RU100785U1 - THREE-LAYER WALL PANEL - Google Patents

Abstract

 1. A three-layer wall panel for buildings with high floors, including an external, internal bearing reinforced concrete layers, a heat-insulating layer and discrete concrete reinforced bonds between them and end protective reinforced concrete layers, characterized in that the discrete bonds are located in horizontal and vertical rows in the area of the panels with the lower a number of connections along the lower end of the panel with the possibility of redistributing the vertical load on the outer and inner layers, while the discrete connections of the lower row flax in the form of vertically oriented ribs. ! 2. The three-layer wall panel according to claim 1, characterized in that the discrete connections of the upper horizontal row are located on the upper end of the panel. ! 3. The three-layer wall panel according to claim 1, characterized in that the discrete connections are made of variable cross section. ! 4. The three-layer wall panel according to claim 1, characterized in that the outer layer has vouts in the lower part.

Description

The invention relates to the field of construction and can be used in the manufacture of prefabricated three-layer wall panels of residential and public buildings.

Known are the external load-bearing three-layer wall panels of a typical project of a 10-story large-panel residential building of the 97 series, consisting of an external protective, internal bearing reinforced concrete layer, a heat-insulating layer, discrete reinforced concrete bonds between them and end protective reinforced concrete layers. ("Structural Mechanics and Structural Analysis", scientific and technical journal, Federal State Unitary Enterprise "Research Center" Construction ", Moscow, 2008, No. 4, p.22-25).

The outer layer of the outer wall panel and the floor slab transfer the load to the inner bearing layer of the lower panel through the platform part of the joint with a width equal to the width of the mortar joints above and below the floor slab. Through the contact part between the sheaths of the outer layers with an eccentricity exceeding the thickness of the outer layer, the load is transferred from the outer layer of the panel to the outer layer of the lower panel. With this load transfer scheme, taking into account the responsibility of the external load-bearing three-layer wall panels, the external layer is not load-bearing due to the large eccentricity and, as a consequence, the corresponding bending moments in it. Bending moments contribute to the rapid loss of stability of the outer layer, the opening of cracks in concrete and corrosion of the reinforcement. When the load is transferred through the joint from the upper panel to the lower, the redistribution of forces between the inner and outer layers does not occur. This leads to a change in the dimensions of the structure, an increase in material consumption, the need to change the mold park during their production, as well as a decrease in usable area and deterioration of thermal insulation properties.

The technical problem is to increase the bearing capacity and crack resistance of the bearing wall panel without increasing the consumption of reinforcement while maintaining its heat-insulating properties, as well as maintaining the fleet of molds for their manufacture.

The stated technical problem is solved in such a way that in the three-layer wall panel for buildings with high floors, including the outer, inner bearing reinforced concrete layers, the insulating layer, discrete concrete reinforced bonds between them and the end protective reinforced concrete layers, according to the useful panel, the discrete connections are horizontal and vertical in rows in the area of the panels with the placement of the lower row of ties along the lower end of the panel with the possibility of redistributing the vertical load on the outside minutes and inner layers, wherein the digital communication of the lower row are formed as vertically oriented edges. In this case, discrete connections of the upper horizontal row can be placed on the upper end of the panel. Discrete bonds can be made of variable cross section. In addition, the outer layer at the bottom of the panel can be made with flutes.

The difference in the proposed design of a three-layer wall panel is that discrete bonds are arranged in horizontal and vertical rows along the panel area with the placement of the lower row of bonds along the lower end of the panel with the possibility of redistributing the vertical load on the outer and inner layers, while the discrete bonds of the lower row are made in the form vertically oriented ribs, which provides increased load-bearing capacity of the panel while maintaining the heat-insulating properties and dimensions of the prefabricated structure, with possession of usable space and makes it possible not to increase the consumption of materials, and not to change the park forms for the manufacture of the panels of the lower floors of a multistory building. To increase rigidity, discrete bonds and the upper horizontal row can be placed on the upper end of the panel. To increase the area of abutment in the contact part of the connection joint made of variable cross-section or in the lower part of the outer layer of the panel made vuty.

Figure 1 presents a three-layer wall outer panel; figure 2 is a section I-I of figure 1; figure 3 is the same as in figure 2 an embodiment of the upper row and vut; figure 4 is a section II-II of figure 1; figure 5 is the same as in figure 2 an embodiment of a panel with connections of variable cross section.

The three-layer wall panel for high-rise buildings includes an external 1 - enclosing, internal 2 - bearing reinforced concrete layers, a heat-insulating layer 3, discrete reinforced concrete bonds 4 between layers 1 and 2 and end protective reinforced concrete layers 5. The bottom row of 6 connections is made at the bottom end of the panel . The top row 7 can also be made on top of the panel. The outer layer 1 of the panel in the lower part of the panel can be made with flutes 8 (Fig.).

The proposed design works as follows. Bending moments from the eccentricity are localized in the bonds located at the lower and upper ends of the panel. Due to this, the outer layer 1 operates in more favorable conditions and can be used as a second carrier layer of the panel. In addition, at the junction, it becomes possible to transfer the load from the inner supporting layer to the outer: as a result, up to 40% of the load from the floor slabs is transferred to the outer layer of the second panel. The intermediate connections located between the upper and lower ends of the panel are unloaded.

Claims (4)

1. A three-layer wall panel for buildings with high floors, including an external, internal bearing reinforced concrete layers, a heat-insulating layer and discrete concrete reinforced bonds between them and end protective reinforced concrete layers, characterized in that the discrete bonds are located in horizontal and vertical rows in the area of the panels with the lower a number of connections along the lower end of the panel with the possibility of redistributing the vertical load on the outer and inner layers, while the discrete connections of the lower row flax in the form of vertically oriented ribs. 2. The three-layer wall panel according to claim 1, characterized in that the discrete connections of the upper horizontal row are located on the upper end of the panel. 3. The three-layer wall panel according to claim 1, characterized in that the discrete connections are made of variable cross section. 4. The three-layer wall panel according to claim 1, characterized in that the outer layer has vouts in the lower part.