portion of the spring is not only pushed back in the vertical direction and reduced to the width of the groove between the opposite projecting portions of the longer groove cheeks, but at the same time even in the laying plane, ie horizontally displaced. The horizontal displacement results from the fact that the projection is an integral part of the spring, which is already supported with its one end in the groove, but is configured so that the other end of the spring is displaced in the direction of the laying plane. The projection is thus in operative connection with a locking portion of the spring, which is displaceable by the movement of the projection in the direction of the groove of the adjacent panel.

As a groove in the context of the invention, not only the region is to be understood, which extends between the immediately opposite groove cheeks. It also includes the area that faces the long groove cheek, as this space is also occupied by the spring. The groove cheeks, in particular the longer groove cheeks, can vary in their distance considered over the groove depth. In particular, over the shorter groove cheeks protruding areas of the longer groove cheeks can be set off or offset from the shorter groove cheeks, so that increases the distance to the opposite groove cheek. Nevertheless, the remote areas also count to the groove.

The holding portion may be connected via a connecting portion with the locking portion. Depending on the installation position, the connecting section is preferably connected to the holding section via a hinge arranged on its edge pointing to the top or to the underside of the panel. The locking portion is coupled via a arranged at its diagonally opposite edge joint with the connecting portion. The position of this joint significantly determines the position of the most prominent point of the projection. The spring is at least partially folded before joining two panels in a starting position, said holding portion, connecting portion and locking portion are pivoted about the joints against each other in the vertical direction from the plane of the holding portion out. In order to enable such a folding, mutually facing side surfaces of the holding section, connecting section and locking section are each bevelled in a complementary manner to the top and bottom of the panels.

When connecting two adjacent panels of the projection is displaced by the approach of the longer groove cheeks of the panels. Depending on the installation position, the projection can point up or down. Preferably, the projection is displaced by contact with a lower groove cheek of the groove receiving the locking portion of the first panel. The vertical movement results in a horizontal movement in which the projection on the lower groove cheek slides along the groove receiving the locking portion. This requires a pivoting of the connecting portion about both joints in the horizontal plane of the holding portion. Likewise, the locking portion is pivoted about the hinge of the projection in the horizontal plane of the holding portion. The spring is stretched out of its folded state as soon as the longer groove flanks have approximated as far as possible. This is the case when the height offset between adjacent panels is minimal. The locking portion is pressed by the stretching movement of the spring in the groove of the first panel. In order to facilitate the threading of the connecting portion in the groove, a groove facing end surface of the connecting portion may be chamfered or rounded.

After shifting the locking portion of the spring into the groove of the adjacent panel, the hinge between the locking portion and the connecting portion at the level of the lower groove cheek of the locking portion receiving groove. Retaining portion, connecting portion and locking portion are preferably aligned horizontally after connecting two adjacent panels. Because the lower groove cheek of the spring-retaining groove extends only over a width of the holding portion, are the underside of the panels facing surfaces of connecting portion and locking portion on a lower groove cheek of the locking portion of the spring receiving groove.

In addition to the embodiment described above, it is of course also conceivable to connect individual sections of the spring in the middle. In this case, the edges of the connecting portion and the locking portion facing the underside of the panels form the projection. Likewise, the spring can have further sections in addition to the holding section, the connecting section and the locking section.

Furthermore, embodiments of springs are conceivable in which a projection is coupled to a specific mechanism. This mechanism causes a locking portion of the spring is pressed in the horizontal direction in the groove of the adjacent panel. The mechanism is triggered as soon as the projection comes into contact with a corresponding groove cheek and is displaced in the direction of the other groove flank.

The specific design of the spring also depends on the laying method. in particular, when a panel is not to be stored in a parallel, linear movement, but should be quasi angled by a pivoting movement. During the pivoting movement, the projecting areas of the longer groove flanks approach the length of the groove approached at a certain time to different degrees. Example: In a 45 ° position, the groove flanks at one end of the groove are almost at the end position, while the groove flanks at the other end are at a distance of several centimeters. In particular, in this case, it is expedient to provide either a plurality of spaced-apart springs, which do not hinder in their kinematics. But it is also possible to provide a spring which is divided by transverse to the groove slots in independently operable spring segments. The spring segments preferably have a common holding section. This configuration can be called comb-like. This embodiment proves to be particularly advantageous when the second panel, starting at one end of the groove, is lowered in the longitudinal direction of the groove, so that the spring sections engage one after the other in the groove of the first panel. Independently actuable spring segments can also be used in any other type of laying, ie even if the panels are not pivoted to each other, but are stored in a parallel movement.

