A concrete component includes a fiber reinforcement structure (12), formed by a grid arrangement (15). At least some of the rods extending in the X or Y direction are preferably designed as double rods having a joined cross-section or having sub-cross-sections separated from each other by a gap (20)
A concrete component includes a fiber reinforcement structure (12), formed by a grid arrangement (15). At least some of the rods extending in the X or Y direction are preferably designed as double rods having a joined cross-section or having sub-cross-sections separated from each other by a gap (20). Such double rods can be arranged in a grid structure both at right angles to each other and at other angles to provide a triangular structure, a hexagonal structure, or the like as a grid. Fiber reinforcement structures (12) made of a plastic-impregnated fiber material, such as epoxy-resin-bonded glass fibers having long fibers (endless fibers), in the particular rod longitudinal direction and without bonding among each other (ravings) can construct an adequately load-bearing composite with the concrete body (II). The steel rods can act as reinforcement, wherein harmful effects on the concrete, in particular wedge and gap effects, do not occur.
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1. Concrete component comprising: a fiber reinforcement structure (12, 12′) with a plurality of first fiber strands (17a) arranged in a first direction (x) and a plurality of second fiber strands (18a) arranged in a second direction (y), said fiber strands forming a first grid array (15, 15′) with i
1. Concrete component comprising: a fiber reinforcement structure (12, 12′) with a plurality of first fiber strands (17a) arranged in a first direction (x) and a plurality of second fiber strands (18a) arranged in a second direction (y), said fiber strands forming a first grid array (15, 15′) with intersection points at which the first fiber strands (17a) and the second fiber strands (18) are connected to each other,wherein each of the first fiber strands (17a) and the second fiber strands (18a) have a plastic portion;additional fiber strands (17b, 18b, 27, 28) having a plastic portion, wherein the additional fiber strands (17b, 18b, 27, 28) are connected, at least in sections, to the first fiber strands (17a) and/or to the second fiber strands (18a), respectively; anda mineral body (11) which consists of a filler and of a binder, and in which the fiber reinforcement structure (12) is embedded. 2. Concrete component as in claim 1, wherein the additional fiber strands (17b, 18b, 27, 28) are arranged parallel to the first fiber strands (17a) and/or to the second fiber strands (18). 3. Concrete component as in claim 1, wherein the additional fiber strands (17b, 18b, 27, 28) are connected to the first fiber strands (17a) and/or to the second fiber strands (18) in longitudinal direction, continuously or with gaps (20) in sections. 4. Concrete component as in claim 1, wherein the first fiber strands (17a) and/or the second fiber strands (18a) define, with the additional fiber strands (17b, 18b), a simple, cohesive cross-section or a double cross-section that, in a center section, defines a waist (23) or a passage (20). 5. Concrete component as in claim 1 further comprising, a second grid array (16, 16′) associated with the fiber reinforcement structure (12, 12′), said second grid array being firmly connected to the first grid array (15, 15′). 6. Concrete component as in claim 5, wherein the first grid array (15, 15′) and the second grid array (16, 16′) have same mesh widths and are oriented so as to be in alignment with each other. 7. Concrete component as in claim 6, wherein the first grid array (15, 15′) and the second grid array (16, 16′) are connected superimposed in a material-bonded manner. 8. Concrete component as in claim 5, wherein the first grid array (15, 15′) and the second grid array (16, 16′) have same or different mesh widths. 9. Concrete component as in claim 5, further comprising a spacer grid (25) arranged between the first grid array (15′) and the second grid array (16′). 10. Concrete component as in claim 9, wherein the two grid arrays (15′, 16′) are connected to each other in a material-bonded manner by the spacer grid (25). 11. Concrete component as in claim 1, wherein the crossing points of the additional fiber strands (17b, 18b) define a plane (E2) at a distance from a plane (E1) that is defined by the intersection points of the first fiber strands (17a) and the second fiber strands (18a). 12. Method for providing a fiber reinforcement structure, said method comprising: producing at least two grid structures, wherein producing a grid structure comprises: providing fiber strands impregnated with plastic material;arranging a portion of the fiber strands as first fiber strands (17) in an x-direction;arranging another portion the fiber strands in a y-direction, obliquely or transversely to the first fiber strands (17), on said first fiber strands to form a planar grid structure (15);partially curing the plastic material to form a rigid, handleable grid structure (15, 15′);superposing at least two of the at least two grid structures (15, 16; 15′, 16′) to create superposed grid structures;aligning the superposed grid structures (15, 16; 15′, 16′) relative to each other;establishing a material-bonded connection of the superposed grid structures (15, 16; 15′, 16′) to each other. 13. Method as in claim 12, further comprising selecting fiber strands having different numbers of filaments as the first fiber strands (17) and as the second fiber strands (18). 14. Method as in claim 12, further comprising arranging a wave-shaped grid element (25) between the superposed grid structures (15′, 16′) to connect the superposed grid structures (15′, 16′) in a material-bonded manner. 15. Method as in claim 14, further comprising producing the wave-shaped grid element (25) by plastically deforming a flat grid structure into a wave-shape.
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