RU92037U1 - QUICK BUILDING BUILDING - Google Patents

Abstract

1. A prefabricated building containing a roof, partitions, external walls with external and internal cladding, forming a fixed formwork, inside of which there is a prefabricated metal frame of steel thin-walled profiles, seamlessly filled with lightweight cellular concrete with the formation of load-bearing walls. ! 2. The building according to claim 1, characterized in that, as lightweight cellular concrete, the formwork is filled with polystyrene concrete. ! 3. The building according to claim 1, characterized in that the external non-metallic cladding-formwork of the external walls is made of fiber cement slabs, and the internal non-metallic cladding-formwork of these walls, as well as partitions and ceilings, is made of fiberglass sheets or fiberboard. ! 4. The building according to claim 1, characterized in that the roof is made with skins forming a fixed formwork, inside of which there is a metal frame made of steel thin-walled profiles filled with lightweight cellular concrete with the formation of monolithic load-bearing walls. ! 5. The building according to claim 1, characterized in that it is provided with an interfloor overlap made of steel thin-walled profiles with sheathing from the group: glass-magnesite sheets, fiberboard, metal profiles forming a formwork filled with polystyrene concrete or cement-sand screed. ! 6. The building according to claim 1, characterized in that the partitions are made with skins forming a fixed formwork, inside of which there is a metal frame made of steel thin-walled profiles, filled with lightweight cellular concrete with the formation of monolithic load-bearing walls. ! 7. The building according to claim 1, characterized in that it is equipped with a staircase, the staircases of which are made of steel subtleties

Description

The utility model relates to the field of construction and can be used for the construction of low-rise prefabricated civil and industrial buildings based on a metal frame of light steel thin-walled structures.

Known designs of low-rise prefabricated buildings SU No. 604907, 33988, 1819316, RU No. 3776, 8387, 26807, 27603, 32510, 33136, 36117, 37338, 41774, 45410, 48193, 51647, 54056, 54599, 54979, 55388, 59096 , 62128, 65924, 66767, 69094, 69547, 69548, 70906, 74932, 79584, 81218, 84873, US No. Des392745, D 502997, D 535756, 3996709, 4037371, 4464877, 4641468, 4718205, 4768322, 4920325, 4968322, 4920322, 4920322, 492032. 5660005, 5765316, 6976337, 7007434, 7021020, 7036276, 7444782, 7475514, DE No. 2400928, 10305273, 19914079, 202004007442, FR No. No. 2547340, 2636994, 2907814, GB No. 2103696, CN No. 101963285, CN No. 101074585 1426521.

The closest technical solution to the proposed is a prefabricated building for the construction of low-rise buildings with a metal frame, including external load-bearing walls, internal load-bearing walls, partitions, structures of floor and attic floors with a frame of steel profiles, load-bearing trusses or beams, roof and wall girders made of steel profiles, ordered structural elements are formed on the basis of frame frames made of thin-walled steel profiles connected by split m connection, thin-walled carcass profiles of the outer walls and attic floors have a perforated wall, and the heat and sound insulating material in the walls and ceilings is located within the cross-sectional height of the carcass elements and is protected from the inside with a vapor barrier film and from the outside with a diffusion waterproofing film. Frame frames of walls, partitions and ceilings are lined with plasterboard or gypsum-fiber sheets from the inside. Outside, ventilated wall or roof girders are installed on the frame frames of external walls, supporting roof trusses or roof beams for the installation of facade or roofing systems. Steel structural elements of walls, floors and roofs are provided with an anti-corrosion coating. The system uses a foundation on which frame frames of walls are installed. (RU No. 62128 prototype).

Significant disadvantages of the known design are: the predominant use of mineral wool insulation for filling the walls, which has a limited life, a low degree of fire resistance and corrosion resistance of metal structures unprotected from the access of moist air, the increased mass (material consumption) of the latter, due to the fact that they are loaded with almost the entire weight of the building, including plates, low heat efficiency of building envelopes, insufficient variety of architectural forms. A building constructed using the above technical solutions of the prototype does not have the advantages of capital.

The technical task of the utility model is the creation of an effective design of a prefabricated house and the expansion of the arsenal of designs of prefabricated houses.

