DE102011052711A1 - Surface made of mechanically interconnectable panels - Google Patents

Abstract

Cover made of mechanically interconnectable panels, wherein the panels (1, 2, 38) have on their opposite sides a corresponding profiling and are locked together by this profiling, wherein on a core (15) of the panels (1, 2, 38) a Spring (11, 11a-f) is arranged, which is displaceable via a joining movement behind a substantially horizontally extending locking edge (17) of the adjacent panel (1, 2, 38). The panels (1, 2, 38) have a multilayer structure with a core (15) made of an elastic material from which the spring (11, 11a-f) is integrally formed integrally with the core (15).

Description

The invention relates to a covering of mechanically interconnectable panels according to the features of claim 1.

Wall, ceiling and floor coverings, such as parquet flooring, 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 through grooves and on the respectively 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 two adjacent rows are arranged 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. Adjacent to the tongue and groove of the panels are mating locking elements in the form of recesses, recesses or projections to hold bonded floor panels in the assembled position 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.

There are also solutions in which the abutting head sides are joined together by a spring which can be displaced in its longitudinal direction. The springs are pre-assembled. An overhanging end of the spring in a head-side groove is displaced into the groove to partially displace the spring from one groove into the corresponding groove of the adjacent panel so as to lock the panels together. The displaceability of the spring requires a certain amount of play, but this is to be kept as low as possible so that there is no height offset in the area of the butt joint of two panels.

In these types of locking systems, the springs are made of a different material than the panels. However, if the springs are integral with the unitary material of the panel, there are some constructive limitations, so that the springs do not break. This is particularly relevant with respect to the usual floor panels having a core of wood chip material, for example MDF or HDF, which as such have only limited elasticity.

Plastic floor coverings are usually made of PVC in the form of individual tiles or panels that are glued together. The impact sound transmission behavior of PVC floors is better due to the softer material compared to MDF or HDF, but the use of adhesives is required to bond the individual panels to the ground.

The invention has for its object to show a covering of mechanically interconnectable panels, which can be laid faster than with the substrate to be bonded panels, but still has an improved impact sound transmission behavior.

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

The subclaims relate to advantageous developments of the inventive concept.

In the covering according to the invention of mechanically interconnectable panels, the panels have on their opposite sides a corresponding profiling. About this profiling, the abutting sides are locked together.

The panels have a core on which a spring is arranged, which is displaceable via a joining movement behind a substantially horizontally extending locking edge of the adjacent panel. The core consists of a soft, elastic material from which the spring is formed integrally with the material in one piece with the core. The panels have a multilayer structure.

Characterized in that the spring is formed integrally with the core, so does not have to be connected by a separate manufacturing step with the core and not made of a different material than the core itself, the production of such panels is relatively inexpensive. The separate insertion of springs in the grooves deleted. Consequently, the installation of a floor covering can be done with relatively little effort. It is not necessary to stick the surface to the substrate. The problems resulting from the bonding, such as vapor diffusion caused by the adhesive layer or by rising moisture from the soil, are avoided.

Elastic materials according to the invention are in particular plastics, especially thermoplastics. By mixing different plastics, by varying the reaction conditions or adding additives, the elastic material properties can be adjusted become. Decisive in the use of plastics in the soil area is that the plastics can deform under load, but on discharge relieve their original shape, so do not tend to cold flow or are brittle. Thermosets are therefore out of the question. The group of thermoplastic materials includes polyvinyl chloride (PVC), polypropylene (PP), polyethylene (PE), polystyrene (PS), polycarbonates (PC) and polyacetals (POM).

A material that is flexible without breaking is PVC. Consequently, PVC and plasticizer-containing plastics as well as plasticizer-free systems with analog mechanical properties are particularly suitable.

It may also be, for example, mixtures of fibrous or granular materials with PVC or plasticized plastics. The granular materials may be mineral materials such as carbonates such as limestone or dolomite. The mineral material may consist wholly or partly of calcium sulfate, namely gypsum. According to the invention, however, the core is more elastic, more flexible and thus less brittle in comparison to pure fibreboard or gypsum boards.

