DE102019116683A1 - COMPONENT FOR INSTALLATION IN SEPARATION JOINTS OF BUILDINGS - Google Patents

Abstract

Component for installation in separating joints of buildings, especially in the area of balconies, loggias or arcades, for the sound-absorbing, force-transmitting connection on both sides of adjoining building parts (A, B), consisting of a separating plate (1) and of this traversing reinforcement elements (3), the partition plate (1) having at least one opening (1d, 1e, 1f, 1g) for a reinforcement element, the partition plate having a trough-shaped shell body (6) in the area of the opening, which starts from the partition plate in the first (B) of the two adjoining building parts protrudes, the reinforcing element (3) protruding from the second (A) of the two building parts, crossing the opening (1d, 1e, 1f, 1g) into the formwork body (4). The first reinforcement element (3) is designed as a transverse force element in that it is inclined to the partition plate and inclined to a horizontal plane (EH) perpendicular to the partition plate when it crosses the opening (11). In addition, the first reinforcement element is also designed as a shear force element in that it is arranged in the region of the partition plate at an angle to a vertical plane (Ev) perpendicular to the partition plate.

Description

The invention relates to a component for installation in separating joints in buildings, in particular in the area of balconies, loggias or arcades, for the sound-absorbing, force-transmitting connection on both sides of adjacent building parts, with the features of the preamble of claim 1.

For sound-insulated power transmission in the area of separating joints, especially on staircase protests, for example, from EP-A 2626479 a component is known which, by dividing it into a partition plate on the one hand and one or more formwork bodies on the other, enables a modular structure that entails a separation of functions: the partition plate only has to ensure a soundproof spacing of the two adjoining parts of the building, whereas the power transmission alone Shells are responsible, which are built into appropriate openings in the partition plate and fixed there. The shell body does not guarantee the transmission of forces on its own, but instead uses reinforcement elements that cross the partition plate in the area of openings, with the reinforcement elements being inclined to the horizontal in order to absorb the forces occurring during the transmission of forces between the two parts of the building according to the model of a conventional transverse force rod can be transferred. Such components for footfall sound insulation have meanwhile proven themselves, which is why there is a need to apply these to further applications.

Starting from this, the present invention is therefore based on the object of further developing a component for installation in separating joints of buildings according to the preamble of claim 1 and adapting it to further requirements in order to be able to make the advantageous impact sound insulation properties available to other components.

According to the invention, this object is achieved by a component for installation in separating joints of buildings, in particular those extending in a vertical plane, with the features of claim 1.

Advantageous further developments of the invention are each the subject matter of subclaims, the wording of which is hereby incorporated into the description by express reference in order to avoid unnecessary text repetitions.

According to the invention, the component for installation in separating joints of buildings is characterized in that the first reinforcement element is also designed as a shear force element in that it is inclined in the region of the separating plate to a vertical plane Ev perpendicular to the separating plate. As a result, the horizontal rigidity of the component can advantageously be increased and the component can thus be used wherever shear forces have to be transmitted in the horizontal direction, namely in particular parallel to the plane of the partition plate and, if necessary, also perpendicular thereto.

In order to further facilitate this absorption and transmission of shear loads, the support element and the insulating element on the one hand and / or the formwork and the insulating element on the other hand are positively connected in the horizontal effective direction, whereby they absorb or pass on shear loads in the horizontal direction both perpendicular and parallel to the plane of the partition can. Normally, such a form-fitting connection is established in that the supporting element or the shell body laterally encompasses the insulating element and / or is supported on it, the insulating element is thus chambered by the supporting element and / or the shell body so that movements of the insulating element in the horizontal direction be passed on to the support element and / or the shell body and vice versa.

With this additional possibility for the planned absorption of stresses, the component according to the invention can be installed in the area of balconies, loggias or lye corridors, which regularly have to be acoustically decoupled for impact sound insulation.

Especially in these areas of use, namely balconies, loggias or arcades, there is a particular advantage that the partition plate, which itself is at least partially made of soundproofing material and / or has soundproofing material to ensure the desired impact sound insulation, also at least partially consists of thermal insulation material and / or has an insulating body for thermal insulation that extends at least partially along the parting line. In this case, the partition plate, together with the thermal insulation material, forms a composite insulation element that has a greater material thickness in the horizontal direction than the partition plate thickness. The properties of the first reinforcement element can really be exploited with the increased material thickness of the composite insulation element compared to the partition plate thickness: because if the first reinforcement element is also inclined in the area of the insulating body to the partition plate and inclined to the horizontal plane perpendicular to the partition plate and inclined to that perpendicular to the partition plate standing vertical plane is arranged, it passes through the insulating body and the partition plate in the inclined manner described and manner and can therefore also provide the desired transverse force transmission on the one hand and shear force transmission on the other hand in the area of the composite insulation element.

