DE102008002899A1 - Component for connecting external building part e.g. wall, and building, has stainless steel support for force-fit connection of external building part, where support is designed as double-T-stainless steel support - Google Patents

Abstract

The component has a stainless steel support (6) for force-fit connection of an external building part. An additional pressurizing medium is provided for receiving pressure forces. The support is designed as a double-T-stainless steel support. The stainless steel support permeates a heat-damming insulation body with arbitrary thickness. Two recesses are formed in a bar (14) of the support, within an area of the insulation body. A reinforcement is provided in the stainless steel support. The support has a tapering cross section.

Description

Technical area

The Invention relates to a component for connecting two components, in particular for connecting a building and an external component.

State of the art

Various elements for connecting projecting components to buildings are known from the prior art. The DE 3 005 571 B1 discloses, for example, a thermally-isolated element having an elongated, cuboid insulating body of thermally insulating material. The insulating body is penetrated by elongated, metal reinforcing elements which extend substantially transversely to the insulating body and which are designed to absorb tensile forces. In addition to these reinforcing elements, the cantilever connection element has transverse force bars made of reinforcing steel and steel construction parts which act as pressure elements.

The known thermally separated connections for balconies all have a basically very similar structure, which in 1 is shown schematically. The Kragplattenanschlusselement of the prior art, shown in vertical section, for connecting a balcony 3 to a ceiling tile 4 is used, has tension rods 2 for absorbing the tensile forces, pressure elements 8th for absorbing the compressive forces and shear force rods 5 for absorbing the transverse forces that occur. These means for absorbing the occurring forces prevail, usually a cuboid insulating body 1 , which ensures the thermal separation of cantilever and building. Thermally isolated connections are offered for example by the companies Schock components (Isokorb ^TM ), Halfen-Deha (balcony connection HIT ^TM ) and Max Frank (Egcobox ^TM ).

The However, known thermally isolated connections have a number of disadvantages. For example, the extent of the Projection of the balcony slab limited, resulting in balcony sizes that do not always meet customer requirements. Often occurs a strong deflection at the balcony end. In addition, the show especially thin used for a large overhang Balcony slabs a strong self-movement with larger ones Wind strengths. Additional external components like walls or supports can as well do not be accommodated on the cantilevered plates as these can not carry such larger loads. In addition, due to the design of the connection elements either the projecting plate or the part of the building to which the cantilevered Plate is connected, usually a ceiling, in Ortbetonverguss getting produced. The thickness of the thermal insulation is also usually set at 8 cm, which is an introduction of the often required thickness of insulation of 10 cm impossible.

It There is therefore a need for components for connecting two Components that at least partially overcome the disadvantages of the prior art.

Presentation of the invention

Here implements the invention. It should be a device for the connection of two components, in particular for connecting a building and an exterior component, provided be, compared to the prior art improved properties having. This object is achieved by the device according to independent claim 1 solved. Further advantageous aspects, details and embodiments The invention results from the dependent claims. the description as well as the drawings.

The Component according to the invention for the connection of two components, in particular for connecting a building and an outer component, has at least one, the non-positive Connection of the external component provided stainless steel support on. From the stainless steel carrier are at least the occurring Traction forces added. Depending on size of the external component can be several stainless steel beams be used for connection to the building.

In the known cantilever connections are occurring Tensile forces are always absorbed and transmitted by tension rods. The minimum distance between the tie rods is while 4 cm. In the device according to the invention The tensile forces are completely removed from the stainless steel beam added. If one uses a stainless steel carrier, the on a running meter of the balcony slab has the same bending moment like a conventional connection, so is the distance the stainless steel carrier from each other in the outer component about 1 m. The reduced number of tensile forces receiving Elements results in a significant saving in production costs and material.

The use of stainless steel as a material for the tensile forces receiving element brings advantages both in terms of durability as well as with respect to the thermal insulation. In the field of insulation namely often occurs corrosion of the metal elements introduced therein. The use of stainless steel virtually eliminates corrosion. Next to it points Stainless steel significantly lower thermal conductivity than black steel, which brings improved thermal insulation.

at a stainless steel carrier is a static one Carrier, which is usually horizontal, rarely oblique, built into the building. A carrier works in contrast to a support under a moment load, that is, the wearer lies on supports and directs Loads into these supports. For a static steel beam So it is a steel profile, in the sense of statics how a carrier works.