In an advantageous embodiment of the invention, the spring is pivotable behind the locking edge, wherein the spring to achieve the locking position is at least partially elastically deformed and remains elastically deformed after reaching the locking position.

The elastic deformation of the spring or the exploitation of this material property of the spring is an essential feature of the locking system according to the invention in connection with the fact that the spring is of uniform material integral part of the core. In the context of the invention, a partially elastic deformation does not mean that the spring, comparable to a tight fit or a press fit, only slightly biased and therefore more likely to be compressed. Rather, it is necessary to change the spring in shape so far that the locking position can be achieved at all. For this purpose, parts of the spring must be significantly deformed, but all deformations should move in the elastic and preferably in the fully reversible area.

This can be achieved, in particular, when the spring in the unlocked position has a substantially arcuately curved course at least in sections and is provided in total elastically when being joined to the adjacent panel by contact with the adjacent panel in the region of its at least one arcuately curved profile deformed and thereby stretched in length. In this case, the spring engages in the extended position, a locking edge of the adjacent panel. This means that the spring in the unlocked position has a shorter length than in the locked position, that is in its extended position. The extension can be made by the accurate insertion of the spring into corresponding recesses of the profiling. The spring is thereby brought into the stretched shape, elongated and thereby transferred to a locking state in which the panels are held together.

The extension or elongation of the spring can only take place on a partial region of the spring, for example by displacing the regions of the spring further spaced from a straight central longitudinal axis of the spring in the direction of the central longitudinal axis. This can be done by flattening a projection in the form of an arc. One can compare this process with a buckling of a body, wherein in the initial state, a bulge is present, but not in the locked state in which the spring is stretched or elongated.

The spring can have several functional sections. In particular, the spring has at its panel-side end a connecting portion. At its other, free end, it may have a locking portion. The connecting portion and the locking portion may be connected to each other via a hinge portion. The joint section may in particular be a film joint. The joint section is therefore characterized by a smaller wall thickness in comparison to the connecting section or locking section.

The locking portion is adapted in its configuration to the profiling of the panel with which the locking portion engages. The joint portion is thus optimized independently of the configuration of the locking portion on the function of the joint, while the connecting portion provides a captive grip of the spring on the core.

Alternatively to the above-described possibility of stretching the spring by straight bending of a curved shape, another possibility is to provide a spring having cavities. These cavities can be reduced in locking, so that the spring lengthens to reach behind the locking edge. The cavities are preferably connected to the atmosphere. This can not counter pressure being constructed. This facilitates the shrinking of the cavities.

The springs are preferably longitudinally channeled with respect to the orientation spaces. That is, the cavities are parallel to the locking edge. The functional principle in the cavities is similar to a curved spring, namely, that the respective areas which are located at a greater distance from the central longitudinal axis of the spring, are displaced towards the center. This displacement process is particularly simplified if the material to be displaced spring does not encounter resistance. An open cavity thus simplifies the displaceability of the spring. As well as at least partially arcuately curved springs of the arc shape in particular a trough opposite, in which the sheet can be moved. Under an arcuately curved spring are also multi-angled or undulating springs to be understood, which also lead to a stretching of the spring after leveling of the wave crests and troughs.

In order to improve the latching with adjacent panels, the locking portion may have on its top and bottom of the panel facing side a profiling, which corresponds to a profiling in a groove of the adjacent panel. This profiling may, for example, be wavy, have individual points or a sawtooth profile.

The springs can have a geometry that can be converted by elastic deformation during locking from a stable to a metastable state in which the spring is stretched by bumps. The metastable state can be left by little force. The spring snaps back and bulges out new. Therefore, different large actuating forces are necessary to get from the stable to the metastable state and vice versa. The bulge of the spring is to be equated with a laterally projecting projection on the spring, which is to be displaced similar to an arcuate spring. The projection is displaced until the spring jumps abruptly into the metastable position. This is the locking position. By a crackling sound, as it occurs with spring made of metal or at least at bumps made of metal, the locking position is also acoustically determined. It also turns a slight jerk when the locking position is reached. The haptic information of the so-called clicker effect is a helpful feedback when laying and also when picking up the panels.

