EP1987211A1

EP1987211A1 - Component

Info

Publication number: EP1987211A1
Application number: EP07701323A
Authority: EP
Inventors: Klaus Ritter
Original assignee: EVG Entwicklungs und Verwertungs GmbH
Current assignee: EVG Entwicklungs und Verwertungs GmbH
Priority date: 2006-02-22
Filing date: 2007-02-14
Publication date: 2008-11-05
Also published as: AT503489B1; ZA200708752B; WO2007095653A1; AT503489A1

Abstract

Component which comprises two parallel, flat wire mesh mats (M1, M2) made from longitudinal and transverse wires (L1, L2; Q1, Q2) which cross one another and are welded to one another at the crossing points, straight frame wires (V1, V2) which hold the wire mesh mats at a predefined, mutual spacing and are connected at each end to the two wire mesh mats, and a central element which is arranged between the wire mesh mats and at a predefine spacing parallel to the latter and is formed from a dimensionally stable, thin barrier layer (T) which is penetrated by the frame wires and is held by the latter at a predefined spacing from each of the wire mesh mats.

Description

module

The invention relates to a component consisting of two parallel flat wire mesh mats of intersecting and welded together at the intersections longitudinal and transverse wires of the wire mesh mats in a predetermined, mutually spaced, at each end connected to the two wire mesh mats straight ridge wires, and consists of a between the wire mesh mats and at a predetermined distance parallel to these arranged central element.

From WO-94/28264 a device is known which consists of two parallel welded wire mesh mats, of the wire mesh mats at a predetermined mutual distance, at each end connected to the two wire mesh mats straight ridge wires and one, with its top surfaces parallel to the wire mesh mats and with insulating body. At the construction site, the building element is provided with a layer of concrete or mortar covering the wire mesh mats on its two cover surfaces. This device has the disadvantage that in the middle of the component, a complex insulating body is arranged, which is unnecessary for many applications.

From DE-Al-24 40 578 a three-dimensional reinforcement element is known, which consists of two smooth, flat outer layers and reinforcement connecting the outer layers. As outer layers of wire mesh mats are used, which consist of intersecting and welded together at the crossing points longitudinal and transverse wires. The connecting reinforcement has a plurality of zigzag-shaped longitudinal wires and a plurality of transverse wires welded to the longitudinal wires. Between the outer layers, at least one substrate layer is arranged, which serves as a carrier layer for the concrete, plaster or mortar to be sprayed onto the reinforcement element. telschicht serves. This reinforcing element has the disadvantage that the outer layers are located on the outer sides of the component and therefore can not be covered with concrete. Another disadvantage of this reinforcing element is that the substrate layer must be subsequently pushed onto the reinforcement, whereby due to the zigzag-shaped configuration of the longitudinal wires of the reinforcement, the substrate layer has extremely large holes for the crests of the amplification. The object of the invention is to provide a reinforcing element which avoids the disadvantages of the known reinforcing elements, and can be used for producing a precast element of shotcrete.

A component according to the invention of the type described in the introduction is characterized in that the central element consists of a dimensionally stable, thin barrier layer, which is penetrated by the webs and held by them at a predetermined distance from each of the wire mesh mats.

Preferably, the web wires in predetermined directions to the wire mesh mats are alternately inclined in opposite directions, arranged like a façade between the wires of the wire mesh mats.

According to a further feature of the invention, the barrier layer is flush with its edges flush with the wire mesh mats. The barrier layer may in the context of the invention consist of cardboard, plasterboard or plywood, but e.g. also consist of an expanded metal grid.

According to a preferred embodiment of the invention, it is provided that at least one wire mesh mat is designed as a mesh reinforcement mat which has a minimum strength of the welding nodes corresponding to the static requirements of the component, corresponding mechanical strength of the wires of the wire mesh mats and corresponding diameters and geometries. has geneeit distances of the wires, that the web wires are formed as shear reinforcement elements and welded to the wires of at least one of the wire mesh mats with a predetermined minimum weld knot strength. The invention also provides a method for producing a prefabricated element with at least one component, characterized in that an outer shell is applied by spraying in each case to the outer wire mesh mat of the component intended to form the outside of the prefabricated element, which adjoins the barrier layer of the component and enclosing the outer wire mesh mat, and that in each case on the inner wire grid mat of the component intended for forming the inside of the prefabricated element, an inner shell is applied by spraying, which adjoins the barrier layer and surrounds the inner wire mesh mat, the barrier layer in each case acting as an impact surface for the Spraying the outer shell and the inner shell is used.

