DE102023127232A1 - Building with a load-bearing part of the building and at least one cantilevered structure fixed to the part of the building - Google Patents

Abstract

A building has a load-bearing building part (2) and at least one cantilevered building body (3) fixed to the building part (2). The structure (1) has a connection arrangement (7) for subsequently connecting the cantilevered structure (3) to the load-bearing structural part (2) with at least one tensile force-transmitting structure (8) and at least one compressive force-transmitting structure (9). The cantilevered structure (3) has at least one first support structure (4), in particular a floor plate or ceiling plate, and at least one second support structure (5a, 5b) formed in one piece with the first support structure (4), in particular a cheek or a cheek rising from the base plate cheek pointing downwards from the ceiling tile. First sections (10) and second sections (11) of the tensile force-transmitting structure (8) are connected to one another via at least one first connecting device (14), and first sections (12) and second sections (13) of the compressive force-transmitting structure (9) are connected via at least one second connecting device (15) connected to each other. The cantilevered structure (3) is a prefabricated part made of concrete and the at least one first support structure (4) of the cantilevered structure (3) has a smallest thickness (a) of at most 150 mm.

Description

The invention relates to a building with a load-bearing structural part and at least one cantilevered structure fixed to the structural part of the type specified in the preamble of claim 1.

From the JP 2002-121818 A a connection arrangement for a balcony is known which has tensile force-transmitting structures and compressive force-transmitting structures. The balcony is trough-shaped to accommodate flooring.

The invention is based on the object of creating a building of the generic type with an advantageous structure.

This task is achieved by a building with the features of claim 1.

It has been shown that the thickness of the first support structure, i.e. the floor or ceiling slab, can be significantly reduced if the cantilevered structure is manufactured as a prefabricated part from concrete and the first and second support structures are formed in one piece. When the cantilevered structure is manufactured as a prefabricated concrete part, a one-piece structure of high quality can be produced in the precast plant.

Due to the one-piece design of the first and second support structure, the cantilevered structure has a high level of rigidity despite the small thickness of the first support structure.

For balconies, the base plate is usually at least 160 mm thick. The design according to the invention makes it possible to design the first support structure, namely the base plate or the ceiling plate, with a smaller thickness. The smallest thickness of the first supporting structure is a maximum of 150 mm. The strength class of the concrete of the cantilevered structure is in particular at least C30/37. If higher-strength concrete is used, it is particularly possible to further reduce the thickness of the first support structure. The strength class of the concrete can in particular be at least C45/55, in particular at least C100/115. A cylinder compressive strength of the concrete of up to 200 N/mm ² can be advantageous. The concrete of the cantilevered structure is in particular high-strength concrete.

The concrete can in particular be fiber-reinforced. In particular, the concrete of the cantilevered structure is reinforced with steel fibers or carbon fibers. If the concrete of the cantilevered structure is fiber-reinforced, the cantilevered structure in particular has no further reinforcement.

In particular, the thickness of the first support structure is constant, so that little material is required to produce the cantilevered structure. However, different thicknesses of the first support structure can also be provided. In the present case, if the thickness of the first support structure is not constant, the smallest thickness of the first support structure is considered.

The smallest thickness is in particular at most 130 mm, in particular at most 120 mm, in particular at most 100 mm. In particular, the smallest thickness is at least 50 mm, in particular at least 80 mm.

Due to the small thickness of the first support structure, improved thermal decoupling is achieved in particular. In the area of the first supporting structure, a layer of insulating material with a reduced thickness is usually formed between the supporting structural part and the cantilevered structural body. Due to the reduced thickness of the first support structure, and in particular due to the also reduced thickness of the at least one second support structure, the area with reduced thickness of the insulating material can be kept small and thereby good thermal decoupling can be achieved.

The at least one second support structure of the cantilevered structure is advantageously also designed with a comparatively small thickness. The smallest thickness of the at least one second support structure is in particular at most 150 mm, in particular at most 130 mm, in particular at most 120 mm, advantageously at most 100 mm. The smallest thickness of the at least one second support structure is in particular at least 50 mm, in particular at least 80 mm. In an advantageous design, the second support structure is designed as a continuous, full-surface cheek.

The second support structure in particular has a constant height. The at least one second support structure has, in particular, a top side that runs horizontally and extends to the outside of the cantilevered building, which is remote from the supporting part of the building. Alternatively, it can also be provided that the height of the at least one second support structure decreases as the distance from the supporting part of the building increases. For example, at least one second support structure can have an approximately triangular shape. Alternatively, the second support structure can run obliquely to the at least one first support structure in the manner of a strut. It can also be provided that at least one second Support structure has one or more recesses.

The first support structure runs in particular approximately horizontally. The first support structure can be a floor slab or a ceiling slab. The at least one second support structure extends transversely to the first support structure. The at least one second support structure runs in particular approximately vertically. However, an inclination towards the vertical can also be provided, for example for optical reasons. An inclination of up to about 45° to the vertical can be advantageous. The at least one second support structure has a greater extent in the vertical direction than the at least one first support structure. The at least one second support structure extends in the vertical direction in particular over at least 50 cm, advantageously over at least 60 cm.

Due to the arrangement of the second support structure transversely to the first support structure, the tensile force-transmitting structure and the compressive force-transmitting structure can be arranged with a vertical offset from one another, in particular with a vertical distance from one another. Compared to the arrangement of the tensile and compressive force-transmitting structures in a common horizontal plate, this results in an enlarged lever arm and therefore a larger transferable bending moment. If the tensile force-transmitting structures and the compressive force-transmitting structures are designed separately from one another, the support structures can in particular be designed with reduced thicknesses.

If the at least one tensile force-transmitting structure projects into a wall of the load-bearing structural part that is transverse to the connecting surface, this wall of the load-bearing structural part can also be designed with a smaller wall thickness. In particular, a greater wall thickness of the wall in which the at least one tensile force-transmitting structure of the load-bearing structural part is embedded can be omitted. This is possible in particular due to the lower weight of the cantilevered structure due to its low wall thickness and due to the good introduction of force, which is achieved by the design of the connection arrangement according to the invention. Any additional reinforcement in the load-bearing part of the building can be reduced in particular compared to known arrangements.