Thus, the spring is deformed during locking, it is provided that it is supported on a support surface of the opposite panel. Depending on the design of the spring, the support surfaces can run parallel to the laying plane. It is also conceivable that the support surface is inclined relative to the laying plane and causes a horizontal displacement of the spring behind the locking edge. It is also conceivable, depending on the connection of the spring to the core, that the displacement of the spring takes place exclusively in the direction of the adjacent panel. This is for example the case when the spring is oriented perpendicular to the laying plane, that is, with its upper end facing towards the top of the panel and facing with its free lower end towards the bottom of the panel. The lower, free end can thus be pivoted in the direction of the laying plane. When the free end or the spring strikes a support surface inclined relative to the laying plane during locking, this causes the horizontal displacement of the free end of the spring behind the locking edge of the other panel.

So that the panels do not drift apart during locking, it is provided in an advantageous development that the panel having the locking edge has a locking strip engaging under the spring-carrying panel, which is suitable for securing adjacent panels against tensile loads in the laying plane.

The panels according to the invention with the elastic core preferably have a decorative layer arranged above the core and a wear protection layer arranged above the decorative layer. The wear protection layer may additionally be provided with a transparent lacquer layer. On the opposite side of the core, that is on the underside of the panel, a Gegenzugschicht can be arranged as a damping layer. The core consists in particular of PVC.

To the decorative layer is to be noted that this can itself consist of PVC. The decorative layer may be a print or a separate printed layer bonded to the core. The decorative layer may optionally be printed after prior application of a primer to the surface of the core, in particular in digital printing or inkjet process. The preparation of the core for a direct application of the decorative layer may also include the application of a base layer, which is subsequently printed. The printing itself can, as mentioned, be done by means of indirect gravure or non-contact digital.

In an advantageous development of the invention, it is conceivable to apply a nonwoven layer to the core. The decorative layer is then preferably formed by a decor printed on the nonwoven layer decor. The nonwoven layer can also be provided with a primer before printing. This embodiment is particularly advantageous, what the Impact resistance and the elasticity of the panels. The fleece also acts as a reinforcement and can be modified for special properties, for example in the antistatic effect. Kevlar or carbon fiber nonwovens can also be used as fleece.

As wear protection and sealing, the panels are provided with a wear protection layer, which is also referred to as an overlay. The wear-resistant layer can in turn be formed in one or more layers and consist of transparent lacquers and / or transparent resins with additives such as corundum. The incorporation of effect particles in the so-called overlay is possible.

The nonwoven fabric is preferably a flexible sheet of individual fibers or filaments. The nonwoven layer can be formed, for example, from a glass fleece or polyester. Basically, a combination of glass and polyester is possible. The nonwoven layer may further be made of polyamide or polyethylene terephthalate (PET). In addition, a combination of polyamide and polyethylene terephthalate is conceivable. The nonwoven may also contain fibers of different strength, in particular stiffening fibers of Kevlar or carbon may be incorporated into the nonwoven. The nonwoven layer is characterized by a high strength and stability. In addition, the nonwoven layer is particularly well suited for receiving the decor. Particularly advantageously, the nonwoven layer consists of endlessly spun filaments.

To increase the stability and to avoid dimensional changes, the panels below the core can be provided with a stabilizing fabric.

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

1 to 3 in each case a cross section through the connecting region of two adjacent panels in different mounting positions, wherein 1 the still unlocked position shows and 3 represents the locking position;

1a a cross section through the connecting region of two adjacent panels in the unlocked position in a further embodiment;

4 to 6 each in cross section a section of the connecting region of two adjacent panels in different mounting positions;

7 and 8th each in cross-section a section of the connecting region of two adjacent panels in a further embodiment in different mounting positions;

9a to 12b other versions of panels with integrally formed springs and

13 a cross-section through another embodiment of a panel.

