RU2277619C2 - Building panels, foundation structure, three-dimensional building structure, methods for three-dimensional building structure erection and building heat insulation - Google Patents

Abstract

FIELD: building, particularly three-dimensional framework structures.

SUBSTANCE: building panel comprises frame members, connection means, which connect frame member one to another to create laminated frame in frame plane. The laminated frame includes steel members and hardened flowing material layer defining inner cavity, as well as insulation means located in the cavity. Hardened flowing material layer is made as flat asbestos cement sheet installed so that the sheet adjoins outer steel frame layers and may be detachably fastened thereto. The connection means are made as threaded members arranged in frame cavity and as orifices for threaded member receiving. Heat insulation means is made as expanded vermiculite located in frame cavity after three-dimensional building structure erection at building site. Method of building panel production, foundation structure, three-dimensional building structure, method of three-dimensional building structure production and method of building heat-insulation are also disclosed.

EFFECT: increased heat insulation and soundproof properties, possibility of compact three-dimensional building structure panel member storage and transportation together with foundation structure members, provision of incremental building frame erection without climbing crane usage, improved manufacturability and reduced operational costs regardless of weather conditions.

16 cl, 15 dwg

Description

The invention relates to the construction of buildings from structural elements of factory production.

The invention will find predominant use in the construction of housing and offices of various floors in areas remote from the construction industry, including with a short construction season, with difficult climatic conditions, weak soils and permafrost.

Known building panel by application EP No. 0381000, class. E 04 C 2/38, 1990, containing a reinforcing frame of longitudinal and transverse metal profile elements that limit the panel around the perimeter. Elements are fixed in 2 reinforced concrete layers with the formation of the internal cavity of the panels in which the insulator is installed. The insulator can be made of granular or dense thermally insulating and / or lightweight material in the form of a panel made in the size of a building panel. For hardening, metal racks and rods with grids installed on them are introduced into the panel. The panels are connected to the structure using threaded connections, and the joints are poured with concrete.

Such a panel is an example of a non-separable panel with all the signs and disadvantages of manufacturing, installing, insulating, transporting it to a site remote from the construction industry, resulting from reinforced concrete panels.

As a prototype, the technical solution according to patent No. 21121044 (publ. 10/27/1998, prosp. USA applicant Ar.A. Ar. Consultants Ltd.) was chosen - “Building panel, method of its manufacture and the foundation building block created on this basis, the foundation of the structure, the three-dimensional building structure, the high-rise building and the three-dimensional structure, as well as the method of attaching the details of the architectural decoration to the surface of the structure. "

The panels include hollow pipes of rectangular cross-section, located along the perimeter in the frame plane, serving simultaneously as fixed formwork and steel frame of the panel. The internal cavity of the pipes is provided for laying communications. On the outer surface of the frame, welded hooks are provided for fastening the tightening cables, as well as other fasteners for pulling reinforcing meshes located in 4 planes. In the middle plane between the pipes and the planes of the nets and cables, a foam insulator is provided, in the manufacture of which longitudinal, transverse and diagonal recesses are provided on both sides for the internal reinforcing ribs reinforced with cables, which form when the external layer is solidified.

The panel also provides a second tension wire mesh, stretched between the frame elements, spaced from the first tension wire mesh, and further comprises another hardening fluid material poured over the nets on the other side of the panels, as well as additional deflection means on the other side of the panel reinforcement.

The disadvantages of building panels.

- Famous panels are non-separable reinforced concrete structures, which makes it difficult to transport and assemble them at a construction site, while requiring cranes;

- they are laborious to manufacture;

- do not provide proper thermal insulation, which is one of the most important problems in the construction of a building for any purpose. This is explained by the fact that the foam does not overlap the cold bridges passing along the perimeter of the panel formed by steel pipes. In addition, due to the recesses on the insulation, the thickness, and hence its insulation, is not equal in area and limited by the minimum thickness in the furrows. An important disadvantage is that the foam insulator dries out over time, loses volume, and in case of fire it burns out even under a layer of concrete.

According to the method of manufacturing panels for their production, a stand for assembling the frame and formwork for pouring the lower layer is required, otherwise, when pouring the reinforcing layer from the top on the alternately two sides of the panel, 2 times more area and working time will be required.

Transportation of panels for the construction of the house is carried out through the construction of an octagonal container made in the form of an open box of mutually interconnected floor panels with the placement of all the elements necessary for building a house.

The disadvantage of such a container is that for laying heavy panels in the container and unloading from it requires special devices for capture by a crane, which are placed on each of the corners of the container. This leads to additional consumption of metal and non-returning elements made from it, which go into expensive waste, and additional nodes for connecting panels to a container require not only the costs of their manufacture, but also labor costs for assembling and disassembling the container.

The design of the container from the panels can lead to failure of the panels themselves included in the building kit, as a significant load is concentrated on them from the panels stacked in them.

The design of prefabricated strip foundation blocks is applicable to the claimed design of panel buildings, so the foundation blocks must be produced and delivered complete with the panels of the building. A special container is required for their transportation. It is possible to produce a foundation near the construction site, which may not always be the case due to unfavorable time for the construction season, as well as hydrogeological conditions.

The disadvantages of the foundation structure:

- the complexity of the assembly-disassembly;

- large specific pressure on the soil;

- the impossibility of building basements for storing food stocks due to the small depth of the foundation;

- the low basement does not protect the rooms of the first floor from flooding in the event of possible water elements and freezing, which can negatively affect the functioning of the water supply and sewerage laid in the canals, and when the soil freezes below the base of the foundation, significant heights that are not uniform in size can deform, and sometimes destroy the three-dimensional frame structure of the building, even from such durable panels

In the prototype, the design of the three-dimensional structure and the method of its manufacture from such panels practically does not differ from the installation of panel houses made of reinforced concrete using a construction crane. The three-dimensional structure is made of prefabricated panels of known construction, connected to a rigid frame with each other using threaded means of connection and pouring joints at the joints with concrete. Therefore, the structure is non-separable, and the manufacturing method is labor-intensive and depends on weather conditions and time of year.

An object of the invention is the creation of a construction of element-wise assembled building panels with high heat and sound insulation properties from non-combustible parts of full factory readiness, the creation of a foundation structure design that allows for complete storage and transportation of prefabricated elements of panels of three-dimensional building structures together with elements of a foundation structure ready for installation prepared construction site, as well as the creation of three-dimensional structures with full steel car ace and a method of manufacturing a three-dimensional structure with element-wise assembly of a frame of various storeys without lifting cranes and "crude" processes using simple threaded connections, as well as creating a method of insulation of panels of a three-dimensional structure, which allows to ensure the quality of the insulator, manufacturability and low cost of work, independent of weather conditions .

