FI127308B - balcony Flat - Google Patents

Abstract

Balcony slab (1), for a suspended balcony, which comprises a matrix structure consisting of a filler substance and reinforcing steel, in which there is at least a flat surface, which forms the upper surface of the slab, and an under-surface on the opposite side to the upper surface, and wall brackets (7) for attachment to the wall and suspension points at a distance from these, in which there are tension-rod lugs (5) for suspending the balcony slab. The flat surface of the balcony slab (1) is encircled by an edge (20), which protrudes outwards from the under-surface of the slab, and in its under-surface are at least two cross-wise webs (21), which webs (21) extend over the area on the under surface delimited inside the edge (20) and are oriented outwards. The edges of the balcony slab (1) are encircled by a steel C-profile frame (2), in which the opening of the C of the profile faces in the direction of the centre of the balcony slab (1), and which forms, together with the filler substance, the edge (20) of the balcony slab (1). The tension-rod lugs (5) of the balcony slab (1) are joined by a reinforcing profile and its steel components are of stainless steel.

Description

(54) Name of the invention - Uppfinningens benämning

The balcony slab

Balkongsplatta (56) References - Anförda publikationer

WO 2007006872 A1, FR 3011565 A1, FR 2881153 A1, SE 469180 B, US 4942707 A, US 3918222 A, EP 0089324 A2, Fl 20145444 A (57) Abstract - Sammandrag

Balcony tile (1), for hanging balcony, comprising a matrix structure of filler and reinforcing steels having at least a planar surface, forming a top surface and a lower surface opposite to the top surface, and wall brackets (7) for wall mounting, with hanging anchors (5) for hanging balcony tile. The plane surface of the balcony tile (1) is rotated by a rim (20) extending outwardly from the lower surface of the tile and having at least two crosswise webs (21) extending over the area defined by the rim (20) in the lower surface and outwardly. The edges of the balcony tile (1) are rotated by a steel C-profile frame (2), in which the opening of the profile C is directed towards the center of the balcony tile (1) and together with the filler forms the rim (20) of the balcony tile. The tension rod brackets (5) of the balcony slab (1) are connected by a connecting reinforcement profile and its steel parts are made of stainless steel.

Balkongplatta (1) avsedd för en upphängningsbar balkong, vilken balkongplatta om-fattar en av fyllmedel och armeringsstäl bestäende matriskonstruktion med ätminstone en planyta, som bildar plattans övre yta, och en päsatta sidan av den övre ytan under ) förfästning vid väggen och Päts avständ frän dessa belägna upphängningspunkter, lively uppvisar dragstängsutspräng (5) för upphängning av balkongplattan. Balkongplattans (1) planyta omges av en kant (20), blazing sträcker sig frän plattans underyta utät och dess underyta uppvisar ätminstone tv corsvisa balk-liv (21), blazing balkliv (21) sträckersig i underytan över det av kanten (20) omslutande avgränsade omrädet och riktar sig utät. Balkongplattans (1) country omger en C-profile (2) av stäl, där öppningen hos Profilen C rictad i riktningen för balkongplattans (1) nonpartisan and som tillsammans med fyllmedlet bildar balkongplattans (1). Balkongplattans (1) dragstängsutspräng (5) förenande armerings-profil och dess stäldelar utgörs av rostfritt stäl.

The balcony slab

Field of the Invention

The invention relates to a load-bearing reinforced concrete slab for a suspended balcony.

In particular, the invention relates to a structure made of steel and concrete for forming a suspended balcony.

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background

A variety of concrete slab structures can be used to form subfloors, floors, balconies and other structures that require a load-bearing structure over a specified span. Concrete slabs are usually used with steel reinforcements and their mass can be reduced by various cavities or rib and web structures. The tiles are usually manufactured in prefabricated factories either to standard dimensions or, if required, to the customer's desired dimension. The use of concrete slab structures is well known in the art.

