DE102020115152A1 - Hollow body with at least one cavity for a component, in particular a gradient component - Google Patents

Abstract

The invention relates to a hollow body (100) with at least one cavity (1) for integration in a component (10), preferably a gradient component, the hollow body (100) being made from a mineral material. The hollow body (100) is particularly characterized in that it comprises at least one foot element (101) and the at least one foot element (101) protrudes from the hollow body (100) and forms a spacer and is preferably used to erect the hollow body (100).

Description

The invention relates to a hollow body with at least one cavity, in particular for creating at least one hollow volume in a component, preferably a (e.g. graded, in particular meso-etched) solid component (e.g. made of concrete, reinforced concrete, mortar or clay). The invention also relates to a component with a large number of such hollow bodies.

Usual solid components from z. B. Concrete, mortar or clay are characterized by a homogeneous materiality within the component. Although it is known that these components are subjected to very inhomogeneous loads in the interior when there is static and / or dynamic loading, that parts of the material in the interior of the component are only subjected to low levels of stress or that they are not required to remove these stresses, there have so far only been few approaches to constructing the interior of the component in a targeted manner To structure cavities in such a way that a reduction in the weight of the component and, related to this, a reduction in the consumption of resources, the energy required to manufacture the component and the emissions released during the manufacture of the component can be achieved.

In DE 20 2006 002 540 U1 a device is described by means of which, by inserting hollow bodies made of plastic into a formwork, solid components, in particular concrete components, can be produced which have cavities in their interior. The device is characterized in that it allows no or only a very limited adaptation of the cavity sizes and densities within the component. The basic concept is a weight saving due to the fact that identical large hollow bodies are laid in a single layer and in an equidistant arrangement to one another in the floor plan. As a result, however, the possibilities of reducing the weight of the components are only partially used.

Furthermore, the in DE 20 2006 002 540 U1 disclosed hollow body made of plastic to secure the position before and during concreting as well as to prevent buoyancy when concreting with a special reinforcement ballasted and / or are connected to the reinforcement of the concrete component that a removal of the hollow body made of plastic z. B. for the purpose of recycling after the end of use of the component is very expensive or almost impossible. The special reinforcement is usually designed as a reinforcement cage that is open at the bottom. This enables any lower and upper reinforcement that may be required to be inserted within the component. Low-weight reinforcement guides, however, require reinforcing bars that are guided at different heights, for example reinforcing bars that are bent in the vertical plane or bent in a Z-shape. These can be found at the in DE 20 2006 002 540 U1 disclosed teaching can not be introduced or only with a disproportionately high effort due to the geometry of the reinforcement cages.

The in DE 10 2011 102 337 A1 disclosed teaching is based on the approach of grading the properties of a particularly massive component in at least one of the three spatial directions of the component. The devices and methods described there allow the production of components with properties that change continuously in at least one of the three spatial directions of the component. The grading of the properties can in particular by generating z. B. pores and / or the introduction of lightweight aggregates. With this technology, significant weight savings can be achieved.

In “Schmeer, D., Sobek, W .: Gradientenbeton. In: Betonkalender 2019. Ernst und Sohn, Berlin, 2019 "technique called" Mesogradierung ", spherical mineral hollow bodies made of a usually special mortar are inserted into the formwork for the solid / concrete components. With an appropriate choice of the ball diameter and the ball arrangement, a finely graduated distribution of the interior spaces within the solid / concrete component and thus a large weight reduction can be achieved. At the same time, the recycling problem is solved by choosing a mineral material for the hollow bodies.

EP 1 718 814 A1 discloses hollow spheres, but when using them the problem can arise that the hollow spheres require additional position securing on a formwork surface, since they would otherwise roll away and / or move relative to one another. Furthermore, the problem can arise that the reinforcement usually required for components made of reinforced concrete cannot be attached to the hollow spheres. Furthermore, the problem can arise that the hollow spheres cannot be connected to one another in the case of a multilayer installation, i.e. installation can only take place on the basis of the theory of spherical packings, in which a hollow sphere must touch at least three other hollow spheres in order to be stable being. With this type of installation, however, it is almost impossible to introduce reinforcement. Furthermore, the problem can arise that some of the hollow spheres lie directly on the surface of the formwork.

The area around the point of contact of the hollow sphere with the formwork surface is a problem area when the building material that constitutes the solid component is subsequently introduced, as incomplete backfilling can be observed again and again. Furthermore, only a few millimeters thick hollow body walls at the point of contact represent a very fragile area after removing the formwork. B. plastering work or when attaching fasteners such as dowels can be critical.

One object of the invention is to provide an alternative and / or improved hollow body, in particular a hollow body, by means of which an interior space of a component (e.g. solid component, in particular gradient component) is appropriately structured (e.g. graded, in particular mesograde) ) leaves. The hollow body should preferably achieve the greatest possible weight saving on the component, have a high level of positional security before and / or during the manufacture of the component, enable easy installation of reinforcement and / or allow the component to be advantageously recycled.

The object can be achieved by the features of the independent claim. Advantageous further developments of the invention are disclosed in the subclaims or result from the following description of preferred exemplary embodiments of the invention.

The invention relates to a hollow body with at least one cavity, e.g. B. for generating at least one hollow volume in a component. The hollow body can expediently be integrated into the component, in particular embedded in the (e.g. mineral) material that constitutes the component.

The component is preferably a gradient component.

The component can (for example, a particularly graded or meso-graded) solid component.

The component can in particular be made of mineral material (expediently building material), in particular concrete, reinforced concrete, mortar and / or clay.

The component can, for. B. be a building wall, a building ceiling or a building floor.

The preferably prefabricated hollow body is made of a mineral material (expediently building material), for. B. concrete, reinforced concrete, mortar and / or clay.

The hollow body is characterized in particular in that it comprises at least one foot element. The at least one foot element can, for. B. protrude from the hollow body.

The at least one foot element can, for. B. form a spacer and / or z. B. serve to (preferably secure and / or stable) erection of the hollow body, z. B. in a formwork.

