RU221443U1 - building block - Google Patents

Abstract

The utility model relates to building elements in the form of blocks or other forms for the construction of individual parts of buildings, in particular characterized by a material composition, for example, consisting of elements with fillers. The technical result is achieved by the fact that a building block made in the form of a hollow frame made of heat-insulating material in the form of OSB boards, containing frame cells open at the top and bottom, into which foam insulation blocks are mounted in such a way that the insulation blocks protrude beyond the upper edge of the frame, Moreover, the side walls of the frame have groove fastening. The upper and lower edges of the frame contain a seal. Thus, the declared utility model, due to the design features used in it, the combination of their characteristics and interrelations, provides an effective design, which significantly reduces the heat losses of the building block. 5 salary f-ly, 6 ill.

Description

The utility model relates to building elements in the form of blocks or other forms for the construction of individual parts of buildings, in particular characterized by a material composition, for example, consisting of elements with fillers.

A heat-insulating composite and waterproofing building block is known, characterized in that: it contains an external block, the internal part of the external block is rigidly equipped with a heat-insulating layer, and the external block - the bottom is equipped with a first connecting node, and the upper part of the external block is equipped with a second connecting node, suitable for the first connecting node; the insulation layer includes an insulation board and a support frame inside the insulation board, the inside of the insulation board is provided with an inner chamber, an end of the supporting frame and an inner chamber. The inner wall of the chamber is fixedly connected and vertical, a bottom groove is open in the middle of the bottom of the outer block, and the first connecting element includes a locking block fixedly mounted on the inner wall of the lower groove, a fixed block permanently connected to the holding block side, and a clamping block movably connected to the inside of the holding block, the inner middle of the holding block is provided with a tank body, one end of the clamping block passes through the fixed block and enters the tank body, the second connecting element has a protrusion coinciding with the lower groove and an elongated block fixedly connected at the top of the protrusion, the protrusion is permanently connected at the top of the outdoor unit body, and the protrusion and groove body are matched, the inner side of the elongated unit is provided with a card slot matching the card unit [CN113738013 (A), publ. 12/03/2021].

The disadvantage of the analogue is the insufficient quality of the connection of the building blocks, associated with the possibility of the formation of cold bridges, which can lead to significant heat losses of the entire structure.

Also known is a preformed brick building block having a preformed insulating insert located in its cavity. The inserts are made of molded expanded polystyrene or similar material and are characterized by cut-out areas for finger access.

edge walls of the block cavities and elongated vertical holes in the inserts to increase compressibility in the cross section. The cross-sectional dimensions of the blocks vary significantly, which requires such compressibility of the insert. In one version, the insert has a tetrahedral shape with an elongated groove on each side, in the other, a built-in flange at the bottom of the insert closes the through internal vertical passage. In the third form, the slots at right angles extend down from the top of the insert and end close to the bottom and side walls. The additional form of the insert includes side walls that are jagged when viewed in cross section, and a pair of vertical holes separated by a flange and capped at the bottom. In yet another form, the through hole extends over most of the cross-section of the insert [US3885363 (A), publ. 05/27/1975].

The disadvantage of the analogue is the location of the insulation block, namely that both the insulation block and the building block itself require additional thermal insulation at the points of connection with each other, which complicates and increases the cost of production.

The closest technical solution is a structural element comprising: a frame containing a cavity opening through an upper opening and a lower opening, and a block configured to move in a first direction in the cavity under the influence of external pressure and remain locked at least partially in the cavity in the absence of external pressure, wherein the upper end of the block is configured to engage with the upper opening of the cavity and is configured to engage with the lower opening of the cavity. A frame comprising a cavity opening through an upper opening and a lower opening, and a block configured to move in a first direction in the cavity under the influence of external pressure and remain locked at least partially in the cavity in the absence of external pressure, wherein the upper end of the block is configured capable of engaging with the upper opening of the cavity and configured to engage with the lower opening of the cavity [US2021189723 (A1), publ. 06/24/2021].

The disadvantage of the closest technical solution is the possible formation of cold bridges between adjacent building blocks. This is due to the absence of any fastening grooves between the building blocks.

The technical problem solved by the claimed utility model is the elimination of the disadvantages of analogues.

The purpose of the utility model is to reduce heat losses of the constructed structure.

The technical result of the claimed utility model is to reduce heat losses of the erected structure.

