RU160046U1 - WALL PANEL - Google Patents

Abstract

1. A prefabricated wall panel, including a successively arranged outer layer, a layer performing the function of a heat-insulating layer, and a carrier layer made on the basis of a binder, characterized in that the thermal insulation layer is attached to the carrier layer by at least one fastening element made in the form of a rod with a flat element at one of its ends, providing a pressing layer of thermal insulation. 2. The wall panel according to claim 1, characterized in that the fastening element is made in the form of a plate anchor. The wall panel according to claim 1, characterized in that the layer acting as a heat-insulating layer is a mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the carrier layer. The wall panel according to claim 3, characterized in that the fibers of the thermal insulation layer at least partially penetrate a large part of the carrier layer. The wall panel according to claim 3, characterized in that the outer layer is made on the basis of a binder. A wall panel according to claim 5, characterized in that the fibers of the thermal insulation layer at least partially penetrate into a large area of the outer layer. The wall panel according to claim 1, characterized in that the bonding of the layers to each other is carried out by means of bonds.

Description

The utility model relates to a wall panel used in panel housing construction.

Three-layer sandwich panels are known from the prior art, including rigidly interconnected sequentially located outer layer made on the basis of a binder, a layer acting as a heat-insulating layer, and a carrier layer made on the basis of a binder, and the layers are bonded to each other using metal bonds.

The disadvantages of these panels is that the outer and thermal insulation layer actually hangs on metal bonds. Over time, due to the high cantilever load caused by the significant thickness of the outer layer (30-40 mm) and its mass, as well as due to wind and atmospheric influences, bond deformation (tension) occurs and a gap arises between the thermal insulation layer and the concrete outer and inner layers , i.e. the structural integrity of the panel is violated. This leads to the formation of cracks in the outer layer and its subsequent rapid destruction under the influence of various factors, which reduces the time between overhauls and the operation time of the panel as a whole.

In addition, it becomes possible to move the outer, insulating and inner layers of the panel relative to each other in both vertical and horizontal directions. Because of this, there is a loss of contact of the heat-insulating layer with the surface of the outer and inner layers and mineral wool insulation begins to sag (compact) under its own weight and other influences, especially in the spring-autumn period or in regions with high humidity. Accordingly, in a sufficiently small time period, the heat-insulating layer loses its functional purpose, in this regard, the panel no longer provides its function - thermal insulation. Moreover, due to the rapid subsidence of the insulating layer and the formation of the internal space, the destruction of the outer layer is accelerated, and since the panel is affected by many heterogeneous factors, depending on the region of operation, it is impossible to reliably predict the start of the destruction of the panel and take the necessary measures in time, accordingly, such a panel quickly becomes unrepairable, which leads to the inability to operate the building, and as a consequence to its demolition due to the impossibility dismantling and replacing panels.

The task to which the claimed utility model is directed is to create a wall sandwich panel with reliable fastening of the layers together, while ensuring the simultaneous achievement of such technical results as increasing the reliability of the panel and increasing the crack resistance of the outer layer, and, accordingly, a significant increase in the overhaul interval and increase the durability of the building as a whole.

The claimed technical results are achieved by the wall panel, which includes the outer layer rigidly connected to each other, a layer that performs the function of a heat-insulating layer, and a carrier layer made on the basis of a binder. The thermal insulation layer is attached to the carrier layer by at least one fastening element, made in the form of a rod with a flat element at one of its ends, which ensures the pressing of the thermal insulation layer.

The fastening element is made in the form of a dish-shaped anchor.

The layer that performs the function of the heat-insulating layer is mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the carrier layer, and the fibers of the insulation layer penetrate at least partially into a large part of the carrier layer.

In addition, the outer layer is made on the basis of a binder, and the fibers of the thermal insulation layer penetrate at least partially into a large area of the outer layer.

Bonding layers to each other is carried out through bonds.

Wall sandwich panels are made as follows.

