RU2742921C2 - Construction wall block and method of connecting the block to adjacent wall blocks - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to construction and production of construction materials. To increase earthquake resistance of blocks and buildings made from them, the unit comprises face and back layers, between which intermediate layer is located. Slot and ridge are located in face layer of unit. Layers of the block have porous structures and are interconnected. In the intermediate layer of the unit, having pores larger than pores of the front and rear layers of the block, longitudinal and vertical grooves communicated with the pores of the intermediate layer are made for the fluid glue composition in them. Longitudinal grooves are interconnected with vertical grooves at points of their convergence at corners of block and are interconnected with pores of intermediate layer of unit. Grooves are intended for free arrangement of longitudinal reinforcing elements and adhesive composition. Vertical grooves are made for formation between adjacent blocks of cavities for adhesive composition located in them, which connects sides of adjacent blocks. In the intermediate layer there are vertical holes communicated with the pores of the intermediate layer under the adhesive composition and vertical reinforcing elements freely installed in them. Each groove has in cross-section the shape of semi-circle or semi-circle, rectangular or trapezoidal groove. Each end of the hole of the block can be made with a conical bell flared out in the intermediate layer of the block. Also described is a method of connecting a building wall unit with adjacent blocks.EFFECT: high earthquake resistance of blocks and structures made therefrom.10 cl, 11 dwg

Description

This invention relates to the field of construction and the production of building materials, in particular to such structures of wall building blocks, which allow to carry out the methods of laying from blocks of walls of buildings without the use of cement mortar to connect the blocks.

The invention is intended for its use in the field of construction of buildings that meet the increased requirements of their resistance to seismic loads.

The description of the present invention presents a wall building block and a method of erecting walls of structures with increased seismic resistance from wall blocks.

Structurally not disclosed are known from publications on the Internet: Reinforcement of aerated concrete blocks. Features of reinforcement of aerated concrete masonry. Reinforcement of aerated concrete blocks: is it necessary to reinforce the masonry and how to do it. Wall block for wall reinforcement. Block with longitudinal grooves for reinforcement. Blocks connected with polyurethane foam. Block with vertical holes, longitudinal grooves and projections on the sides. Block with frame volumetric reinforcement embedded in it. Block with a longitudinal groove and a transverse hole for reinforcement (Yandex. Date of inspection - 12.06.2019).

Also known is the laying of expanded clay wall blocks using reinforcing bars in their joints, while each block of known masonry has two pairs of holes symmetrically located in the middle of the block, into which reinforcing bars are driven into the masonry process (RB House Technology, Youtube com, 08/31/2017 ).

When the rods are driven into the specified mortarless masonry, the structure of the expanded clay intermediate layer of the block is disturbed, especially if the blocks have errors in the parallelism of the lower and upper planes of the blocks being joined, while the strength of the block connection is reduced from impacts during driving, since cracks in the blocks are possible from impacts.

It is also known a building system containing individual building elements, each element has an upper and lower surface, which are substantially parallel to each other, and contains at least one hole extending from the upper surface to the lower surface, while the building elements made with the possibility of their installation one on top of another so that the holes of the different elements are located coaxially with respect to each other, and the connecting element is located in each hole, whereby the first building element belonging to it is pressed against the second building element located directly under the first building element , wherein the connecting element of each first building element acts on the upper surface of this first building element and is connected to a connecting element belonging to the second building element, characterized in that between the lower surface of the first building element element and the connecting element of the second building element, a deformable element is installed, which is deformed by the first predetermined force, thus creating a stress in the connecting element of the first building element, this force being substantially less than the second predetermined force, by means of which each first building element is pressed against the second predetermined force to the second building element. The connecting element contains a rod, attached at one end, the lower end, to the immediately below-located building element, and its second end, the upper end, is provided with an expanded part pressing against the upper surface of the building element. The upper end of each rod has a widened portion provided with a threaded hole for inserting the lower end of the threaded rod of the superimposed building element.

Each hole in the building element near the upper surface and / or the lower surface is provided with a cutout for inserting an expanded portion of the upper end of the rod. The cutout in the upper and / or lower surface is positioned in such a way that the correct alignment of the building elements relative to each other can be obtained through the widened part. The extended part and the connecting piece form a single unit.

The construction system provides that gutters are made in the upper and / or lower surface, ending in the side walls, and these gutters are provided with threads, and the threaded rods are installed in the corresponding grooves of adjacent building elements to form a horizontal connection (RU 2175702 C2, 10.11.2001) ...