The at least one tensile force-transmitting structure has a first center of mass. Each tensile force-transmitting structure has its own first center of mass. The at least one assigned compressive force-transmitting structure has a second center of mass. Each structure that transmits compressive force has its own second center of mass. The assigned compressive force-transmitting structure is the compressive-force-transmitting structure whose center of mass has the smallest horizontal distance to the center of mass of the tensile-force-transmitting structure.

A distance from the first center of mass and the second center of mass, measured in the horizontal direction when looking perpendicularly to a connecting surface of the load-bearing structural part, is in particular at least 5 cm, in particular at least 15 cm. The distance is in particular less than 2.0 m. The distance is in particular a maximum of one third of the width of the first support structure measured in the horizontal direction and when viewed perpendicularly to the connection surface. The connection surface is the surface through which the tensile force-transmitting structure and the associated compressive force-transmitting structure protrude. Different pairs of structures transmitting tensile force and associated structures transmitting compressive force can have different connection surfaces.

In an alternative embodiment, it can be provided that the distance between the centers of mass is 0.

A distance measured in the vertical direction from the first center of mass and the second center of mass is in particular at least 25 cm, in particular at least 40 cm, in particular at least 50 cm. In particular, the distance between the centers of mass measured in the vertical direction is at most 250 cm.

The distance between the centers of mass is the distance between the center of mass of a tensile force-transmitting structure and the center of mass of the associated compressive force-transmitting structure.

Tensile force-transmitting structures and compressive force-transmitting structures are in particular arranged in pairs with one another. The building advantageously has at least two tensile force-transmitting structures, in particular exactly two tensile-force-transmitting structures, and at least two compressive-force-transmitting structures, in particular exactly two compressive-force-transmitting structures. In particular, the number of tensile force-transmitting structures, each forming a unit, and the number of compressive force-transmitting structures, each forming a unit, are the same. In particular, each tensile force-transmitting structure is assigned exactly one compressive force-transmitting structure and each compressive force-transmitting structure is in particular assigned exactly one tensile force-transmitting structure.

However, it can also be provided that, if the first support structure is a floor plate, a common compressive force-transmitting structure is assigned to two tensile force-transmitting structures. In this case, the compressive force-transmitting structure is arranged in particular centrally between the two assigned tensile force-transmitting structures in relation to the horizontal direction. The distance of the center of mass of the compressive force-transmitting structure, measured in the horizontal direction when looking perpendicularly to a connecting surface of the load-bearing structural part, is advantageously the same as both centers of mass of the tensile force-transmitting structures. If the first support structure is a ceiling plate, the arrangement is rotated accordingly and two compressive force-transmitting structures can be assigned to a tensile force-transmitting structure. In this case, in particular, the distance of the center of mass of the tensile force-transmitting structure, measured in the horizontal direction when looking perpendicularly to a connecting surface of the load-bearing structural part, is advantageously the same as both centers of mass of the compressive force-transmitting structures.

If exactly two tensile force-transmitting structures and exactly two compressive-force-transmitting structures are provided, it is in particular provided that the two tensile-force-transmitting structures and the two associated compressive-force-transmitting structures each have a distance from one another measured in the horizontal direction. The distance between the force-transmitting structures arranged in the second support structures is in particular greater than the distance between the force-transmitting structures arranged at least partially in the first support structure. When the first support structure is designed as a floor plate, the force-transmitting structures arranged in the second support structures are the tensile force-transmitting structures, and the force-transmitting structures arranged in the first support structure are the compressive force-transmitting structures. If the first support structure is designed as a ceiling plate, the force-transmitting structures arranged at least partially in the first support structure are in particular the tensile force-transmitting structures, and the force-transmitting structures arranged in the second support structures are in particular the compressive force-transmitting structures. In the first support structure, the force-transmitting structures have a smaller distance from one another, measured horizontally and vertically when looking at the connection surface, than in the second support structures.

In particular, the centers of mass of the force-transmitting structures arranged in the second support structures are at a greater distance than the centers of mass of the force-transmitting structures arranged in the first support structure. The distance is measured in the horizontal direction when looking perpendicular to the respective connection surface.

Each tensile force-transmitting structure and each compressive force-transmitting structure of the connection arrangement is advantageously designed as a separate unit. During the construction of the structure, the separate units can be positioned in a formwork independently of other structures that transmit tensile and compressive forces. The separate units can be connected to one another in the formwork using further reinforcement of the structure and fastening elements for the reinforcement. The reinforcement of the structure, in particular the reinforcement of the load-bearing part of the structure and/or the reinforcement of the cantilevered structure, is in particular not welded to the connection arrangement, in particular not to the force-transmitting structures of the connection arrangement. If the concrete of the cantilevered structure is fiber-reinforced concrete, no additional reinforcement is provided in the load-bearing structure. In this case, the force-transmitting structures in the cantilevered structure are connected in particular exclusively via the concrete of the cantilevered structure.

A separating joint is advantageously formed between the load-bearing structural part and the cantilevered structure, which is bridged by the tensile force-transmitting structures and by the compressive-force-transmitting structures.

Advantageously, at least one tensile force-transmitting structure has a distance of at least 20 cm, measured in the vertical direction, from a compressive force-transmitting structure in the parting line. Due to the distance between the tensile force-transmitting structure and the associated compressive force-transmitting structure, a large distance and thus a large lever arm is achieved between the force-transmitting structures. The second supporting structure of the cantilevered structure also contributes in particular to the power transmission. In particular, the tensile force-transmitting structures and the compressive force-transmitting structures in the cantilevered structure are connected to one another exclusively via the material of the cantilevered structure, namely concrete and, if necessary, additionally via reinforcing elements of the cantilevered structure.

