RU126342U1 - PANEL BUILDING ROOM ASSEMBLY - Google Patents

Abstract

1. The support node of the panel building, containing internal wall reinforced concrete panels, internal floor slabs with longitudinal through holes and elements of their connection, made of reinforcing loop-shaped outlets directed from the floor slabs towards the support node, reinforcing rods located along the junction of the panels, all outlets and reinforcing bars are interconnected by additional connecting elements, characterized in that the distance between the ends of the opposite floor slabs exceeds the thickness of the wall panels connected by the support node, these reinforced loop-shaped outlets are connected at their ends with inserts located in the indicated holes, and are permanently fixed in concrete plugs with a length from the insert to the end of the floor slab, while the reinforced loop-shaped outlets are arranged so that they protrude beyond the plane of the end of the plate overlap by an amount not exceeding the thickness of the mating wall panels, with the displacement of the reinforcing loop-shaped outlets of one of the floor slabs relative to the arm round loop-shaped outlets of another, conjugate floor slab, relative to the axis of the concrete plug, with the possibility of free on-the-fly placement of said loop-shaped outlets of floor slabs opposite to each other in the support node, while elastic gaskets are placed under the bottom of the plugs, and said reinforcing bars are placed in pairs in the upper and the lower parts of the support node, are interfaced with reinforcing loop outlets and attached to them by additional connecting elements. 2. Panel building support

Description

The utility model relates to the field of ground construction, namely to the construction of residential buildings for public and civil purposes and can be used for the construction of large-panel multi-storey buildings with transverse longitudinal or cross-wall structural schemes with large spans of floors.

The structural life of the building and the safety of users, to a large extent, depend on the design features of the supporting nodes of floor slabs on the supporting walls of a large-panel building, especially when using hollow formless ceilings for concrete bearing precast walls.

Currently, the support of the ceilings on the walls is carried out by establishing the end part of the ceilings on the supporting walls. The length of the contact area of the mating building structures is limited by regulatory documents.

The gap between the end surfaces of the slabs on the support is taken to be at least 40 mm to allow filling the space between the ends of the floor slabs with concrete.

In order to prevent the concrete from spreading over the voids of the multi-hollow floor, plugs are used that are installed in the voids before the installation of the slabs. Moreover, the distance from the end of the plate to the working surface of the plug is also regulated by technical conditions.

After concreting the end face of the ceiling and building strength with concrete, the walls are mounted above the located floor.

To improve the passage of concrete into the opening, the supports are cut at a certain angle to the end face of the floor, thereby increasing the access area for concreting.

With this design of the node, the end face of the floor is clamped in the node by the bearing walls. In this case, a bending moment arises in the ribs and the flooring shelf. If the magnitude of this bending moment is greater than the magnitude of the moment of cracking of concrete, then an inclined crack occurs on the support. Multi-hollow formwork-free slabs do not contain transverse reinforcement, which serves to prevent plate collapse in these power situations; therefore, plate collapse is possible. Such a situation occurs when flights of slabs of six or more meters in this case, the moments at the supports exceed the moments of cracking.

Known support node of a panel building, containing internal wall reinforced concrete panels, internal floor slabs with longitudinal through holes and elements of their connection, made of reinforcing loop-shaped outlets directed from floor slabs towards the support node, reinforcing rods located along the junction of the panels, all releases and reinforcing rods are interconnected by additional connecting elements (RF patent No. RU111159 “Assembly unit for building structures”, IPC E04B 1/61, 07.25.2011).

This technical solution is the closest to the invention, therefore, taken as a prototype.

The disadvantages of the prototype are the low strength and durability of floor slabs due to significant cracking from bending moments in the supports.

The technical result from the use of the claimed technical solution is to increase the strength and durability of long floor slabs by reducing cracking in them due to a decrease in the magnitude of bending moments in the supports.

In order to significantly reduce the bending moment in the supporting area of the floor slab, it is proposed to completely remove the supporting area outside the supporting area of the wall.

Below are the general and particular essential features characterizing the causal relationship of the utility model with the specified technical result.