The specified technical result is achieved by the fact that a building block, made in the form of a hollow frame made of heat-insulating material in the form of OSB boards, containing cells open at the top and bottom, into which foam insulation blocks are mounted in such a way that the insulation blocks protrude beyond the upper edge of the frame, wherein the side walls of the frame have a groove fastening, characterized in that the upper and lower edges of the frame contain a seal.

In particular, the frame of the building block includes side walls and end walls.

In particular, the frame of the building block contains partitions.

In particular, the frame can be configured in various configurations, including an intermediate building block and a corner building block.

In particular, the frame cells do not have top and bottom covers.

In particular, the insulation block is made in the form of a three-dimensional figure, for example, a cube made of high-class foam plastic with a density of 25-35 kg/m ³ .

In particular, the insulation block is not secured inside the frame of the building block.

In particular, the side wall of the building block has a grooved side wall fastening along at least one of its end faces.

In particular, the grooved side wall fastening is made in the form of a partially removed side wall thickness, occupying more than 50% of each end surface.

In particular, the side wall contains a groove into which the projection of the partition is mounted.

In particular, a sealant, for example, sealant, is applied to the upper and lower edges of all frame elements.

The proposed utility model is illustrated by a diagram.

In fig. Figure 1 shows a top view of configuration No. 1 of the building block

In fig. Figure 2 shows a top view of configuration No. 2 of the building block

In fig. Figure 3 shows a top view of configuration No. 3 of the building block

In fig. Figure 4 shows section A-A of configuration No. 1 of the building block

In fig. Figure 5 shows a top view of the side wall of the building block

In fig. 6 shows the connection of building blocks

The figures indicate: 1 - building block, 2 - frame, 3 - cell, 4 - insulation block, 5 - side wall, 6 - groove fastening, 7 - seal, 8 - end wall, 9 - partition, 10 - groove, 11 – protrusion

The building block 1 (Fig. 1) is made in the form of a hollow frame 2 made of heat-insulating material containing frame cells 3 open at the top and bottom, in

which the insulation blocks 4 are mounted in such a way that the insulation block 4 protrudes beyond the upper edge of the frame 2, and the side walls 5 of the frame 2 have a groove fastening 6, and the upper and lower edges of the frame 2 contain a seal 7.

The frame 2 of the building block 1 contains side walls 5 and end walls 8. The design of the building block 1 in the form of a hollow frame 2 allows the formation of cells 3 into which insulation blocks 4 are placed, which affects the reduction of heat loss of the structure being built from the building block 1.

The frame 2 of the building block 1 contains partitions necessary for additional strengthening of the structure of the frame 2, as well as for the formation of cells 3 of the frame 2 with an increased length of the building block 1, which can also additionally affect the reduction of heat losses of the building block 1.

The frame 2 can be made in various configurations, including an intermediate building block 1 (Fig. 2) and a corner building block 1 (Fig. 3).

The frame 2 is made of heat-insulating material, for example, oriented strand board (OSB). High-grade OSB has high moisture resistance and strength.

Cells 3 of frame 2 do not have top and bottom covers (Fig. 4), this is necessary so that the insulation block 4 can protrude beyond the upper or lower edge of frame 2 of building block 1, which prevents the formation of cold bridges, thereby reducing heat losses erected structure.

The insulation block 4 significantly affects the reduction of heat losses of the building block 1 and can be made in the form of a three-dimensional figure, for example, a cube made of a composite material, for example, high-class foam with a density of 25-35 kg/m3, which has low thermal conductivity.

The insulation block 4 is not fixed inside the frame 2 of the building block 1. This is necessary for ease of installation of the building blocks 1, the possibility of installing additional equipment inside the building block, as well as a tight fit of the insulation blocks 4 to each other, which reduces the possibility of voids forming inside the frame 2 of the building block 1.

The side wall 5 of the building block 1 (Fig. 5) at least along one of its end faces has a groove fastening 6 of the side wall 5, which is necessary for a rigid connection with the groove fastening 6 of the side wall 5 of the frame 2 of another building block 1, for example, using glue and fasteners such as nails. The presence of this connection eliminates the occurrence of cold bridges between the end faces

building blocks 1, which significantly affects the reduction of heat losses of the erected structure.

The groove fastening 6 of the side wall 5 is made in the form of a partially removed thickness of the side wall 5, occupying more than 50% of each end surface, which allows the side walls 5 to be overlapped, which, if necessary, can further reduce the heat losses of the structure being built.

The side wall 5 contains a groove 10 into which the protrusion 11 of the partition 9 is mounted, which increases the strength of the frame 2 of the building block 1.