The hollow body can, for. B. have at least two, at least three or at least four foot elements.

The erection of the hollow body, in particular a large number of hollow bodies, can preferably take place in a formwork into which the preferably mineral material (e.g. concrete) is then introduced for the production of the component.

The at least one foot element can, for. B. be designed that it causes a particularly high and stable positional accuracy of the hollow body. The at least one foot element can, for. B. an appropriately simple and precisely positioned juxtaposition of individual hollow bodies when laying the hollow body z. B. allow in a formwork.

The at least one foot element can, for. B. be arranged partially or completely below the hollow body.

It is possible that the at least one foot element forms a lateral and / or lower spacer, e.g. B. to ensure a distance to a side and / or lower formwork surface. As an alternative or in addition, the lateral spacing function can serve to ensure a spacing between individual hollow bodies. For this purpose, the at least one foot element z. B. from the hollow body expediently protrude downwards and / or to the side.

It is possible that the hollow body has at least one fastening means for fastening a reinforcement.

The at least one foot element can, for. B. have a fastening device for fastening a reinforcement.

The fastening device and / or the at least one fastening means can, for. B. groove-shaped or channel-shaped, be formed as a hole and / or by a plurality of projections.

The fastening device can preferably be designed to hold the reinforcement z. B. to attach spaced from the hollow body.

It is possible that the hollow body has at least one base, which can preferably be formed on the top of the hollow body and / or for engagement with at least one foot element of a z. B. can be formed over it can be arranged hollow body.

At least one fastener can, for. B. be formed on an upper side of the hollow body and preferably form an upper spacer. Alternatively or in addition, z. B. at least one fastening means can be formed on a side surface of the hollow body and preferably form a lateral spacer. Embodiments are also possible in which at least one fastening means is formed on an underside of the hollow body.

The at least one fastening means can preferably be designed to hold the reinforcement z. B. to attach spaced from the hollow body.

It is possible for the hollow body to have a hollow body wall structure (expediently with a large number of outer walls). The hollow body wall structure can form a hollow body shell and / or enclose the at least one cavity essentially on all sides. The hollow body wall structure can relative to the at least one cavity z. B. be thin-walled.

The geometry of the hollow body, which allows at least one foot element and / or the at least one base z. B. an advantageous, form-fitting juxtaposition of hollow bodies next to one another and / or one above the other.

The hollow body and in particular the hollow body can be placed according to the requirement and / or load profile of the component in order to be advantageous for z. B. to be able to achieve a reduction in component weight and, related to this, a reduction in resource consumption, the energy required to manufacture the component and the emissions released during the manufacture of the component.

In the context of the invention, however, the hollow body can not only be used for the purpose of saving weight, but preferably also for functionalizing the component for building temperature control, for supplying gases (e.g. temperature-controlled gases and / or fresh air) and / or for discharging of gases (e.g. stale room air and / or smoke gases).

It is possible that the hollow body has at least one, at least two or at least three cavity openings, e.g. B. at least one inlet and / or at least one outlet. This allows z. B. a flow through the at least one cavity by means of a fluid (z. B. gas or liquid) can be made possible. The at least one cavity opening can, for. B. be designed as a hollow body hole.

So that the hollow body can preferably be used not only for the purpose of saving weight, but also z. B. for building temperature control and alternatively or in addition to building interior ventilation (e.g. supply of fresh air and / or temperature-controlled air) and / or building interior ventilation (e.g. removal of stale air and / or of smoke gases). The gas is preferably meant to be air.

At least one cavity opening can, for. They can be used, for example, to fluidically connect cavities of individual (e.g. adjacent (e.g. adjacent and / or superimposed) hollow bodies with one another, whereby e.g. interconnected cavities can be achieved. can be realized by the protuberance and / or sleeve explained below.

Alternatively or in addition, z. B. at least one cavity opening can be used to keep the cavity open to the outside (z. B. outside of the component, a building interior and / or atmosphere), so that a fluidic connection between the cavity of the hollow body and in particular on the component the outside of the component can advantageously be guaranteed. This can e.g. B. can be realized by the protuberance and / or sleeve explained below.

At least one cavity opening can, for. B. be formed in the hollow body wall structure and / or transversely (z. B. perpendicular or oblique) open into the at least one cavity. Alternatively or in addition, z. B. an opening or passage cross section of the at least one cavity (at least in places) at least twice or at least three times as large as a passage cross section of the at least one cavity opening.

It can e.g. B. at least one cavity opening can be arranged on an upper side of the hollow body, at least one cavity opening can be arranged on an underside of the hollow body, and / or at least one cavity opening can be arranged on one or more side surfaces of the hollow body.

It is possible for at least one cavity opening to extend through a protuberance (e.g. protruding from the hollow body). Alternatively or in addition, it is possible that at least one cavity opening extends through a sleeve (e.g. protruding from the hollow body).

The at least one cavity opening, the at least one protuberance and / or the at least one sleeve can, for. B. have a substantially round, rectangular or other suitable flow cross-section and / or z. Am Narrow the direction of flow in order to achieve a jet effect.

The protuberance and / or the sleeve can preferably be formed from mineral material.

The protuberance can, for. B. be integrally formed in one piece on the hollow body.

The sleeve can, for. B. be mounted as a separate part on the hollow body.

The sleeve can, for. B. have a projection to bear against the hollow body.

The protuberance and / or the sleeve is designed in particular to be able to extend on the component at least as far as the outside of the component and preferably to be able to open into a component surface.

The sleeve and / or the protuberance can, for. B. be designed as a tube or stub tube.

The hollow body can have one or more sleeves and / or protuberances.

It is possible for the hollow body to have at least one (e.g. manually adjustable and / or remote-controlled) adjustment device (e.g. a flap, a lamella mechanism, sliding mechanism, fan, etc.) in order to regulate a fluid flow (e.g. gas and / or liquid) to control through the at least one cavity opening, for. B. to enable, prevent and / or change in terms of quantity (to regulate appropriately). The adjusting device can, for. B. be arranged inside the hollow body or outside of the hollow body. The adjusting device can, for. B. be mounted in or on the at least one cavity opening.

