RU149068U1 - REINFORCED CONCRETE PLATE OF THE COVERING OF THE BUILDING FRAME (OPTIONS) - Google Patents

Abstract

1. Reinforced concrete slab of the building frame, including the upper and lower shelves connected by at least two longitudinal stiffeners, while the short end of the slab is made with a recess in the body of the slab, with the formation of internal and external end parts, and the stiffeners are protruding from the body of the plate for its inner end part, while the upper shelf contains at least one fastener for connecting to the outer wall panel, and the lower shelf contains at least one fastener for connection with the beam and / or the outer wall panel, while the fasteners are located between the protruding parts of the stiffeners, and in the cavity between the shelves of the plate along the border of the recess is placed material that performs the function of formwork when monolithic joints of the plate. 2. The floor slab according to claim 1, characterized in that the recess is made rectangular with the formation of a short end of the U-shaped slab. 3. The floor slab according to claim 1, characterized in that the stiffeners of the slab are made protruding from the body of the slab beyond its outer end parts. The floor slab according to claim 1, characterized in that the fasteners are located in the plane of the shelves of the slab. 5. The slab according to claim 1, characterized in that the stiffening ribs of the slab are made protruding from the body of the slab to the border of its outer end parts. The floor slab according to claim 1, characterized in that the number of fasteners of the upper shelf is chosen equal to two. The floor slab according to claim 1, characterized in that the number of fasteners of the lower shelf is chosen equal to two. Floor slab under item 1, ha

Description

The utility model relates to the field of industrial and civil construction, namely to floor slabs, and can be used in the construction of prefabricated reinforced concrete frames, mainly multi-storey buildings for various purposes, including for residential, industrial buildings and general buildings.

The prior art various building boards containing nodes of connection with the supporting elements of the carcasses of buildings, monolithic at the edges of the plate.

For example, from the RF patent for invention No. 2353736, a plate is known that includes embedded parts made in the form of a rigidly fixed plate with holes for attaching wall panel anchors.

From the RF patent for the invention No. 2333323, a building plate is known containing channels with anchored metal pipes along the edges of the plate for connecting prefabricated columns.

From the patent of the Russian Federation for utility model No. 127099, prefabricated reinforced concrete slabs containing multi-hollow slabs with longitudinal reinforcement outlets and recesses at the ends are also known. In this case, the voids in the plates are made of a closed loop with an arbitrary, for example, a rounded cross-sectional shape and are located across the length of the plate along the span. The outlets of the longitudinal reinforcing cages are monolithic into longitudinal monolithic crossbars, and in the recesses on the ends of the slabs, monolithic concrete dowels are made, combined with longitudinal monolithic crossbars and receiving transverse forces.

From the patent of the Russian Federation for utility model No. 132103 known floor slab containing monolithic concrete; reinforcement located in the longitudinal direction of the plate in one and / or two levels; embedded parts intended for fastening: 1) plate fencing elements, 2) plates to supporting structures, 3) ties; stationary mounting loops. The embedded parts are located along one of the longitudinal sides and / or on the short sides of the plate, placed on the horizontal and vertical surfaces of the plate with certain distances between the centers of the plates of the embedded parts.

However, the known technical solutions are characterized by insufficient strength of the joints with the supporting elements of the frames, high weight, as well as insufficient accuracy during installation.

Closest to the claimed technical solution is the element of overlapping precast concrete frame structure of a multi-storey building according to the patent of the Russian Federation for utility model No. 62622, IPC: E04B 1/16. The overlap element contains a plate with at least three longitudinal stiffeners installed at intervals relative to each other. The plate is made reinforced with the release of working reinforcement, at least along the transverse ends of the upper belt of the floor slab, which allows the plates to be joined together by welding with monolithic joints. At least part of the stiffeners in the lower surface of the stiffeners are mounted inserts of material that allows easy insertion of fasteners.

The disadvantage of this technical solution is the use of welding when connecting frame elements, which requires the use of technological equipment for both welding and control of welded structural elements, which reduces the possibility of construction work in various climatic conditions. In addition, the complexity of the design of the nodes of the connection of the plates with other elements of the frame, leads to an increase in the cost of building assembly.

The objective of the utility model is to create new options for the construction of the slab, providing a reliable and quick connection of the slabs to each other and other supporting elements of the building frame - beams, beams, wall panels, columns, without the use of welding, as well as expanding the range of architectural and planning solutions.

The technical result is to increase the strength and accuracy of the joints while reducing labor and material costs, as well as construction time. The use of non-welded methods for joining floor slabs makes it possible to carry out construction work in all weather conditions and low temperatures (below -300C).

