RU2065907C1 - Framework and method for erection of building - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: framework has four columns with above-columns and two ceiling slabs located between them. Width of each slab is 4 m, length of above-column slabs is 3.3 m. Columns are spaced by 6.3 m in width and 6.0 m in length. Framework can be provided with additional columns spaced in plan at pitch in length of 6.0 m and/or in width of 6.3 m pitch. Besides, framework can have at least one standard ceiling slab 4.8 m long and 1.2 m wide located between inter-column and above-column slabs. Framework is also provided with cross-section beams located vertically and/or horizontally relative to columns or slabs. Beam can take form of span piece and located between columns in plan parallel to one framework axes or at angle to it. At this version, framework can be given additional beams, each taking form of rafter leg resting against column or slab or span piece. EFFECT: reduced labour, time and material needed for erection. 25 cl, 27 dwg

Description

 The invention relates to construction and can be used in the construction of industrial and residential buildings and public buildings, erected in a frameless frame.

The closest known structure is a frame and a building, a structure containing four columns with column columns and two intercolumn slabs located between them, the width of which is equal to the width of the column columns and at least one spacer element located between the column or intercolumn plates [1]
There is also known a method of building a building, construction, including the construction of a foundation, the installation of four columns, the installation of supercolumn floor slabs on them and the installation of two intercolumn floor slabs between them, the width of which is equal to the width of the supercolumn slabs, the installation of at least one spacer element between the column or intercolumn slabs and roofing [2]
The disadvantages of the known solutions are significant labor costs and construction time, increased material consumption, the inability to obtain optimal planning solutions.

 EFFECT: inventions can significantly reduce labor costs and construction time, reduce the material consumption of both the structures themselves and their constituent elements, while ensuring optimal conditions for the planning of internal premises and a wide choice of building options with the same element base.

 This is achieved by the fact that in the frame of the building, structure, containing four columns with columns and two intercolumn slabs located between them, the width of which is equal to the width of the columnar slabs, and at least one spacer element located between the column or intercolumn slabs, the width of each of the column and intercolumn slabs are 1.2 m, and the column columns are 3.3 m long, and the columns are installed with a horizontal spacing of 6.3 m and a length of 6.0 m between them. Moreover, the building frame is equipped with extra with stupid columns arranged in plan along the length and / or width of the frame with a step along the length of 6.0 m and a width of 6.3 m. The spacer element is made in the form of a floor slab 4.8 m long and 1.2 m wide, or in the form of at least a pair of crossbars, or in the form of a cross-shaped beam located horizontally and / or inclined to the columns of the frame or to the floor slabs. At the same time, the main and additional columns and crossbars have a cross-shaped cross section. The crossbars are located between the columns parallel to one of the axes of the frame or at an angle to it. A, the frame is equipped with building beams, each of which is supported on a column of the frame, and / or on a column or intercolumn plate, or on a crossbar. In addition, the frame is equipped with struts of a cross-shaped cross section, located in plan from the front or end side of the frame or on a column plate.

 In a building or structure, this is achieved by the fact that in a building or structure containing a foundation, four columns with supercolumn slabs installed on them and intercolumn slabs located between them, the width of which is equal to the width of the supercolumn slabs, at least one spacer element located between the column or intercolumn slabs, wall structures of fencing, slanting, rafters and roofing, the width of each of the column and intercolumn slabs is 1.2 m, the column columns are 3.3 m long, and the columns are installed with the distance between them in the plan of the building is 6.3 m wide and 6.0 m long. In this case, the building is equipped with additional columns located in the plan along the length and / or width of the building with a step of 6.0 m in length and width 6.3 m, and between the spacer element is made in the form of a plate 4.8 m long and 1.2 m wide or in the form of a crossbar and is located between the over-column or inter-column plates. The spacer element is made in the form of a beam of a cross-shaped cross section located horizontally and / or inclined to the columns or to the floor slabs. And the main and additional columns have a cross-shaped cross section. The building is equipped with cross-shaped racks installed on the front or on the front side of the building at a distance less than or equal to the column spacing, respectively, along the length or width of the building in plan, with the formation of a fencing connecting the wall structures with a polygonal outline. Moreover, the wall structure of the fence is polygonal in terms of contour. Moreover, the wall structures of the fence are made with ribbed widths of 1.2 m with or without window or door openings, or of small-sized brick elements, tongue-and-groove blocks with cladding or protective and decorative coatings, as well as in the form of monolithic cellular concrete structures with brick or cement-sand lining. fixed formwork slabs. The kosoura are made of L, Z or L-shaped with obtuse angles between the shelves and walls and are supported on columns or columns and columns above columns or columns and intercolumn plates or at one end on columns or plates, and the other are in contact with each other with the formation of roof rafters .