The locking portion may have a profiling on its side facing the upper and / or lower groove cheek side surface. The connecting portion may as well as the locking portion have a profiling on one or both side surfaces. This profiling may, for example, be wavy, have individual points or a sawtooth profile.

The groove cheeks of the panels can have a profiling complementary to profiling. It is also possible to provide on one or both side surfaces of the locking portion locking elements which engage in insertion of the locking portion in the groove of the adjacent panel in corresponding recesses of the upper or lower groove cheek.

It is important that the locking section bridges the gap adjoining the shorter groove cheek to the adjacent longer groove cheek of the other groove in order to minimize the height offset in the region of the butt joint of the panels. The locking portion must therefore partially protrude from the groove receiving it, that is over the shorter groove cheek this groove.

In principle, the spring can extend over the entire length of the groove. In addition, a plurality of springs can be provided in the longitudinal direction of the groove at a distance from each other. These may have independently operable locking portions. This is how panels can be put in too Arrange longitudinally offset the groove to each other. It is conceivable to connect the holding portions in the region of the groove with each other, wherein the compound can be used simultaneously as a spacer between the springs.

On one of the panels a locking strip is provided, which serves to secure the adjacent panels against tensile stress in a laying plane. The locking bar thus serves to couple the panels in the laying plane, while the springs are intended to prevent the panels from shifting relative to one another in the vertical direction. Since the locking strip which engages under the adjacent panel, is arranged at a relatively large distance from the top of the panels, it is additionally provided that the attacked by the locking bar panel is primarily supported on a support strip. This is arranged at a greater distance from the locking bar than the groove. In other words, the groove is between the support bar and the locking bar. The support bar has the function of reducing the distance of the support point from the top of the panels, which is particularly advantageous for very thin-walled and softer materials. Due to the proximity of the support bar to the top of the panels, vertical forces acting at a point in the vicinity of a butt joint, which act on the underreached panel, are introduced in a shorter way into the adjacent underarching panel than is possible via the lower located locking bar. Due to the support in the immediate vicinity of the force application point of the height offset between two panels in the load case is much lower.

Overall, the spring can consist of a uniform material. Correspondingly thin areas can serve as film hinges. The thicker areas then serve to accommodate the forces acting transversely to the laying plane.

The material for the spring may be both a wood material, that is, it may be wood or a material containing wood fibers, or a material made of wood as a base material, such as liquid wood. Metal and metal alloys, such as spring steels, are suitable for the springs as well as composite materials. The use of bimetallic or mixed plastics is just as possible as the use of materials based on thermoplastic or thermosetting plastics. The spring can also consist of a fiber-reinforced plastic. Preferably, the spring is elastic.

The spring may be designed to be biased prior to connection. Due to the bias of the locking portion is pressed into the groove of the adjacent panel and additionally secured the connection of two panels.

Springs with restoring forces due to elasticity or because e.g. a spring steel was used, are suitable to retract the spring after opening the connection back to the starting position or jump back.

The joints connecting portions of the spring are preferably made of the same material as the spring. Of course, it is also possible to choose a different material for this purpose, for example a kind of hotmelt. Hotmelt is to be understood as meaning hotmelt or hotmelt adhesives which are based, for example, on polymers, resins or waxes and still have a flexibility after cooling. The basic idea is based on a functional separation of elastic and non-elastic areas. While the hinged areas require deformable materials, deformation of the locking portion is undesirable. Therefore, a material of lower elasticity should be used for the locking portion, as in the region of the joints, or the connecting portion.

A special feature are springs, which can assume two states. The spring can assume a stable position and a metastable position, from which the spring automatically returns to the stable state upon termination of the force. Also, a bistable spring is provided which is characterized by the fact that two stable positions exist and every change from one position to another presupposes a force.