The problem is solved in that the reinforced concrete slab of the building frame includes the upper and lower shelves connected by at least two longitudinal stiffeners, while the short end of the slab is made with a recess in the body of the slab, with the formation of internal and external end parts, and the ribs stiffness made protruding from the body of the plate for its inner end part. In this case, the upper shelf contains at least one fastener for connecting to the outer wall panel, and the lower shelf contains at least one fastener for connecting to the beam and / or external wall panel. The fasteners are located between the protruding parts of the stiffeners, and in the cavity between the shelves of the plate along the border of the recess is placed material that performs the function of formwork when monoling the joints of the plate.

The recess is made rectangular with the formation of a short end of the plate of a U-shaped.

Fasteners are located in the plane of the shelves of the plate.

The stiffening ribs of the plate can be made protruding from the body of the plate beyond its outer end parts or to the border of its outer end parts.

The number of fasteners for the upper and lower shelves can be selected equal to two for each shelf.

The fastening elements can be made in the form of plates and / or loop-shaped eyes, while the plates are provided with an opening for a connecting element, for example, a bolt.

Plate with a hole can be fixed in the upper shelf of the plate, and loop-shaped eyes in the lower shelf.

The loop-shaped eyes can be made protruding beyond the outer end parts of the plate.

Fasteners are connected with the reinforcing frame of the plate and monolithic in its concrete body.

As the material that performs the formwork function, expanded polystyrene can be selected.

The problem is also solved by the fact that the reinforced concrete slab of the building frame includes an upper and lower shelf connected by at least two longitudinal stiffeners, while the long end of the upper shelf of the plate is made with at least one recess in the body of the shelf, and provided with at least one fastener for connection with an adjacent plate located in the recess. In the cavity between the shelves of the plate along the boundary of the recess placed material that performs the function of formwork when monolithic joints of the plate.

The recess is rectangular.

The fastening element is located in the plane of the shelf of the plate and can be made in the form of a loop-shaped eyelet of metal reinforcement connected with the reinforcing frame of the plate and monolithic in the concrete body of the plate.

The recesses in the upper shelf can be made of at least three located at an equidistant distance from each other.

As the material that performs the formwork function, expanded polystyrene can be selected.

The problem is also solved by the fact that the reinforced concrete slab of the building frame includes upper and lower shelves connected by at least two longitudinal stiffeners, while the long end of the slab is made with at least one recess. The upper shelf contains at least one fastener located in the recess for connection with an external wall panel, and the lower shelf contains at least one fastener located in the recess for connection with a beam and / or an external wall panel. In the cavity between the shelves of the plate along the border of the recess is a material that performs the function of formwork when monoling the joints of the plate.

The implementation of the fasteners and their location are implemented similarly to those proposed in the embodiment described above.

In this case, the fastening elements can be made protruding from the body of the plate to the border of the long end.

The recesses at the end of the plate can be made of at least three located at equidistant distances from each other.

The problem is also solved by the fact that the reinforced concrete slab of the building frame includes upper and lower shelves connected by at least two longitudinal stiffeners, while the short end of the plate is made with a recess in the body of the plate with the formation of an L-shaped end face with an external and internal end parts. In this case, the stiffening ribs of the plate are made protruding from the body of the plate beyond its inner end part. The upper shelf contains at least one fastener for connecting to the outer wall panel, and the lower shelf contains at least one fastener for connecting to the beam and / or external wall panel, while the fasteners are located between the stiffeners of the plate . In the cavity between the shelves of the plate along the border of the recess is a material that performs the function of formwork when monoling the joints of the plate.

The ends of the protruding parts of the stiffeners can be located in the same plane with the outer end part of the plate.

The plate can be equipped with an additional recess for docking with the column of the frame of the building located on the inner end of the plate, while the depth of the recess can be made commensurate with the half width of the column that is joined with the recess.

The implementation of the fasteners and their location are implemented similarly to those proposed in the embodiment * described above.

The magnitude of the recess can be made commensurate with the half width of the column, mating with the short end of the plate.

The problem is also solved by the fact that the reinforced concrete slab of the building frame includes upper and lower shelves connected by at least two longitudinal stiffeners, while the lower shelf and stiffeners are made protruding beyond the border of the upper shelf along the short end part of the plate. The upper shelf is equipped with fasteners for connection with an adjacent plate, and the protruding part of the lower shelf is provided with holes located between the stiffening ribs for fixing the plate to the beam. At the same time, in the cavity between the shelves along the border of the upper shelf there is a material that performs the function of formwork when monolithing the joints of the plate.

The end surfaces of the protruding parts of the stiffeners and the lower shelf of the plate can be located in the same plane.

The number of fasteners in the upper shelf can be selected equal to four, with two of them located between the stiffeners, and the other two at the edges of the short end of the plate.

The number of holes in the lower shelf can be selected equal to two.

The fasteners are located in the plane of the shelf of the slab and can be made in the form of loop-shaped eyes of metal reinforcement connected with the reinforcing frame of the slab and monolithic in its concrete body.

