RU2168590C1 - Skeleton-type building - Google Patents

Abstract

FIELD: construction engineering; erection of buildings with self-supporting walls. SUBSTANCE: each floor slab has over its outer perimeter E-shaped cantilevers with embedded items on their ends; front layer of external slab is placed beyond end of floor slab on angle piece which is rigidly fixed to embedded items; internal layer of external wall is made of individual hollow blocks. Mentioned method involves use of effective building materials ensuring optimal conditions for manufacturing architectural appearance of building and wide choice of development alternatives with same element base. Method involves reduction of reinforcement consumption for floor slab and cost of construction, reduction of nomenclature of building members due to lower weight of wall, and improvement of heat-insulation of building. EFFECT: reduced due date of construction and material input. 8 cl, 10 dwg

Description

 The invention relates to the field of construction, namely to frame buildings, and can be used in the construction of buildings with self-supporting walls.

 Known frame building according to the certificate for a utility model of the Russian Federation N 1508, cl. E 04 C 2/00, 1996, containing floor slabs and multilayer outer walls in the form of an outer layer of small pieces, preferably brick, half a brick thick with buttresses protruding into the wall, thermal insulation of the middle wall layer and the inner layer.

 The disadvantage of this design is poor thermal insulation of horizontal joints of walls with ceilings, and if, when performing external walls in the form of panels, they are mounted on a building frame, which allows to isolate the frame elements from the outside air, then if the wall is made of piece materials, such as brick, such insulation is not reliable enough.

 Known frame building according to the patent of the Russian Federation N 2104371, class. E 04 In 1/18, 2/28, 1998, adopted by the applicant for the prototype and containing floor slabs and multilayer outer walls in the form of an outer layer of small pieces, preferably brick, half a brick thick with buttresses protruding inside the wall, thermal insulation of the middle layer walls and the inner layer of the wall. The outer layer of the wall is mounted flush with the end of the floor slab, in the body of which, through the grooves, the through grooves filled with the insulating material are formed parallel to its outer face, the thickness of the thermal insulation exceeding the length of the protrusions of the buttresses. As thermal insulation, polystyrene foam, or a mineral plate, or a foam-gypsum plate, or a foam board are used. As the inner layer, gypsum tongue-and-groove partition plates or cement-sand blocks can be mounted.

 The disadvantages of this building design are unreliable and insufficient wall insulation at the place where the wall adjoins the floor slab, limiting the architectural design of the building facade due to the presence of horizontal cuts, since the outer layer is mounted flush with the end of the floor slab, and high labor costs when installing external walls due to low-tech work with the presence of a large number of different materials in the wall structure.

 An object of the invention is the use of effective building materials that can significantly reduce the labor costs and construction time of an object, reduce the material consumption of both the structures themselves and their constituent elements, while ensuring optimal conditions for creating the architectural appearance of the building and a wide selection of building options at the same element base. By reducing the dead weight of the wall, reduce the consumption of reinforcement on floor slabs and the cost of building an object, reduce the range of building elements, and improve the thermal insulation of the building.

 The problem is solved in that in the proposed technical solution, each floor slab along the outer perimeter of the building is made with W-shaped consoles, the embedded parts are fixed at the ends of them, and the outer layer of the external wall is placed behind the end of the floor slab and mounted on a corner that is rigidly fixed to embedded parts, the inner layer of the outer wall is made of piece hollow blocks.

 In addition, at least a part of the outer layer of the outer wall is made of brick and reinforced with reinforcement cages or individual rods layer-by-layer multiple to the height of the hollow block of the inner layer of the wall, with each reinforcement cage connected to the hollow block by means of a T-shaped plate.

 In addition, the outer wall is made of hollow blocks, the thickness of each block is equal to the thickness of the wall, and the outer edge of the wall is placed behind the end of the W-shaped consoles.

 In addition, in the outer layer of the outer wall, in the plane of the floor slab, additional hollow piece blocks are installed to a height equal to the thickness of the floor slab.

 In addition, the space between the W-shaped consoles and the corner and between the W-shaped consoles and additional hollow blocks, as well as the structural gap between the wall and the bottom of the floor slab, are filled, for example, with polyurethane foam.