Hanging balconies are balconies hanging from the frame of the building with drawbars. Suspension can also be made from load-bearing partition walls with load-bearing ceilings.

The benefits of a suspended balcony include the fact that balconies can be placed more freely, even individual balconies on the façade are possible. Also, the balconies supported by the layers do not cause any force due to the heat movements.

0 Suspended balcony systems are also available in fiber-reinforced concrete solutions that have reduced the weight of the balcony by utilizing fiber-concrete.

The hanging bar can be inside or outside the balcony. The use of external drawbars may be mainly restricted by city-like factors. Stainless steel rods should be used as pull bars, whereby sufficient can be achieved

5 fire resistance without separate fire protection. The drawbar solutions are usually made of ready drawbar systems or solutions for standard balcony systems.

The drawbars are fastened, for example, to a steel profile in the slab (e.g. a square tube) with ready-made fastening elements for the drawbar. The drawbar is anchored to the load-bearing frame of the building (either to the load-bearing partitions, to the load-bearing outer casing or to the floor), or

0 separately for carrying case.

The rear edge of the balcony slab is supported on the building frame or load-bearing exterior by steel parts. The simplest solution for a concrete balcony slab is the steel profile at the back of the slab, which is supported on the midsole. When using load-bearing brackets for hanging, they should be supported by hanging from load-bearing partitions with steel parts. The steels passing through the thermal insulation must be stainless.

Balcony slabs and similar concrete structures are disclosed in WO 2007006872, FR 3011565, FR 2881153, SE 469180, US 4942707, US 3918222 and EP 0089324.

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Summary of the Invention

Traditional reinforced concrete slab structures are quite massive. As a result, they are highly consumable, expensive to transport, and require efficient transfer equipment to move and install slabs on site. Solid and heavy tile support and support structures must also be robust. These features are emphasized in the exterior structures such as balconies.

For the reasons mentioned above, it would be advantageous to provide a lighter tile solution.

The invention relates to a reinforced concrete slab to form a hanging balcony.

Other features and embodiments of the invention provide a balcony in which an air heating duct or other heating system can be integrated.

According to one embodiment of the invention, there is provided a balcony slab, which is integrated in the insulating plate, the insulating plate forms a bottom side of the form.

According to one aspect of the invention, there is provided a composite composite slab of steel profiles, reinforcement and concrete, which can be used to form a lightweight hanging balcony structure 20 or similar supporting structure forming a load-bearing plane.

The invention is based on the fact that the slab forming the balcony floor is concrete or other aggregate and comprises at least a planar surface which forms the upper surface of the slab and a lower surface on the opposite side of the upper surface and a peripheral surface extending outward from the slab. The underside of the tile has at least two crosswise webs extending

5 on the underside over the area enclosed by the rim and facing outwards. The edge of the tile is rotated by an inwardly directed C-profile frame, which together with the filler forms a transverse reinforcement profile between the edge of the balcony tile and the tile hanging points, to which the hanging points are attached. The reinforcement of the balcony slab is made of stainless steel.

According to one embodiment of the invention, a reinforcement reinforcement is provided inside the C-profile frame having at least one reinforcing steel disposed in the region of the at least one C-profile flange.

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According to one embodiment of the invention, the reinforcing steel fitted to the flange area of the C-profile has at least one bracket and this bracket is also connected to the C-profile to form an anchorage point for railing posts or other balcony equipment.

In one embodiment of the invention, the transverse reinforcement profile is a lattice structure.

According to one embodiment of the invention, at least one side of the C-profile profile orbiting the slab edge has openings for feeding concrete into the profile through these openings.

According to one embodiment of the invention, the openings in the C-profile ring are on the edge of the balcony slab facing the wall of the building.

According to one embodiment of the invention, the wall-to-wall fixing brackets of the balcony slab are secured to the reinforcement structure inside the C-profile.