 In the method of constructing a building, structure, the goal is achieved by constructing a foundation, installing four columns, placing on top of them column columns and installing between them two column columns, the width of which is equal to the width of columns, installation of at least one spacer between the over-column or inter-column plates and the roofing device, and after the foundation of the device is installed, the columns are installed with a distance between them in plan of 6.3 m in width and 6.0 m in length, then install t supercolumn, 3.3 m long, and intercolumn slabs with a width of each equal to 1.2 m, and rafters are mounted in front of the roof device. After installation of the main foundations and columns, additional columns are arranged with their location in plan along the length and / or width of the frame with a step along the length of 6.0 m, and a width of 6.3 m. After installing the intercolumn slabs between them or between the columns spacer elements in the form of at least one floor slab 4.8 m long and 1.2 m wide. After mounting the column columns between them or between the column columns, spacer elements are installed in the form of at least a pair of crossbars. After the installation of the intercolumn plates, spacer elements are installed in the form of beams of a cross-shaped cross section horizontally and / or inclined to the columns of the frame or to the floor slabs. After the foundation is erected, the main and additional columns are installed, having a cross-shaped cross section. After the installation of the column columns, cross-sectional racks are installed on the front or end side of the building or on the column columns. After the columns are mounted, additional crossbars of a cross-shaped cross section are installed between them parallel to one of the axes of the building or at an angle to it. And when installing the rafters, additional rafters of a cross-shaped cross section are installed with each of them resting on a column and / or on a column or inter-column plate or on a crossbar.

The invention is illustrated by drawings, where:
in FIG. 1 schematically shows the frame of the building in plan with column and intercolumn slabs.

figure 2 is the same with the offset columns along the length or width of the building;
figure 3 frame of the building with one slab; in Fig.4 a building frame with a pair of crossbars; figure 5 is a cross section of a cross-shaped beam; figure 6 frame of the building with cross-shaped in cross section of the columns; in Fig.7 the frame of the building with cross-shaped cross-sectional crossbars located between the annular and supercolumn plates; on Fig frame of the building with cross-shaped cross-section crossbars located parallel to one of the axes of the building and at an angle to it; Fig.9 building with rafters; figure 10 is a cross section of one embodiment of a wall panel; figure 11 element kosoura and rafters of the Z-shaped profile; 12 shows an element of the kosour and rafters of the L- and L-shaped profile; on Fig frame of the building with the location of the elements of the rafters of Fig. 11 and 12; on Fig.14-27 variants of plans of buildings, structures designed using the above-described framework of the GVAMP and the elements included in it.

 The frame of the building, structure and building includes the following elements: columns 1 mounted on foundations (not shown conventionally in the figures) with 2 columns placed on them, 3 columns interconnected across the width of the building. Such a combination can be made with the formation of additional spans both along the width of the building and along its length. In the spans between the over-column 2 and the inter-column 3 plates, spacer elements 4 are placed, which can be made in the form of ordinary (inter-span) plates 5, or crossbars 6, or cross-section beams 7 (Fig. 5). Columns 1, crossbars 6 and rafters 8 (Fig. 9) may have a cross-shaped cross section. Wall structures of the fence 9 can be made in the form of ribbed plates 10 with a width of 1.2 m (Fig. 10) with or without window or door openings and act as stiffener core elements in multi-storey buildings. The main 1 and additional 11 columns are installed in increments of 6.3 m in width and 6.0 m in length of the building, which allows for optimal use of the resulting areas with rational choice of 3.3 m column columns, 4.8 ordinary and 3 column columns. distribution of existing loads. Ladder braids 12 are made of beams of rectangular or cross-section (Fig. 5, 9) and have a L, Z or L-shape (Fig. 11, 12) with obtuse angles between the shelves and walls. These elements are supported on columns 1.11 or on columns 1.11 and on-column 2 plates or on columns 1.11 and intercolumn 3 plates, or at one end on columns 1.11 or plates, or on crossbars 6, while others are in contact with each other the formation of the rafters of the roof 13 (Fig.13). The frame can be equipped with racks 14 of a cross-shaped cross-section, which are installed on the front or front side of the building and form a connecting wall structure of the fence 9 with a polygonal outline of the building (Figs. 14-27).