The technical result of the utility model consists in the fact that it simultaneously realizes the technological advantages of prefabricated buildings on a metal frame and the operational advantages of capital reinforced concrete buildings, while ensuring a variety of architectural forms and layouts, reducing the cost and material consumption of low-rise buildings, improving the conditions for their operation and ensuring modern requirements on energy conservation, fire safety, environmental friendliness, strength, reliability and durability. The technical result is also to reduce the consumption of expensive materials, reduce labor costs for the construction of the building, saving energy during operation. The layout capabilities and the scope of the structure are expanding, since the requirements for the bearing capacity of the soil and foundation are reduced.

The essence of the utility model is that a prefabricated building contains a roof, partitions, external walls with external and internal cladding, forming a fixed formwork, inside of which a prefabricated metal frame of steel thin-walled profiles is placed, and cast seamlessly with lightweight cellular concrete with the formation of load-bearing walls.

In particular preferred cases of implementation as lightweight cellular concrete, the formwork is filled with polystyrene concrete, the external non-metallic cladding-formwork of the external walls is made of fiber-cement plate, and the internal non-metallic cladding-formwork of these walls, as well as partitions and ceilings, is made of fiberglass slabs or with skins forming a fixed formwork, inside of which there is a metal frame made of steel thin-walled profiles, filled with lightweight cellular concrete SG to form a monolithic structural walls.

At the same time, the building is equipped with an interfloor overlap made of steel thin-walled profiles with sheathing from the group: glass-magnesite sheets, fiberboard, metal profiles forming a formwork, filled with polystyrene concrete or cement-sand screed, partitions are made with claddings forming a fixed metal formwork; thin-walled steel profiles filled with lightweight cellular concrete with the formation of monolithic load-bearing walls.

In addition, the building is equipped with a staircase, the flight of stairs of which is made of steel thin-walled profiles, filled with reinforced concrete.

Preferably, the metal volumetric frame is made in the form of perforated galvanized profiles from a strip of sheet steel, interconnected by detachable connections, for example, self-tapping screws, and inside the fixed formwork, at least partially placed devices and communications of engineering systems from the group: hot and cold water supply, heating, sewage, electricity, ventilation, dust removal, disinfection.

The building is preferably made with a lightweight foundation on which a metal frame is installed.

The technical result is due to the fact that the technological basis of the structural system of buildings, as well as that of the prototype, is a frame made of steel thin-walled galvanized profiles. However, unlike the prototype, the outer wall cladding is made of a facing fiber cement facade slab. The inner lining of external walls, partitions and ceilings is made of glass-magnesite (LSU) sheets, fiberboard, etc. .. Light cellular concrete (for example, polystyrene concrete (PPSB D-250) is poured into the "body" of the wall according to GOST R 51263-99 ) As a result, the metal frame is deeply “poured” in concrete, enclosed in a fixed formwork and is mainly not a supporting, but a reinforcing structural element. High adhesion of the facade slab and PPSB ensures the solidity of the structure in which the supporting elements are not profiles of the metal frame, but the walls as a whole. Interfloor ceilings consist of steel thin-walled galvanized profiles with a lining with glass-magnesite (LSU) sheets, fiberboard or metal profiles, etc., and poured: on apartment buildings with reinforced concrete, on individual houses of PPSB and a cement-sand screed. Interfloor flights of stairs are made of LSTK and filled with reinforced concrete. Internal engineering systems (Hot and Cold water supply, Heating, Sewerage, Power supply, Ventilation and related systems (Central vacuum cleaner, dust extraction, disinfection, etc.) are laid in the “body” of the walls, which significantly reduces the installation cost and installation time.

The materials used for the structural system belong to the combustibility classes "NG" and "G1" and are environmentally friendly.

