AT18344U1 - flat building element - Google Patents

Abstract

The present invention relates to a flat construction element in which an insulating core and two cover layers are connected to one another in a shear-resistant manner, and at least one cover layer is formed from a profiled metal sheet. In order to provide a flat construction element (1) that can be used or installed as an outer shell, external, internal or apartment partition wall or also as a ceiling element, with further improved properties, it is proposed that the profiled metal sheet (6) has an approximately omega-shaped groove (9), wherein the approximately omega-shaped groove (9) is designed to receive and automatically fix a pipe (10, 11).

Description

Description

FLAT COMPONENT

[0001] The present invention relates to a flat structural element in which an insulating core and two cover layers are connected to one another in a shear-resistant manner, and at least one cover layer is formed from a profiled metal sheet.

[0002] Such flat building elements are known for applications in the renovation, extension or construction of houses and halls. They are characterized by low weight, good processability, high durability and reliability even under mechanical stress, as well as good thermal insulation.

[0003] Currently, numerous approaches are being pursued to operate a more effective energy management with the aim of energy optimization via the outer shell of a building. To this end, a new outer facade is constructed with comparatively little effort, using flat building elements, among other things, through which the outer walls of a building can be heated or cooled. To this end, a thermal insulation composite system can be connected directly to the outer facade of the building in question as the outer shell, or alternatively an outer shell can be designed as a ventilated facade. Such a measure can be carried out not only on new buildings, but also on existing buildings in the course of renovation or refurbishment, and is characterized by a comparatively low impairment of the use of the respective interior rooms during construction, so that uninterrupted use or even occupation of the rooms in question is possible even during such a construction project. In addition to the construction of thermal insulation, the construction of a new outer shell also offers the possibility of optimizing a building in question not only with regard to its energy requirements, but also of creating thermal insulation with additional functions, for example by having the new outer shell take on the functions of energy storage, energy distribution and/or central energy management under the control of integrated sensors. The energy efficiency of a building is increased while effectively reducing CO2 emissions caused by heating and/or cooling. Such facades also serve to protect against external influences, particularly the climate, limit heat transfer, provide a long-lasting external appearance and increase the technical functionality of the building shell.

[0004] Flat building elements are also used as prefabricated elements and are delivered to the respective construction site in a factory, protected from the effects of weather and seasons. On the construction site, flat prefabricated elements are directly assembled as ready-to-install external, internal or apartment partition walls or as roof elements. In a very short time, an extension within an existing building can be realized using dry construction methods, an extension or even the construction of an entire building in the form of a house or a hall on a prepared substructure or foundation.

[0005] Hybrid or composite panels used in construction with two thin metallic cover layers connected to one another in a shear-resistant manner via an insulating core for heat and sound insulation are referred to as sandwich elements or sandwich panels. Instead of a metallic layer, a plastic layer that is mechanically resilient and permanently stable against climatic influences is also used. The thickness of sheets made of steel or aluminum is between 0.5 and 1.5 mm. The shear-resistant insulating core consists of polyurethane foam, natural fiber or mineral wool, for example, and forms a bond with the cover layers by adhesion or bonding, which is characterized by a high load-bearing capacity and great mechanical rigidity with high insulation values and high fire resistance despite its low weight. Sandwich panels can now be designed in such a way that they can also be used as a self-supporting building envelope and thus without a mechanical or static substructure.

[0006] DE 10 2007 028 451 A1 discloses an arrangement of trapezoidal sheets between which an insulation layer is arranged. A trapezoidal sheet is provided with approximately omega-shaped grooves

for the fixing of air conditioning pipes.

[0007] EP 2 169 316 A2 discloses a multi-layered heat conducting plate for heating or cooling buildings with meandering channels for accommodating pipes on a thermally insulating back. Head parts with deflection channels and straight connecting channels are provided, for example, for connection to the flow and return lines.

[0008] The present invention has the object of providing a flat building element which can be used or mounted as an outer shell, external, internal or apartment partition wall or also as a ceiling element, with further improved properties.

