RU137881U1 - FOOTBALL BUILDING UNIT - Google Patents

Abstract

1. A building block for spoon masonry, which is a rectangular parallelepiped in shape with spoon, poke and bed flat faces, while at least two rectangular consecutive holes are arranged along the spoon face in a rectangular plan in terms of through holes, while the longitudinal axis each hole is perpendicular to the plane of the bed side, characterized in that it is made with at least two protrusions of a parallelepiped shape, which are made integral with the body of the building block and p found on the rear faces perpendicular to the stretcher, the end of each projection is flat or stepwise, each protrusion from the side faces of the binder is located at a distance from this binder faces, smaller than half the distance between the projections on the seam thickness rastvora.2 masonry. The block according to claim 1, characterized in that the through holes in the building block are made identical in shape in plan. The block according to claim 1, characterized in that the thickness of the seam of the masonry mortar is 6-15 mm

Description

The utility model relates to the field of construction, namely to the construction of building blocks or bricks with voids of various geometric shapes and masonry from them, and can be used in the construction of external load-bearing walls of buildings and structures.

Also known is a building block made in the form of a rectangular parallelepiped containing rows of through holes located along the spoon face placed offset from each other in adjacent rows, each row of through holes formed by two identical main rectangular through holes and one additional through hole made square (RU 17052, E04C 1/00, publ. 10.03.2001). This decision was made as a prototype.

This building block due to the creation of a sufficiently large number of small (slit-like) through holes has an increased percentage of voidness, which allows to reduce the thermal conductivity and increase the heat efficiency of the building block and the outer walls of buildings and structures from such building blocks. However, these voids cannot be considered as channels for laying engineering communications or power elements of wall reinforcement. This is due to the fact that, firstly, the dimensions of the holes do not allow any long element to pass through them, and secondly, the lack of an optimized location of the holes in the building block does not allow for laying in 1/2 or 2/3 or 3 / 4 bricks (blocks) combine the hole of one with the hole lower or upper located with the offset of another brick (building block). The impossibility of forming, when laying blocks of through vertical channels in the wall, necessary for use for various purposes - for laying communications, for hardening the masonry with reinforcing elements, including by creating in full or in part the height of the wall of the vertical channels of an equal strength monolithic reinforced concrete structure, and / or for masonry insulation with bulk insulating materials with vertical filling on top of more than one row - causes insufficient applicability of the building block.

The technical result of the utility model is to increase the operational properties of a building block when laying masonry from such building blocks by optimizing their voidness for organizing vertically oriented channels in the wall when laying masonry for laying communications and / or for insulating masonry with heat-insulating rigid and / or bulk materials and / or for subsequent hardening of the masonry with reinforcing elements, and increasing the bearing capacity of the masonry and the structure of the structure as a whole.

The specified technical result is achieved by the fact that in the building block for spoon masonry, which is a rectangular parallelepiped in shape with spoon, poke and bed flat faces, while at least two rectangular rectangular geometrical shapes are arranged in series along the spoon face in plan through holes, while the longitudinal axis of each hole is perpendicular to the plane of the bed side, made with at least two protrusions of a parallelepiped shape, which e integrally formed with a building block body and positioned perpendicular faces of one of the stretcher, the end of each projection is flat or stepwise, each protrusion from the side faces of the binder is located at a distance from this binder faces, smaller than half the distance between the projections on the seam thickness masonry mortar.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

This useful model is illustrated by specific examples of execution, which, however, are not the only possible ones, but clearly demonstrate the possibility of achieving the desired technical result.

In FIG. 1 shows a general view of a building block with two protrusions;

FIG. 2 - shows a General view of a building block with three protrusions;

FIG. 3 - shows a General view of a building block with four protrusions;

FIG. 4 - shows a general view of a building block with two step-shaped protrusions;

FIG. 5 - shows a General view of a building block with three step ledges deployed in one direction;

FIG. 6 - shows a General view of a building block with three step-shaped protrusions, two of which are deployed in one direction and one in the opposite;

FIG. 7 - shows a General view of a building block with four step ledges deployed in one direction;

FIG. 8 - shows a General view of a building block with four step ledges, two of which are deployed in one direction, and two others are deployed in the opposite direction;

FIG. 9 is an example of the position of the building blocks of FIG. 1 in a row of masonry, the first example of laying a seam;

FIG. 10 is an example of the position of the building blocks of FIG. 4 in a row of masonry, a second example of laying a seam;