The inventive design provides a reduction in heating and air conditioning costs by 2-4 times - reduced heat transfer resistance of external walls and attic floors with a thickness of D250 polystyrene pouring equal to 240 mm and the use of a facade plate according to TU STO 33928817-001-009 “Front panels. Specifications ”as an external fixed formwork will be at least 3.2 (m ² × ° C) / W, which meets the requirements of SNiP 23-02-2003 for most climatic zones of the Russian Federation. An increase, if necessary, of the heat transfer resistance of walls and floors is easily achieved by increasing the thickness of the filling of the polystyrene concrete core of the wall. The reduction in maintenance costs is due to the high durability of the building from steel structures with a protective coating and monolithic casting in a non-aggressive or slightly aggressive environment is at least 100 years. High vapor permeability (0.09-0.1 Mg / m H Pa) and low water absorption (3-5%) of polystyrene concrete walls according to GOST R 51263-99 make living comfortable and prevent the formation of fungi and mold.

The drawing of figure 1 shows the spatial structure of the metal frame of a two-story building; figure 2 is a structural diagram of the outer load-bearing walls; figure 3 is a structural diagram of partitions; figure 4 is a structural diagram of the device of the floor of the first floor; figure 5 is a structural diagram of an inclined insulated roof; figure 6 is a structural diagram of a horizontal insulated roof.

The metal frame 1 of the building is made of perforated galvanized profiles made of a strip of sheet steel, interconnected by self-tapping screws (Fig. 1).

The outer walls consist of external cladding 2 in the form of front panels (for example, fiber cement boards), mounted on the crate 3, mounted on the rack profiles 4 (racks) of the metal frame 1, on the inside of which there is a crate 5 or a special profile on which the internal is fixed lining 6 (for example, fiberboard or fiberglass sheet). The space between the outer and inner skins 2, 6 is monolithically filled with lightweight cellular concrete - polystyrene concrete (for example, PPSB D-250, according to GOST R 51263-99). Thus, the frame 1 is "filled" with polystyrene concrete, enclosed in a fixed formwork from the outer and inner casing 2, 6 and is not a supporting, but a reinforcing structural element. The thickness of the core of polystyrene concrete between panels 2 and slabs 6 is selected, for example, equal to 240 mm, based on the required heat transfer coefficient, enclosing structure according to SNiP 23-02-2003 “Thermal protection of buildings”.

The partition (inner bearing wall), like the outer wall, contains the outer and inner cladding, for example, of plasterboard or other sheets 7, forming a fixed formwork, inside which there are rack profiles 4 (racks) of the metal frame 1. The space between the outer and inner cladding (sheets 7) can be filled with UPSA insulation and / or monolithically filled with lightweight cellular concrete - polystyrene concrete (for example, PPSB D-250, according to GOST R 51263-99).

Walls and partitions made of polystyrene concrete can be additionally introduced with UPSA insulation (not shown).

The floor device of the first floor contains below the freezing horizon (not indicated) boring piles 8, mounted on piles 8 reinforced concrete grillage 9 with coating waterproofing (not indicated), to which are mounted on top of sheet waterproofing 10 with anchors 11 (bolts with expandable couplings) guide profiles 12 and rack profiles 4 of the metal frame 1. Above the ground, the floor contains a layer 13 of compounded sand layer 13, which serves to eliminate the mechanical connection between the heaving soil and the foundation, layer 14 of monolithic lightweight cellular concrete - polystyrene concrete (for example, PPSB D-600, according to GOST R 51263-99) with a thickness of 200 mm, layer 15 of cement-sand screed M150 with a thickness of 15 to 40 mm and a finishing floor 16. Piles of 8 grillage foundations can be implemented as standing and / or hanging. Simply put, standing piles “stand” on incompressible soil layers and transfer the load from the building to them, while hanging piles are held in the soil due to lateral friction forces arising between the soil particles and the entire surface of the buried part of the pile.

The inclined insulated roof contains a roof covering 17, a lathing 18, an outer lining 19, a counter beam (not indicated), a hydroprotective film (not shown), a hem profile and a rafter foot 20 from the metal frame 1. On the inside of the roof there is an inner lining - gypsum plasterboard 21. The space between the outer and inner claddings (19,21) is monolithically filled with lightweight cellular concrete with polystyrene concrete (for example, PPSB D-150, according to GOST R 51263-99) and / or UPSA insulation.

