CH701351A1 - Cantilever panel. - Google Patents

Abstract

A cantilevered connection element (11) consists of an insulation body (13) and a reinforcement penetrating the insulation body (13), which reinforcement is formed from at least one row of shaped steel rods (15). In the insulating body (13) pressure elements (17) are integrated, which can initiate compressive forces in a wall in which the Kragplattenanschlusselement (11) is inserted. The Kragplattenanschlusselement (11) is constructed of individual Kragplattenmodulen (23) and individual insulating bodies (27), which are individually juxtaposed can be arranged.

Description

Field of the invention

The present invention relates to a cantilever panel connection element according to the preamble of claim 1, a cantilever module for producing a cantilever panel connection element according to claim 14, a system for producing a cantilever panel connection element according to claim 15 and a method for producing a cantilever panel connection element according to claim 17.

State of the art

EP 0 499 590 discloses a heat-insulating cantilever connection element with an insulating body, an upper layer of spaced apart reinforcing bars, which penetrate the insulation body, a lower layer of spaced armouring or pressure transmission elements, which also penetrate the insulation body, and at least one transverse bar on each side of the insulating body. At least one transverse bar is provided on each side of the insulating body, wherein at least one transverse bar is arranged at the upper layer of the reinforcing iron and at least one transverse bar at the lower layer of the reinforcing iron or the pressure transmission elements. In addition, a vertically disposed plate is provided between two adjacent reinforcing bars of a layer of reinforcing bar which interconnects the transverse bars.

The cantilever panel connection element described has the advantage that it can be easily produced in the production and with little and relatively inexpensive material. The disadvantage, however, is that for the absorption of shear forces at least one cross bar per layer of reinforcing iron is necessary.

Object of the invention

It is therefore an object of the present invention to provide a Kragplattenanschlusselement which does not have the above-mentioned disadvantages. In particular, it is an object to provide a connection element which is able to absorb and dissipate the various forces occurring with the smallest possible number of components. Another object of the invention is to provide a cantilever panel connection element that can be adapted individually and with little effort to the present forces.

description

According to the invention the object is achieved in a cantilever panel connection element according to the preamble of claim 1, characterized in that the reinforcement is formed of a plurality of mild steel bars, which are arranged in the upper half of the insulating body. In the insulating body below the forming steel bars a plurality of printing elements are integrated. The shaped steel rods have the advantage that they are able to absorb tensile and shear forces simultaneously. The use of printing elements in the insulating body has the advantage that the pressure forces are derived directly through the insulating body in the adjacent masonry or an adjacent concrete slab.

Characterized in that the pressure elements are conveniently steel rods, the pressure elements have a compressive strength, which has grown any occurring stress in buildings. In addition, the conditions relating to the combustibility of a material in the construction sector of steel are in any case met.

Advantageously, the length of the pressure elements approximately on the wall thickness of the insulating body. Unnecessary material use is avoided and the cantilever connection element is easily integrated into a building, since it has no projections or heels.

The arrangement of the pressure elements in a short distance to the lower edge of the insulating body has the effect that the pressure elements have the greatest possible distance from the overlying steel bars. As a result, the torque introduced via the shaped steel bars is counteracted by a torque which is formed from the product of the largest possible lever between the shaped steel bars and the underlying pressure elements and the lowest possible holding force.

Since the printing elements are round in cross-section, they can be produced inexpensively by round rods are cut to the appropriate diameter.

In a preferred embodiment, pressure distribution plates are fixed at the two ends of the printing elements end face, which project beyond the cross section of the printing elements dimensionally. It can thus be ensured that the pressure forces which occur are uniformly distributed over the pressure elements and that the pressure elements can not be pulled out of the insulation body in the direction of their longitudinal extent.

The inserted steel rods may have different cross-sections such as angle, U, H or T-profile. Molded steel bars with mentioned profiles have the advantage that they can absorb lateral forces in addition to the tensile forces occurring.