It is possible that the at least one cavity z. B. is designed essentially in the form of a Helmholtz resonator (z. B. essentially pear-shaped or teardrop-shaped) and / or has a structured inner surface, preferably to achieve a sound-absorbing effect.

It is possible for the at least one foot element, the at least one fastening means, the at least one protuberance and / or the at least one base to be formed in one piece and integrally on the hollow body and / or to be made of mineral material.

It is Z. B. possible that the at least one foot element, the at least one fastening means, the at least one protuberance and / or the at least one base is produced together with the hollow body in a casting, spraying or centrifugal process, so as to be one-piece with the hollow body to be able to be trained.

However, embodiments are also possible in which at least one foot element, at least one fastening means and / or at least one base is mounted as a separate component on the hollow body and z. B. made of mineral material, plastic or metal.

It is possible for a shear reinforcement and / or a (for example, essentially U-shaped) shear anchor to be fastened to at least one foot element and / or to at least one fastening means. Alternatively or in addition, z. B. a load anchor (especially heavy duty anchor, useful for taking up trailer loads) can be integrated.

The hollow body together with the reinforcement (z. B. shear reinforcement, shear anchor, etc.) and / or the load anchor can, for. B. form a (suitably prefabricated) module. The shear reinforcement, the shear anchor and / or the load anchor z. B. can be firmly attached in particular to the hollow body before it is introduced into the formwork.

The hollow body can, for. B. have a substantially parallelepiped (z. B. cubic) or substantially prismatic basic shape.

The hollow body can, for. B. be a substantially hollow box-shaped hollow body.

The hollow body is preferably a displacement body, in particular for displacing the material forming the component.

It should be mentioned that the hollow body can preferably be prefabricated and (expediently with a large number of other hollow bodies) can be placed in, in particular, a formwork by means of which the component can be produced (e.g. by adding mineral material, concrete, etc.) .

It should be mentioned that an attachment of a reinforcement to a fastening device of at least one foot element and / or to at least one fastening means z. B. can be loose, in particular by placing or laying on the reinforcement z. B. in a groove, a hole, a recess, a guide, along a projection etc .. But it is z. B. also possible that a reinforcement is fixedly and / or essentially immovably mounted on a fastening device of at least one foot element and / or on at least one fastening means.

It is even possible that a reinforcement is embedded in at least one foot element (in particular its fastening device) and / or at least one fastening means and z. B. is encased in areas by at least one foot element and / or at least one fastening means. Here, the reinforcement can preferably be inserted into the production mold of the hollow body.

In the case of the mineral material for the hollow body, the at least one foot element, the at least one fastening means, the protuberance, the sleeve and / or the component, it can be, for. B. be the same mineral material or a different mineral material.

The invention also relates to a component, in particular a (z. B. graded, in particular meso-etched) solid component, e.g. B. made of mineral material such as concrete, reinforced concrete, mortar and / or clay.

The component preferably comprises a plurality of hollow bodies as disclosed herein.

It is possible that the individual hollow bodies are made of mineral material, at least one cavity, e.g. B. to generate at least one hollow volume in the component, and in particular have at least one foot element.

The hollow bodies serve in particular to produce the graduation, in particular mesograde, of the component.

The hollow bodies are preferably not only used for the purpose of saving weight, but can in particular be used by means of the at least one cavity opening disclosed herein for building interior temperature control and alternatively or in addition to building interior ventilation (e.g. supply of fresh air and / or tempered air) and / or for building interior ventilation (e.g. removal of stale air and / or smoke gases). The gas is preferably meant to be air.

The component can through fluidically interconnected cavities z. B. for building interior temperature control, for building interior ventilation (z. B. supply of fresh air and / or tempered air) and / or for building interior ventilation (z. B. removal of stale air and / or from Flue gases).

It is possible that the individual hollow bodies have at least two cavity openings and the cavities via the cavity openings z. B. are fluidically connected to each other, preferably to allow a flow through the cavities by means of a fluid (z. B. gas or liquid). Appropriately, the cavities can here, for. B. interconnected in an open system or a closed system. The cavities can, for. B. be fluidically connected to one another inside the component, preferably in one, two or three spatial directions.

Alternatively or in addition, z. B. have at least one hollow body at least one cavity opening opening towards the outside of the component, preferably to enable a gas to flow out of the component and / or a gas to be transported away via the component.

It is possible that a temperature control and / or supply device (e.g. heating and / or cooling device, an overpressure device, etc.) is provided in order to fill the cavities with a temperature-controlled fluid (e.g. air or water). to supply. Alternatively or in addition, z. B. a loading device (z. B. a suction or overpressure device) can be made available in order to enable a gas (z. B. used air and / or smoke) to be removed via at least one cavity opening of at least one hollow body, preferably from one Building interior.

At least one installation line (e.g. an electrical line, a data cable, a control line, a water or sprinkler line, etc.) can be, for. B. extend through cavity openings of individual hollow bodies.

It is possible for the component to be designed as a component that is graded, preferably meso-etched, by means of the hollow bodies.

The cavities of individual hollow bodies can essentially be of the same size and / or of different sizes and / or have a size of the order of 10 mm to 250 mm, preferably of 75 mm or 100 mm to 250 mm. However, orders of magnitude over 250mm are possible.

It is possible that hollow bodies are expediently arranged one above the other and / or next to one another.

As an alternative or in addition, adjacent hollow bodies can be in engagement with one another (in particular in contact with one another), e.g. B. by means of the foot elements and / or the base.

It is possible that the foot elements of adjacent hollow bodies are in engagement with one another.

The hollow bodies can be distributed in the component preferably in at least one, at least two or three spatial directions and / or in particular be brought into engagement (in particular in abutment) with one another by means of the foot elements.

With intervention z. B. a (suitably pure) contacting and / or z. B. a form fit in at least two spatial directions expediently be included.

