DE202011104783U1 - Structural parts and components made of fiber-reinforced basalt rock - Google Patents

Abstract

Arrangement of a plate that is as thin as possible depending on the load situation or other geometries made of stone fiber-coated on one or both sides, hereinafter referred to as a carrier plate, characterized in that the carrier consists of basalt stone.

Description

The present invention relates to the development of fiber reinforced earthenware building and construction parts which can be used for building buildings, houses, bridges and other building use applications in the form of supporting columns, longitudinal and transverse beams or whole house walls, and as ( self-supporting longitudinal beams or stiffening beams in the structural area of machines, vehicles and aircraft or other applications in which load-bearing supports and beams are required.

The challenge in the structural implementation of parts that were previously produced partly on one-component materials such as metal, concrete or wood, must be made more and more of artificial or hybrid materials, as against the background of now no longer denied climate change wood As a mass application is in short supply and metals and concrete are charged with high production energy costs. For this reason, it is necessary to manufacture such components from a composition of several new materials so that they are less energy-intensive and if possible have the same or better strength values.

The state of the art is fiber-coated earthenware, in which granite was usually considered the stone of choice, since granite has a certain porosity, which is necessary on the one hand to make the connection of fiber and stone on synthetic resins or other resins, on the other hand, the porosity of Granite serves to make such components flexible by means of biasing through the fiber. The porosity ensures a non-destructive volume compressibility, which is used for a sufficient tensile reserve.

With components produced in this way, it is possible to replace aluminum and steel at half the weight, but at a much higher cross-section, than with steel, because the compressive strength of granite does not match that of steel.

For this reason, natural stones were sought, which have an even higher compressive strength, than granite.

Recent experiments with basalt rock provide the desired results. Basalt is with up to 400 N / mm ² compressive strength with only a little - 10% - higher specific gravity significantly more pressure stable than granite, which has only about 160-220 N / mm ² compressive strength. The basalt stone is also more abundant than granite. The disadvantage of basalt is that the surface is very rarely perceived as visually appealing, which, however, plays no role in construction parts with a purely supporting function.

Although the porosity required to bond with the resin is significantly lower for many basalt grades than for granite, it is large enough for most basalts to provide good interfacial fiber-basalt traction across the matrix, which maintains sufficient surface porosity Basalt finds to ensure a sufficiently strong bond.

The aim is to produce components that provide an optimized load-to-weight ratio, and here the basalt is almost a factor of 2 superior to granite, and especially in its own manufacture, it is equipped with a lightweight CO ₂ rucksack, in terms of manufacturing energy Granite is also superior in relation to carrying capacity, not to mention the comparison with the production of concrete and steel, which in itself requires much more energy than fiber-stabilized earthenware such as granite or gneiss.

The present invention accordingly describes a sandwich of one or more sheets of basalt or basalt-like stone with high compressive strength values above 220 N / mm ² and a sufficient porosity by means of, for example, epoxy resins or other adhesive-like networking possibilities - with a fiber fabric is coated. In most cases it will be useful, but not necessary, to make this composite of basalt, fiber material and resin so that the fibrous layer already pretensions the stone slabs. This bias should be generated by such a type of fiber, which no longer loses this bias. Most suitable carbon fibers and stone fibers have proven this, such as. In EP 106 20 92 explained.

These panels can be single-sided or double-sided, cut into strips and assembled into support profiles by holding a final full cover of fibrous material holding the panels together.

Such carriers can serve as supports or transverse beams in construction and they can be prefabricated and finished in construction. The ceiling structures are placed on the transverse support elements or columns. The carrier elements combine all structural and structural requirements of a truss structure. The plates required for the truss mainly take on the normal forces and / or bending or buckling forces. The core of the truss, for example, is formed by 2 V-shaped slanted additional walls in a rectangular or square tube, consisting of 4 parallel, usually the same length tube walls, the inclined walls are shear-stiff connected to the outer walls. With the inclined walls, the thrust forces are absorbed by bending stresses, there is an enormous bending stiffness across the device then when an additional fiber matrix partially or completely envelops the shear forces at the joints of the plates and converts into tensile forces, which of the Fibers - especially carbon fibers - can be absorbed with a high degree of rigidity. The element is thus secured against kinking and it can horizontally across the element occurring loads such as loads in case of lintels or buckling loads of supporting columns are added. Appropriate load introduction and load extraction constructions from the floor slabs to these support members symmetrically load the vertical loads into the beams when used as a support.

