EP4033049A1 - Penetration-resistant and fracture-resistant panel with a locking element and method for manufacturing such a panel - Google Patents

Abstract

A panel (10) is provided with a panel body (28) extending in a longitudinal direction (30) and a transverse direction (32), a retaining groove (20) running in a transverse direction (32) in a short end face of the panel body (28) and a blocking element (22) inserted in the retaining groove (20) so that it is essentially non-moving, wherein for an extension bo of the retaining groove (20) in the transverse direction (32) in relation to a nominal width B of the panel body (28) between a longitudinally running first edge and a longitudinally extending second edge of the panel body (28) 0.50 ≤ b₀/B ≤ 0.97, in particular 0.75 ≤ b₀/B ≤ 0, 95, preferably 0.85 ≤ b₀/B ≤ 0.93 and particularly preferably b₀/B = 0.90 ± 0.02. The retaining groove (20) running only over a larger portion of the short side and the blocking element (22) held in the retaining groove (20) so that it cannot move allows for a break-resistant and secure panel (10) with a good and material-friendly latching.

Description

The invention relates to a panel with a high breaking strength and a high level of security against liquid reaching the underside of the panel, which can cover a surface of a room with the help of a, in particular fixed, blocking element, which can cover a surface of a room, in particular in order to thereby improve the visual appearance of the room and/or to cover the surface of the room with a layer of material better suited to the intended function, and a method by which such a panel can be manufactured.

Out of WO 2007/079845 A1 it is known to provide a retaining groove on a short side of a panel over the entire transverse extent of the panel, into which a locking element designed as a locking clip can be inserted so that it cannot move.

Out of WO 2010/087752 A1 it is known to saw a part-circular groove in a partial area on a short side of a panel, in which a lug of a locking element otherwise provided outside the groove can be displaced in the transverse direction, the lug sliding on the rounded edges of the part-circular groove and thereby locking the locking element with a Movement component can press in the longitudinal direction in an opposite groove of another panel.

There is a constant need to improve the breaking strength and resistance to liquid penetration of panels.

It is the object of the invention to show measures that enable a shatterproof and leak-proof panel.

The object is achieved by a panel with the features of claim 1 and a method with the features of claim 12. Preferred embodiments of the invention are specified in the dependent claims and the following description, which individually or in combination can represent an aspect of the invention .

One embodiment of the invention relates to a panel for covering a surface of a room, with a panel body extending in a longitudinal direction and a transverse direction for transferring service loads introduced on an upper side of the panel body to an underside of the panel body facing the surface of the room, the upper side being is spaced apart from the underside in a thickness direction, and a retaining groove running in the transverse direction in a front short side of the panel body and a locking element inserted in the retaining groove, in particular essentially immovably, wherein for an extent b ₀ of the retaining groove in the transverse direction in relation to a nominal width B of the panel body between a longitudinal first edge and a longitudinal second edge of the panel body 0.50≦b ₀ /B≦0.97, in particular 0.75≦b ₀ /B≦0.95, preferably 0.85≦ b ₀ /B ≤ 0.93 and more preferably b ₀ /B = 0.90 ± 0.02 is applicable.