Expanded polystyrene can be selected as the material performing the formwork function.

The problem is also solved by the fact that the reinforced concrete slab of the building frame is made by analogy with the above and is additionally equipped with a recess located in the corner of the plate for joining the column of the building frame.

Moreover, the number of fasteners in the upper shelf can be chosen equal to three, with two of them located between the ribs, and the third with the edge of the short end of the plate that does not contain a recess.

The implementation of the fasteners and their location are implemented similarly to those proposed in the embodiment described above.

The depth of the recess is made proportional to the half-width of the column, joined with the recess.

The utility model is illustrated by drawings, in which Fig. 1 shows a floor slab, a general view (without detailing of the ends), in Fig. 2 - an embodiment of a short end of a plate intended for connection with a crossbar or beam and a wall panel (external) (option 1), in FIG. 3 - an embodiment of a long end of the plate, designed to connect the plates together (internal) (option 2), in FIG. 4 - an embodiment of a long end of the plate intended for connection with a crossbar or beam and a wall panel (external) (option 3), in FIG. 5 is an embodiment of a short end of a plate intended for connection with a crossbar or beam, a column and a wall panel (outer) (option 4), in FIG. 6 is an embodiment of a long end face of a plate intended for docking with a column; FIG. 7 is an embodiment of a short end of a plate intended to be connected to another plate based on a crossbar or beam (internal) (option 5), in FIG. 8 is an embodiment of a short end of a plate intended for connection with another plate with a support on a crossbar or beam and docking with a column (internal) (option 6), in FIG. 9 is a connection node of a plate with a structurally modified short end with a crossbar or beam and an outer panel, FIG. 10 - connection node of plates with structurally modified long ends to each other, in FIG. 11 - the connection node of the plate with a structurally modified long end with a crossbar or beam and an outer panel, FIG. 12 is a node for connecting plates with structurally modified short and long ends based on a crossbar or beam, FIG. 13 is a node for connecting plates with structurally modified short ends based on a crossbar or beam, in FIG. 14 is a connection node of a plate with a structurally modified short end with a crossbar or beam and an outer panel (using a metal profile), FIG. 15 - site connection plate with structurally modified short end with a crossbar or beam and an outer panel, top view.

The positions in the drawings indicate: 1 - floor slab, 2 - upper shelf of the floor slab, 3 - lower shelf of the floor slab, 4 - stiffener, 5 - external end of the floor slab, 6 - internal end of the floor slab, 7 - plate, 8 - hole plates for the connecting element, 9 - protruding part of the stiffener (beyond the border of the end surface of the plate), 10 - loop-shaped eyelet, 11 - polystyrene foam, 12 - recess in the upper shelf (Fig. 3), 13 - recess in the end of the plate (Fig. 4 ), 14 - recess in the plate for docking with the column (Fig. 5, 6, 8), 15 - hole in the bottom plate for mounting to a crossbar or beam, 16 - crossbar or beam, 17 - gasket, 18 - outer wall panel, 19 - threaded pin, 20 - sleeve, 21 - connecting plate, 22 - bolt with nut, 23 - steel profile, 24 - steel pipe, 25 - HALFEN metal profile, 26 - reinforcing collar.

The claimed technical solution is a ribbed, prestressed plate 1 (hollow), used for floors in the structures of the reinforced concrete frame of buildings (Fig. 1). The plate 1 is equipped with two rectangular shelves - the upper 2 and lower 3, seamlessly connected using at least two stiffeners 4 located at a distance from each other. In this case, the distance between the stiffeners 4 can be different and is determined by the transformable parts of the tooling. In the intercostal space of the plate 1, the necessary communications can be laid. The upper shelf 2 is made thicker than the thickness of the lower shelf 3. In the upper and lower shelves there are reinforcing meshes interconnected by clamps passing through the stiffeners. In areas where the ribs merge with the lower flange 3, prestressed reinforcement can also be placed to absorb tensile forces (with the exception of balcony cantilevered protrusions).

In a particular embodiment, the plate may have the following dimensions: width - 1200 mm, height - 250 mm, thickness of the upper shelf - 40 mm, lower - 60 ÷ 70 mm. In this case, the border of the plate is determined by the most protruding parts of the upper or lower shelves of the plate (protruding ribs and fasteners are not taken into account when determining the border of the plate).

A feature of the design of floor slabs 1 is the implementation of their end parts intended for joining with each other and with other elements of the building frame: beams, crossbars, columns, wall panels, balcony parapets. One of the embodiments of the claimed utility model is the technical solution of the floor slab with a structurally modified end part (option 1), which goes to the outer part of the building frame (short side), except for the balcony, for docking with a crossbar of an H-shaped structure or beam, as well as external panels (Fig. 2).

