DE10318072A1 - Compound plate, for a kitchen working surface, has an upper stone plate bonded to a lower carrier plate by an intermediate hard foam layer to reduce the plate weight - Google Patents

Abstract

The compound plate has an upper stone plate (4) and a lower carrier plate (2) of a hard fiber or wood, with an intermediate layer (3) of a lightweight material. To produce the compound plate, initially the upper stone plate and the lower carrier plate are positioned in a vertical stack with a gap between them, held apart by adjustable limits, to form a shell with a stone front plate (7). The lightweight material, with a soft consistency, is fed into the gap under pressure to give an adhesive bond with the outer layers as a hard foam. Provision is made in the foam structure to take reinforcement profiles (9) and/or hollow zones (8) for cable channels and the like. The finished plate is removed from the limits.

Description

The invention relates to a method for producing a composite panel an upper stone slab, a lower support slab and one in between arranged layer of light material and a composite panel.

Various areas of application come into play for such composite panels consideration; the plate according to the invention is preferred for Kitchen countertops used.

To reduce the weight of stone slabs, in which mainly the The visual impression of the surface is crucial, especially for panels made of natural stone, various composite panels are known, in which the each upper layer consists of stone.

Various methods for producing a Composite plate with an upper stone plate, a lower support plate and one interposed layer of light material and a variety of known composite panels.

According to DE 295 10 629 U1 a natural stone composite panel is known in which a core plate made of light material with a natural stone plate on both sides is glued.

The disadvantage of this natural stone composite panel is the high technological Effort for gluing the individual layers. The main disadvantage is that of Achieving a very accurate overall thickness of the composite panel required high effort; even if the exact thickness of the individual layers is observed is due to the variable thickness of the adhesive layers to achieve one exact dimensional accuracy of the composite panel is not possible.

According to DE 39 40 102 there is a method for producing composite panels Surfaces made of natural stone and a carrier plate, which can be made of wood, known, in which the thickness of the natural stone slab is less than 7 mm. The natural stone slab is connected to the carrier plate by under other polyester resin and glass fiber fleece thin on the natural stone slab be applied; the carrier plate is successively with adhesion promoter, Apply adhesive and adhesive bridge. After the adhesive bridge has hardened The composite is made of the carrier board and the polyester layer of the natural stone slab produced between the two layer materials by means of adhesive.

Another disadvantage of this process is the very high technological level Gluing effort. Due to the required arrangement of several - if thin - additional layers for gluing it is with this one Method not possible to get an exact value for the total thickness of the Composite plate must be observed.

According to DE 195 47 123 A1 is a composite panel made of natural stone and wood, especially a kitchen worktop, with a surface plate Natural stone, a wooden base plate and a thin, fiber-reinforced one Intermediate layer, which contains glue and the surface plate with the Carrier plate glued, known, in which the surface plate made of natural stone thicker than 1 cm and the wooden support plate has a thickness of less than approx. 3 cm and the total thickness of the composite panel is 2-6 cm.

A disadvantage of this composite panel is the relatively large thickness of the Carrier board made of wood, which has a relatively high bulk density and thus leads to a relatively high weight of the composite panel, as well as the high technological effort to glue these layers. In particular is disadvantageous here, too, that adherence by sticking the layers exact dimensional accuracy is also not possible.

According to DE 16 59 179 is a plate, board or tile that consists of at least three there are known layers bonded together by an adhesive, in which a cellular or porous intermediate layer made of sheet metal or Plastic between an upper outer layer of marble and one relatively thin sheet metal or a corresponding skin with a high strength is arranged.

The structure described in this document enables relative low weight of the composite panel good strength properties; adversely is, however, the high manufacturing cost of this composite panel. Further is the adherence to exact dimensional accuracy due to the large number of each other adhesive layers not possible.

According to DE 101 19 552 A1 is a method for producing a composite panel known, being on both sides of a natural stone slab in a predetermined Distance one rear plate is arranged, the two Spaces between the natural stone slab and the two slabs with filled with granules and then foamed. Subsequently the natural stone slab is cut lengthways in its central plane. First of all the natural stone slab on both sides with a stabilizing layer in shape stabilized a mineral fiber mat embedded in a resin; as back plate becomes a stabilizing layer in the form of one in one Resin embedded mineral fiber mat used.