The panel can have a panel body based on a cuboid as the basic shape, the longitudinal extent of which is generally significantly greater than its transverse extent, while the thickness of the panel body in the thickness direction is generally smaller than its transverse extent. The panel body can have a longitudinally extending long side in particular have a bung extension that runs continuously in the longitudinal direction and protrudes in the transverse direction and on the other side has a bung groove introduced in the transverse direction in the panel body, so that essentially identically designed panels rest against the long sides via a tongue and groove connection designed as a bung can be connected to each other. In particular, a locking hook can protrude in the longitudinal direction from the short side of the panel body running in the transverse direction, while a tongue body can protrude from the other short side of the panel body, which delimits a receiving groove, so that essentially identically configured panels also have a tongue and groove on their short sides. Connection can be locked together. In addition or as an alternative to the tongue-and-groove connection formed with the aid of the locking hook and the receiving groove of the spring body, the blocking element can be inserted in the retaining groove provided on the short side of one panel, in particular motion-proof, which can engage in a locking groove on one the short side facing the blocking element of another panel, in particular of substantially identical design, is provided. For this purpose, the blocking element, which is designed in particular in the manner of a locking clip, can have a locking web with a locking lug, which can be pushed away elastically when the panels move past during assembly, in order to elastically at least partially, in particular with the locking lug, in the designated end position of the panels to be locked together , snaps into the latching groove and secures the panels, which are thereby latched together, against unintentional loosening. During installation, one panel can lie flat on a subsurface that defines a usage level, for example a floor, a side wall or a ceiling of a room. The further panel can optionally be attached, for example at an angle of approx. 30°, with an already mounted panel running laterally next to the panel on the long side and then pivoted onto the substrate, whereby the at least one latching of the panels facing each other on the short sides panels can be made. During the latching, the locking hook can be latched into the latching groove of the further panel on the one hand and the blocking element inserted into the retaining groove on the other hand essentially simultaneously in the latching groove of the further panel. The extension of the locking groove in the transverse direction corresponds in particular to the extent of the retaining groove in the transverse direction. In particular, for an extension co of the locking groove in the transverse direction in relation to the nominal width B of the panel body, 0.50≦c ₀ /B≦0.97, in particular 0.75≦c ₀ /B≦0.95, preferably 0.85≦ c ₀ /B ≤ 0.93 and particularly preferably c ₀ /B = 0.90 ± 0.02. The latching groove is preferably designed identically to the retaining groove and/or is produced by the same manufacturing process, which simplifies the simultaneous and/or identical production of the latching groove and the retaining groove. The retaining groove accommodating the preassembled blocking element can be provided on one short side of the panel, while the latching groove is provided on the other short side of the panel.

Since the retaining groove and/or the locking groove is not provided over the entire transverse extension of the panel body, but only in a partial area of the transverse extension, it is possible to avoid a weakening of the panel body in a transition area between the short side and the long side in the corners of the panel body. Here, use was made of the finding that with a retaining groove that is continuous in the transverse direction in a corner of the panel body, both the retaining groove and a bung-type groove can end, which means that a particularly large amount of material is missing in the transition area between the short side and the long side and the strength of the panel as a result could be affected. In addition, outlet openings on the longitudinal edges of the panel, through which water could run down, can be avoided. Instead, a groove base of the bung groove is also closed on the short side, which provides an effective barrier against water running through. However, since the retaining groove running in the transverse direction on the short side can end at a distance from the bung groove running in the longitudinal direction on the long side, sufficient material of the panel body remains between the retaining groove and the bung groove that a significant impairment of the strength of the panel body in the transition area between the short side and the long side is avoided in comparison to the strength of the rest of the bung-groove and / or the rest of the retaining groove. The risk that, in the event of heavy, particularly punctiform, stress on the panel in the corners, for example if an office chair is driven over the corner or a table leg is supported on the corner, is thereby at least reduced. If the blocking element is not movable but is used in a fixed manner in the retaining groove, an air gap between the blocking element and at least a part of the surfaces of the retaining groove pointing towards the blocking element can be minimized, in particular eliminated by a press fit. A breaking off of the material delimiting the retaining groove can thereby be avoided. Instead, the blocking element can fill out a large part of the volume of the retaining groove, in particular over 50%, preferably over 75%, more preferably over 85% and particularly preferably over 95%, whereby loads acting on the material of the panel body delimiting the retaining groove are reduced the locking element can be removed. This improves the breaking strength of the panel, particularly in the corner areas of the panel.

At the same time, hydraulic communication between the holding groove and the bung groove can be avoided or at least reduced. As a result, a larger collection volume at a T-joint of three panels, into which two bung grooves and one retaining groove would otherwise open, can be avoided compared to the flow cross section along the retaining groove in the transverse direction and/or along the bung groove in the longitudinal direction. A drop in capillary forces acting on liquids that have penetrated can be avoided, so that the liquid that has penetrated can also evaporate more easily at a T-joint at a later point in time and/or can exit again from a gap between the panels. An accumulation of liquid in the collection volume, from which the liquid can get to the underside of the panel body, in particular due to hydrostatic pressure increasing over time as a result of subsequent liquid, remains there and promotes the formation of mold, is thereby at least reduced or even avoided . The risk of liquid being able to run through gaps between the panels to the underside of the panel is at least reduced as a result, so that the security against liquid getting through to the underside of the panel is improved.