 In addition, the voids of the hollow blocks are filled with lightweight foam concrete, or, for example, polyurethane foam, and at least part of the horizontal and vertical voids are reinforced with anti-corrosion coating.

 In addition, reinforced frames are installed in the voids of the hollow blocks and filled with heavy concrete, and on the outer part of the outer wall there is a heater, for example, made of polyurethane foam, or expanded polystyrene, or from a mineral wool plate with a protective coating.

 In addition, the hollow blocks are made of structural foam concrete, or of expanded clay concrete, or fired ceramic, each hollow block having dividing partitions, in which through holes are made in the center, and two half-openings are made at the upper and lower ends of the partitions.

In FIG. 1 shows a general view of a building with a prefabricated exterior wall;
in FIG. 2 - general view of the building in plan;
in FIG. 3 - the outer layer of the outer wall and floor slab with W-shaped consoles;
in FIG. 4 - section AA in FIG. 2;
in FIG. 5 - node I in FIG. 1;
in FIG. 6 is a section BB in FIG. 5;
in FIG. 7 - outer wall of hollow blocks;
in FIG. 8 - a fragment of a wall with vertical concrete filled with vertical voids;
in FIG. 9 - hollow block;
in FIG. 10 is a view B in FIG. 9.

 The frame building contains a floor slab 1 mounted on a column 2, a self-supporting and multi-layer external wall 3. The floor slab 1 along the outer perimeter of the building is made with W-shaped consoles 4, on the ends of which are embedded parts 5. At the level of the lower plane of the floor slab 1 to embedded parts 5, for example, a corner 6 is welded on which the outer layer 7 of the outer wall 3 is placed, and it is located behind the end of the floor slab 1. The inner layer 8 of the outer wall 3 is made of piece hollow blocks 9, and the outer layer 7 can be Gross, for example, made of brick thick and is reinforced in a half-brick reinforcement 10 and separate rods. Armoframes 10 are placed along the height of the wall in layers multiple to the height of the hollow block 9, and each armature 10 is connected to the hollow block 9 by means of a T-shaped metal plate 11 with a corrosion-resistant coating, for example galvanized, and the reinforcement 12 is placed in the hollow blocks 9, and it can be placed if necessary both horizontally and vertically. This placement of reinforcing frames 10, reinforcement 12 and plate 11 provides the reliability and rigidity of the outer wall 3. Moreover, reinforcing frames 10 and reinforcement 12 are made with a corrosion-resistant coating.

 The outer wall 3 can be made entirely of hollow blocks 9, while the minimum thickness of the wall 3 will be equal to the thickness of the block 9, and the outer edge of the wall 3 is placed behind the end of the W-shaped consoles 4. In this case, in the outer layer 7 of the outer wall 3, the plane of the floor slab 1, installed additional hollow piece blocks 13 to a height equal to the thickness of the floor slab 1.

 When erecting the outer wall 3 between the wall and the bottom of the floor slab 1, a structural gap is provided, as well as spaces: for example, between W-shaped consoles 4 and corner 6, between W-shaped consoles 4 and additional hollow blocks 13, which are filled, for example, with polyurethane foam 14.

 If necessary, based on the purpose and design features of the building, the voids of the hollow blocks 9 can be filled with lightweight foam or polyurethane foam, and also part of the voids of the hollow blocks 9 can be filled with heavy concrete. At the same time, insulation 15 is installed on the outer part of the outer wall 3, for example, of polyurethane foam, or of a mineral wool board with a protective coating consisting of a mesh 16 and mortar 17 or building mastic, and thermal insulation 18 is laid in between the W-shaped consoles 4.

 Hollow blocks 9 can be made of structural foam concrete, or expanded clay concrete, or fired ceramic. Moreover, the hollow block 9 has dividing partitions 19, in which through holes 20 are made in the center, and two half-openings 21 are made at the upper and lower ends of the partitions 19. Half-openings 21 are designed to accommodate either armor frames or individual rods.

 The construction of a frame building is as follows.