The supporting unit includes internal wall reinforced concrete panels, internal floor slabs with longitudinal through holes and elements of their connection made of reinforcing loop-shaped outlets directed from the floor slabs towards the supporting node. Reinforcing bars are located along the junction of the panels. All outlets and reinforcing bars are interconnected by additional connecting elements. The distance between the ends of the opposite floor slabs exceeds the thickness of the wall panels connected by the support node, i.e. floors do not enter the opening between the panels.

These reinforcing loop-shaped outlets are connected at their ends with inserts located in the indicated holes and are permanently fixed in concrete plugs with a length from the insert to the end of the floor slab. In this case, the required bearing capacity of the joint of the floor slabs is made by selecting the length of the zone of the concreting section inside the slab void. Reinforcing loop-shaped outlets are arranged so that they protrude beyond the plane of the end face of the floor slab by an amount not exceeding the thickness of the mating wall panels with a displacement of the reinforcing loop-shaped outlets of one of the floor slabs relative to the reinforcing loop-shaped outlets of the other, conjugate overlapping slab relative to the axis of the concrete plug with the possibility of free oncoming placement of these loop-shaped releases of floor slabs opposite each other in the support node. Under the lower part of the plugs, elastic gaskets are placed, and the indicated reinforcing bars are placed in pairs in the upper and lower parts of the support node, are interfaced with the reinforcing loop outlets and attached to them by additional connecting elements. Additional connecting elements can be made of knitting wire or in the form of plastic ties. The specified liner is made of non-metallic material.

The device is illustrated by drawings, where: in Fig.1 shows a support, a section along the floors; figure 2 is a view aa in figure 1; figure 3 is a view of BB in figure 1; figure 4 - option reinforcing loop release.

The supporting unit includes internal wall reinforced concrete panels 1, internal floor slabs 2 with longitudinal through holes 3 and their connection elements made of reinforcing loop-shaped outlets 4 directed from the floor slabs 2 towards the supporting node, Reinforcing bars 5 are located along the junction of the panels 2.

All outlets 4 and reinforcing bars 5 are interconnected by additional connecting elements 6.

The distance between the ends of the opposite floor slabs 2 exceeds the thickness of the wall panels 1 connected by the support node, i.e. floors do not enter the opening between the panels.

These reinforcing loop-shaped outlets 4 are connected at their ends with liners 7 located in the indicated holes 3 and are permanently fixed in concrete plugs 8 in length from the liner 7 to the end of the floor slab 2.

In this case, the reinforcing loop-shaped outlets 4 are arranged so that they protrude beyond the plane of the end face of the floor slab 2 by an amount not exceeding the thickness of the mating wall panels 1 with a displacement of the reinforcing loop-shaped outlets 4 of one of the overlapping plates relative to the reinforcing loop-shaped outlets 4 of the other conjugate overlapping plate 2 relative to the axis concrete plugs 8 with the possibility of free onward placement of these loop-shaped outlets 4 floor slabs 2, opposite each other in the reference node.

Under the lower part of the plugs 8, elastic gaskets 9 are placed, and the indicated reinforcing bars 5 are placed in pairs in the upper and lower parts of the support node, are interfaced with the reinforcing loop outlets 4 and attached to them by additional connecting elements 6.

Additional connecting elements 6 can be made of knitting wire or in the form of plastic ties.

The specified liner 7 is made of non-metallic material.

Comparison of the claimed technical solution with the prior art known from the scientific, technical and patent documentation as of the priority date in the main and related sections did not reveal a tool that has features identical to all the features contained in the utility model proposed by the applicant, including the purpose of use. That is, the set of essential features of the claimed solution was not previously known and is not identical to any known technical solutions, therefore, it meets the condition of patentability “novelty”.

This technical solution is industrially applicable, since its description is indicated in the description of the application and the name of the utility model, it can be manufactured industrially and used in the construction of panel buildings.

The technical solution is workable, feasible and reproducible, and the distinguishing features of the device allow to obtain the desired technical result - increasing the strength and durability of long floor slabs by reducing crack formation in them due to a decrease in the magnitude of bending moments in the supports, i.e. are significant.

