RU60552U1 - BUILDING SYSTEM - Google Patents

Abstract

The utility model relates to the field of building structures and can be used in the construction of prefabricated monolithic, mainly low-rise buildings, as well as for the construction of attic floors and superstructures of multi-storey buildings.

The building system contains a foundation, a roof, supporting and enclosing structures in the form of prefabricated monolithic walls with fixed formwork 6, connected to the foundation with anchors 5, and at least one precast monolithic ceiling, while the fixed formwork of walls 6 and ceilings 15 made of thin-walled material based on gypsum and / or glass silicate and / or cement and / or asbestos cement, and the wall formwork is attached to the racks of cut profiles 7, and the wall monolith is made with the formation of at least one structural thermal insulation layer, and the wall monolith is made of concrete on a gypsum binder, the window and door openers 11 are formed by struts 7 with jumpers 12 fixed between them, the overlap is made by supporting beams 14, resting their ends on the strapping beam 13, between which a precast fixed formwork 15 is placed arched form, resting on the lower belt of the supporting beams 14, a reinforcing mesh is placed in the upper part of the floor, the monolith of the floor is made with the formation of at least one structural and heat-insulating of the layer, wherein the monolith overlap is made of concrete for gypsum and / or cement binder.

The technical result is expressed in reducing energy consumption during the construction of buildings, increasing energy efficiency during the operation of the building, reducing the construction time, reducing the cost of the building, while improving the quality of life in the building and ensuring a high degree of durability of the building structure. An additional technical result is expressed in the expansion of functionality to change the structural and heat-conducting properties of walls and ceilings.

1 n.p. f-ly, 7 z.p. f-ly., 4 ill.

Description

The utility model relates to the field of building structures made of building mixtures and building elements directly on the construction site using fixed formwork. The utility model can be used in the construction of prefabricated monolithic, mainly low-rise buildings, as well as for the construction of attic floors and superstructures of multi-storey buildings.

Various types of building structures are known, containing a foundation, a roof, supporting and enclosing structures in the form of prefabricated monolithic walls with fixed formwork and ceilings. [Publication of the international application WO 2005019549, 2005; US patent No. 5477652, publ. 12/26/1995].

Obtaining the required technical result is hindered by the need to use heavy lifting equipment for the installation of walls and ceilings and the high energy and estimated construction costs.

A technical solution is known, described in Russian patent No. 2099482 (publ. 1997), according to which the building system contains a foundation, a roof, supporting and enclosing structures in the form of prefabricated-monolithic walls with fixed formwork and, overlap, and the interdeck space is filled with light concrete, mainly arbolitom.

Obtaining the required technical result is hindered by the need to use vibration technology, and the need to withstand the curing time of the composition, which lengthens the construction time.

The closest in the set of essential features (prototype) of a utility model is a building system,

containing a foundation, a roof, supporting and enclosing structures in the form of precast-monolithic walls with fixed formwork connected to the foundation by anchors, and at least one precast-monolithic ceiling [Russian Patent No. 2155045, publ. October 20, 2001], and the interdeck space is filled with porous fine-grained concrete, and the formwork is made of asbestos cement.

Obtaining the required technical result is hindered by the use of materials based on energy-consuming production and construction technologies (cement, asbestos cement production, crane installation of individual structures), as well as the limited functionality of the device to change the structural and heat-conducting properties of walls and ceilings. It should be noted that the low vapor permeability of the walls made according to the indicated technical solution negatively affects the quality of life in such buildings.

The inventive utility model is aimed at solving the problem of improving the quality of life of the population by providing it with comfortable housing using environmentally friendly materials in a fairly short time.

The technical result obtained by the implementation of the claimed utility model is expressed in a reduction in energy consumption during the construction of buildings, an increase in energy efficiency during the operation of the building, a reduction in the construction time, a reduction in the cost of the building, while improving the quality of life in the building and ensuring a high degree of durability of the building structure. An additional technical result is expressed in expanding the functionality for changing the structural and heat-conducting properties of walls and ceilings depending on climatic, seismological and operational conditions. Additional technical result is also expressed in the expansion

the range of materials used using local materials and the possibility of using production waste with a view to their disposal.

To achieve the above technical result in a building system containing a foundation, a roof, supporting and enclosing structures in the form of prefabricated monolithic walls with fixed formwork connected to the foundation with anchors, and at least one precast monolithic ceiling, fixed formwork of precast monolithic walls and ceilings are made of thin-walled material based on gypsum and / or glass silicate and / or cement and / or asbestos-cement, moreover, the formwork of the walls is attached to the racks of cut profiles, and the monolith of the walls is made with the formation of at least one structural and heat-insulating layer, and the wall monolith is made of concrete on a gypsum binder or lightweight concrete on a cement base in the basement and concrete on a gypsum basis in the upper part, the window and door apertures are formed by racks with jumpers fixed between them of pro-thinned-out profiles, the overlap is prefabricated-monolithic with a fixed formwork, containing load-bearing beams resting at their ends on a strapping beam of a concrete-cut pro-thinned profile, between the existing beams placed a prefabricated non-removable arch formwork resting on the lower belt of the load-bearing beams, a reinforcing mesh is placed in the upper part of the floor, the floor monolith is formed with at least one structural and heat-insulating layer, and the floor monolith is made of concrete on gypsum and / or cement binder.