The problem is solved due to the fact that in the well-known building panel, including frame elements, means for connecting the frame elements to each other with the formation of a layered frame made of steel elements located in the frame plane and layers of hardened flowing material bounding the internal cavity, as well as an insulator located in her, according to the invention, a layer of hardened flowing material is made in the form of an asbestos cement flat sheet mounted adjacent to the outer layers of a steel cable casing with the ability to assemble and disassemble, and the insulator is made in the form of expanded vermiculite, placed in the frame cavity after manufacturing a three-dimensional building structure.

In this case, the steel layer of the carcasses of partitions and walls is made in the form of a welded frame, consisting of two vertical posts and two horizontal ties in the form of channels facing the periphery of the panel with the middle part, in addition, the frame of the carcass of the partitions and the inner layer of the carcass wall are equipped with horizontal strips.

Horizontal ties and fillers of the frame of the partition walls are provided with holes for filling the insulator, made as close as possible to each other, and the size of the holes is not more than the width of the middle wall of the channel.

Moreover, the middle walls of the uprights of the frames are provided with holes for interconnection with the adjacent walls of the uprights of the frames of the partitions and walls frames. On the inner surface of the walls of the frames of the frame cavity are welded bushings with threaded holes, the axes of which are perpendicular to the frame plane.

The intermediate layer of the metal frame of the wall is made of two vertical racks in the form of a thermo-profile of the channel section with the middle wall outward, and holes on the shelves for interconnection with threaded bushings welded to the frame posts.

The asbestos cement layer of the flat sheet is provided with holes with recesses for a countersunk screw for interaction with threaded bushings on the frame of the frame.

In this case, first, according to the template, holes are drilled directly in the asbestos-cement flat sheet for walls. For partitions, holes are drilled simultaneously in two sheets folded together, then in these holes recesses are made under the countersunk head of the screw and the corresponding screws are installed, to which on the other side of the sheet plane the connecting elements are screwed in the form of threaded bushes, after which the sheet is turned upside down and to they are joined by frame racks, to which horizontal ties and strips are installed, after which the threaded bushings are electrically welded to the frame racks and at the joints of these elements.

In the construction panel of the attic, a layer of hardened flowing material adjacent to the steel frame of the wall of the attic from two sides is made of polycarbonate plastic, while the plastic of the outer layer at the bottom has an elongated end.

The frame of the overlap panel includes four beams made of a bent channel, pairwise and parallel located along the perimeter of the room to be blocked, and two layers of intermediate beams placed mutually perpendicular to each other along the axes of the modular grid, while the middle walls of the channel beams of the perimeter are provided with two rows of holes for interaction with the intermediate beams of the layers, and the number of intermediate beams in each layer corresponds to the number of intermediate axes, in addition, the intermediate beams of the upper layer I, having an I-section, are mounted with the possibility of supporting their ends on the supporting corners attached to the lower row of holes, and secured with the help of corner plates with their connection to the upper row of holes, and the ends of the (suspended) intermediate beams of the lower layer are fixed with corner elements to the lower a row of holes of the second pair of parallel beams of the perimeter, and at the junctions of the intermediate beams of the upper and lower layers at the intersection of each axis to the lower beams are suspended lower beams connected in an I-beam using the limbs cut out on the upper shelf of these beams made of two bent channels, the asbestos cement sheets in the lower part are installed on the lower shelves of the suspended beams and the lower shelves of the perimeter beams, and in the upper part they are installed on the upper shelves of the beams.

In the layered frames of the proposed building panels (partitions, walls, ceilings), elements of the traditional profile section of the full factory readiness of light weight are used, which allows you to do without lifting equipment in the manufacture of individual elements in the workshop or panels when assembling them at the construction site. The use of simple threaded connections provides quick assembly or disassembly of the panel in case of relocations.

The use in the panels of walls and partitions of a flat asbestos-cement sheet provides increased diagonal stiffness of the frame frames in the plane of the frame, as well as additional strength and rigidity in the vertical plane of the supporting walls perpendicular to the frame, because in its structure, asbestos fibers bound by a cement hardened layer play the role of reinforcement in a thin-walled concrete product, therefore, the sheet has high compressive, tensile and bending strength, while asbestos fibers are not an obstacle for drilling and sawing of the material, therefore, sheets are made by existing technical means the specified sizes, with the holes specified for fastening to the frame and the weight acceptable for manual assembly. In addition, this material has high fire resistance and protects metal structures from fire in case of fire, and its high waterproof and vapor barrier properties make it possible to reliably protect the vermiculite insulator from external precipitation and internal fumes.

The use of standard sections in the rental panels allows for maximum load-bearing characteristics at the minimum steel consumption.

The method of joining asbestos-cement sheets with frame frames and threaded elements allows for simple alignment of threaded joints.

The use of a channel cross-sectional thermal profile in the intermediate wall layer of thin galvanized steel while maintaining the strength of the connection of the carcass layers and reducing heat loss provides a well structure of the walls, which makes it possible to backfill them with an insulator from the attic of the structure. The open-top well structure contributes to the natural ventilation of the insulating layer, which favorably affects the quality of the insulator during operation.

The use of a bent steel channel as the beams of the overlapping panel located around the perimeter of the overlapping three-dimensional structure provides horizontal connection of the vertical frame frames in the plane of the walls located around the perimeter of the three-dimensional structure, and the longitudinal and transverse beams located in two layers along the intermediate axes of the axial grid provide rigidity to horizontal connections with the help of fasteners to the middle wall of the bent channel, where two horizontal rows of holes coincide with the threads bushings on the plane of the joint of the frame frames, which allows one frame to connect three frame elements: a wall stand, an adjacent beam and an axial beam, which ensures the indestructibility of the floor panel during earthquakes, because all frame elements are connected to the frame of the bearing walls and partitions, and the vertical plane of the middle wall of the channel adjacent to the junction planes of the frame frames of the walls and partitions provides their vertical stiffness at the joints, which reduces flexibility and increases the strength of the bearing racks.

The design of the floor panel with intermediate longitudinal and transverse beams provides a relatively uniform distribution of the load from the floor and from the load on the floor to all four rows of racks located along the perimeter, and not to two parallel bearing walls in a traditional structural design with load-bearing walls.

The middle wall of the channel located around the perimeter, equipped with two horizontal rows of holes intended for connection in the ceiling structure over the foundation building with the foundation structure, and in the floor ceiling structure - for connection with the frame of the walls and partitions of the next floor, including the attic, provides strong connection of frame frames in the horizontal and vertical planes of walls and partitions and connects them with the foundation structure, which ensures the indestructible structure of any number of storeys during hurricanes and earthquakes.