The utility model in the form as described in each of the claims can be implemented using the tools and methods described in the prototype, which became public until the priority date of the utility model. Therefore, the claimed technical solution meets the condition of patentability "industrial applicability".

The device is implemented as follows.

On the installation site, in the voids (openings 3) of the floor slabs 2, plugs 8 are made of concrete with reinforced loop outlets 4 connected to them, which can protrude beyond the plane of the end face of the slab by an amount not exceeding the thickness of the wall panels.

On the upper end of the wall panel 1, before installing the ceilings 2, a reinforcement bar is deployed - 5 of the lower reinforcement zone of the monolithic belt. After that, the installation of the ceilings 2 together with the plugs 7 and the loop outlets 4 on the pre-installed temporary mounting supports 10, while the loop outlets in the joint are located towards each other. Moreover, so that during the installation of the ceilings 2 there is no collision or displacement of the loop outlets, they are installed in the plugs 7 with an offset relative to its axis. After this, the longitudinal reinforcement 5 of the lower zone is tied to the looped outlets 4 with a knitting wire 6 or plastic puffs. The upper longitudinal reinforcement 5 is laid on the loop outlets 4 and is also connected to them by knitting wire 6 or plastic ties. After this, the joint of the support is poured with concrete 11, and after its hardening, the temporary mounting supports 10 are removed.

The support works as follows. After the concrete has set in the cavity of the holes 3 of the floor slabs 2, reinforced concrete dowels are formed from its end to the plugs. These concrete keys transmit vertical forces from floor slabs to walls. The bearing capacity of the dowels is regulated by selecting the concrete class and reinforcement sections of the loop outlets 4. Since the floor slabs 2 are deformed under loads, their ends on the supports tend to rotate in a vertical plane. The reinforced key will prevent this. In this case, a bending moment will occur on the support of the floor slab 2, which is an extremely undesirable fact, given the lack of transverse reinforcement of the slabs of this class. To eliminate the bending moment on the support, it is enough to place elastic gaskets 7 in the lower part of the holes 3 of the floor slab 2. Then, only transverse forces appear in the supporting section of the floor slab and no supporting moments arise, and, as a result of this, cracks from the action of bending moments do not form. The bearing capacity of the floor slabs of this class in this unit device is provided by the bearing capacity of the vertical ribs on the gap and the upper shelf of the slab on the cut. The required bearing capacity of the butt joint is made by selecting the length of the zone area of the concreting section (plug 8) inside the holes of the floor slab.

Using the utility model allows to increase the service life of the building and the safety of users due to the exclusion of destructive cracking in long floor slabs in operation.

Claims (4)

1. The support node of the panel building, containing internal wall reinforced concrete panels, internal floor slabs with longitudinal through holes and elements of their connection, made of reinforcing loop-shaped outlets directed from the floor slabs towards the support node, reinforcing rods located along the junction of the panels, all outlets and reinforcing bars are interconnected by additional connecting elements, characterized in that the distance between the ends of the opposite floor slabs exceeds the thickness of the wall panels connected by the support node, these reinforced loop-shaped outlets are connected at their ends with inserts located in the indicated holes, and are permanently fixed in concrete plugs with a length from the insert to the end of the floor slab, while the reinforced loop-shaped outlets are arranged so that they protrude beyond the plane of the end of the plate overlap by an amount not exceeding the thickness of the mating wall panels, with the displacement of the reinforcing loop-shaped outlets of one of the floor slabs relative to the arm round loop-shaped outlets of another, conjugate floor slab, relative to the axis of the concrete plug with the possibility of free on-the-fly placement of these loop-shaped outlets of floor slabs, opposite each other in the support node, while elastic gaskets are placed under the bottom of the plugs, and these reinforcing bars are placed in pairs in the upper and the lower parts of the support node, are interfaced with reinforcing loop outlets and attached to them by additional connecting elements. 2. The reference node of the panel building according to claim 1, characterized in that the additional connecting elements are made of knitting wire. 3. The support node of the panel building according to claim 1, characterized in that the additional connecting elements are made in the form of plastic ties. 4. The reference node of the panel building according to claim 1, characterized in that said insert is made of non-metallic material.

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