RU111167U1 - CONSTRUCTION CONNECTION ASSEMBLY - Google Patents

Abstract

 1. The junction of building structures, containing internal wall reinforced concrete panels, internal floor slabs and elements of their connection, characterized in that the reinforced concrete panels consist of one carrier layer, and floor slabs are hollow, the connection elements consist of reinforcing loop-shaped outlets, direct reinforcing outlets , reinforcing bars, C-shaped staples and an additional connecting element, while the reinforcing loop-shaped outlets exit the panels with the formation when they intersect of at least two annular guides, direct reinforcing outlets exit from the floor slabs and participate in the formation of the joint guides, reinforcing bars are placed along the panel joint on the guides and are connected to each other by C-shaped brackets, while all outlets and reinforcing bars are connected between each other with an additional connecting element, thereby forming a three-dimensional reinforcing frame of the interface unit, while the voids of the junction of building structures and the surface of the slabs are concreted. ! 2. The node according to claim 1, characterized in that the number of guides of the joint, including ring-shaped, corresponds to the number of guides that prevent progressive collapse. ! 3. A node according to any one of paragraphs.1 and 2, characterized in that the internal reinforced concrete floor slabs contain a reinforcing mesh. ! 4. An assembly according to any one of claims 1 and 2, characterized in that a knitting wire is used as an additional connecting element. ! 5. The node according to any one of paragraphs.1 and 2, characterized in that the ends of the C-shaped staples are facing down.

Description

The utility model relates to the field of construction, in particular, panel housing construction and can be used in the design and construction of buildings and structures, both residential and social, intended for use, including in areas with increased seismic activity.

The prior art solutions of a similar nature.

Known interface unit for reinforced concrete hollow core slabs (RU 2363819, E04B 1/61, 08/10/2009). Slabs coupled with a bearing reinforced concrete crossbar are made with two grooves. The grooves face each other in the area of the interplate seam and are formed in the place of voids to their bottom. The plates have rebar outlets facing the area of the inter-plate seam. Parallel to the end surface, in each plate, metal rods are placed, connected to each other by strands with hooks at the ends, hooked to the rods. The rods are made integral and are interconnected in the area of the interplate seam. Along the edges of the plates are two pairs of parallel longitudinal reinforcing bars. One of the longitudinal reinforcing bars of each pair is located in the upper part of the plate jumper, and the other is underneath in the lower part of the same jumper. Each pair of rods is formed by a single rod, passed through the jumper and forming a stitch on the surface of the jumper along its height. Between the upper and lower rods of each pair there is a zigzag wire. The wire is fastened in separate places with those longitudinal reinforcing bars with which it is in contact. The bearing reinforced concrete crossbar has reinforcing outlets of longitudinal reinforcement and transverse reinforcing bars that are placed above the longitudinal reinforcing bars and with which additionally introduced loop-shaped reinforcing elements are connected. In the interplate seam above the reinforced concrete crossbar, a reinforcing cage is placed along the entire length of the seam. The height of the loop-shaped reinforcing elements does not exceed the height of the reinforcing cage. The width of the loop-shaped reinforcing elements does not exceed the width of the same reinforcing cage.

Also known from the prior art is a node for interlocking multi-hollow floor slabs with crossbars (RU 81227, E04B 1/61, 03/10/2009), comprising crossbars with shelves mounted on the supporting elements of the columns, multi-hollow floor slabs with consoles for positioning them on the shelves of the crossbar and elements for the formation of metal bonds. The height of the shelves of the crossbar is made commensurate with the distance from the lower surface of the multi-hollow floor slab to the supporting surface of the console, for example, equal to half the thickness of the multi-hollow floor slab. The consoles of multi-hollow floor slabs are reinforced with reinforcing frames made in the form of welded gratings, vertically installed in the side sections of the multi-hollow floor slab and in hollow spaces free of prestressed rods. Crossbars of the assembly are equipped with embedded parts located either in recesses on its upper surface or on its lateral surfaces. Elements for forming metal bonds of multi-hollow plates are made in the form of embedded parts located on the upper surface of multi-hollow floor slabs, and metal bonds having the form of rods or plates are made with the possibility of connecting multi-hollow floor plates with a crossbar by welding along the mentioned embedded parts and connecting opposite ones relative to the crossbar hollow core slabs. Welded gratings include an anchored rod with bends at the ends and rods of longitudinal reinforcement connected by transverse clamps, the upper and shortened middle rods being placed above the supporting surface of the console, and the lower rod between the end walls of the multi-hollow floor slab and below the supporting surface of the console.

