DE202006016659U1 - Arrangement comprising slab, member or other geometry of stone is stabilized in a support which contains stone fibers - Google Patents

Abstract

The arrangement comprising a slab (1), a member or other geometry of natural stone, stoneware, artificial stone, concrete, ceramic or material with glass content, subsequently referred to as stone, is stabilized in a support (2) which contains stone fibers. The stone fiber may be a basalt fiber. The matrix of the support has an epoxy resin, polyester resin, phenolic resin, polyimide resin, cyanate ester resin, melamine resin, polyurethane resin or silicon resin base.

Description

The The present invention relates to the stabilization of stone in the broader sense, that is Natural stone, artificial stone of all kinds, concrete and other earthenware, as well as ceramics up to glass-containing substances - in the following Stone or earthenware called - the through a brittle and at risk of breakage Structure are marked. Here are especially natural stones like Granite, basalt, granite-like Rocks such as gneiss, as well as marble, limestone, high pressure resistant modern Ceramics, glass ceramic or glass to mention, as well as all other Materials of stone or ceramics, natural or artificial created earthenware, which are usually high pressure resistant.

These Materials are referred to below as stone or stoneware. On the one hand, they are characterized by a high load capacity under pressure, however, are almost completely unstable at tensile and bending load, especially if you want to thin and material-saving, philigran and especially lightweight designed should be.

These are mainly thin stoneware slabs or stone rods, as well as any conceivable geometry that is used in construction, in construction, in mechanical engineering and plant construction. Stone slabs are increasingly being used in façade construction and as countertops, in particular kitchen countertops, but also in other areas, such as furniture and fittings construction and in the construction industry, as stair steps, wall coverings and floor tiles, as well as generally in construction. Stein as a supplier for all kinds of parts, for example when stabilized with carbon fibers, as in the EP 106 92 20 described, have meanwhile found their way into industrial application.

carbon fibers however, are very expensive and energy consuming to manufacture and can - at least partially - through modern other fibers added, or depending on the application also be replaced.

The present invention proposes a way to such thin designed geometries of stone or stone rods and stone slabs or ceramic or artificial stone slabs to sustainably stabilize in a cost-effective manner, that they remain stable over wide temperature ranges, that is, that the stone is protected from breakage is. Also stabilized under temperature-controlled thermal expansion To stay that way, the stone is protected from breakage is the challenge for the solution described here.

Thin, but To stabilize even thicker stone slabs so that they are possible stay straight, should be another objective of the present invention be. To reach this goal, it is not only necessary, the earthenware or to stabilize ceramic plates against traction and associated breakage, but also one on the stone side to be stabilized at the interface between stablisierendem stone and stabilizer a pressure gradient set practically to zero, so the stone slat neither to the one side, to the other side in changing temperatures is bent and thus the visible or usable area over a large area straight and just stay. Such a way suggests the invention, the feature The flatness of the flagstone in wide temperature ranges is an important one Purpose of the solution described here. The path ensures that both Stone, as well as ceramics among the most diverse thermal conditional mechanical loads, as well as purely mechanical Loads are stabilized so that they through one, for the respective Use and load cases suitable, stabilization against mechanical destruction by tearing the stone rods or stone slabs on the one hand, and especially in addition to mechanical breakage protected become. The dimensional stability at temperature change Within the weather-related areas is also important.

core the solution, that for thin stone slabs at the It is best to find the most suitable stabilizing agent, the Gesamtauskehnungskoeffizent of the stone stabilizing material stabilizing the stone Set side between flagstone and stabilizer material so that he is similar is with the total expansion coefficient of the flagstone itself.

The Invention is based on the stabilization of stone or ceramics through a partial or full area mounted on the stone fibrous carrier material, which has a Ausdehungsverhalten has, as possible, the stone comes close. For that will be in the present invention stone fibers, in particular basalt fibers used.