It is possible for the hollow bodies to be enclosed on all sides by a material forming the component (e.g. mineral) and integrated into the component. B. foot elements, other spacers, the at least one sleeve and / or protuberance and / or one or more cavity openings z. B. can extend to the component surface (expediently outside of the component) and thus z. B. not necessarily have to be covered and / or enclosed on all sides by the material forming the component. Alternatively or in addition, z. B. a space between the foot elements of the individual hollow body can be filled by a component forming (z. B. mineral) material. This allows z. B. a multi-axis load transfer are made possible.

The at least one foot element of the individual hollow body can, for. B. extend up to the component surface and / or terminate essentially flush with the component surface. So are z. B. also includes embodiments in which the component surface and thus the foot elements z. B. is provided with plaster, wallpaper, a cover, etc.

As already stated, the at least one foot element is particularly helpful for the manufacturing process of the component. The at least one foot element here preferably projects from the individual hollow bodies downwards and preferably laterally and enables the individual hollow bodies to be set up in a secure and / or stable position, e.g. B. in a formwork for manufacturing the component. As an alternative or in addition, it enables individual hollow bodies to be attached to one another in an expediently simple and precisely positioned manner.

However, the foot elements on the component do not necessarily have to be aligned downwards. The foot elements can on the component z. B. downwards, upwards and / or laterally (z. B. substantially horizontally or obliquely) and thus z. B. protrude down, up or to the side of the associated hollow body, z. B. depending on whether the component extends vertically, horizontally, obliquely or arcuately, e.g. B. a building wall, a building ceiling or a building floor, etc. forms.

The component can, for. B. be a beam or wall-shaped component (e.g. for a bridge, an elevator shaft or other supporting functions, etc.).

• 1 zeigt eine Seitenansicht eines Hohlkörpers,
• 2 zeigt eine Seitenansicht des Hohlkörpers der 1 mit Bewehrungsführung,
• 3 zeigt eine perspektivische Darstellung eines anderen Hohlkörpers,
• 4 zeigt eine Draufsicht mehrerer Hohlkörper,
• 5 zeigt einen vertikalen Schnitt durch zwei Hohlkörper,
• 6 zeigt einen vertikalen Schnitt durch einen Hohlkörper,
• 7 zeigt einen vertikalen Schnitt durch zwei Hohlkörper,
• 8 zeigt einen vertikalen Schnitt durch einen Hohlkörper,
• 9 zeigt einen vertikalen Schnitt durch einen anderen Hohlkörper,
• 10 zeigt eine perspektivische Darstellung eines Hohlkörpers mit Bewehrung,
• 11 zeigt eine perspektivische Darstellung eines Hohlkörpers mit Bewehrung,
• 12A zeigt eine Aufsicht ohne Oberseite eines Hohlkörpers,
• 12B zeigt einen Schnitt entlang Linie A-A der 12A mit im Hohlkörper integriertem Schwerlastanker,
• 13A zeigt eine Explosionsdarstellung einer beispielhaften Kopplungskonstruktion zur Verbindung der Hohlräume von zwei Hohlkörpern,
• 13B zeigt die Kopplungskonstruktion der 13A in zusammengebautem Zustand,
• 14 zeigt einen Ausschnitt eines horizontal ausgerichteten Bauteils mit einer Vielzahl an Hohlkörpern), und
• 15 zeigt einen Ausschnitt eines vertikal ausgerichteten Bauteils mit einer Vielzahl an Hohlkörpern.

The preferred exemplary embodiments and features of the invention described above can be combined with one another. Advantageous further developments of the invention are disclosed in the subclaims or result from the following description of preferred exemplary embodiments of the invention in conjunction with the accompanying figures. Show it:

• 1 shows a side view of a hollow body,
• 2 shows a side view of the hollow body of FIG 1 with reinforcement guide,
• 3 shows a perspective view of another hollow body,
• 4th shows a top view of several hollow bodies,
• 5 shows a vertical section through two hollow bodies,
• 6th shows a vertical section through a hollow body,
• 7th shows a vertical section through two hollow bodies,
• 8th shows a vertical section through a hollow body,
• 9 shows a vertical section through another hollow body,
• 10 shows a perspective view of a hollow body with reinforcement,
• 11th shows a perspective view of a hollow body with reinforcement,
• 12A shows a plan view without the top of a hollow body,
• 12B shows a section along line AA of FIG 12A with heavy-duty anchor integrated in the hollow body,
• 13A shows an exploded view of an exemplary coupling construction for connecting the cavities of two hollow bodies,
• 13B shows the coupling construction of 13A in assembled condition,
• 14th shows a section of a horizontally aligned component with a large number of hollow bodies), and
• 15th shows a section of a vertically aligned component with a large number of hollow bodies.

The exemplary embodiments of the invention described with reference to the figures partially coincide, with similar or identical parts being provided with the same reference symbols and reference being made to the description of other exemplary embodiments for their explanation. For purposes of illustration, not all parts are provided with reference symbols in all figures.

1 shows a side view of a hollow body 100 , whereby 2 the hollow body 100 shows with reinforcement.

The hollow body 100 is used for integration in a component 10 (e.g. 14th ), in particular a solid component expediently made of concrete, in particular reinforced concrete.

the 1 and 2 show by way of example only a single hollow body 100 in a formwork (mold) 401 to manufacture the component 10 namely before completion of the actual component 10 . In the formwork 401 however, a large number of further hollow bodies are expedient 100 placed. After all hollow bodies 100 are placed, the formwork 401 with which the component 10 constituent, in 1 symbolically represented material M. are filled, in particular so that the hollow body 100 from the material M. enclosed on all sides in the component 10 are integrated.

The component to be manufactured 10 thus comprises a large number of hollow bodies 100 and thereby represents an especially graded, preferably meso-graded component 10 represent, e.g. B. a building ceiling, a building floor or a building wall.