Advantageously, the individual mold steel bars are connected by at least one transverse bar. This design feature ensures that individual shaped steel bars can not be pulled out of the insulating body. A position assurance of the forming steel rods is given by.

Conveniently, the shaped steel bars are connected on both sides by at least one transverse bar. As a result, a position assurance is ensured with respect to both directions of the longitudinal axis of a forming steel bar.

In a preferred embodiment, the at least one transverse bar is located at a short distance from one end of the shaped steel bars.

The present invention is also a cantilever module for producing a Kragplattenanschlusselements according to claim 14, wherein the reinforcement is advantageously formed by a single forming steel bar, which is arranged in the upper half of the insulating body and, in the insulating body, a single pressure element below and in Distance to the forming steel bar is integrated. Single cantilever modules contain only a single bar and a single pressure element. The cantilever panel connecting element consisting of several cantilever modules can be individually adapted to the forces occurring in the respective building.

Another object of the present invention is a system for producing a Kragplattenanschlusselements, wherein the system advantageously consists of a plurality of individual Kragplattenmodulen described above and individual insulating bodies, which are individually composable. Therefore, only a few different modules are necessary for the construction of a cantilever panel connection element. A cantilever panel connection element can be custom-built to existing forces according to a modular system. Consequently, the cantilever panel connection element is neither undersized nor oversized, and only those production costs are incurred which are necessary.

Another object of the present invention is also a method for producing a Kragplattenanschlusselements, wherein in a first step, a single cantilever module is made. In the upper half of a cuboid insulating body, a reinforcement in the form of a single steel bar is used. Below the forming rod a pressure element is used. In a second step, several cantilever modules are arranged side by side. The mutually oriented side surfaces of the individual insulation body are connected together. Since a cantilever panel connection element is not produced in one piece, but is assembled from standard cantilever panel modules, the production method according to the invention is inexpensive and at the same time flexible.

In a preferred method, the mutually oriented side surfaces of the individual cantilever modules are glued together. Gluing can be easily automated and keep the side surfaces together permanently.

Characterized in that between two cantilever modules or at the edge of the cantilever panel connecting element further insulation body are used, the cantilever connection element thus produced can be individually adapted to the respective forces of a building. The cantilever panel connection element is tailor-made, although it is composed of cantilever module modules and insulation bodies, which are mass products.

The invention will be explained by way of example with reference to the figures. It shows: <Tb> FIG. 1 <sep> is a perspective view of an inventive Kragplattenanschluss-element, which is composed of 5 Kragplattenmodulen and two outside of the Kragplattenmodule subsequent insulation bodies; <Tb> FIG. Fig. 2 <sep> the cantilever panel connection element of Fig. 1 in a front view; <Tb> FIG. 3 <sep> the cantilever panel connection element of Figure 1 in a side view. <Tb> FIG. 4 <sep> is a perspective view of a cantilever panel connection element, which is constructed from 2 cantilever panel modules and 5 insulation bodies; and <Tb> FIG. 5 <sep> an exploded view of a Kragplattenanschlusselements, which is composed of 4 Kragplattenmodulen and 3 insulation bodies.

1 to 3 show a Kragplattenanschlusselement 11 with an insulating body 13 and a plurality of the insulating body 13 crossing shaped steel bars 15. The shaped steel rods 15 may have different cross-sectional profiles (T-, H- or U-shaped, etc.). In contrast to the above-mentioned EP 0 499 590 mentioned cross-sectional profiles allow the recording not only of tensile forces, but also of lateral forces. The use of transverse bars, which serves in EP 0 499 590 to absorb transverse forces, can be dispensed with in the cantilevered-panel connection element 11 according to the invention. For example, in the case of a T-beam, the flange absorbs the tensile forces that occur and the web absorbs the transverse forces that occur. The insulating body 13 is made of a foamed plastic, preferably PU foam, a glass or rock wool plate. In the insulation body 13 pressure elements 17 are integrated. In the exemplary embodiment, the pressure elements 17 have a round cross section. It would also be conceivable, however, for the printing elements 17 to be of e.g. a rectangular (shown in Fig. 5) or a cross-shaped cross-section. A cross-shaped pressure element can be z. B. in that two L-profiles are welded at their corners.

