RU2759464C1 - Method for building the upper floor of a building - Google Patents

Abstract

FIELD: building.SUBSTANCE: invention relates to the field of building, namely to the method for building the upper floors of buildings. The method for building the upper floor of a building is characterised by installing the wall frame and the roof frame in the form of a trussing system. The outer layer of the wall is mounted to the wall frame and finishing thereof is executed, and the roof covering is mounted on top of the roof frame. The wall frame is made multi-row and comprises vertical guides and bridges connecting said guides and rows. The ceiling frame in the form of a three-dimensional truss structure from connected rows of trusses is mounted on the wall frame. The inner space of the wall frame and the ceiling frame is insulated with an insulating layer, and the formed space is filled with a filler. A frame of the roof containing a roofing panel is mounted on the walls and ceiling, mounted whereon is the roof covering, finishing works are performed. Prior to assembling the roof, finishing the walls and ceiling, a vapour barrier, wind and moisture protection thereof are executed.EFFECT: reduction in the complexity of building.7 cl, 2 dwg

Description

The invention relates to the field of construction, namely to insulated structures of the upper floors of buildings with an adjoining rafter roofing system.

From the prior art, the CONSTRUCTION OF THE TRUSS AND THE METHOD FOR PERFORMING THE WORKS [JPH11172836 (A), publ .: 06/29/1999] is known, in which the upper frame of the uppermost storey wall, consisting of light steel profiles, passes between the upper end parts of the uppermost storey wall, and the second beams are located on the upper frame of the upper frame of the upper storey wall and light steel profiles and are connected by a screw with a hole directed to the interior of the building, the steel profile serving as a ceiling beam opens from the side and is inserted into the steel profile and passes between them for screw connection , plywood for the structure, is placed on a steel profile with the possibility of a ceiling, the triangular roof walls are assembled together on the ceiling for connection with screws, the ridge beam and main guides pass between the triangular roof walls, and the rafters run to form a truss.

The disadvantage of the analogue is the low bearing capacity and reliability of the structure, due to the execution of the walls from a single-row profile, on top of which the Mauerlat and the rafter system are immediately mounted. Construction in this way, despite its low labor costs and material consumption, does not ensure that the structure meets the strength requirements.

The closest in technical essence is the TECHNOLOGY OF CONSTRUCTION OF INDIVIDUAL RESIDENTIAL BUILDINGS AND STRUCTURES [RU2717600 (C1), publ .: 03.24.2020], characterized by the fact that a metal frame made of light steel thin-walled structures of LSTC is installed to the pre-arranged foundation and basement of the building cold-rolled galvanized steel profiles with a thickness of 2-2.5 mm, while all the frame elements are bolted together, and the frame itself is fixed to the base on the anchor group, the roof frame is mounted, which is also made in the form of a metal frame made of LSTC, while during construction of the frame, internal walls and partitions are made of SKTs 2R blocks or foam concrete blocks, which are laid on the finished masonry rasters, and a welded mesh is laid between the blocks, the outlets of which are fastened with self-tapping screws to the supporting elements of the metal frame, that is, to the shelves of rack profiles, while between the inner the wall and the frame are air shny gap, which serves as additional insulation and for laying engineering communications in it, then proceed to the installation of external insulation and external walls, while sandwich panels made to the required dimensions at the manufacturer's plant are used as insulation, while due to the fact that the rack the profiles of the metal frame are made stepped and are located in the frame through one in the form of ascending steps, and the adjacent ones through one in the form of descending steps, the sandwich panels are attached to the shelves of rack-mount profiles with standard hardware and shaped elements, the outer layer of the wall is attached to the outside of the insulation to the metal frame in the form of sheets of OSB or foam, which are glued with a reinforcing mesh and leveled with acrylic putty, on which decorative plaster is applied Bark beetle, and the metal roof frame in the form of a rafter system is also made using the LSTK technology, insulated and covered with OSB, on top of which a soft roof or metal shingles are mounted , silt and sandwich panels are mounted on the metal roof frame, which serve as insulation and roofing material, at the final stage, they carry out internal work to insulate floors and floors, install windows and doors, and carry out communications.

The main technical problem of the prototype is the low bearing capacity of the walls and the roof, due to the construction of the walls from the wall block and the absence of the ceiling covering holding the roof, as well as the high labor intensity of construction in the described way, due again to the use of blocks as a bearing material and as an external insulation sandwich. panels that increase the material consumption of the building structure, including due to the attachment of these panels to separately mounted rack profiles.