The angles of support of the ends of the intermediate beams of the upper bearing layer are used in the design of the floor frame to transfer the load to the middle wall of the channel connected to the frame frames of the walls and partitions, and therefore, on the racks of these frames, as well as for the convenience of mounting the beams of the upper intermediate layer on which to support the ends of the mounted intermediate beams, fixing their ends with a pair of corner connecting elements and means of threaded fastening.

The design used bent thin-walled channels around the perimeter and bent thin-walled channels of suspended intermediate beams, which are made of steel tape of the same thickness and with the same bending radii of the shelves, which provides a single horizon for supporting asbestos-cement sheets on the lower shelves of these channels, and two horizontal rows of holes on the middle the channel wall and folding elements of fastening on the upper shelf of the channel of the hanging beams are more technologically feasible to execute on the sheet before the bend of its shelves, since and the holes and bends are set by axial breakdown, which ensures the combination of all operations in one rolling machine, and, as a result, reduces the cost of the fastening element of the suspended beams in comparison with traditional elements of the threaded fastening.

The use of threaded bushings with threading along its entire length, made of a steel tube on a lathe and welded at the points of contact with the elements of the frame frame in its internal cavity, allows the frame frame to be provided with threaded elements on both sides of its frame plane, which are uniformly distributed throughout the height of the racks between the strips and in the corner joints of horizontal ties and vertical racks designed to connect with the middle wall of the channel of the perimeter of the overlap panel, with this sleeve, welded in the corners of the joint with the filler and the connection, provides the frame frame with additional diagonal strength and rigidity in these corners.

The removable construction of asbestos-cement flat sheets from a metal frame allows the device of building panels to have frame connection elements hidden in the internal cavity and to provide element-wise assembly of a three-dimensional building structure in a simple manner.

The implementation of the insulating material in the form of expanded vermiculite, filled up in the cavity of the panel after the building is completely ready, increases the heat-insulating properties of the wall panel and the sound-insulating properties of the partitions. Holes made as close as possible to each other in horizontal connections and nashcheliki frameworks of partitions, create channels for the unhindered passage of expanded vermiculite into the internal cavity of the panel when it is backfilled.

The problem is also solved due to the fact that the foundation structure, containing the foundation blocks of the molded hardened flowing material, each of which has a sole, a support part, a channel running along the length, and openings to provide access to the channel and for means of connecting to a similar block, according to the invention, the foundation blocks are made in the form of a pair of volume blocks, and the foundation structure is equipped with a second pair of volume blocks forming the basement, while the lower blocks of both pairs are made in the form of a “trough”, and the upper ones are in the form of a “cap” and have the shape of rectangular parallelepipeds, the internal cavities of which are container containers for laying and transporting a complete set of building structures and elements necessary for the manufacture of a three-dimensional building structure of a one-story house or for the next floor, respectively, while the opening made in the bottom of the “trough” of the upper block is aligned with the opening on the “cap” of the lower base block, and a steel butt joint is installed between each pair of foundation blocks a girdle over the entire joint area of the abutting walls made of an I-beam, the width of the middle wall of which is not less than the width of the abutting walls of the blocks, each docking belt being rigidly fixed to the abutting wall of the lower block, and at one of the ends of the pair of volumetric blocks forming the basement mortgages and openings for garage doors, in addition, the upper surface of the basement unit is provided with units to which cantilever beams can be installed with the possibility of disassembly and adjustment in the horizontal plane for widening I support surface.

The internal cavity of the “trough” of the foundation block and the “trough” of the upper block of the basement are made in the form of a bowl of pools equipped with drain holes, and the “caps” of the blocks are provided with openings for maintenance and lighting.

The implementation of the foundation structure in the form of underground and aboveground parts made of reinforced concrete in the form of assembled from two halves: in the lower one in the form of a “trough” and the upper one in the form of a “cap”, creates assembled in the inner cavity underground and elevated rooms intended for use as a useful area, namely for a cellar and garage or for underground and aboveground pools, or the like.

The foundation structure may consist of one set of blocks under a single-family house of two residential floors and an attic floor or a larger set of blocks arranged in rows for apartment buildings with a common staircase or multi-storey office with a set of premises for the pool, warehouses, workshops and garages.

The internal cavities of volumetric blocks in the form of rectangular parallelepipeds create containers for storing a set of structural elements in them for a single-family house or an apartment building.

The large area of the support of the lower half of the buried part of the foundation structure helps to reduce the specific pressure on the ground, which allows you to build buildings on soils that are weak and weakened during floods.

The foundation structure of two pairs of volumetric blocks eliminates the flooding of residential floors in places prone to flooding.

The combination of the openings in the "cap" of the foundation block with the opening in the "bottom" of the basement block allows the fastening of the connecting elements during the assembly of the building and the laying of communications.

The installation of a steel belt at the junction of two blocks made of an I-beam, along the entire length of the joined walls, ensures their fixation from shear during transportation with cargo to the construction site, as well as during operation.

The installation of a steel frame on the supporting surface of the upper block of the basement with attachment points ensures the transfer of load to the interconnected basement blocks of the basement.

The foundation of the proposed design is easily disassembled in the event of a relocation or reconstruction of the building and is again transformed into a transport container, in addition, the construction time is significantly reduced, high quality and construction are provided at any time of the year.

The problem is also solved due to the fact that in a three-dimensional building structure, including building panels, each of which contains frame elements, means for connecting the frame elements to each other with the formation of a layered frame made of steel elements in the frame plane and a layer of hardened fluid material bounding the internal cavity , as well as means for connecting the panels to each other and connecting elements for interacting with the corresponding means of connecting each panel for closing insulating adjacent panels with each other, while the frame elements of adjacent panels form a rigid frame that defines the shape of the building structure, according to the invention, the layers of hardened fluid material are made in the form of asbestos-cement flat sheet installed adjacent to the outer layers of the steel frame with the possibility of assembly and disassembly, and the means of connecting the frame elements are made in the form of threaded elements with their placement inside the frame plane, and the connecting element of the frames is a burnout the dock is made in the form of a square tube, the length of which is equal to the height of the interfloor space and provided with holes for connecting the partition wall frames, the square section of the connecting element corresponding to the thickness of the joined partitions, and the connection of the inner layer of the wall frame with the adjacent partition is made in the form of a vertical rectangular pipe, the cross-sectional dimensions of which in the plane of the joined partition correspond to its thickness, and in the plane of the inner frame of the wall, respectively corresponds to the thickness of the frame of this layer and the thickness of one layer of asbestos-cement sheet, and three walls of such pipes are provided with holes for interaction with means of connection with adjacent frame elements, and the fourth wall is equipped with mounting holes, while the beams made of a bent channel are arranged in pairs and in parallel along the perimeter of the room to be covered, and two layers of intermediate beams are placed mutually perpendicular to each other along the axes of the modular grid, while the middle walls of the channel beams of the perimeter fitted with two rows of holes for interaction with the intermediate beams of the layers, and the number of intermediate beams in each layer corresponds to the number of intermediate axes, in addition, the intermediate beams of the upper layer having an I-section are installed with the possibility of supporting their ends on the support angles attached to the lower row of holes , and fixed with the help of corner elements with their attachment to the upper row of holes, and the ends of the suspended intermediate beams of the lower layer are fixed with corner elements to to the lower row of holes of the second pair of parallel perimeter beams, and at the junctions of the intermediate beams of the upper and lower layers at the intersection of each axis, lower beams are suspended from the upper beams made of two bent channels connected to the I-beams by means of bends cut on the upper shelf of these beams, in this case, asbestos-cement sheets in the lower part are installed on the lower shelves of the suspended beams and lower shelves of the perimeter beams, and in the upper part the sheets are installed on the upper shelves, while on the middle wall of the floor beams s hole, the compounds with threaded bushings mounted in the corners of frames welded skeletons of partitions and the inner layer of the wall for pinching the ends of vertical supports three-dimensional structure.

