DE9417777U1 - Cantilever panel connection element - Google Patents

Description

6600SDE Utility Model

Applicant: Hans-Werner Dausend 42289 Wuppertal

Cantilever plate connection element

The invention relates to a cantilever plate connection element with a heat-insulating, cuboid-shaped insulating body consisting of an upper part and a lower part, which is provided with horizontally directed upper reinforcing iron as tension members, with diagonally downwardly directed reinforcing iron as transverse force members and with compression members.

Such cantilever slab connection elements are used as prefabricated reinforcement parts in the transition area between a floor slab to be cast and a cantilever slab to be connected to it, e.g. a balcony, and are intended to exclude heat transfer between the cantilever slab and the floor slab as far as possible.

The known cantilever plate connection elements are only suitable for use on site, i.e. on the building to be constructed. In practice, however, cantilever plates are increasingly being manufactured in two stages, whereby firstly a filigree plate made of reinforced concrete with a thickness of approx. 4**6 cm is cast in a precast concrete factory, which serves on site as the lower part of the cantilever plate and is also used as a formwork element, while in a second stage the floor slab is

together with the upper part of the cantilever plate. When using the previously known filigran cantilever plates, which consist only of concrete, difficulties arise with regard to thermal insulation between the cantilever plate and the building and with regard to the absorption of compressive forces that are to be transferred from the cantilever plate to the building. There are also cantilever plate connecting elements on the market in which the elements consist of an upper and lower part and which contain round profiles with welded-on pressure plates that protrude as pressure elements on both sides of the connecting elements. The pressure elements that protrude on both sides often lead to problems in the manufacture of the concrete cantilever plates and in the transport of these.

The invention is based on the object of creating a cantilever plate connection element which is particularly suitable for cantilever plates to be produced using a filigree plate.

To achieve this object, the invention provides that the lower part of the

Cantilever plate connection element can be used as an edge finish when casting the filigree plate and has reinforcement irons protruding towards the side of the filigree plate as pressure elements, which carry pressure plates at their other end, which are flush with the building-side side surface of the

Cantilever plate connection element lower part.

The invention provides the precast concrete factory with a heat-insulating and at the same time compressive force-transferring reinforcement element, which is used there in

the filigran cantilever plate is cast in such a way that the insulating body is located on the edge of the filigran cantilever plate facing the building, whereby the compression member reinforcing iron is cast into the filigran cantilever plate, while the compression plates of the compression members lie flush in the connection surface on the building side. The filigree cantilever plate produced in this way, which has no protruding compression members, essentially has the shape of non-bulky plates that can be stacked in a weight- and space-saving manner and can therefore be transported to the construction site without any problems. At the construction site, the filigree cantilever plate with its insulating body is attached to the building, after which the upper part of the insulating body, which carries the tension members and the shear force members, is placed on the lower part of the insulating body cast into the filigree cantilever plate. In order to facilitate precise alignment of the two parts of the insulating body, a longitudinal groove is preferably provided on the upper part to accommodate an associated key provided on the lower part. The floor slab and the actual cantilever plate cast.

According to the invention, the lower part of the insulating body can have a height equal to the thickness of the filigree cantilever plate, so that the lower part lies within the slat contour of the filigree cantilever plate. However, it is also possible to make the height of the lower part of the insulating body greater than the plate thickness of the filigree cantilever plate, whereby, however, the projection of the lower part of the insulating body over the filigree cantilever plate should be lower than the height of the lattice girders cast into the filigree cantilever plate for the upper reinforcement, so that the

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Filament cantilever plates can still be stacked on top of one another without the risk of damaging the insulating body. In the latter case, it is advisable to provide the insulating body's lower part with bevelled corner recesses on its upper side to accommodate the shear force members of the upper part.

According to the invention, the pressure plates and the parts of the reinforcing iron close to the insulating body are made of stainless steel, while the protruding end areas of the reinforcing iron can be made of structural steel to reduce costs.

The subject matter of the invention is described in more detail below with reference to a drawing in which:

Fig. 1 a two-part cantilever plate connection element according to the invention, in a perspective view,

Fig. 2 the cantilever plate connection element, in a

perspective view in Fig. 1 seen from the right,

Fig. 3 a using the

Cantilever plate connection element according to Fig. and 2 cantilever plate cast onto a building and

Fig. 4 shows a cantilever plate cast onto a building with a slightly modified design of the insulating body.

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The cantilever plate connection element shown in Fig. 1 to 3 has an approximately cuboid-shaped insulating body to be arranged between the cantilever plate and the building, which is divided in a horizontal plane into an upper part 1 and a lower part 2, with a feather key 3 being provided on the upper side of the lower part 2, to which a groove 4 is assigned on the underside of the upper part 1. Two horizontally directed reinforcing irons 5, 6 are cast into the upper part 1 as tension members and two reinforcing irons 7, 8 angled downwards in the area of the insulating body upper part 1 as transverse force members, with the two

Tension member reinforcement bars 5,6 and the two transverse reinforcement bars 7,8 are connected to one another at their ends facing the floor by a welded cross bar 9. Cross bars 17 can also be welded to the opposite ends of the reinforcement bars 5,6,7,8 facing the cantilever plate, or these reinforcement bars can have transverse bends.