The security of the panel can be measured by filling a liquid, in particular water, with a predefined specific volume into a vessel that is open at the bottom and at the top, so that the liquid has a defined fill level in the vessel with a defined hydrostatic pressure resulting therefrom results. The vessel filled with the liquid is placed centrally on a joint crossing area formed between three panels that are latched together in a T-shape on the upper sides of the three panels. The level of liquid remaining in the vessel after a predefined specific time is a measure of the flow security against penetration of the liquid into the joint forming between the panels that are locked together.

Since the retaining groove does not extend over the entire transverse extent of the panel body, the blocking element can also have an extent in the transverse direction that is less than the entire transverse extent of the panel body. Here, use was made of the knowledge that the blocking element in the configuration in the form of a locking clip can provide sufficiently good locking even with a smaller extension in the transverse direction due to the positive clip connection, so that locking over the entire transverse extension is not necessary at all of the panel body to be provided. At the same time, the transverse extension of the locking element is still so great that the forces acting on the locking element during locking can be distributed over a larger area and the local mechanical loads on the locking element can be kept low. The selected ratio of the extension b ₀ of the retaining groove in the transverse direction in relation to the nominal width B of the panel body results in improved breaking strength and improved safety in the corner areas of the panel body, while at the same time good latching with low component loads for the locking element is ensured. Due to the holding groove running only over a larger partial area of the short side and the blocking element accommodated in the holding groove, an unbreakable and walk-through-proof panel with a good and material-friendly latching is made possible.

In particular, the blocking element is inserted into the retaining groove in such a way that movement of the blocking element in the transverse direction is blocked with a friction fit and/or a form fit. In particular, it can be provided that the blocking element strikes the corresponding end of the retaining groove during a movement in the transverse direction and cannot be moved any further. A loose fit is preferably formed between the retaining groove and the locking element in the transverse direction. A press fit is particularly preferably formed between the retaining groove and the locking element in the thickness direction, as a result of which the material of the panel body forming the retaining groove can be stiffened. Suitable blocking elements are, for example, in WO 2007/079845 A2 described, the relevant content of which is hereby referred to as part of the invention.

In particular, a first reinforcement area with an extension t ₁ in the transverse direction is formed in the transverse direction between a first end of the retaining groove pointing in the transverse direction towards the first edge, a second reinforcement area being formed in the transverse direction between a second end of the retaining groove pointing in the transverse direction towards the second edge with an extension t ₂ in the transverse direction, wherein for the first reinforcement region 0.005 ≤ t ₁ /B ≤ 0.090, in particular 0.015 ≤ t ₁ /B ≤ 0.050, preferably 0.020 ≤ t ₁ /B ≤ 0.030 and particularly preferably t ₁ /B = 0.025 ± 0.002 and/or for the second amplification range 0.005 ≤ t ₂ /B ≤ 0.090, in particular 0.015 ≤ t ₂ /B ≤ 0.050, preferably 0.020 ≤ t ₂ /B ≤ 0.030 and particularly preferably t ₂ /B = 0.025 ± 0.002 holds, with the proviso that t ₁ + b ₀ + t ₂ = B holds. The respective reinforcement area adjoins the associated edge of the panel body and extends along the short side in the transverse direction to the associated end of the retaining groove. As a result, the reinforcement area is free of the retaining groove. Instead of the holding groove, which would otherwise be provided in the reinforcement area, the volume of the holding groove that would otherwise be present is filled by the material of the panel body. This accumulation of material in the reinforcement area leads to increased stability and increased breaking strength in the corner area of the panel body. At the same time, the respective amplification range is short enough that a sufficiently large proportion of the Transverse extension of the short side for the retaining groove and the locking element used in the retaining groove remains.

On the first edge, the panel body preferably has a bung groove extending into the panel body and on the second edge a bung protruding from the panel body, where t ₁ <t ₂ , in particular 0.75≦t ₁ /t ₂ ≦0 .99, preferably 0.80≦t ₁ /t ₂ ≦0.95 and particularly preferably 0.85≦t ₁ /t ₂ ≦0.90. It can be taken into account here that the panel body is designed to be more stable and firmer on the second edge than on the first edge, where the bung groove is provided, due to the bung attachment. This allows the second reinforcement area to be made correspondingly shorter in the transverse direction than the first reinforcement area. In the area of the joint between two essentially identically designed panels that rest on each other on the long sides, there is an equally large joint reinforcement area of t ₁ + t ₂ on both long sides of the respective panel, in which the first reinforcement area is from one panel and the second reinforcement area from the other panel is provided. As a result, with good breakage resistance in the area of the bung-groove, good breakage resistance can be achieved at the joint of the bung formed on the long sides. The bung groove is provided inside the panel body between the first edge and the second edge of the panel body. The bung extension projects from the remainder of the panel body with which the bung extension may be integrally formed and is thereby located outside the nominal width B of the panel body measured from the first edge to the second edge so that the extension of the bung extension Approach does not contribute to the nominal width B of the panel body.