The spring with a metastable position is transferred from the stable position to a metastable position by the process of buckling, the restoring force being much less from the metastable position to the stable position than vice versa. This favorable force-displacement characteristic can also be utilized in the present invention. The bulge is equivalent to a projection on the spring, which is to be relocated. The projection is displaced until the spring jumps abruptly into the metastable position. This is the locking position. By a clicking sound, as it occurs in springs made of metal or at least in bumps made of metal, the locking position is also audible. But it also turns a slight jerk when the locking position is reached. The haptic information as well as the acoustic information of the so-called clicker effect are helpful feedback when laying and also when picking up the panels. As far as materials are concerned, the clicker effect primarily occurs with metallic materials. However, the principle is also compatible with other bulking materials, such as e.g. Plastics feasible.

There is no restriction with regard to the material of the panels, as long as this can be brought into the necessary form, in particular by machining. These can be panels based on wood-based materials or plastics, as well as mineral materials and composite materials. The size of the panels also plays a minor role. The panels may also be large in size, e.g. as component plates of 600 mm x 1500 mm.

The inventive concept is particularly applicable to all floor systems in which an upper covering is arranged on a support, such as real wood coverings, laminate, support with painted surfaces as top coat, linoleum, cork on support plates, etc. The cover layer can in particular a decorative paper with overlay, which determines the appearance of the element plate. A floor covering may thus be a parquet floor, a finished parquet floor, a real wood floor or a laminate floor.

The floor covering may in particular also be a raised floor or a hollow floor in which below the covering, i. below the panels is a cavity that is used for the wiring. Especially in these raised floors, it is advantageous if individual panels can be resumed, which is very feasible with the invention. Since said springs can be provided not only on head sides but also on longitudinal sides of a panel, it is possible to provide individual panels e.g. Lift again by a siphon and then put it down again.

The invention will be explained in more detail with reference to embodiments shown in the schematic drawings. Show it:

Figures 1a to 1c respectively in cross section a section of the

Connecting area of two adjacent panels, in different mounting positions and

Figures 2a to 7b and 8 respectively different embodiments of the spring.

FIG. 1a shows a cross section through the connecting region of two panels 1, 2. The panels 1, 2 are configured so that the panels 1, 2 can be assembled into a floor covering. The panels 1, 2 have an underside 3 facing the panel background and an upper side 4 facing away from the panel background. The illustration shows a left first panel 1 and on the right a second panel 2, before joining both panels 1, 2. The second panel 2 points its, in a laying position facing the first panel 1 head side, which is hereinafter referred to as page 5, a extending in the horizontal direction groove 6. In this case, an upper groove cheek 7 is wider than a lower groove cheek 8. In the groove 6, a spring 9 is arranged.

The spring 9 is arranged with its holding portion 10 in the groove 6. The holding portion 10 is coupled with its opposite the lower groove cheek 8 protruding, pointing to the top 4 of the panel 2 edge with a connecting portion 11. The coupling of holding portion 10 and connecting portion 11 is effected by a joint 12. This joint 12 is designed in this embodiment as a film hinge. It consists of the same material as the spring 9 and can be manufactured with this in one production step. Adjoining the connecting section 11 is a locking section 13, which is provided to engage with a groove 14 of the first panel 1 complementary to the groove 6 of the second panel 2. The locking portion 13 is connected to the connecting portion 11 via a hinge 15, which is also designed here as a film hinge. The joint 15 is arranged between two edges of the locking section 11 and of the connecting section 13 facing each other and towards the underside 3 of the panels 1, 2. The connecting portion between locking portion 11 and connecting portion 13 forms with the hinge 15 a relative to the groove 6 of the second panel 2 in the direction of the bottom 3 of the panels 1, 2 projecting projection 16. The facing side surfaces of holding portion 10, connecting portion 11 and locking portion 13 designed such that the spring 9 is quasi folded in an initial state by the connecting portion 11 relative to the holding portion 10 and the locking portion 13 relative to the connecting portion 11 from the horizontal plane E of the holding portion 10 are pivoted out.

The projection 16 comes when connecting the first panel 1 with the second panel 2 with a lower groove cheek 17 of the Verrieglungsabschnitt 13 receiving groove 14 in contact (Figure 1b). Upon further displacement of the second panel 2 in the direction of the arrow P, the projection 16 is pressed by the lower groove cheek 17 in the direction of the upper side 4 of the panel 2. In this case, connecting portion 11 and locking portion 13 are pivoted about the joints 12, 15 against each other from the folded position in a horizontal plane E of the holding portion 10. The locking portion 13 protrudes beyond the length of the upper groove cheek 7 and engages in the groove 14 of the adjacent first panel 1 a.