In this embodiment, the end part of the plate on the short side (short end of the plate) is made of a profile - U-shaped (in horizontal projection) with a rectangular recess in the body of the plate, forming two outer ends 5 of the plate and the inner end 6, while the stiffeners 4 of the plate made protruding from the body of the plate beyond its end border, passing along the outer ends of the shelves 2 and 3 (Fig. 2), with the possibility of support on the crossbar or beam and the wall panel. The plate is equipped with fasteners connected to its reinforcing frame, protruding beyond the ends of the shelves of the plate. Fasteners can be made of two types. The first type of fastening is a plate 7 provided with at least one hole 8 for a connecting element, for example, a bolt. In this case, one or two such plates can be made in the plate, which are fixed directly in the upper shelf 2 of the plate (for example, monolithic in the body of the upper shelf of the plate) between the protruding parts 9 of the stiffeners. The plates 7 are located in one plane parallel to the plane of the shelves and are configured to connect them to the wall panel mounting element. The second type of fastening is made in the form of loop-shaped eyes 10 (one or two) of metal reinforcement, which are located in a plane parallel to the plane of the shelves, under the plates 7. The eyes 10 are also connected to the reinforcing frame of the plate and fixed (monolithic) in the body of the lower shelf 3. The loop-shaped eyes are made protruding beyond the outer ends 5 of the plate with a length not exceeding the length of the protruding parts of the stiffeners with the possibility of passing through them pins 19, fixed in the wall panel 18 and the beam 16 (Fig. 9). The first type of fasteners is intended for fastening the outer panels 18 of the building frame, for example, by using an additional connecting plate 21, which is connected to the plate 7 fixed in the plate, thereby ensuring the fit of the connected structural elements (panels with a floor slab) (Fig. 9) . The second type of fastening is designed to connect the floor slab with the beam or crossbar 16 and the outer panel 18. In the cavity between the shelves of the plate along the perimeter of the short end part of the U-shaped plate, material is placed, for example, polystyrene foam 11, which provides the formwork function in the process of monoling the nodes of the element connections constructions (joints of a plate with beams or crossbars and panels).

Another embodiment is a plate with a structurally modified long end part (option 2), used for joining plates together (long side) inside the building. In this embodiment, from the side of the long end part of the plate in the upper shelf 2, a rectangular recess 12 is made, which is a cutout of a part of the shelf having a rectangular shape in horizontal projection. In the recess 12 there is a fastening element, for example, in the form of a loop-shaped eye 10 of metal reinforcement, connected to the reinforcing frame of the upper shelf 2 of the plate and monolithic in its body (Fig. 3). At the same time, along the long end of the plate, at least two such recesses can be made, located symmetrically relative to the center of the plate and offset closer to its short ends. With more recesses, they are located at equidistant distance from each other. Along the perimeter of the recess in the cavity between the shelves of the end part of the plate is a material (for example, polystyrene foam 11), which provides the formwork function in the process of monoling the connected structural elements (joints of adjacent plates). An example of the implementation of the node for coupling floor slabs with long ends is shown in FIG. 10, which shows the connection of plates in cross section along their long side passing through the recesses. A possible embodiment of the plate with a different number of loop-shaped eyes located on opposite long ends of the plate.

The third embodiment is a plate with a structurally modified end part along the long side (long end part) used to dock the plate with a crossbar or beam and a wall panel (Fig. 4). In this embodiment, a through recess 13 of a rectangular shape (in horizontal projection) passing through the upper 2 and lower 3 shelves is made from the side of the long end part of the plate. The magnitude of the recess does not exceed the distance from the long end of the plate to the nearest stiffener. Moreover, in this embodiment, both the fasteners themselves and the principle of their location in the body of the plate described in embodiment 1 can be used. The plates 7 and the loop-shaped eyes 10 fixed in the upper and lower shelves, respectively, and located in the recess, are made protruding from the body of the plate to the border of its long end. At the same time, at least two recesses located symmetrically with respect to the center of the plate and offset closer to its short ends can be made along the long end of the plate. With more recesses, they are located at equidistant distance from each other. Along the perimeter of the recess in the cavity between the shelves of the slab, formwork, for example, of polystyrene foam 11, was also used to enable monolithic connection of structural elements. In this case, when docking, the plate is supported and fixed on the crossbar or beam 16 and attached to the wall panel 18. An example of the connection of the listed structural elements is presented in FIG. eleven.

The fourth option is a slab with a structurally modified short end part (short end), which extends to the outer part of the building frame, except for the balcony, for joining the plate with an H-beam or a beam and a column, as well as an external enclosing structure of various types (as external panels, and brickwork, etc.). This embodiment of the plate is similar to option 1 with the following structural differences: the ends of the protruding parts 9 of the ribs are located in the same plane as the outer end 5 of the plate, in the corner part of the end of the plate there is additionally made a recess 14 for docking with the column. The boundaries of the recess 14 are the lateral face of the protruding part 9 of the stiffener, closest to the long end of the plate, and part of the ends of the upper and lower shelves (Fig. 5). The magnitude of the deepening of the recess 14 in the thickness of the plate is made commensurate with half the width of the column mating with the recess. The loop-shaped eyes 10 can be made protruding beyond the outer ends 5 of the plate.