FIG. 11 is an example of the position of the building blocks of FIG. 4 in a row of masonry, a third example of laying a seam;

FIG. 12 is a first example of the masonry of building blocks of FIG. 1 with a 1/2 shift of each block in each subsequent upper row;

FIG. 13 is a second example of the masonry of building blocks of FIG. 1 with a shift of 1/2 in the first row of masonry blocks relative to each other and with a shift of 1/2 of each subsequent block in each upper row relative to the underlying block;

FIG. 14 is an example of the masonry of building blocks of FIG. 5 without shifting blocks relative to each other;

FIG. 15 is an example of the masonry of the building blocks of FIG. 5 showing the technology of laying a block by turning the block 180 ° in the embodiment without shifting the blocks relative to each other in the first row and with a step increment of 1/3 of each subsequent block in the upper row relative to the underlying block and the block in the same row;

FIG. 16 is an example of the masonry of building blocks of FIG. 5 with a shift of 1/3 in the first row of masonry blocks relative to each other;

FIG. 17 is an example of the masonry of building blocks of FIG. 5 with a shift of 1/3 in the first row of the masonry blocks relative to each other and each subsequent upper row of blocks relative to the lower lying row of the block;

FIG. 18 is an example of the masonry of the building blocks of FIG. 1 and the masonry variant of FIG. 12 with 1/2 offset of each subsequent block in the upper row relative to the underlying block using inserts in the voids present in the block and formed during masonry;

FIG. 19 is an example of the masonry of building blocks of FIG. 1 with a 1/2 offset of each subsequent block in the upper row relative to the underlying block using inserts and reinforcing the masonry using the voids present in the blocks and formed during the masonry, and also is an example of masonry blocks for creating a wall from the blocks of FIG. 1 bypassing the previously created vertical reinforced structural element;

FIG. 20 is an example of the masonry of the building blocks of FIG. 7 with a shift of 1/2 blocks relative to each other in the first row and with a shift of 1/2 of each subsequent block in the upper row relative to the underlying block in the corresponding row.

According to this utility model, the construction of a building block or brick with voids for spoon masonry is considered, which is a rectangular parallelepiped 1 in shape with two spoon 2, two poke 3 and two bed 4 faces (Fig. 1-3). At least two vertically oriented through holes 5 of square or rectangular or round or other geometric shape (oval or polygonal) in plan are made in the body of such a block. The through holes in the building block are made identical in shape in plan. In FIG. 1 shows a building block, in the body of which there are two through holes 5 rectangular in horizontal section, arranged successively along a spoon face. In FIG. 2, in the body of the building block, there are three through holes 5 rectangular in horizontal section, arranged successively along the spoon face, and in FIG. 3 shows a block where there are four such through holes 5. These building block body examples are preferred. A feature of the building block under consideration is that it is made with protrusions 6 of a parallelepiped shape, which are made integral with the body of the building block and are perpendicular to the spoon face. In FIG. 1 shows a building block in which there are two such protrusions 6, in FIG. 2 such protrusions 6 three. In FIG. 3 shows a building block having four protrusions 6. The protrusions 6 are made equal to the height of the spoon face, and are parallelepipeds in shape with flat faces. The protrusions are located at a distance from the adjacent bonded face, and between adjacent adjacent protrusions an open recess 7 is formed, partially or completely repeating in plan the shape of the through hole 5 in the body of the block.

A feature of the shape of the through hole 5 in the plan is that it must be symmetrical with respect to two mutually perpendicular axes or planes of symmetry extending in the direction parallel or perpendicular to the surface of the spoon face. In FIG. 12 shows how, when masonry, two adjacent building blocks of FIG. 1 can be joined to each other in the same row (same plane) through a vertical layer of masonry mortar (masonry seam) along the spoon edges from the side of the projections 6 (Fig. 1 and Fig. 9), which allows additional through holes 8 to be formed at the junction of the blocks .

In FIG. 12 shows how when laying rows of blocks of FIG. 1 by the method of FIG. 9 through holes 8 are formed by connecting the recesses 7 of each of the adjacent blocks joined in the same plane along the protrusions of 6 blocks through the connecting faces 10 due to the connection through the vertical layer of masonry mortar 11 or due to the subsequent connection in the row of bonded faces of 3 blocks through the vertical layer of masonry mortar 12. Through vertical holes 9 in the masonry between the corner zones on the other side of the protrusions (Fig. 13), equal to the geometric shape of the part of the hole 8 formed in the plane of one row, are formed when laying each new block of the top row of FIG. 1 by the method of connecting the blocks of FIG. 9. A through vertical hole 14 in the masonry completely formed by two or more horizontal rows of masonry is shown in FIG. 13, 15, 17, 20.