[0009] This object is achieved according to the invention by the features of claim 1. Accordingly, a flat component according to the invention has an approximately omega-shaped groove on a profiled metal sheet, which is designed to receive and automatically fix a pipe, wherein the profiled metal sheet adjoins the approximately omega-shaped groove and runs into flat side surfaces that form a plane that is lowered by the depth of the groove. A flat component represents a stable component that can be easily fixed using known measures and is optimally prepared at an installation location by this groove, for example to receive a pipe as part of a heating and/or cooling installation directed towards an interior. The insulation core serves as thermal insulation in the opposite direction. A flat component according to the invention therefore has improved properties compared to known devices. The profiled metal sheet adjoins the approximately omega-shaped groove and runs into flat side surfaces, wherein these side surfaces form a plane. At one end of each parallel section of a continuous, meandering course of the air conditioning pipe, an area is provided adjacent to a groove in which the pipe is arranged in an arc shape in order to repeatedly equip grooves adjacent to one another with a pipe in a meandering course after completion of a structure in an insert until a predetermined surface or level is filled to achieve a planned heating and/or cooling output. Automatic fixation of the air conditioning pipe in the profiled metal sheet of the flat component in the area of the approximately omega-shaped, spring-elastic clamping receptacle of the groove is always sufficient to ensure a defined, secure and permanent receptacle of an air conditioning pipe with good thermal contact with the metal sheet. Fixation in the area of this flat side surface is therefore generally not required.

[0010] Advantageous further developments of the invention are the subject of the dependent claims. Accordingly, the profiled metal sheet has several grooves running parallel to one another at a distance. This means that several and also different types of pipes etc. can be fixedly arranged therein, increasing the mechanical rigidity of the flat component. The grooves and the pipes or other devices fixed therein are advantageously used independently of one another. Accordingly, adjacent grooves can, for example, fulfill heating or cooling tasks by carrying pipe sections connected to one another or a one-piece continuous air conditioning pipe in a meandering course, but mixed use of these grooves is also possible and can be planned in advance, as shown below using exemplary embodiments according to the invention.

[0011] The profiled metal sheet is particularly preferably designed as a surface of the flat component that is oriented towards an interior in a final installation position. When using a pipe inserted in a groove of the profiled metal sheet as part of a heating and/or cooling device, the profiled metal sheet also serves as a heat conducting profile oriented towards an interior and thus increases the thermal effect of the pipe used as a climate pipe. In contrast, for example, when installing wall heating, corresponding recesses and/or grooves are usually only made on site in a flat component. Meandering pipes with sections that run parallel to one another are then laid in this recess and fixed by additional elements, whereby the pipes are equipped with so-called climate plates to increase thermal efficiency. Retaining strips etc. used in known solutions and which have to be fixed separately to the flat component are time-consuming and, as a result, due to the use of retaining strips as additional individual

parts are also cost-intensive. Due to an approximately omega-shaped groove in the profiled metal sheet that is already provided at the factory in a final installation position oriented towards an interior, climate panels and retaining strips are advantageously already functionally present in a flat structural element according to the invention. As shown below using an exemplary embodiment, such a groove is designed to accommodate a heating and/or cooling device, or also for water, power or data lines, etc. This significantly reduces assembly time when installing and removing a flat structural element of the type mentioned on site at a respective construction site with subsequent installation of pipes, e.g. over a certain area to create surface heating or cooling and their connection. These specifications and optimizations can be implemented excellently in building data modeling with BIM networking from planning to production in the form of a flat prefabricated element according to the present invention.

[0012] Alternatively, a profiled metal sheet is designed and used as a surface of the flat component in a final installation position oriented towards a free outside space so that it is exposed to solar radiation as well as possible. By means of a coating and/or coloring of the profiled metal sheet that strongly absorbs solar radiation, a flat component according to the invention with a pipe laid in the at least one groove can thus be used directly in particular as a solar thermal system.

[0013] In one embodiment of the invention, these flat side surfaces are realized by an adjacent flat component. This means that a climate pipe can be flexibly fixed in the profiled metal sheet itself after completion of the other assembly work, with the length of the climate pipe being freely selectable. For example, in a meandering shape, a climate pipe of any length can be laid over parallel groove sections in the profiled metal sheet to cover any conceivable surface shape.

[0014] In an alternative embodiment of the invention, the profiled metal sheet has an adapted pipe guide bend at one end of each parallel section of a continued, meandering course of the air conditioning pipe, adjacent to these grooves. Here, the pipe is thus guided in a defined manner in continued close contact with the material of the metal sheet, so that in particular a minimum bending radius of the air conditioning pipe is always reliably maintained in an advantageous manner. This section with pipe guide bends adapted to the grooves is preferably implemented in the form of a subsequently fixed, separate flat component.