The balcony tile can be made by a method of producing tile reinforcement which is fitted inside a C-profile frame. The C-profile frame is formed with openings on one side for feeding the concrete mass inside the frame and the open sides of the frame are closed with a planar mold plate and a molded forming mold on the opposite side thereof and the concrete is poured from the C-profile frame side openings to fill the mold.

Several molds can be placed facing each other, whereby the C-profile openings are positioned upwards and several molds are filled at the same time.

Significant advantages are achieved with the various embodiments of the invention.

A grate-type stainless steel (SST) reinforced molded balcony achieves a structural load of less than 2 kN / m2 plus the required minimum utility load of the balcony of 2.5 kN / m2. Reducing the total load is important for wall-mountable brackets. Stainless steel reinforcement

5, the required casting thickness is lower than that of conventional structural steels used for reinforcement. Stainless steel has a protective thickness of at least 10 mm or reinforcement diameter when casting concrete. This reduces the amount of concrete required, thus reducing the load on the building wall. Instead of concrete, lightweight concrete with at least some aggregate may also be used as the pouring mass

0 replaced with eg EPS or foam glass filler and / or fiber reinforcement. Substances other than concrete as binder may also be used in the grout. In addition, stainless steel reinforcement retains its strength significantly better than structural steels (eg A500HW) in case of fire.

Stainless steel C-profile at the edge of the balcony slab has both an aesthetic role (resistant to environmental stress 3), fire resistance, structural strength, simplifying railing attachment, facilitating installation time and reducing on-site work. The C profile is made of 1.5 -4.0 mm stainless steel plate and stainless steel reinforcement according to dimensioning.

The combination of stainless steel and concrete is flexible for a variety of architectural 5 balcony structures such as aesthetic railing and glazing solutions. The balustrade elements can also be made to warm the balcony.

The stainless steel reinforced concrete grate structure is durable and non-flammable and does not have any fire problems such as wood, plastic or aluminum decking and mats. The structure is weatherproof and maintenance free.

Other objects and features of the invention will be described in the following detailed description with reference to the accompanying drawings. It is to be understood that the description of the purpose of the drawings and of the invention is merely illustrative and not a limitation of the invention. For the purpose of defining the invention, please refer to the claims.

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Explanation of the figures

Figure 1 shows a balcony slab according to the invention with railing posts and fasteners.

Figure 2 is a detail of the steel structure of the balcony slab of Figure 1.

Figure 3 shows the reinforcement reinforcement and C-profile frame of the balcony slab of Figure 1.

Fig. 4 shows the reinforcement reinforcement and C-profile frame of the balcony slab of Fig. 1, as well as the surface grid of the slab 20 0.

Figure 5 shows one embodiment of reinforcement reinforcement of a balcony slab.

Figures 6 and 7 show some details of the invention.

Figure 8 schematically shows a balcony slab in the direction of its underside.

Figure 9 is a cross-sectional view of one of the balcony slabs of the invention.

Figure 10 is a cross-sectional view of a slab according to another invention.

Figure 11 shows the balcony slab of Figure 1 in another direction.

Figure 12 shows a balcony floor according to the invention, the steel structure and the molds used for the preparation of the surface and the underside.

Figure 13 shows an alternative mold used in the manufacture of the lower side.

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Detailed Description of the Invention

For the purposes of this application, stainless steel means alloys that are standard stainless steel.

For the purposes of this application, a profile is defined as a shaped profile whose cross section differs from a solid bar such as a flat bar, a square bar or a round bar.

Figures 1 and 3 show a balcony tile 1 having a planar upper surface 2 for forming a floor level and a lower surface 3. The periphery of the tile 1 is rotated by a C-profile frame 2 with the C opening of the profile facing inward, i.e. towards the center of the tile. The flanges of the profile 2 form the upper and lower surfaces of the edge of the balcony slab 1. The upper flange of the C-profile frame 2 is provided with brackets for railing posts 4 or other balcony fittings. In addition, the balcony tile 1 has tension rod brackets 5 for balcony tension rods 6 and wall brackets 7 for wall mounting. A loop of the drawbar 6 is mounted on the drawbar lugs 5 and the nut is secured to keep the loop in place. The wall bracket 7 has a slot 10 which is mounted on the counter part of the bracket anchored to the wall of the building.

