EP1509656A1

EP1509656A1 - Surfacing structure for traffic areas and for surfaces of structures

Info

Publication number: EP1509656A1
Application number: EP02738118A
Authority: EP
Inventors: Josef Scherer
Original assignee: Individual
Current assignee: Individual
Priority date: 2001-05-29
Filing date: 2002-05-28
Publication date: 2005-03-02
Also published as: PL205947B1; US20050047863A1; DE10126074A1; CZ20033449A3; WO2003002821A1; HRP20031038A2; HUP0400602A2; US7052203B2; CA2487868A1; CA2487868C; PL373109A1

Abstract

The invention relates to a surfacing structure for traffic areas and for surfaces of structures, which has a substructure located on the base of the surfacing and has a superstructure, which covers the latter and is comprised, at least in part, of concrete, especially of asphaltic concrete. The substructure comprises at least one lattice work extending along the surfacing and having a number of strips, which intersect while forming a mesh, consist of high-strength fiber billets with different tensile E-moduli, and which are interconnected with material fit or in a non-positive manner. A thermally removable covering can be applied to at least one surface of the lattice work.

Description

Covering construction for traffic areas and building surfaces

The invention relates to a covering construction for traffic areas and building surfaces, which has a substructure arranged on the sub-surface of the covering and a superstructure covering the latter and consisting at least partially of concrete, in particular asphalt concrete. The substructure comprises at least one latticework extending along the covering with a plurality of coulters of high-strength fiber strands arranged crosswise, which are connected to one another in a material or non-positive manner. The invention also includes special fiber strand lattice structures as such and components for covering constructions of the aforementioned type.

Such covering constructions are known in the prior art. They have tangled fiber material in the area of the lattice gaps of the substructure, that is to say a voluminous fiber material, which is intended to produce a surface-covering connection between the subsurface and the superstructure or its fiber strands and cover layers. In practice, when the latticework is introduced, the tangled fiber fleece comes to a greater or lesser extent into contact with viscous bitumen and tends to stick to the rollers or vehicle wheels when rolling on and when driving over construction site vehicles in the meantime. The result is an undesirable lifting and moving, even tearing out the tangled fiber material and possibly also the latticework associated with it. The object of the invention is therefore first of all to create a covering construction which, while preserving the advantages of high-strength fiber structures in the covering substructure, makes it possible to overcome the aforementioned disadvantages which are associated with the adherence and lifting or tearing out or moving of area-covering fiber material. The solution to this problem according to the invention is determined in connection with the generic features mentioned at the outset in that the fiber strands of the lattice work are impregnated and / or enveloped by themselves with a tough-elastic connecting compound and by means of this encapsulation or impregnation with one another in the region of their crossing points and with the substrate and are directly connected to the superstructure, and that the superstructure is connected at least in sections in the area of the open mesh interior of the latticework to the substrate of the covering in a material and / or form-fitting manner.

This solution is based on the surprising but practice-based knowledge that the fiber strands of the latticework, which are impregnated and / or covered with a tough-elastic connecting compound, form a sufficiently stable bond with the subsurface on the one hand and the superstructure on the other hand to withstand the bending tensile stresses of a high level load the loaded surface and to ensure the required load-bearing capacity of the surface.

Of particular importance in the context according to the invention is the direct and overall extensive shear bond between the superstructure and the subsurface within the mesh interiors. This shear bond can be produced in a material and / or form-fitting manner by means of the binders present in the usual manner in the area of the underside of the superstructure - in particular bituminous masses. In this context, the material connection can be formed by the adhesive or adhesive effect of the connecting compound with respect to the solid bodies concerned, but the positive connection can be formed by the macroscopic or microscopic toothing effect.

An essential development of the invention consists in that at least two sets of high-strength fiber strands with at least partially different tensile emodules are arranged in the latticework. This enables adaptation to the given load conditions on the covering as well as cost savings with regard to the covering components. In particular, for traffic areas subject to movement loads, a construction is contemplated in which at least one family of fiber strands with a relatively higher train emodule is arranged at an acute angle, in particular at least approximately along a main direction of load movement. With a given load-bearing capacity or lifespan of the covering, this can be used to optimize material costs. In a development of the invention, a design can serve this purpose in particular, in which at least two sets of high-strength fiber strands arranged crosswise in the latticework, which at least partially consist of glass fibers in one of these sets and at least partially consist of carbon fibers in the other set.