The connection arrangement includes, in particular, insulating material arranged in the joint. In particular, at least one insulating body arranged in the joint is provided. The insulating material can include several insulating bodies in the joint.

In particular, at least one connecting device is arranged at least partially, in particular completely, outside the parting line. In particular, all connecting devices of tensile force-transmitting structures, in particular all connecting devices, are arranged at least partially, in particular completely, outside the parting line.

A simple structure results when the compressive force-transmitting structure includes a contact surface on which the cantilevered structure is supported in the horizontal direction. The compressive force-transmitting structure includes, in particular, a support surface on which the cantilevered structure is supported in the vertical direction.

If the cantilevered structure is merely supported on the compressive force-transmitting structure, a simple subsequent connection of the cantilevered structure to the load-bearing part of the building is possible. Securing in the vertical direction takes place in particular via the at least one structure that transmits tensile force.

In particular, a connecting device of a tensile force-transmitting structure comprises at least one screw connection.

The parting joint advantageously has a vertically extending imaginary boundary surface that touches the concrete of the cantilevered structure and does not cut it. The support surface is in particular arranged completely on the side of the boundary surface that is remote from the load-bearing part of the building. If the contact surface and the support surface are arranged on the cantilevered building and are arranged comparatively far away from the supporting building structure, a favorable introduction of force results. It can be provided that the contact surface is arranged completely on the side of the boundary surface that is remote from the load-bearing part of the building. A simple structure is achieved if the contact surface and the support surface are formed on a support angle.

The compressive force transmitting structure advantageously comprises at least one transverse force element. The shear force element can be, for example, a shear force bar. The at least one transverse force element is in particular fixed directly to the support bracket. The support bracket can include side cheeks on which a separate transverse force element, for example a transverse force bar, is arranged, for example welded. Alternatively, it can be provided that a side cheek of the support bracket is formed in one piece with a transverse force element. For this purpose, a side cheek of the support bracket can be designed to be extended in the corresponding direction. The support bracket can be designed with a section of the transverse force element as a bent sheet metal part. A different design can also be advantageous.

A compact arrangement results when at least a first section of a tensile force-transmitting structure comprises at least one bent tension rod. The tension rod runs in particular completely in a wall of the load-bearing part of the building. At least two tension rods are advantageously provided, which are bent in opposite directions. The two tension rods can, for example, run vertically or horizontally in the wall.

The tensile force-transmitting structure has in particular at least one tension rod embedded in the cantilevered structure. In particular, several tension rods are embedded in the cantilevered structure, which run vertically one above the other. In particular, the at least one tension rod embedded in the cantilevered structure, in particular all of the tension rods embedded in the cantilevered structure, runs horizontally.

• 1 eine schematische, perspektivische ausschnittsweise Darstellung eines Bauwerks, wobei auch in Beton eingebettete, nicht sichtbare Elemente mit durchgezogener Linie dargestellt sind,
• 2 eine Seitenansicht des Bauwerks aus 1 in schematischer Darstellung,
• 3 eine Draufsicht auf das Bauwerk aus 1 in schematischer Darstellung in Richtung des Pfeils III in 2,
• 4 eine schematische Seitenansicht des Bauwerks aus 1 in Richtung des Pfeils IV in 2,
• 5 eine schematische, ausschnittsweise perspektivische Darstellung des Ausschnitts V aus 1,
• 6 den in 5 dargestellten Teil der Anschlussanordnung in perspektivischer Darstellung,
• 7 eine Seitenansicht der Anordnung aus 6,
• 8 eine Seitenansicht der Anordnung in Richtung des Pfeils VIII in 7,
• 9 eine Seitenansicht der Anordnung in Richtung des Pfeils IX in 7,
• 10 eine Seitenansicht eines alternativen Ausführungsbeispiels eines Bauwerks in einer ausschnittsweisen schematischen Darstellung,
• 11 eine schematische Draufsicht des Ausführungsbeispiels aus 10 in Richtung des Pfeils XI in 10,
• 12 und 13 schematische Darstellungen von alternativen Verbindungseinrichtungen von zugkraftübertragenden Strukturen, wobei auch in Beton eingebettete, nicht sichtbare Elemente mit durchgezogener Linie dargestellt sind,
• 14 bis 16 schematische ausschnittsweise Seitenansichten von weiteren Ausführungsbeispielen von Bauwerken.

Exemplary embodiments of the invention are explained below with reference to the drawing. Show it:

• 1 a schematic, perspective, partial representation of a building, in which invisible elements embedded in concrete are also shown with a solid line,
• 2 a side view of the building 1 in a schematic representation,
• 3 a top view of the building 1 in a schematic representation in the direction of arrow III in 2 ,
• 4 a schematic side view of the building 1 in the direction of arrow IV in 2 ,
• 5 a schematic, partial perspective representation of section V 1 ,
• 6 the in 5 shown part of the connection arrangement in a perspective view,
• 7 a side view of the arrangement 6 ,
• 8th a side view of the arrangement in the direction of arrow VIII in 7 ,
• 9 a side view of the arrangement in the direction of arrow IX in 7 ,
• 10 a side view of an alternative exemplary embodiment of a building in a partial schematic representation,
• 11 a schematic top view of the exemplary embodiment 10 in the direction of arrow XI in 10 ,
• 12 and 13 schematic representations of alternative connecting devices of tensile force-transmitting structures, with invisible elements embedded in concrete also being shown with a solid line,
• 14 until 16 Schematic partial side views of further exemplary embodiments of buildings.

1 shows schematically a section of a building 1. The building 1 can be, for example, a residential or office building or the like. The building 1 can also be any other type of building. The building 1 comprises a load-bearing structural part 2. In the exemplary embodiment, the load-bearing structural part 2 comprises a floor ceiling 21, shown in detail, and a wall 22, shown in part. The wall 22 in particular has a door opening 28. A cantilevered structure 3 is held on the supporting structural part 2. The cantilevered structure 3 is fixed to the supporting structural part 2 via a connection arrangement 7. The connection arrangement 7 is designed such that the cantilevered structure 3 can be fixed to the load-bearing structural part 2 after the load-bearing structural part 2 and the cantilevered structure 3 have been completed, for example made of concrete. The cantilevered structure 3 is a prefabricated concrete part. In particular, the cantilevered structure 3 was not manufactured on the construction site, but in a precast factory and was transported to the construction site as a whole.