The horizontal insulated roof contains running boards 22, a hem profile (not indicated) and floor beams 23 of the metal frame 1, upper and lower cladding (not marked), the space between which is monolithically filled with lightweight cellular concrete - polystyrene concrete (for example, ППСБ D-150 , according to GOST R 51263-99) with the formation of a horizontal rigid diaphragm.

Filing roof profiles are installed through a vapor barrier film (not shown). The upper and lower roof sheathing is performed mainly from a glass-magnesite sheet and / or fiberboard, the lower ones can be made of drywall sheet.

Thus, the structural design of the building is formed from frame frames of external load-bearing walls, internal load-bearing walls, partitions, structures of floor and attic ceilings, load-bearing trusses or beams, roofing and wall girders of an open structure with a predetermined configuration made of thin-walled steel profiles. The stability of structural elements and the overall stability of the structural system as a whole is ensured by the creation of a spatially unchanged frame-bond system, reinforced by wall cladding elements, monolithic filling with lightweight cellular concrete, hard disks of overlapping and coating. Exterior wall cladding is made of durable facing fiber cement facade slab. The inner lining of external walls, partitions and ceilings is made of glass-magnesite (LSU) sheets, fiberboard, etc. .. Light cellular concrete (for example, polystyrene concrete (PPSB D-250) is poured into the "body" of the wall according to GOST R 51263-99 ) Thus, the frame is “poured” with concrete enclosed in a fixed formwork and is not a supporting, but a reinforcing structural element. High adhesion of the facade slab and polystyrene concrete provides a monolithic structure. As a result, the supporting elements are not the metal frame, but the walls themselves. Interfloor ceilings consist of steel thin-walled galvanized profiles with a binder of glass-magnesite (LSU) sheets, fiberboard or metal profiles, etc. On apartment buildings, the floor profiles are filled with reinforced concrete, on individual houses - polystyrene concrete and cement-sand screed. Interfloor flights of stairs are made of light steel thin-walled structures (LSTK) and are filled with reinforced concrete. Internal engineering systems (Hot and Cold water supply, Heating, Sewerage, Power supply, Ventilation and related systems (Central vacuum cleaner, dust removal, disinfection, etc.) are laid in the “body” of the walls, which significantly reduces the installation cost and reduces the installation time.

The materials used for the structural system belong to the combustibility classes "NG" and "G1" and are environmentally friendly.

The fiberboard from which the fiberboard is made is a multifunctional building material that eliminates rotting of the material and is practically non-combustible. Elements of the metal frame of the exterior and other walls of the building consist of perforated (perforated) galvanized metal profiles, which are made of a strip of sheet steel with a thickness of 1.5-2.0 mm, interconnected by self-drilling self-tapping screws in the wall plane. The use of lightweight steel thin-walled structures from a perforated (perforated) profile significantly reduces the mass of the structure and reduces heat loss through the walls due to the elongation of the cold flow path and gives additional rigidity.

Prefabricated building is constructed as follows.

The metal frame 1 is quickly and completely assembled in place and connected to a prefabricated concrete foundation at the nodes of the interface of the uprights 4 with the horizontal guide of the wall frame 1 by means of bolts 11 having expandable couplings. The appearance of the building is formed almost immediately. Then, as a rule, double-sided (external and internal) non-metallic cladding of monolithic walls (as well as, if necessary, partitions, ceilings, roofs) is mounted immediately - fixed formwork from decorative plates and / or sheets and / or panels. At the same time, the basic, time-consuming and practically uncontrolled operations of connecting the fittings - electric welding, wire knitting, are excluded. Conventional dismantling formwork mounting and dismounting operations are also not required.

Surfaces facing the inside or outside of the building do not require decoration or coating. Steel consumption for the supporting frame of buildings of light steel thin-walled structures is 18-23 kg for a two-story building based on 1 m ^{2 of} construction area. The weight of any mounting element of the building structures does not exceed 80-100 kg, which allows you to install them manually in place. Simultaneously with the installation of internal and external wall formwork, cable channels are laid in the voids of the frame for electrical wiring, communications and other communications, there is a heating, water, and dust removal and air conditioning lines. After completing all the installation of formwork, laying communications in the walls, expanded polystyrene (PPSB) is poured. Floors, ceilings and roof are made similarly, in accordance with their design. Installation of building structures can be carried out without the use of lifting equipment in a short time: a team of 4-5 people can build houses prepared for fair finishing with a total area of 150-200 m in 12-15 days. The operations of connecting the individual blocks are not required.

