RU112916U1 - FRAME OF BUILDINGS AND STRUCTURES AND ITS ELEMENTS (OPTIONS) - Google Patents

Abstract

 1. The frame of buildings and structures containing columns, beams and floor slabs mounted on the beams, characterized in that the columns are made with at least one internal channel located along the column, the beams are made with at least one hole on at least one end, the crossbars are installed at the end of the column, while at least one inner channel of the column and at least one hole of the crossbars are formed to provide one through hole in which the rod is placed. ! 2. The frame of buildings and structures according to claim 1, characterized in that it contains a embedded part, consisting of a platform and passing through it at least one rod, designed to be placed in a through hole formed by at least one internal channel columns and at least one bolt hole. ! 3. The frame of buildings and structures according to claim 2, characterized in that the embedded part contains two rods. ! 4. The frame of buildings and structures according to any one of claims 1, 2 or 3, characterized in that the column contains two internal channels. ! 5. The frame of buildings and structures according to any one of claims 1, 2 or 3, characterized in that the floor slabs are made monolithic. ! 6. The frame of buildings and structures according to claim 4, characterized in that the floor slabs are made monolithic. ! 7. The frame of buildings and structures according to any one of claims 1 to 3 or 6, characterized in that on at least one rod protruding from the crossbar above the floor slab, another column is installed with at least one internal channel. ! 8. The frame of buildings and structures according to claim 4, characterized in that on at least one rod protruding from the crossbar

Description

This utility model relates to the field of construction and can be used in the construction of any buildings and structures in any areas, including seismic areas. Also, a real utility model can be used in the restoration and reconstruction of various buildings.

From the RF patent for utility model No. 96143, a frame of buildings and structures is known containing reinforced concrete columns with openings at the level of floors, reinforced concrete crossbars rigidly interconnected, and floor slabs, while the crossbars are made of precast monolithic in the form of spatial bodies with a preliminary assembly tense lower part having a tray-like shape, on the inner surface of which at least one wedge-shaped protrusion is made, and monolithic upper part in the form of a monolithic reinforced concrete belt, lower h part of which is placed in the tray, and the upper - between the ends of the plates.

The assembly of the rear frame and structures is as follows. First, reinforced concrete columns are installed vertically. After installing the columns, the lower parts of the crossbars are installed on the mounting tables at the level of the through openings in the columns. Under the lower parts of the crossbars, mounting racks are brought down. On the upper lower parts of the crossbars, slabs are laid. In the inner space formed by the lower part of the crossbar and the ends of the floor slabs, fittings are installed. Then the concrete is laid.

After a set of the required strength is made with cast concrete, the racks and tables are dismantled and the crossbar is included in the building frame, as a solid prestressed continuous beam rigidly coupled to the columns.

To increase the strength of the frame at the stage of installing the reinforcement in the inner space formed by the lower part of the crossbar and the ends of the floor slabs, rods are installed. In this case, the rods are installed inside the columns and on the one hand go into the inner space of one crossbar, and on the other - into the inner space of the other crossbar.

The column, crossbars and floor slab at the junction form a docking station.

Moreover, according to the known technical solution, the connection is provided by monolithic concrete laid in the inner space formed by the lower part of the crossbar.

Monolithic concrete in the docking unit, according to a known design, takes on the vertical and horizontal loads of the entire building.

It should be noted that columns, crossbars and floor slabs are made in advance in the factory. At the same time, a monolithic belt is formed at the construction site. The quality of reinforced concrete elements manufactured at the factory is usually higher than the quality of elements manufactured at the construction site.

When forming a monolithic belt, to ensure the required quality of the monolithic belt, large labor costs are required.

Thus, the disadvantages of the above technical solution is the large amount of monolithic work performed at the construction site, as well as high demands on the quality of the monolithic belt and, accordingly, the quality of the monolithic work carried out at the construction site, due to the high loads on the monolithic belt in docking nodes of the building frame.

It should also be noted that the general production cycle of a building or structure includes the production of frame elements of a building or structure in the factory.

In accordance with the known technical solution, all frame elements, with the exception of reinforced concrete columns, can be made by formless molding.

However, reinforced concrete columns can only be produced on stands in the mold, since these columns have openings at the level of ceilings. These openings are filled with concrete, as indicated above, during the formation of a monolithic belt, which ensures the creation of a solid frame.

Such columns cannot be produced by the formless molding method, since without formwork molding it is not possible to perform protrusions, consoles, embedded parts, indirect and transverse reinforcement and, therefore, it is not possible to form openings.

However, the method of formless molding of reinforced concrete products is superior in efficiency to the method of production of reinforced concrete products on stands in the mold. The formless molding method requires less labor costs per unit of production and ensures the production of a larger volume of products per unit of production area than in the production of reinforced concrete products on stands in molds.