The first panel 1 engages with a locking bar 18 on the underside of the second panel 2. The second panel 2 has for this purpose a downwardly open dome channel 19 and an adjoining, downwardly directed, end Kuppelwulst 20. The locking bar 18 of the first panel. 1 is opposite to a designated as side 21 head side horizontally before, so that the Kuppelwulst 20 engages in the upwardly open coupling channel 22 of the locking bar 18. At the dome channel 22, the locking bar 18 connects at the end of an upwardly directed Kuppelwulst 23, which engages in the mounting position in the associated dome channel 19 of the second panel 2. Due to the undercut of Kuppelwülste 20, 23, the two panels 1, 2 in the laying plane V, that is secured in the horizontal direction of the laid flooring, against displacement. The fact that the Kuppelwülste 20, 23 abut each other in its contact area 24 obliquely to the laying plane V, is when swinging down the second panel 2 in the direction of the arrow P on the already laid first panel 1, the second panel 2 with his, to the side 21 of the first Panel 1 complementary side 5 pulled against the first panel 1, so that the sides 5, 21 of the panels 1, 2 abut each other.

In addition to the contact between the Kuppelwülsten 20, 23, the second panel 2 is located on a support bar 25 above a groove 14. The support strip 25 is thus located at a smaller distance from the top 4 of the left panel 2 as the locking bar 18 on which the Panel 2 is usually supported in the vertical direction. Due to the smaller distance of the support strip 25 to the top 4 tighter tolerances can be met, so that with this solution, any height offset between the panels 1, 2 can be minimized. The support strip 25 immediately adjoins the groove 14, so that its lower edge is part of an upper groove cheek 26 of the groove 14. The support strip 25 thus extends together with the locking portion 13 of the spring 9 receiving groove 14th

The panels 1, 2 preferably touch each other at certain support and support points. The locking bar 18 and the Kuppelwulst 20 touch in this embodiment, only in the above-described contact area 24. However, the remaining space between the locking bar 18 and the Kuppelwulst 20 are so small gaps that with extreme vertical load and a touch can not be excluded due to the limited elasticity of the materials. Due to the free space also manufacturing tolerances can be compensated.

The locking portion 13 extends in the locking position shown in Figure 1c from the left groove 14 and thus bridges the gap between the adjacent upper groove cheeks of the left and the right groove 14, 6th

For reasons of clarity, the reference numerals of FIGS. 1a to 1c have been adopted for the panels 1, 2 in FIGS. 2a to 5b described below, but this does not exclude that the panels 1, 2 in the specific embodiments due to the adaptation to the various Springs may differ slightly in their design.

In addition, the panels 1, 2 are shown only partially below. However, they all have the locking strip described in FIGS. 1a to 1c as well as coupling channels and coupling beads

FIG. 2 a shows a further embodiment of a spring 9 a arranged in a second panel 2. The spring 9a is fixed with a holding portion 27 in a groove 6 of the second panel 2. Which is attached to the holding section 27 subsequent connecting portion 28 is arcuately curved. In this case, the arcuate connecting portion 28 forms a projection 16a, which protrudes in the direction of the bottom 3 of the panel 2 and in the direction of the bottom 3 opposite the lower groove cheek 8 of the spring 9a holding groove 6. The adjoining the connecting portion 28 locking portion 29 is aligned approximately transversely to the longitudinal direction of the groove 6. Of course, spring designs are also possible on which an end section of the connecting section facing the adjacent panel forms the locking section.

When joining two adjacent panels 1, 2, the bent connecting portion 28 is displaced by a lower groove cheek 17 of the groove 14 of the first panel 1 in the direction of the upper groove cheek 7 of the groove 6 of the second panel 2. Characterized the curved connecting portion 28 of the spring 9a is flattened and the locking portion 29 is pushed transversely to the longitudinal direction of the groove 6 in the groove 14 of the first panel 1. The spring 9a is quasi stretched. The bent connecting portion 28 is compressed between the lower groove cheek 17 of the groove 14 of the first panel 1 and the upper groove cheek 8 of the groove 6 of the second panel 2. The spring 9a is thereby biased longer and due to their elasticity when connecting the adjacent panels 1, 2. Thus, the spring 9a is biased and sits non-positively in the opposing grooves 6, 14 of the panels 1, 2 (Figure 2b).