The concept of a “building system” is a complex characteristic of a building’s structural solution based on the material and technology of erecting its vertical load-bearing and enclosing structures in combination with a specific structural system

(solid monolithic, frame, with load-bearing walls, etc.) [Architecture of civil and industrial buildings: Civil buildings. Textbook for universities. / Under the total. ed. A.V. Zakharova, Moscow: Stroyizdat, 1993. - 509 p.].

In the particular case of the utility model, the overlying walls are connected to the ceiling with the formation of a platform joint.

In the particular case of the utility model, the racks are made up of two or more vertical elements interconnected.

In the particular case of the utility model, the racks are made of galvanized steel profiles or profiles made of composite materials based on carbon or fiberglass.

In the particular case of the utility model, the load-bearing floor beams are made in the form of I-beam and / or channel profiles.

In the particular case of the utility model, the foundation is made lightweight and shallow.

In the particular case of the utility model, the roof is made using slotted profiles as load-bearing structures.

In the particular case of the utility model, the strapping beam for wall spans is made of two grooved profiles embedded in one another and filled with concrete.

The proposed utility model differs from the closest analogue in the following. Fixed formwork of precast-monolithic walls and floors is made thin-walled from a material based on gypsum and / or glass silicate and / or cement and / or asbestos cement. The expansion of the formwork wall materials allows you to change the structural, heat-conducting properties of walls and floors, depending on operating conditions. The use of racks of perforated profiles, to which the wall formwork is attached, allows you to create a reliable wall structure that can perform supporting functions and

withstand temperature changes. The ability to perform a monolith of walls with the formation of at least one structural and heat-insulating layer expands the functionality to change the structural and heat-conducting properties of walls and ceilings depending on climatic, seismological and operational conditions, which makes it possible to control the thermal protection of buildings, the thermal efficiency of buildings during their operation , and also gives the opportunity to choose various options for the cost of construction. The monolith of walls made of concrete on a gypsum binder or lightweight concrete on a cement base in the basement and concrete on a gypsum base in the upper part, reduces the energy consumption of construction 2 or more times. High setting speed in the manufacture of gypsum-based building elements significantly reduces construction time. Each individual building element of the building system weighs no more than 50 kg and eliminates the need for heavy lifting equipment. The use of concrete on a gypsum basis significantly reduces the cost of the building. The use of gypsum-based concrete walls as a monolith increases the vapor permeability of the walls, which favorably affects the quality of life in buildings using the building system according to the utility model. In the manufacture of concrete on a gypsum binder, it is possible to use local materials, as well as waste from various industries for the purpose of their disposal. The use of mechanized means of production of construction works significantly reduces the traditional complexity, energy consumption and significantly reduces the construction time of the building. When using gypsum binder walls as a monolith, to ensure reliable load-bearing capacity of a building, it is necessary to use special floor structures that, on the one hand, can withstand the necessary load-bearing loads, and on the other hand, they themselves must not

create large loads on the walls. Performing overlapping according to the proposed design, containing load-bearing beams, resting at their ends on a strapping beam of a concrete grooved profile, between which a prefabricated fixed formwork of an arched shape is placed, resting on the lower belt of the load-bearing beams, in conjunction with the use of concrete wall concrete on a gypsum binder , allows you to create a strong and durable building structure, with optimal parameters of bearing capacity (strength, stability, durability). In order to enhance the bearing capacity of the floor, a reinforcing mesh is placed in the upper part of the floor. In order to improve the heat and sound insulating properties, the monolithic overlap is made with the formation of at least one structural and heat-insulating layer. The connection of the overlying walls with the overlap with the formation of the platform joint ensures the reliability of the structure. The structural design of walls and ceilings provides high thermal protection and optimal vapor permeability, which creates a comfortable indoor microclimate.

Thus, it is a combination of technical solutions for wall and floor structures that ensures the achievement of the claimed technical result.

The utility model is illustrated by drawings, where

Figure 1 is a perspective view of a building system,

Figure 2 is a spatial fragment of the wall structure and floor,

Figure 3 - schematically presents the nodes of the wall structure,

Figure 4 - schematically presents the nodes of the structure of the floor.