[0015] According to a further development of the invention, the profiled metal sheet has parallel grooves flanking a groove, which are designed as a guide for a loading carriage for pressing a pipe into the relevant groove. The pipe or air conditioning pipe can thus be assembled quickly and safely in a semi-automated manner with a further significantly reduced use of manual labor.

[0016] In an advantageous embodiment of the invention, the profiled metal sheet with at least one approximately omega-shaped groove is the product of a roll forming process. The sections described above at the ends of parallel sections of the grooves are preferably realized by adjacent fixed flat components.

[0017] The flat building element is preferably designed as a self-supporting prefabricated element. It can be used or installed as an external, internal or apartment partition wall or as a roof element and basically does not require any further mechanical or static substructure or auxiliary construction.

[0018] In preferred embodiments of the invention, the pipe is an air conditioning pipe of a heating and/or cooling device, as already explained above. However, the pipe also represents an empty pipe for accommodating electrical cables and/or data lines, or a water pipe, which is preferably part of a fire extinguishing device. The grooves can also be used by means of expansion or clamping pieces fixed therein or thereto, so that, for example, a lamp or a modular lighting and/or supply strip can be suspended from a ceiling element.

is suspended from a flat building element.

[0019] Since the market generally wants individually designed prefabricated houses and tailor-made halls, the degree of standardization for flat prefabricated elements is rather low. A flat building element according to the invention can be optimally adapted to these conditions thanks to its flexible production as a component made of just three layers. Integrated digital planning based on an image of a building to be constructed in the computer now allows so-called building data modeling or building information modeling, abbreviated to BIM. BIM describes a working method for the computer-aided networked planning, construction and subsequent management of buildings and other structures. All relevant building data is digitally modeled, combined with one another and recorded uniformly so that a building can also be geometrically visualized as a virtual model and can also be tested for thermal behavior in simulations. This approach optimizes the entire process chain within the planning and construction of buildings in a location- and time-independent collaboration across all trades, which ensures greater transparency, reliability and efficiency. At the same time, new freedom is created for flexible design, especially in the construction of prefabricated houses, since the effects of changes to plans can now be implemented and shown or visually illustrated in all plans without delay. Based on modeling of a room climate, completely new positions for heating or cooling can be found, which are now preferably realized using specially equipped flat building elements. But even in the course of renovating an old building, it is possible to optimally adapt flat building elements as components of an insulating and additionally heated and/or cooled new outer shell. This means that high savings potential can be tapped during the construction phase through largely waste-free prefabrication on site and very time-efficient, 1st degree dry installation and assembly.

[0020] For reasons of better efficiency and aesthetics, but also to improve the use of space and the room climate, there has been an increasing move away from conventional heating systems using radiators in recent years. Modern heating is increasingly being moved into a wall or ceiling in order to be able to perform both heating and cooling tasks from there. While conventional radiators or heating elements work with convection, i.e. use the air as a medium for heat transport, wall heating systems work with radiant heat. It is not the air that is heated, but the human body or objects in the room in a much more energy-efficient manner. In addition to significantly lower heating costs and more freedom in space planning, even in a hall, other advantages of wall heating are that, compared to radiators, it generates heat that is perceived as more pleasant and comfortable, with significantly less dust being stirred up. These and other advantages can be achieved using a flat component according to the invention.

[0021] Further features and advantages of embodiments according to the invention are explained in more detail below with reference to embodiments of the invention using the drawing. In the drawing, there is shown in a schematic representation:

[0022] Figure 1: a sectional view of an embodiment of a planar component;

[0023] Figure 2: a plan view of the embodiment of Figure 1 of a planar component as part of a composite of several adjacent planar components and

[0024] Figure 3: a sectional view of a known flat construction element in the form of a sandwich panel with a trapezoidally profiled and a flat outer sheet analogous to the representation in Figure 1.

[0025] Throughout the various figures and embodiments, the same reference numerals are used for the same elements. Without limiting the

In order to adapt the invention to this application, only a flat component with a filling made of a foamed plastic with two metallic outer sheets is shown and described in the drawing below. However, those skilled in the art are familiar with adaptations in which an outer layer consists of a non-metallic material that can withstand high mechanical loads, such as a plastic-fiber composite material.