Due to the installation of asbestos-cement sheets of removable panels, free access is provided to the means of connection located inside the frame plane in the form of threaded joints and to the fastening elements at the junction points of the frame elements during their installation and disassembly, reducing the production time by using element-wise assembly from elements of full factory readiness, eliminates the use of welding and wet monolithic technologies, and therefore allows assembly regardless of the season.

The overlap panel is the basic connecting element of the connection with its horizontal plane of the four vertical planes of the walls and partitions, and also contains interfloor elements located around the perimeter for interconnection with the above - and the underlying frame elements of the walls and partitions, which eliminates the destruction of a three-dimensional structure with a full steel frame. Embodiments of the connecting elements of the partitions and the inner layer of the wall with the partition made in the form of square and rectangular pipes, respectively, are options for providing a solid collapsible connection of the panels in two mutually perpendicular planes using threaded elements.

The objective of the invention is also solved due to the fact that in the method of manufacturing a three-dimensional structure, including attaching building panels to each other using connecting elements and to the supporting surface of the base structure, according to the invention, a three-dimensional structure frame is made from elements of floor frames, partitions and walls, after which asbestos-cement sheets are attached to the frame surfaces with the formation of the internal cavity of the building panels and the panels themselves without an olator, in this case, first, on the supporting surface of the foundation structure, the frame of the lower overlapping panels is fixed, consisting of beams made in the form of channels located along the perimeter of the overlapping three-dimensional structure, as well as intermediate transverse and longitudinal beams located in the upper and lower layers along the axes of the modular grid , after which the vertical elements of the framework walls and walls are installed, their lower joints are attached to the middle wall of the channel located around the perimeter, and with each other using the element goods and means of connecting vertical elements, then to the upper joints of the vertical elements of the walls and partitions frameworks, beams of the upper floor are installed around the perimeter, after which intermediate beams of the upper and lower layers along the axes of the modular mesh are installed, followed by fixing the ends of these beams and beams to each other in their places intersections and junctions.

In the method of manufacturing the attic structure, the steel frame of the attic wall panel is laid on the floor of the lower floor, the elongated end of the polycarbonate plastic of the panel is connected to the upper horizontal connection of the outer frame layer of the wall with the formation of a slope, after which the frame of the panel wall is lifted to a vertical position and joined by a joint at the bottom to the channel beam of the perimeter of the overlapping room, and the installation of the upper panel of the attic is carried out in the order of assembly of the floor, but with filling the insulator to the roof, while along the perimeter of the floor beams in the upper part set the trays for water drainage with the help of connecting elements and means of connection to the upper row of openings of floor channels, and the racks of the steel frame are joined and the insulator is filled into the walls with the removed polycarbonate inner layer plastic, while the top layer of asbestos-cement flat sheets of the roof panel is applied with mastic and an additional asbestos-cement flat sheet is glued.

The connection of the elongated end of the plastic with the upper horizontal connection of the outer frame layer of the wall protects it from water entering the wall, creating a reliable fence, because a flexible sealant of known design is inserted into the seam between the layers of plastic, and the connection method provides a safe possibility of such a connection.

The method of element-wise assembly allows you to erect buildings from elements of full factory readiness without lifting mechanisms using threaded connections with the formation of the internal cavity of the partition walls, walls with a well structure of the panels themselves to place an insulator in the form of expanded vermiculite at the end of the construction of the building with a roof. Threaded connections during assembly also allow in the case of relocations to carry out quick element-by-element disassembly of the building without loss of structural elements.

During the construction of residential, industrial and agricultural buildings made of panels, high demands are placed on thermal insulation, namely fire resistance. Durability, manufacturability and thermal protection efficiency.

Laminated panels are known in the prior art in which structural elements form an internal cavity into which the insulation is filled. So, there are known technical solutions "Panel and method of its manufacture" according to patent No. 2158338, Russia, IPC 6 E 04 C 2/26, decl. 04/12/1999, publ. 04/20/1995, the panel frame and sheet sheathing when connected to each other form cavities that are filled with a loose filler. This filler is enclosed in a vapor barrier.

The disadvantages of the panel made in this way are insufficient thermal insulation, heavy filler ineffective in thermal insulation that does not meet the modern requirements of thermal protection of buildings, as well as problems associated with the transportation of panels, in which the insulating mass is compacted and voids form in the panel, which will negatively affect the efficiency thermal protection erected from these building panels.

In a well-known building panel according to the application EP No. 0381000, class. E 04 C 2/38, 1990, adopted as a prototype, longitudinal and transverse metal elements limit the panel around the perimeter. Elements are fixed in 2 reinforced concrete layers with the formation of an internal cavity into which the insulator is filled. The insulator may be made of granular thermally insulating material.

The disadvantage of this method is the seal (sludge) of the insulator during transportation of the panels to the construction site, the formation of voids, which will adversely affect the quality of thermal insulation of the building assembled from such panels. At the same time, it is impossible to control the heat insulator during the operation of the building and eliminate drawdowns.

The objective of the invention is to provide a method of warming a building, providing improved thermal insulation qualities of the building and the manufacturability of insulation work.

The problem is solved due to the fact that in the method of warming a building by filling the insulator into the internal cavity of the panels included in the building structure, according to the invention, filling the insulator is carried out after the building is completely erected under the roof, while in the walls and partitions with a well structure - from the attic , into the walls under the window - through the removable window sill, into the walls and partitions under the doorway - through the removable threshold, and into the ceilings - through the removable asbestos cement sheets of the upper layer of the panels.

The claimed method of warming a building provides high-quality backfill from the attic floor of the building after its complete erection, except for the floor panel of the attic. Expanded vermiculite is used as an insulator, in which the “elongated accordions” of expanded mica are placed during filling in such a way that the mica plates are arranged vertically, and in this position the vermiculite layers do not sag due to the weight of the overlying layers. Expanded vermiculite has long hydrophobic properties when it is produced on a microwave device by the method of patent No. 2227380.