According to one preferred embodiment, the stainless steel carrier takes in addition to the tensile forces, at least in part, the other occurring forces and transmits these on the building. These are, for example about compressive forces, shear forces, shear forces and moment loads. It can be the individual occurring Forces can be absorbed in any proportions of the stainless steel carrier. It is therefore conceivable that in addition to the tensile forces, for example the shear forces from the stainless steel beam completely for example, while only a part the pressure forces is absorbed. In this case would have to additional pressure medium to absorb the remaining portion the pressure forces are provided. Especially preferred takes the stainless steel carrier next to the tensile forces also the other occurring forces completely and transfers it to the building.

in the Case that the stainless steel beam all occurring Forces do not need additional pressure and / or transverse force means for absorbing pressure and / or shear forces be provided. In the event that the stainless steel carrier but can not completely absorb the forces mentioned additional pressure medium to absorb pressure forces and / or additional transverse force means for absorbing transverse forces be provided.

The in particular, the present invention comprises components for connection of two components, in particular for connecting a building and an external component, in which exclusively stainless steel support for non-positive connection of the outer component are provided. From the stainless steel beams are in this Case all occurring forces completely recorded and transferred to the building. ever according to size of the outer component are several Stainless steel carrier used for connection to the building, but there are no other means of absorbing tensile, compression or lateral forces provided.

in principle The stainless steel support may have any cross section. By way of example, those known to the expert U-carrier and Z-carrier called. But there are also any asymmetrical Cross sections possible, such as a double T-beam, in which one of the two flanges a larger one Has extension than the other one. In addition, carrier forms conceivable in which the web does not emanate centrally from the flanges, but one or both flanges in two sections of different sizes divided. According to a preferred embodiment The present invention is the stainless steel carrier but about a double-T stainless steel support such as a IPB carrier made of stainless steel.

According to one another preferred embodiment of the present invention If the stainless steel carrier is a welded stainless steel carrier or around a rolled stainless steel beam. Rolled stainless steel beams become industrially according to the respective norm in size stages produced. Rolled stainless steel beams are therefore relatively inexpensive, but have the disadvantage that they are not always accurate can be adapted to the respective construction situation. In contrast, welded stainless steel beams exactly fitting for the respective construction situation manufactured, so with suitable cross section, suitable length, etc. This tailor-made packaging brings on the other hand but higher costs.

According to one another preferred embodiment of the present invention the stainless steel carrier has at least one recess. In the case of a double-T stainless steel carrier, this recess provided in the region of the vertical web of the carrier. A recess brings advantages in terms of thermal insulation, because the heat conduction through the recess is interrupted and thus significantly reduced.

The Location of the recess in the web of the stainless steel carrier determined also the course of forces in this area. Is the exterior part in the ceiling of the building hooked, then the bridge of the stainless steel carrier in the area of the insulation by a starting from the building side from the top diagonally down toward the exterior component side running bridge are formed. Will the exterior part or the stainless steel beam on a building side Support placed, then the bridge of the stainless steel carrier in the area of the insulation by a starting from the building side from below diagonally up towards the exterior component side running bridge are formed.

Basically, the stainless steel beam can be used with and without reinforcement. According to a further preferred embodiment of the present invention, the stainless steel carrier is a stainless steel carrier with at least one reinforcement. The reinforcement is around welded to the stainless steel beam metal parts. Through these metal parts, a dimensionally accurate adaptation to the respective structural situation can be made. For example, rolled stainless steel beams can be precisely adjusted with the help of reinforcements.