Figure 2 illustrates the steel structure of a balcony slab. This figure shows the reinforcement reinforcement of the balcony slab 1 (Fig. 5) and part of the C-profile frame 2. The profile steel 8 to be installed towards the wall of the C-profile 2 has evenly spaced openings 9. The purpose of these openings is

0 period. The number or shape of the openings 9 is otherwise not limited provided that their surface and position in the wall-mounted profile steel 8 is such that the concrete mass can be fed into the molded C-profile frame 2. The apertures 9 are preferably directed toward the wall for appearance reasons. The figure also shows that the C profile is partially closed, i.e. the flanges of the profile pivot about their edges towards the center line of the profile.

The reinforcement reinforcement consists of two superimposed transverse reinforcing rings 10, Ilya and transverse reinforcements 12 formed by straight steels 11, 12. The transverse reinforcements 13 are placed at the web locations of the balcony slab. The distance between the webs is preferably dimensioned such that a fire door or other necessary throughput is provided between them. In addition, reinforcement reinforcement is provided between the hanging points of the balcony slab

In this embodiment, the reinforcing grid consists of two reinforcing steel bars 15 at the bottom of the grid, a bar 16 at the upper edge and transverse rests 17 connecting them. is fitted to the holes formed in the flanges of the C-profile ring so that they form anchorage points for attaching handrail tops or other equipment. By adjusting the length of the threaded sleeves 18, the distance between the upper surface and the lower surface of the reinforcing grid from the upper surfaces of the flanges of the C-profile frame can be adjusted.

20155600 prh 05 -02-2018 thus also filling the frame with casting surfaces. The wall bracket 7 is attached to the reinforcement reinforcement and to the profile steel 8 against the wall.

Figure 3 illustrates a C-profile frame 2 mounted around a reinforcing grid and Figure 4 illustrates the entire steel deck of the balcony slab. A reinforcing mesh 19 is provided on the upper surface of the balcony slab to provide the necessary strength of the upper surface of the slab. Figures 3 and 4 show the location of the hanging points of the balcony slab, i.e. the tension rod lugs 5 and the wall brackets 7, and their alignment with the C-profile frame 2.

In the steel structure of the balcony slab, there is a truss bar, reinforcing lattice 14, in the attachment line of the pull rods 6, to which the lugs 5 of the pull rods 6 are welded. At the top and bottom of the structure are rectangular reinforcing rings 11, 12, on which threaded sleeves 18 are welded, which may be for example female threaded sleeves (e.g. M12-M16). Other reinforcement is welded to these reinforcing frames 11, 12. The transverse reinforcement of the lower surface is mounted under the lower surface of the webs. The reinforcement of the upper surface (parallel to the mounting line of the drawbars 6) is installed in accordance with the slope of the balcony floor. The wall mounting plates are welded between the aforementioned 15 J reinforcement rings 11.12.

The C-profile frame 2 has holes / openings at the lugs 5 of the tension rods 6, the wall clips 7 and the drain holes 9. The steel structure to be installed inside the C-profile frame 2 is fastened through said holes with bolts to the threaded bushes 18. This ensures that the structure remains firmly in place even during casting. The C-profile frame 2 acts as a frame

0 when reinforcing reinforcement is installed, the wall tile clips 7 and the threaded bushings 18 of the balustrade posts are precisely aligned before being welded. The C-profile frame 2 acts as a mold for producing a surface for vertical casting and as a decorative and load-bearing element for environmental protection. In addition, the stainless steel C-profile frame 2 (1.4301, 14310 or equivalent) improves the fire resistance of the structure. The C-shaped steel 8 of Sei2 5 has openings 9 (typically 60-110 mm in diameter) through which the mold formed by the C-profile frame 2 is filled with concrete or other suitable casting material.