FIG. 3 a shows a further embodiment of a spring 9 b made of an elastic material. The spring 9b is divided into three sections. In this case, in each case between the holding portion 30 and the connecting portion 31 and between the connecting portion 31 and the locking portion 32, a projection 33 is provided. The projections 33 project toward the underside 3 of the panel 2 via the lower groove cheek 8 of the groove 6 of the second panel 2. Both projections 33 are opposite, so arranged on the side facing the top 4 of the panel 2 side of the spring 9b, a recess 34. The recess 34 can, as shown here, a have triangular cross-section. Semicircular or rectangular cross sections are also conceivable.

When connecting two adjacent panels 1, 2 presses the lower groove cheek 17 of the groove 14 of the first panel 1, the projections 33 toward the upper groove cheek 7 of the groove 6 of the second panel 2. Due to the elastic material used here, the material urges to the top 4 pressed projections 33 in the respective opposite recess 34 and the spring 9b expands transversely to the longitudinal direction of the groove 6 from. Due to the expansion of the locking portion 32 enters the groove 14 of the first panel 1. Since a height H of the grooves 6, 14 of the first panel 1 and second panel 2 does not change after connection, the pressure of the lower groove cheek 17 remains on the Projections 33 are made, the spring 9b remains stretched and sits non-positively in the grooves 6, 14 of the panels 1, 2 (Figure 3b).

In a further embodiment (Figure 4a) connecting and locking portion 35 of the spring 9c are made in one piece. In this case, a free space 36 extending in the longitudinal direction of the groove 6 is provided in the connection and locking section 35. Of course, in alternative embodiments, several open spaces are conceivable. The holding portion 37 connected to the connecting and locking portion 35 is disposed in the groove 6 of the second panel 2.

On the underside 3 of the panels 1, 2 facing side of the spring 9c a projection 16b is arranged in the region of the free space 36, which protrudes in the direction of the bottom 3 of the panels 1, 2 on the lower groove cheek 7 of the groove 6 of the second panel 2 , The projection 16b is formed by a relative to the height H of the groove 6 widened region of the connecting and locking portion 35. The spring 9 c is made of an elastic material, so that when joining two panels 1, 2, the projection is pressed by the lower groove cheek 17 of the groove 14 of the first panel 1 upwards toward the upper groove cheek 8 of the groove 6 of the second panel 2 , Due to the elasticity of the spring 9 c, the widened area of the Connecting and locking portion 35 in its width to the height H of the groove 6 of the second panel 2, and the groove 14 of the first panel 1 is reduced. The here circular cross-section of the free space 36 becomes an ellipse, which results in an extension of the locking and connecting portion 35 transversely to the longitudinal direction of the groove 6. Due to the extension of the locking and connecting portion 35 enters the groove 14 of the adjacent first panel 1 and is held there non-positively (Figure 4b).

FIG. 5a shows an exemplary and schematic illustration of a spring 9d with a locking mechanism. In this case, the spring 9d has a holding portion 38, with which it is held in the groove 6 of the second panel 2. The holding portion 38 has a biased in the initial position spring element 39. The holding portion 38 is connected to the locking portion 41 via a connecting portion 40. The connecting portion 40 has a relation to the lower groove cheek 8 of the groove 6 of the second panel 2 in the direction of the bottom 3 of the panels 1, 2 protruding projection 42, via which it is held simultaneously with the prestressed spring element 39 of the holding portion 38 in the starting position.

When connecting two panels 1, 2, the projection 42 is displaced by the lower groove cheek 17 of the groove 14 of the first panel 1 in the direction of the top 4 of the second panel 2. Thereby, the holder of the connecting portion 41 is released and the spring force F of the spring element 39 acts on the connecting portion 41, which in turn acts on the locking portion 42 and this in the groove 14 of the first panel 1 hineinverlagert. The spring force F of the spring element 39 acting transversely to the longitudinal direction of the groove 14 causes a frictional fit of the locking section 42 in the groove 14 of the first panel 1 (FIG. 5b).