According to one another preferred embodiment of the present invention the device additionally has a heat-insulating Insulating body of any thickness, wherein the stainless steel carrier passes through the insulating body. In the known cantilever panel connection elements an insulating body is provided with a thickness of 8 cm. These thermally isolated ports are the cross sections and the location of the bars penetrating the insulation accurately tuned to an insulation with a thickness of 8 cm. It So can not while retaining the tensile, shear force and pressure elements simply a thicker insulation can be installed. Much more need the cross sections and layers of the rods the new insulation thickness will be adjusted, resulting in a new one Stability proof required. By the invention Use of a stainless steel carrier can provide thermal insulation of any thickness, in particular used with a thickness of 10 cm become. The stainless steel carrier has at least in the area The insulation has a constant cross section, which is an unproblematic enlargement the thickness of the insulation makes possible without that in addition a new approval by the Institut für Bautechnik is required.

in principle the stainless steel carrier may be in the outer component as well as in the building in any form continue. According to a further preferred embodiment However, the stainless steel carrier of the present invention a tapered cross section. The stainless steel carrier can be both in the field of the external component as well also rejuvenate in the area of the building. By the Rejuvenation can save a lot of material while still being sufficient Strength and load capacity can be achieved.

The Component according to the invention with stainless steel support fixes all the disadvantages of conventional connections. The component can be used in building construction as well as in civil engineering become. The stainless steel support of the invention Component can be used as cantilever beam, single-field beam or multi-field beam can be installed.

The Component according to the invention is preferred for Connection of canopies in commercial and industrial buildings, in the production of non-thermally insulated transitions between buildings, not thermally insulated in case of connections Structures on buildings with thermal insulation, in the Balcony slab production and used in external stairs.

The Component according to the invention is preferably in In-situ concrete construction, precast concrete construction, steel construction and timber construction used.

Mentioned should be at this point that the inventive Component, of course, also in combination with a conventional cantilever plate connection can be used. Such Solution will be particular in a large Projection of the outer component offer.

moreover It should be noted that in the production of a cantilever Plate on a building corner with a combination of inventive Component and conventional cantilever plate connection no special order the conventional cantilever plate connection is required.

Brief description of the drawings

The Invention will be described below with reference to embodiments explained in more detail in connection with the drawings become. All figures show the invention only schematically and with its essential components. Same reference numerals correspond to elements of the same or comparable function. Show it

1 in vertical section perpendicular to the building wall, a schematic representation of a Kragplattenanschlusselements of the prior art,

2 in vertical section a stainless steel support according to the present invention in the form of a double-T-beam,

3 in vertical section perpendicular to the building wall an inventive component, wherein the stainless steel support in the direction AA of 2 is shown

4 in vertical section perpendicular to the building wall an inventive component with a stainless steel support with recesses, the stainless steel support in the direction of AA 2 is shown

5 schematically the flow of forces in the stainless steel carrier according to 4 .

6 in vertical section perpendicular to the building wall an inventive element connected to a precast reinforced concrete support or steel support, wherein the stainless steel support in the direction of AA 2 is shown

7 in vertical section perpendicular to the building wall an inventive component with a stainless steel support with recesses, wherein the Stainless steel girder in the direction AA of 2 is shown

8th schematically the flow of forces in the stainless steel carrier according to 7 .

9 in horizontal section an inventive component.

Ways to execute the invention

The component according to the invention can be used to connect a building and an external component. It has at least one stainless steel support, from which at least the tensile forces occurring are absorbed. In 2 is a vertical support in stainless steel 6 according to the present invention, which has the shape of a double-T-carrier. This type of stainless steel beam 6 with flanges 15 and footbridge 14 is known to those skilled in the art.

In 3 is a device according to the invention in vertical section perpendicular to the building wall 13 shown, the stainless steel carrier 6 in the direction of AA 2 is shown. Due to the lateral line of sight it becomes clear that the bridge 14 of the stainless steel carrier 6 has no recesses. With the reference number 7 are the two welds designated by the projecting into the outer part or in the building reinforcement to the stainless steel support 6 of the device according to the invention 13 can be connected non-positively. The stainless steel carrier 6 but may also have a greater length and even protrude as a reinforcement in the exterior part and / or in the building.

4 shows one of the 3 corresponding view of a device according to the invention, which is provided for use in the event that the outer component is hung in the ceiling of the building. The stainless steel carrier 6 has in this embodiment two recesses 9 in the field of insulation 1 on. The recesses 9 are located in the area of the jetty 14 of the double-T stainless steel girder 6 , The stainless steel carrier 6 thus forms in the area of insulation 1 a starting from the side of the building from above diagonally down towards the outer component side extending web.