The hollow body 100 are preferably in accordance with the requirement and / or load profile of the component 10 placed in order to benefit z. B. a reduction in component weight and thus a reduction in resource consumption, a reduction in the production of the component 10 required energy and a reduction in the production of the component 10 to be able to achieve released emissions.

The hollow body 100 is made of a mineral material (e.g. mineral building material) and includes a cavity 1 , but can also have several cavities 1 include and thus form a multi-chamber hollow body. The cavity 1 serves to create at least one hollow volume (expediently a hollow space) in the component 10 .

The hollow body 100 is preferably designed in the shape of a hollow box. The hollow body 100 and / or the cavity 1 has, for example, an essentially cuboid basic shape, but in the context of the invention can have any other suitable basic shape or geometry.

The hollow body 100 comprises an expedient hollow body wall structure with in particular a large number of outer walls. The hollow body wall structure forms a hollow body shell and encloses the at least one cavity 1 all-round. The hollow body wall structure can here such. Tie 5 until 9 and 14th and 15th shown one or more cavity openings 2 have and relative to the cavity 1 be thin-walled.

A special feature is that the hollow body 100 at least one, preferably several foot elements 101 for appropriately positionally secure, stable erection of the hollow body 100 in the formwork 401 and Z. B. several fasteners 103 for fastening a reinforcement 204 , 205 having.

The foot elements 101 form lower and z. B. lateral spacers and are preferably from the hollow body 100 down and z. B. sideways.

The foot elements 101 can thus z. B. securing a distance to be maintained between the underside of the hollow body 100 to the top of the formwork 401 and / or a hollow body arranged underneath 100 serve. But you can also z. B. securing a lateral distance to be observed between the side surface of the hollow body 100 and side surface of the formwork 401 serve. They can also be used, for. B. securing a lateral distance to be observed between side surfaces of two adjacent hollow bodies 100 serve.

The foot elements 101 form z. B. down to the formwork 401 down spacers, leaving a gap S. between the foot elements 101 and the formwork 401 from which the component 10 forming material M. can be filled out. The same applies to the spaces between the individual hollow bodies 100 in the component 10 (e.g. 4th , 5 , 7th and 14th and 15th ).

The foot elements 101 preferably have a fastening device for expediently movable or immovable fastening (e.g. receiving) a reinforcement 202 , 204 and can z. B. a (lateral and / or lower) minimum coverage of the reinforcement 202 , 204 in the component 10 guarantee.

The fasteners 103 can expediently on one or more side surfaces and / or on the top of the hollow body 100 be trained.

The side fasteners 103 are preferably used for expediently movable or immovable attachment (z. B. recording) and z. B. Securing the position of an oblique to the component longitudinal axis and / or curved reinforcement 204 , optionally also on a foot element 101 can be attached. The upper fasteners 103 are preferably used for expediently movable or immovable attachment (z. B. recording) and z. B. Securing the position of an upper reinforcement 205 .

The hollow body 100 can preferably have several sockets on its upper side 105 exhibit. The pedestal 105 can with not shown foot elements of a hollow body, which is above the in the 1 and 2 shown hollow body 100 can be arranged, come into engagement, in particular to enable a form fit in preferably at least two spatial directions. The socket 105 and / or the foot elements 101 z. B. be substantially L- or V-shaped.

The foot elements 101 who have favourited Fasteners 103 and the socket 105 can e.g. B. one-piece-integral on the hollow body 100 be designed and made of mineral material. You can e.g. B. during the manufacture of the hollow body 100 preferably in a casting, spraying or centrifugal process directly on the hollow body 100 be molded.

3 shows a perspective view of another embodiment of a hollow body 100 .

3 shows e.g. B. That side faces 301 of the hollow body 100 , as well as, alternatively or in addition, its top 302 and bottom, non-parallel to each other, so as to z. B. to enable a non-parallel course of possibly required reinforcing bars. The top 302 of the hollow body 100 can e.g. B. be inclined in one or two directions so as to z. B. to enable an inclined course in the vertical plane of possibly required reinforcing bars.

4th shows in a plan view how several hollow bodies 100 to each other and on the edge of a formwork 401 can be positioned. The foot elements 101 serve to secure the position of the hollow bodies 100 on the formwork 401 . The foot elements 101 also serve to secure the spacing between the hollow bodies 100 opposite a lateral formwork level and a lower formwork level of the formwork 401 . The foot elements 101 also serve to secure the position and the spacing of individual hollow bodies 100 among each other, e.g. B. of side by side and / or one above the other arranged hollow bodies 100 .

Adjacent hollow bodies 100 can by means of foot elements 101 are brought into engagement with one another, preferably by means of two pairs of foot elements. Hollow bodies can also be used 100 are brought into mutual engagement vertically by means of the hollow body 100 with their foot elements 101 on other hollow bodies 100 be set up.

5 shows a vertical section through two hollow bodies 100 . The individual hollow bodies 100 form a cavity 1 .

A special feature is that the individual hollow bodies 100 at least two (z. B. designed as hollow body holes) cavity openings 2 have and the cavities 1 via the cavity openings 2 are fluidically connected to one another, preferably in order to flow through the cavities 1 by means of a fluid such. B. to enable a gas (especially air) or a liquid (especially water). The cavity openings 2 can e.g. B. via a with reference to the 13A and 13B coupling structure described be fluidically connected to one another.

The cavity openings 1 of the individual hollow bodies 100 are formed in the hollow body wall structure and open transversely into the associated cavity 1 . An opening or passage cross-section of the associated cavity 1 can e.g. B. at least twice as large as a passage cross section of the cavity openings 2 .

In the in 5 The embodiment shown are the cavity openings 2 on expediently laterally opposite side surfaces of the hollow body 100 educated. However, embodiments are also possible in which the cavity openings 2 on the upper and / or lower sides of the hollow body 100 are trained.

In the 5 The arrows shown symbolize a flow of fluid (e.g. water or air) on the component 10 through the cavities 1 the hollow body 100 through.

The fluid flow can be, for. B. to be tempered air or tempered water, thereby the component 10 and thus z. B. to be able to temper a building interior.