The latticework provided in the covering according to the invention, with cross-arranged groups of high-strength fiber strands from different train emodules, as a component, represents an independent commercial product, accordingly in accordance with its own subject-matter. This also applies to the arrangement of glass and carbon fibers in a latticework already mentioned in a constructive context. Subject matter of the invention is further a prefabricated component, in which on at least one surface of the latticework or the fiber strands impregnated and / or coated with tough-elastic connecting compound, a removable covering that is not adhesive and / or non-adhesive and / or repellent to the connecting compound, in particular one corresponding layer is provided. This development of the invention is of considerable importance in that it enables a commercial product in the form of a compact reel body. The installation on site is also made easier by simply rolling it out. In this context, it is particularly progressive to design the cover as a thermally removable, in particular burnable, film. This results in a further rationalization of the covering work.

The invention is explained in more detail below on the basis of an exemplary embodiment shown schematically in the drawings. It shows:

1 shows a perspective partial section of a road surface according to the invention in situ,

2 shows a vertical section of a road surface according to the invention in accordance with the sectional view IT-II identified in FIG. 1, but with the superstructure already present in the cutting area,

3 shows a vertical section of a road surface similar to FIG. 2, but according to the sectional view HI - HI marked in FIG. 1, again with the superstructure already present in the cutting area, and 4 shows a prefabricated covering component according to the invention in the form of a roller body in a side view, specifically in a schematically indicated installation process.

The covering construction shown in FIG. 1 comprises a substructure UB arranged on the underground UG of the covering B and a superstructure OB covering the latter and consisting at least partially of concrete, in particular asphalt concrete. The substructure comprises a lattice work GW extending along the covering with a plurality of coulters S 1, S 2 arranged in a crosswise fashion from high-strength fiber strands FS. The latter are connected to one another at the intersection points K in a material or non-positive manner. The fiber strands FS are in themselves impregnated and / or covered with a tough-elastic, in particular bituminous connecting mass and are thus directly bonded to one another at their crossing points and to the underground UG and to the superstructure OB. The superstructure is connected in the area of the open mesh interiors MI of the latticework GW to the underground UG of the covering B in a material and / or form-fitting manner, and in fact over a large area.

In a further embodiment of the invention, there is a particular technical advance if a connecting compound which is thermoplastic to the molten liquid, in particular bituminous, and which at least partially fills the interstices of fibers within the fiber strands is used.

2 shows in the latticework GW two sets S 1, S 2 arranged crosswise of high-strength fiber strands FS with a flat rectangular cross section, the flat sides of which are arranged essentially parallel to the ground. The intersections shown in section K1 and K2 indicate that this lattice is a woven structure. At the crossing points, the fiber strands are secured to one another by a suitable, possibly also a hardening, connecting compound VM, so that a substructure UB transmitting tensile force results in connection with the substructure and superstructure.

According to the invention, high-strength fiber strands with at least partially different tension emodules can preferably be provided for the coulters arranged crosswise in this latticework. This allows you to define the best constructions in terms of statics and costs. A family of fiber strands with a relatively higher tension module is preferably arranged at an acute angle, in particular at least approximately longitudinally, to a main direction of load movement. The tensile modulus of the more rigid fiber strands is preferably selected in the range between 180 kN / mm ² and 260 kN / mm ² , the tensile emodulus of the softer tensile fiber strands in the range between 60 kN / mm ² and 80 kN / mm ² . Particularly high-quality constructions result if at least two sets of high-strength fiber strands are arranged in the latticework, which are at least partly made of glass fibers in one of these sets and at least partly made of carbon fibers in the other set.

The dimensions of the meshes are also important for optimal system design. For this purpose, the following benchmarks have proven to be valuable: The minimum diameter of the free mesh interiors of the latticework should be at least about 10 mm, but the maximum diameter at most about 80 mm, in particular at most about 50 mm. In connection with this, the maximum diameter of the fiber strands should be 3 to 10 mm, in particular up to about 5 mm. This information also serves to reliably penetrate the still deformable or not yet hardened superstructure over the open mesh inner surfaces of the latticework to the ground and thus finally secure fastening of the superstructure against separation, shear and bending stresses.

4 shows a covering component according to the invention, designed as a winding or roll body RK, with layers of lattice flat material that are not adhering to one another. For this purpose, at least one surface of the latticework or of the fiber strands impregnated and / or coated with a tough-elastic connecting compound is provided, in particular in the form of a corresponding coating, which is non-adhesive, non-adhesive or repellent to the connecting compound. According to the invention, this coating is preferably in the form of a thermally removable, in particular burnable, film. In this respect, a flame device with a burner BR is indicated schematically in FIG. As illustrated by movement or work progress arrows, this embodiment enables a rational procedure with continuous work progress. An essential further development of the invention with regard to the component in this context is that a removable cover BD of the aforementioned type is provided on one surface of the latticework and a non-adhesive or non-adhesive or repellent granulate coating GS is provided on the other surface with respect to the connecting compound VM.