The above results are achieved due to the fact that the structural design of the building for the construction of buildings with a metal frame consists of the following structural elements and processes:

- external load-bearing walls, internal load-bearing walls or supporting columns, partitions, structures of floor and attic floors formed on the basis of steel frame frames, as well as load-bearing trusses or beams, roofing and wall girders of an open structure with a predetermined configuration. All elements are made of thin-walled steel galvanized profiles and are connected by a detachable connection to form enlarged structural elements and create a building frame. For elements of external building envelopes - external walls and attic floors, the use of profiles with a perforated wall (perforated) is provided, which exclude the formation of "cold bridges" and give additional structural strength.

- fixed formwork (outer and inner lining):

From the front part - the front facing fiber cement plate (exterior decoration element)

From the inside - LSU sheet, fiberboard, etc. (element of interior decoration).

- internal engineering systems laid in the “body” of walls and ceilings.

- continuous monolithic pouring with lightweight cellular concrete of the “body” of walls and ceilings.

- continuous monolithic pouring of the roof with lightweight cellular concrete.

Achieving the above results is possible only when using the combination of essential features of the claimed home.

The wall construction and foundation make it possible to build comfortable, durable houses in areas with seismic hazard, in wetlands, in areas with permafrost. The design of the walls allows the manufacture of mobile and portable homes, which is important in areas of natural disasters.

The most popular version of this building is a two-story two-story residential building.

As a result, an effective design of a prefabricated house was created and the arsenal of architectural forms and designs of prefabricated houses was expanded.

At the same time, the advantages of prefabricated buildings on a metal frame and the advantages of capital reinforced concrete buildings are combined, the cost and material consumption of low-rise buildings are reduced, their operating conditions are improved and modern requirements for energy conservation, fire safety, environmental friendliness, ergonomics, strength, reliability and durability are achieved.

Claims (10)

1. A prefabricated building containing a roof, partitions, external walls with external and internal cladding, forming a fixed formwork, inside of which there is a prefabricated metal frame of steel thin-walled profiles, seamlessly filled with lightweight cellular concrete with the formation of load-bearing walls. 2. The building according to claim 1, characterized in that, as lightweight cellular concrete, the formwork is filled with polystyrene concrete. 3. The building according to claim 1, characterized in that the external non-metallic cladding-formwork of the external walls is made of fiber cement slabs, and the internal non-metallic cladding-formwork of these walls, as well as partitions and ceilings, is made of fiberglass sheets or fiberboard. 4. The building according to claim 1, characterized in that the roof is made with skins forming a fixed formwork, inside of which there is a metal frame made of steel thin-walled profiles filled with lightweight cellular concrete with the formation of monolithic load-bearing walls. 5. The building according to claim 1, characterized in that it is provided with an interfloor overlap made of steel thin-walled profiles with sheathing from the group: glass-magnesite sheets, fiberboard, metal profiles forming a formwork filled with polystyrene concrete or cement-sand screed. 6. The building according to claim 1, characterized in that the partitions are made with skins forming a fixed formwork, inside of which there is a metal frame made of steel thin-walled profiles, filled with lightweight cellular concrete with the formation of monolithic load-bearing walls. 7. The building according to claim 1, characterized in that it is equipped with a staircase, the flight of stairs of which is made of steel thin-walled profiles, filled with reinforced concrete. 8. The building according to claim 1, characterized in that the metal surround frame is made in the form of perforated galvanized profiles from a strip of sheet steel, interconnected by detachable joints, for example, self-tapping screws. 9. The building according to claim 1, characterized in that the devices and communications of engineering systems from the group: hot and cold water supply, heating, sewage, electricity, ventilation, dust removal, disinfection are at least partially placed inside the fixed formwork. 10. The building according to claim 1, characterized in that it is made with a lightweight foundation on which a metal frame is installed.