So far, lightweight designs are known in which, as in this new invention as thin as possible natural stone layer with fiber matrix are protected from breakage and area enhanced by an additional substructure of various substrates and carrier forms, such as frames, honeycomb and similar constructions and is made strong, respectively it is only possible to thinly perform stone geometries such as stone slabs or stone rods. The support material has usually been chosen from the standpoint that it is determined with sufficient mechanical strength mainly by the use of conventional materials such as steel and aluminum, or such layers, of a similar or the same material, such as consist of material to be stabilized. More recent methods suggest glass fibers, aramid fibers or carbon fibers as a carrier material. Each of these fibers has a certain physical advantage, but also specific disadvantages, depending on the application. More suitable of the total spectrum of physical properties seems to have the stone fiber itself to stabilize stone. The coefficient of expansion, tensile strength and tensile elongation are closest to the physical properties of the stone. In addition, for example, straight, corrugated or honeycomb-shaped metal or aluminum sheets, wood panels and steel or wooden frames, or other stone slabs are used as support material, the thin stone geometries may have a thickness of up to 15 mm without breaking. Such additional stabilizing measures are also proposed in this invention, wherein the characteristic feature of the basic use of stone fibers are proposed to be applied as a stabilizing layer directly on the stone in order to make the stabilized stone geometries much philigraner can.

One additional Stabilization process is in combination with stone fibers also the use of glass fiber, carbon fiber or aramid fiber laminates to apply, which together with the stone or basalt fiber the Stone more or less large area or even over the entire surface stabilize. The result is a pressure and tension loadable Stone geometry, which in normal applications for adequate stabilization of the stone for thermal and mechanical load cases ensures.

In most cases is a sufficient stabilization already with a thin film achieved by stone fiber matrix, which has both a stabilization in the thermal, as well as in the mechanical load case ensured.

By The prior art is described as components made of stone or Ceramic, the extreme thermal-static, such as thermal and mechanical-dynamic Have to take loads, when stabilized with carbon fibers. Similar and sometimes even better results are achievable with rock fibers, and that too less Costs.

The Task, the slope of thin Natural stone and / or ceramic plates for breaking or tearing too to safely counteract much lighter designs, is by additional stabilizing carrier or carrier materials solved. For this purpose, a carrier material used, which is a similar has a low coefficient of expansion, as stabilized with stone fibers Stone slab, and which has a very low specific weight Has.

The carrier material, hereinafter referred to as carrier, consists of a fiber-reinforced matrix, which is a synthetic resin or optionally itself a ceramic material. It come as a fiber material stone fibers, especially basalt fibers are used, which withstand high tensile loads and expand only minimally under heat, so have a very small thermal expansion coefficient, which is usually smaller than that of the stone material to be stabilized. As a result, stone rods, stone slabs and other stone geometries are protected in particular against cracks due to overstretching and heat, and the fracture is counteracted by mechanical stress perpendicular to the earthenware. In addition, such plates - depending on the application - additionally for mechanical stresses - as in EP 106 20 92 described with an additional Snadwicheinlage - made stable. This is also done in this invention by a layer consisting of a sandwich of egg-box geometry with additional lower plates, or a honeycomb geometry, other geometries of intermediate layers or the so-called expanded glass. Expanded glass is a foamed glass material, which is characterized by a high compressive strength, a low specific weight and a very low coefficient of thermal expansion.

Thin flagstones, for example, worktops - especially kitchen worktops - and facade cladding are protected by the invention, in particular with simultaneous thermal and mechanical stress and the associated carrier material elongation, which would lead to cracks or surface fractures of the supported stone material, secure against cracking. The usually resulting, under certain circumstances microscopic hairline cracks, which lead to rapid deterioration of the stone, especially when exposed to outdoor, or as a countertop in the kitchen area constantly changing temperatures, mechanical pressure loads and water and frost are completely excluded by the invention without having to resort to a massive design. The overall plate including the stabilization layer can thus be extremely lightweight, without breaking or warping or shuffle, as the jargon says. Even the thinnest flagstones can be made using the invention while maintaining the stability one is used to from solid stone material. The same applies to carriers in the construction sector, in the automotive industry and if necessary. also in aircraft construction in the pressure-loaded zones. Generally, the newly formed composite stone with Stone fiber in many areas steel and aluminum replace. Natural stone has a specific weight equal to that of aluminum and the compressive strength of a normal structural steel, which means that stone, especially natural stone, which is now protected against breakage by the stone fiber therefore in thermal and mechanical load case, because they have a smaller Expansion coefficient has, as the stone itself, especially in lightweight construction, which is a novelty in the art and is therefore important because stone is available in unlimited masses as a cheap material anywhere in the world and very energetically won and easily mined can.

With Help of the use of, for example, temperature-stable epoxy resins, Polyester resins, resins based on phenolic, polyimide, cyanate, melamine, Polyurethane or silicone base, called matrix, in combination with Stone fibers that have a small coefficient of thermal expansion As a stone, now will be a safe stabilization of stone rods, the in turn, the stabilization of fiber-structured components as well as stone components can serve themselves, possible.