Two pressure elements 10,11 are cast into the insulating body lower part 2, each of which comprises reinforcing irons 12,13 projecting towards the side of the cantilever slab to be connected or towards the permanent formwork, each of which carries a pressure plate 14,15 at its other end. The pressure plates 14,15' are embedded flush with the surface in the housing-side side surface 16 of the lower part 2. The pressure plates 14,15 and the parts of the reinforcing irons 5,6,7,8,12,13 near the insulating body are made of stainless steel, while the projecting end areas of the reinforcing irons, marked by hatching in the drawings, are made of structural steel. The freely projecting ends of the

In the example, compression member reinforcement bars 12, 13 are connected to one another by a welded cross bar 17, the ends of which are angled several times.

The lower part of the cantilever plate connection element is first used in a concrete part factory when casting a filigree cantilever plate 18, which is shown in solid lines in Fig. 3. Here, the insulating body lower part 2 is arranged on the edge of the filigree cantilever plate 18 and its protruding reinforcing irons 12,13 are cast into the filigree cantilever plate. The lower part 2 protrudes here a little beyond the top of the filigree cantilever plate 18 and is provided on its top on the side facing the filigree cantilever plate 18 with corner recesses 19,20 to accommodate the lower areas of the bevelled shear force reinforcing irons 7,8. On site, the filigree cantilever plate 18 is attached to the building 21 to be erected in the manner shown in Fig. 3, after which the insulating body upper part 1 is placed with its groove 4 on the key 3 of the lower part 2. The shear reinforcement iron 7, 8 extend with their cantilever plate-side ends between the connecting reinforcement loops 22 of the filigree cantilever plate 18, while the tension member reinforcement iron 5, 6 extend close to the top of the cantilever plate 23 and floor slab 24 to be cast. After the floor slab 24 and the cantilever plate 23 have been cast, the pressure plates 14, 15 lie against the front surface of the floor slab 24, so that the compressive forces exerted by the cantilever plate are perfectly transferred to the building.

In the embodiment example according to Fig. 4, the insulating body lower part 25 has a height equal to the thickness of the filigree cantilever plate 18. The lower part 25 is here attached with its pressure plates 14, 15 directly to the slightly higher wall of the building 21, while the insulating body upper part 26 lies between the cantilever plate 23 and the floor slab 24.

As can be seen from Fig. 3 and 4, the fig. 18 cantilever plates manufactured using the insulating body bases 2 and 18 have a lightweight plate shape, so that they can be easily handled during storage, transport and also when attached to the building.

Reference list

1 Iso L i body*-upper part i L

2 Insulating body"lower part

3 key

4 grooves

5 Reinforcing bars/tension bars

6 Reinforcing bars/tension bars

7 Reinforcing bars/shear force members

8 Reinforcing bars/shear force members

9 Crossbar

10 Pressure link

11 Pressure link

12 reinforcing bars

13 Reinforcing bars

14 Printing plate

15 Printing plate

16 Side surface

17 Cross tab

18 Filigran cantilever plate

19 corner recesses

20 corner recesses

21 buildings

22 Connection"Reinforcement Loops

23 Cantilever plate

24 Floor ceiling

25 Insulating body'-lower part

26 Insulating body^upper part

Claims (4)

66008DE Protection claims 1. Cantilever slab connection element, with a heat-insulating, cuboid-shaped insulating body consisting of an upper part and a lower part, which is provided with horizontally directed upper reinforcement bars as tension members, with diagonally downward directed reinforcement bars as shear members and with compression members, characterized in that the lower part (2) can be used as an edge finish when casting the filigree cantilever plate (18) and has reinforcement irons (12, 13) projecting towards the side of the filigree cantilever plate (18) as pressure members (10, 11), which carry pressure plates (14, 15) at their other end, which are embedded flush with the surface in the side surface (16) of the lower part (2) facing the building. 2. Cantilever plate connection element according to claim 1, characterized in that the tension members (5, 6) and transverse force members (7, 8) are firmly enclosed in the upper part (1) and that the upper part (1) is provided with a groove (4) for receiving a feather key (3) provided on the lower part (2). 3. Cantilever plate connection element according to claims 1 and 2, characterized in that the lower part (2) is provided on its upper side with bevelled corner recesses (19, 20) for receiving the transverse force members (7, 8) of the upper part (1). 4. Cantilever plate connection element according to claims 1, 2 or 3, characterized in that the pressure plates (14, 15) and the parts of the reinforcing iron (5, 6, 7, 8, 12, 13) near the insulating body are made of stainless steel and that the projecting end regions of the reinforcing iron are made of structural steel. ■ ·