As a result, the first reinforcement element forms a vertically compressing shear and transverse force transmission element. The vertical compression results from the fact that the component is expediently used in supported or elevated building parts, that is to say additional means for absorbing weight forces, such as, in particular, supports, stands or cross members are provided. The present component is therefore not primarily used to absorb the weight forces of these parts of the building or the moments acting in the vertical plane as a result, but smaller weight forces in the vertical direction inevitably occur in the area of the component, which the first reinforcement element must absorb, which leads to the vertical compression described, which is usually of the order of a few millimeters and preferably less than 10 mm and in particular 4-8 mm.

Further advantageous effects result from the fact that the first reinforcing element consists of a reinforcing rod and is loop-shaped at least in some areas with two inclined loop legs which are at least partially horizontally spaced from one another in the area of the partition plate and in particular with opposite inclinations to the vertical plane perpendicular to the partition plate Ev run. Such a symmetrical structure results in essentially the same horizontal rigidity in the mutually opposite horizontal directions. The two inclined side-by-side loop legs are expediently connected to one another again in the area of the formwork body via a common loop base running essentially in a horizontal plane, the first reinforcing element with this loop base engaging around the support element. In this way, the first reinforcement element can be anchored on the support element and thus on the first part of the building and the desired connection can be established between the first part of the building and the second part of the building.

As is already known in the prior art, the rod material makes it possible to achieve ideal adaptation to the static tasks of power transmission with a comparatively thin cross-section of the reinforcement element. For the material of the reinforcement element, in particular reinforcement bar, metal and in particular stainless steel come into question, which can be ribbed in the form of a so-called reinforcing steel and thereby transfer the tensile force via the ribs to the material of the second part of the building or which can also be smooth-walled and is then anchored in the second part of the building via, for example, hook-shaped bends or terminal anchor heads.

For the desired transmission of transverse forces, the inclination of the first reinforcement element relative to the horizontal plane should be between 20 ° and 60 ° and preferably between 20 ° and 50 °, while for the desired transmission of shear force, the inclination of the first reinforcement element relative to the vertical plane between 10 ° and 30 ° and preferably should be between 10 ° and 20 °. This makes it possible to transfer the forces occurring in the force-transmitting connection between the two building parts according to the model of a conventional transverse force element, the reinforcement element - like a transverse force element - generally only being subjected to tension in its inclined course.

A major advantage of the inclined course of the reinforcement element is that the insulation element can be arranged in the first part of the building in such a way that the greatest possible height of the first part of the building is available above - or, depending on the installation case, below - the insulation element. This enables a significantly larger concrete cover, through which the force introduction or transmission can be optimized.

Especially when using the insulating body described for thermal insulation and the associated significantly increased thickness of the partition plate or the composite element, it is advisable to additionally provide a second reinforcement element that protrudes from the second of the two building parts, crossing the partition plate in the horizontal direction into the formwork body and there interacts with the support element for the insulating element. The second reinforcement element is designed as a compressive force element in that it extends perpendicular to the partition plate in the horizontal direction and / or that it consists of a reinforcement bar and / or that it crosses the partition plate in the area of the openings or another opening. The second reinforcement element is sensibly connected to the end face of the support element in a form-fitting, force-fitting or material-locking manner for stable compressive force transmission and has a terminal pressure plate on the opposite side, i.e. in the area of the second part of the building, which extends parallel to the parting plane and thus for improved anchoring of the second reinforcement element in the second part of the building. The contact area of the first reinforcement element on the support element and the connection area are advantageously located between the second reinforcement element and the support element at least essentially at the same height, that is to say the same horizontal section, the first reinforcement element engaging behind the support element with its loop base and the associated contact area thereby facing the connection area of the second reinforcement element on the support element. As a result, the tensile stressed first reinforcement element and the pressure stressed second reinforcement element mutually stabilize in the area of the support element by the additional second reinforcement element counteracting the forces transmitted from the first reinforcement element to the support element.

It is essential for the sound decoupling provided by the component that the reinforcement element crosses the opening in the partition plate, but does not extend into the adjoining second part of the building (i.e. not into the material of the second part of the building), but rather extends into the area of the Shawl body limited. An overlap of the two adjoining parts of the building is only created in the area of the formwork body, which - given the appropriate dimensioning or number of formwork bodies - is sufficient to ensure the necessary power transmission.

The formwork body with the associated first reinforcement element on the one hand and the partition plate on the other hand can easily be adapted to one another in terms of position, size, etc. For example, with one and the same partition plate, which only has to be based on the corresponding height of the adjacent building parts, a transfer of large forces by installing appropriately large formwork bodies or a correspondingly large number of formwork bodies as well as the transmission of only small forces, including then it is possible to work with a few or relatively small-sized formwork bodies and first reinforcement elements. The only adjustment of the partition plate must be to adapt the size and position of the opening to the installation situation and the number and dimensions of the formwork bodies to be connected.