[0026] Figure 3 shows a known flat construction element 1 in the form of a sandwich panel 2. This flat construction element 1 is mechanically designed to be used as an external, internal or apartment partition wall or also as a roof element and to be mounted self-supporting without additional mechanical auxiliary construction. In this flat construction element 1, an insulating core 3 and two cover layers 4, 5 are connected to one another in a shear-resistant manner. One of the cover layers 4, 5 is made of a metal sheet. To increase its inherent rigidity, the metal sheet is profiled trapezoidally as a cover layer 6 and lies on the insulating core 3 opposite a flat cover layer 4 made of a glass fiber reinforced plastic composite, in this example a GRP. Various designs and modifications of this basic principle of a flat construction element 1 in the form of a product range that can be freely selected in terms of length and width over a wide range are known on the market, with both cover layers 4, 5 1.d.R. can be selected and used equally as an outer or inner layer. With adjacent sandwich panels 2, known tongue and groove connections 8 are provided for water- and wind-tight connection as well as mechanically resilient fixing on the edge or on the edge surfaces 7 all around, as only indicated in principle and by way of example in Figure 3.

[0027] In order to increase efficiency when constructing or building a hall or other building, at least with the aim of reducing costs, a flat construction element 1 is described with the aid of the figures described below, which has improved properties regardless of whether it is used on an outer shell, outer wall, as a roof, wall or ceiling part, etc. Figure 1 shows, analogously to Figure 3, a view of a sectional plane of a first embodiment of a flat construction element 1 in the form of a sandwich panel 2, in which an insulating core 3 and two cover layers 4, 5 are connected to one another in a shear-resistant manner and a cover layer 5 is formed from a metal sheet 6. The outer layer is optionally made of metal or GRP. According to the invention, the inner cover layer 5 as a metal sheet 6 has a profile with at least one approximately omega-shaped groove 9. In the section shown, four grooves 9 are outlined, each of which is designed to receive and automatically fix a pipe 10. The design of edge surfaces 7 of a planar component 1 is left to the discretion of the person skilled in the art in accordance with a particular application and is not described further here.

[0028] In the manner indicated in Figure 1, adjacent grooves 9 in the metal sheet can also be used in very different ways. In this embodiment, it is indicated that a groove 9 shown on the very left is equipped with a pipe 10 that is designed as an air conditioning pipe, and in the groove 9 provided on the right, a pipe is provided as an empty pipe 11 for receiving a power supply line 12 and a data line 13. This is followed by a pipe 9 as an extinguishing water line 14, which, in a manner not shown in more detail, directly feeds ceiling sprinklers, for example. Finally, a groove 9 is equipped with an expandable tension anchor 15 in order to suspend supply lines and/or lighting strips from a ceiling, for example. By means of expandable tension anchors 15 or clamping parts inserted into a groove 9, such fixations can be implemented flexibly and even subsequently after completion of a structure without drilling into the flat structural element 1 or otherwise damaging the covering layer 5 made of profiled metal sheet 6.

[0029] Figure 2 shows a plan view of the embodiment of a flat component 1, whereby a sectional view in a plane A-A results in the image of Figure 1. Figure 2 shows two embodiments of installation situations as well as differently profiled metal sheets 6: On the right, the flat component 1 is shown with approximately omega-shaped grooves 9 at a distance d from each other in the inner cover layer 5, which is made of metal sheet. In these grooves 9, parallel sections of a climate tube 10 are arranged, which is arranged in a meandering course across the flat component 1. The profiled metal

The sheet metal 6 runs at edge surfaces 7 into flat side surfaces 16 which are formed adjacent to the approximately omega-shaped grooves 9, wherein these side surfaces 16 form a plane of an adjacent flat structural element 1, 2 which is lowered by a depth t of the groove 9 and on which the arches of the air conditioning pipe 10 arranged in a meandering course while maintaining a minimum radius r rest.

[0030] In contrast, in the left half of Figure 2, a pipe guide bend 17 is provided on an edge surface 7 of the profiled metal sheet 6, continuously at one end of each parallel section of a continuous, meandering course of the air conditioning pipe 10, adjoining the grooves 9. Here too, the pipe guide bends 17 form elements of an adjacent flat component 1, 2. Furthermore, in the left half of Figure 2, guide grooves 18 are provided in the profiled metal sheet 6, flanking each groove 9, which are designed as a guide for a loading carriage for pressing a pipe 10, 11 into the relevant groove 9. These guide grooves 18 are also provided on the pipe guide bends 17 with a continuous course.

