DE9307041U1 - Horizontal beams for buildings - Google Patents

Description

G2 942

Johann Moissl

Zurlberg 5
8311 Kröning

Horizontal beams for buildings

Description

The invention relates to a horizontal beam for buildings with a section for anchoring in a building part and an adjoining cantilever arm.

Such horizontal beams serve as supports for balconies, canopies, stairs, steps and the like and usually consist of profile beams or flat irons that are anchored in the part of the building that bears the load during construction. To do this, the clamped end of the beam, which for static reasons must be half as long as the cantilever arm, is usually cast into a false ceiling or secured in some other way. A major problem here is the precise alignment of the beam in a horizontal position before the clamped end is finally cast in or anchored in some other way. Alignment requires a series of relatively difficult tasks that require dowelling or welding to components that are already in place.

The invention is based on the object of providing a horizontal beam of the specified type which can be precisely aligned during construction within a short time without complex measures and which safely absorbs the loads that occur despite a shorter section for anchoring in the building part.

In the case of a horizontal beam of the type outlined at the outset, this object is achieved according to the invention in that the section for anchoring in the building part consists of a reinforcement framework with at least one horizontal tension rod and a vertical support plate firmly connected to it, to which the clamped end of the cantilever arm is attached.

In the current state of the art, the anchoring section consists of a continuation of the cantilever profile, which - as already stated at the beginning - is relatively long, takes up a lot of space, especially in height, and is difficult to fix. The solution provided by the invention has the advantage, in contrast, that instead of extending the cantilever, an anchoring section is created that is designed as a light reinforcement framework that requires only a very small amount of space and can be firmly anchored in the respective part of the building by pouring it into it.

It is advantageous if the clamped end of the cantilever is designed as a plate that is detachably connected to the support plate. The tension rod absorbs the tensile forces introduced by the cantilever, while a significant part of the moments acting on the cantilever act as compressive forces on the plate that is supported on the fixed part of the building. This means that relatively thin tension rods can be used, with two tension rods preferably being attached to the support plate that are parallel to one another.

It is particularly advantageous if a height-adjustable support element is attached to the end of the tension rod pointing away from the support plate. This support element can be used to set the reinforcement framework to a precisely horizontal position, which can easily be done before pouring. The cantilever arm then has a precisely defined, horizontal position after the reinforcement framework has been poured.

In a further development of the invention, the ends of the two tension rods pointing away from the support plate are connected by a tab

connected to each other, to which the height-adjustable support element is attached and whose upper edge is at the same height as the upper edge of the support plate. This type of design of the reinforcement framework allows effortless adjustment to the horizontal position.

In order to ensure a defined position of the reinforcement framework before final fastening by pouring or similar, the lower edge area of the support plate has a clamping element for fixing the reinforcement framework to a horizontal rail that is laid in the building part of the structure.

The clamped end of the cantilever can be firmly connected to the support plate from the start, for example by welding. It is also possible, however, to design the clamped end of the cantilever as a plate that is detachably connected to the support plate. This simplifies the installation of the horizontal beam, the reinforcement framework of which is initially embedded during the construction of the structure, after which the cantilever can later be screwed to the support plate via its plate or fastened in some other way.

According to a further feature of the invention, the end of the tension rod protruding from the support plate is designed as a threaded bolt to which the plate of the cantilever arm can be attached. Before the cantilever arm is finally attached, the threaded bolt is used to fix a plate-shaped insulation which prevents the still liquid concrete from leaking out during the pouring of the reinforcement framework and which is cut out after the concrete has hardened in order to screw on the plate of the cantilever arm.

The invention is explained below using an embodiment shown in the drawing.

Figure 1 shows the oblique view from above of a horizontal beam according to the invention before pouring the reinforcement framework and before the attachment of the cantilever arm,

Figure 2 shows a vertical section through the reinforcement framework before casting,

Figure 3 a section through the building section and the cantilever after pouring the reinforcement framework and fastening the cantilever,

Figure 4 shows a section through the horizontal beam after installation and fastening of a balcony beam and

Figure 5 is a plan view of the installed horizontal beam of Figure 4.

As the figures show, the horizontal beam 10 according to the invention consists of a cantilever arm 12 with an I-profile and a reinforcement framework 14. The cantilever arm 12 projects outwards over a masonry 16 of a building and serves to support loads, for example a balcony.

The clamped end of the cantilever arm 12 is designed as a vertically aligned plate 18 into which two bore holes 20 are machined. The reinforcement framework 14 consists of two parallel, horizontal tension rods 22 that are firmly connected to a vertical support plate 24, for example by welding. The ends of the tension rods 22 that protrude from the support plate 24 are designed as threaded bolts 26 onto which the two bore holes 22 of the plate 18 of the cantilever arm 12 can be placed. The plate 18 can then be screwed using nuts 28 so that it is pressed firmly against the support plate 24.