1 shows a cross section through two panels 1 . 2 , This may be a longitudinal or head-side cross section of the panels 1 . 2 act. The panels 1 . 2 are identically configured so that the panels 1 . 2 can be assembled to a floor covering.

1 shows two adjacent panels 1 . 2 before the lock. The illustration on the left shows a first panel 1 and on the right a second panel 2 , which is intended for, with the first panel 1 to be connected. The first panel 1 has a locking bar 3 on and the second panel 2 a downwardly open dome channel 4 and a subsequent, downwardly directed dome bulge 5 , The locking bar 3 of the first panel 1 faces a head of the first panel 1 in this embodiment, only as a page 6 is designated before. The panel 2 is so opposite panel 1 arranged that when lowering in the direction of arrow P dome bulge 5 of the second panel 2 with the dome channel 7 the locking bar 3 and the dome channel 4 of the second panel 2 with the dome bulge 8th the locking bar 3 engaged. This area of the panels 1 . 2 essentially serves for positional orientation in the horizontal plane, horizontally in the context of the invention corresponding to the laying plane V, which coincides with the mutually parallel upper sides 9 and subpages 10 the panels 1 . 2 coincides.

An essential part of the profiling according to the invention is a spring 11 , The feather 11 is a substantially down, that is from the top 9 directed tongue, which is formed by a rectangular in cross-section space 12 to the core 15 of the element 2 is formed. The feather 11 is with an upper end 13 with the panel 2 or with the core 15 integrally connected in one piece. It can be seen that on the free space 12 opposite side of a crimp 14 is arranged as a narrow notch. As based on the 2 and 3 can be seen, serves the crimping 14 to become smaller when the spring 11 in the horizontal direction, that is, to the side, of the other panel 1 back, is relocated. The pinch joint 14 is a thickness of the spring 11 reducing constriction that serves the upper end 13 the feather 11 opposite the core 15 even more mobile. The pinch joint 14 is only optional.

Another essential element of the spring 11 is a lead 16 that to the other panel 1 points and is provided behind a locking edge 17 the other panel 1 to grab. In the other panel 1 this is a groove 18 provided, which the projection 16 can record.

In the groove 18 or a lower groove cheek the groove 18 also opens a support surface 19 , at which the lower, free end 20 the feather 11 supported. The support surface 19 is inclined with respect to the laying plane V, that is, with respect to the horizontal. The support surface 19 Here is a straight line with a slope of about 20 ° relative to the laying plane V. The support surface 19 but may also have a concave curvature. In addition, the support surface points 19 a recessed rest stop 29 in the form of a groove.

The feather 11 has a displacement in the direction of the arrow P, that is, when lowering the panel 2 , only the possibility according to the inclination of the support surface 19 slide off on this. This bends the spring 11 in the area of the crimping line 14 so the lead 16 behind the locking edge 17 is pivoted.

1a shows an alternative to the embodiment of the 1 to 3 , The differences exist in the design of the locking edge 17 , which is provided with a larger radius, the groove 18 which is also significantly larger because of the free end 20 the feather 11 also has a greater rounding. Instead of sharp-edged radii, a larger contact area is created by the larger radii. This is due to the desired higher elasticity of the materials, so that the deflected in the locking direction spring 11 securely held in the latching position according to the principle of a ball detonator. This is largely due to the contour of the support surface 19 with the recessed rest stop 29 in the form of a flat, trough-like rounded groove, wherein the radius of curvature is substantially the radius of curvature of the end 20 the feather 11 equivalent.

2 shows the spring 11 in an intermediate position before entering the in 3 shown end position / locking position passes. In the locking position are the two tops 9 the panels 1 . 2 in the same horizontal plane. There is no offset anymore. It can be seen that the right panel 2 can not be lowered further. It relies on a console 21 of the first panel, which is still above the locking edge 17 located. This console 21 is relatively close to the top 9 arranged so that one on the right in the image plane panel 2 applied force as short as possible in the left panel 1 is initiated. This minimizes any height offset.