Particularly preferably, for an extension b ₁ of the blocking element in the transverse direction based on the nominal width B of the panel body, 0.40≦b ₁ /B≦0.95, in particular 0.50≦b ₁ /B≦0.90, preferably 0, 60 ≤ b ₁ /B ≤ 0.80 and more preferably b ₁ /B = 0.70 ± 0.05. The extent of the blocking element in the transverse direction of the panel body can in particular essentially correspond to the extent of the retaining groove in the transverse direction correspond to. However, it is also possible for the length of the blocking element in the transverse direction to be selected to be somewhat or significantly less than the length of the retaining groove. The extension of the blocking element can be dimensioned, for example, essentially solely with regard to the latching functionality and the ability to withstand the forces to be expected, which means that it is quite possible that the extent of the blocking element can be selected to be smaller than the extent of the retaining groove. In this case it is in principle possible to adapt the extent of the holding groove in the transverse direction to the required smaller extent of the blocking element. However, if the extent of the retaining groove in the transverse direction is chosen to be significantly larger than the extent of the blocking element, there are alternative manufacturing options for the retaining groove. Instead of producing the retaining groove with a pin-shaped milling cutter that moves in the transverse direction, the diameter of which corresponds in particular to the extent of the retaining groove in the thickness direction, it is possible to produce the retaining groove with a circular saw or peripheral milling cutter that plunges into the panel body, since a rounded entry area at the ends of the Holding groove can be approved. As a result, the retaining groove can be produced more quickly and cost-effectively.

In particular, a frictional connection of the blocking element in the retaining groove is provided exclusively by clamping forces pointing in the direction of thickness. The locking member may be clamped between a thicknesswise upper surface of the retaining groove and a lower surface of the retaining groove. Hooks and/or spikes protruding from the locking element are preferably driven into the material of the locking element delimiting the retaining groove in a form-fitting manner. Clamping in the transverse direction is not intended. Unnecessary shearing forces acting on the blocking element can thereby be avoided. It is also possible for the blocking element to yield somewhat elastically in the transverse direction when inserted into the retaining groove, which makes it easier to press the blocking element into the retaining groove and/or drive hooks and/or spikes into the material of the retaining groove.

Preferably, the blocking element has a latching web that can be elastically bent at least partially in the direction of the retaining groove. The locking element can be used as a locking clip be designed. If, when two panels are latched, one panel is moved past the other, in particular during a pivoting movement, the panel can bend the latching web elastically towards the retaining groove of the locking element and/or at least partially into the retaining groove of the locking element, so that the Panel can be moved past the locking element. In the intended end position, the blocking element, in particular a latching lug of the latching web, can snap elastically into a latching groove of the panel moved past and bring about the latching connection. The latching web of the panel can at least partially engage in the latching groove of the other panel and thereby form a tongue and groove connection.

Particularly preferably, the retaining groove has a receiving space adjoining an end face of the short side for accommodating a part of the blocking element, in particular for temporarily receiving an elastically flexible latching web of the locking element, and a fastening space adjoining the side of the receiving space pointing away from the end face for friction-locking and / or form-fitting attachment of an attachment lug of the blocking element, wherein the extent of the attachment space in the direction of thickness is smaller than the extent of the receiving space in the direction of thickness. The fastening of the blocking element in the retaining groove, which is particularly fixed against movement, can be carried out to a large extent or completely via the fastening shoulder of the blocking element that dips into the fastening space. At the same time, the blocking element can reserve enough free space in the volume of the receiving space of the retaining groove, into which the elastically flexible latching web of the blocking element or another component causing latching can immerse when the panel to be latched is moved. A relative movement of the panels provided for the locking of the two panels is not blocked by the blocking element.