 The building frame is erected, including columns 2 and floor slabs 1 with W-shaped consoles 4 and embedded parts 5 at the ends of the W-shaped consoles 4. Then, corner 6 is attached to the embedded parts 5 and the space between the W-shaped consoles 4 and corner 6 is filled with heat-insulating material 15, for example polyurethane foam. On the corner 6 lay the outer layer 7 of the outer wall 3, consisting, for example, of a brick half a brick thick. In this case, the outer layer 7 is located behind the end of the floor slab 1. On the brickwork, reinforcement frames 10 are placed, on which T-shaped plates 11 are mounted with a shelf in the direction of the inner layer 8, vertically orienting it. The inner layer 8 of the outer wall 3 is mounted from single-piece hollow blocks 9, and the shelf of the T-shaped plate is sent to the voids of the block 9. The reinforcement 12 is mounted on the hollow blocks 9, based on half-openings 21. Then, the voids of the hollow blocks 9 are filled with hardening material: light or heavy concrete, or polyurethane foam, depending on the purpose of the design. Moreover, heavy wells are filled with "wells", vertically reinforced with reinforcement 12, forming additional pillars of the building.

 Thus, the outer layer 7 and the inner layer 8 of the outer wall 3 are erected to the floor slab 1 of the next floor of the building. In the case of using hollow blocks 9 for mounting the outer 7 and inner 8 layers of the outer wall 3 in the plane of the floor slab 1, add additional hollow blocks 13 to a height equal to the thickness of the floor slab 1, and the hollow blocks 9 of the inner layer 8 are laid to the bottom of the floor slab, leaving a structural gap. After that, the voids of the upper hollow blocks 9 are filled with hardening material and the structural gap between the wall and the bottom of the floor slab is filled with polyurethane foam 14. The self-supporting wall between the two floor slabs is ready. The next stage of construction begins with the fastening of the next corner 6 to the embedded parts 5 of the floor slab 1 of the next floor.

 Using the proposed technical solution makes it possible to apply new effective building materials, which not only reduce the complexity and time of the construction of the object, but also provide ample opportunity to create a diverse architectural appearance of the building and the choice of development options. By reducing the dead weight of the wall, reducing labor costs for its construction, cost is reduced, which reduces the consumption of fittings for the construction of the facility, as well as operating costs for heating the building.

Claims (8)

 1. A frame building containing floor slabs, multilayer outer walls, including brick and thermal insulation of the middle layer, characterized in that each floor slab along the outer perimeter of the building is made with W-shaped consoles, the embedded parts are fixed at the ends of them, and the outer layer of the outer wall placed behind the end of the floor slab and installed on the corner, which is rigidly fixed to the embedded parts, the inner layer of the outer wall is made of piece hollow blocks.  2. The building according to claim 1, characterized in that at least a part of the outer layer of the outer wall is made of brick and reinforced with reinforced frames, or with individual rods layer-by-layer multiple to the height of the hollow block of the inner layer of the wall, with each reinforced frame connected to the hollow block via a plate T -shaped.  3. The building according to claim 1, characterized in that the outer wall is made of hollow blocks, the thickness of each block is equal to the thickness of the wall, and the outer edge of the wall is placed behind the end of the W-shaped consoles.  4. The building according to claim 1, characterized in that in the outer layer of the outer wall, in the plane of the floor slab, additional hollow piece blocks are installed to a height equal to the thickness of the floor slab.  5. The building according to claim 1, characterized in that the space between the W-shaped consoles and the corner, and between the W-shaped consoles and additional hollow blocks, as well as the structural gap between the wall and the low floor slabs are filled, for example, with polyurethane foam.  6. The building according to claim 1, characterized in that the voids of the hollow blocks are filled with lightweight foam concrete or, for example, polyurethane foam, with at least part of the horizontal and vertical voids reinforced with reinforcement with an anti-corrosion coating.  7. The building according to claim 1, characterized in that in part of the voids of the hollow blocks, reinforced frames are installed and filled with heavy concrete, and on the outer part of the wall there is a heater, for example, from polyurethane foam, or from polystyrene foam, or from a mineral wool board, with a protective coating.  8. The building according to claim 1, characterized in that the hollow blocks are made of structural foam concrete, or expanded clay concrete, or fired ceramic, each hollow block having dividing walls, in which through holes are made in the center, and at the upper and lower ends partitions are made in two half-openings.

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