Furthermore, based on the 3 to recognize that in the locking position of the dome 15 almost completely behind the dome bulge 8th the locking bar 3 is located so that a secure locking in the horizontal direction is given.

The support surface 19 is configured to be the end 20 the feather 11 when locking in the recessed detent 29 is guided and can engage there. It comes to a positional fixation of the spring 11 in the recessed rest stop 29 and thus to a secure clamping of the projection 16 behind the locking edge 17 ,

The upper groove cheek 22 the groove 18 that are in the locking edge 17 ends, runs in the laying plane V, that is in the horizontal direction. Also a catch area 23 at the projection 16 the feather 11 runs in the locking position horizontally, that is in the laying plane V. Will now be a vertical force on the left in the image plane panel 1 exercised, then on this locking surface 23 a sufficient support force in the spring 11 be initiated, which is on the right panel 2 transfers.

4 shows a cross section through the connecting region of two panels 1 . 2 , wherein in the following explanation to the to 1 to 3 already introduced reference numerals, if substantially identical elements are designated. According to the invention, the configuration of the spring is essential 11a , In this embodiment, the spring 11a , andes than in the 1 to 3 essentially horizontally oriented and not vertically oriented. The feather 11a is in this embodiment uniformly in one piece material from the core 15 the panels 1 . 2 developed. The feather 11a owns in 1 a curved course when joining the panels 1 . 2 can be stretched, as in 6 is shown. The feather 11a For this purpose has at its free end a locking portion 24 that has a joint section 25 with a connection section 26 connected is. The connecting section 26 is in turn via a joint section 27 with the core 15 of the upper panel in the picture plane 2 connected.

When lowering the upper panel 2 the joint section hits 25 on a support surface 19 at the bottom panel 1 , Unlike the embodiment of the 1 to 3 the support surface is aligned parallel to the laying plane V in this embodiment. Through the joint sections 25 and 27 , which are designed as film hinges, the spring 11a However, be transferred from the arcuate curved contour in a stretched arrangement, as in 6 is shown. In the extended arrangement, the locking portion engages 24 in the groove 18 below the locking edge 17 and thus lies on the underside of the support surface 19 and on the upper side on a groove cheek 28 the groove 18 at. In addition to the contact between the dome beads 5 . 8th lies the second panel 2 on the console 21 above the groove 18 on. The console 21 is thus located at a smaller distance from the top 9 of the left panel in the picture plane 1 as the locking bar 3 on the panel 2 Usually supported in the vertical direction. Due to the smaller distance of the console 21 to the top 4 Tighter tolerances can be maintained, so that with this solution a possible height offset between the panels 1 . 2 can be minimized. The console 21 immediately adjacent to the groove 18 so that its lower edge forms part of an upper groove cheek 22 the groove 18 is. The foremost corner of the groove cheek 22 forms the locking edge 17 ,

The panels 1 . 2 preferably touch at certain support and breakpoints. The locking bar 3 and the dome bulge 5 In this embodiment, they only touch in the contact region described above 30 , However, the remaining space between the locking bar 3 and the dome bulge 5 so small that, depending on the load condition, a contact can also be made here, which is due to the elasticity of the core 15 is due. Due to the free space also manufacturing tolerances can be compensated.

The locking section 24 extends into the in 6 shown locking position in the groove 18 into it. The joint sections 25 . 27 are stretched, with the connecting portion 26 with its lower end on the support surface 19 rests and with its upper, the joint section 27 adjacent end to a groove cheek 28 is applied.