In addition, a knot for interfacing reinforced concrete multi-hollow slabs in prefabricated monolithic floors with load-bearing reinforced concrete crossbars intended for use in the construction of buildings in earthquake-prone areas is known from the prior art (RU 74935, E04B 1/61, 07.20.2008, closest analogue) . According to this decision, reinforced concrete multi-hollow slabs conjugated with a bearing reinforced concrete crossbar are made with two grooves facing each other in the area of the inter-plate seam and formed at the place of voids to their bottom, reinforced concrete multi-hollow plates have outlets of reinforcement also facing the area of the inter-plate seam, parallel to the end surface, in each plate, metal rods are placed, connected to each other by strands with hooks, hooked at the ends to the rods. The rods are made integral and mated to each other in the area of the inter-plate seam, along the edges of the plates are two pairs of parallel longitudinal reinforcing bars. One of the longitudinal reinforcing bars of each pair is located in the upper part of the jumper of the hollow core, and the other is underneath in the lower part of the same jumper. Each pair of rods is formed by a single rod, passed through the jumper and forming a stitch on top of the jumper, between the upper and lower rods of each pair a zigzag wire is placed, in some places bonded to those longitudinal reinforcing bars with which it is in contact. The bearing reinforced concrete crossbar, with which the above reinforced concrete multi-hollow slabs are interfaced, also has reinforcing outlets of longitudinal reinforcement and transverse reinforcing bars that are placed above the longitudinal reinforcing elements and with which additionally introduced loop-shaped reinforcing elements are connected; , the height of the loop-shaped reinforcing elements does not exceed the height of the reinforcing cage, and its width does not exceed the width of the above reinforcing rkasa.

The disadvantage inherent in each of the above technical solutions is the insufficiently high ability of nodes to resist seismic loads and, as a consequence, insufficiently high seismic stability (ability to withstand earthquakes with minimal damage) of buildings and structures constructed according to the above technologies.

Moreover, the listed nodes are unnecessarily structurally complicated and, as a consequence, material-intensive, which is also their significant drawback, because on the one hand, it leads to an increase in the cost of the unit, and on the other, an increase in the time for its assembly. The use of welding operations in the assembly of nodes is also a negative technological moment - because leads to an increase in the assembly time of the nodes and, very importantly, a decrease in the durability of the nodes (buildings, structures), due to premature corrosion of the elements of the interface node.

The problem to which this technical solution is directed is to create a new node for interfacing building structures, which allows to eliminate the above disadvantages.

The technical result consists in increasing the earthquake-resistant properties of the interface unit of building structures, which will lead to an increase in the seismic stability characteristics of buildings and structures constructed using this utility model. Simplification of the assembly design, reduction of material consumption, and, as a result, reduction of its assembly time are also technical results achieved by implementing this utility model. Not the least importance is given to increasing the durability of buildings and structures erected using this utility model.

The solution to the above problem is achieved as follows.

The interface unit of building structures contains internal wall reinforced concrete panels, internal floor slabs and elements of their connection. Reinforced concrete panels consist of one carrier layer, and floor slabs are made hollow. Connection elements consist of reinforcing loop-shaped outlets, direct reinforcing outlets, reinforcing bars, “C” -shaped brackets and an additional connecting element. Reinforcing loop-shaped outlets exit the panels with the formation, at their intersection, of at least two annular (“0” -shaped) guides. Direct reinforcement outlets come out of floor slabs and participate in the formation of the joint guides. Reinforcing bars are located along the junction of the panels on the rails, and are connected to each other by "C" -shaped brackets. All outlets and reinforcing bars are interconnected by an additional connecting element, thereby forming a three-dimensional reinforcing frame of the interface unit. The voids of the junction of building structures and the surface of the slabs are concreted. The number of guides of the joint, including “0” -shaped ones, corresponds to the number of guides that prevent progressive collapse. Internal reinforced concrete floor slabs may contain reinforcing mesh. As an additional connecting element, it is possible to use a knitting wire. The ends of the "C" -shaped brackets can be turned down.

The execution of hollow core slabs allows, in particular, to simplify the assembly process of the assembly and reduce its material consumption, while reducing the assembly time of the assembly as a whole.

The special design and interconnection of all the elements of the connection, as well as the orientation when calculating the design of the interface unit for possible progressive collapse (collapse of the building structures (or parts of it with a height of two or more floors) that have lost support as a result of local destruction of any floor), allows to increase the seismic stability of the interface node and buildings and structures being built with its use.

The use of reinforcing mesh in the design of floor slabs contributes, in particular, to increase the strength characteristics of the interface unit, to increase its seismic stability.

The use of knitting wire as an additional connecting element eliminates the use of welded joints of structures, which leads to a combination of favorable technological and other equally important consequences: reducing the time allocated for assembly of the assembly, reducing material consumption, reducing assembly assembly costs, increasing the durability of buildings and structures erected using the interface unit due to the refusal to use welding in the assembly process of the interface unit (the first and more dangerous of corrosion in structures).

Below is a description of the graphic materials, in no way limiting all possible embodiments of the utility model.

Figure 1 is a General diagram of the interface node.

