UA82634C2 - Method to make cell floor slab and slab made with that method - Google Patents

Abstract

The invention relates to building and can be used at making barrier structures to which requirements are set forth on sound insulation and strength. A method for making cell floor slab includes installation of casing, laying net of the lower layer of slab, laying reinforcement spatial frames normally to each other with laying plates made of polystyrene material, laying net of the upper layer of slab and formation of the lower and the upper concrete layers and beams of the plate. After laying net of the lower layer of plate one lays frames of bearing and secondary beams, respectively, with formation of cavities-cells between frames, after that one lays concrete of lower layer of slab, on that at distance from frames to cavities-sells one places inventory plates-slabs made of polystyrene material, between those one lays concrete mix with formation of main bearing and secondary beams, after that in contour of plate by surface formed one lays additional casing made of face bricks, one lays net of the upper layer with filling concrete mix there. On the last one, after its partial curing, one places layer of semi-dry bulk material. Slab made with that method is proposed as well. The invention provides rigid link and joint operation of floor slab and wall barrier structure.

Description

Description of the invention

The invention relates to the field of construction and can be used in the construction of residential and public 2 buildings, the enclosing structures of which require heat and sound insulation and strength.

The invention can also be used in other branches of the national economy: shipbuilding, transport, etc.

A known method of manufacturing a monolithic three-layer structure and a constructive solution of this plate, which includes the establishment of structural connections between layers of reinforcement, which is characterized by the creation of 70 opportunities for the transmission of structural noise through these connecting elements, which leads to the deterioration of the insulating properties of the panel, see Japanese patent Mo59-14132, IPC EO481/76, 1984). The method of setting up a monolithic reinforced concrete floor and its construction is also known (SHA Mob5787 patent, IPC Е0О4В5/00, 2004). A monolithic honeycomb floor contains stiffeners, reinforcing frames, which form load-bearing main and secondary beams, placed in mutually perpendicular directions, having different widths, 72 and rigidly connected to each other, as well as lightweight concrete aggregate.

This structure is made by creating monolithic layers of reinforced concrete using formwork with working fittings and a frame.

The closest to the proposed method is the technology of manufacturing a floor slab, which includes the operations of laying out reinforcing meshes of the lower and upper layers of the slab, installing polystyrene foam plates with the formation of cavities between them, in which reinforcing spatial frames are installed in mutually perpendicular directions and which are poured with a concrete mixture, thus forming like the cross ribs-beams of the floor slab. The known method includes the formation of the lower reinforced concrete layer of the slab and also the upper reinforced layer of the slab together with the ribs-beams | see OB 5398470, EO4C2/26, 1995). The method ensures the production of a floor slab without rearranging the formwork, also ensures a reduction in the weight of the slab, significant strength and certain heat and sound insulation properties. But along with this, the known method does not ensure the production of a floor slab with the possibility of combining it with wall enclosing structures, the slab made in this way still has insufficient sound insulation and a defective surface structure.

Known constructions of sound-insulating slabs of residential buildings, which contain insulating inserts and a lower and upper slab of reinforced concrete with stiffening ribs |Himofeenko L.P. Increased efficiency of sound insulation. - K.: Budivelnyk, 1979, p. 52, fig. 27). This constructive solution of the floor slab is characterized by insufficient external insulation in the area of high frequencies, the presence of resonance phenomena in the "floor - construction of a clean floor" system. co

The floor slab and the method of its manufacture with the help of the formation of spatial voids, as well as formwork and insulation elements, which are located between the elements of the supporting frame and which are in contact with concrete, are also known (patent KO Mo2054099, IPK EO485/00, ЕЕО4С2/04, 1996) . The disadvantage of this solution is the insufficient rigidity of the plate structure, which leads to a decrease in sound insulation in the low-frequency area, as well as the difficulty in manufacturing inserts in the form of sandwiches with separate layers, which complicates the plate manufacturing process. "

The monolithic honeycomb ceiling according to the technical decision according to OA Mob5787 has the disadvantage of insufficient rigidity of the plate structure, which is due to the presence of a lightweight concrete layer over the entire height of the "Instructions" and, as a result, a decrease in sound insulation in the mid-frequency area, the occurrence of a dip in the frequency range. characteristics of sound insulation from air noise in this frequency range, as well as the increased complexity of manufacturing the structure.

The closest analogue to the proposed floor slab is the cellular floor slab described in 42 (85 5398470), which contains the lower and upper mesh-reinforced concrete layers, beams reinforced with spatial reinforcing frames located mutually perpendicular to each other, in the cavities between the frames installed plates made of polystyrene foam, the upper and lower grids are connected by vertical rods that pierce the polystyrene plates. The disadvantages of the plate in the field of heat and sound insulation and in view of the possibility (22 of ensuring reliable and compatible spatial operation with other structures of the building) are due to the method of its manufacture, as well as certain structural features.