The 7 and 8th show an embodiment in which the spring 11b as they are in the 4 to 6 is shown, in a sense rotated by 180 ° and instead of the right panel 2 now on the left panel 1 is arranged. The locking section 24 now points to the right in the image plane and should be in the right groove in the image plane 31 in the upper panel 2 be introduced. The conditions are therefore exactly the opposite, so that also the locking edge 17 at the front edge of the groove 31 located. The support surface 19 is therefore located on an extension of the upper groove cheek of the groove 31 of the upper panel 2 , At this upper support surface 19 abuts when lowering the panel 2 again the joint section 25 on, which faces upward due to the reverse arrangement in this embodiment. This will turn the arcuately curved spring 11b , which is effectively formed of two segments, in the region of their joint sections 25 . 27 elastically deformed and thereby stretched, so that the locking portion 24 behind the locking edge 17 in the groove 31 grips and the two panels 1 . 2 locked together. Regarding the other components of the panels 1 . 2 will refer to the comments on the 4 to 6 Referenced.

The embodiment of 7 and 8th is representative of the possibility to modify all other illustrated embodiments with respect to the mounting location of the spring. It is thus possible in all variants, to rotate the spring by 180 °, that is, not only to be arranged on the still to be laid upper panel, but also on the already laid lower panel.

In this sense, the following embodiments are according to the 9a to 12b to understand. The embodiment of the 9a and 9b shows a spring 11c in the relaxed position ( 9a ) and in the locking position ( 9b ). The feather 11c is arcuately curved and in turn uniform material integral with the core 15 of the panel 2 educated. The feather 11c is divided into two sections. End is the locking portion 24 , which has an arcuately curved connecting section 26 with the core 15 uniform material is formed integrally. The arcuately curved connecting portion 26 points from the top 9 of the panel 2 away, leaving the spring 11c in the illustrated state an approximately semicircular space to an upper groove cheek of the upper panel 2 forms. The one through the arch shape towards the bottom of the panel 2 pointing projection has such a strong curvature that the spring 11c by a multiple of its thickness in the region of the connecting portion 26 is distracted. This significant deflection, it is possible when locking two panels 1 . 2 to press the arcuate section in an extended configuration so that the spring 11c overall lengthens. This will be the locking portion 24 displaced in the longitudinal direction and can over the front side 6 of the panel 2 protruding into a groove 18 of the adjacent panel 1 be introduced.

The embodiment of the 10a respectively. 10b differs from the previous one by being attached to a spring 11d a plurality of substantially arcuate curved portions are provided. In the context of the invention, therefore, an arcuately curved section is also one such in which the spring is not straight over only a portion of its length, but has an exhibition to one side, while on the opposite side of the spring there is a recess.

In this embodiment, there are two of these protrusions 33 which are intended for use with a support surface 19 to come into contact with the material of the elastic spring 11d in the opposite direction, ie towards the groove cheek 32 to relocate. Opposite the projections 33 are on the top 9 of the panel of the spring 11d recesses 34 , The recess 34 may for example have a triangular cross-section. Deviating cross-sectional shapes are conceivable. Decisive is that the projections 33 should not lead to a compression of the spring, but to a material shift and thus to an elongation of the spring 11d so this, as in 10b shown in the groove 18 of the first panel 1 is relocated.

The 11a and 11b show a further embodiment with a spring 11e , which in turn is integral with the core in the same material 15 is trained. The feather 11e has a cavity 35 , Of course, you can also use several cavities 35 be provided. By pressure on the spring 11e in the vertical direction, as when laying the panel 2 on a neighboring panel 1 is constructed, there is an elongation of the spring 11e in the direction of the corresponding groove 18 of the adjacent panel 1 so the spring 11e the panels 1 . 2 locked together ( 11b ). The cavity 35 is brought in this embodiment of its original round shape in an oval shape. The elongation of the cavity 35 to the oval shape corresponds essentially to the change in length of the spring 11e ,

The embodiment of the 12a and 12b shows a bow-shaped spring with three segments. The end-side segment is again the one above as a locking portion 24 designated part of the spring 11f , About a joint section 25 closes a middle section 36 at. About another joint section 27 the connection to a connection section takes place 26 , which over another joint section 37 with the core of the panel 2 connected is. All joint sections 25 . 37 are at a lying in the image plane bottom of the spring 11f arranged. Due to the arcuate curvature are the locking portion 24 and the connecting section 26 in the area of the joint sections 25 . 27 at the middle section 36 at. In the extended position, that is in the locking position, as in 12b is shown, are the locking portion 24 and the connecting section 26 no longer at the middle section 36 at. This results in wedge-shaped interspaces caused by the elastic fanning in the region of the joint sections 25 . 27 be generated. As a result, the end-side locking section engages 24 turn into the groove 18 the opposite panel 1 one.