The load introduction of supports consists of a thermally weakly conductive pressure and shear stiff foot element made of fiberglass or fiber-coated stone slabs.

The same profiles can also be used in the construction of machines and vehicles or aircraft as a longitudinal beam or cross member. In these cases, the construction is adapted to the respective load conditions by treating the lower and upper chords differently as the tension or pressure sides, as regards the type and use of the fiber and the plate thickness, which can be adjusted as desired. On the tension side - usually in the lower chord - one will use strong fibers (eg carbon fibers) - which, unfortunately, are usually also energy intensive and therefore usually also equipped with a heavy CO ₂ backpack - and more fiber material as in the upper belt, while in the upper belt on the pressure side less energy-intensive fiber material - such as basalt fiber - is sufficient, it makes sense more cross section in the basalt rock layer thickness is selected.

Another special feature of this invention is therefore to use different fibers and different amounts of fibers at different sites. For example, low-energy basalt fibers can be used on the large outer surfaces, while at the edges and splices the tensile carbon fiber, for example in a unidirectional execution perpendicular to the stresses occurring locally partially used where the cracking of the adhesive seams is specifically to prevent. These measures not only increase material efficiency, but also energy efficiency, since less energy-intensive fibers are also used at less stressed points.

One of the many possible embodiments of the invention describes in a pipe standing on a ground ( 1 ) as a supporting support with square cross-section and 4 walls of basalt plates ( 2 ), each on both sides with a Basaltfaserroving ( 3 ) are stabilized ( , Top view, the upper end shows the structure in cross section). The connection between basalt and fiber is produced by a temperature-stable epoxy resin matrix, which can be thermally stable depending on the field of use and their total coefficient of expansion is smaller than that of the basalt plates to be stabilized if possible. By two further, V-shaped inclined basalt plates ( 4 ) made of large basalt fiber-stabilized stoneware is by means of adhesive bond at the interfaces ( 7 ) in the form of a spatial truss additionally mechanically stiffened the tube and stabilized against bending forces, with the aid of force introduction elements ( 6 ) made of carbon fiber reinforced stone slabs - for example, granite or basalt - the force introduction of the loads of the support is implemented in the bottom. Additional reinforcing carbon fiber layers ( 5 ) at the corner points and impact points of the plate geometry take partially enveloping only at the rounded edges and seam splices ( 5 ) local tensile forces connecting the connection points ( 7 protect against shear forces and stress peaks, and thus substantially control destructive bending, buckling and shear forces where they are greatest, dispensing with the energy-intensive carbon fibers being used all over the assembly, and preferably lower energy basalt fibers only Cover flat surfaces of the basalt plates to optimize the CO ₂ balance and make the CO ₂ backpack as light as possible. These additionally reinforcing carbon fiber layers preferably have a rounded fiber course perpendicular to the longitudinal axis of the support, in order to avoid a force distribution weakening of the fibers and a bursting of the bonded impact points.

The shows a cross member or side member ( 1 ) with a similar construction as in For example, to carry the loads of an overlying ceiling and another floor, z. B. above a lintel or other fall or wall breakthrough, with the difference that the additional carbon fiber reinforcement ( 8th ) in the lower flange ( 2 ) and at the lower corner or adhesive impact points ( 3 ) are optimized for horizontal installation and load case, in order to optimally control the bending forces and a deflection between the supports ( 4 ) largely avoided. As in is the breaking of the V shaped stiffeners ( 6 ) by a particularly strong recording of the tensile forces in the ntergurt ( 2 ) with the help of a reinforcing carbon band ( 8th ), which in the lower chord in the longitudinal direction and around the rounded lower edges ( 7 ) of the profile is placed, wherein the fiber direction of the preferably used UD-Geleges are arranged around the edges perpendicular to the longitudinal axis and at the bottom parallel to the longitudinal axis of the carrier. By this measure, a bursting or tearing off of the adhesive joints is avoided and the bending of the overall composite is reduced to a minimum. To further reduce sagging and increase payloads, the basalt fiber coated top chord ( 5 ) is reinforced by a thicker basalt plate than the lower flange ( 2 ), which in turn is equipped by a strong carbon fiber layer, which is designed so that in case of failure never breaks the lower flange, but the basalt layer is crushed in the upper flange to set a good natured failure behavior.

