RU149231U1 - BUILDING HEAT EFFICIENT UNIT - Google Patents

Abstract

1. A heat-efficient building block, including a front layer, a carrier layer and a heat-insulating layer located between them, characterized in that it further comprises side layers, provided with a closed reinforcing frame located inside the carrier, face and side layers, and the outer surface of the face layer is made with embossed finish. 2. A heat-efficient building block according to claim 1, characterized in that it is made in the form of an ordinary, angular, additional or zone building heat-efficient block. 3. A heat-efficient building block according to claim 1, characterized in that the front layer is made of heavy concrete, mainly of class B 15, grade M200.4. A heat-efficient building block according to claim 1 or 3, characterized in that the relief finish is made imitating the texture and surface structure of masonry or natural stone, and a chamfer is made around the perimeter of the front layer. 5. A heat-efficient building block according to claim 1, characterized in that the heat-insulating layer is made of foamed or extruded polystyrene foam of a brand no lower than M25.6. A heat-efficient building block according to claim 1, characterized in that the reinforcing cage is made of wire, mainly of class Bp-1, or of fiberglass reinforcement with a diameter of 4-5 mm. 7. A heat-efficient building block according to claim 1, characterized in that the supporting layer and the side layers are made of structural aerated concrete, or foam concrete mainly of class B 3.5, grade M50.

Description

The utility model relates to the field of construction, in particular to building elements in the form of blocks used in particular in low-rise and frame construction, as well as in the construction of civil and industrial facilities with high requirements for decorative exterior cladding of buildings, heat and sound insulation of premises, for example residential houses, cottages, summer residences, industrial and warehouse premises, etc.

Known building block, consisting of a carrier layer, the front layer and the inner heat-insulating layer of polyurethane foam. The front layer can be made of porcelain stoneware, marble, clinker tiles, asbestos cement slabs with marble chips, painted asbestos cement slabs, tile, gypsum-fiber sheet or glass-magnesium sheet. The carrier layer may be made of foam concrete or aerated concrete. In this case, the carrier and the front layer are fixed relative to each other due to the high adhesive properties of the polyurethane foam located between them. The adhesive joint of the heat-insulating layer with the carrier and front layers is formed after curing of the polyurethane foam. [Patent No. 88705, Е04С 1/00, 04/27/2009].

A disadvantage of the known building block is the low strength characteristics due to the lack of reinforcing elements.

Closest to the proposed utility model is a set of building blocks, including sets of main, angular and opening building blocks containing a front layer, a bearing layer and a heat-insulating layer located between them, fastened together by polymer rods. Angular-type blocks are made of two types, one of which is equipped with equidistant L-shaped face and heat-insulating layers, and a shortened carrier layer is located in the cavity of the heat-insulating layer. Another type of blocks is equipped with equidistant L-shaped bearing and heat-insulating layers, and a shortened front layer is located in the cavity of the heat-insulating layer. The layers of each block are interconnected by metal or plastic jumpers passing through the heat-insulating layer, the ends of which are embedded, respectively, in the front layer and in the carrier layer. The bearing layer is made of expanded clay mixture with a density of 1600-1800 kg / m3, and the front layer is made of expanded clay mixture with a density of 900-1000 kg / m3. If necessary, a plasticizer or coloring pigment is added to the claydite-concrete mixture of the front layer. The heat-insulating layer is made using materials having low thermal conductivity, for example, from polystyrene foam. [Patent No. 2381336, Е04С 1/40, 10.28.2008].

A disadvantage of the known building blocks is the low strength characteristics, due, firstly, to use a low-density claydite-concrete mixture for the formation of the front layer, which creates the prerequisites for its destruction from external factors during operation, and, secondly, the formation of the front and carrier layers without the use of reinforcing elements. In addition, the low strength characteristics of the described building blocks are due to the lack of a structural layer on the sides of the products.

The utility model is aimed at solving the problem of increasing the strength characteristics of building heat-efficient blocks, while expanding the arsenal of technical means that provide good thermal insulation properties and allow you to get a textured surface of the outer surfaces of the walls of buildings.

The essence of the utility model consists in the fact that it is proposed that the building heat-efficient block, including the front layer, the supporting layer and the heat-insulating layer located between them, contain side layers, while each heat-efficient building block is provided with a closed reinforcing frame located inside the bearing, front and side layers and the outer surface of the front layer to perform with embossed finish.

The building heat-efficient block can be made in the form of an ordinary, angular, additional or zone building heat-efficient block.

The front layer can be made of heavy concrete, mainly class B 15, grade M200, and the relief finish of the outer surface of the front layer can be simulated by the texture and surface structure of masonry or natural stone, with a chamfer along the perimeter of the front layer.

The heat-insulating layer can be made of foamed or extruded polystyrene foam of a brand no lower than M25.

The reinforcing cage can be made of wire, mainly of class Bp-1, or of fiberglass reinforcement with a diameter of 4-5 mm.

The carrier layer and the side layers can be made of structural aerated concrete, or foam concrete mainly of class B 3,5, grade M50.