It is also important that the first reinforcement element has a support element for the insulation element and, together with the support element, forms a bracket-like mounting projection for the second of the two building parts and that this second building part extends into the formwork body by means of the mounting projection and thus into the first part of the building to the sound-absorbing part , power-transmitting connection of the two building parts protrudes. Thus, the console-like bearing projection, which is assigned to the second part of the building and extends into the first part of the building, forms exactly the overlap that is necessary for the mutual force transmission, without reinforcing bars extending from the first part of the building into the material of the second part of the building must and also without the overlap having to be provided by a particularly complicated design of the partition plate.

Thus, the support element can consist of a profile plate which at least indirectly supports the insulating element and / or is supported on it, the support element in turn being held or supported by the first reinforcement element. If the reinforcement element is rod-shaped and bent in the shape of a loop, it can, for example, rest on its bent area.

In the contact area between the support element and, in particular, the rod-shaped first reinforcement element, recesses or, in particular, bends can provide a contact surface on which the first reinforcement element can be supported on the support element - or vice versa - in the horizontal direction. As a result, the horizontal components that result from the vertical load and the introduction of force via the inclined first reinforcing bar can be carried away via the supporting element into the connected second part of the building.

As far as the support element or, in particular, the profile plate is concerned, its main function must first be taken into account: it must ensure the transmission of forces between the remaining part of the reinforcement element and the insulation element. The support element or the profile plate is expediently designed to be flat with an essentially horizontal bearing surface for the insulating element. It extends substantially horizontally and can be planar, e.g. Be cuboid or advantageously has a partially angled, in particular U-shaped vertical cross-section with two U-legs and a U-base, the horizontally extending U-base between the two U-legs carrying the insulating element. The two U-legs can take on additional functions such as securing the position of the insulating element or fixing the position of the support element on the partition plate.

Above all, however, if the support element extends through the partition plate or the opening provided in it from the shell body into the second part of the building (or is connected to the second part of the building in another, indirect or direct manner), the support element and in particular whose terminal U-legs are supported between the support element and the second part of the building, through which any horizontal force components that occur are transmitted as compressive forces can be. This means that even if the reinforcement element can or should only serve to transmit transverse forces, any horizontal components resulting from the vertical load can be absorbed and passed on via the additional support element and can thus be kept away from the rod-shaped reinforcement element in particular. It is important that the support element is of course also decoupled from the first part of the building and thus also insulated from the footstep noise in the contact area of the said terminal U-leg on the second part of the building.

The insulating element can be designed in the known manner like a mat or plate and in particular consist at least partially of an elastomer. In the aforementioned case of the support element, an elastomer bearing thus formed is placed on the profile plate and extends in the horizontal plane.

On the side of the insulation element opposite the support element there is a contact surface of the insulation element which forms a force input / output area and in which the forces are transmitted as compressive force between the first part of the building and the insulation body. In this case, the insulating element in the area of the contact surface can either be acted upon directly by the material of the first building part, that is to say in particular by concrete, or with the interposition of the formwork body. That is, the shell body can either have a recess in the area of which the contact surface of the insulating element is arranged in order to come into direct contact with the material of the first part of the building; or the shell body can cover the insulating element in the area of the contact surface and directly pass on the forces occurring there between the first part of the building and the insulating element. For this purpose, the shell body should consist of hard, incompressible material.

In this context, it is particularly advantageous if the contact surface of the insulating element interacts with a distribution element, which consists in particular of pressure-resistant and / or high-strength material such as UHPC in particular and thus ensures improved force transmission between the insulating element and the material of the first part of the building. Because in this case the distributor element ensures a uniform introduction of force or force transmission without the quality of the material of the first part of the building in the contact area on the shell body having any significant effect on the force transmission. If the distribution element were not provided in this area, then imperfections in the contact area on the formwork body or on the insulating element could result in an uneven load on the insulating element and thus impair the insulating effect. However, this can be safely excluded by the distribution element. Even if the shell body is arranged between the distribution element and the material of the first part of the building, it usually consists of pressure-stable, thin-walled material that does not impair the desired force transmission.

The trough-shaped shell body is designed to be open on one side in the direction of the second building part in order to accommodate the first reinforcement element and the support element. It separates the first and second parts of the building from each other by a closed trough-shaped surface. In a particularly preferred embodiment, concrete is applied to the shell body only on the outer surface facing the first building part. The interior of the formwork body and thus also its inner surface are shielded from the material of the second part of the building by the partition plate and remain free of the material of the second part of the building, ie in particular concrete. This interior space advantageously serves to accommodate only the bracket-like storage projection, that is to say the first reinforcement element and the support element, and in particular also the insulating element. As a result, the contact areas between the bearing projection and the shell body are reduced to the comparatively small area of the insulating element, which is optimized with regard to a sound-absorbing mutual contact. This leads to an optimal, sound-insulated, force-transmitting connection to the building element of adjacent parts of the building.