Thus, another disadvantage of the above technical solution is the high complexity and low efficiency in the production of columns.

The objective underlying this utility model is to reduce the volume and complexity of monolithic work when assembling the frame of buildings and structures, increase the reliability of the docking unit of the frame of buildings and structures, as well as reduce labor costs and increase the efficiency of column production.

The problem underlying this utility model is solved using a building frame containing columns, crossbars and floor slabs mounted on crossbars, with columns made with at least one internal channel located along the column, crossbars made from at least one hole on at least one end, the crossbars are installed on the end of the column, with at least one inner channel of the column, and at least one hole of the crossbars is made to ensure the formation of one the through hole in which the rod is placed.

Additionally, the frame of buildings and structures may contain a embedded part, consisting of a platform and passing through it at least one rod, designed to be placed in a through hole formed by at least one internal channel of the column, and at least one bolt hole.

Also, the embedded part may contain two rods.

In addition, the column may contain two internal channels.

Floor slabs can be made monolithic.

In addition, at least one rod protruding from the crossbar above the floor slab can be equipped with another column with at least one internal channel.

Also, the problem underlying the present utility model is solved with the help of a building frame assembly of buildings and structures containing at least one column and at least one crossbar, while the column is made with at least one internal channel located along the column, the crossbar is made with at least one hole at at least one end, the crossbar is installed at the end of the column, with at least one inner channel of the column, and at least one hole crossbars are made with ensuring the formation of one through hole in which the rod is placed.

Additionally, the frame assembly of buildings and structures may contain a embedded part consisting of a platform and at least one rod passing through it, designed to be placed in a through hole formed by at least one internal channel of the column and at least one bolt hole .

In this case, the embedded part may contain two rods.

According to one embodiment of the utility model, two crossbars are installed on the column with at least one hole on at least one end, and each of the crossbars is mounted on the column so that one of the rods of the embedded part passes through the hole in one crossbar, and the other rod of the embedded part through the hole in another crossbar.

In addition, at least one crossbar is installed, at least one floor slab.

Also, the floor slab can be made monolithic.

Additionally, another column is installed on the floor slab having at least one inner channel located along the column, and at least one rod protruding from the crossbar above the floor slab is installed in at least one inner channel of the other column .

According to another embodiment of the utility model, at least one crossbar has at least one floor slab and another column having at least one inner channel located along the column, with at least one rod protruding from the crossbar, installed in at least one inner channel of the other columns, while the floor slab has a cutout that allows the placement of another column on the crossbar.

The floor slab can be made monolithic.

The problem underlying this utility model is solved using a column used in the construction of buildings and structures and having at least one internal channel located along the column and performed by formless molding.

Also, the problem underlying the present utility model is solved using a crossbar used in the construction of buildings and structures and having at least one opening at least at one end.

The following is a detailed description of options for the best implementation of the utility model with links to the accompanying drawings, in which:

figure 1 depicts a General view of the docking node of the frame of buildings and structures and its assembly drawing;

figure 2 - column with one internal channel in the context;

figure 3 - column with two internal channels in the context;

figure 4 - embedded part;

figure 5 - docking node in the context;

6 is a General view of the docking node of the frame of buildings and structures, according to the second embodiment, and its assembly drawing;

Fig.7 is a docking node, according to the second variant of implementation of the utility model, in section.

In the right part of figure 1 shows a General view of the docking node of the frame of buildings and structures.

The left side of FIG. 1 shows an assembly drawing of such an assembly.

As shown in figure 1, the frame of buildings and structures contains columns 1, crossbars 2 and slabs 3 floors.

The length of column 1 is equal to the height of one floor of the building. That is, one column 1 is used to form one floor of the frame.

The crossbars 2 are installed on top of the column 1.

According to a first embodiment, floor slabs 3 are laid on the crossbars.

A new column is installed on the 3 floor slabs above column 1 to form the next floor of the building.

As shown in figure 2, the column has an internal channel 4 located along the length of the column 1.

As shown in figure 3, the column 1 can be made with two internal channels 4. The size and shape of the channel 4 are selected with the same functional load as in the presence of one internal channel 4.

Additionally, the frame of buildings and structures contains embedded part 5 (figure 4).

The embedded part 5 consists of a pad 6 and two rods 7 passing through the pad 6.

Preferably, the shape of the pad 6 corresponds to the shape of the end of the column 1.

The location of the rods 7 corresponds to the location of the internal channel 4 of the column 1 or internal channels 4 of the column 1 with two internal channels.