According to one embodiment, the steel portions of the balcony slab are assembled by connecting the reinforcing mesh 19 (e.g., B600KX or equivalent), the balcony clamps (drawbar bracket 5 and

0 wall bracket 7) and threaded sleeves for fixing handrail posts and glazing 18.

The threaded bushings 18 are bolted to their designated points in the C-profile frame and welded to the reinforcement, upper and lower reinforcement rings 11, 12. The welding rod 6 is provided with a welded lattice bar, reinforcing grid 14, at its ends for securing the tow rods 6 or struts 5.

5 Instead of a lattice reinforcing profile, it is possible to use a lightened I-beam or other profile or structure which provides sufficient rigidity at low deadweight.

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The wall brackets 7 are fastened to the respective bracket. to the reinforcing bars inside the C-profile at the edge (reinforcing rings 11, 12). The wall brackets 7 are designed so that the lower floor tension rods 6 can be connected to the same building wall anchored bracket or to a separate external wall mounted support structure. On the reinforcement reinforcement, on the inside of the C-profile frame, a reinforcing steel mesh (eg B600KX 5 # 150) is installed and secured to the upper surface of the reinforcement according to the desired tilt of the floor. The tensioning rods 6 have a reinforcing grid 14 having two dimensioned lower edge reinforcing steel rods 15 at the lower end and a steel rod welding between them to form a zigzag-shaped transverse struts 17, welded to the upper edge of the reinforcing steel rod 16. The tensioning rods 6 dimensioned according to the load requirement.

The C profile forming the C profile frame typically has a height of 200 to 300 mm, a width of 40 to 80 mm and a wall thickness of 1.5 to 4.0 mm. The reinforcement according to the exemplary embodiment is mounted inside the C-profile frame and secured to the reinforcement by welding threaded bushes 18 with bolts to the C-profile through the holes made at the respective points. Alternatively, the threaded sleeves are first secured to the C-profile frame with bolts and the other reinforcement welded to the threaded sleeves. The finished balcony has a steel structure with wall anchors and drawbar brackets ready. Other attachment points are designed for lifting balconies

0 and installation, for attaching handrails, handrails, glazing and drawbars. With this solution, only C-corner welds need to be completed. Other welding and their thermal effect remain in the casting

The above details of the steel structure of the balcony slab are illustrated in Figures 5, 6 and 7.

Figure 8 shows the underside of the balcony slab waist web structure. The balcony tile is surrounded by a rim

5 20, which consists of a C-profile frame 2 and a slab filler. The filler is mostly concrete, but other moldable and sufficiently strong materials can be used. Edge 20 rotates the entire circumference of the balcony tile to form a stiffener at the edge of the tile. An object of the invention is to provide a lightweight balcony slab with a good load-bearing capacity. This is achieved by using, in addition to the rim 20, the outwardly extending webs 21 in the bottom surface of the tile. The core 21 is arranged to cross across the bottom surface of the tile. In this example, the webs 21 are at right angles to each other. Such a structure is easy to implement, but the invention makes it possible, if necessary, to use curved webs 7 or a grid structure. For example, if the web has a curved edge, even if it is semi-circular, one or more of the 5 amps of the slab is curved, a web pattern other than a rectangular structure could be used.

The grate structure as described above allows cost-effective and dimensionally accurate implementation of the required surface forms (escape route, water grooves, cant, wells, ...). The grate structure is dimensioned so that emergency escape routes (typically 620 mm x 620 mm) can be easily installed between the webs 21.

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At least one reinforcing steel is embedded in the lower edge of the balcony slab edge 20 and the webs 21, i.e. the surface furthest from the top surface of the slab. In the example of Figures 9 and 10, the lower reinforcing steels of the collar 20 form the lower reinforcing ring 12. The reinforcing ring 12 is positioned near the lower load-bearing surface of the structure in a manner known in the art of casting so as to obtain dimensioned load-bearing capacity. At the upper edge of the rim 20, reinforcement is formed by the upper reinforcing ring Ilia at the webs 21, the reinforcement is formed by transverse reinforcements 13. Reinforcing steels are provided in each web 21 and edging 20. In addition, a shield steel mesh 19 is provided on the upper surface of the slab.