The vertical dividing plane between the two building parts is provided with these trough-shaped indentations, which extend into the first building part, but without this having an effect on the course and especially on the shape of the remaining parting plane in the area of the partition plate.

The shell body should be arranged in the region of its cavity on the side opposite the insulating element at a distance from the first reinforcing element and the support element in order to avoid impairment or disruption of the impact sound insulation through mutual contact.

It is also particularly advantageous if the trough-shaped formwork body consists of at least one arched trough element for receiving the reinforcement element, which extends essentially in the horizontal direction, the support element and the insulating element, as well as an edge extending essentially in the especially vertical partition plate plane and if the formwork body in the area of the edge of the partition plate in the area or preferably slightly outside of it Breakthroughs is added to ensure a liquid concrete-tight system on the partition plate. The joining can take place by means of clamping, latching or clip connections, but also by means of materially bonded adhesive or welded connections.

The trough shape must of course be dimensioned so large that the console-like mounting projection (which preferably consists of a reinforcement element and a support element) surrounded by the shell body is strong enough to ensure the necessary power transmission. A large number of shell shapes are certainly possible, which are generally described as "trough-shaped" in the present case, which is primarily intended to mean that the parting plane in the area of the shell body is bulbous, arched, deepened or in some other way to create a space, in particular a cavity for the reinforcement element is formed and thus deviates from the other planar course of the partition plate. The phrase "trough shape" used here is not intended to define the exact shape of the room; Rather, cuboids with flat side surfaces are just as possible, as are bodies deviating from these with curved or inclined side surfaces, etc., as well as wedges, cylinders, trapezoids, etc. All common and therefore corresponding to the "trough shape" is the one-sided open design, which ensures that the shell body is connected to the partition plate in the area of an opening adapted to the shell body and that at least partially the parting plane in the region of the shell body from the partition plate plane into the shell body plane, ie the level of the shell body is laid.

As described above, the insulating element can - depending on the application - be arranged in the area of the ceiling and / or floor surface of the formwork body, namely at least where the force transmission takes place.

Instead of a single-shell shell, a multi-shell structure is also possible, or the combination of a flat shell shell with an insulating layer (e.g. in the form of a PE foam panel), whereby these two components can be connected to one another over the entire surface, in particular glued.

The same applies to the partition plate, which can also be made up of a flat first wall and an insulating layer attached to it (e.g. in the form of a PE foam panel) or also of two flat first walls and an insulating layer arranged in between, these components in turn over the entire surface can be connected to one another, in particular glued.

As far as the fixing of the reinforcement element on the material of the partition plate is concerned, for example the openings can be adapted to the shape of the reinforcement element in the traversing area so that a direct mutual contact ensures the necessary fixation of the reinforcement elements on the partition plate. If the first reinforcement element runs inclined in the area of the partition plate, there is also an additional possibility of support in a horizontal direction.

In addition, there are of course other options for setting, e.g. in that holding elements made of plastic are molded onto the partition plate, into which the reinforcement element can be inserted, clipped or fixed in any other way. The type of fixing should be designed in such a way that the reinforcement element can actually be securely fixed in position with respect to the separating plate so as not to prevent the specified position of the reinforcement element within the formwork body from being affected even if loads occur during transport, assembly on the construction site or when the concrete is exposed to in-situ concrete affect. Against this background, it makes sense to additionally fix the reinforcement element in the area within the formwork body by means of a plastic web at another point on the partition plate.

An essential aspect of the present invention is its modular structure. Against this background, it is particularly useful that the component has a plurality of openings provided in the partition plate, a plurality of formwork bodies arranged next to one another, in particular in the area of the openings, and a plurality of first reinforcement elements which extend into the corresponding formwork body. This makes it possible to adapt the component to the respective application or load case and to utilize the desired modular structure according to the invention.

It should also be pointed out that the present invention can be used not only for using the component according to the invention on the construction site and for creating the first and second building parts from in-situ concrete, but that the present invention can also be used particularly advantageously and effectively in the precast plant.

Finally, the building element can be provided with a fire protection material in a manner known per se, particularly in the area of the partition plate, e.g. with a strip of intumescent material, which in a recess of the partition plate and / or in end caps to the side, i.e. terminal closing of the partition plate is arranged.