The recess for the column can be located on different ends of the slab (both long and short), depending on the design of the building. In FIG. 6 shows an embodiment of placing a recess for a column made in the body of the plate in its long end part.

The fifth option is a slab with a structurally modified end part on the short side, which is the inner part of the building frame, for connection with adjacent floor slabs with a support on a crossbar of an H-shaped structure or beam. In this embodiment, the upper shelf 2 of the plate is shortened (does not reach the border of the plate formed by the lower shelf 3 and stiffeners 4), and the fastening elements, for example, in the form of loop-shaped eyes 10, are protruding from the ends of the upper shelf 2, and their ends connected to the reinforcing cage and monolithic in the upper shelf (Fig. 7). The number of fasteners in the upper flange was chosen to be four, with two of them located between the stiffeners, and the other two along the edges of the short end of the plate (on the opposite sides of the short end between the corresponding edge and the nearest long end of the plate). The loop-shaped eyes can be made with a length not exceeding the length of the protruding parts of the stiffeners, which ensures the butt joint of the short ends of adjacent plates. In the lower shelf 3 in the protruding part between the stiffening ribs, holes 15 are made for attachment to crossbars or beams, for example, using anchor pins. The holes 15 can be located under the eyes 10. The plate is also equipped with a formwork, for example, of polystyrene foam 11, located in the cavity between the upper and lower shelves around the perimeter of the short end of the upper shelf, which allows monolithic connected structural elements (joints of the plate with the beam or crossbar and / or adjacent slabs).

The sixth option is the design of the plate, made according to the fifth embodiment, and additionally equipped with a recess 14 for docking with a column of an H-shaped frame structure, the recess being located in the corner of the short end of the plate, and its borders are the side of the protruding part 9 of the stiffener, the nearest to the long end of the plate, and part of the ends of the upper and lower shelves (Fig. 8). The magnitude of the deepening of the recess 14 in the thickness of the plate is made commensurate with half the width of the column mating with the recess. At the same time, three loop-shaped eyes protruding beyond the end of the upper shelf are fixed in the upper shelf of the plate, two of which are located between the stiffeners, and the third - with the edge of the short end of the plate that does not contain a recess.

In FIG. 16 shows one example of a plate (with overall dimensions of 1200 mm × 7800 mm) with different configurations of the ends and with a different number of loop-shaped eyes located on opposite short and long ends of the plate. Short ends of this plate are made according to options 4, 6, respectively, and long ends - according to options 2 and 3, while one of the long ends of the plate is equipped with a cutout for the column. Thus, a plate can have two eyes on one long end side (for example, for docking with the long end side of an adjacent plate), on the other long end side - 5 eyes (for example, for connecting to a crossbar or beam, a wall panel and a column) , three eyes on one short end side (for connecting to the long or short end sides of adjacent plates) and two eyes on the other short end side of the plate (for connecting to various frame elements, for example, a crossbar or beam, a wall panel and with a column).

The following describes examples of the implementation of the connections of the floor slab with various supporting elements of the building frame.

The connection of the short end of the floor slab with the crossbar or beam and with the outer panel can be carried out as follows. The floor slab according to option 1 is supported by a short end part with protruding stiffeners on the crossbar or beam 16 through a rubber or plastic gasket 17 (Fig. 9). In addition, the protruding parts of the stiffening ribs of the floor slab also rest on the lower installed outer wall panel 18. The floor slab is fixed to the beam or crossbar 16 through steel loop-shaped eyes 10 protruding from the lower shelf 3 of the floor slab. A threaded thread pin 19 is passed through the eye 10, which is fixed in a special sleeve 20 located in the upper part of the beam or crossbar 16. A nut and washer are screwed onto the pin 19 (between the gasket and the eye clamp). The fastening of the floor slab 1 to the lower installed outer panel 18 is carried out through the same loop-shaped eye 10 according to the previously described principle, but without the additional use of gaskets. Further, the above-installed outer panel 18 is connected to the floor slab by means of connecting plates 21. The connecting plate 21 from the side of the floor slab is fastened with a bolt and nut 22 to the plate 7 protruding from the upper shelf 2 of the floor slab. The other end of the connecting plate 21 is connected by means of a pin 19 with the above-installed outer panel. Then, expanded polystyrene 11 is placed in the joint, and the joint itself is monolithic with special concrete. In a similar way, a long-end floor slab (made, for example, according to option 3) can be connected to the outer panel and the beam or crossbar, while reinforcing collar 26 is additionally used to increase the rigidity of the connection node (Fig. 11). The connection of the floor slab with a short end to the outer panel, column and beam or crossbar is carried out in the same way, but using floor slabs made according to option 4 with a recess 14 for docking with the column.