This side member may, among other things, also form a supporting frame for a car or other driving and aircraft.

shows the crossbeam ( 1 ) in combination with the wall ends carrying the cross member ( 2 ) on the ground ( 3 ), ceiling to be supported ( 4 ) and wall ( 5 ) of the upper floor, as well as the tilting bearings ( 6 ) and ( 7 ).

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1062092 [0009]

Claims (19)

Arrangement of depending on the load case as thin plate or other geometries of one-sided or double-sided fiber-coated stone, hereinafter referred to as support plate, characterized in that the carrier consists of basalt rock. Arrangement according to claim 1, characterized in that matching carrier plates are glued together to form profiles, hereinafter referred to as carrier, the respective parts or regions of the carrier structure depending on the mechanical load case with different fiber types, if necessary. different strength, are stabilized. Arrangement according to claim 1 and 2, characterized in that the overall structure of the carrier is coated with an outer shell made of fiber material, wherein different portions of the carrier is coated with similar or different fiber material. Arrangement according to claim 1 to 3, characterized in that the fiber layers by means of a matrix on epoxy resin, polyester resin, phenolic resin, polyimide resin, cyanate ester resin, melamine resin, polyurethane resin or silicone resin, water glass base or by means of thermoplastic resins on the basalt surface is applied. Arrangement according to claim 1 to 4, characterized in that the matrix contains fiber materials such as stone fibers, basalt fibers, carbon fibers, aramid fibers, glass fibers or natural and vegetable fibers, and wood fibers. Arrangement according to claim 1 to 5, characterized in that the fiber-containing matrix of the carrier contains a mixture of different fiber materials in different layers, which overall preferably have a coefficient of expansion similar to that of the basalt plate to be stabilized. Arrangement according to claims 1 to 6, characterized in that the coefficient of expansion of the fiber matrix is smaller than that of the support plates to be stabilized. Arrangement according to claim 1 to 7, characterized in that the carrier plates are biased by means of the fiber materials. Arrangement according to claim 1 to 8, characterized in that the carrier plates are joined together in the form at the joints or at the corners and edges that the ends or edges of the plates are rounded, so that the tensile forces receiving fiber casing always one has straight and / or curved - and never kinked - fiber shape. Arrangement according to claim 1 to 9, characterized in that the carrier at the outer edges of an additional reinforcement in the form of preferably UD carbon fibers whose orientation is preferably perpendicular to the longitudinal axis of the carrier. Arrangement according to claim 1 to 10, characterized in that the component - if there is a preferably as a pressure and preferably as tension side claimed side, for example in the case of a cross member - on the tension side preferably with an additional reinforcement of the fiber layer - preferably made of carbon fibers - Is provided, which is designed to be stronger than on the pressure side, the pressure side preferably with a stronger - ie thicker - basalt plate than the tension side and if necessary. is equipped with the less energy-intensive basalt fiber in contrast to the tension side. Arrangement according to claim 1 to 11, characterized in that the carrier has a suitable construction for the introduction of force when it is used, for example, as a support. Arrangement according to claim 1 to 12, characterized in that this force introduction consists of fiberglass or other pressure-resistant materials, for example of fiber-coated stone or basalt. Arrangement according to claim 1 to 13, characterized in that the carrier is used as a structural component in construction as a support or transverse support member, or as another supporting element in building construction use. Arrangement according to claim 1 to 13, characterized in that the component is used as floor or ceiling beams or as lintels. Arrangement according to claim 1 to 13, characterized in that the component is used as a longitudinal beam or cross member in sports equipment, such as skis or snowboards, or in the construction of load-bearing parts in the body of vehicles and aircraft, as well as in other engineering. Arrangement according to claim 1 to 13, characterized in that the roughness of the basalt surface is adjusted so fine depending on the basal type that optimum adhesion of the resin is ensured. Arrangement according to claim 1 to 13, characterized in that basalt rocks are used which have a compressive strength above 200 N / mm ² . Arrangement according to claim 1 to 13, characterized in that also basalt-like rocks are used which have a compressive strength above 200 N / mm ² .

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