FIGS. 1, 2 and 4 show that the number of printing elements 17 corresponds to the number of shaped steel rods 15. It would also be possible that the number of pressure element 17 is not equal to the number of shaped steel rods 15. These pressure elements 17 are arranged at a short distance from the lower edge of the insulating body and below the shaped steel rods 15. Thus, the majority of the pressure forces occurring are absorbed by the pressure elements 17 and can be introduced by these in a subsequent to the insulating body 13 wall. In this embodiment, the printing elements 17 are made of steel.

On the front side 17 square pressure distribution plates 19 are attached to the pressure elements. The pressure distribution plates 19 may be welded, screwed or glued to the end faces of the pressure elements 17. Other forms of connection are conceivable, it is only important that the compound does not solve unintentionally.

The pressure distribution plates 19 project beyond the cross section of the pressure elements 17 and distribute on the one hand the pressure forces occurring evenly on the pressure elements 17 and on the other hand prevent a shift of the pressure elements 17 in the direction of their longitudinal axis. It would also be conceivable for a single elongate plate to replace the pressure distribution plates 19 on one side of the insulating body. The elongate plate covers all end faces of the printing elements 17, which have the same orientation.

At a short distance from the ends of the shaped steel rods 15 connect cross bars 21, the forming steel rods 15 transversely to the longitudinal direction thereof. The transverse rods 21 prevent a single shaped steel rod 15 from being unintentionally pulled out of the insulating body 13 on the one hand during transport and installation of the cantilevered connection element 11 and on the other hand when installed. The cross bars 21 fulfill the task of a pull-out protection and are not intended for the absorption of forces occurring in the building. The cross sections of the transverse rods 21 can therefore be dimensioned small and preferably have a cross section of 6 to 8 mm. For the pull-out protection in the installed state, it would also be conceivable that the transverse rods 21 do not connect the shaped steel rods 15 continuously and are provided, for example, in each case as individual parts at the ends of the shaped steel rods.

FIGS. 1 and 4 show that the cantilevered connection element 11 can be composed of individual cantilever module modules 23. Each individual cantilever module 23 consists of a cuboid insulating body, in which in the upper half of a shaped steel support 15 and below a pressure element 17 is inserted. Between two cantilever module 23 and at the edge of Kragplattenanschlusselements 11 more cuboid insulating body 27 may be used. The individual cantilever module 23 and the insulation body 27 are glued to their mutually oriented side surfaces.

Fig. 5 shows the modular structure of the cantilever panel connection element 11 from Kragplattenmodulen 23 and insulation bodies 27. The mutually oriented side surfaces 25 of a single cantilever module 23, respectively. an insulating body 27 may additionally be positively connected (not shown in Fig. 5). As positive locking z. B. a positive or negative dovetail shape, for producing a dovetail connection, be executed.

The modular structure of the cantilever panel connection element 11 has the advantage that it is constructed of cantilever module 23 and insulation bodies 27. This allows individual adaptation of the cantilever panel connection element 11 to the existing forces in the respective building. Also, by the appropriate selection of Kragplattenmodulen 23 and insulating bodies 27, an individual length of the Kragplattenanschlusselements 11 can be achieved. Oversizing or undersizing the cantilevered connection element with respect to the prevailing forces can be avoided by the modular construction. The storage costs of the inventive Kragplattenanschlusselements 11 are low, since only a few standard modules must be kept in stock. The production costs of a cantilevered connection element 11 are also low, since the respective customized cantilever connection element 11 is manufactured from standard modules.