The disadvantage of this method is that it is divided up as required the natural stone slab in its central plane two different thicknesses Composite panels can arise; in any case, also with this procedure an exact dimensional accuracy of the composite panel is not possible.

In the aforementioned document is also a composite panel with a Natural stone top layer, lying on a back, a foam containing carrier layer is described, in which the carrier layer a stabilizing layer for natural stone in the form of a resin embedded mineral fiber mat, one between this and another Stabilizing layer in the form of a mineral fiber mat embedded in resin embedded intermediate layer and a rigid foam, the Top layer has a thickness of 3-8 mm.

The composite panel described has a high weight with low weight Strength values on; however, the high outlay for Production of this composite panel, mineral fiber mats being expensive must be embedded in a resin, and on the other hand because of the small thickness of the cover plate relatively high temperature sensitivity Composite plate, for example when putting hot pots on Kitchen worktops can cause cracks.

The invention has for its object a composite panel and a Processes for their manufacture specify the relatively light weight has good mechanical strength properties and also against selective heating is insensitive, whereby at low technological effort to maintain an exact total thickness of the Composite plate is made possible.

According to the invention, the object is achieved by a method which the Claim 1 specified features and with a composite panel, which the contains features specified in claim 5, solved.

Advantageous embodiments of the method and the composite panel are shown in specified in the subclaims.

The method for producing the composite panel provides that the upper stone slab or an upper support plate and the lower support plate itself standing opposite between adjustable, fixed stop elements are arranged. The stop elements form a formwork, so that between the stone slab or the upper support plate and the lower Carrier plate a defined clear distance is maintained.

Then the light material layer with a first soft consistency under pressure between the stone slab or upper support plate and the lower Carrier plate introduced and foams there independently. The glue Stone slab or the upper support plate and the lower support plate with the to a hard foam-setting light material layer. Then become solved at least some stop elements and the so produced Composite panel can be removed.

It is to facilitate transportation and to improve stability expedient that the light material layer between an upper support plate and the lower support plate is inserted, and the stone slab after Curing the light material layer is glued.

An advantageous embodiment of the method provides that before Introduction of the light material layer closed and / or open profiles inserted between the stone slab and the lower support plate and fixed there become. This can both achieve an increase in strength as well Fittings or cables to be mounted inside the plate are conveniently attached become.

Another advantageous embodiment results from the fact that before the A front panel is introduced with the initially soft-consistent light material layer made of stone between or in front of the stone slab and the lower support plate is arranged, the space between stone slab and lower Carrier plate closes to the front.

In the composite panel according to the invention, a light material layer forms the preferably made of polyurethane, between a stone slab made of natural or stone and the lower support plate one under pressure foamed and hardened hard foam layer that without use an additional adhesive by bonding the stone slab with the lower support plate connects, the thickness of the stone slab between 6 mm and 13 mm and the thickness of the lower support plate between 3 mm and 8 mm is.

The total thickness of the composite panel is approximately 30 to 50 mm, preferably approx. 40 mm.

The light material layer can be directly between the stone slab and the lower support plate may be arranged or between an upper and a lower support plate. In the latter case, the stone slab on the upper support plate attached, preferably by gluing.

It is also possible on one or more front sides of the composite panel stone front panels are arranged. It is particularly advantageous making sure that the front panel is attached by the foamed Lightweight layer is possible without using an additional adhesive.

The support plates usually consist of a hard fiber material or Wood. For special applications, support plates are also made from one vapor-tight material used. See an advantageous embodiment for this before that the lower support plate is constructed in two layers, with one Layer of hard fiber or wood a second, vapor-tight layer Aluminum is arranged.

Reinforcement profiles and / or closed can be in the light material layer or open cavities for receiving functional elements, such as Cable ducts and the like, with foam.

The invention has a number of advantages.

By introducing an initially soft-consistent light material, the takes place under pressure, the light material then foams, between a support plate fixed in formwork and one from the support plate spaced stone slab succeeds an exactly dimensionally stable Manufacture composite panel. It is particularly advantageous as a light material To use polyurethane foam with which high strength is achieved. The inventive method also allows for additional Reinforcement of the composite panel support profiles or hollow profiles that as Cable ducts can be used in the layer of light material to arrange. By using a wooden support plate, the Production of a composite plate that can be screwed on from the support plate side.