The hanging points of the balcony slab are located at a distance from the wall of the building (balcony 10 of the slab wall mounts) and this distance is determined in the slab strength calculation. The most advantageous position is facing the wall at the front of the tile. In the examples of Figures 9 and 10, a first transverse web 21 facing from the leading edge to the wall mounting is disposed at such a defined position and a transverse reinforcement profile connecting the transverse suspension points is within this web. In exemplary embodiments, the reinforcement profile is the lattice structure described above

14. The drawbar brackets 5 form the suspension points and the drawbar brackets 5 are attached to the lattice structure 14 which thus carries a part of the load applied to the suspension points.

The dimensioning and amount of reinforcing steels depends on the stresses on the slab and is calculated by standard strength calculation methods, preferably optimizing the slab mass,

0 results in the most favorable result possible for the invention.

The shape of the lower surface of the tile with its edges 20 and the web 21 is formed by using filler blocks in the tile casting mold or by forming the necessary shape in the lower tile molding mold.

In the embodiment of Figure 9, the spacing between the webs 21 is open. In the embodiment of Figure 10, the gaps

5 is filled with a filler material 22, which may be preferably a heat insulating material, whereby the heat insulating ability of the slab is utilized. In addition to heat, the insulating material may be sound or fire insulating or even just filler material. Suitable materials include, for example, cellular polymer-based EPS (expanded polystyrene), XPS (extruded polystyrene) or rock and glass wool.

Figure 11 shows one example of the placement of railing posts 4 and floor drain 23

Figure 12 is a schematic view of the structural elements and molds for making one of the balcony slabs of the invention. In the center is a steel structure mounted inside the C-profile frame 2, on the right a lower surface mold 23, which may also be an integral part of the product remaining in the product. To the left is a mold 24 which produces the upper surface contours. In this embodiment, the top surface mold 24 is wedge-shaped to provide a slope for a suitable balcony floor, and the bottom surface mold 25 has grooves 26 to form the bottom surface webs 21. When preparing a balcony tile on the upper surface side

20155600 prh 05 -02-2018 a corresponding plate-like mold 24 and a grooved lower surface mold 25 providing a grate structure on the underside side are placed, e.g., EPS, XPS or fir wool. The lower surface mold 25 may be designed to be left in the structure and its upper surface may be provided with grooves 27 of heating ducts for air heating ducts (ducts may be either rectangular, square or circular, 30-80 mm depending on total structure thickness) (Fig. 13). A cover may be installed on the underside if the grate of the underside does not remain in the product.

For drainage, the balcony tile units of Figure 12 are placed in an upright position, with the building fastening board facing upwards and pressed together so that

The C-profile frames 2 form a dense frame for a casting unit consisting of several balcony tile units. The structural steel 8 of the balcony C-profile frame 2 facing the wall of the building is provided with holes 9 to allow filling of the mold. After the casting and concrete have cured, the molds are removed and the lifting anchors are attached to the above fixing points of the balcony slab, the threaded sleeves 18. The top surface of the balcony is finished with eg water washing, sanding, brushing or coating. The bottom surface is finished by coating when the mold remains in the product, or by coating on the inside of the C-profile, eg on a plate (this step can also be done during the pre-installation phase on site). Balcony slabs are prefabricated with handrail posts and handrails (possibly also handrail glazing) on site prior to lifting to their installation site.

In production, it is advantageous to place several of these molds together and press them together.

In this case, one mold at a time can be used to fill several molds at the top at the same time.

One advantageous feature of the invention is the ease of arranging various equipments. For heating, air ducts can be formed in the balcony tile as shown in Figure 13. Air ducts in the balcony slab allow it to be heated or cooled by blowing

5 air through the formed duct system, replacing, for example, separately installed IR heaters.