In FIG. 2 shows a building block with three holes 5 and three protrusions 6, and in FIG. 3 shows a building block with four holes 5 in the body and four protrusions 6. In the examples of FIG. 1-3 protrusions 6 are made equal in height to the height of the spoon face, and are parallelepipeds in shape with flat faces. Each protrusion on the side of the bonded face 3 is located at a distance from this bonded face 3, equal to half the distance between the protrusions reduced by the thickness of the vertical seam of the masonry mortar.

The connecting face 10 in the blocks of FIG. 1-3 and FIG. 9 is made flat. These blocks are used to form a masonry, in which all the blocks in the same row are joined along the length of the row with bonded faces from the side of the protrusions 6 through the connecting edge 10 (through the masonry mortar), and two stacked blocks are joined along the width of the row by pressing the protrusions 6 into each other through the connecting edges 10 of each block (and flat spoon edges are located outside the wall).

When laying and joining in the same row two building blocks of FIG. 1, mortar is introduced between the connecting edges through protrusions and forms a vertical masonry seam 11. An example of such a row of masonry from building blocks of FIG. 1 is shown in FIG. 12, 13. The next upper row is laid through the masonry mortar onto the previous (lower) block with a block offset of 1/2 relative to the blocks in the previous (lower) row. When optimizing the size of the through holes 5, 8 and 9 in the masonry, vertical channels can be arranged, while such channels will have a height equal to the height of the wall. In this regard, some optimization requirements must be presented to the shape of the holes in the plan and their location to the body of the building block with respect to the poke and spoon faces. Only with an optimized arrangement, such openings with direct or offset laying 1/2 or 1/3 steps allow the formation of vertically oriented channels.

To solve the joint problem of creating vertically oriented channels in the body of the block and using them as communication paths, the size and shape of the hole located along the line E1-E2 (along the spoon face) is chosen based on the considerations below.

Building blocks during masonry with an overlap of 1/2 the length of the block (for example, in Fig. 1) should be located so that the holes of some blocks overlap the holes of other building blocks, forming vertical through channels of the same channels.

It is taken into account that the building blocks are interconnected in the masonry by means of a mortar having a predetermined thickness “c” (the size of the vertical joints 11 and 12 of the masonry).

In the presented masonry embodiments of FIGS. 12, 13, the building block of FIG. 1 is provided with two holes 5 located along the spoon face and made of the same shape (geometric) and dimensions in terms of. Blocks are laid in masonry through vertical joints 11 and 12 of masonry mortar having a predetermined thickness "c" (width). The thickness (width) of the jumper “g1” between the holes 5 in a row, measured on the surface of the bed side along an imaginary line E1-E2, drawn parallel to the surface of the spoon side, is greater than the sum of the thicknesses h1 and h2 of the jumper between the holes 5 and the surfaces of the butt faces 3 of the block , measured along the same line, by the value of "c" equal to the specified thickness of the vertical layer of masonry mortar 12 between the blocks during masonry, that is, the equality

g1 = h1 + h2 + c,

where g1 is the thickness of the jumper between the holes 5 in the block;

h1 is the thickness of the jumper on the first bonded face, measured along the imaginary line E1-E2 indicated above;

h2 is the thickness of the jumper on the second bonded face, measured along the same imaginary line E1-E2 indicated above;

c - the specified thickness of the vertical layer of the masonry mortar / glue (seam) between the blocks during masonry.

Typically for masonry, such a seam has a thickness of 6-15 mm (usually 9-12 mm). In fact, the thickness of the seam for a brick or building block is a constant, that is, an unchanged value. Regardless of the size of the building block, the joint is used in a standard size, that is, in the range of 6-15 mm (article “Types of masonry”, posted on the Internet in online access at: http://works.tarefer.ru/ 82/100076 / index.html). Thus, in relation to the masonry, we can say that one building block is located from another building block at a distance equal to the size of the vertical seam.