In another embodiment, connecting the short end of the plate with the crossbar or beam and with the outer panel 18, it is possible to use the plate according to option 1 with stiffeners not protruding beyond the outer end of the plate and made without plates in the upper shelf (or the plates may not be involved in this form connections). In this case, the outer panels 18 are supported on each other through a plastic gasket (Fig. 14, 15). The upper part of the outer panel 18 is fixed to the beam or crossbar 16 and the floor slab through the steel profile 23. The steel profile 23 is inserted into the steel pipe 24 installed in the upper part of the lower outer panel 18, and then, with the help of anchor bolts, is fixed in the sleeves installed at the top of the subordinate outer panel. The fastening of the floor slab to the beam or crossbar 16 is carried out by analogy with the above method. The lower part of the above-installed panel is fixed to a beam or crossbar, for example, through a HALFEN POWERCLICK 25 steel profile. The pins 19 and steel profiles 23, 25 are connected with a reinforcing collar 26 (Fig. 15). In addition, the lower part of the outer panel also connects to the beam and the floor slab using the connecting plate 21. The assembly is monolithic with special concrete. In a similar way, a long-end floor slab can be connected to the outer panel and the beam or crossbar.

When pairing the long end of the floor slab (according to option 2) with the short (according to option 5) and the beam or crossbar, the corresponding ends of the floor slabs are supported on the beam or crossbar 16 inside the building (Fig. 12). Fastening to a beam or a crossbar is carried out using holes in the lower shelf 3 of the short end of the plate. The pin 19 is passed through the hole and secured in a sleeve 20 installed in the beam or crossbar 16. The loop-shaped eyes 10, mounted in the upper shelves of the short and long ends of the conjugate floor slabs, are interconnected by reinforcing collars 26. The assembly is monolized with special concrete. In this case, polystyrene foam 11 is used as the formwork. Similarly, the short ends of the floor slabs are connected with the support on the crossbar or beam (Fig. 13).

When connecting floor slabs 1 with long ends, reinforcing collars 26 pass through the loop-shaped lugs 10 protruding from the upper shelves 2, and the joint is monolithic with special concrete (Fig. 10). In various embodiments, the connection of the reinforcing collar 26 can be made in the form of a loop or C-shaped bracket.

Thus, the connection of floor slabs is carried out in a non-welded manner, using a special mortar with which the nodes of the mechanical joints are concreted. As such a solution, a mobile, non-shrinking solution is used that protects the metal elements of the joints from corrosion. Using the various types of plate joints described above allows you to transfer horizontal loads from wind, temperature extremes and seismic effects, not exceeding 2% of the mass. In addition, the use of a mechanical joining method allows for precise control against sagging plates at the assembly stage.

The production of floor slabs can be carried out on an installation based on a conveyor line with a circulation of pallets of 2.9 × 13.0 meters, containing 2 products at the same time (if the length of the floor slab is less than 6 meters, then simultaneous placement of 4 products on one pallet) . The conveyor line includes a multi-level steaming chamber and a mechanical stacker, filling, removing and transversely moving pallets. For the formation of the internal shape of the products, Domex steel holders with a high modulus of elasticity and a small thickness can be used, which are removed from one end of the product after the concrete has been kept in the steaming chamber. In another embodiment, a central pore former (exclusively for the central space) is used, made of ordinary steel and having a slightly conical shape, which is removed after a 4-hour concrete curing cycle. After removing the blank former, the products are again transferred to the steaming chamber to complete the heat treatment cycle. In this case, the external shape of the product is created through the use of side boards.

The developed floor slab has dimensions and weight, providing the necessary level of sound insulation of low-frequency noise and fire resistance (60 minutes). In addition, the slab has a bearing capacity corresponding to building codes and the purpose of the buildings; deformability within the established standards for operational loads; smoothness and plane of the lower and upper surfaces; can reach a maximum length of 9 m with a console overhang.

The designed ribbed floor slabs are characterized by increased strength compared to analogues due to the fact that during the installation process their integrity is not violated, since all the connecting elements are installed at the stage of manufacturing the slabs. Moreover, these slabs have a relatively small mass due to the small number of stiffeners that does not go to the detriment of their sound insulation and fire resistance.

The manufacturing process of the proposed floor slabs involves the use of standard equipment and inexpensive materials, is characterized by simple technology and does not require the use of sophisticated equipment, which reduces the cost of finished floor slabs. Since the entire process of manufacturing plates, including the installation of connecting elements, is carried out in the factory, the finished floor slab is characterized by high manufacturing accuracy.