The task set during the development of this invention was to ensure effective heat and sound insulation of the floor slab in the area of medium frequencies, to simplify its manufacture due to the elimination of time-consuming operations for moving the formwork, and the possibility of ensuring a highly rigid connection and compatible spatial operation of the floor slab with the wall enclosing structure; improving the quality of the surface layer of the plate. 25 The task is solved by the fact that in the method of manufacturing a cellular floor slab, which includes

Gee! installation of formwork, layout of the grid of the lower layer of the slab, layout of reinforcing space frames mutually perpendicular to each other, laying of polystyrene material slabs, layout of the grid to the upper layer of the slab and operations of forming the lower and upper concrete layers and beams of the slab, according to the invention, after the grid is laid out of the lower layer, the frames of the supporting beams are first laid out, and then 60 secondary beams with the formation of cavities-chairs between the frames, after which the concrete of the lower layer of the slab is laid, on which, at a distance from the frames, in the cavities-honeycombs, inventory slabs-inserts of polystyrene material are installed, between with which the concrete mixture is laid, forming the main load-bearing and secondary beams, after which an additional formwork of face bricks is laid along the contour of the slab on the surface formed, the mesh of the upper layer is laid out and the concrete mixture is poured, on which, after its partial hardening, a layer of semi-dry loose material

The cellular slab of the floor, manufactured by the above-mentioned method according to item 1, according to the invention, contains the lower and upper reinforced layers, located in a mutually perpendicular direction, supporting main and secondary beams, which have reinforcing spatial frameworks, which form a box-honeycomb structure between them with placed inside the honeycombs, inventory plates-liners made of polystyrene material with side vertical surfaces, in the space between which a concrete mixture is placed, and the upper layer contains a layer of semi-dry bulk material with high dissipative losses.

There is a possible version of the construction of the plate, according to which polystyrene foam, in particular polystyrene foam of the PSB brand, is used as the insulating material of the insert plate. It is also possible to implement the 7/o invention, according to which a sand mixture with a cement component is used as a layer of semi-dry material.

In the following, the invention is explained by a specific example of its implementation and a drawing, which shows: in Fig. 1 - a general view of the plate; in Fig. 2 - a connection node with a column; in Fig. 3 - a fragment of the reinforcement of the node; in Fig. 4 - the junction of the floor plate with the wall, which is an additional formwork during the manufacture of the floor plate; in Fig. 5 - placement of liners between secondary beams; in Fig. b6 - reinforcement with rod reinforcement.

The floor slab contains main load-bearing beams 1, secondary beams 2, located inside and along the contour of plate C, which are placed in mutually perpendicular directions and form honeycombs, as well as artificial filler inserts 4, mainly from stock polystyrene boards, which fill the honeycombs between the beams. The slab includes an upper layer 5 and a lower layer 6. The load-bearing beams contain the frame 7, and the secondary beams contain the frame 8, with reinforcement outlets 9 and 10, respectively, in the lower and upper zones. The floor slab in Fig. 2 is placed directly around the column 11 with reinforcing vertical frames 12. On the upper plane of the layer 5, a layer 13 of a semi-dry loose material with high dissipative losses is placed, for example, a semi-dry sand mixture with a cement component. (8)

The method of manufacturing the floor slab includes the installation of formwork (not shown in the drawings), the layout of the reinforcing mesh 9U of the lower layer of the slab and frames 7, 8, reinforcing frames 12. After reinforcement, the following specified operations are performed, which give preference to the proposed method, namely: install "g from the formwork, mark the contour of the plate with beams 1, 2; lay out the nets of the lower layer 9 according to the project, lay out the three-dimensional frameworks 7 of the supporting beams 1, and then the secondary beams 2. After that, the concrete of the lower layer is laid and the insulating slabs-liners 4 are installed, thus forming a formwork for receiving concrete for main beams 1 and secondary beams 2.

It is possible to implement the invention with the laying along the contour of the formwork plate made of facing brick 14 and with ordinary brick 15. After that, the mesh 10 of the upper layer of the concrete floor slab is laid and the concrete is laid along it. After the concrete has partially hardened, a layer of semi-dry bulk material with high dissipative losses is placed over it.

Such a solution allows to ensure the achievement of the set task due to: - increasing the module of losses in the system of a box plate with light mass elements and a dissipative "interlayer; - c - increase in energy losses when passing through a system with different stiffnesses and loss modules; - a significant decrease in the unit density of the floor slab; c - the possibility of a continuous cycle of installation of building ceilings; - reduction of material costs, especially concrete; - the possibility of ensuring a highly rigid connection and compatible spatial operation of the floor slab with other building structures; - defect-free structure of the plate surface. The conducted studies have confirmed the high efficiency of the proposed solution, which allows to implement it in construction without significant expenditure of money and resources. with

Claims (4)

The formula of the invention ch 1. The method of manufacturing a honeycomb floor slab, which includes the installation of formwork, the layout of the grid of the lower layer of the slab, the layout of reinforcing space frames mutually perpendicular to each other, the laying of polystyrene material plates, the layout of the grid of the upper layer of the slab and the operations of forming GF) of the lower and upper concrete layers and slab beams, which differs in that after laying out the mesh of the lower layer, the frames of the supporting beams are first laid out, and then secondary beams with the formation of honeycomb cavities between the frames, after which the concrete of the lower layer of the slab is laid, on which at a distance from the frames in cavity-honeycombs, insert slabs made of polystyrene material are installed, between which a concrete mixture is laid, forming the main load-bearing and secondary beams, after which an additional formwork of facing bricks is laid along the contour of the slab on the formed surface, the mesh of the upper layer is laid out and it is poured with concrete mixture, on which, after its partial hardening, place a layer of semi-dry bulk material. 65 2. A cellular floor slab made by the method according to claim 1, which is characterized by the fact that it contains the lower and upper reinforced layers, the main and secondary supporting beams are located in a mutually perpendicular direction, having reinforcing spatial frameworks that form a box-honeycomb structure between them with inventory plates-inserts made of polystyrene material with lateral vertical surfaces placed inside the honeycombs, in the space between which a concrete mixture is placed, and the upper layer contains a layer of semi-dry bulk material with high dissipative losses . 3. The plate according to claim 1, which differs in that polystyrene foam of the brand is used as a polystyrene material ON. 4. The slab according to claim 1, which differs in that a sand mixture with a cement component is used as a layer of semi-dry material. with 7 o (ze) (Se) with Zo so - and? so ko (22) o ko 60 b5