Further features and advantages of the invention will be explained below with reference to an exemplary embodiment with reference to the drawings. 2 shows a side view of the component, FIG. 3 shows a prefabricated element with outer and inner concrete shell, and FIG. 4 shows a side view of the finished part element.

The component B shown in FIG. 1 has two parallel, flat wire mesh mats M 1 and M 2, which respectively consist of longitudinal and transverse wires L 1, L 2 or Q 1, Q 2 which intersect and which are welded together at the intersection points. The mutual distance of the longitudinal wires Ll, L2 and the cross wires Ql, Q2 to each other is selected according to the static requirements of the component B. The distances are preferably the same size, for example in the range of 50 to Selected 150 mm, so that the respective adjacent longitudinal and transverse wires form square mesh. In the context of the invention, the meshes of the wire mesh mats Ml, M2 may also be rectangular and, for example, have short side lengths of 50 to 100 mm and long side lengths in the range of 75 to 150 mm. The diameters of the longitudinal and transverse wires L1, L2 and Q1, Q2 are also selectable according to the static requirements and are preferably in the range of 2 to 7 mm. Furthermore, the component B has several, the two wire mesh mats Ml, M2 in a predetermined mutual distance holding straight ridge wires Vl, V2. The web wires V 1, V 2 are welded at their ends to the wires of the two wire mesh mats M 1, M 2, wherein the web wires V 1, V 2 in the context of the invention are either connected to the respective longitudinal wires L 1, L 2 or, as shown in FIG can also be welded to the transverse wires Ql, Q2. The web wires Vl, V2 are alternately inclined in opposite directions, ie arranged in a lattice, whereby the grid body is stiffened against shearing stress. All web wires Vl, V2 form a matrix-like structure in the component B, which gives the component B the required rigidity, so that a dimensionally stable grid body is formed.

The distances of the web wires Vl, V2 to each other and their distribution in the component B depend on the static requirement of the component B and are for example along the longitudinal wires 200 mm and along the transverse wires 100 mm, the number of web wires Vl, V2 preferably 50 to 200 per m ² . The mutual distances of the web wires Vl, V2 in the direction of the longitudinal wires Ll, L2 and the cross wires Ql, Q2 are expediently a multiple of the mesh pitch. The diameter of the web wires Vl, V2 is preferably in the range of 2 to 7 mm. Within the scope of the invention it is possible the diameter of the web wires Vl, V2 greater than the diameters of the wires Ll, Ql; L2, Q2 of the wire mesh mats Ml, M2 to choose.

The spatial grid body formed from the two wire mesh mats M1, M2 and the bridge wires V1, V2 must not only be dimensionally stable, but also fulfill the function of a spatial reinforcement element when used as a wall and / or ceiling element, i. Absorb thrust and pressure forces. Therefore, both the longitudinal and transverse wires are common to one another, as is usual with reinforcing mats, as well as the web wires V 1, V 2 with the wires L 1, L 2; Ql, Q2 of wire mesh mats Ml, M2 welded while maintaining a minimum strength of the welding knots. In addition, the wires Ll, L2; Ql, Q2 of the wire mesh mats Ml, M2 and the web wires Vl, V2 of the component B are made of suitable materials and have corresponding mechanical strength values, so that they as reinforcing wire for use as reinforcing mesh mats mesh Ml, M2 or as the two wire mesh mats Ml, M2 connecting Shear reinforcement elements are used.

In the space between the wire mesh mats Ml, M2 is at a predetermined distance from the wire mesh mats Ml, M2 is a dimensionally stable, thin barrier layer T arranged substantially parallel to the wire mesh mats Ml, M2 and at their edges flush with the outer edges of the wire mesh mats , M2 completes. The barrier layer T has the task in the production of a prefabricated element F shown schematically in FIGS. 3 and 4 and described in greater detail below as an impact surface for the concrete to be applied in the spray process of an outer shell Sl and an inner shell S2 of FIG

Prefabricated element F to serve.