The invention is explained in more detail below with the aid of an exemplary embodiment explained.

In the accompanying drawing:

Fig. 1 shows a section through a composite panel with an attached between two rigid panels foam layer,

Fig. 2 shows a section through a composite panel with an aluminum layer on the lower support plate,

Fig. 3 shows an arrangement with stone slab and

Fig. 4 shows the manufacture of the composite panel.

Fig. 1 shows a section through a composite panel, in which an existing rigid polyurethane foam lightweight material layer 3 is arranged as an intermediate layer between the upper support plate 1 and the lower supporting plate 2. The support plates 1 and 2 are preferably designed as hardboard, but can also be made of other materials, such as wood.

FIG. 2 shows an embodiment in which cavities 8 for accommodating functional elements such as cable ducts, pipes and the like are provided in the light-material layer 3 . Furthermore, there is a reinforcement profile 9 in the light material layer 3 , which serves to increase the load-bearing capacity of the composite panel. The light material layer 3 was introduced by first introducing soft-consistent light material under pressure between the upper support plate 1 and the lower support plate 2 , foaming there independently and gluing the two support plates 1 and 2 to one another during hardening.

Fig. 3 explains an application example in which the composite plate is provided with a glued stone plate 4 , which consists of composite stone or natural stone. It is of course also possible to use a stone slab made of stone. The thickness of the stone slab 4 is 13 mm, the thickness of the two support plates is 4 mm and the thickness of the rigid foam intermediate layer 3 is 22 mm. The total thickness of the composite panel is exactly 40 mm. At the front of the composite plate, a front plate 7 is arranged, which consists of the same material as the stone plate 4 . It is also possible to attach a front plate 7 consisting of plastic elements. The lower support plate 2 is expediently provided with an aluminum layer 10 . This is particularly appropriate when the composite panel is to be made vapor-tight, which is very advantageous, for example, for kitchen worktops that are attached above dishwashers.

The manufacturing process is illustrated in FIG. 4. The figure shows a section through a composite panel according to the invention, which is arranged between adjustable and fixable stop elements 11 . The composite panel is formed by a stone slab 4 , which consists of composite stone or natural stone, a light material layer 3 serving as an intermediate layer, and a lower support plate 2 , which consists of wood. The thickness of the stone slab 4 is 10 mm, the thickness of the lower wooden support plate 2 is 4 mm and the thickness of the light foam layer 3 consisting of hard foam is 26 mm. The total thickness of the composite panel is exactly 40 mm. At the edge of the composite plate, a front plate 7 is arranged, which consists of the same material as the stone plate 4 . Reinforcement profiles 9 and cavities 8 are arranged in the light foam layer 3 made of hard foam, the cavity 8 shown on the left serving as a cable duct for guiding lines through the composite panel and the reinforcement profile 9 shown on the right for reinforcing the load-bearing capacity of the composite panel. The light material layer 3 was introduced by first introducing soft-consistent polyurethane under pressure between the stone slab 4 and the lower support plate 2 , foaming there independently and gluing the stone slab 4 and the lower support plate 2 to one another during hardening. Lateral leakage of the swelling light material was largely prevented by the front plate 7 arranged on the common edges of stone plate 4 and lower support plate 2 ; the front panel 7 , which can also be attached to a plurality of side surfaces, is likewise firmly connected to the composite panel after the light material layer 3 has hardened. The light material layer 3 , which has swelled out of the joints between the stone plate 4 and the front plate 7 or between the lower support plate 2 and the front plate 7 during its swelling, can be easily removed after curing.