The location of the recesses in the dock 14 of the stainless steel carrier 6 determines the course of the forces occurring in this area. In the 5 is the flow of forces in the stainless steel beam 6 in the 4 illustrated component 13 wherein Z ₁ indicates the direction of the tensile force, Z ₂ the direction of the suspension tension and D ₁ the direction of the compressive force.

6 again shows one of 3 corresponding view of a device according to the invention 13 , The component 13 is in this embodiment of a precast reinforced concrete support 11 connected. Due to the lateral line of sight it becomes clear that the bridge 14 of the stainless steel carrier 6 has no recesses. On the cantilevered plate 3 is an exterior component 16 such as a wall, a pillar or a staircase.

7 also shows one of the 3 corresponding view of a device according to the invention for connection to a precast reinforced concrete support or steel support (not shown). The exterior part or the stainless steel support in this case on the building side support 11 (please refer 6 ) hung up. The stainless steel carrier 6 has in this embodiment two recesses 9 in the field of insulation 1 on. The recesses are located in the area of the bridge 14 of the double-T stainless steel girder 6 , The stainless steel carrier 6 forms in this embodiment in the field of insulation a starting from the side of the building from below diagonally upwards toward the outer component side extending web.

The location of the recesses 9 in the dock 14 of the stainless steel carrier 6 determines the course of the forces occurring in this area. In the 8th is the flow of forces in the stainless steel beam 6 in the 7 illustrated component 13 in which Z ₁ indicates the direction of the tensile force, D ₁ the direction of the compressive force and D ₂ the direction of the support pressure force.

9 shows in horizontal section the in 3 already shown inventive component 13 , Shown in this case, the outlines of the cantilevered plate 3 and the building ceiling 4 , The component 13 with the stainless steel carrier 6 ensures a frictional connection of the plate 3 to the building 4 ,

1

insulation

2

tension rod

3

cantilever plate

4

ceiling tile

5

Shear bar

6

stainless steel carrier

7

Weld

8th

pressure element

9

recess

11

Prefabricated reinforced concrete support or steel support

13

module

14

web

15

flange

16

external component

Z ₁

traction

Z ₂

Aufhängezugkraft

D ₁

thrust

D ₂

Abstützdruckkraft

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 3005571 B1 [0002]

Claims (12)

Component ( 13 ) for connecting two components, in particular for connecting a building ( 4 ) and an outer component ( 3 ), with at least one, for non-positive connection of the outer component ( 3 ) provided stainless steel support ( 6 ), wherein at least the tensile forces occurring from the stainless steel support ( 6 ). Component ( 13 ) according to claim 1, characterized in that the stainless steel support ( 6 ) in addition to the tensile forces at least partially absorbs the other forces occurring. Component ( 13 ) according to at least one of claims 1 and 2, characterized in that the stainless steel support in addition to the tensile forces and the other forces occurring completely absorbs. Component ( 13 ) according to at least one of claims 1 to 3, characterized in that additional pressure means are provided for receiving pressure forces. Component ( 13 ) according to at least one of claims 1 to 4, characterized in that additional transverse force means are provided for receiving transverse forces. Component ( 13 ) according to at least one of claims 1 to 5, characterized in that it is in the stainless steel support ( 6 ) around a double-T stainless steel support ( 6 ). Component ( 13 ) according to at least one of claims 1 to 6, characterized in that it is in the stainless steel support ( 6 ) around a welded stainless steel carrier ( 6 ). Component ( 13 ) according to at least one of claims 1 to 6, characterized in that it is in the stainless steel support ( 6 ) around a rolled stainless steel support ( 6 ). Component ( 13 ) according to at least one of claims 1 to 8, characterized in that the stainless steel support ( 6 ) at least one recess ( 9 ) having. Component ( 13 ) according to at least one of claims 1 to 9, characterized in that the stainless steel support ( 6 ) has at least one gain. Component ( 13 ) according to at least one of claims 1 to 10, characterized in that the stainless steel support ( 6 ) has a tapered cross-section. Component ( 13 ) according to at least one of claims 1 to 11, characterized in that the component ( 13 ) additionally a heat insulating insulating body ( 1 ) of any thickness, the stainless steel support ( 6 ) the insulating body ( 1 ) interspersed.