The barrier layer T is preferably arranged centrally to the wire mesh mats Ml, M2, wherein the distance to each Wire mesh mat Ml; M2 is preferably 10 to 30 mm. The barrier layer T is penetrated by the web wires V 1, V 2 and fixed in their position relative to the wire mesh mats M 1, M 2 by the alternately opposite, ie oblique, ie, lattice-like arrangement of the web wires. The barrier layer T may in the context of the invention of cardboard, thin cardboard, made of a thin plywood or gypsum board or other thin, dimensionally stable materials. In the context of the invention, the barrier layer T can also consist of a close-meshed expanded metal mesh or of a close-meshed, welded wire mesh. The meshes of these grids must be so tight that these grids represent an effective barrier during spraying of the outer and inner shells Sl, S2 and when spraying the material only very little material can penetrate the barrier layer T. In order to increase the blocking effect, in the context of the invention, these grids can be equipped with a layer of building paper.

In the production of the component B, the web wires Vl, V2 pierce the barrier layer T, wherein the holes O arise. In the case of very hard material of the barrier layer T, in the context of the invention the holes 0 in the barrier layer T can also be pushed or drilled into the barrier layer T during manufacture of the component B in the production apparatus immediately prior to the attachment of the bridge wires V1, V2. The diameter of the holes O may be only slightly larger than the diameter of the web wires Vl, V2, to represent an effective barrier for the shotcrete. The barrier layer T can be provided in the invention with pre-drilled holes 0 for receiving the web wires Vl, V2. The position and the number and the diameter of the predrilled holes O in the barrier layer T is determined by the oblique ridge wires Vl, V2, which penetrate the barrier layer T. For producing a prefabricated element F, which is used for a vertical wall or a horizontally extending ceiling, as shown schematically in FIGS. 3 and 4, an outer shell Sl is formed on the outer wire mesh mat M1 intended for forming the outside of the finished part element F. applied, which adjoins the barrier layer T and encloses the outer wire mesh mat Ml and forms together with this the supporting component of the precast element F. The thickness of the outer shell Sl is chosen according to the static as well as the sound and heat requirements of the precast element F and is for example 20 to 200 mm. If the prefabricated element F is used as a ceiling element, the minimum thickness of the outer shell S1 must be at least 50 mm for static reasons. The outer shell Sl is preferably made of concrete.

An inner shell S2, which adjoins the barrier layer T and encloses the inner wire mesh mat M2, is applied to the inner wire mesh mat M2, which is intended to form the inside of the prefabricated element F. The inner shell S2 can, for example, as well as the outer shell Sl consist of concrete or in the context of the invention also of other materials, such as mortar or plaster, are produced. The thickness of the inner shell S2 is chosen according to the static as well as the sound and heat-technical requirements of the finished part element F and is for example 20 to 200 mm. The inner shell S2 can also be formed so strong in the context of the invention that it forms the supporting component of the finished element F together with the inner wire mesh mat M2. The two shells Sl, S2 are applied at the place of use of the precast element F, for example sprayed by wet or dry method. The barrier layer T serves as a barrier and as an impact surface for the aufzuspritzenden Concrete. The thickness of the barrier layer T is arbitrary and should be chosen so strong that, depending on the material used, the barrier layer T during spraying of the outer and inner shells Sl or S2 no deformation occurs. In the case of different materials of the outer shell Sl and the inner shell S2, the required thickness of the outer shell Sl and the inner shell S2 also determines the respective distance between the barrier layer T and the wire mesh mats M2, M2, ie the barrier layer T can also be off-center in the context of the invention Wire mesh Ml, M2 can be arranged.

In order to improve the adhesion of the aufzuspritzenden material on the top surfaces of the barrier layer T and to prevent unwanted downflow of the material during application of the outer layer Sl and the inner shell S2, the cover surfaces of the barrier layer T can be roughened or provided with depressions. To improve the adhesion of the outer shell Sl and the inner shell S2 on the barrier layer T, plaster support gratings may also be used within the scope of the invention, which lie on the top surfaces of the barrier layer T and are fixed on the barrier layer T by the bridge wires V1, V2. The plaster carrier grid consist for example of a fine-mesh welded or woven wire mesh with a mesh size of for example 10 to 25 mm and wire diameters in the range of 0.8 to 1 mm.

Claims

Claims:

1. component consisting of two parallel, flat wire mesh mats (Ml, M2) of intersecting and welded together at the crossing points longitudinal and transverse wires (Ll, L2, Ql, Q2), from the wire mesh mats at a predetermined mutual distance holding, connected at each end with the two wire mesh mats straight web wires (Vl, V2), as well as from a between the wire mesh mats and with a predetermined distance arranged parallel to these central element, characterized in that the central element of a dimensionally stable, thin barrier layer ( T), which is penetrated by the ridge wires (Vl, V2) and held by them with a predetermined distance to each of the wire mesh mats (Ml; M2).