In the presented embodiment (Fig. 1), the block is made with one recess, width h3 between the protrusions 6 located on the block on one of the butt sides 2. To form vertical channels that are identical in plan shape due to the formation of through holes 8 between the joined faces of the protrusions and through holes 9 between the corner zones on the other side of the protrusions, it is necessary that when laying with an offset of 1/2 the holes 8 and 9 (Fig. 13) overlap each other between the rows. For this, it is necessary that the width h3 of the recess between the protrusions 6 is equal to the sum of the widths h4 and h5 of the corner zones of the block, which are formed between the protrusion and the adjacent bonded face, plus the thickness “c” of the vertical layer of masonry mortar / glue (joint) between the blocks at masonry, that is, the following equality holds:

h3 = h4 + h5 + c,

where h3 is the width of each recess formed by the protrusions on one of the butt sides of the block;

h4 is the angular zone on the first bonded edge, measured along the imaginary line E1-E2 indicated above from the nearest protrusion to this (first) bonded edge;

h5 is the angular zone on the second bonded edge, measured along the imaginary line E1-E2 indicated above from the nearest protrusion to this (second) bonded edge;

c - the specified thickness of the vertical layer of the masonry mortar / glue (seam) between the blocks during masonry.

In the optimal (ideal) embodiment, the thickness (width) of the protrusions 6 measured along the imaginary line E1-E2 above equal to g2 will be equal to the thickness (width) of the jumper “g1” between the holes 5 in a row, and the width h6 of the holes 5 measured along the imaginary line indicated above E1-E2 will be equal to the width h3 of each recess formed by the protrusions on one of the butt sides of the block measured along the imaginary line E1-E2 indicated above.

This optimization is based on the fact that the protrusions in the block are made identical and are located symmetrically with respect to a plane passing perpendicular to the spoon face through its middle (at the same distance from the butt faces).

Similar conditions will be fulfilled for the spoon masonry of building blocks made with three or four through holes in the body and with three or four protrusions, respectively (Fig. 2 and Fig. 3, respectively).

A feature of the considered building blocks of FIG. 1-3 is that when laying a wall in each row, one building block is laid with a flat spoon face out of the masonry, and the next building block of the same design as the first is turned 180 ° relative to the horizontal plane of the masonry and laid next to the first one, that all of its protrusions or part of the protrusions abut through the masonry mortar 11 forming a vertical seam in the protrusions of the previously laid block (Fig. 13).

In FIG. 18 shows an example of the masonry of FIG. 12 of the blocks of FIG. 1 using liners that can be made of heat-insulating or other material specified by the project.

In FIG. 15 shows an example of the masonry of the building blocks of FIG. 1 with a 1/2 offset in each row of masonry blocks relative to each other and with a 1/2 offset of each subsequent block in each upper row relative to the underlying block. In FIG. 15 shows how when laying rows of blocks of FIG. 1 with a shift of 1/2 blocks relative to each other in the plane of one row, through holes 8 are formed by connecting the recesses 7 of each of the adjacent blocks joined in the same plane along the protrusions 6 of the blocks through faces 10 by connecting through a vertical layer of masonry mortar 11 or behind due to the subsequent connection in the row of bonded faces 3 of the blocks through a vertical layer of masonry mortar 12. Through vertical holes 9 in the masonry between the corner zones on the other side of the protrusions in FIG. 15 are equal in geometrical shape to the portions of the hole 8 formed in the plane of one row, are formed when each new top row of blocks of FIG. one.

In FIG. 4-6 show building blocks, the construction of which repeats the design of the previously considered blocks of FIG. 1-3, but the protrusions of these blocks while maintaining the parallelepiped shape as a whole from the side of the connecting face are made stepped in shape 13. When laying with a flip, the stacked block with its stepped protrusion of the connecting face completely enters the stepped part of the protrusion of the previously laid building block of FIG. 10 or partially as shown in FIG. 11. This is possible due to the fact that when the block is rotated, the stepped portion of the protrusion becomes responsive to the stepped portion of the protrusion of the first block. With this connection, through the stepped contacting (masonry mortar), the seam can be on the entire surface of the steps of the connecting edge (Fig. 11) or only in the inner zone of the docking sandwiched between the protrusions (Fig. 10).

