DE102008020944A1 - Carrier component for supporting or building construction, has material layer made of hybrid material and consisting of basic components e.g. outer shell surrounding material layer, where shell exhibits larger hardness and material density - Google Patents

Abstract

The component has a carrier component core, and a material layer partly surrounding the component core. The material layer made of a hybrid material consists of three basic components e.g. fiber remainders and fiber chips, calcite, gypsum, quartz and/or materials containing finely ground mineral material mixture, plastic resin e.g. epoxy resin and/or acrylate resin and/or polyurethane resin, and an outer shell surrounding the material layer. The outer shell exhibits larger hardness and larger material density. The carrier component core is manufactured from a concrete, reinforced concrete, steel and/or a bonding material. The outer shell is made of tungsten carbide and steel.

Description

Technical area

The The invention relates to a carrier component for a support or building construction that is by an increased load capacity, in particular with regard to on explosion-related impact and / or pressure effects compared to comparable conventional structural designs distinguished.

State of the art

conventional Structural structures consist of wall-like structures, Supports, support pillars, braces and the like together and mostly consist of reinforced concrete or combinations of concrete, Reinforced concrete and steel for the construction of so-called composite beam components. Brittle However, materials such as concrete or reinforced concrete fail very quickly under impact loads, such as those occur in explosions in the form of shock waves. Currently at With regard to the growing danger of terrorist attacks at least for strategically important buildings and structural structures to take appropriate precautions.

investigations on conventional concrete or reinforced concrete support components, the have been exposed to explosion-induced shockwaves, show that the shock waves propagate in the concrete and be reflected on respective component backs, whereby it comes to internal tensions, which is the tensile strength of the material Concrete exceed and thus irreversible damage in the form of cracks and flaking lead. Such damage occur extremely quickly in concrete, as the tensile strength only about a tenth of the compressive strength is and while a crack opening can dissipate only little energy. Further is Concrete a porous material that passes through a shock wave compacted, d. H. its internal structure collapses, causing the carrying capacity of the respective carrier component almost completely lost.

With the goal of avoiding such internal damage especially in concrete components is after a damping material been sought, that between the support member to be protected and the site of the explosion and whose task is to the pressure-time course of acting on the support member to prolong the explosion-induced shock wave and in addition, the pressure peak of the shock wave too to reduce.

From the DE 101 37 720 A1 For this purpose, a potting material forth, which is referred to as a kind of hybrid material composition as polymer concrete or biobeton and consists essentially of three basic components, namely a) of porous organic fillers and / or organic fibers for reinforcement purposes, b) of calcite , Gypsum, quartz and / or materials containing finely ground mineral mixtures, and c) ultimately for purposes of internal bonding and optionally bonding to technical surfaces of epoxy resin. Due to the fillers used, a polymer concrete composed in this way has large pore volumes which lead to a porosity of up to 50% and thereby give a very high energy absorption capacity.

Though Wear the included in such polymer concrete materials Pore volumes for compaction of the material and related to a desirable shockwave absorption potential but the material strength is reduced with increasing pore volume and the associated carrying capacity of this material existing components.

Presentation of the invention

Of the Invention is based on the object, a carrier component for a support or building construction using a hybrid material known as polymer concrete in such a way that the carrier component at a Explosionsbelastung one over previous solutions improved Resistance behavior, which in particular by a high Damping measure for on the developer part acting, explosive shockwaves, paired with a component resistance that is largely unchanged despite the shock wave effect, d. H. unchanged load, should be distinguished.

The Solution of the problem underlying the invention is specified in claim 1. The concept of the invention advantageously further Features are the subject of the dependent claims and the other Description in particular with reference to the embodiments refer to.

The novel support member for a support or building structure is characterized by a support member core, which is preferably composed of a steel or reinforced concrete structure, which is at least partially surrounded by a material layer of hybrid material, which is formed in the manner of the polymer concrete described above and of three Basic components consists, namely a) fiber residues, fiber chips and / or grain residues and / or straw-like residues from corncobs after removal of the corn kernels, b) a calcite, gypsum, quartz and / or materials enthal tende finely ground mineral mixture and c) plastic resin, preferably an epoxy resin, acrylic resin and / or polyurethane resin. In addition, an outer shell surrounding the material layer consisting of the hybrid material is provided which, compared to the hybrid material, has a greater hardness and greater material density, preferably made of hardened steel or stainless steel.

in the Unlike previous carrier components, at least Partially have the hybrid material "polymer concrete" and this material for shock absorption of a the carrier component acting, explosion-induced shock wave Immediately expose, see the solution trained Carrier component a hard, preferably made of metal, steel, Stainless steel or similar existing external cladding, on which the explosion-induced shock wave impinges or acts. Opposite the component core is the hard outer shell spaced by an intermediate layer consisting of polymer concrete, so that the impact on the hard outer shell shock wave and the associated pressure initially flat distributed and from the immediately below intermediate layer made of polymer concrete over a large area Area is absorbed by way of compaction, so ultimately the explosive damage potential acting on the component core can be significantly reduced, preferably in a load area, where the component core is not irreversible, the strength of the Carrier component in question damage experiences.

