RU10194U1 - MULTILAYER BEARING EXTERIOR WALL - Google Patents

Abstract

1. A multilayer external curtain wall of the building, including the outer and floor-mounted on the floor inner layer, the insulation layer placed between them and flexible connections, characterized in that the outer layer is self-supporting and floor-connected with the floor by means of flexible connections located at the level of the latter, moreover the inner layer is collapsible and connected to the outer layer or overlap by means of removable deformable ties. 2. The wall according to claim 1, characterized in that a ventilated air gap is made between the insulation and the outer layer. Wall 1 and 2, characterized in that the outer layer is made in the form of a ribbed structure. The wall according to claim 1, characterized in that the outer layer is made in the form of a hollow structure.

Description

MULTI-LAYER BEARING OUTSIDE E04В 2/00 NAYA WALL

The proposed utility model relates to the field of construction and can be used in the construction and reconstruction of residential and public buildings for various purposes, including in seismic areas.

Known is a comprehensive supporting (self-supporting) external wall, including the outer and inner layers and insulation placed between them, in which both layers are made to the height of the building, and the inner layer is directly adjacent to the ceiling and connected to it by means of flexible connections fixed in a frame of expanded clay concrete. (The program for increasing the thermal protection of buildings in accordance with change N3 SNiN II-3-79, Central Research Institute for Housing, Moscow, Album 2, p. 41).

The strength and stability of the known wall is ensured by a complex section of the outer and inner layers.

The disadvantages of the known solutions include structural complexity, high material consumption and non-maintainability of the insulation. Moreover, the presence of bonds rigidly tipped in the inner layer leads to cracking in the places of their installation and to their possible tearing or shearing. The use of a well-known solution is possible only for low-rise buildings.

The closest proposed utility model is a multilayer Mbnesuschaya outer wall, including the outer and inner brick layers, floor-mounted on the floor, the insulation placed between them and flexible connections connecting the layers and ensuring the compatibility of the layers. (Program to increase the thermal protection of buildings in accordance with change N3 of SNiP P-3-79, Central Research and Design Institute of Housing, Moscow, Album 2, l. 45).

However, the increased material consumption of the known complex wall structure and the non-repairability of the insulation, as well as the limited area of use (mainly in buildings with monolithic ceilings), are also disadvantages of the known solution. In addition, the presence of cantilevered protrusions from the floor for floor support of the outer layer complicates the design of the wall and non-ceilings and leads to the formation of cold bridges. In this case, the night-time characteristics of the outer layer are largely underutilized. The task, the solution of which is aimed at creating the proposed useful

model is to reduce the material consumption, the complexity of its construction and increase the operational reliability of the outer multilayer walls of the building. The technical result of using the proposed utility model is to simplify the structure, reduce the specific gravity of the wall and ensure maintainability of the insulation layer. When using the indicated repgepy in buildings in seismic regions due to a decrease in weight of the wall, the inertial component of seismic loads decreases.

The specified technical result is achieved in that in a multilayer

the outer bearing wall of the building, including the outer layer and floor

installed on the overlap of the inner layer, the insulation layer between them and flexible connections, according to the proposal, the outer layer is co-bearing and floor-connected by overlapping by means of flexible connections located at the level of the latter, the inner layer is collapsible and connected to the outer layer or to the overlap removable deformable ties.

The multilayer outer wall can be made with a ventilated air gap between the outer layer and the insulation layer. In this case, the outer layer can be made of various materials, including in the form of a ribbed or hollow structure, factory and construction manufacturing.

The proposed structural extrusion of the outer wall due to the device of the outer layer self-supporting and floor-connected with overlap by flexible deformable bonds ensures its independent operation under force (from its own weight and wind load) and ensures the independence of vertical and horizontal deformations (power and temperature) of internal load-bearing structures and external self-supporting walls, which improves the performance of the building.

This solution provides a differentiated approach to the external enclosing structures, eliminating the need for the production and use of expensive structures and materials that combine strength and thermal insulation qualities. This greatly simplifies the technology of production of wall materials and reduces their cost.

The implementation of the collapsible inner layer secures an individual approach to the thickness and type of insulation. Given the durability of the known types of insulation, 5-8 times less durability of the supporting structures, as well as taking into account the increase in the cost of energy resources, this

2

the solution provides the possibility of its replacement or warming, which also

improves the performance of the building.

The proposed solution of the external self-supporting wall allows its use in any structural systems of the building (transverse, longitudinal, frame or mixed layout of unsuccessful structures). In the case of a longitudinal pattern in overlapping along the external self-cradle; the walls are carried out for it, for example, by a laying beam, a longitudinal longitudinal beam or a frame is provided.

