RU156207U1 - WALL PANEL - Google Patents

Abstract

1. The wall panel, including rigidly interconnected sequentially located outer layer made on the basis of a binder, a thermal insulation layer representing mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the outer and subsequent inner layer, made on the basis of a binder, characterized in that the fiber layer thermal insulation, at least partially penetrate into a large area of the inner layer. 2. A wall panel according to claim 1, characterized in that the fibers of the thermal insulation layer at least partially penetrate a large part of the outer layer. A wall panel according to claim 1, characterized in that it comprises at least one element for attaching the thermal insulation layer to the inner layer, 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. The wall panel according to claim 3, characterized in that the fastening element is made in the form of a plate anchor. 5. The wall panel according to claim 1, characterized in that it contains at least one element for attaching the insulation layer to the inner layer, made in the form of a L-shaped rod.

Description

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

A sandwich panel is known from the prior art, including a sequentially arranged outer layer rigidly interconnected based on a binder, a thermal insulation layer representing mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the outer and subsequent inner layer, based on the binder and the inner layer. the panel has increased compressive strength, which ensures its resistance to various influences during transportation and installation.

The disadvantages of this panel are that when the panel is formed, reliable adhesion of its layers is not ensured, and to ensure their interaction, it is necessary to use additional metal bonds - end-to-end bundles, on which, in fact, the thermal insulation and the outer layer hang. 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. structural integrity of the structure is violated. Thus, it becomes possible to move the outer, insulating and inner layers of the panel relative to each other both in the vertical and horizontal directions, which leads to premature destruction of the panel. However, the most negative is that due to the violation of the integrity of the panel, the contact of the heat-insulating layer with the surface of the outer and inner layers is lost, and accordingly the mineral-wool thermal insulation begins to quickly sag (compact) under its own weight and other influences, especially in the spring-autumn period or in the regions with high humidity, and due to the specificity of the mineral wool thermal insulation used to increase stiffness, subsidence occurs much faster than when using mineral cotton thermal insulation with the direction of the fibers parallel to the outer and inner layer. 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 heat-insulating layer and the formation of the internal space, the destruction of the outer layer is accelerated, which is reflected in the appearance of cracks, and since the panel is affected by many heterogeneous factors, depending on the region of operation, it is impossible to predict the start of destruction of the panel and take the necessary measures in a timely manner, respectively, such a panel quickly becomes unrepairable, which leads to the inability to operate the building, and as a result to its sleep y by the impossibility of removing and replacing panels.

Also, it should be noted that the bonds are metal rods, and with this installation technology they are simply stuck in the uncured outer layer, which does not provide reliable fastening, due to the small metal-concrete contact area due to the small thickness of the outer layer, and there is a high probability of deviation of bonds from the vertical to the curing of the outer layer. In addition, the bonds fall deep into the outer layer due to its small thickness and a sufficiently large bond weight, i.e. pass through the outer layer, which leads to their corrosion during operation and the formation of rust spots on the outer facing surface.

Installation of mineral wool thermal insulation on this type of connection leads to the bending of some of them, and accordingly, such connections do not fulfill their function, which reduces the design strength of the panel. To eliminate this drawback, it is necessary to dismantle the thermal insulation and straighten the bonds, which, obviously, no one will do, at least because of the complexity and duration of the operation to pull out the mineral wool plates and their inevitable partial destruction during this operation, and which is more likely due to the lack of control on at this stage since verification is carried out only finished plate.

The task to which the claimed utility model is directed is to create wall sandwich panels that are universal for all regions with minimal material consumption and labor costs, with reliable fastening of the layers together, while ensuring the simultaneous achievement of such technical results as increasing the strength characteristics of the layer contact point, reducing time for their manufacture, a significant increase in the overhaul interval and an increase in the durability of the building as a whole.

The claimed technical results are achieved by a wall panel comprising rigidly interconnected sequentially located outer layer made on the basis of a binder, a thermal insulation layer representing mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the outer and subsequent inner layer, made on the basis of the binder and the inner layer, and the fibers of the thermal insulation layer at least partially penetrate into a large area of the inner layer.

The fibers of the thermal insulation layer at least partially penetrate into a large area of the outer layer.

It contains at least one element for attaching the thermal insulation layer to the inner layer, made in the form of a rod with a flat element at one of its ends, which provides pressing of the insulation layer, for example, a plate anchor or made in the form of a L-shaped rod.

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. A thermal insulation layer is laid, which is a mineral wool thermal insulation in such a way that the mineral wool thermal insulation fibers are directed mainly perpendicular to the outer and subsequent inner layer. The reinforcing cage of the inner layer is laid in such a way that a gap is formed between the thermal insulation layer and the reinforcing cage of the inner layer to prevent the reinforcement from contacting the thermal insulation and the airspace. Then make laying or filling of the inner layer, performed on the basis of a binder. All operations are carried out until the curing of the inner layer, which ensures at least partial penetration of the fibers (not the entire length of the fiber and / or not their entire amount) of mineral wool thermal insulation into at least a large area of the inner layer.

The outer layer can be fixed both using bonds, and other methods, for example, by bonding concrete layers around the perimeter of the panel, by the interconnection of solutions from which the layers are made.

However, it is preferable from the point of view of increasing the bond strength of the outer and thermal insulation layer and simplifying the manufacturing technology, in the same way as with the inner layer, to connect the thermal insulation and the outer layer, i.e. carry out all operations before curing the outer and inner layers.