In the figures, the elements of the connection arrangement 7 are shown with a solid line, even if the structures are embedded in the concrete of the load-bearing structural part 2 or the cantilevered structure 3 in order to make them more visible. When installed, the elements of the connection arrangement 7 are advantageously not or only slightly visible.

The cantilevered structure 3 comprises at least a first support structure 4 and at least a second support structure 5a, 5b. In the exemplary embodiment, two second support structures 5a and 5b are provided. The first support structure 4 extends in particular essentially horizontally. The first support structure 4 is a floor plate in the exemplary embodiment. The first support structure 4 can also be a ceiling panel, for example.

At least one cheek is provided on the first support structure 4. In the exemplary embodiment, second support structures 5a, 5b designed as ascending, i.e. upwardly directed cheeks are arranged on both long sides of the support structure 4. This results in an approximately U-shaped cross section of the cantilevered structure 3. If the first support structure 4 is a floor plate, the second support structures 5a and 5b extend upwards, in particular approximately in the vertical direction. If the first support structure 4 is a ceiling panel, the at least one second support structure 5a, 5b extends downwards from the ceiling panel, in particular approximately in the vertical direction. Each second support structure 5a, 5b can be arranged on a long side of the first support structure 4, as in the exemplary embodiment. However, an arrangement in another region, for example in a central region of the first support structure 4, can also be provided.

The second support structure 5a, 5b advantageously encloses an angle of less than 60°, in particular of at most 45°, preferably at most 30°, with the vertical direction when viewed perpendicularly to a connection surface 32 of the load-bearing structural part 2. In the exemplary embodiment, both second support structures 5a and 5b run in the vertical direction. The connection surface 32 is in particular the surface of the load-bearing structural part 2 to which the cantilevered structure 3 is fixed. For each second support structure 5a, 5b, the area of the connection surface 32 is considered, to which the force-transmitting structures holding this second support structure 5a, 5b are connected, as will be explained in more detail below.

The connection arrangement 7 comprises at least one compressive force transmitting structure 9 and at least one tensile force transmitting structure 8. In the exemplary embodiment, two tensile force transmitting structures 8 and two compressive force transmitting structures 9 are provided, which together form the connection arrangement 7.

The tensile force-transmitting structures 8 of the connection arrangement 7 are designed to transmit the tensile forces occurring between the cantilevered structure 3 and the load-bearing structural part 2. The compressive force-transmitting structures 9 of the connection arrangement 7 are designed to transmit the compressive forces occurring between the cantilevered structure 3 and the load-bearing structural part 2. Advantageously, in addition to the tensile force-transmitting structures 8 and the compressive-force-transmitting structures 9, no further structures for transmitting tensile forces and compressive forces between the cantilevered structure 3 and the load-bearing structural part 2 are provided. The force-transmitting structures 8, 9 of the connection arrangement 7 can also contain additional forces transmitted. In the exemplary embodiment, the compressive force-transmitting structures 9 are also designed to transmit the shear forces occurring between the cantilevered structure 3 and the supporting structural part 2.

The tensile force transmitting structures 8 each include a first section 10 and a second section 11, each of which is connected to one another via a connecting device 14. The connecting device 14 is designed to connect the sections 10 and 11 to one another after the load-bearing structural part 2 and the cantilevered structure 3 have been manufactured. Because the cantilevered structure 3 is fixed to the load-bearing structural part 2 in the finished state, crane times, which can be considerable when producing the cantilevered structure 3 from in-situ concrete, can be reduced, and the structure 1 can be constructed quickly.

The connecting devices 14 are arranged in particular outside the parting line 6. In the exemplary embodiment, the connecting devices 14 are arranged in the cantilevered structure 3. Arranging at least one connecting device 14 in the load-bearing structural part 2 can also be advantageous. This is described schematically in the following 12 and 13 shown.

The first sections 10 of the tensile force transmitting structures 8 are embedded in the load-bearing part of the building 2. In the exemplary embodiment, the first sections 10 comprise tension rods 17 which run vertically in the wall 22. In the exemplary embodiment, two tension rods 17 are provided, one of which extends upwards and one downwards in the wall 22.

The second sections 11 are embedded in the second support structures 5a, 5b. In the exemplary embodiment, the second sections 11 comprise tension rods 18. In the exemplary embodiment, three tension rods 18 are provided for each second section 11. A different number of tension rods or a different design of the first sections 10 and/or the second sections 11 can also be provided.

In the exemplary embodiment, a separating joint 6 is formed between the load-bearing structural part 2 and the cantilevered structural body 3, which is bridged by the tensile force-transmitting structures 8 and by the compressive force-transmitting structures 9. In the exemplary embodiment, several insulating bodies 16 are arranged in the parting line 6. Alternatively, other insulating elements can also be arranged in the parting line 6.

The compressive force transmitting structures 9 each include a first section 12, which extends into the supporting structural part 2, and a second section 13, which extends into the first supporting structure 4 of the cantilevered building body 3. The first section 12 and the second section 13 are connected to one another via a connecting device 15. The connecting device 15 is also designed in such a way that the cantilevered structure 3 can be fixed to the supporting structural part 2 after it has been manufactured in the precast factory. The first sections 10, 12 and the second sections 11, 13 of the force-transmitting structures 8 and 9 are already embedded in the load-bearing structural part 2 and the cantilevered structure 3.

The connecting devices 15 are in particular arranged outside the parting line 6. In the exemplary embodiment, the connecting devices 15 are each arranged in a recess 37 in the cantilevered structure 3. However, an arrangement of at least one connecting device 15 in the load-bearing structural part 2 can also be advantageous.