The embedded part 5 is installed on the end of the column 1, so that the platform 6 covers the end of the column 1. In this case, the rods 7 are placed inside the channel or channels 4.

Crossbars have openings made at their ends. Moreover, the location of the holes corresponds to the location of the rods 7 of the embedded parts.

Assembly of the frame is as follows.

First, columns 1 are installed.

The inner channel of 4 columns 1 is filled with concrete mixture.

At the ends of the columns 1 are embedded parts 5. In this case, the rods 7 are placed inside the channel 4.

Then, the crossbars 2 are installed on the columns 1, namely, each of the rods 7 of the embedded part is threaded through the corresponding hole of one crossbar 2.

Next, crossbars 2 are installed on crossbars 2.

After installing the 3 floor slabs, reinforcement can be placed in the internal cavity (tray) of the crossbar 3, around the crossbars 2 and columns 1, where necessary, formwork is installed and poured with concrete mixture. Thus, the formation of a concrete belt is carried out.

The concrete belt may be formed by any method known in the art.

After the solidification of concrete and, accordingly, the formation of a monolithic concrete belt, all parts will be firmly interconnected.

After the solidification of concrete, on the protruding from the monolithic belt rods 7 (release rods) embedded parts 5 set the column 1 of the next floor.

After installing columns 1 of the next floor, these steps are repeated to form the next floor.

Before installing the column 1 of the next floor, the inner channel 4 of this column can be filled with concrete to ensure the strength of the connection.

Also, the concrete mixture can be placed inside the channels 4 and after installing the column 1 from the upper end, as the channels are made through.

Figure 5 shows a cross-sectional view of a docking assembly according to a first embodiment of a utility model with a monolithic belt formed.

As shown in FIG. 6, the second embodiment is similar to the first embodiment and contains the same elements.

However, the floor slabs 3 have a cutout 8. The shape and size of the cutout 8 corresponds to the shape and size of the column 1.

Cutouts 8 are made at least at the slabs 3 of the floors adjacent to the columns 1.

Cutouts 8 provide the placement of the column 1 of the next floor on the crossbars 2.

The assembly of the second embodiment of the frame is as follows.

First, columns 1 are installed.

The inner channel 4 of the column 1 is filled with concrete mixture.

At the ends of the columns 1 are embedded parts 5. In this case, the rods 7 are placed inside the channel 4.

Then, the crossbars 2 are installed on the columns 1, namely, each of the rods 7 of the embedded part is threaded through the corresponding hole of one crossbar 2.

Next, crossbars 2 are installed on crossbars 2.

Also, the protruding rods 7 (the release of the rods) of the embedded part 5 establish a column 1 of the next floor.

After installing the 3 floor slabs, reinforcement can be placed in the internal cavity (tray) of the crossbar 3, around the crossbars 2 and columns 1, where necessary, formwork is installed and poured with concrete mixture. Thus, the formation of a concrete belt is carried out.

The concrete belt may be formed by any method known in the art.

After the solidification of concrete and, accordingly, the formation of a monolithic concrete belt, all parts will be firmly interconnected.

Next, these steps are repeated to form the next floor.

Fig. 7 shows a cross-sectional view of a docking assembly according to a second embodiment of the utility model with a monolithic belt formed.

The above describes methods for assembling the frame of buildings and structures using columns 1 with one internal channel. However, it is possible to use column 1 with two internal channels. In this case, each of the rods 7 of the embedded part 5 is placed in one of the channels 4 of the column 1.

Additionally, in any of the embodiments of the utility model, brackets 9 may be used.

The brackets 9 have a curved shape and are installed at one end in the internal cavities of the floor slabs 3, and the other end is placed in the internal cavity (tray) of the crossbar 3.

The use of brackets 9 increases the strength of the structure. Staples 9 can be used, both in conjunction with the fittings placed in the internal cavity (tray) of the crossbar 3, and without it.

Also in the area 6 of the embedded part 5, a hole 10 can be made.

Preferably, the size and shape of the hole 10 corresponds to the channel or channels 4. In this case, the filling of the channel or channels 4 with concrete can be performed after installing the embedded part 5 on the end of the column 1.

To increase the strength of the frame, according to any embodiment of the utility model, at the stage of installing the reinforcement in the inner space of the crossbars, rods can be installed. In this case, the rods on the one hand go into the inner space of one crossbar, and on the other - into the inner space of the other crossbar.

In the case of using monolithic floor slabs, instead of laying slabs 3 of floor slabs on the crossbars 2, formwork is installed to form monolithic floor slabs. Reinforcement of monolithic floor slabs and their concreting is carried out simultaneously with concreting of a monolithic belt. In this case, a monolithic reinforced concrete belt and monolithic floor slabs will be a single whole.

