RU230019U1 - Three-layer 3D panel - Google Patents

Abstract

The utility model relates to the field of construction, namely to the construction of three-layer panels with insulation in the middle layer. The utility model solves the problem of increasing the speed of construction. The three-layer 3D panel contains outer 1 and inner 2 concrete reinforced layers, between which insulation 3 is located, in both layers 1, 2 there are recesses 4 for subsequent fixation of the connecting element 5 for fastening the panels together, the connection can be made using glue, mortar, welding, thread.

Description

The utility model relates to the field of construction, namely to the construction of three-layer panels with insulation in the middle layer.

Currently, a three-layer wall panel RU 19851 U1 is known, containing internal and external reinforced concrete layers connected to each other by flexible discrete metal ties, a heat-insulating layer located between the concrete layers, a fire-protective layer made of concrete located along the perimeter of the heat-insulating layer.

The disadvantage of the specified wall panel is the lack of fastening of the outer concrete layers to each other, obtaining a concrete layer of 25-35 mm thick along the perimeter of the insulation, which reduces the thermal characteristics of the panel, and the exclusion of the outer concrete layer from the work of the structure to prevent its displacement relative to the inner layer, imposes the need to use more massive connections, which increase heat loss.

Currently, a three-layer wall panel RU 107209 U1 is known, containing internal and external reinforced concrete layers connected to each other by flexible ties, a heat-insulating layer located between the concrete layers, grooves in the insulation, in places of adjoining the external concrete layer.

The disadvantage of this wall panel is the lack of fastening of the outer concrete layers to each other.

Currently, a three-layer wall panel US 6272805 B1 from 14.08.2001 is known, containing internal and external reinforced concrete layers connected to each other by flexible ties, a heat-insulating layer located between the reinforced concrete layers.

The disadvantage of this wall panel is the lack of fastening of the outer concrete layers to each other.

The technical objective of the proposed utility model is to improve the performance characteristics of a three-layer panel.

The technical result is an increase in the reliability of the panel joining unit.

In the embodiment shown in Fig. 1, the three-layer 3D panel contains outer 1 and inner 2 reinforced concrete layers connected to each other, between the reinforced concrete layers 1, 2 there is an insulator 3 in the form of a filler layer made of heat- and/or sound-insulating material, for example, rigid mineral wool, polyurethane or polystyrene, expanded polystyrene, extruded polystyrene foam, cellular concrete, perlite, expanded clay, foamed material based on rubber, synthetic resin, plastic, pressed sludge, plasterboard, cellulose-based materials, chipboard, jute, in both layers 1, 2 there are recesses 4 for subsequent fixation of the connecting element 5 for fastening the panels together, the connection can be made using glue, foam, mortar.

In the embodiment shown in Fig. 1-1, the three-layer 3D panel contains outer 1 and inner 2 reinforced concrete layers connected to each other, between the reinforced concrete layers 1, 2 there is insulation, in both layers 1, 2 there are recesses 4 for subsequent fixation of the connecting element 5 for fastening the panels together, the connection can be made using welding. It is possible to use a threaded connection.

In the variant shown in Fig. 1-2, the inner layer 2 is connected by welding, the outer layer 1 is connected by glue, mortar, thread.

This solution allows to increase the reliability of the panel joint, due to the elimination of the possibility of divergence, opening of the outer concrete shells relative to each other under external influence and uneven settlement of the foundation. The fact that both reinforced concrete layers are load-bearing increases their joint work, thereby averaging, redistributing the efforts in the joints of adjacent panels

In the variant shown in Fig. 2, the three-layer 3D panel has a recess 6 in the core 3 or the core 3 is shifted by the entire thickness relative to the end of the panel. An elastic heat-insulating gasket is inserted into the recess 6 during installation.

This solution allows to increase the reliability of the panel joint by organizing an additional lock that prevents the impact of the environment on the core in its thickness.

In the variant shown in Fig. 3, the three-layer 3D panel in reinforced concrete layers 1, 2 has a groove 7. During installation, an elastic gasket is installed in the groove or the groove is filled with a composition after the installation of the panels. The groove has a rectangular, triangular or round shape. It is possible to create local depressions in the end of the core and subsequently form a concrete platform during concreting of the panel for direct installation of the filling elements of the openings.

This solution allows to increase the reliability of the panel joint by organizing an additional lock that prevents the impact of the environment on the core.

In the variant shown in Fig. 4, the three-layer 3D panel is made angular with a continuous layer of insulation.

This solution allows to increase the reliability of the panel joint in the corner of the building, since the factory connection is always more reliable than the construction connection.

Sources of information:

1. Patent for PM RU 19851 U1 2001.02.13.

2. Patent for PM RU 107209 U1 dated March 30, 2011.

3. Patent US 6272805 B1 dated 08/14/2001 (analogue).

Claims (10)

1. A three-layer 3D panel comprising internal and external reinforced concrete layers connected to each other, insulation between the concrete layers, characterized in that the ends of both concrete layers have recesses for placing connecting elements intended for connection with adjacent panels, wherein both reinforced concrete layers are load-bearing. 2. A three-layer 3D panel according to item 1, characterized in that the inner and outer concrete layers have different thicknesses. 3. A three-layer 3D panel according to item 1, characterized in that the inner and outer concrete layers have different compositions. 4. A three-layer 3D panel according to item 1, characterized in that the inner and outer concrete layers have different thicknesses and compositions. 5. A three-layer 3D panel according to item 1, characterized in that the end of the insulation has a recess or is offset by the entire thickness relative to the end of the panel. 6. A three-layer 3D panel according to any of paragraphs 1-5, characterized in that the ends of the outer and/or inner concrete layer have a groove. 7. A three-layer 3D panel according to any of paragraphs 1-5, characterized in that the panel contains channels for laying utility networks. 8. A three-layer 3D panel according to any of paragraphs 1-5, characterized in that the insulation layer consists of several layers. 9. A three-layer 3D panel according to any of paragraphs 1-5, characterized in that the panel is made angular with a continuous layer of insulation. 10. A three-layer 3D panel according to any of paragraphs 1-5, characterized in that embedded products and/or holes for slinging are embedded in the concrete layers.