By designing the cantilevered structure 3 with at least one first support structure 4 and at least one second support structure 5a, 5b, which are manufactured in one piece as a finished part, both the first support structure 4 and the at least one second support structure 5a, 5b can participate in the transmission of the to transmitting forces participate. As a result, the thickness of the cantilevered structure 3 can be significantly reduced. The first support structure 4 has a thickness a. The thickness a is constant in the exemplary embodiment. If the first support structure 4 has different thicknesses in different areas, the thickness a considered here is the smallest thickness of the first support structure 4. In the exemplary embodiment, the second support structures 5a and 5b have a thickness b, which in the exemplary embodiment is in both support structures 5a, 5b is equal to. In the exemplary embodiment, the thickness b of every second support structure 5a, 5b is constant. If the thicknesses of the support structures 5a and 5b are different or not constant, the smallest thickness b of the respective support structure 5a, 5b is decisive.

It is envisaged that the thickness a is at most 150 mm, in particular at most 130 mm, in particular at most 120 mm, advantageously at most 100 mm. The smallest thickness a is advantageously at least 50 mm, in particular at least 80 mm. The smallest thickness b of the at least one second support structure 5a, 5b is advantageously at most 150 mm, in particular at most 130 mm, in particular at most 120 mm, advantageously at most 100 mm. The smallest thickness b is advantageously at least 50 mm, in particular at least 80 mm.

2 shows the arrangement of the force-transmitting structures 8 and 9. The second support structures 5a and 5b have a distance d from one another, measured in the horizontal direction. The two tensile force transmitting structures 8 have a distance e from each other measured in the horizontal direction. In the exemplary embodiment, the distance e corresponds to the distance d between the second support structures 5a and 5b. However, the distance e can also be larger than the distance d. The distances d and e are measured in the viewing direction perpendicular to the connection surface 32.

The first support structure 4 has a width n. The width n is measured in the horizontal direction when looking perpendicular to the connection surface 32. The second support structures 5a and 5b rise from the first support structure 4. The first support structure 4 extends from one outer edge to the other outer edge of the floor slab or ceiling slab of the cantilevered structure 2.

The width n is in particular at least 1.0 m, in particular at least 1.5 m, in particular at least 2.5 m to 5.0 m. The width n is in particular at most 10 m.

The tensile force transmitting structures 8 each have a center of mass S1. At the in 2 In the view shown when looking perpendicular to the connection surface 32, the centers of mass S1 of the two tensile force-transmitting structures 8 have a distance g measured in the horizontal direction. The distance g is in particular slightly larger than the distance d of the second support structures 5a and 5b.

The compressive force transmitting structures 9 have a distance f. The distance f is smaller than the distance e of the tensile force-transmitting structures 8. The compressive force-transmitting structures 9 each have a center of mass S2. The centers of mass S2 of the two compressive force transmitting structures 9 point in the figure 2 shown view perpendicular to the connection surface 33 a distance h measured in the horizontal direction. The distance h between the centers of mass S2 is smaller in the exemplary embodiment than the distance g between the centers of mass S1. The distance h is in particular smaller than the distances d and/or e.

As the 2 and 3 show, the centers of mass S1 and S2 are at a distance c from each other. The distance c is in particular at least 5 cm, in particular at least 15 cm. The distance c is advantageously less than 2.0 m. The distance c is in particular at least 10 cm and in particular less than 1.0 m. The distance c is measured when looking perpendicular to the connection surface 32 and in particular in the horizontal direction. The distance c is in particular at most a third of the width n of the first support structure 4. The distance c is the distance from the center of mass S1 of a tensile force-transmitting structure 8 to the center of mass S2 of an associated compressive force-transmitting structure 9.

The compressive force-transmitting structure 9 assigned to a tensile force-transmitting structure 8 is the compressive-force-transmitting structure 9, whose center of mass S2 has the smallest distance c from the center of mass S1 of the tensile-force-transmitting structure 8, measured in the horizontal direction when viewed perpendicularly to the connecting surface 32.

Advantageously, each compressive force transmitting structure 9 is assigned to exactly one tensile force transmitting structure 8. The tensile force transmitting structures 8 and the compressive force transmitting structures 9 are in particular arranged in pairs. Adjacent pairs of force-transmitting structures 8, 9 are advantageously at a distance from one another. The distance between adjacent pairs of force-transmitting structures 8, 9 corresponds in particular to the distance f of the compressive force-transmitting structures 9.

How 3 and 4 show, the compressive force transmitting structures 9 each include two transverse force elements 23. In the exemplary embodiment, the transverse force elements 23 are designed as transverse force rods. The distance between the transverse force elements 23 of the two compressive force transmitting structures 9, which are arranged close to one another, corresponds to the distance f of the compressive force transmitting structures 9.

The elements of the connecting devices 14 and 15 are in 4 presented in detail. The individual elements of the connecting devices 14 and 15 are also in 3 to make their lateral position clear.

The connecting device 14 comprises the at least one tension rod 17, which is embedded in the supporting structural part 2, the at least one tension rod 18, which is embedded in the cantilevered structure 2, and the connecting device 14. In the exemplary embodiment, the connecting device 14 comprises a connecting plate 26, on which the Tension rods 18 embedded in the cantilevered structure 3 are fixed, as well as fastening nuts 27 which are screwed onto ends of the tension rods 17 inserted through the connecting plate 26.

The tension rods 18 are arranged one above the other in particular in the vertical direction. The tension rods 18 run in particular parallel to one another. In particular, the tension rods 18 run in a horizontal direction.

The tension rods 18 have a diameter u, like 4 shows. In the exemplary embodiment, the tension rods 17 have a diameter u which corresponds to the diameter of the tension rods 18. Different diameters u of the tension rods 17 and 18 can also be provided.

The tension rods 18 embedded in the cantilevered structure 3 have a length v. The length v with which the tension rods 18 are embedded in the cantilevered structure 3 corresponds in particular to at least 10 times the diameter u, in particular at least 30 times the diameter u, in particular at most 50 times the diameter u. In particular, the length v corresponds to at least 5 times smallest thickness a of the first support structure 4 and/or at least 5 times the smallest thickness b of the second support structure 5a, 5b ( 3 ).