The objective of the invention is to eliminate the disadvantages of the prototype.

The technical result of the invention is to reduce the labor intensity of the construction of energy efficient buildings.

The specified technical result is achieved due to the fact that the method of construction of the upper floor of a building, characterized by the fact that a wall frame and a roof frame in the form of a rafter system are mounted to the foundation of the building, the outer layer of the wall is mounted to the wall frame and finished, and over the roof frame is mounted a roof, characterized in that the wall frame is multi-row and contains vertical guides and connecting said guides and rows of lintels, a floor frame is mounted on the wall frame, made in the form of a volumetric truss structure from connected rows of trusses, the inner space of the wall frame and the floor frame is insulated with an insulating layer and the formed space is filled with filler, the roof frame is mounted on the walls and overlap in the form of a rafter system containing a roofing panel of longitudinal and transverse guides, on which the roof is mounted and finishing works of the inner and outer walls and ceilings are performed I, at the same time, before installing the roof, finishing the walls and ceilings, they carry out their vapor barrier, wind and moisture protection, while the vapor barrier layer on the inside of the wall frame is mounted with an overlap on the ceiling, the wind and moisture protection layer on the outside of the wall frame is mounted with an overlap on the roof panel protruding outward, the wall frame, floor and roof frame are made of steel profiles.

In particular, the steel profile is made in the form of a U- or C-shaped LSTC profile.

In particular, the connection of the elements of the wall frame, floor frames and roof frames is detachable.

In particular, the filler is made in the form of a fast-setting solution with a density of at least 150 kg / m ³ .

In particular, holes are made in the steel profiles of the wall frame for pouring a filler made in the form of a solution through them.

In particular, the filler is made in the form of a mineral fiber with a density of at least 10 kg / m ³ .

In particular, to provide a ventilation gap and improve air circulation under the roofing, holes are made in the guides of the roofing panel.

Brief description of the drawings.

Figure 1 shows a general view of the structure of the upper floor of the building.

Figure 2 shows a side view of the structure of the upper floor of the building.

The figures indicate: 1 - trusses, 2 - lintels, 3 - outer row, 4 - inner row, 5 - horizontal lintels, 6 - insulating layer, 7 - filler, 8 - finishing layer, 9 - heat-insulating layer, 10 - facade decoration , 11 - vertical posts, 12 - Mauerlat, 13 - rafters, 14 - roof panel, 15 - lathing, 16 - roof, 17 - abutment.

Implementation of the invention.

The structure of the upper floor of the building consists of a wall frame, a ceiling, a roof frame and a roof.

The overlap consists of vertically installed parallel rows of trusses 1 as the top overlap, containing at least one belt and made of light steel thin-walled cold-formed profile.

The wall frame is made of at least outer 3 and inner 4 rows made of light steel thin-walled structures, each of which is formed by vertical posts connected in one plane by horizontal bridges 5. Rows 3,4 are interconnected by bridges (not shown in the figures ).

In one embodiment, the horizontal bridges 5 connecting the vertical posts of rows 3, 4 and in the said posts 3, 4 are provided with holes for the filler solution 7 to pass through them to uniformly fill the inner space of the wall frame.

On top of the wall frame, trusses of 1 floor are mounted. The lower chords of the trusses 1 are flush-connected by jumpers 2, which form the plane of the ceiling. An insulating layer 6 made of sheet material, for example, of a cement-particle board, is mounted to the bridges 2 from below through a vapor barrier layer (not shown in the figures).

Along the perimeter along the outer row 3, a Mauerlat 12 is mounted on its vertical posts.

An insulating layer 6 is mounted to the wall frame on both sides, made of sheet material, for example, from a cement-particle board, while a vapor barrier layer is laid between the profile of the inner row 3 of the wall frame and the insulating layer 6 mounted to it.

The space formed between the insulating layers 6 with the rows 3, 4 placed inside is filled with filler 7, for example, in the form of modified monolithic foam concrete or mineral fiber.

The space between the insulating layers 6 mounted above and below on the trusses 1 of the floor is filled with filler 7, for example, in the form of modified monolithic foam concrete or mineral fiber.

To the upper chords of the trusses 1 are mounted vertical pillars 11 of the roof frame.