The structure shown allows the heat collected by the solar heater acting as a handrail, for example, to be transferred to the floor tile. Because the mass of the slab can be kept low, the reaction to temperature changes is rapid.

Correspondingly, plating can be made for other equipment and it is easy to make ready-made locations either at the prefabricated factory or at the construction site as a precursor for fixing the luminaires to the insulation.

Stainless steel is used for reinforcing and equipping the balcony slab, which provides sufficient fire resistance and allows reinforcements to be placed close to the surface of the concrete structure without worrying about the cause of corrosion.

In general, the tile structure according to the invention consists of a thin continuous flat plate and a web structure supporting it. The height and reinforcement of the atoms are determined by the dimensioning of the structure according to the span and load of the slab.

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The invention provides various products.

In balcony structures, the invention can be utilized to construct a new type of balcony. Unlike earlier structures, stainless steel is used as reinforcement and as an edge beam. The reinforcement of the webs and the reinforcing mesh on the deck as well as the drawbar rod fasteners are welded to the edge profile. This assembly, which constitutes the reinforcement of the balcony and the reinforcement of the beam and webs on the outer edge, is installed between the molds forming the upper and lower surfaces of the balcony slab. The benefits of stainless steel in terms of meeting the fire and corrosion resistance requirements of balconies are easier than with structural steel structures. These advantages allow for a thinner concrete protective layer, whereby the total weight of the structure can be significantly reduced. The solutions presented achieve the robustness of the concrete slab, good weather resistance and an important advantage, lightness, for the balcony attached with drawbars.

At least one embodiment of the tile according to the invention, for example illustrated in Figs. 1-4, can also be used for hanging balconies in buildings where the structure of the building, such as wall and floor, does not allow the use of conventional drawbar brackets. The balcony can then be secured by attaching to the wall of the house load-bearing steel trusses extending outwardly from the wall, with a bracket facing the balcony and a bracket, referred to herein as a draw bar20, attached to the edge of the balcony. That is, the wall-anchored brackets are replaced by a wall-mounted load-bearing lattice that is mounted on both sides of the balcony and has anchor points for the balcony brackets. This is an option for balconies in buildings where the wall and floor construction does not allow the use of drawbar brackets. The solution also allows balconies to be made in buildings that have no par2 5 platters and the building frame has not been designed with balconies in mind.

In this way, the invention can also be used to increase alternatives in renovation construction.

In the examples above, the tile has been rectangular and the webs are crosswise at right angles to each other. Of course, the shape of the tile may be varied such that at least one edge thereof is curved, polygonal or other suitable shape. In particular, the semi-circular shape could be easily accomplished. In this case, the webs may also be curved or inclined to one another. Different tile shapes can provide additional opportunities for building design.

The grate-type structure is advantageous especially because the fire hatches (600-800 mm x 600-800 mm) can be flexibly placed in the tile. Such a structure also reduces the weight of the par3 5 pleats. Proper web placement and the use of stainless steel also achieve weights well below 200 kg / m2 on concrete deck balconies. This is very important for wall anchors. However, this requires very careful planning so that current quality, fire resistance and cost requirements can be met.

When properly done and treated, concrete is a durable, versatile, non-flammable, long-lasting, carefree and cost-effective solution for floors (both indoor and outdoor). The C-profile on the side is both aesthetic, resistant to environmental stress, fireproof, strengthens the structure, simplifies the attachment of handrails and facilitates lifting during installation and plays a role in reducing on-site work. In various embodiments of the invention, a class 2.5mm stainless steel sheet can be used, which allows the use of stainless steel, although it is significantly more expensive than standard structural steel.