The spring 9e in the embodiment of Figures 6a and 6b shows an alternative embodiment to the spring 9 in Figures 1a to 1c. Here is a relation to the lower groove cheek 8 of the groove 6 of the second panel. 2 projecting projection 43 formed by a first portion 44 of the two-part connecting portion. The first portion 44 is connected to the locking portion 47 and to the second portion 48 of the connecting portion via a hinge 45, 46, respectively. The second portion 48 of the connecting portion is connected via a further hinge 49 with the holding portion 50 of the spring 9 e. All hinges 45, 46, 49 are arranged on a side surface of the spring 9e facing towards the underside of the second panel 2. The first section 44 is arranged in a plane parallel to the plane E of the holding section 50. The locking portion 47 and the second portion 48 are inclined relative to the plane E of the holding portion 50.

When connecting two adjacent panels 1, 2, the projection meets the lower groove cheek 17 of the groove 14 of the opposite first panel 1 and is displaced with further lowering of the second panel 2 in the direction of the arrow P to the top 4 of the panels 1, 2 out. As a result of this displacement, the first section 44 is moved into the plane E of the holding section 50. In this case, the locking portion 47 is displaced into the groove 14 of the adjacent first panel 1. If the spring 9e is already preloaded before the panels 1, 2 are connected, the panels 1, 2 are additionally braced against each other by the residual stress of the spring 9e.

Figures 7a and 7b show an embodiment in which the spring 9, as shown in Figure 1 has been rotated by 180 ° and is now arranged in the left panel 1 instead of in the right panel 2. The holding portion 10 is now in the left groove 14. The locking portion 13 is to be inserted into the right-hand groove 6. The projection 16 faces upwards and no longer downwards.

With regard to the further function, reference is made to the explanation of FIGS. 1a to 1c, since in FIG. 7 only the orientation and assignment of the spring has changed. The example of Figure 7 is representative of the possibility also to modify all other embodiments shown with respect to the mounting location of the spring. It is therefore possible in all variants also to turn the spring by 180 ° and to mount in the corresponding groove of the other panel.

The embodiment of Figure 8 is a modification of the embodiment of Figure 2b. The spring can be converted in this variant in the illustrated metastable state. The stable state substantially corresponds to the representation in FIG. 2a with the difference that the curved connecting section is designed as a bulge. This bulge is pushed back over a tipping point so far that the connecting portion 28 is issued in the other direction. For this purpose, a corresponding recess 51 in the upper groove cheek 7 and an upwardly projecting pusher 52 is provided on the lower groove cheek 17.

The geometry of the spring is shown and described rectangular in all embodiments. However, the invention does not preclude providing springs of other geometries, so that the illustrated and described shape is representative of other geometries.

Reference numerals:

