RU2035556C1 - Prefabricated building - Google Patents

Abstract

FIELD: construction. SUBSTANCE: prefabricated building has modular bearing members of exterior and interior walls, floors and platings, heat insulation and sound-proofing materials. Exterior and interior walls are formed from vertically installed modular bearing members in form of trough-shaped sheels of glass-fiber-reinforced concrete interconnected by means of fastening members passed through side walls. Hollows of shells of exterior walls facing inside are filled with heat insulating material and closed with covers, and hollows of shells of interior walls are filled with sound-proofing material and closed with covers facing alternately opposite sides. Floors are formed from bearing members in form of thin walled glass-fiber-reinforced concrete shells rectangular in plan interconnected by means of side walls and resting with their end faces on end faces of wall shells. Exterior walls consist of row and corner shells forming guard of story and frieze. Side walls of row shells are located normal to their bottom plate, and one or both longitudinal walls of corner shells are positioned at angle less than 90 deg. to bottom plate. Shells forming floor are trough-shaped. EFFECT: higher efficiency. 11 cl, 9 dwg

Description

 The invention relates to the field of construction and can be used in the construction of housing in extreme situations, as well as for the construction of low-rise and manor houses, cottages, country houses.

 From the patent literature there is known a modular system of wall fences of residential buildings made in the form of hollow panels, the outer plates of which are separated from each other at some distance and are connected to each other by spacers, the panels are installed at the height of the floor, openings are formed in the places of windows and doors in the panels [1] In this case, the dimensions of the wall panels do not allow their installation without the use of crane equipment. In addition, the modular elements of the described type are intended only for the walls of the building.

 Also known is a modular element for walls and ceilings made of rigid insulating foam treated accordingly. The edges of the element are processed in such a way that it can have a different purpose: to make the walls of the facade, internal walls with different ways of joining the ceilings, and also to make insulating elements. Elements allow you to perform racks and transverse frames after installing reinforcement and pouring concrete on a construction site [2] The disadvantage of the described method is the need for the so-called "wet" processes at the construction site, which in individual construction or construction in extreme situations is difficult.

 In another analogue [3], prefabricated modular building elements wall panels and ceilings are mounted on reinforced columns and beams forming the building frame. The fastening of the enclosing elements on the frame is carried out by means of threaded joints of bolts and nuts. In this version of the building, its construction is complicated by columns and beams.

 The closest analogue adopted for the prototype is the building structure, consisting of modular load-bearing elements of external and internal walls and floors, connecting elements and heat and sound insulation mounted on modular load-bearing elements [4] The disadvantage of the described construction is the technical solution, in which the heat and sound insulation is laid on top of the modular bearing element, remaining on the outside unprotected. This is only possible if rigid heat and sound insulation is used, which significantly limits the selection of these materials.

 The objective of the invention is the creation of a building system, the main components of which are external and internal load-bearing walls, ceilings, coating elements are made of fundamentally identically solved products, are made of the same material using a fundamentally unified technology. In addition, the weight of any single element should allow its installation without the use of lifting means, and a set of these elements should satisfy the principle of complete delivery of the ground part of the building.

The essence of the invention lies in the fact that the outer and inner walls are formed of vertically mounted modular load-bearing elements in the form of trough-like thin-walled shells of fiberglass concrete, connected by fasteners passed through the side walls. The shell cavities of the outer walls are facing the inside of the building, filled with heat insulation and covered with lids, and the shell cavities of the internal walls are filled with sound insulation and closed with lids facing alternately in opposite directions. Overlappings are formed of load-bearing elements in the form of thin-walled glass-fiber-reinforced concrete shells rectangular in plan, connected by side walls and supported by their ends on the end walls of wall-mounted shells. The outer walls consist of rows and angular shells forming the enclosure floor and the frieze, the sidewalls of ordinary shells are arranged normal to their bottom, and one or both longitudinal walls of angular shells located towards the bottom at an angle smaller than ⁹⁰ °. The shells forming the overlap can be made in a trough-like shape, or can consist of extreme and ordinary elements, the extreme elements having an L-shaped cross section and their width equal to half the width of the ordinary shells of the wall, and the ordinary elements have a T-shaped cross section and width they are equal to the width of the ordinary shells of the wall. Connecting fasteners are made in the form of coupling bolts passed through oval holes formed in the side walls of adjacent shells. The coating has rafters of T-section, on the shelf of which a longitudinal groove is formed with a wooden block embedded in it. On the outer surfaces of the shells, longitudinal grooves are made in which a sealing gasket is installed. The ceiling shells can be connected to the wall shells by bolts passing through the cover plate installed on the edges of the side walls of the ceiling shells in the gap formed between adjacent side walls of the ceiling shells and through the side wall of the wall shell. The frieze and floor shells can rest on the side wall of the shell of the floor fencing and are connected to it by bolts passing through the side walls of the frieze shell and the floor guard and the bottom of the shell of the floor. The frieze shell can be mounted on the ceiling shell and can be bonded to the shell shell and floor fencing with vertical bolts passed through these shells.