The frame of buildings and structures, according to this utility model, is designed in such a way that the horizontal and vertical loads of the building are not distributed to the monolithic belt in the area of the building’s docking nodes, but to the frame elements themselves, which are factory-made.

Thus, the overall reliability of the building frame is increased and the requirements for monolithic work are reduced.

In addition, the volume of monolithic work is reduced, since the crossbars 2 are supported on columns 1 having a certain height and, accordingly, the installation of crossbars 2 in the required position relative to the columns 1 is simpler, with less labor costs and greater accuracy than when installing mounting tables at the level through openings in columns.

Column 1, according to this utility model, does not have any openings.

This shape of the column 1 allows for its manufacture to use the formless molding method.

The inner channel or channels 4 can be made using an appropriate form of pressing.

Thus, the frame of buildings and structures, according to this utility model, reduces the volume and complexity of monolithic work when assembling the frame of buildings and structures, increases the reliability of the docking unit of the frame of buildings and structures and reduces labor costs and increases the efficiency of production of columns, due to the possibility of using the formless molding method.

Claims (19)

1. The frame of buildings and structures containing columns, beams and floor slabs mounted on the beams, characterized in that the columns are made with at least one internal channel located along the column, the beams are made with at least one hole on at least one end, the crossbars are installed at the end of the column, while at least one inner channel of the column and at least one hole of the crossbars are formed to provide one through hole in which the rod is placed. 2. The frame of buildings and structures according to claim 1, characterized in that it contains a embedded part consisting of a platform and at least one rod passing through it, designed to be placed in a through hole formed by at least one internal channel columns and at least one bolt hole. 3. The frame of buildings and structures according to claim 2, characterized in that the embedded part contains two rods. 4. The frame of buildings and structures according to any one of claims 1, 2 or 3, characterized in that the column contains two internal channels. 5. The frame of buildings and structures according to any one of claims 1, 2 or 3, characterized in that the floor slabs are made monolithic. 6. The frame of buildings and structures according to claim 4, characterized in that the floor slabs are made monolithic. 7. The frame of buildings and structures according to any one of claims 1 to 3 or 6, characterized in that on at least one rod protruding from the crossbar above the floor slab, another column is installed with at least one internal channel. 8. The frame of buildings and structures according to claim 4, characterized in that on at least one rod protruding from the crossbar above the floor slab, another column is installed with at least one internal channel. 9. The frame of buildings and structures according to claim 5, characterized in that on at least one rod protruding from the crossbar above the floor slab, another column is installed with at least one internal channel. 10. Assembly node of the frame of buildings and structures, containing at least one column and at least one crossbar, characterized in that the column is made with at least one internal channel located along the column, the crossbar is made with, at least one hole on at least one end, the bolt is mounted on the end of the column, while at least one inner channel of the column and at least one hole of the bolts are made to ensure the formation of one through hole, which the rod is placed b. 11. The assembly node of the frame of buildings and structures of claim 10, characterized in that it contains a embedded part consisting of a platform and passing through it at least one rod, designed to be placed in a through hole formed by at least one the internal channel of the column and at least one bolt hole. 12. The assembly node of the frame of buildings and structures according to claim 11, characterized in that the embedded part contains two rods. 13. The Assembly site of the frame of buildings and structures according to item 12, characterized in that the column has two crossbars with at least one hole at least at one end, each of the crossbars being mounted on the column in such a way that one of the rods of the embedded part passes through the hole in one crossbar, and the other rod of the embedded part passes through the hole in the other crossbar. 14. Assembly unit of the frame of buildings and structures according to any one of paragraphs.10-13, characterized in that at least one crossbar has at least one floor slab. 15. The assembly node of the frame of buildings and structures according to 14, characterized in that the floor slab is made monolithic. 16. The assembly node of the frame of buildings and structures according to 14, characterized in that another column is installed on the floor slab having at least one inner channel located along the column, at least one rod protruding from the crossbar above the floor slab is installed in at least one inner channel of the other column. 17. The Assembly site of the frame of buildings and structures according to clause 15, characterized in that another column is installed on the floor slab having at least one internal channel located along the column, at least one rod protruding from the crossbar above the floor slab is installed in at least one inner channel of the other column. 18. Assembly node of the frame of buildings and structures according to any one of paragraphs. 10-13, characterized in that at least one crossbar installed at least one floor slab and another column having at least one inner channel located along the column, while at least one rod protruding from the crossbar is installed in at least one inner channel of the other column, and the floor slab has a cutout that allows the placement of the other column on the crossbar. 19. The assembly node of the frame of buildings and structures according to claim 18, characterized in that the floor slab is made monolithic.