The patent studies did not reveal identical and similar technical solutions, which allows us to conclude that the claimed technical solution is new.

The proposed technical solution can be implemented on an industrial scale and is applicable in the production of buildings and structures erected at sites remote from the construction industry at any time of the year.

The invention is illustrated by drawings, where

- figure 1 shows a factory-made building being erected on a foundation structure by element-wise assembly;

- figure 2 - blocks of the base structure, underground floor;

- figure 3 - blocks of the base structure forming the basement of the house;

- figure 4 is a foundation structure of two floors with pools and an extended support for a three-dimensional structure;

- figure 5 is a panel of the partition;

- figure 6 is a wall panel;

- Fig.7 - wall panel assembly (horizontal section);

- Fig. 8 is a wall panel above a window; under the window;

- figure 9 is a three-dimensional building structure (without a fourth wall);

- figure 10 is a section aa in figure 9;

- Fig 11 is a section of the ceilings and walls of the attic with trays and nodes for their attachment to the frame;

- Fig.12 - the connection node of the inner layer of the frame of the wall with the frame of the partition (in three-dimensional design);

- Fig.13 - the connection node of the frames of the partitions;

- in Fig.14 - the construction of pinched racks and the design diagram of the bearing capacity;

- Fig.15 - connection of a light interroom hollow partition with asbestos cement layers of the ceiling and floor.

Building 1 (Fig. 1) includes a foundation structure 2, consisting of foundation blocks 3, 4 and basement blocks 5, 6, wall panels 7, window sills 8, window sills 9, floor panel 10, cover panel of the attic room 11, panel fences of the flight of stairs 12, corner panels 13, panel of partitions 14, panel of walls above door 15, panel of partitions above door 16, panel of walls of the attic 17.

The base blocks 3, 4 are made in the form of two volumetric blocks, one of which (3) is made in the form of a “trough”, and the other (4) in the form of a “cap”. The blocks are rectangular parallelepipeds. The internal cavities of the blocks 18 are used as container containers for laying and transporting a complete set of building structures and elements necessary for a three-dimensional building structure of a one-story house. Between these blocks a docking belt 19 is installed over the entire joint area of the abutting walls, made of an I-beam, the width of the middle wall of which is not less than the width of the abutting walls.

The second pair of building blocks included in the foundation building 5, 6 forms the basement. Volumetric blocks are mounted on the supporting part of the “cap” 4 of the foundation block and are made in the form of a “trough” 5 of the cap “6” and have the shape of rectangular parallelepipeds. The internal cavities of this pair of blocks 18 are also used as container containers for laying and transporting a complete set of building structures and elements necessary for assembling the next floor of the three-dimensional building structure of the building.Apertures (manholes) 20 made in the bottom of the “trough” of the basement floor block 5 and in the “cap” of the foundation building block and 4, are combined to perform maintenance and input into these three-dimensional structures.

Between blocks 5-6 of the basement is installed docking belt 21 over the entire area of the joint. According to one embodiment, in the “cap” in one of the ends of the basement, mortgages 22 and openings 23 for garage doors are made. On the upper surface of the “cap” 6 of the basement unit, fastening units 24 are mounted for interaction with the frame of the three-dimensional building structure.

The base structure (figure 4) can be made in the form of pools: for storing water and lower bathing - upper.

Building panels include frame elements 25, means for connecting 26 frame elements to each other to form a layered frame made of steel elements located in the frame plane and a layer of hardened fluid material 27 defining the internal cavity and the insulator 28 located therein. The layer of hardened flowing material 27 is made in the form of an asbestos-cement flat pressed sheet installed adjacent to the outer layers of the steel frame with the possibility of assembly and disassembly. Means for connecting the frame elements 26 are made in the form of threaded elements and placed inside the frame plane. The insulator 28 is made in the form of expanded vermiculite, which is placed in the frame cavity after the construction of a three-dimensional building structure.

All elements of the steel frame included in the panel of partitions, walls and floors, as well as asbestos-cement sheets are elements of full factory readiness. They can be cut with high precision using computer technology. The steel layer of the carcasses of the partitions 29 and the walls 30 is made in the form of a welded frame, consisting of two vertical posts 31, two horizontal ties 32 in the form of channels, while the outer edge of the middle wall 33 of the channel is located around the perimeter from the outside, in addition, the frame of the partitions frame 29 and the inner layer of the frame of the wall 30 is provided with horizontal slats 34 in the form of the same channel. All frame elements are made of rolling channel No. 5 by cutting to size. In this case, the ends of the strips 34 are cut off at right angles, and the ends of the struts 31 and horizontal ties 32 are cut off for joining to the “mustache” at an angle of 45 so that the outer edge of the middle wall 33 of the channel is located around the panel perimeter from the outside.

Before welding into the frame in horizontal ties and overlays of the frame of the partition wall frame, holes 30 with a diameter of 30 mm are drilled or holes 30 × 30 mm are cut with a laser with a maximum approximation to each other to fill the insulator 28 into the internal cavity after the construction of the building.

The middle walls of the uprights of the frames 29 and 30 are provided with openings 36 for interconnection with the adjacent uprights of the frames of the partitions and walls frames.

In the inner cavity of the frame of the frame to the inner surface of the frame around the perimeter and in the corners are welded sleeves 37 with threaded holes, the axis 41 of which are perpendicular to the plane of the frame and its outer layers 38, joined with the asbestos-cement layer of the sheet 27.

The intermediate layer 39 of the metal frame of the wall is made of two vertical racks in the form of a thermo-profile of the channel section with the middle wall located in the same plane as the middle walls 33 of the channels of the racks of the frame 30 of the frame of the inner and outer layers.

The asbestos cement layer of the flat pressed sheet 27 is provided with holes 40 with recesses for a countersunk screw 42 for engaging with threaded bushings 37 on the frame of the frame 35.

For the accuracy of making these holes, they are drilled directly in the asbestos-cement flat pressed sheet of the rack according to the template, and for partitions, holes are drilled simultaneously in two sheets folded together, recesses are made for the head of the countersunk screw and these screws are installed 42. To these screws on the other side of the plane the asbestos-cement sheet 27 is screwed onto the threaded bushings 37, after which the sheet is turned upside down and the racks of the frames 29, 30 are joined to them, to which horizontal ties 32 and strips 34 are connected, and then welded threaded bushings 37 are connected to the steel elements of the frames and at the joints of these elements.