For all the embodiments described above, the tolerances and in the region of the groove 18 with respect to the locking portion 24 are dimensioned so that by the restoring forces of the spring no independent return to the starting position is possible. There is a jamming of the locking portion 24 inside the groove 18 , so that there is a positive connection. By additional profiling of the groove cheeks or the areas of the locking portion coming into contact with the groove 24 An even better locking function can be achieved.

13 shows a sectional view through a panel 38 to illustrate a possible layer structure of the panel 38 , The cutting direction runs parallel to the head side of the panel 38 and thus at right angles to the cutting plane of the 1 to 12b , It can be seen that the panel shown 38 frontal with a profiling 39 which is representative of other possible types of profiling. The profiling 38 sees strip-like locking means 40 in front. For this purpose, on a first longitudinal side, a continuous coupling groove 41 with a bottom-projecting resilient locking strip 3 intended. At the opposite second side edge is the locking means by a projecting clutch spring 42 educated. On the underside of the clutch spring 42 is a dome channel 4 intended. The coupling groove 41 and the clutch spring 42 are contour matched so that adjacent panels 38 latching engaged. This is where the clutch springs engage 42 in the coupling grooves 41 , The locking bar 3 slides under the clutch spring 42 so they are in the dome channel 4 locks. That way, the panels can 38 be added without tension and pressure resistant along their side edges. At the core 15 are optional cavities 43 intended. The cavities shown here 43 are within the core 15 embedded and closed on the periphery. However, they can have frontal openings in the panels 38 be connected to the atmosphere. Through these cavities, the damping can be improved.

Above the core 15 there is a decorative layer 44 , This can be a printed decorative paper. It is also possible and advantageous for the decorative layer to be printed on the upper side of the core 15 is printed. Optionally, on the top before printing the decorative layer 44 a primer has been applied. At the core 15 can also be a fleece layer 45 be applied, the decorative layer 44 preferably digitally on the nonwoven layer 45 is printed. Above the decorative layer 44 there is a wear protection layer 46 which is also known as an overlay. It forms the top or side sealing and consists of transparent paints and / or transparent resins, which may be applied in one or more layers. In the top relief-like surface structures can be embossed. The gloss levels of the top can vary in some areas to improve the natural look of the decor. The surface structure is so deep that the wear protection layer 46 , the decorative layer 44 , the fleece layer 45 and the top 47 of the core 15 are structured.

Lower side of the core 15 is a stabilizing fabric 48 arranged, which serves as a countermove. As a countermove, other materials, especially suitable plastics, can be used.

LIST OF REFERENCE NUMBERS

1

paneling

2

paneling

3

locking bar

4

dome channel

5

Kuppelwulst

6

page

7

dome channel

8th

Kuppelwulst

9

top

10

bottom

11

feather

11a

feather

11b

feather

11c

feather

11d

feather

11e

feather

11f

feather

12

free space

13

top end

14

squeezing nip

15

core

16

head Start

17

locking edge

18

groove

19

support surface

20

The End

21

console

22

cheek

23

Rest area

24

locking section

25

hinge section

26

connecting portion

27

hinge section

28

cheek

29

resting place

30

contact area

31

groove

32

cheek

33

head Start

34

recess

35

cavity

36

section

37

hinge section

38

paneling

39

profiling

40

locking means

41

coupling groove

42

clutch spring

43

cavity

44

decorative layer

45

fleece layer

46

Wear protection layer

47

top

48

stabilizing tissue

P

arrow

V

laying plane

Claims (15)