Above the mentioned racks 11, rafters 13 are mounted, resting with their lower part on the Mauerlat 12. On the rafters 13, a roofing panel 14 is mounted, made in the form of longitudinally and transversely arranged guides in one plane, while part of the longitudinally located guides of the roofing panel 14 is mounted directly on the rafters 13 The dimensions of the cells of the roofing panel 14 correspond to the size of the cell in the size of which the roofing material is to be laid.

In one embodiment, the cells of the roofing panel 14 are filled with mineral fiber filler. In this embodiment, the roofing panel 14 is closed at the bottom with an insulating layer (not shown in the figures).

Vertical posts 11, Mauerlat 12, rafters 13, roofing panel 14 are made of steel profiles.

In one embodiment, a lath 15 is mounted transversely over the roofing panel 14, for example made of a wooden beam. The lathing 15 can be mounted on an insulating layer (not shown in the figures) made of sheet materials and mounted over the roofing panel 14, while a wind and moisture protection layer (not shown in the figures) is laid between the insulating layer and the roofing panel 14. Above the lathing 15, a sheet roof 16 is mounted, for example, of slate, sheet steel or aluminum, metal tiles, etc.

In another embodiment, the roofing sheet 16 is mounted directly on an insulating layer mounted over the roofing panel 14, with a wind and moisture barrier sandwiched between the insulating layer and the roofing sheet 16 (not shown in the figures).

In the third embodiment, the roofing sheet 16 is mounted directly on the roofing panel 14, while the wind and moisture protection layer is laid between the rafters 13 and the roofing panel 14, while, in order to provide a ventilation gap and improve air circulation under the roofing, in the profile from which the roofing panel is made 14 holes are made.

To the insulating layers 6 of the inner row 4 of the wall frame and trusses 1, a finishing layer 8 is mounted, made, for example, of plasterboard sheets.

To the insulating layer 6 of the outer row 3 of the wall frame through a wind and moisture protection layer (not shown in the figures), made, for example, in the form of a wind and moisture protection and vapor barrier membrane, a heat insulating layer 9 is mounted, on top of which the facade finish 10 is made, made, for example, of plaster, when In this case, the edge of the wind and moisture protection layer is brought out from under the heat-insulating layer and overlapped onto the roofing panel 14.

The plaster can be applied to a reinforcing layer (not shown in the figures) pre-assembled on the heat-insulating layer 9.

An abutment 17 is mounted between the edge of the roof 16 and the facade trim 10 under the rafters 1.

The structure of the upper floor of the building is assembled as follows.

At the first stage, trusses 1 and external 3 and internal 4 rows of the wall frame are assembled from a light-steel thin-walled cold-formed profile. Rows 3, 4 of the wall frame are interconnected with jumpers and installed vertically, for example, to the foundation, existing wall or floor of a building. The profile elements of rows 3, 4 are connected to each other by a detachable connection made at least at two points, for example, riveted and screwed, or double riveted, or double screwed, etc.

The trusses 1 are mounted on the wall frame. The lower chords of the trusses 1 are connected with jumpers 2, while the jumpers 2 are mounted flush to the trusses 1.

To prevent the formation of freezing areas and improve the thermal insulation of the building, after the installation of the floor on the wall frame, the joints of the floor profiles and the wall frame are laid with heat-insulating material, for example, penoizol, teplofol, etc. (not shown in the figures) and an overlap on the wall frame and the ceiling is laid with a vapor barrier a layer (not shown in the figures), wherein said heat-insulating material and a vapor barrier layer form an additional insulation contour of the floor, preventing the transfer of heat or cold from the roof through the abutment of the wall frame, floor and roof frame into the building.

Further, insulating layers 6 are mounted to the wall frame from the outside and inside and to the floor from below, while the insulating layers 6 mounted inside the wall frame and floors are laid with a vapor barrier layer and adjoin each other.

At the next stage, along the perimeter along the outer row 3 of the wall frame, the Mauerlat 12 is mounted on the vertical posts of the mentioned row 3 and the assembly of the roof frame is started.

When assembling the roof frame, vertical posts 11 are mounted to the upper chords of the trusses 1, while the mentioned roof posts 11 are made with different heights with a uniform decrease from the center to the edge of the roof. The rafters 13 are mounted to the vertical posts 11 and to the Mauerlat 12. The roofing panel 14 is mounted on the rafters 13.

The adjoining profile elements of the roof frame are connected to each other by a detachable connection made at least at two points, for example, riveted and screwed, or double riveted, or double screwed, etc.