1 - panel

2 - panel

3 - bottom

4 - top

5- page

6- groove

7 - upper groove cheek

8 - lower groove cheek 9- spring

9a - spring

9b spring

9c spring

9d - spring

9e - spring

10- holding section

11 - connecting section

12- joint

13- locking section

14- groove

15- joint

16- lead

16a advantage

16b lead

17 - lower groove cheek

18 - locking strip

19- dome channel

20- dome bulge

21 - page

22- dome channel - dome bulge

- Contact area

- Support bar

- groove cheek

- Holding section

- Connection section

- Locking section

- Holding section

- Connection section

- Locking section

- Head Start

- recess

- Locking and connecting section - free space

- Holding section

- Spring element

- Connection section

- Locking section

- Head Start

- first section

- joint

- Locking section

- second part

- joint

- Holding section

- recess

- pusher E - level

V-laying level

P- arrow

H-height

F - spring force

Claims

claims

1. covering of mechanically interconnectable panels, having the following features: a) adjacent first and second panels (1, 2) have at their mutually complementary sides (5, 21) each have a groove (6, 14), b) the grooves (6, 14) each have differently long upper and lower groove cheeks (7, 8, 17, 16), c) in one of the grooves (6, 14) is a spring, which is relatively displaceable relative to the panel (1, 2), at least in part (9, 9a, 9b, 9c, 9d), which is adapted to engage in connecting the adjacent panels (1, 2) in the corresponding groove (6, 14) of the adjacent panel (1, 2), d) the spring (9, 9a, 9b, 9c, 9d) has at least one projection (16, 33, 42, 43), which in the direction of the opposite to the shorter groove cheeks (8, 26) projecting portion of the longer groove cheeks (7, 17) of the other Groove (6, 14) points, e) the projection (16, 33, 42, 43) is provided, when in contact with this region of the groove cheek (7,17) transversely to the laying plane () of the Pane ele (1, 2), said projection (16, 33, 42, 43) operatively associated with a locking portion (13, 29, 32, 35, 41, 47) of said spring (9, 9a, 9b, 9c , 9d), which, due to the movement of the projection (16, 33, 42, 43), in the direction of the groove (6, 14) of the adjacent panel (1, 2) is displaceable.

2. Covering according to claim 1, characterized in that the projection (16, 33, 42, 43) on a relative to the locking portion (13, 29) and a holding portion (10, 27) of the spring (9, 9a) displaceable connecting portion (11, 28) is formed.

3. Covering according to claim 1 or 2, characterized in that the locking portion (13, 29) in the locking position, a gap between the short groove flank (6, 26) of the receiving groove (6, 14) and the adjacent, longer groove flank (7, 17) of the other groove (6, 14) bridged.

4. Covering according to claim 2 or 3, characterized in that the connecting portion (11, 28) is pivotally connected to the locking portion (13, 29) and / or the holding portion (10, 27).

5. covering according to claim 4, characterized in that joints (12, 15, 45, 46, 49) between the connecting portion (11) and the locking portion (13, 47) and / or between the connecting portion (11) and the holding portion ( 10, 50) have a parallel to the groove (6, 14) extending pivot axis.

6. covering according to claim 4 or 5, characterized in that the joints (12, 15, 45, 45, 49) are film hinges.

7. Covering according to one of claims 4 to 6, characterized in that the joints (12, 15) between mutually facing edges of holding portion (10), connecting portion (11) and locking portion (13) are arranged.

8. Covering according to one of claims 4 to 7, characterized in that the joints (12, 15, 45, 46, 49) made of the same material as the other parts of the spring (9, 9e).

9. covering according to one of claims 4 to 7, characterized in that the joints (12, 15, 45, 46, 49) made of a different material than the other parts of the spring (9, 9e).

10. covering according to claim 9, characterized in that the joints consist of hotmelt.

11. Covering according to one of claims 1 to 9, characterized in that the spring (9, 9a, 9b, 9c, 9d, 9e) consists of an elastic material.

12. A covering according to any one of claims 1 to 11, characterized in that the locking portion (13, 29, 32, 35, 41, 47) consists of a material of lower elasticity than other parts of the spring (9, 9a, 9b, 9c, 9d, 9e).

13. Covering according to one of claims 1 to 12, characterized in that the spring (9, 9a, 9b, 9c, 9d, 9e) a plurality of at a distance in the longitudinal direction of the groove (6, 14) arranged mutually, independently operable locking portions (13, 29, 32, 35, 41, 47).

14. covering according to claim 12, characterized in that the holding portions (10, 27, 30, 37, 38, 50) of a plurality of springs (9, 9a, 9b, 9c, 9d, 9e) in the region of the groove (6, 14) are connected.

15. Covering according to one of claims 1 to 14, characterized in that the locking portion (13, 29, 32, 35, 41, 47) of the spring (9, 9a, 9b, 9c, 9d, 9e) at its to the top of the Panel (1, 2) facing side surface and / or on its side facing the underside of the panel (1, 2) side surface has a profiling.

16. Covering according to one of claims 1 to 15, characterized in that the groove (6, 14) for receiving the locking portion (13, 29, 32, 35, 41, 47) of the spring (9, 9a, 9b, 9c, 9d, 9e) has a profiling on its upper and / or lower groove cheeks (7, 8, 17, 26).

17. Covering according to claim 16, characterized in that the profiling of the locking portion (13, 29, 32, 35, 41, 47) engages in the profiling of the groove (6, 14).

18. Covering according to one of claims 1 to 17, characterized in that parts of the spring can assume two states, one state is a stable state and the other is a stable or metastable state.