The ends of the two tension rods 22 pointing away from the support plate 24 are connected to one another by a plate-like tab 30 lying in a vertical plane. The upper edge 32 of the tab 30 and the upper edge 34 of the support plate 24 are at the same height, which makes it possible to precisely align the reinforcement framework 14 horizontally with the aid of a spirit level 36 shown in Figure 1. For this purpose, a

A support element designed as a screw bolt 4 0 is attached to the horizontal extension 3 8 of the bracket 3 0, the base 42 of which rests on a horizontal plane 44 of an already installed ceiling plate 4 6. By adjusting the screw bolt 40, an exactly horizontal position of the reinforcement framework 14 can be set using the spirit level 36.

In particular, it can be seen in Figure 2 that a clamping element 48 is attached to the lower edge area of the support plate 24, which consists of a threaded bolt 50 protruding from the support plate 24 in the direction of the support member 40 with a screwed-on locking nut 52 and a clamping angle 54 that can be placed on the threaded bolt 50 and fixed by the locking nut 52. The lower edge of the support plate 24 is placed on an L-shaped horizontal rail 56 that rests on the top of the masonry 16. By tightening the locking nut 52, the support plate 24 is fixed to the horizontal rail 56.

After the support plate 24 has been fixed to the horizontal rail 56, the reinforcement framework 14 is adjusted to the horizontal position by means of the support element designed as a screw bolt 40.

The reinforcement framework 14 positioned in the manner described is fixed to an insulating plate 58 using the two nuts 28 screwed onto the threaded bolts 26, whereby the two threaded bolts 28 penetrate the insulating plate 58. In the screwed-on position shown in Figure 2, the support plate 24 rests on the side of the insulating plate 58 facing the inside of the building, the lower edge of which rests on the masonry 16. On the side of the insulating plate 58 facing outwards, a recess 60 is left in the masonry 16, which is dimensioned such that the end of the cantilever arm 12 to be clamped can be inserted with the plate 18.

In the position and fixed position of the reinforcement framework 14 shown in Figure 2, the space above the

Ceiling plate 4 6 is filled with concrete 62 (see Figure 3) or similar. The continuous insulating plate 58 prevents the still liquid concrete 62 from running into the recess 60 of the masonry 16. After the concrete 62 has hardened, the reinforcement framework 14 is immovably secured. All that is then required is to cut out the part of the insulating plate 58 lying in the recess 60, whereupon the plate 18 of the cantilever arm 12 with its two bore holes 22 is pushed onto the threaded bolts 26 of the support plate 24 and tightened there using the two nuts 28. Finally, the recess 60 is closed, for example by bricks corresponding to the masonry 16.

As shown in Figures 4 and 5, the loads to be supported can now be placed on the cantilever arm 12, for example wooden beams 64 for a balcony.

Since the reinforcement framework 14 according to the invention consists essentially only of the two tension rods 22 over most of its length, the diameter of which is usually 22 mm, the reinforcement framework 14 requires very little installation space, so that there is enough room to accommodate other structural parts underneath or above it, for example reinforcements for roller shutter boxes. Due to the very simple alignment of the reinforcement framework 14 and the easy screwing of the cantilever arm 12 to the reinforcement framework 14, the installation time for the entire horizontal beam 10 is very short.

The reinforcement framework 14 is not only subjected to bending stress by the cantilever arm 12 and the load supported on it, but also to tension and compression. The tensile forces are absorbed by the tension rods 22, while the compression forces act on the lower part of the support plate 24, which transmits these forces into the building part (concrete 62). This has the significant advantage that the reinforcement framework 14 can be very short compared to the cantilever arm 12; in a practical embodiment, the length ratio is approximately 3:1, i.e. that with a length

of the cantilever arm 12 of 140 cm, a length of 50 cm is sufficient for the reinforcement framework 14.

Of course, the cross-sectional shape of the cantilever arm 12 can be selected according to the requirements, for example as a tube, square profile, I- or T-profile beam.

Claims (7)

Protection claims 1. Horizontal beam for buildings with a section for anchoring in a building part and a cantilever arm adjoining thereto, characterized in that the section for anchoring in the building part consists of a reinforcement framework (14) with at least one horizontal tension rod (22) and a vertical support plate (24) firmly connected thereto, to which the clamped end of the cantilever arm (12) is attached. 2. Horizontal support according to claim 1, characterized in that the clamped end of the cantilever arm (12) is designed as a plate (18) which is detachably connected to the support plate (24). 3. Horizontal support according to claim 1 or 2, characterized in that a height-adjustable support member (40) is attached to the end of the tension rod (22) pointing away from the support plate (24). 4. Horizontal support according to one of claims 1 to 3, characterized in that two mutually parallel tension rods (22) are attached to the support plate (24). 5. Horizontal support according to claim 4, characterized in that the ends of the two tension rods (22) pointing away from the support plate (24) are connected to one another by a tab (30) to which the height-adjustable support member (40) is attached and whose upper edge (32) is at the same height as the upper edge (34) of the support plate (24). 6. Horizontal support according to one of claims 1 to 5, characterized in that the lower edge region of the support plate (24) has a clamping element (48) for fixing the reinforcement framework (14) to a horizontal rail (56). 7. Horizontal support according to one of claims 2 to 6, characterized in that the end of the tension rod (22) protruding from the support plate (24) is designed as a threaded bolt (26) for fastening the plate (18) of the cantilever arm (12).