Thus, due to the fact that the mineral wool insulation fibers are directed perpendicular to the inner and outer layers, and the outer and inner layers are not hardened, the fibers of the insulating layer are pressed (penetrated) into these non-hardened layers, i.e. not only the fibers are fixed in the layers over a large contact area of the thermal insulation layer and the outer and inner layers, but also part of these layers is reinforced, which, after the product is cured, creates a reliable thermal insulation fastening without any additional fastening elements that affect the strength of the product, moreover, the contact point is so strong that separation of the thermal insulation is possible only when the fibers are broken. Thus, intermediate reinforced fiber-concrete layers are created that have the greatest strength in the entire product, i.e. the weakest point of the product with the claimed manufacturing method is the most durable, and accordingly it is no longer possible to peel the insulation from the inner and / or outer concrete layer, which eliminates the rapid subsidence of the insulation, and also ensures reliable communication of the outer and inner layers, which allows to achieve the claimed technical results.

In addition, with a small thickness of the outer layer and / or with a large weight of the inner layer, there is a through reinforcement of the outer layer with fibers of the heat-insulating layer, which makes its destruction almost impossible, because there is a multiple increase in its strength, and, accordingly, the possibility of cracking under normal operating conditions is excluded.

Such a product can be used in any region, regardless of climatic features, which ensures its versatility and allows you to significantly expand the field of construction of panel houses and structures. Eliminates the need for monitoring the state of mineral wool insulation and virtually eliminates the need for repair of the outer layer, up to the deadline set by the manufacturer, which significantly reduces the capital and material consumption of construction and operation of buildings.

For the claimed panel, there are several ways. First, the inner layer should have, in the process of manufacturing the structure, the possibility of free vertical movement under its own weight, and then the weight of the inner layer should be sufficient to create pressure to ensure at least partial indentation of the mineral wool fibers into the inner and outer layers. The second - it is necessary to apply an additional vertical load, for example, to act on the upper surface of the manufactured product with a press. Third - the penetration of fibers is ensured by vibration of the mold or the platform on which it is installed. However, the second and third options are the least preferred due to the complexity of manufacturing technology and a significant increase in material and energy consumption of such production. In addition, additional exposure can destroy the reinforcing cage (at additional pressure) or lead to destruction of the concrete mixture (exit to the surface of the binder water layer, movement of aggregate, etc.), which will not allow to obtain the estimated strength characteristics of the layers. However, when using thick or rigid concrete mixtures, a combination of the first and second and / or third options will be desirable, as this will ensure guaranteed penetration of the insulation fibers into the inner and outer layers.

In addition, with a large thickness of the thermal insulation layer and / or with a large weight of the outer layer, as well as for the construction of multi-storey buildings and structures in which wind exposure to the panel is a significant factor, it is necessary to mount additional fasteners to increase the reliability of fastening of the layers. In the manufacture of the claimed plate it is much simpler, because such fasteners can be mounted directly into the thermal insulation before being laid in the mold. This technology allows you to control the correct installation of fasteners (to eliminate distortions, insufficient rod output from a 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.

An additional advantage is that with this manufacturing technology there is no need to mount fasteners in each insulation plate, because its reliable fastening is already ensured, and, in fact, the fastening elements provide only the maintenance of the thermal insulation layer and / or the outer layer, i.e. prevent their displacement relative to the inner or supporting layer. Thus, depending on the size of the structure and / or the design loads, the fastener can only be mounted on one and only one thermal insulation plate.

It is optimal to use a rod as a fastening element, one end of which protrudes outward when mounted in thermal insulation and is intended for fastening in the inner layer, and an element is made on the other end that provides contact with the thermal 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 insulation in the mold, and will also provide additional pressing (fixing) of the insulation to the inner layer after curing of the product.

The element that provides contact with the thermal insulation surface facing the outer layer is made in such a way that significantly reduces the likelihood of its penetration into the uncured outer layer, for example, made in the form of a plate, i.e. as an element, you can use a plate anchor, or a L-shaped connection. However, the use of a plate anchor is preferable, because, firstly, the plate more reliably prevents the penetration of the rod into the outer layer than the L-shaped form of the rod, and secondly, on the surface of the anchor plate facing the outer layer, as a rule elements are made that provide adhesion of the outer layer to the surface of the plate, for example, protrusions and / or recesses and / or holes, which will ensure reliable adhesion of the fastening element to the outer layer due to the developed surface of the plate, which also increases reliability spine attachment layers.

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

Claims (5)

1. The wall panel, including rigidly interconnected sequentially located outer layer made on the basis of a binder, a thermal insulation layer representing mineral wool thermal insulation, the fibers of which are directed mainly perpendicular to the outer and subsequent inner layer, made on the basis of a binder, characterized in that the fiber layer thermal insulation, at least partially penetrate into a large area of the inner layer. 2. The wall panel according to claim 1, characterized in that the fibers of the thermal insulation layer at least partially penetrate a large area of the outer layer. 3. The wall panel according to claim 1, characterized in that it contains at least one element for attaching the thermal insulation layer to the inner layer, 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. 4. The wall panel according to claim 3, characterized in that the fastening element is made in the form of a plate anchor. 5. The wall panel according to claim 1, characterized in that it contains at least one element for attaching the insulation layer to the inner layer, made in the form of a L-shaped rod.