• 1 ein erfindungsgemäßes Bauelement im zwischen zwei Gebäudeteilen montierten Zustand in geschnittener Seitenansicht;
• 2a - 2b das Bauelement aus 1 in Seitenansicht (2a) und in Draufsicht (2b);
• 3a einen Teil des Bauelements aus 1 bestehend aus erstem Bewehrungsstab, zweitem Bewehrungsstab und Tragelement in perspektivischer Vorderansicht;
• 3b einen anderen Teil des Bauelements aus 1 bestehend aus einer Trennplatte in perspektivischer Vorderansicht;
• 4a - 4c ein erstes Bewehrungselement des Bauelements aus 1 in perspektivischer Seitenansicht (4a), in Draufsicht (4b) und in Seitenansicht (4c);
• 5a - 5b einen Teil des Bauelements aus 1 bestehend aus erstem Bewehrungsstab, Tragelement, Dämmelement, Verteilelement und Schalelement in geschnittener Vorderansicht (5a) und in einer weiteren geschnittenen Vorderansicht (5b);
• 6a - 6b ein Schalelement des Bauelements aus 1 in perspektivischer Vorderansicht (6a) und in Seitenansicht ( 6b);
• 7a - 7d ein Tragelement des Bauelements aus 1 in perspektivischer Rückansicht (7a), in Rückansicht (7b), in Seitenansicht (7c) und in Vorderansicht (7d);
• 8a - 8b ein Verteilelement des Bauelements aus 1 in perspektivischer Unteransicht (8a), in Vorderansicht ( 8b) und in Seitenansicht (8c).

Further features and advantages of the present invention emerge from the following description of an exemplary embodiment with reference to the drawings; show here

• 1 a component according to the invention in the assembled state between two building parts in a sectional side view;
• 2a - 2 B the component 1 in side view ( 2a) and in plan view ( 2 B) ;
• 3a part of the component 1 consisting of a first reinforcing bar, second reinforcing bar and supporting element in a perspective front view;
• 3b another part of the component 1 consisting of a partition plate in a perspective front view;
• 4a - 4c a first reinforcement element of the structural element 1 in perspective side view ( 4a) , in plan view ( 4b) and in side view ( 4c );
• 5a - 5b part of the component 1 consisting of the first reinforcement bar, load-bearing element, insulation element, distribution element and formwork element in a sectioned front view ( 5a) and in another sectioned front view ( 5b) ;
• 6a - 6b a formwork element of the component 1 in perspective front view ( 6a) and in side view ( 6b) ;
• 7a - 7d a support element of the component 1 in perspective rear view ( 7a) , in rear view ( 7b) , in side view ( 7c ) and in front view ( 7d );
• 8a - 8b a distribution element of the component 1 in perspective bottom view ( 8a) , in front view ( 8b) and in side view ( 8c ).

In 1 is a component D. for installation in buildings shown in a sectional side view, which is between two adjacent parts of the building A. , B. in the form of an arcade 9 as the first part of the building B. and a building wall 8th as the second part of the building A. is arranged. Between the second part of the building A. and the first part of the building B. is a parting line C. arranged vertically over the entire height of the thinner of the two parts of the building, here the part of the building A. extends and not only represents a construction joint, but must also ensure footfall sound insulation between the adjacent components.

In the area of the parting line C. between the two parts of the building A. , B. is a flat partition plate 1 arranged over the entire height of the parting line C. extends and - like it in particular from 2 B can be seen - has a horizontal length on the order of, for example, 1 meter.

The partition plate 1 consists - like in particular from 2a can be seen - from two relatively pressure-resistant outer walls 1a , 1b , which are only connected to each other via a few horizontal intermediate webs and otherwise maintain a mutual distance in the order of magnitude of approx. 10 mm in order to thereby surround the two adjacent parts of the building A. and B. to keep a distance from each other and to prevent a corresponding mutual contact and thus the transmission of vibrations and sound. The outside walls 1a , 1b have several horizontally running ribs or webs protruding a few millimeters, which allow for a certain anchoring of the partition plate in the adjacent concrete of the building part B. to care. The outside walls 1a , 1b with the intermediate webs are self-supporting and pressure-resistant enough to withstand the forces of the liquid concrete material if the building parts are made of in-situ concrete or prefabricated from concrete in the precast plant and to keep both parts of the building permanently at a distance even after the concrete material has hardened.

To improve the sound insulation there is between the two outer walls 1a , 1b an insulation board 1c made of polyethylene, the three elements being fixed to one another in a sandwich construction, eg glued over their entire surface.

The partition plate 1 has several openings arranged next to and one above the other 1d on - see in particular 3b , to the trough-shaped shell 6th (each in the same direction) added or through the reinforcement elements 3 , 4th are inserted through - see in particular 2a . Each shell body is flat and liquid-tight on the outer wall with its upper edge 1b the partition plate 1 set. The shell body 6th is - as in particular from the 5a , 5b , 6a and 6b it can be seen - trough-shaped, in particular bulged or arched, and forms a cavity 6d , which is largely limited or enclosed by the shell body. The cavity 6d serves to hold a first reinforcement element in particular 3 , while the outside of the formwork from the concrete of the building part B. is applied.