The frame of the floor panel is made at the construction site from the finished elements. The frame includes four beams 43 from a bent channel for placing them around the perimeter of the room to be blocked. The frame also includes two layers of intermediate beams placed mutually perpendicular to each other along the rails 44 of the modular mesh. On the middle walls of these beams 43 of the perimeter are made in two rows of holes 45 for interaction with the intermediate beams of the layers. At the ends of the intermediate beams there are openings 46 for threaded connection by a pair of corners 47 and 48, which are screwed through the hole 45 in the channel wall 43 to the sleeve 37 of the frame of the walls 30 and partitions 29. The number of intermediate beams in the upper and lower frame layers corresponds to the number of intermediate center lines 44.

The longitudinal beams located in the lower frame layer 50 are made of channels that are paired into an I-beam with folding elements 51 for interaction at the junctions with the transverse beams 52 located in the upper frame layer.

In a specific embodiment, the beams are cut to the desired length. The length of the beams in the upper frame layer 52 is equal to the length of the channel of the beam 43 of the perimeter, reduced by the size of the double size of the width of the shelves. The length of the beams in the lower frame layer is equal to the length of the beam 43 of the perimeter, reduced by the size of the double size of the width of the shelves 53 of the channel. In the construction, supporting beams 52 from I-beam No. 10 and hanging beams 50 from a bent channel 80 × 50 × 4 mm and 43 bent channel around the perimeter 180 × 50 × 4 mm were used.

The wall panels of the attic room 17 differ from the partition wall panels 14 in that a layer of hardened flowing material instead of asbestos-cement flat sheets 27 adjacent on both sides to the steel frame 29, a layer of plastic 54, 55 (polycarbonate) is applied, while the outer layer 55 of plastic at the bottom is made with an elongated end 56

The wall panel above the window 8 and the wall panel under the window 9 include the outer layer of the frame 30 and the inner layer of the frame, as well as the intermediate layer of the frame from the thermoprofile 39 and asbestos cement sheets 27.

The window sill panel 9 is located under the window opening between two ordinary panels 7 of the inner and outer layer of the wall and has a width that is a multiple of the width of the ordinary panels or axial modular grid. It consists of 3 layers of the frame 30, 39, 30 and 2 layers of panel coating 27, connected by fasteners 37, 42, 49 to each other and to ordinary neighboring panels. Filling insulator 28 is carried out in the window sill 9 of the wall. Vertical elements 39 of the middle layer are made of thermoprofile with the same design parameters and properties as in the wall panel. Its width is a multiple of the axial modular grid 44.

The three-dimensional building structure includes building panels (partitions 14, walls 7, floors 11), each of which contains frame steel elements 29, 30, 43, 50, 52, means for connecting the frame elements 37, 49, 42 to each other with the formation located in the frame the plane of the layered frame of these elements and the hardened fluid material layer 27 defining the inner cavity 28, as well as the means for connecting the panels to each other 57, 58 and the connecting elements 59, 60, 61 for interaction with the corresponding means of connecting each panel to secure adjacent panels to each other. The layers of the hardened fluid material 27 are made in the form of an asbestos cement flat, mounted adjacent to the outer layers 38 of the steel frame with the possibility of assembly and disassembly. Means for connecting the frame elements are made in the form of threaded elements 37, 59, 60, 61, 45, 49, which are placed inside the frame plane.

The connecting element of the frames 29 of the partitions 14 is made in the form of a vertically arranged pipe 57 of square section. The length of the pipe is equal to the height of the interfloor space. Holes 45 are made on it for connecting means 59, 60 of the framework walls. The side of the square section of the connecting element 57 corresponds to the thickness of the connected partitions 14

Instead of a square tube, a “C” -shaped profile of the same section can be used.

The connecting element of the inner layer of the frame of the wall 7 with the adjacent partition 14 is made in the form of a vertical rectangular pipe 58. The dimensions of the pipe section in the plane of the attached partition 14 are made in the size of its thickness, and in the plane of the inner frame of the wall 7 is made in the size of the thickness of the frame of this layer, and in the thickness size of one layer of asbestos cement sheet 27.

On the three walls of the pipe 58, holes 45 are made for interaction with means of connection 60, 61 with adjacent frame elements 29, 30, and mounting holes 62 are made on the fourth wall.

Two longitudinal and two transverse beams 43 of the lower 11 and upper 11 floor panels are made in the form of channels No. 18 and are installed along the perimeter of the room to be blocked with the formation of an interfloor connection and a connection of vertical elements 29, 30, 7, 13, 11 of a three-dimensional structure with horizontal longitudinal and transverse beams 43, 50, 52 in the upper and lower layers of the overlap.

On the middle wall of the beams of the perimeter 43, holes 45 are made for connecting with threaded sleeves 37 installed in the corners of the welded frames of the frameworks of the partitions 29 and the inner layer of the walls 30 to ensure pinching of the ends of the vertical posts of a three-dimensional structure.

The three-dimensional structure of the attic includes longitudinal and transverse beams of the lower 11 and upper 11 floor panels with their placement along the perimeter of the room to be blocked and along the axial lines and connecting to the frame of the walls 17, covered on both sides with plastic layers 54, 55, fixed with screws 62. In the upper a layer of the panel (roof), the asbestos cement sheet 27 is covered with mastic 63, on which a thin asbestos cement sheet 64 is installed. The tray 65 for the directional drain is fixed with a bolt and nut 60 to the inter-channel channel 43.

All elements of the steel frame of the partitions 14, walls 7, ceilings 11, asbestos-cement sheets 27 for joining with them to form panels, connection means 37, 42, 45, volume blocks 3, 4, 5, 6 of the base structure 2 are manufactured in the shops of the enterprise they are stored element-wise and transported to the assembly building site, where the building elements are connected to the supporting structures and to each other by threaded connections 37, 49, 53, 60, 61 into a three-dimensional building structure.

A method of manufacturing a three-dimensional structure includes attaching building panels to each other using connecting elements and to the supporting surface of the foundation structure.

A three-dimensional structure frame is made element-wise and sequentially from elements of floor frames 11, partitions 14 and walls 7, after which asbestos-cement layers 27 are attached to the surfaces of the frame to form the internal cavity 28 of the building panels and the panels themselves without an insulator.

First, two longitudinal 43 and two transverse beams from the bent channel of the lower overlap panel 11 are fixed with bolts on the supporting surface of the basement floor of the base structure to the docking steel belt 66 with bolts around these. The beams are equipped with two rows of holes 45. The intermediate beams 50, 52 are located in two layers along the axes of the modular mesh 44.

Support angles 67 are fixed to the lower row of holes with bolts 49, after which intermediate beams 52 of the upper layer are mounted on them. These beams on both sides from both ends are fixed with corner elements 47 with bolts 46, 49.