1 - internal load-bearing wall reinforced concrete panels,

2 - hollow prestressed concrete slab (first),

3 - hollow prestressed concrete slab (second),

4 - reinforcing loop-shaped releases from the bearing wall panels

5 - direct reinforcing releases of the first plate,

6 - direct reinforcing releases of the second plate,

7 - volume reinforcing cage,

8 - reinforcing mesh

9 - concrete.

The following is an example implementation of a utility model that in no way limits all possible options for its implementation.

Internal reinforced concrete panels (1) and internal reinforced concrete slabs (2) and (3) floors are made at the factory. Equipping panels (1) with reinforcing loop-shaped outlets (4) is also carried out in the factory. Panels (1) are made single-layer, with the presence of one layer - the carrier.

In the manufacture of panels and slabs, the number of reinforcing releases, including those intended for the formation of "O" -shaped guides, is taken into account initially. At the same time, they proceed from a combination of such factors as: the number of storeys of a building, its geographical location (for taking into account the seismic stability zone), the building material used, etc., based on the need for resistance to progressive destruction of the structure constructed using such interface units.

According to this example, the number of outlets, including those used to form “0” -shaped guides, is set based on the ratio: 1 (one) “0” -shaped guide and 2 (two) direct reinforcement outlets per 1 m of the interface. Other ratios are possible.

Building structures are delivered to the place of construction of buildings, structures, which is preceded by the assembly procedure of the interface nodes of building structures.

In the process of assembly of the interface node panels (1) are installed with end surfaces opposite each other with the formation between them of at least two “0” -shaped guides from the reinforcing outlets (4) of the panels (1).

Reinforcing outlets (5) and (6) of reinforced concrete floor slabs (2) and (3) take part in the formation of the guides of the entire joint, which are installed perpendicular to the junction of the panels (1) forming “+” -shaped construction interface with the panels constructions.

Direct reinforcing outlets (5) and (6) are placed in the corresponding recesses in the plates (2) and (3) directly in the process of connecting the panels (1) and plates (2) and (3). Moreover, at one end, outlets (5) and (6) are placed in the recesses of the plates (2) and (3), and the other in the space formed between the panels (1).

Features of the assembly of direct reinforcing outlets (5) and (6) allow more accurately forming a guide system, since outlets (5) and (6) are installed in accordance with the specific location of each “0” -shaped guide formed at a particular junction of the panels (1) and plates (2) and (3).

Then, reinforcing bars are placed on the already formed guides of the joint along the entire joint of the panels (1) and plates (2) and (3), for example, inside the guides. After this, the reinforcing bars are interconnected by "C" -shaped brackets, with their ends facing down.

Then all the reinforcing outlets (4), (5) and (6) and the reinforcing bars are connected with an additional connecting element, for example, with a knitting wire, thereby forming a three-dimensional reinforcing frame of the interface unit.

Then, reinforcing mesh (8) is placed on the slabs (2) and (3) of the ceilings and the voids of the interface of the interface unit, like the slabs (2) and (3), are poured with concrete (9) for additional bonding of all the elements included in it, which leads to an increase in the strength characteristics of the interface.

As can be seen by the implementation of the utility model, an increase in the earthquake-resistant properties of the interface unit of building structures is achieved, which will lead to an increase in the seismic stability characteristics of buildings and structures constructed using this utility model.

Simplification of the assembly design, reduction of material consumption, and, as a consequence, reduction of the time allotted for its assembly, are also technical results achieved by implementing this utility model. The durability of buildings and structures erected using this utility model is also significantly increased.

Claims (5)

1. The junction of building structures, containing internal wall reinforced concrete panels, internal floor slabs and elements of their connection, characterized in that the reinforced concrete panels consist of one carrier layer, and floor slabs are hollow, the connection elements consist of reinforcing loop-shaped outlets, direct reinforcing outlets , reinforcing bars, C-shaped staples and an additional connecting element, while the reinforcing loop-shaped outlets exit the panels with the formation when they intersect of at least two annular guides, direct reinforcing outlets exit from the floor slabs and participate in the formation of the joint guides, reinforcing bars are placed along the panel joint on the guides and are connected to each other by C-shaped brackets, while all outlets and reinforcing bars are connected between each other with an additional connecting element, thereby forming a three-dimensional reinforcing frame of the interface unit, while the voids of the junction of building structures and the surface of the slabs are concreted. 2. The node according to claim 1, characterized in that the number of guides of the joint, including ring-shaped, corresponds to the number of guides that prevent progressive collapse. 3. A node according to any one of paragraphs.1 and 2, characterized in that the internal reinforced concrete floor slabs contain a reinforcing mesh. 4. An assembly according to any one of claims 1 and 2, characterized in that a knitting wire is used as an additional connecting element. 5. The node according to any one of paragraphs.1 and 2, characterized in that the ends of the C-shaped staples are facing down.