The fluid flow can be, for. B. to be tempered air and / or fresh air, the z. B. can be fed to a building interior.

The fluid flow can be, for. B. be stale air and / or flue gases that z. B. can be removed from a building interior.

The hollow body 100 and the cavities 1 can thus not only be used for the purpose of saving weight, as is usual for gradient components, but in particular because of the cavities that can be fluidically connected to one another 1 also for the functionalization of the component 10 for building temperature control, for building interior ventilation (e.g. temperature-controlled air and / or fresh air) and / or for building interior ventilation (e.g. used room air and / or smoke gases).

6th shows a vertical section through another hollow body 100 .

6th shows in particular one of the hollow body 100 protruding protuberance 602 , through a cavity opening 2 extends.

The protuberance 602 can e.g. B. be provided with a temporary cover in order to produce the component 10 the penetration of material during the introduction of the component 10 constituent material M. (Building material) to prevent.

The protuberance 602 is preferably made of mineral material and z. B. one-piece-integral on the hollow body 100 educated.

Which extends through the protuberance 602 extending cavity opening 2 can in particular be used to the cavity 1 after completion of the component 10 to the symbolically represented outside 701 of the component 10 (z. B. a building interior and / or building exterior, in particular atmosphere) to keep open, so that a fluidic connection between the cavity 1 of the hollow body 100 and the outside 701 of the component 10 can be made possible e.g. B. a fluid supply to the outside 701 and / or a fluid discharge from the outside 701 out to be able to guarantee.

On the component 10 the protuberance may develop 602 thus to the outside 701 of the component 10 extend towards.

Alternative to the protuberance 602 is z. B. a separate sleeve (z. B. stub tube, etc.) that can be mounted on the hollow body is possible. Such a sleeve can, for. B. like one with reference to the 13A and 3B be formed sleeve described.

7th shows a vertical section through two hollow bodies 100 before completion of the component 10 .

A hollow body 100 can at least one adjustment device 603 have to allow fluid flow through it through the protuberance 602 extending cavity opening 2 to control. However, one or more other of the in 7th cavity openings shown 2 with an adjustment device 603 be equipped.

The in 7th left hollow body 100 includes three cavity openings 2 , where the in 7th right hollow body 100 two cavity openings 2 includes.

The adjustment device 603 can e.g. B. can be set manually and / or remotely controlled. You can z. B. a flap, a lamellar mechanism, a sliding mechanism, etc., to allow a fluid flow (z. B. gas and / or liquid) through the cavity opening 2 to be able to control, e.g. B. to prevent a fluid flow, to enable a fluid flow and / or to change the quantity (to be regulated appropriately).

The adjustment device 603 is z. B. within the hollow body 100 arranged, with embodiments outside the hollow body 100 possible are. In the context of the invention, the adjusting device 603 also z. B. comprise a fan.

As already explained above, through the protuberance 602 extending cavity opening 2 after completion of the component 10 Gas, preferably air, e.g. B. tempered air and / or fresh air, into the outside 701 of the component 10 introduced or removed from it.

The gas can in this case from the system of cavities that are fluidically connected to one another 1 of the component 10 flow in. The gas can e.g. B. also elsewhere with overpressure in the system of the fluidically connected cavities 1 be introduced so that it is attached to the protuberance 602 extending cavity opening 2 can flow out.

However, as already mentioned, it is possible to use gas, preferably air, e.g. B. used room air and / or smoke gases, from the outside 701 of the component 10 by means of the protrusion 602 extending cavity opening 2 and the system of cavities fluidly connected to one another 1 to remove, especially suction.

The cavity openings 2 can also be beneficial for the management of in 7th Installation lines not shown, such as electrical lines, data cables, control lines, water or sprinkler lines, etc., can be used.

8th shows a vertical section through a hollow body 100 .

The cavity 1 includes a cavity opening 2 and a textured inner surface 802 to achieve a sound absorbing effect. The cavity opening 2 can thus also be used advantageously to achieve a sound-absorbing effect.

9 shows a vertical section through a hollow body 100 .

The individual cavities 1 have a cavity opening 2 and are designed in the form of a Helmholtz resonator in order to achieve a sound-absorbing effect. The Helmholtz resonators can be designed essentially identically or differently (e.g. differently sized and / or with different geometries).

10 shows a perspective view of a hollow body 100 with foot elements 101 and a fastener 103 .

A shear plug 901 made of a suitable metal, preferably reinforcing steel, essentially has a U-shape. The two free ends of the longitudinal legs of the shear anchor 901 can each e.g. B. a thickening 903 have, by means of which tensile forces in the longitudinal legs in the later to be introduced, the component 10 constituent material, but in particular through this also on the upper reinforcement 205 can be debited.

The shear plug 901 can with the hollow body 100 by means of the fastening means 103 be firmly connected. The fastener 103 can be made of mineral material, but also z. B. a separate fastening means made of metal or plastic. It can, for example, consist of a metallic one with the hollow body 100 firmly connected bracket or other fixation exist. But it can also be made of mineral material and thus of the same building material as the hollow body 100 be formed, with z. B. the longitudinal leg of the shear anchor 901 in the hollow body 100 and in particular in the fastener 103 can be embedded and at least partially enclosed by it. This can e.g. B. be made possible by the shear plug 901 already in the form of manufacture of the hollow body 100 is inserted.

The upwardly open U-shaped geometry of the shear anchor 901 allows the simple insertion of a lower reinforcement 202 and / or a reinforcement running obliquely or curved in the vertical plane from above. Because the thickenings 903 preferably always above the upper reinforcement layer 205 The installation of an upper layer of reinforcement is also necessary 205 possible without any problems. The thickening 903 is z. B. by upsetting the free bracket ends during the production of the shear anchor 901 causes. Alternatively, other possibilities of a thickening, for example the pressing on of suitably shaped sleeves or the screwing on of nuts or comparable elements, are possible. The shear plug 901 can alternatively not in U-shape, but as a single rod-shaped element with z. B. above and / or below attached thickenings 903 are executed.