Another feature of this connection is that the protrusions with a stepped connecting surface serve as block positioning elements relative to each other. That is, when laying, each docked block occupies only that position, which for it is determined by the position of the protrusions of the previously laid block and the second block of FIG. 4-8 is stacked only by turning it 180 ° relative to the horizontal plane of the masonry. This allows you to maintain a constant throughout the wall masonry vertical thickness of the joint 11 and to guarantee the exact position of the blocks in the same row with respect to the blocks in the previously laid row at an offset of 1/2 (in Fig. 4 and in Fig. 7-8) or 1 / 3 (in FIG. 5-6) or 3/4 (in FIG. 7-8). An example of such oriented masonry of the blocks of FIG. 5 is shown in FIG. 14-17.

In addition, in the masonry row, the longitudinal loads falling on the building block in the direction of the masonry row are redistributed to adjacent blocks due to the fact that the adjacent blocks are interlocked. This important new property allows you to more efficiently redistribute the dynamic loads in the masonry both horizontally and vertically over a large area in comparison with the standard masonry scheme, since in this case there is no local loading of more than one block in the masonry and the vertical seam 12 in each horizontal row will be accordingly, it is bounded above, below, and from the side (on three sides) by the whole body of the neighboring block. Thus, in those shown in FIG. 14-17 variants of masonry according to figure 5 there is an interconnected transfer of load from one block to adjacent blocks located on all sides. This should provide a higher bearing capacity of the masonry and its durability compared to the masonry variant of FIG. 12, 13. With the local destruction of one of the blocks or the destruction of the seam, the further development of a vertical crack will be significantly limited, since the bearing capacity of the destroyed block (seam) is immediately redistributed to adjacent blocks interconnected with it and each other and the destructive force in the vertical or horizontal direction, respectively will be immediately weakened at times due to the increase in the times of the area to which it is attached.

In FIG. 4-5 and FIG. 7 shows building blocks in which a step in all protrusions is made on the same side of each protrusion. This allows you to position each block in the masonry with an emphasis in one direction, that is, in masonry, the positioning of the blocks is carried out with an emphasis in one direction, leaving the possibility of laying a seam and fitting the blocks along the seam.

And in FIG. 6 and 8 show building blocks in which on at least two adjacent protrusions the stepped surfaces on the protrusions are facing towards each other. This embodiment allows you to form a "castle" in the connection between the blocks. When laying, one protrusion enters the cavity between the other protrusions, excluding the movement of the block along the row. This rigid positioning allows you to provide high load capacity created by two blocks of a new element in the masonry.

In FIG. 20 shows a variant of the masonry of FIG. 7 with 1/2 blocks offset relative to each other in each horizontal row, each building block joining one protrusion with two protrusions of the first block opposite, and the other two protrusions with protrusions of the second block opposite being adjacent to the tying face with the first block and each the block of the subsequent upper row is laid in relation to this block in a ratio of 1/2 s preserving the rule of ratios 1/2 in a horizontal row.

During the laying process in the building blocks, whole connected vertical rows of through voids 14 can be formed in the form of certain geometric columns (channels) over the entire height of the wall (Fig. 12, 13, 15, 18, 19, 20). These holes can be used to fill bulk insulation: expanded clay, vermiculite, crumbled foam glass, polystyrene foam, expanded polystyrene, expanded polystyrene, etc., or to reinforce masonry with reinforcing elements, to join hard insulation in vertical ducts of a wall to a joint, without penetration of masonry mortar / glue. These channels can also be used for laying communications - electrical wiring, pipes, telephone cables, etc. The purpose of these channels can be taken into account in the design and construction of the building (for example, there is no need for the subsequent operation of “punching” the walls under the hidden wiring of communications in the wall, which is laid during the construction of the wall).

In the through holes 5 of the blocks and in the vertical rows of through voids 14 formed during masonry, as well as in the recesses 7 between the protrusions 6, inserts 15 of a predetermined heat-insulating or other special material can be installed (Fig. 12, 13, 15, 18, 19, 20 ) The liners 15 may repeat the shape of the through hole in the body of a rectangular box and be made with a height equal to the height of this through hole. Such liners 15 can be inserted into all the through holes in the body of the unit or only to part of them. The same inserts 15 are used for placement in the formed through holes 8 and 9, which are formed during spoon laying when the bonded edge of one building block 1 adjoins the bonded edge of the stacked building block 1 or in the recess 7 when laying the blocks in a row (Fig. 12, 18 , 19).

If the formed whole communicating vertical rows of through voids 14 exceed horizontal inserts 15 in horizontal section, then two inserts 15 can be inserted into such voids 14 and between them there will remain a void equal to the thickness of the vertical masonry seam (Fig. 18) or insert 16 repeating fully in horizontal section the vertical void formed during masonry 14.