The construction system contains a foundation 1, a roof 2, supporting and enclosing structures in the form of precast-monolithic walls 3 with fixed formwork and precast-monolithic ceilings 4 with fixed formwork (Figure 1). The design and method of foundation is carried out according to

well-known structural schemes, but, given the reduced material consumption of wall structures and floors of this building system, lightweight shallow, shallow foundation structures are used: pile, strip, slab, freestanding.

The design and method of roof device 2 is carried out according to well-known structural schemes, but, given the use of lightweight metal grooved profiles in wall and ceiling structures, similar grooved profiles can be used in roof supporting structures.

Prefabricated monolithic walls 3 are connected to the foundation 1 with 5 steel anchors.

Prefabricated monolithic walls 3 have fixed formwork 6, which are attached to the posts 7 of the cut profiles using instrumental fasteners.

Anchor 5 is attached to the posts 7.

Racks 7 are used for fastening fixed formwork 6 and perform basic load-bearing functions in the walls (figure 2). Racks can be made of profiles of various materials, for example, galvanized steel, carbon-based composite materials or fiberglass. The monolith of walls 8 is made of concrete on a gypsum binder or lightweight concrete on a cement basis in the basement and concrete on a gypsum basis in the upper part. The average bulk density of concrete on a gypsum binder is 400-500 kg / m ³ . In the basement of the walls can be used lightweight concrete based on cement or a modified gypsum binder. The monolith of walls 8 is made with the formation of at least one structural and heat-insulating layer 9 (figa). Racks 7 can be made up of two or more vertical elements 10 and 10 ^I , interconnected. When several vertical elements 10 and 10 ^I are connected to each other in the longitudinal direction, the possibility is technologically ensured

the formation of a monolith of walls 8 from several structural and heat-insulating layers 9, 9 ^{I with} various characteristics with the formation of a multilayer wall structure (Fig.3b).

When the monolith of wall 8 is formed during the hardening of concrete on a gypsum binder due to adhesion, a reliable connection of the formwork 6 with the monolith of wall 8 is formed.

The window and door openers 11 are formed using struts 7 with bridges 12 fastened between them from cut profiles.

On the top of the uprights 7 are installed strapping beams 13 of a concrete grooved profile that increase the rigidity of the wall and serve as a support for the ceiling structure. Concreting of the cut-in profile of the strapping beam is made of high-strength concrete (B15-B20). When overlapping spans in the walls, the strapping beam 13 can be made of two perforated galvanized profiles, nested one in the other and filled with concrete.

The overlap 4 contains load-bearing beams 14, leaning at their ends on a strapping beam 13 from a concrete grooved profile, and attached to it using tool fasteners (Fig. 4).

The load-bearing beams of the floor 14 are made of perforated double-tee channel profiles made of galvanized steel. Other materials with the required load-bearing capacity can be used, such as carbon-based composite materials, fiberglass, basalt plastic. Between the supporting beams of the floor 14, a prefabricated fixed formwork 15 of an arch shape is placed, resting on the lower belt of the supporting beams 14. A reinforcing mesh 16 is placed in the upper part of the floor 4 (Fig. 4). The monolith of overlap 4 is made with the formation of at least one structural and heat-insulating layer 17. The monolith of overlap is made of concrete on

gypsum and / or cement binder. The floor monolith can be made, for example, with the formation of three structural heat-insulating layers 18, 19 and 20. In this case, the upper supporting layer of the floor monolith 18 is made of concrete with a modified gypsum binder with an average bulk weight of 1500 kg / m ³ . The reinforcing mesh 16 is made of fiberglass placed in the layer 18. The intermediate layer 19 is made of concrete on a gypsum binder with an average bulk density of 500 kg / m ³ . The monolith layer of the ceilings 20, reinforcing the fixed formwork 14, is made of concrete on a modified gypsum binder with an average bulk weight of 1500 kg / m ³ .

The overlying walls 3 are connected with the overlap 4 with the formation of the platform joint 21 (figure 2).

Fixed formwork of precast-monolithic walls 6 and fixed formwork 13 of precast-monolithic ceilings are made thin-walled from a material based on gypsum and / or glass silicate and / or cement and / or asbestos cement.

The use of the construction system is as follows.