Installation of buildings, structures based on the framework of the GVAMPOM is carried out as follows:
Columns 1.11 of the first floor are mounted vertically on the center axes of the building using pre-assembled and verified foundations using single or group conductors. After the alignment of the columns 1,11 they are poured with concrete in the glasses of the foundations. Without removing the conductors, the column pins 2 are put on the column pins 2. After the installation of the column columns 2, the overlap of the first cell (6.0 x 6.3 m) is laid on them with cement mortar, the column columns 3 and on the console of the column 2 and column 3 3 are laid ordinary plates 4 or crossbars 6 (depending on the chosen project). Then the conductors are rearranged to the next cell and the operations described above are repeated. Prior to the installation of the second floor structures, it is necessary to install wall panels 10, both external and internal walls, as well as flights of stairs using Kosoures 12 of the forms described above. Wall panels 10 are installed with the bottom face on top of the foundations or foundation beams, and the top face is connected to the floor slabs by welding. Stair slopes 12 at the top are attached to the slabs. The installation procedure for the second floor is similar to the installation of the first floor with the exception of the installation of columns 1.11, because the lower end of the upper column 1.11 is welded through the embedded part to the embedded part of the over-column floor slab.

Roof elements are mounted in the following order:
columns are mounted using conductors;
make installation of the main rectangular crossbars, which are fastened through embedded parts to the columns for welding;
they install roof slabs or cross-shaped rafters, which are attached to the main beams or columns for welding through embedded parts.

 Features of the installation of the aerial parts of five-story houses are that it begins with the middle cell, where the stiffness core is located, made of paired with each other elements of wall structures 1.2 m wide (Figs. 10, 26 and 27). In this case, the wall panels of the stiffener core are connected to each other in the horizontal and vertical planes by steel plates or reinforcing bars in welding. Installation of structures on the next floor also begins with a core of rigidity.

 Significant economic effect from the implementation of these inventions is confirmed by calculations and comparison of technical and economic indicators introduced in construction in several regions of Russia and the well-known frame systems 1.020-1, 1.420A, UMK (KSM), KUB 2.5. YYY2 YYY4 YYY6 YYY8 YYY10 YYY12 YYY14 YYY16 YYY18 YYY20 YYY22 YYY24 YYY26

Claims (25)