The supply of building heat-efficient blocks with lateral layers provides the possibility of forming a high-quality external protective coating of the heat-insulating layer, which reduces the likelihood of destruction of the heat-insulating layer under the influence of external factors, which leads to an increase in the strength characteristics of the proposed building heat-efficient blocks, while the supply of building heat-efficient blocks with lateral layers helps to increase reliability adhesion with masonry mortar side surfaces p relative heat-efficient blocks and, as a result, increase the strength and load-bearing capacity of the walls constructed from them.

The supply of building heat-efficient blocks with a closed reinforcing cage located inside the bearing, front and side layers and made of wire, mainly of class BP-1 or fiberglass reinforcement with a diameter of 4-5 mm, provides high strength of the obtained building heat-efficient blocks, which also contributes to the increase of strength characteristics of the resulting heat-efficient building blocks.

The implementation of the outer surface of the front layer with a relief finish, mainly imitating the texture and surface structure of masonry or natural stone, while chamfering along the perimeter of the front layer, helps to expand the arsenal of technical means that provide good thermal insulation properties and allow you to get a textured surface of the outer surfaces of the walls of buildings.

The implementation of the front layer of heavy concrete, mainly of class B15, grade M200, reduces the likelihood of its destruction under the influence of external factors during operation, which helps to increase the strength characteristics of the proposed building heat-efficient blocks.

In FIG. 1 shows a top view of an ordinary building heat-efficient block, in FIG. 2 shows a top view of a heat-efficient building block; FIG. 3 is a top view of a heat-efficient building block; FIG. 4 presents a photo of a fragment of the wall.

The building heat-efficient block can be made in the form of an ordinary, angular, additional or zone building heat-efficient block (not indicated in the figures). The building heat-efficient block includes a front layer 1, a bearing layer 2 and a heat-insulating layer located between them 3. Building heat-efficient blocks also contain side layers 4 and are equipped with a closed reinforcing frame 5 located inside the bearing layer 2, the front layer 1 and the side layers 4. The outer surface 6 of the front layer 1 is made with a relief finish that simulates the texture and surface structure of masonry or natural stone. The front layer 1 is made of heavy concrete, mainly of class B 15, brand M200. The heat-insulating layer 3 is made of foamed or extruded polystyrene foam, grade no lower than M25. The carrier layer 2 and the side layers 4 are made of structural aerated concrete, or foam concrete mainly of class B 3,5, grade M50. The reinforcing cage 5 is made of wire, mainly of class BP-1, or of fiberglass reinforcement with a diameter of 4-5 mm.

Building heat-efficient blocks can be manufactured as follows.

Pre-prepare the form (not shown in the figures), the working surface of which is treated with grease. After lubricating the molds, the matrix is laid to form the front layer 1 and its embossed finish. Then prepare the concrete composition for the front layer 1, immediately after preparation, the composition is poured into matrices, vibro-compaction is performed. Then, a heat-insulating layer 3 and a reinforcing cage 5 are installed in the mold. Vibro-compaction is repeated, controlling the filling of the matrix with concrete to form the face layer 1 before joining the heat-insulating layer 3. After the setting of the concrete composition begins to form the face layer 1, the composition is filled into the mold to form the carrier layer 2 and lateral layers 4. After a set of strength sufficient to dismantle the blocks, the form is disassembled, the blocks are stacked on pallets, tightly packed and fed to the warehouse erate a set of design strength.

Thus, the proposed building heat-efficient unit due to the implementation containing lateral layers and equipped with a closed reinforcing cage located inside the bearing, front and side layers, as well as performing the outer surface of the front layer with embossed finish has high strength characteristics and helps to expand the arsenal of technical means that provide good heat-insulating properties and allowing to obtain a textured surface of the external surfaces of the walls of buildings

Claims (7)

1. A heat-efficient building block, including a front layer, a carrier layer and a heat-insulating layer located between them, characterized in that it further comprises side layers, provided with a closed reinforcing frame located inside the carrier, face and side layers, and the outer surface of the face layer is made with embossed finish. 2. The building heat-efficient block according to claim 1, characterized in that it is made in the form of an ordinary, angular, additional or zone building heat-efficient block. 3. A heat-efficient building block according to claim 1, characterized in that the front layer is made of heavy concrete, mainly of class B 15, grade M200. 4. A heat-efficient building block according to claim 1 or 3, characterized in that the relief finish is made imitating the texture and surface structure of masonry or natural stone, and a chamfer is made around the perimeter of the front layer. 5. A heat-efficient building block according to claim 1, characterized in that the heat-insulating layer is made of foamed or extruded polystyrene foam of a brand no lower than M25. 6. A heat-efficient building block according to claim 1, characterized in that the reinforcing cage is made of wire, mainly of class Bp-1, or of fiberglass reinforcement with a diameter of 4-5 mm. 7. A heat-efficient building block according to claim 1, characterized in that the supporting layer and side layers are made of structural aerated concrete, or foam concrete mainly of class B 3.5, grade M50.

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