 The inner load-bearing wall is connected to the external load-bearing wall by means of a shell element of the angular profile fastened to the side walls of the wall forming bolt.

 A comparative analysis of the proposed prefabricated building with the prototype shows that it differs in the execution of the external and internal walls in the form of vertically mounted modular load-bearing elements in the form of trough-like thin-walled shells made of fiberglass concrete, connected by fasteners passed through the side walls. The shell cavities of the outer walls are facing the inside of the building, filled with heat insulation and covered with lids, and the shell cavities of the internal walls are filled with sound insulation and also closed with lids facing alternately in opposite directions. Overlappings are formed of load-bearing elements in the form of thin-walled glass-fiber-reinforced concrete shells rectangular in plan view, connected by side walls and supported by their ends on the end walls of wall-mounted shells. Such a combination of elements, from the mutual arrangement and relationship, as well as the structural design, was not previously known, which allows us to conclude that there is novelty in the claimed invention.

 The claimed design of a prefabricated building allows you to perform all the main load-bearing elements of the building, internal and external walls, floors, rafters of fundamentally the same structure from the same material using the same technology and ensures the prefabrication of the building and the completeness of its delivery. In addition, the construction of the building is made in such a way that the weight of any single prefabricated element allows it to be installed manually without the use of lifting mechanisms.

 In FIG. 1 shows a cross section of a building; in FIG. 2 building plan, section AA in FIG. 1; in FIG. 3 node connecting the outer walls; in FIG. 4 junction of the shell of the outer and inner walls; in FIG. 5 node connecting the shell of the walls and floors; in FIG. 6 connection node of the shell of the walls of the floor and the frieze with the shell of the ceiling (option); in FIG. 7 connection node of the shell of the wall of the floor and the ceiling (variant of the shell of the ceiling of the T-section); in FIG. 8 node connecting the walls of the floor, floor and frieze (option); in FIG. 9 rafters, cross section.

 The building consists of modular load-bearing elements of the outer 1 and inner 2 walls mounted on the foundation 3. The walls are formed of vertically mounted trough-like thin-walled shells 4 of fiberglass concrete, in the side walls 5 of which oval holes are made 6. Fasteners 7 are passed through these holes, as which used bolts or studs with nuts. The cavities 8 of the shells of the outer walls are facing the inside of the building, filled with thermal insulation 9, for example semi-rigid mineral wool boards, and closed with lids 10. The cavities of the shells of the internal walls are filled with soundproofing 11, are also closed with lids and are located alternately in opposite directions. The overlap 12 is also made in the form of thin-walled fiberglass concrete shells 13, 14, 15 of a rectangular shape and supported by the ends 16 on the end walls 17 of the wall shells.

The outer walls consist of ordinary 18 and angular 19 shells, forming fences of the 20th floor and a frieze 21. For ordinary shells, the location of the side walls 5 is normal to the bottom of the shell 22, and for the corner one or both longitudinal walls 23 are located at an angle less than the bottom 90 ^about .

 The shells forming the overlap can be made of a trough-shaped form 13 or can consist of two types of elements: the L-shaped section 14 and the T-section 15, and the elements of the L-shaped section have a width equal to half the width of the ordinary shell of the wall, and t-shaped equal to the width of the ordinary wall shells: this ensures optimal load distribution from the overlapping of the walls.

 Covering 24 of the building has rafters 25 of T-section, on the shelf 26 of which a longitudinal groove is formed with a wooden block 27 embedded in it. The rafter beam is also made of fiberglass concrete.

 To ensure reliable insulation of the walls from the penetration of atmospheric moisture and from blowing on the outer surfaces of the walls of the shells, longitudinal grooves are made in which sealing gaskets 28 are installed.

 The fastening of the shells of the ceiling with the shells of the walls can be solved in two versions. According to the first embodiment, the fixing bolt 7 is passed through a cover plate 30 installed on the ribs 29 of the side walls of the floor shells, passes through the gap 31 formed between adjacent side walls of the shells of the floor, and through the side wall of the wall shell. This mount is suitable when the ceiling is supported on an internal wall. According to the second variant, the shells of the frieze and the floor are supported on the side wall of the shell of the floor fencing and are connected to it by bolts passing through the side walls of the shell of the frieze and the floor guard and the bottom of the shell of the floor.

 The inner supporting wall may be connected to the outer walls by means of a corner 32.

 A variant is possible in which the frieze shell is mounted on the ceiling shell and bonded to the ceiling shell and floor fencing with vertical bolts passed through these shells.

 Installation of the building is carried out in the following order.