In particular, the blocking element rests against both surfaces of the receiving space pointing in the thickness direction, in particular with a clamping force, with the blocking element in particular having a receiving pocket extending into the receiving space for temporary Has recording of an elastically bendable connected latching web of the locking element. This makes it possible to provide a non-moving and/or in particular load-dissipating attachment of the blocking element in the retaining groove. It can even be allowed that the blocking element can yield elastically in the direction of thickness within the volume of the receiving space. As a result, the blocking element can be manufactured more cost-effectively. Since the blocking element bears against the surfaces pointing in the thickness direction, there is at least a certain frictional connection, which can make it more difficult for the blocking element to slip out of the retaining groove. A free volume for forming the receiving pocket can be reserved between the material areas of the blocking element lying against the surfaces. This allows sufficient pivotability of the elastically bendable connected latching web into the receiving pocket when a panel to be latched moves past and a good frictional connection of the locking element within the retaining groove.

Preferably, the panel body has, on the short side forming the retaining groove, a locking hook protruding in the longitudinal direction from the short side of the panel body for latching in a receiving groove of a further panel. This allows one panel to be latched to another panel with the aid of the blocking element engaging in a latching groove of the other panel and with the aid of the locking hook engaging in a holding groove of the other panel. Suitable locking hooks and suitable spring bodies with a retaining groove are in WO 2006/133690 A1 described, the relevant content of which is hereby referred to as part of the invention.

Particularly preferably, in a sectional plane spanned by the longitudinal direction and the transverse direction, the retaining groove has a cross-sectional area that can be produced by rotary machining and has rounded run-out areas at the ends of the retaining groove pointing in the transverse direction. Rotational machining is understood as meaning a metal-cutting manufacturing process with a rotating cutting movement on a workpiece that is stationary relative thereto using a rotating machining tool with a geometrically defined cutting edge, for example circular saws with a circular saw blade or Milling with the help of a peripheral milling cutter. In the case of rotary machining, there is no machining with a circular cutting movement assigned to the tool and any feed movement, with the axis of rotation of the cutting movement maintaining its position relative to the tool independently of the feed movement. The three-dimensional shape of the blocking element can be adapted to the shape of the retaining groove, so that surfaces that correspond to one another can face one another and, in particular, can lie flat against one another. The blocking element is preferably based essentially on a cuboid basic shape, so that the blocking element is inserted in the retaining groove outside of the rounded run-out areas of the retaining groove, in particular in a non-moving manner, as a result of which the blocking element can be produced more cost-effectively. Here, use is made of the finding that a smaller extent of the locking element in the transverse direction can also be sufficient to provide the latching functionality of the locking element. The extension of the blocking element can be dimensioned, for example, essentially solely with regard to the latching functionality and the ability to withstand the forces to be expected, which means that it is quite possible that the extent of the blocking element can be selected to be smaller than the extent of the retaining groove. Instead of producing the retaining groove with a pin-shaped milling cutter moving in the transverse direction, the diameter of which corresponds in particular to the extent of the retaining groove in the direction of thickness, it is possible to produce the retaining groove using a circular saw or peripheral milling cutter plunging into the panel body, since there are rounded entry areas at the ends of the retaining groove can be allowed. As a result, the retaining groove can be produced more quickly and cost-effectively.

In a further embodiment, the retaining groove has, in a sectional plane spanned by the longitudinal direction and the transverse direction, a cross-sectional area that can be produced by milling, in particular that is essentially rectangular and rectangular. In the case of panels that are very narrow in the transverse direction, for example, the entire extension of the retaining groove in the transverse direction can be used to accommodate the blocking element. Rounded inlet areas that remain free can thus be avoided.

Another embodiment of the invention relates to a method for producing a panel, which can be designed and developed as described above, in which the retaining groove is machined by rotary machining with a machining tool that is immersed into the panel body on the short side of the panel body and rotates about an axis of rotation running in the thickness direction is produced, wherein the cutting tool dips into the panel body at a distance from the first edge and the second edge, is then moved linearly in the transverse direction relative to the panel body and the cutting tool then emerges from the panel body at a distance from the first edge and the second edge. In particular, the method can be designed and developed as explained above with reference to the panel. Due to the retaining groove running only over a larger portion of the short side due to rotary machining and the blocking element accommodated in the retaining groove, a break-proof and passage-proof panel with a good latching that is gentle on the material is made possible.