Legend:

[0029] <Tb> 11 <sep> cantilever panel <Tb> 13 <sep> insulation body <Tb> 15 <sep> form steel bars <Tb> 17 <sep> print elements <Tb> 19 <sep> Druckverteil plates <Tb> 21 <sep> crossbars <Tb> 23 <sep> Kragplattenmodul <tb> 25 <sep> side surfaces of the cantilever plate modules or the insulation body <Tb> 27 <sep> insulation body

Claims (19)

1. cantilever connection element (11) having an insulating body (13) and a insulation body (13) penetrating reinforcement, characterized in that the reinforcement of a plurality of mild steel bars (15) is formed, which in the upper half of the insulating body (13) are and in the insulating body (13) below the mold steel rods (15) a plurality of pressure elements (17) is integrated. 2. cantilever connection element (11) according to claim 1, characterized in that the pressure elements (17) are steel rods. 3. cantilever connection element (11) according to one of claims 1 to 2, characterized in that the length of the pressure elements (17) has approximately the wall thickness of the insulating body (13). 4. cantilever connection element (11) according to one of claims 1 to 3, characterized in that the pressure elements (17) are arranged at a short distance from the lower edge of the insulating body (13). 5. cantilever panel connection element (11) according to one of claims 1 to 4, characterized in that the pressure elements (17) are round in cross-section. 6. cantilever panel connection element (11) according to one of claims 1 to 5, characterized in that at the two ends of the pressure elements (17) frontally Druckverteil plates (19) are fixed. 7. Kragplattenanschlusselement (11) according to claim 6, characterized in that the Druckverteil plates (19) dimensionally beyond the cross section of the pressure elements (17). 8. cantilever panel connection element (11) according to one of claims 6 to 7, characterized in that the pressure distribution plates (19) preferably flush with the insulating body (13) close. 9. cantilever panel connection element (11) according to one of claims 1 to 8, characterized in that the shaped steel rods (15) in cross section have an angle, U, H or a T-profile. 10. cantilever connection element (11) according to one of claims 1 to 9, characterized in that the individual shaped steel rods (15) by at least one transverse bar (21) are connected. 11. cantilever connection element (11) according to one of claims 1 to 9, characterized in that the shaped steel rods (15) on both sides by at least one transverse bar (21) are connected. 12. cantilever panel connection element (11) according to one of claims 1 to 11, characterized in that the at least one transverse bar (21) is located at a short distance to one end of the forming steel rods (15). 13. cantilever connection element (11) according to one of claims 1 to 12, characterized in that the insulating body (13) made of a foamed plastic, a glass or rock wool plate or foam glass is made. 14 cantilever module (23) for producing a Kragplattenanschlusselements (11) having a plurality of Kragplattenmodulen (23) with - An insulation body (27) and - A reinforcing body (27) penetrating reinforcement, characterized in that the reinforcement is formed by a single forming steel rod (15) which is arranged in the upper half of the insulating body (27) and, in the insulating body (27), a single pressure element (17) is integrated below and at a distance from the forming steel rod (15). 15. System for producing a cantilever panel connection element (11), characterized in that the system consists of a plurality of individual cantilever module (23) according to claim 14 and individual insulating bodies (27). 16. System for producing a Kragplattenanschlusselements according to claim 15, characterized in that the individual cantilever module (23) and the individual insulation body (27) to adapt to forces and dimensions that occur on a building, in their order are individually composable. 17. A method for producing a Kragplattenanschlusselements (11), characterized in that in a first step, a single cantilever module (23) is prepared by in the upper half of a cuboid insulating body (27) a reinforcement in the form of a single forming steel rod (15) and a pressure element (17) is inserted below the forming steel rod (15); and that in a second step a plurality of cantilever module (23) are arranged side by side and the mutually oriented side surfaces (25) of the individual insulating body are interconnected. 18. A method for producing a Kragplattenanschlusselements (11), characterized in that the mutually oriented side surfaces (25) of the individual cantilever module (23) are glued together. 19. A method for producing a Kragplattenanschlusselements (11), characterized in that between two Kragplattenmodule (23) or at the edge of the Kragplattenanschlusselements (11) further insulation body (27) are used.