So that the fastening nuts 27 can be tightened after completion of the cantilevered structure 3, the cantilevered structure 3 has at least one access opening 29. In the exemplary embodiment, in 4 Two access openings 29 are shown schematically with a dashed line. The access openings 29 are not shown in the other figures. After the cantilevered structure 3 has been fixed, the access openings 29 can be covered, for example, with cover caps. The access openings 29 can be provided on each side of a second support structure 5a or 5b, i.e. in particular in the case of two second support structures 5a and 5b on the sides of the second support structures 5a and 5b that face one another and/or those that face away from one another. It can be provided that the access openings 29 of a second support structure 5a or 5b open to the same side or to different sides.

In the exemplary embodiment, two tension rods 17 and three tension rods 18 are provided. A different number of tension rods 17 and 18 can also be advantageous. The tension rods 18 are in particular straight and each extend over slightly more than half of a depth t of the cantilevered structure 3. The depth t is measured perpendicular to the connection surface 32 and in particular in the horizontal direction. The depth t is measured in particular parallel to the first support structure 4 and parallel to the second support structures 5a, 5b.

The depth t is in particular at least 1.0 m, in particular at least 1.5 m, in particular at least 2.0 m. In particular, the depth t is not more than 3.0 m. The depth t is in particular at least 50 times the diameter u Tension rods 17 and/or the tension rods 18.

How 4 shows, both tension rods 17 extend in the wall 22. The upper one of the tension rods 17 is bent upwards and the lower one of the tension rods 17 is bent downwards. The tension rods 17 run vertically in the wall 22 over a large part of their length. The tension rods 17 can also be bent in a lateral direction.

The compressive force transmitting structure 9 includes compression rods 20 embedded in the cantilevered structure 3. In the exemplary embodiment, two compression rods 20 are provided. The compressive force transmitting structure 9 also includes two transverse force elements 23. To transmit the compressive forces into the load-bearing structural part 2, pressure plates 19 are provided, which are fixed to a support bracket 24. How 3 shows, two pressure plates 19 are fixed to each support bracket 24. The support angle 24 is part of the connecting device 15.

How 6 shows, two pressure rods 20 are provided, which are fixed to a support bracket 25. The compression rods 20 and possibly also the support angle 25 can be embedded in the cantilevered structure 3. The support angle 25 rests on the support angle 24, in both the horizontal and vertical directions. A different number of pressure rods 20 can also be advantageous.

How 4 shows, the tensile force-transmitting structure 8 and the compressive force-transmitting structure 9 in the parting line 6 have a distance i from one another, measured in the vertical direction. The tensile force-transmitting structure 8 traverses the parting line 6 above the compressive force-transmitting structure 9. The distance i is advantageously at least 60 cm and in particular at most 130 cm. In particular, the distance i is from 60 cm to 80 cm. In the exemplary embodiment, the distance i between a tension rod 17 and a transverse force element 23 is measured.

How 4 shows, the parting line 6 has a vertical, imaginary boundary surface 38. The boundary surface 38 touches the concrete of the cantilevered structure 3 and does not cut it. How 4 shows, the support angle 24 extends largely, in particular completely, on the side of the boundary surface 38, on which the cantilevered structure 3 also extends. This is the side of the boundary surface 38 that is remote from the load-bearing structural part 2. It can be provided that the support angle 24 partially projects beyond the boundary surface 38 into the parting line 6.

In 4 the viewing direction 33 is drawn perpendicular to the connection surface 32.

The design of the tensile force transmitting structure 8 and the compressive force transmitting structure 9 is also in the 5 and 6 shown in detail. How 6 shows, the support angle 24 includes two side cheeks 36. A transverse force element 23 is fixed to each side cheek 36.

Also 7 shows the distance c between the centers of mass S1 and S2 in the horizontal direction when looking vertically at the connection surface 32.

How 8th shows, the centers of gravity S1 and S2 can also have a distance k in the direction perpendicular to the connection surface 32. In the exemplary embodiment, the centers of gravity S1 and S2 are at a distance m from one another in the vertical direction. The distance measured in the vertical direction from the first center of mass S1 and the second center of mass S2 is in particular at least 25 cm, in particular at least 40 cm, in particular at least 50 cm. In particular, the distance m measured in the vertical direction between the centers of mass S1 and S2 is at most 250 cm.

How 8th shows, the insulating body 16 has a storage box 39 in the exemplary embodiment. Insulating material, for example mineral wool, is arranged in the storage box 39. In the exemplary embodiment, the support angle 24 rests on the storage box 39. The support angle 24 can partially protrude beyond the boundary surface 38 into the parting line 6, in particular with the vertically arranged leg, which forms the contact surface 34.

In 8th The fastening nuts 27 are also shown, with which the tension rods 17 are fixed to the connecting plate 26.

How 9 shows, the support angle 24 has a support surface 35 and a contact surface 34. The support angle 25 is supported in the horizontal direction on the contact surface 34. Compressive forces are transmitted via the contact surface 34. The support angle 25 rests on the support surface 35. Transverse forces are transmitted via the support surface 35. In 9 The two side cheeks 36 are also shown, on each of which a transverse force element 23 is fixed. The transverse force element 23 has an oblique section which is fixed to the side cheeks 36, for example welded to it. In an alternative design, it can be provided that a transverse force element 23 or a section of a transverse force element 23 is formed in one piece with the support angle 24.

The 10 and 11 show an alternative exemplary embodiment in which the compressive force transmitting structures 9 have a smaller distance f than in the previous exemplary embodiment. The distance f is significantly smaller than the distances e of the tensile force transmitting structures 8 and d of the second support structures 5a, 5b. The distance c between the centers of gravity S1 and S2, which is measured in the horizontal direction when looking vertically at the connection surface 32, is significantly larger than in the previous exemplary embodiment. The design of the cantilevered structural part 3 otherwise corresponds in particular to that of the previous exemplary embodiment. To avoid repetition, this design is no longer described in detail.