The connection nodes of the developed floor slabs in the building frame are also characterized by increased strength, since the connecting elements are made in one piece with the plates in the factory, and the nodes themselves are monolized by the mortar during installation. The advantages are also high accuracy and low installation costs due to the fact that the factory-installed fasteners uniquely determine the joints, and the installation process does not require the use of welding, as well as complex and expensive equipment. The use of various options for connecting plates between each other and with other supporting elements of the frame expands the possibilities of architectural and planning solutions

Claims (53)

1. Reinforced concrete slab of the building frame, including the upper and lower shelves connected by at least two longitudinal stiffeners, while the short end of the slab is made with a recess in the body of the slab, with the formation of internal and external end parts, and the stiffeners are protruding from the body of the plate for its inner end part, while the upper shelf contains at least one fastener for connecting to the outer wall panel, and the lower shelf contains at least one fastener for connection with the beam and / or external wall panel, while the fasteners are located between the protruding parts of the stiffeners, and in the cavity between the shelves of the plate along the border of the recess is placed material that performs the function of formwork when monolithic joints of the plate. 2. The slab according to claim 1, characterized in that the recess is made rectangular with the formation of a short end of the slab U-shaped. 3. The floor slab according to claim 1, characterized in that the stiffening ribs of the slab are made protruding from the body of the slab beyond its outer end parts. 4. The slab according to claim 1, characterized in that the fasteners are located in the plane of the shelves of the plate. 5. The slab according to claim 1, characterized in that the stiffeners of the slab are made protruding from the body of the slab to the border of its external end parts. 6. The floor slab according to claim 1, characterized in that the number of fasteners of the upper shelf is chosen equal to two. 7. The floor slab according to claim 1, characterized in that the number of fasteners of the lower shelf is chosen equal to two. 8. The slab according to claim 1, characterized in that the fasteners are made in the form of plates and / or loop-shaped eyes, while the plates are provided with an opening for a connecting element, for example, a bolt. 9. The slab according to claim 8, characterized in that the plates with the hole are fixed in the upper shelf of the plate, and the loop-shaped eyes are in the lower shelf. 10. The slab according to claim 8, characterized in that the loop-shaped eyes are protruding beyond the outer end parts of the slab. 11. The floor slab according to claim 1, characterized in that the fasteners are connected with the reinforcing frame of the slab and monolithic in its concrete body. 12. The floor slab according to claim 1, characterized in that polystyrene foam is selected as the material performing the formwork function. 13. Reinforced concrete slab of the building frame, including the upper and lower shelves, connected by at least two longitudinal stiffeners, while the long end of the upper shelf of the plate is made with at least one recess in the body of the shelf, and provided with at least at least one fastener for connecting to an adjacent plate located in the recess, and in the cavity between the shelves of the plate along the border of the recess is placed material that performs the function of formwork when monoling the joints of the plate. 14. The floor slab according to claim 13, characterized in that the recess is rectangular. 15. The floor slab according to claim 13, characterized in that the fastener is located in the plane of the shelf of the slab. 16. The slab according to claim 13, characterized in that the fastening element is made in the form of a loop-shaped eyelet of metal reinforcement connected with the reinforcing frame of the plate and monolithic in the concrete body of the plate. 17. The slab according to claim 13, characterized in that the recesses are made of at least three located at an equidistant distance from each other. 18. The floor slab according to claim 13, characterized in that polystyrene foam is selected as the material performing the formwork function. 19. Reinforced concrete slab of the building frame, including the upper and lower shelves connected by at least two longitudinal stiffeners, while the long end of the slab is made with at least one recess; the upper shelf of the plate contains located in the recess, at least one fastener for connecting to the outer wall panel, and the lower shelf contains located in the recess, at least one fastener for connecting to the beam and / or external wall panel, in the cavity between the shelves of the plate along the border of the recess is a material that performs the function of formwork when monolithic joints of the plate. 20. The slab according to claim 19, characterized in that the recess is rectangular. 21. The slab according to claim 19, characterized in that the fasteners are located in the plane of the shelves of the plate. 22. The slab according to claim 19, characterized in that the fastening elements are made in the form of plates and / or loop-shaped eyes, while the plates are provided with an opening for a connecting element, for example, a bolt. 23. The slab according to claim 22, characterized in that the plates with the hole are fixed in the upper shelf of the plate, and the loop-shaped eyes are in the lower shelf. 24. The floor slab according to claim 19, characterized in that the fastening elements are protruding from the body of the slab to the boundary of the long end. 25. The floor slab according to claim 19, characterized in that the fasteners are connected to the reinforcing frame of the slab and monolithic in its concrete body. 26. The floor slab according to claim 19, characterized in that the recesses are made of at least three located at an equidistant distance from each other. 27. The floor slab according to claim 19, characterized in that polystyrene foam is selected as the material performing the formwork function. 