In particular, the cutting tool has cutting teeth with respect to the axis of rotation of a main cutting edge pointing essentially in the radial direction and two secondary cutting edges pointing essentially in opposite axial directions, wherein in addition to the main cutting edge the two secondary cutting edges engage the panel body in a cutting and/or smoothing manner to produce the retaining groove . The thickness of the cutting teeth in the direction of thickness can run essentially wedge-shaped in the circumferential direction, so that the tooth flanks of the cutting teeth pointing in the direction of thickness can form free surfaces for a suitable wedge angle of the secondary cutting edges. The secondary cutting edges and the main cutting edge can share a common chip face. With the help of the secondary cutting edges, the surfaces of the retaining groove produced by the main cutting edge and pointing in the thickness direction can be finished in the same machining step, which makes it easier to insert the blocking element into the retaining groove. Scattering of surface roughness and coefficients of friction of the surfaces can be reduced by smoothing the surfaces that face one another with the help of the secondary cutting edges. The cutting tool preferably has cutting teeth with radial extensions of different widths in the axial direction relative to the axis of rotation, the cutting teeth in particular having a radial profile for simultaneously generating both a receiving space and a fastening space for the retaining groove. As a result, part of the incisor can dip less deeply into the material of the panel body, for example to create part of the receiving space, while another part of the incisor, which is offset in the axial direction, can dip deeper into the material of the panel body, for example to additionally create the fastening space .

• Fig. 1: eine schematische Draufsicht auf einen Endbereich eines Paneels,
• Fig. 2: eine schematische geschnittene Seitenansicht des Paneels aus Fig. 1,
• Fig. 3: eine schematische geschnittene Seitenansicht des Paneels aus Fig. 2 während der Fertigung und
• Fig. 4: eine schematische geschnittene Seitenansicht eines Details des Paneels aus Fig. 1 mit einem eingesetzten Sperrelement.

In the following, the invention is explained by way of example with reference to the attached drawings using preferred exemplary embodiments, it being possible for the features presented below to represent an aspect of the invention both individually and in combination. Show it:

• 1 : a schematic plan view of an end area of a panel,
• 2 : a schematic sectional side view of the panel 1 ,
• 3 : a schematic sectional side view of the panel 2 during manufacturing and
• 4 : a schematic sectional side view of a detail of the panel 1 with an inserted blocking element.

This in 1 The panel 10 shown can be used, for example as a floor laminate, to cover a surface of a room. The panel 10 can have a bung groove 12 on the one hand and a bung attachment 14 on the other hand on its respective long sides running in the longitudinal direction 30 . A nominal width B is provided between the long sides of the panel 10, the nominal width B between the edges of the panel 10 on the long sides disregarding the bung groove 12 and the bung lug 14 and considering them non-existent. In particular, that shows Panel 10 on the short sides running in the transverse direction 32 has a locking hook 16 on the one hand and a spring body 18 that can interact with such a locking hook 16 on the other hand. For example, on the short side with the locking hook 16 there is a holding groove 20 into which a blocking element 22 can be inserted so that it cannot move. The retaining groove 20 does not extend over the entire nominal width B, but only over a section bo, so that between the retaining groove 20 and the long side with that of the bung groove 12, a first reinforcement area 24 with an extent t ₁ in the transverse direction 32 and between the retaining groove 20 and the long side with which the bung attachment 12 remains a second reinforcement area 26 with an extension t ₂ in the transverse direction 32 . The retaining groove 20 can be produced by a grooving cutter 40 which is immersed into the short side of a panel body 28 of the panel 10 and is designed in the manner of a circular saw or peripheral milling cutter, so that at the ends of the retaining groove 20 rounded outlet areas 31 with an extension b ₂ in the transverse direction 32 result. The extension b ₁ of the retaining groove 20 remaining between the run-out areas 31 can essentially correspond to the extension of the blocking element 22 in the transverse direction 32 .

As in 2 is shown, the holding groove 20 can have different depths in the longitudinal direction 30 at different heights in a thickness direction 34 of the panel body 28 . The retaining groove 20 thus has a receiving space 36 adjoining the short side of the panel body 28 in the longitudinal direction 30 and a fastening space 38 protruding from the receiving space 36 in the longitudinal direction 30 into the interior of the panel body 28, which differ in their extent in the direction of thickness 34. The extent of the receiving space 36 in the direction of thickness 34 is greater than the extent of the fastening space 38 in the direction of thickness 34.