As especially from the 1 and 5a , 5b As can be seen in the vertical section, an insulating element is approximately based on its height in the middle area of the shell body 5 Arranged in the form of a plate-shaped elastomer bearing, which is used for the sound-insulated power transmission between part of the building B. and part of the building A. cares. The Elastomer bearings 5 lies flat with its upper contact surface 4a from below on part of the reinforcement element, namely the support element described in more detail below 4th on, whereas the elastomer bearing 5 with its lower contact surface 5b a distribution element 7th applied flat from above. The distribution element 7th in turn, it borders the elastomer bearing or insulating element 5 opposite surface on the shell body 6th at. The exact external shape of the distribution element 7th is in the 8a , 8b and 8c recognizable, where you can also see the curved underside over which the distribution element rests on the shell body. Shawl bodies lie like this 6th , Elastomer bearings 5 and support element 4th fully to one another, as it is in particular from 5a , 5b can be seen.

The 5a , 5b , 6a , 6b leave the trough shape of the shell 6th recognize, whereby in the illustrated embodiment it is primarily the underside of the shell body on which the described distribution element is important 7th and which serves to introduce force.

The rest of the trough shape is not primarily decisive for power transmission and sound insulation; It is only necessary to ensure that there is a distance from other elements such as in particular reinforcement element 3 and / or support element 4th is adhered to in order not to impair the impact sound insulation through mutual contact.

The formwork has two on the course of the reinforcement bar 3 adapted inclined legs 6a on as well as two especially from the 5a and 5b visible folds 6b , between which the elastomeric bearing 5 and the distribution element 7th edged in the horizontal direction and so determined.

In the other areas of the shell body this is - in particular off 5a , 5b , 6a , 6b can be seen - approximately cuboid with substantially horizontal and vertical flat side surfaces and runs there at a distance from the first reinforcement element 3 and anything else in the cavity 6d arranged elements.

The shape, the course, the position and the orientation of the first reinforcement element 3 are particularly off 3 , 4a , 4b and 4c evident. Every shell 6th is a first reinforcement element 3 assigned, which consists of a rebar made of metal. The reinforcing bar is loop-shaped in the area of the cavity 6d of the shell 6th bent so that there are two legs 3a , 3b of the rebar 3 from the shell 6th out towards the second part of the building A. extend, with a loop base connecting the two legs 3c roughly horizontal in the shell 6th runs.

The two loop legs 3a , 3b are in the area of the partition plate 1 horizontally spaced from each other and extend with mutually opposite inclination by an angle β of about 14 ° with respect to the perpendicular to the partition plate and in the 2 B and 4b shown vertical plane Ev.

On the way to the second part of the building A. cross the two legs 3a , 3b the opening in each case 1d in the separator 1 . Starting from the horizontal base 3c while crossing the breakthroughs 1d and then in the area near the edge of the second part of the building A. run the two legs 3a , 3b straight at an angle α of about 30 ° inclined to in the 2a and 4c shown horizontal plane E _H , as is known from transverse force reinforcement bars in structural elements for thermal insulation. Only in a lower area of the second part of the building A. if the two legs meet again, they are bent together according to the aforementioned angle α of about 30 ° and go into a parallel horizontal section 3d over and are so over a large integration length in the second part of the building A. anchored.

The rebar 3 lies down in its inclined course 3a , 3b at the edges of the openings and is also supported on the legs 6b of the shell 6th from, in its cavity 6d he protrudes.

According to an essential aspect of the invention, the reinforcement element has a support element 4th for the insulation element 5 on. The reinforcement bar supports this 3 in the area of its base 3c a profile plate that the support element 4th forms and - as already mentioned above - on the insulating element 5 is applied. The profile plate extends essentially in the horizontal direction, with its edges 4c Angled in the vertical direction and thus forms a U-shaped vertical section with two vertical U-legs 4c and a horizontal U-base 4a on the plate-shaped insulation element 5 rests. Using the two U-legs 4c goes the support element 4th a positive connection in the horizontal effective direction with the insulating element 5 a.

The profile plate serving as a support element is particularly made of the 7a - 7d recognizable, which show the profile plate in different views, as well as from 3 who also made the first rebar 3 and shows its interaction with the support element.

In addition, the support element 4th on his the partition plate 1 facing upper front an increase 4d on that of the first reinforcement element 3 by means of the two legs 3a , 3b and the loop base 3c is encompassed, as in particular from the 2a and 3 can be seen. The first reinforcement element is for this purpose 3 with its thigh base 3c flat on one of the said elevation 4d final throat 4f and due to the enlarged contact surface it ensures a favorable power transmission between the first reinforcement element 3 and support element 4th .