 1. The frame of the building, structure, containing four columns with a column and two intercolumn slabs located between them, the width of which is equal to the width of the column, and at least one spacer element located between the column or intercolumn slabs, characterized in that the width each of the over-column and inter-column plates is 1.2 m, and the over-column plates are 3.3 m long, and the columns are installed with a distance between them in plan in terms of the width of the frame 6.3 m and length 6.0 m.  2. The frame of the building, structure according to claim 1, characterized in that it is equipped with additional columns arranged in plan in terms of length and / or width of the frame with a pitch of 6.0 m in length and 6.3 m in width.  3. The frame of the building, structure according to claims 1 and 2, characterized in that the spacer element is made in the form of a floor slab 4.8 m long and 1.2 m wide.  4. The frame of the building, structure according to claims 1 and 2, characterized in that the spacer element is made in the form of at least a pair of crossbars.  5. The frame of the building, structure according to claims 1 and 2, characterized in that the spacer element is made in the form of a cross-shaped beam located horizontally and / or inclined to the columns of the frame or to the floor slabs.  6. The frame of the building, structure according to claims 1, 2, 4, characterized in that the main and additional columns and crossbars have a cross-shaped cross section.  7. The frame of the building, structure according to claims 4, 6, characterized in that the crossbars are located between the columns parallel to one of the axes of the frame or at an angle to it.  8. The frame of the building, structure according to claims 1-7, characterized in that it is equipped with rafter beams, each of which is supported on a column of the frame, and / or on a column or intercolumn plate, or on a crossbar.  9. The frame of the building, structure according to claims 1 to 8, characterized in that it is equipped with cross-shaped racks located in plan from the front or front side of the frame or on a column plate.  10. A building, a structure containing a foundation, at least four columns with supracolumn slabs installed on them and intercolumn slabs located between them, the width of which is equal to the width of the supercolumn slabs, at least one spacer element located between the supercolumn or intercolumn slabs, wall structures of fencing, slanting, rafters and roofing, characterized in that the width of each of the over-column and inter-column plates is 1.2 m, the over-column plates are 3.3 m long, and the columns are installed with spacing The curiosity between them in terms of the building is 6.3 m wide and 6.0 m long.  11. The building, structure according to claim 10, characterized in that it is equipped with additional columns located in plan along the length and / or width of the building with a pitch of 6.0 m in length and 6.3 m in width, the spacer element made in the form of a plate 4.8 m long and 1.2 m wide or in the form of a crossbar and located between the column or intercolumn plates.  12. The building, structure according to claims 10 and 11, characterized in that the spacer element is made in the form of a beam of a cross-shaped cross section located horizontally and / or inclined to the columns or to the floor slabs.  13. The building, construction according to PP.10 and 11, characterized in that the main and additional columns have a cross-shaped cross section.  14. The building, structure according to claims 10-13, characterized in that it is equipped with cross-shaped racks installed on the front or on the front side of the building at a distance less than or equal to the pitch of the columns, respectively, along the length or width of the building in plan with the formation of the wall structures connecting them with a polygonal fence in terms of contour.  15. The building, structure according to claim 10, characterized in that the wall structures of the fence are made with ribbed widths of 1.2 m with or without window or doorways, or of small-sized brick elements, tongue-and-groove blocks with lining or protective and decorative coatings, and also in the form of monolithic structures made of cellular concrete with brick lining or cement-sandy slabs of fixed formwork.  16. The building, structure according to claim 10, characterized in that the skewers are made of L-, Z-or L-shaped with obtuse angles between the shelves and walls and are supported on columns, or on columns and over-column plates, or on columns and inter-columns slabs, or at one end on columns or slabs, and on the other contact with each other with the formation of roof rafters.  17. The method of construction of a building, construction, including the construction of a foundation, the installation of four columns, the placement of supercolumn floor slabs on them and the installation of two intercolumn floor slabs between them, the width of which is equal to the width of the supercolumn slabs, the installation of at least one spacer element between the column or intercolumn slabs and roofing device, characterized in that after the construction of the foundations, the columns are installed with a distance between them in plan of 6.3 m in width and 6.0 m in length, then over-column are installed, length 3.3 m, and intercolumned plate width of each of 1.2 m, and the front of the device roof rafters assemble.  18. The method of building a building according to claim 17, characterized in that after mounting the main foundations and columns, additional columns are arranged with their layout in plan along the length and / or width of the frame with a step along the length of 6.0 m, and the width 6.3 m.  19. The method of construction of a building, structures according to PP.17 and 18, characterized in that after mounting the intercolumn plates between them or between the column columns, spacer elements are installed in the form of at least one floor slab 4.8 m long and 1 wide, 2 m  20. The method of construction of a building, structure according to PP.17 and 18, characterized in that after the installation of the intercolumn plates between them or between the column columns, spacer elements are installed in the form of at least a pair of crossbars.  21. The method of construction of a building, structures according to PP.17 and 18, characterized in that after the installation of the intercolumn plates, spacer elements are installed in the form of beams of a cross-shaped cross section horizontally and / or inclined to the columns of the frame or to the floor slabs.  22. The method of construction of a building, structures according to PP.17 and 18, characterized in that after the construction of the foundation establish the main and additional columns having a cross-shaped cross section.  23. The method of construction of a building, structures according to PP.17 and 22, characterized in that after the installation of the columns above the columns, racks of cross-shaped cross section are installed on the front or end side of the building or on the columns above the columns.  24. The method of construction of a building, structure according to claim 20, characterized in that after the installation of the columns between them establish additional crossbars of a cross-shaped cross section parallel to one of the axes of the building or at an angle to it.  25. The method of construction of a building, structure according to claim 17, characterized in that during the installation of the rafters, additional rafters of a cross-shaped cross section are installed with each of them resting on a column and / or on a column or inter-column plate or crossbar.

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