As in 3 shown, the stepped retaining groove 20 can be produced with the aid of a groove cutter 40 designed in the manner of a circular saw or a peripheral cutter. For this purpose, the slot milling cutter 40 has a cutting tool 42 on the radial outside of which cutting teeth 44 are provided. The cutting teeth 44 have a stepped profile radially on the outside formed so that the main cutting edges 46 are offset in the radial direction. The receiving space 36 with the shorter extension in the longitudinal direction 30 and the fastening space 38 with the greater extension in the longitudinal direction 30 can be produced in a common production step. In addition, the cutting teeth 44 have secondary cutting edges 48 pointing in the direction of thickness 34, so that the entire retaining groove 20 can be produced with a defined surface. The holding groove 20 can be spaced far enough from an upper side 52 of the panel body 28 in the thickness direction 34 that the cutting tool 42 of the groove cutter 40 can be guided past the locking hook 16 . At the same time, the retaining groove 20 is spaced far enough from an underside 50 of the panel body 28 in the thickness direction 34 that the panel body 28 is also sufficiently strong in the region of the retaining groove 20 . Preferably, the holding groove 20 is produced with the aid of the grooving cutter 40, while the upper side 52 of the panel 10 points downwards and the lower side 50 of the panel 10 points upwards, so that the locking hook 16 covering the cutting teeth 44 above can discharge separated chips downwards.

As in 4 is shown, the blocking element 22 can have a fastening projection 60 pressed into the fastening space 38 of the retaining groove 20 . If necessary, the blocking element 22 can also be pressed into a part of the receiving space 36 of the retaining groove 20 that faces the fastening space 38 . The blocking element 22 has a latching web 54 with a latching lug 56 which, when it is locked with another panel, can slide off on the outside of the other panel and in doing so elastically in the direction of the receiving space 36 of the retaining groove 20 and possibly into a receiving pocket kept free by the blocking element 22 can be swiveled in completely or partially. When the panel 10 is in the designated position relative to the other panel, the latching web 54 can elastically snap out of the receiving space 36 so that the latching lug 56 can engage in a corresponding latching groove 58 and bring about latching.

Claims (14)