It gets over it addition to the requirement, the mechanical strength and temperature resistance of thin to thinnest To optimize stone geometries so that the total expansion coefficient a stone stick or a stone slab in wide temperature ranges in the stabilizing layer to the same or similar Value can be adjusted to, among other things, the bowls of To avoid stone slabs and still realize a lightweight construction. At the moment where it succeeds in stretching the stabilizing layer Made of stone fiber by introducing a certain bias smaller To hold on, as the stretching of the stone itself, one becomes on this Way stabilized stone rods even within certain limits, they can bend without breaking them. Base for this Knowledge is that made in the context of this invention Observation that, in particular, natural stone is actually non-destructive compresses, ie e.g. a stone bar will shrink in length due to pressure leaves.

The Invention is realized by the use of partial or full-surface coating of Stone slab or a stone stick with a stone fiber laminate, the mixing ratio of Stone fiber and resin can be adjusted so that the coefficient of expansion smaller stone to be stabilized and the rock fiber laminate or at least practically identical. This can also be done by a Mixture of different additional fibers be achieved.

One of the many possible embodiments of the invention describes a plate of stoneware ( 1 ) unilaterally with a stone fiber roving ( 2 ) is stabilized ( 1 ). The connection between stone and fiber is z. B. produced by a temperature-stable epoxy resin, which can be thermally stable depending on the field of use and their total coefficient of expansion of fiber and matrix should be similar to that of the stone plate to be stabilized.

2 shows this second embodiment of the invention as a more or less long, relatively thin stone rod ( 1 ) enveloping with a layer of stone fiber matrix ( 2 ) whose coefficient of expansion is less than or equal to or at most only slightly larger than that of the stone rod to be stabilized.

3 shows a flagstone ( 1 ), on whose stabilization layer of stone fiber matrix ( 2 ) another layer ( 3 ) is made up of expanded glass. A special variant is created when the two stabilization layers ( 2 ) and ( 3 ) in sum have an identical expansion behavior as the stone slab to be stabilized ( 1 ).

4 shows another special variant of the flagstone ( 1 ), on whose stabilization layer of stone fiber matrix ( 2 ) another layer ( 3 ) is made of stone, which has the same or identical expansion behavior as the stone slab to be stabilized ( 1 ).

Claims (11)

Arrangement with a plate, a rod or other geometry of natural stone, earthenware, artificial stone, concrete, ceramics, glaschaltigem material - in the following stone called - which unilaterally or bilaterally partially or wholly, or completely enveloping with a fibrous matrix - in the following carrier called - Is stabilized, characterized in that the carrier contains rock fibers. Arrangement according to claim 1, characterized that the Stone fiber is a basalt fiber. Arrangement according to claim 1, characterized that the Matrix of the carrier an epoxy resin, polyester resin, phenolic resin, polyimide resin, cyanate ester resin, Melamine resin, polyurethane resin or silicone resin base has. Arrangement according to claim 1, characterized that the Matrix has a ceramic or waterglass base. Arrangement according to claim 1 to 4, characterized in that the carrier comprises a mixture different additional fiber materials, such as glass fibers or carbon fibers, is or consists of meheren different fiber layers. Arrangement according to Claims 1 to 5, characterized that under the stabilizing fiber matrix another carrier - e.g. in Shape of an egg box geometry, a milled phenolic resin impregnated paper, a honeycomb structure or made of expanded glass or the same or a similar one Stone material, such as the stone to be stabilized for additional mechanical Stabilization is appropriate. Arrangement according to Claims 1 to 6, characterized that the Matrix and fiber - if necessary also along with the extra Stabilization layer - one Overall expansion coefficients are similar that of the stone to be stabilized. Arrangement according to claims 1 to 6, characterized that the expansion coefficient of the stone fiber matrix is smaller or equal to that of the stone to be stabilized. Arrangement according to claim 1 to 8, characterized that the Stone fiber-stabilized stone as a rod-shaped structural component in the Construction and mechanical engineering is used. Arrangement according to claim 1 to 9, characterized that one Rock stone stabilized stone plate as a worktop, in particular as a kitchen worktop Use finds. Arrangement according to any one of claims 1 to 10, characterized in that in the case that ceramic in the manner defined in the claims 1 to 10 manner stabilized, the stone fiber incorporated into the ceramic material is and thus the material to be worn together with the stone fiber itself to the carrier material becomes. The material thus obtained can thus, for example, as Brake pad or self-stabilized or self-stabilizing Component to be used.