Some inserts may have a height greater than the height equal to the height of the through hole by an amount equal to the thickness of the horizontal layer 17 of the binder (masonry) joint solution (height from 6 to 15 mm).

The liner may be made solid or hollow in the form of a thin-walled shell or in the form of a tubular element. The insert is made of heat-insulating material or an insulating or other special material, or in a combination of such materials. The insert is used to solve the joint task of creating channels to increase the path length of the heat flux in the body of the block, weaken the strength of the heat and / or sound flux and use them as communication paths.

Placing in at least part of the through holes of all or part of the building blocks of the liners 15, protruding above the blocks of the laid row to the double height of the horizontal seam 17 of the masonry mortar, provides guides for the next row of masonry. After uniform laying on top of the blocks of the base row of masonry mortar, liners stick out above the masonry mortar to the height of the horizontal seam 17 between the rows, being guides for installing on top of the blocks of the next row. This process is repeated during the laying of each subsequent row. If the height of the protruding part of the liner is equal to the thickness of the seam 17, then such liners will increase the path of cold air through the masonry seam and the masonry as a whole.

Channels formed vertically by masonry by matching the through holes in the blocks can be used for pouring concrete and for forming power bonding elements of the masonry, for example, by creating partly vertical channels of a monolithic equal strength reinforced concrete structure 18 (Fig. 18).

The use of the blocks of FIG. 1-8 allows you to masonry according to various technological methods.

In FIG. 12 shows the masonry of FIG. 1, in which the blocks are joined in a row through the bonded face 3 with a uniform orientation of the spoon part of block 2 without protrusions in one direction and the spoon part with protrusions 6 in the other direction.

In FIG. Figure 14 shows the masonry in which in each two-row row the building blocks are joined in the transverse direction by protrusions, and in the longitudinal direction of the masonry, docking through the seam is carried out by the abutment of the bonded faces. In this case, the building blocks are located so that the protrusions of one block are joined with the protrusions of another block located opposite. Between the rows there is a 1/2 offset. And in FIG. 15 shows the same masonry, but with a 1/2 offset of each block in the same horizontal row so that with one protrusion the block joins one protrusion of the other block, and the other protrusion with the protrusion of the third block which is located in a row with the previous block with which docking with one ledge. In FIG. 15-17 show masonry options using the building blocks of FIG. 5 with three protrusions to form a “lock”.

In FIG. 15-17 shows the masonry with 1/2 blocks offset relative to each other in each horizontal row, with each building block joining one protrusion with two protrusions of the first block opposite, and the other two protrusions with protrusions of the second block opposite being adjacent to the butt edge the first block, and each block of the subsequent upper row is laid in relation to this block in a ratio of 1/2 s preserving the rule of 1/2 ratios in a horizontal row. A feature of such masonry is that the docking unit is turned over only 180 ° horizontally and is installed in the masonry mirror in relation to the previously laid block.

In the masonry embodiment of FIG. 9 shows an example of forming masonry from the blocks of FIG. 1 with the ability to bypass the previously formed reinforced power element 19 of the structure of the structure (building) made of reinforced concrete while maintaining the same thermal properties in the outer rows of the masonry using a liner 15 of insulation or other insulating material.

The use of this utility model in the field of construction during the laying of the external walls of civil and industrial buildings and structures and during the construction of external load-bearing walls of buildings and structures makes it possible to increase the thermotechnical properties of masonry from such building blocks by increasing the voidness of building blocks to increase the length of the heat flux in the body block while increasing bearing capacity due to the redistribution of loads between a large number of blocks in the masonry.

Claims (3)

1. A building block for spoon masonry, which is a rectangular parallelepiped in shape with spoon, poke and bed flat faces, while at least two rectangular consecutive holes are arranged along the spoon face in a rectangular plan in terms of through holes, while the longitudinal axis each hole is perpendicular to the plane of the bed side, characterized in that it is made with at least two protrusions of a parallelepiped shape, which are made integral with the body of the building block and p found on the rear faces perpendicular to the stretcher, the end of each projection is flat or stepwise, each protrusion from the side faces of the binder is located at a distance from this binder faces, smaller than half the distance between the projections on the seam thickness masonry mortar. 2. The block according to claim 1, characterized in that the through holes in the building block are made identical in shape in plan. 3. The block according to claim 1, characterized in that the thickness of the seam of the masonry mortar is 6-15 mm

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