Covering of mechanically connectable panels, wherein the panels ( 1 . 2 . 38 ) have on their opposite sides a corresponding profiling and are locked together by this profiling, wherein on a core ( 15 ) of the panels ( 1 . 2 . 38 ) a feather ( 11 . 11a F) is arranged, which via a joining movement behind a substantially horizontally extending locking edge ( 17 ) of the adjacent panel ( 1 . 2 . 38 ) is displaceable, characterized in that the panels ( 1 . 2 . 38 ) have a multilayer structure with a core ( 15 ) made of an elastic material from which the spring ( 11 . 11a -F) integral with the core (integral with the core) 15 ) is formed. Covering according to claim 1, characterized in that the spring ( 11 . 11a -F) behind the locking edge ( 17 ) is pivotable, wherein the spring ( 11 . 11a -F) is at least partially elastically deformed to achieve the locking position. Covering according to claim 1 or 2, characterized in that the spring ( 11a F) in the unlocked position at least in sections has a substantially arcuate curved course, wherein the spring ( 11a -F) is provided for joining with the adjacent panel ( 1 . 2 . 38 ) by contact with the adjacent panel ( 1 . 2 . 38 ) elastically deformed in the region of its at least one arcuately curved course and thereby stretched, wherein the spring ( 11a F) in the extended position behind a locking edge ( 17 ) of the adjacent panel ( 1 . 2 . 38 ) attacks. Covering according to claim 3, characterized in that the spring ( 11a , b, f) at its panel-side end a connecting portion ( 26 ) and at its other free end a locking portion ( 24 ), wherein the locking section ( 24 ) via a joint section ( 25 ) with the connecting section ( 26 ) connected is. Covering according to claim 4, characterized in that the joint section ( 25 ) is designed as a film joint. Covering according to one of claims 1 to 5, characterized in that the spring ( 11e ) Cavities ( 35 ), which are reduced in locking, so that the spring ( 11e ) lengthens to reach behind the locking edge. Covering according to one of claims 4 to 6, characterized in that the locking portion ( 24 ) at its top ( 9 ) and / or underside ( 10 ) of the panel ( 1 . 2 . 38 ) facing side has a profiling, with a profiling in a groove ( 18 ) of the adjacent panel ( 1 . 2 . 38 ) corresponds. Covering according to one of claims 1 to 7, characterized in that the spring has a geometry which can be converted by elastic deformation during locking from a stable to a metastable state in which the spring is stretched by bumps. Covering according to one of claims 1 to 8, characterized in that the spring ( 11 ) when locking on a support surface ( 19 ) of the opposite panel ( 1 ) is supported, wherein the support surface ( 19 ) is inclined relative to the laying plane (V) and a horizontal displacement of the spring ( 11 ) behind the locking edge ( 17 ) causes. Covering according to one of claims 1 to 9, characterized in that the displacement of the spring element ( 11 . 11a -F) only in the direction of the adjacent panel ( 1 . 2 . 38 ) he follows. Covering according to one of claims 1 to 10, characterized in that the spring element ( 11 ) at least one crimp ( 14 ) having. Covering according to one of claims 1 to 11, characterized in that the locking edge ( 17 ) having panel ( 1 ) one under which the spring ( 11 . 11a , c-f) supporting panel ( 2 . 38 ) interlocking locking strip ( 3 ), which is suitable, adjacent panels ( 1 . 2 . 38 ) against tensile loads in the laying level (V). Covering according to one of claims 1 to 12, characterized in that the panels ( 1 . 2 . 38 ) an elastic core ( 15 ), one above the core ( 15 ) arranged decorative layer ( 44 ) and one above the decorative layer ( 44 ) wear protection layer ( 47 ). Covering according to claim 13, characterized in that below the core ( 15 ) a Gegenzugschicht is arranged as a damping layer. Covering according to one of claims 1 to 14, characterized in that the core ( 15 ) consists of PVC.

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