In the area of the mentioned increases 4d has the support element 4th finally a central nose-like projection on its upper side 4e to connect a second reinforcement element 13 serves, and in particular in the 2a and 3a is shown. This second reinforcement element 13 extends in the horizontal direction, consists of a rod material and takes on the function of a pressure element that extends from the support element 4th through the partition plate 1 up to the second part of the building A. extends. While the second reinforcement element 13 one end into the nose-like elevation 4d of the support element dips, it points to its other, in the second part of the building A. arranged end of a pressure plate 13a in order to anchor it in the second part of the building A. to improve. The pressure plate 13a extends in one to the partition plate 1 parallel plane perpendicular to the direction of extension of the second reinforcement element 13 . In the exemplary embodiment shown in the drawing, the connection to the support element takes place by means of a welded connection, the main load on this connection being pressure forces, so the connection does not have to meet excessive requirements.

To the second reinforcement element 13 Space to cross the partition plate 1 to let the openings 1d - as in particular from 3b can be seen - central elevations on their upper edge 1f on.

Finally, the partition plate 1 in addition to the soundproofing material 1d an insulating body 1e which consists of thermal insulation material and extends along the outer wall 1a the partition plate 1 extends and is also provided, together with the remaining partition plate 1 in parting lines C. to be arranged. The insulating body 1e lies flat on the outer wall 1a and is from the first rebar 3 and the second rebar 13 crosses. Since such insulating bodies for thermal insulation usually have a horizontal thickness of at least 80 mm, the free length of the first and second reinforcement elements, i.e. not supported by the two building parts, is correspondingly large, which of course also increases the load due to the shear and transverse forces occurring accordingly.

Now the component according to the invention 1 in in 1 application shown in the parting line C. installed, the ribbed first reinforcing bar ensures 3 for anchoring the component 1 in the part of the building A. and thus for a correspondingly sufficient power transmission into the adjacent part of the building A. . On the other hand, the shell body takes care of it 6th especially in the area of the building part for an introduction of compressive force in particular in the vertical direction B. so that the elastomeric bearing 5 that between the shell 6th or distribution element 7th and support element 4th is arranged, the power transmission between part of the building B. and part of the building A. in a soundproofed manner. About the additional in the parting line C. to the partition plate 1 attached insulating body 1e and there is the first reinforcement element 3 and the second reinforcement element 13 through the partition plate 1 with attached insulating body 1e extend, said sound-insulated power transmission also takes place in a heat-insulated manner.

The insulation material consists of high-quality closed-cell polyurethane (PUR), for example. As for the two outer walls of the partition plate 1 concerns, these can consist of pressure-resistant material such as hard PVC, whereas the insulation board arranged between the outer walls 1c made of polyethylene (PE). In addition, other insulating materials or other pressure-resistant plastics can of course also be used.

It is not difficult to see that the partition plate, formwork body, insulating element and also the first and second reinforcement element and support element can easily be varied in terms of their dimensions or number and that due to the modular structure according to the invention with few components, a very high variety of variants is made possible.

This forms the first reinforcement element 3 , the second reinforcement element 13 and the support element 4th together a console-like storage projection that extends into the interior of the shell body 6th extends, there with the insulating element 5 and the distribution element 7th cooperates, which is in operative connection with the first part of the building B. and are acted upon directly or indirectly by its material, in particular concrete.

In summary, the present invention offers the essential advantage of being able to be adapted for a wide variety of applications by simple changes in terms of dimensions and number of individual parts, without this leading to a complete reworking of the component would have to. The component according to the invention can thus be used wherever a sound-insulated transverse and shear force transmission is required between two horizontally adjacent building parts, which can have additional properties such as, in particular, thermal insulation.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the 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.

Patent literature cited

• EP 2626479 A [0002]

Claims (16)