2. The component according to claim 1, characterized in that the web wires (Vl, V2) in predetermined directions to the wire mesh mats (Ml, M2), alternately opposite directions obliquely between the wires (Ll, L2, Ql, Q2) of the wire mesh mats (Ml , M2) are arranged like a truss.

3. The component according to one of claims 1 or 2, characterized in that the barrier layer (T) with its edges flush with the wire mesh mats (Ml, M2) closes.

4. The component according to one of claims 1 to 3, characterized in that the barrier layer (T) consists of cardboard or thin cardboard.

5. The component according to one of claims 1 to 3, characterized in that the barrier layer (T) consists of a thin plasterboard or thin plywood.

6. The component according to one of claims 1 to 5, characterized in that at least one cover surface of the barrier layer (T) roughened and / or provided with recesses.

7. The component according to one of claims 1 to 6, characterized in that at least one cover surface of the barrier layer

(T) is provided with a plaster base grid.

8. The component according to one of claims 1 to 3, characterized in that the barrier layer (T) consists of a close-meshed expanded metal mesh or of a close-mesh welded wire mesh.

9. The component according to one of claims 1 to 8, characterized in that the barrier layer (T) is arranged centrally to the two wire mesh mats (Ml, M2), wherein the distance to each wire mesh mat (Ml; M2) is preferably 10 to 50 mm ,

10. The component according to one of claims 1 to 8, characterized in that the barrier layer (T) off-center to the two wire mesh mats (Ml, M2) is arranged.

11. The component according to one of claims 1 to 10, characterized in that at least one wire mesh mat (Ml; M '2) is designed as a grating reinforcement mat, a minimum static strength of the welding node corresponding to the static requirements of the component (B), corresponding mechanical Strength of the wires (Ll, L2, Ql, Q2) of the wire mesh mats (M1, M2) and corresponding diameters and mutual distances of the wires (L1, L2, Q1, Q2), that the webs wires (V1, V2) formed as shear reinforcement elements and with the wires (Ll, Ql or L2, Q2) of at least one of the wire mesh mats (Ml; M '2) are welded to a predetermined minimum welding knot strength.

12. The component according to one of claims 1 to 11, characterized in that the wires (Ll, L2, Ql, Q2) of the Drahtgit- mats (Ml, M2) form square meshes whose side lengths are preferably in the range of 50 to 150 mm ,

13. The component according to one of claims 1 to 11, characterized in that the wires (Ll, L2, Ql, Q2) of the wire mesh - li ¬

term (Ml, M2) rectangular meshes with short side lengths of preferably 50 to 100 mm and long side lengths of preferably 75 to 150 mm form.

14. The component according to one of claims 1 to 13, characterized in that the distances between the web wires (Vl, V2) to each other in the direction of the longitudinal wires (Ll, L2) and the transverse wires (Ql, Q2) of the wire mesh mats (Ml, M2) Many times the mesh pitch, wherein the number of ridge wires (Vl, V2) is preferably 50 to 200 per m ² .

15. The component according to one of claims 1 to 14, characterized in that the diameters of the wires (Ll, L2, Ql, Q2) of the wire mesh mats (Ml, M2) and the land wires (Vl, V2) in the range of 2 to 8 mm lie.

16. The component according to one of claims 1 to 15, characterized in that the diameter of the web wires (Vl, V2) is greater than the diameter of the wires (Ll, L2, Ql, Q2) of the wire mesh mats (Ml, M2).

17. A method for producing a prefabricated element with at least one component according to one of claims 1 to 16, characterized in that in each case on to the formation of the outside of the finished part element (F) certain outer wire mesh mat (Ml) of the component (B) an outer shell (Sl ) is applied by spraying, which adjoins the barrier layer (T) of the component (B) and enclosing the outer wire mesh mat (Ml), and in that each of the to form the inside of the precast element (F) certain inner wire mesh mat (M2) of the component (B) an inner shell (S2) is applied by spraying, which adjoins the barrier layer (T) and the inner wire mesh mat (M2) encloses, wherein the barrier layer (T) each as an impact surface for the spraying of the outer shell (Sl) and the inner shell (S2) is used.