[0031] A particular advantage of this flat component 1 described above across the embodiments is that, according to the invention, a degree of prefabrication has been deliberately shifted to a final contour-accurate prefabrication, i.e. to a factory. Here, when manufacturing such flat components 1 in this embodiment, all customer-specific wishes are taken into account with an advantageous connection to a BIM system, so that each flat component 1 delivered to a construction site for direct installation on site not only has a prepared length L and width as well as suitable mechanical connection and sealing systems on the edges, but is also provided with pipes for water, gas and electrical lines etc. as well as empty pipes in the groove recesses after quick and dry installation by hand or semi-mechanically and also has space for a highly efficient and space-saving heating and/or cooling device.

[0032] Thus, over a number of embodiments, a structure of a flat building element 1 with receptacles in the form of flexibly usable grooves 9 that can be quickly and flexibly adapted to changeable technical specifications and/or wishes of building owners has been described, which, among other things, also enables a direct installation of a heating and/or cooling device from a BIM-based planning.

REFERENCE SYMBOL LIST

1 flat component

2 sandwich panels

3 insulation core

4 outer cover layer

5 inner cover layer, metal sheet

6 Top layer, trapezoidal profiled 7 Edge surfaces

8 tongue-and-groove joint

9 groove, approximately omega-shaped

10 pipe / air conditioning pipe

11 Empty pipe for electrical and data installation

12 power supply line

13 data lines

14 (firefighting) water pipe

15 tie rods, expandable in the empty pipe

16 flat side surface on which a bend of the climate tube 10 rests

17 Pipe guide bend for guiding and holding a bend of the climate pipe 10

18 Guide groove for a semi-automated assembly of the groove 9 with a pipe 11 or air conditioning pipe 10

d Minimum distance between adjacent loops of the climate pipe 5

r Minimum radius when forming loops of the climate pipe 10

t Depth of the groove 9 in the component 1

L Length of a planar component 1

Claims (10)

claims 1. Flat structural element (1), in which an insulating core (3) and two cover layers (4, 5) are connected to one another in a shear-resistant manner, and at least one cover layer (4, 5) is formed from a profiled metal sheet (6), a profiled metal sheet (6) having an approximately omega-shaped groove (9), the approximately omega-shaped groove (9) being designed to receive and automatically fix a pipe (10, 11), characterized in that the profiled metal sheet (6) runs adjacent to the approximately omega-shaped groove (9) into flat side surfaces (16) which form a plane lowered by a depth (t) of the groove (9). 2, Flat component (1) according to the preceding claim, characterized in that the profiled metal sheet (6) has a plurality of grooves (9) running parallel to one another at a distance (d). 3. Flat component (1) according to one of the preceding claims, characterized in that the profiled metal sheet (6) is designed as a surface of the flat component (1) oriented towards an interior space (I) in a final installation position. 4. Flat structural element (1) according to one of the preceding claims, characterized in that a profiled metal sheet (6) is designed as a surface of the flat structural element oriented towards a free external space in a final installation position with a pipeline laid in the at least one groove, in particular as a solar thermal system. 5. Flat component (1) according to one of the preceding claims, characterized in that the plane of the side surfaces (16) is realized by an adjacent flat component. 6. Flat structural element (1) according to one of the preceding claims, characterized in that the profiled metal sheet (6) has a pipe guide bend (17) at one end of each parallel section of a continued, meandering course of the air conditioning pipe (10) adjoining the grooves (9), which is preferably realized by an adjacent flat structural element. 7. Flat component (1) according to one of the preceding claims, characterized in that the profiled metal sheet (6) has grooves (18) flanking a groove (9), which are designed as a guide for a loading carriage for pressing a tube (10, 11) into the relevant groove (9). 8. Flat structural element (1) according to one of the preceding claims, characterized in that the profiled metal sheet (6) with at least one approximately omega-shaped groove (9) is the product of a roll forming process. 9. Flat building element (1) according to one of the preceding claims, characterized in that the flat building element (1) is designed as a self-supporting prefabricated element and can be used or mounted as an external, internal or apartment partition wall or also as a roof element. 10. Flat component (1) according to one of the preceding claims, characterized in that the pipe is a climate pipe (10) of a heating and/or cooling device, an empty pipe (11) for receiving electrical cables and/or data lines or a water pipe (14), which is preferably a spacer part of a fire extinguishing device. Here 2 sheets of drawings