Component for installation in separating joints of buildings that extend in a vertical plane, in particular in the area of balconies, loggias or arcades, for the sound-absorbing, force-transmitting connection on both sides of adjacent building parts (A, B), the component consisting of an at least partially along the dividing line (C) extending dividing plate (1) and reinforcing elements (3, 13) passing through it, the dividing plate (1) having at least one opening (1d) for at least one first reinforcing element (3) in the region of the dividing line (C), wherein the partition plate (1) in the area of the opening (1d) has a trough-shaped shell body (6) which, starting from the partition plate, protrudes into the first (B) of the two adjacent building parts, the first reinforcing element (3) starting from the second (A ) of the two parts of the building, crossing the opening (1d), protrudes into the shell (6) and there with a sound-insulated Kr After transmission between the two building parts (A, B) serving insulating element (5) cooperates, wherein the first reinforcement element (3) has a support element (4) for the insulation element (5) and together with the support element, a bracket-like mounting projection (3, 4) for the second (A) of the two building parts forms and wherein this second building part extends into the shell body (6) by means of the bearing projection and thus protrudes into the first building part (B) for the sound-insulating, force-transmitting connection of the two building parts (A, B), and wherein the first reinforcement element (3) is designed as a transverse force element in that it is inclined to the separating plate and inclined to a horizontal plane (E _H ) perpendicular to the separating plate when it crosses the opening (1d), characterized in that the first reinforcing element (3 ) is also designed as a thrust element in that it is inclined in the area of the partition plate (1) to a perpendicular to the Tre nnplatte standing vertical plane (Ev) is arranged. Component according to at least Claim 1 , characterized in that the supporting element (4) and the insulating element (5) are positively connected to each other in the horizontal effective direction and the supporting element, in particular for this purpose, laterally encompasses the insulating element, and / or that the shell body (6) and the insulating element (5) in the horizontal The direction of action are positively connected to one another and the shell body, in particular for this purpose, laterally encompasses the insulating element. Component according to at least Claim 1 , characterized in that the partition plate (1) consists at least partially of sound insulation material and / or has sound insulation material, and / or that the partition plate (1) consists at least partially of thermal insulation material and / or parallel to the partition plate (1) at least partially along the Separating joint (C) extending insulating body (1e) is arranged for thermal insulation, so that the separating plate (1) forms a composite insulation element with the thermal insulation material. Component according to at least Claim 1 , characterized in that the first reinforcement element (3) consists of a reinforcement bar (3a, 3b, 3c) and is loop-shaped at least in partial areas with two loop legs (3a, 3b) which are at least partially horizontal from one another in the area of the partition plate (1) at a distance and in particular with an inclination opposite to one another with respect to the vertical plane (Ev) which is perpendicular to the partition plate. Component according to at least Claim 4 , characterized in that the two loop legs (3a, 3b) are connected to each other again in the area of the shawl body via a common loop base (3c) running essentially in a horizontal plane, and that the first reinforcement element (3) supports the support element (4) with the encompasses two loop legs (3a, 3b) and the loop base (3c). Component according to at least Claim 1 , characterized in that the first reinforcement element (3) in the area of the partition plate (1) has an inclination relative to the horizontal plane (E _H ) of between 20 ° and 60 ° and preferably between 20 ° and 50 ° and / or that the first reinforcement element (3) in the area of the partition plate (1) has an inclination with respect to the vertical plane (Ev) of between 10 ° and 30 ° and preferably between 10 ° and 20 ° Component according to at least Claim 1 , characterized in that a second reinforcement element (13) protrudes from the second (A) of the two building parts, traversing the partition plate (1) in the horizontal direction into the formwork body (6) and there with the support element (4) for the insulating element (5) cooperates. Component according to at least Claim 7 , characterized in that the second reinforcement element (13) is designed as a compressive force element in that it extends perpendicular to the partition plate in the horizontal direction and / or that the second reinforcement element (13) consists of a reinforcement bar and / or that the second reinforcement element (13) the partition plate (1) traverses in the region of the opening (11) or another opening (12). Component according to at least Claim 1 , characterized in that the support element (4) is supported at least indirectly on the insulating element (5). Component according to at least Claim 1 , characterized in that the support element (4) consists of a profile plate, which consists in particular of metal, preferably of stainless steel. Component according to at least Claim 10 , characterized in that the profile plate (4) extends essentially in the horizontal direction and / or that the profile plate (4) has an essentially horizontal contact surface (4a) for the insulating element (5). Component according to at least Claim 1 and or Claim 7 , characterized in that the first reinforcement element (3) and / or the second reinforcement element (13) consist at least partially of metal and preferably of stainless steel. Component according to at least Claim 1 , characterized in that the insulating element (5) is plate-like and in particular consists at least partially of an elastomer. Component according to at least Claim 1 , characterized in that the insulating element (5) cooperates on the side opposite the support element (4) with a distribution element (7) which is in operative connection with the first building part (B), and that the distribution element (7) is made up of pressure and / or high-strength material such as UHPC and is used for power transmission between the insulation element and the first part of the building. Component according to at least Claim 1 and or Claim 7 , characterized in that the trough-shaped shell body (6) is open on one side in the direction of the second (A) of the two building parts and in its interior space (6d) the first reinforcement element (3), the second reinforcement element (13), the support element (4 ) and / or the insulating element (5). Component according to at least Claim 1 , characterized in that the component (1) has a plurality of openings (1d) and further openings in the separating plate (1), a plurality of formwork bodies (6) arranged next to one another and a plurality of first and second reinforcement elements (3, 13).

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