11th shows a perspective view of a hollow body 100 with shear reinforcement 204 and fasteners 103 .

On at least one of the four sides of the hollow body 100 fixed shear reinforcement 204 serves to absorb and transfer any shear and / or transverse forces that may have to be transferred within the component 10 .

The shear reinforcement 204 can by means of a z. B. separate fastening means fixed to the hollow body 100 be connected, e.g. B. as with reference to FIG 10 described. The fastener 103 can consist, for example, of a metallic clamp firmly connected to the hollow body or some other fixation. But it can also be made of mineral material and thus the same building material as the hollow body 100 be trained. In this case the shear reinforcement is 204 already in the form of manufacture of the hollow body 100 to insert.

12A shows a plan view with the upper side of a hollow body omitted 100 and 12B shows a vertical section along line AA of FIG 12A .

the 12A and 12B illustrate a possible embodiment for a hollow body 100 with a load anchor 1103 , especially heavy duty anchors. Hollow body 100 with load anchors are used in particular, where a later absorption of trailer loads on the component 10 is required.

The hollow body 100 can be equipped with one or more heavy-duty dowels. The hollow body 100 has a itself in and / or through the cavity 1 extending reinforcement structure, e.g. B. two vertical bars 1101 and 1102 . The heavy duty anchor 1103 is located in the line of intersection of the system levels of the webs 1101 and 1102 . The heavy duty anchor 1103 has at its upper end a suitable anchoring element, for example a thickening z. B. in the form of an upsetting, e.g. B. similar to with reference to the shear anchor 901 explained. At its lower end is the heavy duty anchor 1103 with a screw-in sleeve 1104 or another device.

13A shows an exploded view of a coupling structure, in particular for the fluidic connection of the cavity openings 2 of two neighboring hollow bodies 100 . 13B shows the coupling structure in the assembled state. the 13A and 13B illustrate a z. B. already in the 5 and 7th Visible connection of the cavities 1 of two hollow bodies 100 .

To form the fluidic connection, two sleeves that can be pushed into one another are used in particular 1201 and 1203 used, preferably by z. B. a coil spring 1205 or some other device that can be held together or that can simply be snapped tightly into one another.

The pods 1201 and 1203 can e.g. B. be formed from particularly high-strength mineral mortar. You can e.g. B. be made with a suitable formwork in a casting process.

The pods 1201 and 1203 each include a z. B. formed as a brim projection 1202 and 1204 for resting, in particular for pressing, on the associated hollow body 100 .

For installation or assembly, the spiral spring can be used in a first step 1205 on the longer shaft of the sleeve 1203 be pushed. In a second step, this shaft can be inserted into the longer part of the sleeve 1201 be inserted to thereby form a coupling device. By pressing the two sleeves together 1201 and 1203 and thus tensioning the spiral spring 1205 the coupling device can be inserted into the gap between the two hollow bodies to be connected 100 inserted and positioned. When the pressure is released when the coupling device is compressed, the coupling device expands and slides into the openings in the hollow body provided for this purpose 100 .

Alternative to the sleeves 1201 and 1203 is it z. B. possible on the hollow bodies 100 z. B. one-piece-integrally formed protuberances to be coupled together, z. B. to slide into each other. Such protuberances can such. B. with reference to the 6th be designed as described.

14th shows a sectional view of a detail of a component 10 with a large number of different hollow bodies, for example 100 .

The component 10 is a gradient component, in particular a meso gradient component, its graduation through the cavities 1 and the hollow body 100 is formed. The cavities 1 preferably have an order of magnitude of 10mm to 250mm.

The hollow body 100 represent displacement bodies and are one of the components 10 forming mineral material M. enclosed on all sides in the component 10 integrated, with z. B. foot elements 101 and cavity openings 2 (z. B. sleeves and / or protuberances) z. B. up to the component surface 11th (functional outside 701 of the component 10 ) can extend and thus z. B. not from which the component 10 forming material M. are covered and / or enclosed on all sides.

The component 10 is exemplary as a horizontal component such. B. a building ceiling or a building floor is shown, with z. B. vertically, obliquely or arcuately aligned components such. B. building walls or bar-shaped components are possible.

In 14th are the foot elements 101 of the individual hollow bodies 100 oriented downwards, if the component is oriented differently 10 but also z. B. be aligned upwards.

15th shows a sectional view of a detail of a component 10 with a large number of different hollow bodies, for example 100 .

15th shows a vertically aligned component 10 such as B. a building wall.

In 15th are the foot elements 101 of the individual hollow bodies 100 laterally aligned.

Depending on the orientation of the component 10 (z. B. horizontal, vertical, inclined or arched course), embodiments are possible in which the foot elements 101 do not necessarily have to be aligned downwards, but z. B. can be aligned upwards or to the side (z. B. horizontally or at an angle).

The invention is not restricted to the preferred exemplary embodiments described above. Rather, a large number of variants and modifications are possible which also make use of the inventive concept and therefore fall within the scope of protection. In addition, the invention also claims protection for the subject matter and the features of the subclaims regardless of the features and claims referred to.