The intermediate beams of the lower layer 50 are positioned along the axes 44 of the modular mesh, mutually perpendicular to the intermediate beams 52 of the upper layer, and suspended from them. Beams 50 are made of paired bent channels connected to each other by a middle wall, forming a double tee. At the junctions 44 of the intermediate beams 50 and 52 with each other in the upper shelves of the channels of the hanging beams 50, cutouts 51 are made, which, with their limbs, cover the lower shelves of the upper beams 52, thereby eliminating displacement. The ends of these beams are connected by two pairs of corner joints 48 with the channel wall 43 forming a perimeter. After that, flat asbestos cement sheets 27 are laid on the lower shelves 68 of the paired channels 50.

Communications are laid in the internal cavities of the floor frames 11, walls 7 and partitions 14, after which the asbestos cement sheets are laid on the upper shelves 53 and the sheets 27 are attached to the vertical frames 29, 30.

The insulator 28 is filled in the form of expanded vermiculite in the internal cavity of the overlap panel 11 at the end of roofing by removing the upper layer 27, pouring the insulator out of the bags, aligning it along the upper edge with the subsequent installation of flat asbestos cement sheets in the same place. On these sheets, a finishing layer of linoleum or other coating materials can be installed.

After that, the vertical elements of the steel frames of the partitions 17, 29 and the walls 30 are installed, they are connected to the lower joints 69 to the middle wall 43 of the channel of the interfloor connecting beams, forming the perimeter with the help of threaded sleeves 37 and bolts 49, and with each other using the connection elements 57, 58 and bolts 59, 60, 61, and then to the upper joints of the vertical elements of the carcasses of the walls 30 and partitions 29, the longitudinal and transverse beams of the interfloor connection of the upper floor panel are installed in the same sequence as when installing lower pole overlap.

In accordance with Fig. 1, after installation and attachment of the upper floor panel, the construction of the first floor is completed. The overlap panel is the basic connecting element of the connection with its horizontal plane of the four vertical planes of the walls and partitions and contains the elements of the interfloor connection located around the perimeter for interconnection with the above- and underlying elements of the frame of the walls and partitions. The second, third and subsequent floors can be created in this way.

The manufacture of the attic construction completes the construction of the house.

A method of manufacturing an attic (three-dimensional) structure. The upper floor 11 of the three-dimensional building structure is the floor (lower floor) of the attic. The steel frame of the attic wall panel 30 is laid on the lower floor 11, the elongated end of the plastic layer 56 of the panel 17 is connected to the upper horizontal connection 32 of the outer frame layer of the wall with the formation of a slope, after which the wall panel frame is raised to a vertical position and attached at the bottom to the channel beam 43 of the perimeter of the overlapping room and carry out the installation of the upper panel of the floor 17 of the attic. Along the perimeter of the floor beams 43 in the upper part, trays 58 are installed for draining water using threaded connections 46 to the upper row of openings of floor channels. On the upper layer of asbestos-cement sheets 27 put a mastic on which an additional flat asbestos-cement sheet is glued.

In conclusion, they connect the racks of the steel frame 31 and fill the insulator into the walls with the inner layer 54 of polycarbonate plastic removed.

The method of warming a building by filling insulator 28 at the end of roofing ensures that the quality of the insulator is completely preserved from the effects of the weather - precipitation, wind, and also allows you to visually complete the filling of a light, well-laid insulator in the cavity of the walls, the well structure of which allows this method to be implemented.

The attic space can be occupied by a greenhouse, which gives income from planted vegetables. According to the author’s calculations, planting cucumbers, tomatoes, eggplants, greens and flowers over 10 years will pay off the costs of constructing a 2-story building.

Thus, the element-wise assembly and dismantling of the erected premises from elements of full factory readiness will make it possible to produce a house of any number of floors with any options for using any interior space of volume blocks of the base structure in any weather and in a short time, aimed at improving comfort, everyday life and for commercial purposes.

Claims (16)