An outer protective layer based on a binder is laid or poured into the mold. Level it either mechanically or manually. At least one fastening element is mounted in the thermal insulation, made in the form of a rod with a flat element at one of its ends, which ensures that the thermal insulation layer is pressed. Then, lay a layer of thermal insulation. After that, the reinforcing frame of the carrier layer is laid in such a way that a gap is formed between the thermal insulation layer and the reinforcing frame of the inner layer to prevent the reinforcement from contacting the thermal insulation and the air space, and the carrier layer, which is made on the basis of the binder, is laid or filled.

This reinforcement of the fastening of the insulation layer and the carrier layer contributes to the redistribution of the load from the connections to the additional fastening elements, due to the compression of the insulation layer to the carrier layer by a flat element, which greatly increases the reliability of the layers being fastened to each other, and accordingly the crack resistance of the outer layer increases, due to the exception the possibility of moving the layers relative to each other, which contributes to a significant increase in the overhaul interval and the durability of the building as a whole.

In addition, this technology allows you to control the correct installation of fasteners (eliminate distortions, insufficient rod exit from the mineral wool plate, etc.) and greatly facilitates the process of replacing fasteners in case of breakage during installation, which allows to obtain a high-quality final product.

It is optimal to use a rod as a fastening element, one end of which protrudes outward when installing the insulation, and is intended for fastening in the carrier layer, and an element is made on the other end that makes contact with the insulation surface facing the outer layer, because this will ensure the vertical position of the rod without any effort on the part of the installer and with further laying of the thermal insulation in the mold, as well as ensure that the thermal insulation is pressed (fixed) to the inner or supporting layer after the product has cured.

It is preferable to use a fastener such as a dish-shaped anchor, because, firstly, the plate more reliably prevents the penetration of the rod into the outer layer, and secondly, on the surface of the anchor plate facing the outer layer, elements are usually made that provide the adhesion of the outer layer to the surface of the plate, for example, protrusions and / or recesses and / or holes, which improves the adhesion of the fastener to the outer layer due to the developed surface of the plate.

It is advisable to make protrusions and / or recesses or bends, for example, wavy, for more securely fastening in the carrier layer at the end of the rod protruding outward and intended to be mounted in the carrier layer.

Depending on the method of manufacturing the panel, it is possible to increase the reliability of fixing the layers together, thereby enhancing the claimed technical results, by the interaction of thermal insulation with the outer and supporting layers. To do this, these layers are based on a binder, and the layer that performs the function of the heat-insulating layer is made of mineral wool insulation, the fibers of which are directed mainly perpendicular to the carrier and the outer layers, and the insulation fibers must at least partially penetrate a large part of the carrier layer, and, preferably, the outer layer.

This is ensured by the method of manufacturing the panel, in which all operations are carried out until the curing of the outer and supporting layers, while creating the necessary pressure, ensuring the penetration of part of the fibers into these layers. This manufacturing method significantly contributes to the increase of panel strength due to reliable adhesion of the layers between each other and the formation of reinforced fiber-concrete layers, and also eliminates the connection due to reliable fastening, i.e. simplify panel manufacturing.

However, a method is also possible in which bonds are attached to the non-hardened outer layer, holding the layers together, and after further curing, further operations are carried out.

The claimed utility model is easy to manufacture using known equipment using well-known materials both in the factory and at the construction site.

Claims (7)

1. A prefabricated wall panel, including a successively arranged outer layer, a layer performing the function of a heat-insulating layer, and a carrier layer made on the basis of a binder, characterized in that the thermal insulation layer is attached to the carrier layer by at least one fastening element made in the form of a rod with a flat element at one of its ends, providing a pressing layer of thermal insulation. 2. The wall panel according to claim 1, characterized in that the fastening element is made in the form of a plate anchor. 3. The wall panel according to claim 1, characterized in that the layer that performs the function of the heat-insulating layer is a mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the carrier layer. 4. The wall panel according to claim 3, characterized in that the fibers of the insulation layer at least partially penetrate into a large area of the carrier layer. 5. The wall panel according to claim 3, characterized in that the outer layer is made on the basis of a binder. 6. The wall panel according to claim 5, characterized in that the fibers of the insulation layer at least partially penetrate into a large area of the outer layer. 7. The wall panel according to claim 1, characterized in that the bonding of the layers to each other is carried out by means of bonds.