The C-profile frame can also serve as a mold when making casting top surface down against the mold. The reinforcement shown is mounted around the top mold

Inside the C-profile ring as described above. This enables a cost-effective and dimensionally accurate implementation of the required surface forms (fire hatches, water trenches, inclines, wells, ...). Reinforcement and brackets pull bars, handrails and glazing attachments can be pre-installed in the C-profile at the factory. After casting a uniform cover slab, mold blocks are placed and casting of the webs formed between them is carried out immediately.

The mold blocks can be left in place or removed and reused. When using mold sections made of fire wool or foam glass, they can be left in place to improve fire resistance.

The air ducts shown allow the balcony or the like to be heated by blowing warm air through the formed duct system. As glazing becomes more common on balconies

0 have become '' second living rooms '' and often use IR heaters. The structure shown allows, for example, the transfer of heat collected by the solar heater mounted on the handrail to the floor tile. Massive, it retains heat and makes the floor more comfortable as the evening gets cold (almost free). There is no need for problematic fires, such as wood terrace tiles and carpets.

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Reference numbers:

balcony slab

The C-profile bars

C-flange flange

4 handrail posts draw bar bracket draw bar wall bracket structural steel

9 hole slot upper reinforcement frame lower reinforcement frame transverse reinforcement

14 reinforcing steel lower edge reinforcing bar upper upper reinforcing bar transverse threaded bushing

0 19 reinforcement mesh edging web filler floor drain

5 24 top surface mold groove bottom surface

20155600 prh 05 -02- 2018

Claims (5)

Claims: 20155600 prh 18 -08- 2016 Requirement 1 Balcony tile (1), for hanging balcony, comprising a matrix structure of concrete filler and 5 reinforcing steels having at least a planar surface which forms the upper surface of the tile and a lower surface opposite to the upper surface, and wall brackets (7) for wall attachment , having drawbar brackets (5) for hanging a balcony slab, known - a circumferential rim (20) extending from the underside of the slab 10 outwards, - at least two crosswise webs (21) on the underside of the slab (1) extending over the area delimited by the collar (20) on the underside and extending outward to form a concrete grate structure, - the edges of the balcony slab (1) in a rotating steel C-profile frame (2), 15 wherein the opening of the profile C is oriented in the direction of the center of the balcony slab (1) and together with the filler forms the border (20) of the balcony slab (1), - a reinforcement profile connecting the tile bar lugs (5) to the balcony slab (1), and - that the steel parts of the balcony tile (1) are made of stainless steel. Requirement 2 Balcony tile for forming a hanging balcony according to claim 1, characterized by a lighter material than concrete, in which the recesses between the rim (20) and the webs (21) are at least partially filled. Requirement 3 Balcony tile according to Claim 1 or 2, characterized in that a reinforcement reinforcement is provided inside the C-profile frame (2) with at least one reinforcing steel (11, 12) disposed in the region of the at least one C-profile flange (8). Requirement 4 Balcony tile according to Claim 1, 2 or 3, characterized in that the stainless steel C-profile frame (2), which is wound on the slab (1), is secured via the slab filler matrix reinforcing steels (11, 12, 14). Requirement 5 Balcony tile (1) according to one of the preceding claims, characterized in that the reinforcing steel (11, 12) fitted in the region of the C-profile flange (8) has at least one bracket (18) and this bracket (18) is also connected to the C profile ) or other balcony equipment. Requirement Balcony tile according to one of the preceding claims, characterized in that the transverse reinforcement profile is a lattice structure (14). Requirement 7 Balcony tile according to one of Claims 1 to 6, characterized in that at least one side of the C-profile frame (2) orbiting the edge of the balcony tile (1) has openings (9) for feeding filler inside the C-profile frame (2). Requirement 8 Tile (1) according to Claim 7, characterized in that the openings (9) in the C-profile frame (2) are on the edge facing the wall of the balcony slab. Requirement 9 Slab (1) according to one of the preceding claims, characterized in that the wall clips (7) of the building of the balcony slab (1) are fixed to the reinforcing structure (11, 12) inside the C-profile. 20155600 prh 18 -08- 2016 20155600 prh 05 -02- 2018