The 12 and 13 show alternative designs for the design of the connecting device 14. In the exemplary embodiment 12 are two tension rods 17, which are embedded in a load-bearing structural part 2, fixed to a connecting plate 26. A tension rod 18, which is embedded in a cantilevered structure 3, protrudes through an opening, not shown, in the connecting plate 26 and is fixed to the connecting plate 26 with a fastening nut 27. The load-bearing structural part 2 has an access opening 29 through which the fastening nut 27 is accessible.

In the exemplary embodiment according to 17 the anchoring elements in the load-bearing structural part 2 are not designed as tension rods 17, in which the anchoring is achieved over the length of the rod, but as tension rods 30, each of which carries an anchor head 31 at its end for anchoring. The tension rods 30 are fixed to the connecting plate 26 and two tension rods 18, which are embedded in the cantilevered structure 3, are fixed to the connecting plate 26 via fastening nuts 27.

A different design of the connecting devices 14 and 15 can also be provided.

The first support structure 4 and the at least one second support structure 5a, 5b are formed in one piece. This means that the support structures 4, 5a and 5b are manufactured as a common part in a common formwork as a prefabricated concrete part and cast together.

The tensile force-transmitting structures 8 and the compressive force-transmitting structures 9 are advantageously designed in all exemplary embodiments as separate units that can be arranged independently of one another in a formwork for producing the load-bearing structural part 2 and the cantilevered structural body 3. This allows the distances e and f as well as the distance i to be set individually the installation conditions and the forces to be transmitted must be coordinated.

Advantageously, the center of mass S2 of a compressive force transmitting structure 9 is not arranged centrally in the horizontal direction between the centers of mass S1 of two tensile force transmitting structures 8. Advantageously, each tensile force-transmitting structure 8 is assigned exactly one compressive force-transmitting structure 9.

The exemplary embodiments according to the 14 until 16 show embodiments in which the first support structure 4 forms a ceiling panel and the second support structures 5a and 5b form cheeks directed downwards from the ceiling panel. In these exemplary embodiments, the cantilevered structure 3 each forms a canopy on a door opening 28.

The second sections 11 of the tensile force transmitting structures 8 are partially embedded in the first support structure 4. In the exemplary embodiment according to 14 a tension rod 18 of a tensile force-transmitting structure 8 is embedded in the first support structure 4 and another two tension rods 18 are embedded in the second support structure 5a or in the second support structure 5b. The tension rods 18 are arranged one above the other and run parallel to one another and in particular in the same vertical plane.

The second support structures 5a, 5b have a smallest width b. The second sections 13 of the compressive force transmitting structures 9 are embedded in a region of the second support structure 5a, 5b, which has an increased width b'. The width b' corresponds in particular to at least one width w of the support surface 35 of the support angle 24.

The first support structure 4 has a smallest thickness a, which is constant in the exemplary embodiment.

The first force-transmitting structures 8 have a distance e from one another, which is smaller than a distance f of the pressure-force-transmitting structures 9. Accordingly, the distance between the force-transmitting structures embedded at least partially in the first support structure 4 is smaller than the distance between the force-transmitting structures embedded in the second day structures 5a, 5b. The centers of mass of the force-transmitting structures 8 and 9 are at a distance c from one another. The distance c is in the exemplary embodiment 14 comparatively small.

15 shows an exemplary embodiment in which the first sections 11 of the tensile force-transmitting structures 8 are completely embedded in the first support structure. The tension rods 18 run next to each other.

The first support structure 4 is in the exemplary embodiment 4 executed with an increased smallest thickness a. The smallest thickness a is greater than the smallest thickness b of the second support structures 5a and 5b. The smallest thickness a can, for example, correspond approximately to the increased width b' of the second support structures 5a or 5b.

The first force-transmitting structures 8 have a distance e from one another, which is smaller than a distance f of the pressure-force-transmitting structures 9. The centers of mass of the force-transmitting structures 8 and 9 are at a distance c from one another.

In the exemplary embodiment according to 16 the second support structures 5a and 5b are inclined to the vertical. Every second support structure 5a, 5b forms an angle α with the vertical direction when looking perpendicular to the connection surface 32 of the supporting structural part 2. The angle α is in particular less than 60°, in particular at most 45°, preferably at most 30°. Different angles α for the two support structures 5a and 5b can be advantageous. In the exemplary embodiment, the support structures 5a and 5b are inclined in opposite directions.

The centers of mass S1 and S2 of assigned force-transmitting structures 8 and 9 are shown in the exemplary embodiment 16 each at a distance c from each other. The distance c is increased compared to the previous exemplary embodiment due to the inclination of the second support structures 5a and 5b to the vertical.

The tensile force transmitting structures 8 are in the exemplary embodiments according to 15 and 16 arranged rotated compared to the previous exemplary embodiments. The tension rods 18 run next to each other in a horizontally arranged plane. All tension rods 18 are arranged in the first support structure 4.

When the first support structure 4 is designed as a ceiling plate, the distances and thicknesses advantageously correspond to the sizes specified for the versions as a floor plate. The design of the connection device 7 advantageously corresponds to features of the design of the previous exemplary embodiments that are not described in detail in individual figures, to which reference is made to avoid repetition.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2002121818 A [0002]

Claims (18)