It is also possible to use 7 plastic elements as front panels; it is also possible to use a lower support plate 2 , which is itself designed as a composite panel - in particular, the use of an aluminum-coated wood or hardboard is useful if the composite panel is to be made vapor-tight, such as for kitchen worktops above dishwashers. For the stone slab 4 , slabs of natural stone as well as of stone or of a mineral material can be used. REFERENCE SIGN LIST 1 upper support plate
2 lower support plate
3 light material layer
4 flagstone
5 screw
6 additional part
7 front panel
8 cavity for profiles
9 reinforcement profile
10 aluminum layer
11 stop element

Claims (17)

1. A method for producing a composite plate with an upper stone plate ( 4 ), a lower support plate ( 2 ) and a light material layer ( 3 ) arranged between them, characterized in that
that first the upper stone slab ( 4 ) and the lower support slab ( 2 ) are arranged opposite or lying one above the other between adjustable, fixed stop elements ( 11 ) that form a formwork, whereby between the stone slab ( 4 ) and the support slab ( 2 ) a defined clear distance is maintained,
that the light material layer ( 3 ) with an initially soft consistency is then introduced under pressure between the stone slab ( 4 ) and the lower support plate ( 2 ), foams up there independently, adheres to the stone slab ( 4 ) and the lower support plate ( 2 ) and closes sets a hard foam and that at least some stop elements ( 11 ) are then released to remove the composite panel produced. 2. The method according to claim 1, characterized in that before the introduction of the light material layer ( 3 ) closed and / or open profiles between the stone slab ( 4 ) and the lower support plate ( 2 ) are introduced and fixed there. 3. The method according to claim 1 or 2, characterized in that before the introduction of the initially soft-consistent light material layer ( 3 ) between the stone slab ( 4 ) and the support plate ( 2 ) on parallel edges of the plates ( 4 , 2 ) at least one front plate ( 7 ) is arranged, which close the space between the stone slab ( 4 ) and the lower support plate ( 2 ) to form a cavity. 4. The method according to any one of claims 1 to 3, characterized in that the light material layer ( 3 ) between an upper support plate ( 1 ) and the lower support plate ( 2 ) is introduced, and the stone slab ( 4 ) after the curing of the light material layer ( 3 ) is glued. 5. Composite panel, in particular composite panel manufactured according to one of claims 1 to 4, with a stone plate ( 4 ), a lower support plate ( 2 ) and an intermediate layer of light material ( 3 ), characterized in that the light material layer ( 3 ) one between the stone plate ( 4 ) and the lower support plate ( 2 ) is foamed and hardened hard foam layer under pressure development, which connects the stone plate ( 4 ) with the lower support plate ( 2 ) without using an additional adhesive, the thickness of the stone plate ( 1 ) being between 6 mm and 13 mm and the thickness of the lower support plate ( 2 ) is between 3 mm and 8 mm. 6. Composite panel according to claim 5, characterized in that the light material layer ( 3 ) consists of polyurethane. 7. Composite plate according to claim 5 or 6, characterized in that the light material layer ( 3 ) is arranged directly between the stone plate ( 4 ) and the lower support plate ( 2 ). 8. Composite panel according to claim 5 or 6, characterized in that an upper support plate ( 1 ) is arranged between the light material layer ( 3 ) and the stone plate ( 4 ), on which the stone plate ( 4 ) is glued. 9. Composite panel according to one of claims 5 to 8, characterized in that a stone front panel ( 7 ) is arranged on a front side of the composite panel. 10. Composite panel according to claim 9, characterized in that the front panel ( 7 ) by the foamed light material layer ( 3 ) is fastened by adhesive bonding without using an additional adhesive. 11. Composite panel according to one of claims 5 to 10, characterized in that the support plates ( 1 , 2 ) consist of hard fiber or of wood. 12. Composite panel according to one of claims 5 to 10, characterized in that the support plates ( 1 , 2 ) consist of a vapor-tight material. 13. Composite panel according to claim 11 or 12, characterized in that the lower support plate ( 2 ) is constructed at least in two layers, a second, vapor-tight layer of aluminum being arranged on the layer of hard fiber or wood. 14. Composite panel according to one of claims 5 to 13, characterized in that in the light material layer ( 3 ) reinforcement profiles ( 9 ) and / or closed or open cavities ( 8 ) for receiving functional elements, such as cable ducts and the like, are also foamed. 15. Composite plate according to one of claims 5 to 14, characterized in that the stone plate ( 4 ) consists of natural stone. 16. Composite plate according to one of claims 5 to 14, characterized in that the stone plate ( 4 ) consists of stone. 17. Composite plate according to one of claims 5 to 14, characterized in that the stone plate ( 4 ) consists of a mineral material.