Claims

claims

1.Cover construction for traffic areas and building surfaces, comprising a substructure (ÜB) arranged on the underground (UG) of the covering (B) and a superstructure (OB) covering the latter and at least partially consisting of concrete, in particular asphalt concrete, the substructure at least comprises a latticework (GW) extending along the covering with a plurality of coulters (S 1, S 2) made of high-strength fiber strands (FS) which are arranged in a crosswise manner and which are connected to one another in a material or non-positive manner, characterized in that the fiber strands (FS ) impregnated and / or coated with a viscous-elastic connecting compound and are directly cohesively connected by this impregnation or coating to each other at their crossing points as well as to the underground (UG) and to the superstructure (OB), and that the superstructure at least in sections in the area of the open mesh interior (MI) of the latticework (GW) with the U background (UG) of the covering (B) is connected to the material and / or in a form-fitting manner.

Covering construction according to Claim 1, characterized by a connecting compound which is thermoplastic to the molten liquid, in particular bituminous, and which at least partially fills the interstices of fibers within the fiber strands (FS).

3. covering construction according to claim 1 or 2, characterized in that in the latticework (GW) at least two cross-arranged coulters (Sl, S2) of high-strength fiber strands with at least partially flat-rectangular cross section are provided, which are at least approximately parallel with their flat side are arranged to the underground.

Covering construction according to claim 3, characterized in that the latticework has a woven structure.

5. Covering construction according to one of the preceding claims, characterized in that in the latticework (GW) at least two cross-arranged groups (S1, S2) of high-strength fiber strands with at least partially different train emodules are provided.

6. Covering construction according to claim 5, for traffic areas under movement loads, characterized in that at least one set of fiber strands with a relatively higher train emodule is arranged at an acute angle, in particular at least approximately lengthways, to a main direction of load movement.

7. covering construction according to claim 5 or 6, characterized in that the tensile modulus of the tensile fiber strands is in the range between 180 kN / mm ² and 260 kN / mm ² .

8. covering construction according to one of claims 5 to 7, characterized in that the tensile emodule of the softer tensile fiber strands is in the range between 60 kN / mm ² and 80 kN / mm ² .

Covering construction according to one of claims 5 to 6, characterized in that in the latticework (GW) at least two cross-arranged sheets (S1, S2) made of high-strength fiber strands, at least partially made of glass fibers in one of these sheets and at least partially in the other sheet consist of carbon fibers.

10. Deck construction according to one of the preceding

Claims, characterized in that the minimum diameter of the free mesh interiors of the latticework (GW) is at least about 10 mm.

11. Deck construction according to one of the preceding

Claims, characterized in that the maximum diameter of the free mesh interior of the latticework (GW) is at most about 80 mm, in particular at most about 50 mm.

12. Deck construction according to one of the preceding

Claims, characterized in that the maximum diameter of the fiber strands is 3 to 10 mm, in particular up to about 5 mm.

13. Fiber strand latticework for coverings and reinforcements from

Traffic areas and structures, in particular for covering constructions according to one of the preceding claims, in particular also for fiber laminates with synthetic resin matrix which are to be produced and prefabricated in situ, characterized in that at least two crosses of high-strength fiber strands with at least partially different train emodules are provided in the latticework ,

14. Latticework according to claim 13, characterized in that the fiber strands consist at least partially of glass fibers in at least one first coulter and at least partially consist of carbon fibers in at least one second coulter arranged to cross the first.

15. covering construction according to claim 13 or 14, characterized in that in the latticework (GW) at least two cross-arranged coulters (Sl, S2) of high-strength fiber strands with at least partially flat-rectangular cross section are provided, which are at least approximately parallel with their flat side are arranged to the underground.

16. Covering construction according to claim 15, characterized in that the latticework has a fabric structure.

17. Prefabricated component for a covering construction according to one of claims 1 to 12, characterized in that on at least one surface of the latticework (GW) or the fiber strands impregnated and / or coated with tough-elastic connecting mass (FS) a removable, compared to the connecting mass non-adhesive and / or non-adhesive and / or repellent covering (BD), in particular a corresponding layer, is provided.

18. The component according to claim 17, characterized in that the covering (BD) is designed as a thermally removable, in particular burnable film.

19. The component according to claim 17 or 18, characterized in that on one surface of the latticework (GW) a removable cover (BD) and on the other surface a non-adhesive and / or non-adhesive and / or repellent granulate coating (GS) with respect to the connecting mass is provided is.

20. The component according to one of claims 14 to 16, characterized by a design as a winding or roll body (RK) with non-adherent layers of flat material.