Building with a load-bearing part of the building (2) and at least one cantilevered structure (3) fixed to the part of the building (2), the building (1) having a connection arrangement (7) for subsequently connecting the cantilevered structure (3) to the load-bearing part of the building ( 2), wherein the connection arrangement (7) has at least one tensile force-transmitting structure (8) which is designed to transmit tensile forces occurring between the cantilevered structure (3) and the supporting structural part (2), and wherein the connection arrangement (7) has at least a compressive force-transmitting structure (9) which is designed to transmit compressive forces occurring between the cantilevered structure (3) and the supporting structural part (2), the tensile-force-transmitting structure (8) and the at least one compressive-force-transmitting structure (9) each having a first , section (10, 12) connected to the load-bearing structural part (2) in a force-transmitting manner and each having a second section (11, 13) running in the cantilevered structure (3), the first sections (10) and the second sections (11) the tensile force-transmitting structure (8) are connected to one another via at least one first connecting device (14), the first sections (12) and the second sections (13) of the compressive force-transmitting structure (9) being connected to one another via at least one second connecting device (15), wherein the connecting devices (14, 15) are designed to connect the cantilevered structure (3) to the supporting structural part (2) after connecting the first sections (10, 12) to the supporting structural part (2) and after embedding the second sections (11, 13) into the cantilevered structure (3), characterized in that the cantilevered structure (3) has at least one first support structure (4) and at least one second support structure (5a, 5b) formed in one piece with the first support structure (4). ) has that the cantilevered structure (3) is a prefabricated part made of concrete, that the at least one first support structure (4) of the cantilevered structure (3) has a smallest thickness (a) of at most 150 mm, and - that the first support structure ( 4) forms a base plate and the at least one second support structure (5a, 5b) has a cheek rising from the base plate, the second section (11) of the at least one tensile force transmitting structure (8) being embedded in the at least one second support structure (5a, 5b). is, and wherein the second section (13) of the at least one compressive force transmitting structure (9) is embedded in the at least one first support structure (4) or - that the first support structure (4) forms a ceiling plate and the at least one second support structure (5a, 5b) a cheek directed downwards from the ceiling panel, wherein the second section (11) of the at least one tensile force transmitting structure (8) is at least partially embedded in the at least one first support structure (4), and wherein the second section (13) of the at least a compressive force-transmitting structure (9) is embedded in the at least one second support structure (5a, 5b). building Claim 1 , characterized in that the smallest thickness (a) is at most 130 mm, in particular at most 100 mm. building Claim 1 or 2 , characterized in that the smallest thickness (a) is at least 50 mm, in particular at least 80 mm. Building based on one of the Claims 1 until 3 , characterized in that the at least one second support structure (5a, 5b) of the cantilevered structure (3) has a smallest thickness (b) of at most 130 mm, in particular at most 120 mm, advantageously at most 100 mm and that the smallest thickness ( b) the at least one second support structure is in particular at least 80 mm. Building based on one of the Claims 1 until 4 , characterized in that the at least one tensile force-transmitting structure (8) has a first center of mass (S 1), that the at least one assigned compressive force-transmitting structure (9) has a second center of mass (S2) and that, when viewed in the direction perpendicular to a connection surface (32 ) of the load-bearing part of the building (2) the distance (c) measured in the horizontal direction from the first center of mass (S1) and the second center of mass (S2) is at least 5 cm, whereby the connection surface (32) is the area of the load-bearing part of the building (2) through which the tensile and compressive force transmitting structures (8, 9) protrude. Building based on one of the Claims 1 until 5 , characterized in that the at least one tensile force-transmitting structure (8) has a first center of mass (S 1), that the at least one associated compressive force-transmitting structure (9) has a second center of mass (S2) and that a distance (m) measured in the vertical direction of the first center of mass (S 1) and second center of mass (S2) is at least 25 cm, in particular at least 40 cm. Building based on one of the Claims 1 until 6 , characterized in that the building (1) has at least two tensile force transmitting structures (8), in particular exactly two tensile force transmitting structures Structures (8), and at least two compressive force transmitting structures (9), in particular exactly two compressive force transmitting structures (9). building Claim 7 , characterized in that the two tensile force-transmitting structures (8) and the two associated compressive force-transmitting structures (9) each have a distance (e, f) from one another measured in the horizontal direction, the distance (e) in the second support structures (5a, 5b) arranged force-transmitting structures (8, 9) is greater than the distance (f) of the force-transmitting structures (9, 8) arranged at least partially in the first support structure (4). Building based on one of the Claims 1 until 8th , characterized in that each tensile force-transmitting structure (8) and each compressive force-transmitting structure (9) of the connection arrangement (7) is each designed as a separate unit, which is independent of other tensile force-transmitting structures (8) and others during the production of the structure (1). compressive force transmitting structures (9) can be positioned in a formwork. Building based on one of the Claims 1 until 9 , characterized in that a separating joint (6) is formed between the load-bearing structural part (2) and the cantilevered structure (3), which is bridged by the tensile force-transmitting structures (8) and by the compressive-force-transmitting structures (9). building Claim 10 , characterized in that the connection arrangement (7) comprises insulating material arranged in the parting joint (6), in particular at least one insulating body (16) arranged in the parting joint (6). building Claim 10 or 11 , characterized in that at least one connecting device (14, 15), in particular all connecting devices (14, 15) are arranged at least partially outside the parting line (6). Building based on one of the Claims 1 until 12 , characterized in that the compressive force-transmitting structure (9) comprises a contact surface (34) on which the cantilevered structure (3) is supported in the horizontal direction. Building based on one of the Claims 1 until 13 , characterized in that the compressive force-transmitting structure (9) comprises a support surface (35) on which the cantilevered structure (3) is supported in the vertical direction. Building according to the Claims 9 , 13 and 14 , characterized in that the parting line (6) has a vertically extending imaginary boundary surface (38) which touches the concrete of the cantilevered structure (3) and does not cut it, and that the support surface (35) rests completely on the supporting structural part (2). remote side of the boundary surface (38) are arranged. Building according to the Claims 13 and 14 , characterized in that the contact surface (34) and the support surface (35) are formed on a support angle (24). building Claim 16 , characterized in that the compressive force-transmitting structure (9) comprises at least one transverse force element (23) which is fixed directly to the support bracket (24). Building based on one of the Claims 1 until 17 , characterized in that at least a first section (10) of a tensile force-transmitting structure (8) comprises at least one bent tension rod (17), which in particular runs completely in a wall (22) of the load-bearing structural part (2).

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