Panel for covering a surface of a room, with
a panel body (28) extending in a longitudinal direction (30) and a transverse direction (32) for transferring service loads introduced on an upper side (52) of the panel body (28) to an underside (50) of the panel body (28) facing the surface of the room ), wherein the top (52) is spaced from the bottom (50) in a thickness direction (34),
a retaining groove (20) running in the transverse direction (32) in a front short side of the panel body (28) and
a blocking element (22) inserted in the retaining groove (20), in particular essentially immobile,
characterized in that
for an extension b ₀ of the retaining groove (20) in the transverse direction (32) in relation to a nominal width B of the panel body (28) between a longitudinally running first edge and a longitudinally running second edge of the panel body (28) 0.50 ≤ b ₀ /B ≤ 0.97, in particular 0.75 ≤ b ₀ /B ≤ 0.95, preferably 0.85 ≤ b ₀ /B ≤ 0.93 and particularly preferably b ₀ /B = 0.90 ± 0.02 is applicable. Panel according to Claim 1 , characterized in that in the transverse direction (32) a first reinforcement region (24) with an extension t ₁ in the transverse direction (32) is formed between a first end of the retaining groove (20) pointing towards the first edge in the transverse direction (32). is formed in the transverse direction (32) between a second end of the retaining groove (20) pointing towards the second edge in the transverse direction (32) a second reinforcement region (26) with an extension t ₂ in the transverse direction (32), wherein for the first gain range (24) 0.005 ≤ t ₁ /B ≤ 0.090, in particular 0.015 ≤ t ₁ /B ≤ 0.050, preferably 0.020 ≤ t ₁ /B ≤ 0.030 and particularly preferably t ₁ /B = 0.025 ± 0.002 and/or for the second Gain range (26) 0.005 ≤ t ₂ /B ≤ 0.090, in particular 0.015 ≤ t ₂ /B ≤ 0.050, preferably 0.020 ≤ t ₂ /B ≤ 0.030 and more preferably t ₂ /B = 0.025 ± 0.002, with the proviso that t ₁ + b ₀ + t ₂ = B applies. Panel according to Claim 2 , characterized in that the panel body (28) has a bung groove (12) extending into the panel body (28) on the first edge and a bung attachment (14) protruding from the panel body (28) on the second edge. t ₁ <t ₂ , in particular 0.75≦t ₁ /t ₂ ≦0.99, preferably 0.80≦t ₁ /t ₂ ≦0.95 and particularly preferably 0.85≦t ₁ /t ₂ ≤ 0.90 applies. Panel according to one of Claims 1 to 3 , characterized in that for an extension b ₁ of the blocking element (22) in the transverse direction in relation to the nominal width B of the panel body (28), 0.40 ≤ b ₁ /B ≤ 0.95, in particular 0 .50 ≤ b ₁ /B ≤ 0.90, preferably 0.60 ≤ b ₁ /B ≤ 0.80 and particularly preferably b ₁ /B = 0.70 ± 0.05. Panel according to one of Claims 1 to 4 , characterized in that a frictional connection of the locking element (22) in the retaining groove (20) is provided exclusively by clamping forces pointing in the direction of thickness (34). Panel according to one of Claims 1 to 5 , characterized in that the locking element (22) has a latching web (54) which can be elastically bent at least partially in the direction of the holding groove (20). Panel according to one of Claims 1 to 6 , characterized in that the retaining groove (20) has a receiving space (36) adjoining one end face of the short side for receiving a part of the blocking element (22), in particular for temporarily receiving an elastically flexible latching web (54) of the blocking element (22), and a fastening space (38) adjoining the side of the receiving space (36) pointing away from the end face for the frictional and/or positive fastening of a fastening attachment (60) of the blocking element (22), wherein the extent of the fastening space (38) in the direction of thickness (34) is smaller than the extent of the receiving space (36) in the direction of thickness (34). Panel according to Claim 7 , characterized in that the blocking element (22) bears against both surfaces of the receiving space (36) pointing in the direction of thickness (34), in particular with a clamping force, the blocking element (22) in particular having a force extending into the receiving space (36). Accommodating pocket for temporarily accommodating an elastically flexibly attached latching web (54) of the blocking element (22). Panel according to one of Claims 1 to 8 , characterized in that the panel body (28) on the short side forming the retaining groove (20) has a locking hook (16) protruding in the longitudinal direction (30) from the short side of the panel body for latching in a receiving groove of a further panel having. Panel according to one of Claims 1 to 9 , characterized in that the holding groove (20) in a sectional plane spanned by the longitudinal direction (30) and the transverse direction (32) has a rounded run-out area which can be produced by rotary machining at the ends pointing in the transverse direction (32) of the Retaining groove (20) having having cross-sectional area. Panel according to one of Claims 1 to 9 , characterized in that the retaining groove (20) has a cross-sectional area which can be produced by milling and which is in particular essentially rectangular and rectangular in a cutting plane spanned by the longitudinal direction (30) and the transverse direction (32). Method for producing a panel according to one of claims 1 to 10, in which the holding groove (20) by rotary machining with a on the short side of the panel body (28) immersed in the panel body (28) and by an in Thickness direction (34) extending axis of rotation rotating cutting tool (42) is generated,
wherein the cutting tool (42) dips into the panel body (28) at a distance from the first edge and the second edge,
subsequently moved linearly in the transverse direction (32) relative to the panel body (28) and
subsequently the cutting tool (42) emerges from the panel body (28) spaced from the first edge and the second edge. Method according to Claim 12, in which the cutting tool (42) has cutting teeth (44) with, in relation to the axis of rotation, a main cutting edge (46) pointing essentially in the radial direction and two secondary cutting edges (48) pointing essentially in opposite axial directions, wherein in addition to the The main cutting edge (46) engages the two secondary cutting edges (48) to produce the holding groove (20) by cutting and/or smoothing the panel body (28). Method according to Claim 12 or 13, in which the cutting tool (42) has cutting teeth (44) with radial extensions of different widths in the axial direction in relation to the axis of rotation, the cutting teeth (44) in particular having a radial profile for the simultaneous creation of both a receiving space (36 ) and a fastening space (38) of the retaining groove (20).

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