During production or before installation of building blocks 1, a sealant 7 (Fig. 6) is first applied to the upper and lower edges of all frame elements 2, for example, a sealant necessary to prevent cold bridges between building blocks 1. During installation, the sealant 7 is pressed down by the weight of the upper building block 1, compensating for possible irregularities on the edges of the side walls of frame 2 of building block 1, which affects the reduction of heat losses of the erected structure.

Thus, the design of the building block 1 is in the form of a hollow frame 2 made of heat-insulating material, the cells 3 of the frame 2 are open at the top and bottom, the presence of an insulation block 4 made of composite material, the possibility of the insulation block 4 protruding beyond the upper edge of the frame 2 of the building block 1, end connections edges of building blocks 1 using groove fastening 6, as well as the presence of a seal 7 on the upper and lower edges of the frame 2 ensure a reduction in heat losses of the building block 1 and the structure erected from it.

Examples of implementation.

First implementation example.

The building block 1 is made in the form of a hollow frame 2 made of OSB board. The cells 3 of the frame 2 of the building block 1 are not closed at the top and bottom. Insulation blocks 4, made of foam plastic, are mounted inside the cells 3 of the frame 2 in such a way that the upper part of the insulation block 4 protrudes beyond the upper edge of the frame 2 of the building block 1. A sealant 7 in the form of a sealant is applied to the lower and upper edges of the frame elements 2. The side walls 5 of the building block 1 contain a groove fastening 6, made in the form of a partially removed thickness of the side wall 5 of the frame 2 and occupies 50% of the end face of the side wall 5. A wall was built from the presented building block 1, where the vertical connections of the building blocks 1 were made with using groove fasteners 6, and horizontal joints are sealed using pre-sealed

applied sealant. The implemented design reduces heat losses of the building block by 10%.

Second implementation example.

The building block 1 is made in the form of a hollow frame 2 made of OSB board. The cells 3 of the frame 2 of the building block 1 are not closed at the top and bottom. Insulation blocks 4 made of foam plastic are mounted inside the cells 3 of the frame 2 in such a way that the upper part of the insulation block 4 protrudes beyond the upper edge of the frame 2 of the building block 1. A sealant 7 in the form of a sealant is applied to the lower and upper edges of the frame elements 2. The side walls 5 of the building block 1 contain a groove fastening 6, made in the form of a partially removed thickness of the side wall 5 of the frame 2 and occupies 75% of the end face of the side wall 5. A wall was built from the presented building block 1, where the vertical connections of the building blocks 1 were made with using groove fasteners 6, and horizontal joints are sealed using pre-applied sealant. The implemented design reduces heat losses of the building block by 14%.

Third implementation example.

The building block 1 is made in the form of a hollow frame 2 made of OSB board. The cells 3 of the frame 2 of the building block 1 are not closed at the top and bottom. Insulation blocks 4 made of foam plastic are mounted inside the cells 3 of the frame 2 in such a way that the upper part of the insulation block 4 protrudes beyond the upper edge of the frame 2 of the building block 1. A sealant 7 in the form of a sealant is applied to the lower and upper edges of the frame elements 2. The side walls 5 of the building block 1 contain a groove fastening 6, made in the form of a partially removed thickness of the side wall 5 of the frame 2 and occupies 100% of the end face of the side wall 5. A wall was built from the presented building block 1, where the vertical connections of the building blocks 1 were made with using groove fasteners 6, and horizontal joints are sealed using pre-applied sealant. The implemented design reduces heat losses of the building block by 18%.

Thus, the declared utility model, due to the design features used in it, the combination of their characteristics and interrelations, provides an effective design, which significantly reduces the heat losses of the building block.

Claims (6)

1. A building block made in the form of a hollow frame made of heat-insulating material in the form of OSB boards, containing cells open at the top and bottom, into which foam insulation blocks are mounted in such a way that the insulation blocks protrude beyond the upper edge of the frame, and the side walls of the frame have groove fastening, characterized in that the upper and lower edges of the frame contain a seal. 2. Building block according to claim 1, characterized in that it contains partitions. 3. The building block according to claim 1, characterized in that the groove fastening is made in the form of partially removed thickness of the side wall of the frame slab. 4. The building block according to claim 1, characterized in that the groove fastening occupies more than 50% of the end face of the side wall. 5. Building block according to claim 1, characterized in that the insulation block is not fixed inside the frame cell. 6. Building block according to claim 1, characterized in that a sealant is used as a sealant.