 The shells of the fencing of the floor 20 are installed in the vertical design position on the foundation 3 and secured to each other by means of bolts 7, passed through the holes 6 in the side walls 5 of the shells, and with the foundation 3 (fixing to the foundation is not shown in the drawings). At the joints of the side walls 5 of the shell shells of the fencing of the floor 20, sealing gaskets 28 are laid, for example, of paroisol, which are compressed when tightening the bolts 7. Simultaneously with the shells of the outer walls of the fencing of the floor 20, the shells of the inner walls 2 are mounted. The cavities 8 of the shells of the outer walls 1 are facing the inside of the building, and the shells of the shells of the inner walls 2 are located alternately in opposite directions. The shells of the inner walls 2, as well as the shells of the outer walls 1, are interconnected by bolts 7, passed through the holes 6. The shells of the outer and inner walls at their junctions are connected with each other using the corner 32 on the bolts 7. Then, the ends of the outer shells 17 walls 1 are laid with their ends 16, the shells of the ceiling 12 and are also fastened to the shells of the walls with bolts 7. The installation of the shells of the frieze 21 can be done in different ways: either the shells of the frieze 21 are installed and fastened with bolts 7 on the ends of the wall shells 1 to the mouth new shells of the ceiling 12, or the shells of the frieze 21 are mounted on pre-installed shells of the ceiling 12, and then all three shells: the frieze 21, the floors 12 and the walls of the floor 20 are connected by one common bolt passed through them 7. Between the shells of the walls 1 and the ceiling 12 can be cement-sand paste 33 was laid. With the installation of overlapping of L-shaped 14 and T-shaped 15 shells, the order of their installation remains the same.

 When the flooring shells 12 are supported on the shell of the inner wall 2, they are also fastened to each other on bolts 7, passed through the shells of the overlapping shells 30 installed on the ribs 29 of the sidewalls, passing through the gap 31 formed between adjacent sidewalls of the shells of the ceiling, and through the side wall shell wall.

 After installation is complete, the shells of walls 1, 2 and the overlapping of their cavity 8 are filled for external walls and ceilings 12 with thermal insulation 9, and for the inner wall 2 with sound insulation 11 and are closed with covers 10.

 The shells of the frieze 21, lintels, window sills, walls are also made of fiberglass concrete and do not have fundamental structural differences from the shells that form the floor wall.

Claims (11)

 1. ASSEMBLY BUILDING, containing modular load-bearing elements of external and internal walls, ceilings and coatings, connecting fasteners and heat and sound insulation, characterized in that the external and internal walls are formed of vertically mounted modular load-bearing elements having the form of trough-like thin-walled shells of fiberglass concrete connected by fasteners passed through the side walls, the shell cavities of the outer walls facing the inside of the building, filled with thermal insulation and covered with lids, and Lost shells filled interior walls are soundproofed and capped facing alternately in opposite directions, the overlap of the carrier members formed as thin rectangular in plan GRC shells connected by side walls and at the supported ends of the end walls of wall shells. 2. The building according to claim 1, characterized in that the outer walls are made of ordinary and angular shells forming a floor fence and a frieze, the side walls of ordinary shells being located normally to their bottom, and one or both longitudinal walls of the corner shells are located to the bottom under angle less than 90 ^o .  3. The building according to claim 1, characterized in that the shells forming the overlap are made of a trough-like shape.  4. The building according to claim 1, characterized in that the shells forming the overlap are made of extreme and ordinary shells, the extreme shells having an L-shaped cross-sectional shape and their width equal to half the width of the ordinary shells of the wall, and the ordinary shells are T-shaped cross section and their width is equal to the width of the ordinary shells of the walls.  5. The building according to paragraphs 1 to 4, characterized in that the connecting fasteners are made in the form of coupling bolts passed through oval holes formed in the side walls of adjacent shells.  6. The building according to claim 1, characterized in that the coating has rafters of T-section of fiberglass concrete, on the shelf of each of which a longitudinal groove is made for installing a wooden block in it.  7. The building according to claims 1 to 4, characterized in that on the outer surfaces of the walls of the shells longitudinal grooves are made for installing sealing gaskets.  8. The building according to claims 1 to 5, characterized in that the ceiling shells are connected to the wall shells by means of overlays through which the bolts are passed and which are installed on the edges of the side walls of the ceiling shells, while the bolts are placed in the gap formed between adjacent side walls of the shells overlapping, and passed through the lining and the side wall of the shell wall.  9. The building according to claims 1 to 5, characterized in that the frieze shells and ceilings are supported on the side wall of the shell of the floor fencing and are connected to it by bolts passing through the side walls of the frieze shell and the side walls of the shell of the floor fencing, as well as through the bottom of the shell of the ceiling and side walls of the floor guard.  10. The building according to claims 1 to 5, characterized in that the frieze shell is mounted on the floor shell and bonded to the floor shell and floor fencing with vertical bolts passed through these shells.  11. The building according to paragraphs 1 to 5, characterized in that the inner bearing wall is connected to the outer bearing wall by means of an angular profile, bolted to the side walls of the wall-forming shells of the element.

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