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

• DE 202006002540 U1 [0003, 0004]
• DE 102011102337 A1 [0005]
• EP 1718814 A1 [0007]

Claims (30)

Hollow body (100) with at least one cavity (1) for integration in a component (10), preferably a gradient component, the hollow body (100) being formed from a mineral material, characterized in that the hollow body (100) has at least one foot element (101) and the at least one foot element (101) protrudes from the hollow body (100) and preferably forms a spacer and / or serves to erect the hollow body (100). Hollow body (100) after Claim 1 , characterized in that the at least one foot element (101) protrudes from the hollow body (100) below and / or laterally and forms a lower and / or lateral spacer. Hollow body (100) after Claim 1 or 2 , characterized in that the hollow body (100) has at least one fastening means (103) for fastening a reinforcement (204, 205). Hollow body (100) according to one of the preceding claims, characterized in that the at least one foot element (101) has at least one fastening device for fastening a reinforcement (202, 204) and the fastening device is preferably designed to be spaced apart from the reinforcement (202, 204) to attach from the hollow body (100). Hollow body (100) according to one of the preceding claims, characterized in that the hollow body (105) has at least one base (105) which is preferably formed on the top of the hollow body (100) and / or for engagement with at least one foot element (101 ) is trained. Hollow body (100) according to one of the Claims 3 until 5 , characterized in that - at least one fastening means (103) is formed on at least one side surface of the hollow body (100), and / or - at least one fastening means (103) is formed on an upper side of the hollow body (100), and / or - at least a fastening means (103) is formed on an underside of the hollow body (100). Hollow body (100) according to one of the Claims 3 until 6th , characterized in that at least one fastening means (103) is designed to fasten the reinforcement (204, 205) at a distance from the hollow body (100). Hollow body (100) according to one of the preceding claims, characterized in that the hollow body (100) has a hollow body wall structure which forms a hollow body shell and encloses the at least one cavity (1) on all sides. Hollow body (100) according to one of the preceding claims, characterized in that the hollow body (100) has at least one, at least two or at least three cavity openings (2), preferably at least one inlet and at least one outlet, in order to flow through the at least one cavity ( 1) to enable. Hollow body (100) after Claim 9 , characterized in that - the at least one cavity opening (2) opens transversely into the at least one cavity (1), - an opening or passage cross section of the at least one cavity (1) is at least twice as large as a passage cross section of the at least one cavity opening ( 2), and / or - the at least one cavity opening (2) is formed in the hollow body wall structure. Hollow body (100) after Claim 9 or 10 , characterized in that at least one cavity opening (2) - is formed on an upper side of the hollow body (100), - is formed on an underside of the hollow body (100), and / or - is formed on at least one side surface of the hollow body (100) . Hollow body (100) according to one of the Claims 9 until 11th , characterized in that at least one cavity opening (2) extends through a protuberance (602) and / or sleeve (1201) protruding from the hollow body (100). Hollow body (100) after Claim 12 , characterized in that the protuberance (602) and / or the sleeve (1201) is formed from mineral material. Hollow body (100) after Claim 12 or 13th , characterized in that - the protuberance (602) is formed in one piece and integrally on the hollow body (100), and / or - the sleeve (1201) is mounted as a separate component on the hollow body (100) and preferably has a projection (1202) for Has contact with the hollow body (100). Hollow body (100) according to one of the Claims 9 until 14th , characterized in that the hollow body (100) has at least one adjusting device (603) in order to control a fluid flow through at least one cavity opening (2). Hollow body (100) according to one of the preceding claims, characterized in that at least one cavity (1) is designed in the form of a Helmholtz resonator and / or has a structured inner surface (802). Hollow body (100) according to one of the preceding claims, characterized in that the at least one foot element (101), the at least one fastening means (103) and / or the at least one base (105) is formed in one piece and integrally on the hollow body (100) and / or is made of mineral material. Hollow body (100) according to one of the preceding claims, characterized in that the hollow body (100) forms an in particular prefabricated module together with reinforcement attached to at least one foot element (101) and / or with reinforcement attached to at least one attachment means (103) . Hollow body (100) according to one of the preceding claims, characterized in that - at least one foot element (101) and / or at least one fastening means (103) fasten a shear reinforcement (204) and / or a shear plug (901), and / or - in a load anchor (1103) is integrated into the hollow body (100). Hollow body (100) according to one of the preceding claims, characterized in that - the hollow body (100) is designed in the shape of a hollow box, and / or - the hollow body (100) and / or the cavity (1) has a cuboid or prismatic basic shape. Component (10), preferably gradient component, with a plurality of hollow bodies (100) integrated into the component (10), the individual hollow bodies (100) being made of mineral material, having at least one cavity (1) and according to one of the preceding claims are formed. Component (10) after Claim 21 , characterized in that the individual hollow bodies (100) have at least two hollow space openings (2) and the hollow spaces (1) are fluidically connected to one another via the hollow space openings (2), preferably to allow a fluid to flow through the hollow spaces (1). Component (10) after Claim 21 or 22nd , characterized in that at least one hollow body (100) has at least one cavity opening (2) opening towards the outside (701) of the component (10), preferably to allow a gas to flow out of the component (10) and / or to transport a To enable gas via the component (10). Component (10) according to one of the Claims 21 until 23 , characterized in that the component (10) is formed by the fluidically interconnected cavities (1) for building interior temperature control, building interior ventilation and / or building interior ventilation and / or a building wall, building ceiling or forms a building floor. Component (10) according to one of the Claims 21 until 24 , characterized in that the component (10) - is a gradient component, the gradation of which is formed by the cavities (1) and / or the hollow bodies (100), and / or - forms a gradient concrete component or meso gradient concrete component. Component (10) according to one of the Claims 21 until 25th , characterized in that the cavities (1) of the individual hollow bodies (100) are of different sizes and / or have a size of 10mm to 250mm, preferably 75mm to 250mm. Component (10) according to one of the Claims 21 until 26th , characterized in that - hollow bodies (100) are arranged one above the other and next to one another, and / or - adjacent hollow bodies (100) are in engagement with one another, preferably by means of the foot elements (101) and / or the base (105). Component (10) according to one of the Claims 21 until 27 , characterized in that the hollow bodies (100) are distributed in at least two or three spatial directions and / or are brought into engagement with one another. Component (10) according to one of the Claims 21 until 28 , characterized in that the hollow bodies (100) are enclosed on all sides by a mineral material (M) forming the component (10) and integrated in the component (10) and / or an intermediate space (S) between the foot elements (101) of the individual hollow bodies (100) is filled by a mineral material (M) forming the component (10). Component (10) according to one of the Claims 21 until 29 , characterized in that the at least one foot element (101) of the individual hollow bodies (100) extends up to the component surface (11) and / or is oriented downwards, upwards or to the side.

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