Further, depending on the implementation, the roofing is mounted. For example, in an embodiment with a batten 15, first, a batten 15 is mounted on top of the insulating layer 6 or without it over the roofing panel 14, and then a sheet roof 16 is mounted on top of the batten 15 on the wind and moisture protection layer.

In another embodiment, without lathing, the roofing sheet 16 is mounted directly to the roofing panel 14 with or without insulating layer 6. This version of the installation of the roof 16 reduces the material consumption and reduces labor costs, since it excludes the crate 15 or the hat profile replacing it from the structure.

Further, the spaces formed between the insulating layers 6 of the wall frame and the overlap are filled with filler 7 made of, for example, modified monolithic foam concrete, while thanks to the holes (not shown in the figures) made in the profile of the wall frame, the filler 7 is poured through the aforementioned holes evenly filling the space.

At the next stage, finishing work is performed, for which, first, a finishing layer 8 is mounted on the insulating layers 6 of the inner walls and floors, and on the outside, a wind and moisture-proof and heat-insulating layer 9 is applied, a wind and moisture-proof layer is adjacent to the roofing panel 14 and the facade finish 10 is performed.

And at the last stage, an abutment 17 is mounted between the edge of the roof 16 and the facade finish 10 under the rafters 13.

EFFECT: reduced labor intensity of construction of energy-efficient buildings is achieved due to the fact that the walls of the building are made in the form of a multi-row structure made of LSTC profile filled with filler, and the roof of the building is mounted on a ceiling made of a truss structure made of LSTC profile also filled with filler, while the profile of the structures fulfills a reinforcing function that increases the bearing capacity of the building structure, and a decrease in the labor intensity of construction is ensured by reducing the time spent on the construction of walls and floors due to the rapid filling of the space between the insulating layers 6 of the wall frame with filler 7, eliminating the need to perform masonry from separate wall stones, while eliminating the lathing 15 of the structure and hat profile during finishing work also reduces the material consumption and labor intensity of construction, and the use of vapor barrier and wind and moisture protection layers, including those launched from the wall to the arch overlapping the ceiling and the roof frame provide thermal insulation of the structure. The use of filler 7 in the wall frame and ceiling, vapor barrier, wind and moisture protection, as well as heat insulating layer 9 ensure high energy efficiency of the building erected in the described way, and the methods and places for laying vapor barrier and wind and moisture protection layers exclude the occurrence of cold bridges.

In addition, in addition to the speed of construction, the installation of a building in the described way can be carried out by a limited number of workers without the participation of heavy construction equipment, which makes it attractive for inexpensive construction, which is not inferior in terms of performance to buildings constructed by other, more labor-intensive and material-intensive methods.

Claims (7)

1. A method of constructing the upper floor of a building, characterized in that a wall frame and a roof frame in the form of a rafter system are mounted to the foundation of the building, the outer layer of the wall is mounted to the wall frame and finished, and a roof is mounted on top of the roof frame, characterized in that the wall the frame is multi-row and contains vertical guides and connecting the said guides and rows of lintels, a floor frame is mounted on the wall frame, made in the form of a volumetric truss structure from connected rows of trusses, the inner space of the wall frame and the floor frame is insulated with an insulating layer and the formed space is filled with filler, on walls and ceilings mount the roof frame in the form of a rafter system containing a roofing panel made of longitudinal and transverse guides, on which the roof is mounted and finishing works of the inner and outer walls and ceilings are performed, while before installing the roof, finishing the walls and ceiling their vapor barrier, wind and moisture protection are carried out, while the vapor barrier layer on the inner side of the wall frame is overlapped on the ceiling, the wind and moisture protection layer on the outer side of the wall frame is overlapped on the outwardly protruding roofing panel, the wall frame, the ceiling and the roof frame are made of a steel profile. 2. The method according to claim 1, characterized in that the steel profile is made in the form of a U- or C-shaped LSTC profile. 3. The method according to claim 1, characterized in that the connection of the elements of the wall frame, the frames of the floor and the roof between each other is made detachable. 4. The method according to claim 1, characterized in that the filler is made in the form of a fast-setting solution with a density of at least 150 kg / m ³ . 5. The method according to claim 1 or 4, characterized in that holes are made in the steel profiles of the wall frame for pouring a filler made in the form of a solution through them. 6. The method according to claim 1, characterized in that the filler is made in the form of a mineral fiber with a density of at least 10 kg / m ³ . 7. The method according to claim 1, characterized in that holes are made in the guides of the roofing panel to provide a ventilation gap and improve air circulation under the roofing.

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