1. The building panel, including the frame elements, means for connecting the frame elements to each other with the formation located in the frame plane of the layered frame of steel elements and a layer of hardened fluid material that limits the internal cavity, as well as an insulator placed in it, characterized in that the layer of the hardened fluid material is made in the form of a flat asbestos-cement sheet installed adjacent to the outer layers of the steel frame with the possibility of assembly and disassembly, the means are connected The frame elements are made in the form of threaded elements placed inside the frame plane and in the form of holes for the threaded elements, and the insulator is made in the form of expanded vermiculite placed in the frame cavity after the construction of a three-dimensional building structure on the construction site. 2. The construction panel according to claim 1, characterized in that the steel layer of the frameworks of the partitions and walls is made in the form of a welded frame consisting of two vertical posts, two horizontal ties in the form of channels, with the outer edge of the middle wall of the channel located around the perimeter with the outer the sides, in addition, the frame of the frame of the partitions and the inner layer of the frame of the wall are equipped with horizontal strips in the form of the same channel. 3. The construction panel according to claim 1, characterized in that the flat asbestos-cement sheet is provided with holes with recesses for a countersunk screw for engaging with threaded bushings on the frame of the frame. 4. The construction panel according to claim 1, characterized in that the skeleton of the floor panel includes four beams from a bent channel, pairwise and parallel located along the perimeter of the room to be blocked, and two layers of intermediate beams placed mutually perpendicular to each other along the axes of the modular grid, while the middle walls of the perimeter beams are equipped with two rows of holes for interconnection with the intermediate beams of the layers, and the number of intermediate beams in each layer corresponds to the number of intermediate axes, in addition, the intermediate The beams of the upper layer, having an I-section, are installed with the possibility of installation with their ends on the support angles attached to the lower row of holes, and are fixed with the help of corner plates with their joining to the upper row of holes, and the ends of the intermediate beams of the lower layer are fixed with corner elements to the lower a number of holes of the second pair of parallel beams of the perimeter, and at the junctions of the intermediate beams of the upper and lower layers at the intersection of each axis to the lower beams suspended lower beams made of two bent channels connected in an I-beam using bends cut on the upper shelf of these beams, while asbestos-cement sheets in the lower layer are installed on the lower shelves of the suspended beams and the lower shelves of the perimeter beams, and in the upper layer they are installed on the upper shelves of the perimeter beams.      5. The construction panel according to claim 1, characterized in that the layer of hardened flowing material adjacent to the steel frame of the walls of the attic from two sides is made of polycarbonate plastic, while the plastic of the outer layer at the bottom is provided with an elongated end. 6. The construction panel according to claim 2, characterized in that the horizontal ties and slatters of the frame walls of the partitions are provided with holes for filling the insulator placed in the inner cavity, made as close as possible to each other, and the size of the holes is not larger than the width of the middle channel wall. 7. The construction panel according to claim 2, characterized in that the intermediate layer of the metal frame of the wall is made of two vertical posts in the form of a thermo-profile of the channel section with the middle wall located in the same plane as the middle walls of the channel posts of the frame racks of the frame of the inner and outer layers. 8. The construction panel according to claim 2 or 6, characterized in that the holes for interconnection with the adjoining racks of the frames of the partition walls and walls are made on the middle walls of the racks of the frames, the middle walls of the racks of the frames are provided with holes for interconnection with the adjoining racks of the frames of the partition walls and walls. 9. The construction panel according to claim 8, characterized in that in the inner cavity of the frame of the frame, bushings with threaded holes are welded around the perimeter, the axes of which are perpendicular to the plane of the frame and its outer layers joined to the asbestos-cement sheet layer. 10. A method of manufacturing a building panel according to claim 3, characterized in that first, the holes are drilled directly in the asbestos-cement flat sheet according to the template, and for partitions, holes are drilled simultaneously in two sheets folded together, then, in these holes, recesses are made for the countersunk screw head and install the corresponding screws to which on the other side of the sheet plane screw the connecting elements in the form of threaded bushings, after which the sheet is turned upside down by the bushings and the frame racks are joined to them, to which anavlivayut horizontal connections and flashings, after which carry electric welding threaded sleeves to steel frames and elements in the joints of these elements.     11. A foundation structure comprising foundation blocks of a molded hardened flowing material, each of which has a sole, a support part, a channel extending in length, and openings for providing access to the channel and for means for connecting to a similar block, characterized in that the foundation blocks made in the form of a pair of volumetric blocks, and the foundation structure is equipped with a second pair of volumetric blocks forming the basement, while the lower blocks of both pairs are made in the form of a “trough”, and the upper ones in the form of a “cap” and have the shape rectangular parallelepipeds, the internal cavities of which are container containers for laying and transporting a complete set of building structures and elements necessary for making a three-dimensional building structure of a one-story house or for the next floor, respectively, while the opening made in the bottom of the “trough” of the upper block is aligned with the opening on the “cap” of the lower foundation block, and between each pair of foundation blocks a steel docking belt is installed over the entire joint area walls made of I-beam, the width of the middle wall of which is not less than the width of the joined walls of the blocks, each connecting belt is rigidly fixed to the joined wall of the lower block, and at one of the ends of the pair of volume blocks forming the basement, mortgages and openings for garage doors are made in addition, the supporting part of the upper docking belt is provided with connection elements for interconnection with the three-dimensional structure of the building. 12. The base structure according to claim 11, characterized in that the inner cavity of the “trough” of the foundation block and the “trough” of the upper block of the basement are made in the form of a basin of pools equipped with drain holes, and the “caps” of the blocks are provided with openings for maintenance and lighting. 13. A three-dimensional building structure, including building panels, each of which contains frame elements, means for connecting the frame elements to each other with the formation of a layered frame made of steel elements in the frame plane and a layer of hardened fluid material bounding the internal cavity, as well as means for connecting the panels between themselves and connecting elements for interaction with the respective means of connecting each panel to secure adjacent panels between themselves d, while the frame elements of adjacent panels form a rigid frame that defines the shape of the building structure, characterized in that the layers of hardened flowing material are made in the form of asbestos-cement flat sheet installed with adjoining to the outer layers of the steel frame with the possibility of assembly and disassembly, and the means of connection frame elements are made in the form of threaded elements with their placement inside the frame plane, and the connecting element of the partitions frames is made in the form of a square pipe cross-section, the length of which is equal to the height of the interfloor space and is provided with openings for means for connecting the partition walls, moreover, the size of the square section of the connecting element corresponds to the thickness of the connected partitions, in addition, the connection of the inner layer of the wall frame with the adjacent partition is made in the form of a vertical rectangular pipe, the cross-sectional dimensions of which the planes of the attached partition correspond to its thickness, and in the plane of the inner frame of the wall correspond to the thickness of the frame of this layer and the thickness of one layer of asbestos-cement sheet, and three pipe walls are provided with holes for interaction with means of connection with adjacent frame elements, and the fourth wall is equipped with mounting holes, in addition, four beams of the lower and upper overlapping panels, made in the form of channels, are installed around the perimeter overlapping premises with the formation of interfloor connection and the connection of vertical elements of a three-dimensional structure with horizontal longitudinal and transverse beams in the upper and It overlapping layers, wherein the middle wall on beams interfloor compound openings for connecting means with threaded bushings mounted in the corners of the welded frame scaffolds partition walls and the inner layer to provide a pinching end uprights three-dimensional structure. 14. A method of manufacturing a three-dimensional structure, including attaching building panels to each other using connecting elements and to the supporting surface of the foundation structure, characterized in that the three-dimensional structure frame is made element-wise and sequentially from the elements of the floor frames, partitions and walls, and then to the surface of the frame asbestos cement layers are attached to form the internal cavity of the building panels and the panels themselves without an insulator, while first on the supporting surface of the foundation The structure of the ceiling is fixed by the frame of the lower overlapping panels, consisting of two longitudinal and two transverse interfloor connecting beams made in the form of channels, as well as intermediate transverse and longitudinal beams placed along the intermediate axes of the modular grid, after which the vertical elements of the framework walls and walls are installed, and connected them to the lower joints to the middle wall of the channel of the interfloor connecting beams, and to each other using vertical connection elements, then to the upper joints vertically For the linear elements of the framework walls and the inner layer of walls and partitions, the longitudinal and transverse beams of the interfloor connection of the upper floor panel are installed, and then the longitudinal and transverse intermediate beams are installed along the longitudinal and transverse axes of the modular grid, with the subsequent fixing of the ends of these beams and beams to each other at their places intersections and junctions. 15. A method of manufacturing a three-dimensional structure according to claim 14, characterized in that the steel frame of the wall of the attic panel is laid on the lower floor, the elongated end of the polycarbonate plastic panel is connected to the upper horizontal connection of the outer frame layer of the wall of the lower floor with the formation of a slope, after which the wall frame raise to a vertical position and attach the bottom joint to the middle wall of the interfloor beams around the perimeter of the room to be blocked and install the upper floor panel, at m around the perimeter of the floor beams in the outer upper part set the trays for water drainage using connecting elements and means of connection to the upper row of holes on the middle wall of the floor beams, and the racks of the steel frame of the walls along the perimeter are connected and the insulator is filled into the walls of the lower floors with the removed inner a layer of polycarbonate plastic, while the top layer of flat asbestos cement sheets is applied with a layer of mastic and an additional layer of flat asbestos cement sheets is glued. 16. A method of warming a building by filling the insulator into the internal cavity of the panels included in the building structure, characterized in that the insulator is filled after the building is completely erected under the roof, with walls and partitions with a well structure from the attic, into walls under the window - through a removable window sill, into walls and partitions under a doorway - through a removable threshold, and into ceilings - through removable asbestos cement sheets of the upper layer of panels.

Images