The proposed solution to the outer wall of the building provides the multivariance of its implementation.

Thus, the device of the ventilated ventilated layer between the insulation and the outer layer improves the operating conditions of the insulation by reducing moisture accumulation and thereby increasing its durability.

The implementation of the outer layer ribbed allows you to minimize its material consumption, subject to the requirements for strength and stability.

When the outer layer is hollow, in the form of panels (such as multi-hollow slabs) or from individual hollow blocks, the material consumption is also reduced while creating the most favorable mode of operation of the insulation.

A multilayer wall of the proposed design can be made both in construction and in factory conditions. The wall panel manufactured in the factory can be made in one, two, or three-layer construction and smallpox, it is appropriate, they are embedded in the outer layer for

panel mounting to building structures.

The design of the multi-layer exterior; its outer wall is presented on

following drawings:

Figure 1 - Fragment of a multilayer outer wall (0, O -internal

and outside air). Link device 7 is an example. Figure 2 - The junction of the multilayer outer wall to

overlap. Link device 7 is an example.

The multilayer external gnoush, the wall includes an outer layer 1, installed with a gap 2 to the ceiling 3, an inner layer 4, floor-mounted on the ceiling 3 and a gap between the layers 1 and 4 of the insulation 5. The outer layer 1 is floor-mounted connected to the ceiling 3 by means of flexible bonds 6, which are spread; at the level of overlap 3. The inner layer 4 is collapsible and connected to the outer layer 1 or overlap 3 by deformable removable bonds 7.

The construction of a multilayer external curtain wall is known

snobs. The execution of the outer layer 1 can be carried out in parallel, or after the erection of the internal load-bearing structures of the building. The floor fixing of the outer layer 1 to the ceiling 3 is carried out using predominantly metal, having an anti-corrosion coating, flexible joints 6, either welded to embedded products, or simply anchored (monolithic) in the outer layer 1 and the ceiling 3.

The length of the flexible bonds 6 is assumed to be calculated from the condition for eliminating the mutual influence of the force and temperature deformations of the outer layer 1 and non-closure 3 through them.

The gap between the ceiling 3 and the outer layer 1 is taken from the conditions of the absence of a cold bridge, a device for reliable fire cutting through the floors and the possibility of installing and fixing the inner layer 4,

The installation of the insulation layer 5 is advisable to perform after the construction of the building. Rigid insulation is either glued to the outer layer 1, or taped on the frame. If necessary, installed in the project, a vapor barrier layer is applied and fixed to the insulation layer 5. Hard insulation or the inner layer 4 can be made with vapor barrier film, which simplifies the work. When arranging an iridescent layer between the insulation 5 and the outer layer 1, the insulation plates are mounted on pre-fixed clips made of the same insulation.

The inner layer 4 of the wall (usually lightweight - with a specific gravity less than the outer one) is made collapsible, from elements that allow their manual carrying and installation. The type of materials and the thickness of the inner layer 4 must satisfy fire, hygienic and aesthetic requirements.

The fastening of the inner layer is determined by its type. When using, for example, sheets of dry plaster, a preliminary device of the frame is necessary. Application for the inner layer of 4 naso-crest blocks does not require a frame device. The fastening of the inner layer 4 can be carried out both to the outer layer 1 and to the ceiling 3. The main requirement for the bracket is the absence of the transfer of forces from deformations of the outer layer 1 or the ceiling 3 and the possibility of its simple dismantling during repair work. as removable ties 7 for fixing the inner layer 4

Known constructions and products (rod, bolt, loop, etc.) from materials allowed for use can be used.

Private architectural plans for the arrangement of bay windows at the level of any floor determine the need to install an external wall on the cantilever sections of floors 3. In this regard, in floors 3 to exclude cold bridges provide discrete heat-insulating inserts.

Thus, the use of the proposed design solution

not external M1 supporting wall of the building provides the implementation of various facade

building solutions at minimal cost.

The calculation and design of the claimed utility model of a multilayer wall is performed in accordance with the requirements of regulatory documents.

about

Claims (4)

1. A multilayer external non-bearing wall of the building, including an external and floor-mounted inner layer, an insulation layer placed between them and flexible connections, characterized in that the external layer is self-supporting and is connected to the floor by means of flexible connections located at the level of the latter, moreover the inner layer is collapsible and connected to the outer layer or overlap by means of removable deformable bonds.  2. The wall according to claim 1, characterized in that a ventilated air gap is made between the insulation and the outer layer.  3. The wall according to paragraphs. 1 and 2, characterized in that the outer layer is made in the form of a ribbed structure. 4. The wall according to claim 1, characterized in that the outer layer is made in the form of a hollow structure.