In accordance with the project, soil conditions, adopted space-planning decision, I arrange the foundation. The foundations 1 are equipped with anchor devices 5. The base part of the walls 3 rests on the foundation 1. Walls 3 above the zero mark rest on the underlying floors, forming the platform joint 21. The fixed formwork 6 of the base part of the walls is made of flat pressed asbestos-cement sheets that are attached to the posts 7 by self-cutting screws. The permanent formwork of part of the walls 6 located above the zero mark is made of waterproof environmentally friendly materials, such as gypsum-fiber sheets, cement-bonded or particle-oriented plates. To ensure structural rigidity of the racks 7 along the perimeter of the bearing

walls 6 is attached to the strapping beam 13 in the form of a guide profile at the level of the top of the uprights 7, which is designed to create support for the ceiling. The installation of formwork 6 begins on the inside of the walls 3 and can be exposed to the entire height of the uprights 7. The outer formwork 6 is exposed as the walls 3 are filled with modified gypsum-based concrete. Monolithic pouring with modified gypsum concrete occurs in layers manually or mechanized - using a mortar pump. The production of gypsum concrete mixture is carried out mechanized using a mixer or concrete mixer. Such materials as expanded clay, expanded polystyrene, perlite, sawdust and other environmentally friendly lightweight fillers are used as lightweight fillers of modified gypsum concrete in the walls. The monolithic filling of the wall in accordance with the structural and thermal insulation requirements can be single-layer or multi-layer. After reconciling structures at horizontal and vertical levels, the anchor releases 5 from the foundation 1 and the ceilings are secured to the corresponding posts 7. On the horizontal surfaces of the formwork sheets of the inner layer of fixed formwork 6, rails are attached that create additional rigidity from the spread of the monolithic mixture and fix the formwork sheets in the design position. After gaining strength with plaster concrete, the slats are removed.

The apertures 11 are made of ready-made boxes of windows, doors and profiles and are installed in design positions as the walls are poured. Additional fastening of the opening holes in the design position is carried out by self-tapping screws to the sheets of the fixed formwork 6. Before filling the walls in the design position, flexible tube-cables are installed under the hidden electrical and telecommunication wiring. Outdoor and

the inner surface of the walls 3 are ready for painting or other methods of finishing the surface of the walls.

The overlap 4 is as follows. Bearing beams of floors 14 made of profiles are installed in the design position on the walls and fastened to the strapping beam 13 by self-tapping screws. On the lower shelves of the load-bearing beams 13 of the overlapping walls, prefabricated formwork arched form 15 is installed, filling the entire space along the length of the beams. The monolithic filling of the floor is a multilayer structure: a pouring layer of concrete mix with lightweight fillers, for example, polystyrene foam or perlite, to the upper level of the formwork arch form 15; concrete filling mixture with heavy fillers up to the upper design level of overlap, the upper layer of which is reinforced with fiberglass mesh. Concrete mixture is laid manually or mechanized - using a mortar pump. Before pouring the petia along the walls into the voids under the formwork of the arch form 15, gypsum concrete inserts of the corresponding form are installed. A feature of the installation of formwork on the outer surface of the walls of the building is that the formwork is displayed at the level of the top of the floor. If necessary, apertures are installed in the process of concreting or arranged in the finished floor mechanically. The lower surface of the ceiling - the ceiling - is finished by known methods. In this case, it is allowed to preserve the original wave-like form of overlap. The floor structure is performed in the traditional way.

Claims (8)

1. A building system comprising a foundation, a roof, supporting and enclosing structures in the form of prefabricated monolithic walls with fixed formwork, connected to the foundation with anchors, and at least one precast monolithic structure, characterized in that the fixed formwork of prefabricated monolithic walls and ceilings are made of thin-walled gypsum and / or glass-silicate and / or cement and / or asbestos-cement based materials, the wall formwork being attached to racks of cut profiles, and the wall monolith is formed to form at least one structure thermal insulation layer, and the monolith of the walls is made of concrete on a gypsum binder or lightweight concrete on a cement base in the basement and concrete on a gypsum basis in the upper part, the window and door openings are formed by struts with bridges made of cut profiles fixed between them, the overlap is made containing load-bearing beams, resting at their ends on a strapping beam made of a concrete grooved profile, between the load-bearing beams a prefabricated fixed formwork of an arched form, resting on the bottom a supporting belt of beams, a reinforcing mesh is placed in the upper part of the floor, the floor monolith is made with the formation of at least one structural and heat-insulating layer, and the floor monolith is made of concrete with gypsum and / or cement binder. 2. The construction system according to claim 1, characterized in that the overlying walls are connected to the ceiling with the formation of a platform joint. 3. The construction system according to claim 1, characterized in that the racks are made up of two or more vertical elements interconnected. 4. The construction system according to claim 1, characterized in that the racks are made of galvanized steel profiles or profiles made of composite materials based on carbon or fiberglass. 5. The construction system according to claim 1, characterized in that the load-bearing floor beams are made in the form of I-beam and / or channel profiles. 6. The construction system according to claim 1, characterized in that the foundation is made lightweight and shallow. 7. The construction system according to claim 1, characterized in that the roof is made using notched profiles as load-bearing structures. 8. The construction system according to claim 1, characterized in that the strapping beam for wall spans is made of two grooved profiles, nested one in the other and filled with concrete.