28. Reinforced concrete slab of the building frame, including the upper and lower shelves connected by at least two longitudinal stiffeners, while the short end of the slab is made with a recess in the body of the plate of a L-shape with the formation of the outer and inner end parts, while the stiffening ribs of the plate are made protruding from the body of the plate beyond its inner end part; the upper shelf contains at least one fastener for connecting to the outer wall panel, and the lower shelf contains at least one fastener for connecting to the beam and / or external wall panel, while the fasteners are located between the stiffeners of the plate ; in the cavity between the shelves of the plate along the border of the recess is a material that performs the function of formwork when monolithic joints of the plate. 29. The floor slab according to claim 28, characterized in that it is provided with an additional recess for joining the column of the building frame located on the side of the inner end of the slab. 30. The floor slab according to claim 29, characterized in that the depth of the recess is made commensurate with the half width of the column that is joined to the recess. 31. The slab according to claim 28, characterized in that the ends of the protruding parts of the stiffeners are located in the same plane as the outer end part of the plate. 32. The floor slab according to claim 28, characterized in that the fasteners are located in the plane of the shelves of the slab. 33. The slab according to claim 28, characterized in that the fastening elements are made in the form of plates and / or loop-shaped eyes, while the plates are provided with an opening for a connecting element, for example, a bolt. 34. The slab according to claim 33, characterized in that the plates with the hole are fixed in the upper shelf of the plate, and the loop-shaped eyes are in the lower shelf. 35. The floor slab according to claim 33, characterized in that the loop-shaped eyes are made protruding beyond the outer end parts of the slab. 36. The floor slab according to claim 28, characterized in that the fasteners are connected with the reinforcing frame of the slab and monolithic in its concrete body. 37. The floor slab according to claim 28, characterized in that polystyrene foam is selected as the material performing the formwork function. 38. The floor slab according to claim 28, characterized in that the size of the recess is made commensurate with the half-width of the column, mating with the short end of the slab. 39. Reinforced concrete slab of the building frame, including the upper and lower shelves connected by at least two longitudinal stiffeners, while the lower shelf and stiffeners are made protruding beyond the border of the upper shelf along the short end part of the plate, the upper shelf is equipped with fasteners for connection with an adjacent plate, and the protruding part of the lower shelf is provided with holes located between the stiffeners for fastening the plate to the beam, while in the cavity between the shelves along the border of the upper shelf races olozhen material performs shuttering function when monolithing plate joints. 40. The floor slab according to claim 39, characterized in that the end surfaces of the protruding parts of the stiffeners and the lower shelf lie in the same plane. 41. The slab according to claim 39, characterized in that the fasteners are located in the plane of the shelf of the plate. 42. The floor slab according to claim 39, characterized in that the number of fasteners in the upper flange is chosen to be four, with two of them located between the stiffeners, and the other two at the edges of the short end of the slab. 43. The floor slab according to claim 39, characterized in that the number of holes in the lower shelf is chosen equal to two. 44. The slab according to claim 39, characterized in that the fastening elements of the upper shelf are made in the form of loop-shaped eyes of metal reinforcement, connected to the reinforcing frame of the plate and monolithic in its concrete body. 45. The floor slab according to claim 39, characterized in that polystyrene foam is selected as the material performing the formwork function. 46. Reinforced concrete slab of the building frame, including the upper and lower shelves connected by at least two longitudinal stiffeners, while the lower shelf and stiffeners are made protruding beyond the border of the upper shelf along the short end part of the plate; the plate is provided with a recess located in the corner zone of the plate for docking with the column of the building frame; the upper shelf is equipped with fasteners for connection with an adjacent plate, and the protruding part of the lower shelf is provided with holes located between the stiffening ribs for fixing the plate to the beam, while in the cavity between the shelves along the border of the upper shelf there is material that performs the function of formwork when monolithing the joints of the plate. 47. The floor slab according to claim 46, characterized in that the end surfaces of the protruding parts of the stiffeners and the lower shelf lie in the same plane. 48. The floor slab according to claim 46, characterized in that the fasteners are located in the plane of the shelf of the slab. 49. The floor slab according to claim 46, characterized in that the number of fasteners in the upper shelf is chosen equal to three, with two of them located between the stiffeners, and the third with the edge of the short end of the slab that does not contain a recess. 50. The floor slab according to claim 46, characterized in that the number of holes in the lower shelf is chosen equal to two. 51. The slab according to claim 46, characterized in that the fastening elements of the upper shelf are made in the form of loop-shaped eyes of metal reinforcement connected with the reinforcing frame of the plate and monolithic in its concrete body. 52. The floor slab according to claim 46, characterized in that polystyrene foam is selected as the material performing the formwork function. 53. The floor slab according to claim 46, characterized in that the depth of the recess is made commensurate with the half-width of the column that is joined to the recess.

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