In a particularly preferred embodiment exists between the hybrid material material layer both sides the carrier component core as well as sides of the outer shell a direct, immediate contact without any adhesion-promoting Interlayer. To produce such a sandwich assembled three - component structure consisting of the Carrier component core consisting of the hybrid material Material layer as well as the outer shell, which is made of hybrid material existing material layer provided in the form of a potting compound and inserted between carrier component core and outer shell, for example by way of a casting process. The self-immortal Potting compound consists of the above three basic components a) fiber remnants, fiber shreds, grain remnants and / or straw-like Corncob residue after removal of corn kernels, b) a finely ground, containing calcite, gypsum, quartz and / or materials Mineral mixture and c) plastic resin, the basic component a) about 35 to 40%, the base component b) about 18 to 24% and the basic component c) amount to 38 to 43% of the volume of the hybrid material. In the casting compound bears the proportion of the first in flowable form present plastic resin in that the potting compound by way of a contract or casting process with the respective opposite technical surfaces the carrier component core on the one hand and the carrier component core facing surface of the outer shell on the other a flat adhesion-based surface joint received.

in the Ways of self-staring of the potting compound blended plastic resin solidifies the material layer and ultimately leads to an intimate layer network. Depending on training and characteristics the carrier component core, for example in the form of a strut, a pillar or a wall, it is the outer shell corresponding to the surface contour of the carrier component core adapt. For example, in a wall-shaped Carrier component core is the outer shell as a compliant formed to the wall surface metal, preferably steel plate formed, preferably the entire wall surface the carrier component core, the at least one potential Placed facing explosion, covered. Corresponding it applies the existing hybrid material layer between the wall surface of the carrier component core and to provide or bring that of the metal plate.

These it is a carrier component core embodied as a strut or a support, for example in the form of a solid cylindrical reinforced concrete support, so it offers itself in an advantageous manner, the entire peripheral contour the columnar carrier component core in full to coat with the material layer consisting of hybrid material, which in turn is adapted in shape and size Hardmetal outer casing completely surrounded is.

By experiences the solution measure the carrier component core against effective protection explosion-related shock waves, as also from the attached Figure is to be taken. This is shown in the single figure Diagram shows an ordinate along which a measure B which is the carrying capacity of a carrier component core represents the abscissa corresponds to the deformation of the Support the structural core. So, suppose that in the Diagram shown function curves a, b, c measurement results a load test on a columnar carrier component core represent. The load test was static with a time increasing load acting along the post, until each irreversible damage in adjusted the carrier component core, whereby the load capacity decreases. Here is the achievable characteristic Maximum value per function run the maximum residual load capacity the carrier component core is.

Of the from the diagram removable function course represents a the load capacity of a not previously damaged (by explosion event), conventional Reinforced concrete support, which no additional, layered Having sheaths. On the other hand illustrates the course of the function c the load capacity of a previously damaged, conventional Reinforced concrete support, which before the stress test execution of a explosive shockwave has been exposed, and thereby a structural damage along the reinforced concrete support received. It clearly shows that the damaged reinforced concrete column, which otherwise has no further protective measures, already almost due to the explosion-related damage completely weakened in terms of strain has been.

On the other hand shows the function course b, one compared to the case study c much better remaining load capacity of a reinforced concrete column, the likewise an explosion-induced shock wave action, as the case b, has been exposed before the stress test has been carried out, however, dismissed the reinforced concrete support in this case, the solution-based layer structures on, which consists of hybrid material material layer with a surrounding steel casing.

Clear can be seen on the basis of the function curve b, that the residual capacity far above that in unprotected case c, so that with suitable dimensioning of the solution sequence layer Beam components even after explosion-induced shock wave effects a negligible impairment of their Experience residual capacity, so that in this way high costs associated with repair or refurbishment Support or building structures after an explosion can be avoided.

A Another alternative embodiment for producing a according to the invention layer composite for Carrier component cores provides for the separate production of Hybrid material existing intermediate layer before acting as self-supporting Plate or mold is produced and with the help of a primer both to the surface of the carrier component core as well as with the carrier component core facing surface the outer shell can be joined. To this Way is a subsequent attachment of the solution Protective measure on already existing carrier component cores without major additional expenses possible.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• - DE 10137720 A1 [0005]

Claims (10)

Carrier component for a support or building construction with a carrier component core, a material core at least partially surrounding the component core from a hybrid material consisting of three basic components, namely a) fiber residues, fiber chips and / or grain residues and / or strawy residues from corncobs after removal the corn kernels, b) a calcite, gypsum, quartz and / or materials containing finely ground mineral mixture and c) plastic resin, and one surrounding the existing of the hybrid material layer material Outer shell, compared to the hybrid material a larger Has hardness and greater material density. Support member according to claim 1, characterized that the carrier component core with the of the hybrid material existing material layer and consisting of the hybrid material Material layer with the outer shell an indirect or to enter immediate area network. Support member according to claim 2, characterized that the hybrid material as a potting compound on the carrier component core facing surface of the outer shell applied is and with the outer shell by way of solidification at least one Tie-up connection received. Support member according to claim 2, characterized that between the carrier component core and the material layer and / or between the material layer and the outer shell a bonding agent is provided. Carrier component according to one of the claims 1 to 4, characterized in that the plastic resin epoxy resin and / or acrylic resin and / or polyurethane resin. Carrier component according to one of the claims 1 to 5, characterized in that the outer shell of a hard metal, preferably made of steel. Carrier component according to one of the claims 1 to 6, characterized in that the carrier component core in the form of a strut, support or wall is formed. Carrier component according to one of the claims 1 to 7, characterized in that the carrier component core made of concrete, reinforced concrete, steel and / or a composite material is. Carrier component according to one of the claims 1 to 8, characterized in that the basic component a) approx. 35 to 40%, the basic component b) about 18 to 24% and the basic component c) amount to 38 to 43% of the volume of the hybrid material. Carrier component according to one of the claims 1 to 9, characterized in that the carrier component core a column-like, made of reinforced concrete Prop is completely made with the hybrid material existing material layer is encased, and that of hybrid material existing material layer completely from a carbide existing sleeve-like outer shell is surrounded.