From the patent documentation, building wall blocks are known, made with elements that make it possible to reinforce the wall masonry from blocks connected to each other during the construction of the wall, in particular, a wall block is known, which has two symmetrically located grooves for laying horizontal reinforcement, as well as an oval-shaped window located in the middle of the block to accommodate vertical reinforcement. Each block also has oval lateral end recesses and upper projections and lower counter recesses located on the front side (WO 2001018317, 15.03.2001).

Known wall block having closed grooves for vertical rods and vertical oval holes located in the corners of the block for the passage of vertical reinforcement (JP4119946B2, 20.02.2004). It is also possible that this block has two vertical through-holes for the passage of reinforcement (JP 4119946 B2 16.07.2008).

Known building wall block for masonry of walls of buildings, while the blocks form a wall including a first reinforcing mesh and a second reinforcing mesh, and the first reinforcing mesh and the second reinforcing mesh respectively contain a transverse rib and a longitudinal rib, and the transverse rib and longitudinal rib are sewn vertically transversely with by forming a reinforcing mesh with a rectangular mesh, the first reinforcing mesh and the second reinforcing mesh are parallel and correspond to the rectangular mesh. An insulating block is formed between the cavities, and the two sides, as well as the upper and lower surfaces of the insulating block, are respectively provided with arc-shaped grooves, and the arc grooves are connected to the first reinforcing mesh and the second reinforcing mesh (CN 109208780 A, 01/05/2019).

Known reinforced blocks and reinforced walls of buildings, the reinforcement of which is located in blocks and between blocks (RU2688696C2, 17.09.2018. RU 2557275 C1, 20.07.2015. US 2006260256, 23.11.2006. RU 2529534 C1, 27.09.2014. RU 125598 U1, 03/10/2013. RU 2634136 C1, 24.10.2017. RU 150788 U1, 27.02.2015. RU 119772 U1, 27.08.2012. RU 2402660 C1, 20.03.2010. RU 2402661 C2, 27.10.2010. RU 2634139 C1, 24.10. 2017. RU 2011112603 A, 10.10.2012. RU 123036 U1, 20.12.2012. RU 2229570 C2, 20.10.2003. RU 93074 U1, 20.04.2010. RU 53329 U1, 10.05.2006. RU 234243 C2, 20.01.2009) ...

From the patent RU 2640527 C2, a method for constructing a wall structure is known, which consists in laying building blocks in the form of a parallelepiped with at least two through holes located symmetrically from the edges of the building block, in rows one on top of the other with a sequential displacement of each subsequent row by the amount necessary for the coaxial arrangement of the holes of the previous and subsequent rows, with further placement of fasteners in the holes, and fasteners having a length greater than the height of the building block are installed in the holes through one and securely fixed, while fastening elements are installed in each subsequent row of building blocks into the holes free from the fasteners of the previous row, thus forming a staggered arrangement of fasteners in the wall structure. The building blocks are pre-installed with embedded elements located at the locations of the through holes and having a height equal to the height of the building block, and the width and depth - greater than the diameter of the through hole, while the through holes are made in the embedded elements. Insulation is placed between the rows of building blocks and between the building blocks of one row. In building blocks, grooves are made to accommodate insulation (RU 2640527 C2, 01/09/2018).

A significant disadvantage of the method and block according to patent RU 2640527 C2 is that the above-described connection does not meet the requirements of its tensile strength from forces acting in vertical directions. These forces act on structures, both in seismic conditions and in other conditions as a result of ground vibrations, air shock waves, wind loads, flooding and floods. In the case of large alternating loads in vertical directions, the joints of the blocks fail.

At the same time, as noted above, when driving reinforcing bars into blocks, the structure of the most vulnerable expanded clay intermediate layer of the block is disturbed, especially if the blocks have errors in the parallelism of the lower and upper planes of the joined blocks and errors in the tight fit of the upper block to the lower block. In the latter case, the strength of the connection of the blocks against impacts when driving reinforcement decreases. As a rule, subsequently growing microcracks appear in the blocks, and often the upper and lower blocks split from impacts, due to a loose fit to each other during driving. In this case, driving along the end of the reinforcing bar with the aim of pressing the blocks against each other and increasing the strength of the connection of the blocks is associated with an increase in the bearing capacity of the bar and an increase in its diameter. In the case of insufficient resistance to bending, the diameter of the bar increases, while the metal consumption increases, and in the case of a decrease in the diameter of the reinforcing bar, it bends when driven into the hole of the lower block and destroys the wall of the block hole. At the same time, it is impossible to use rods made of composite reinforcement in the method according to patent RU 2640527 C2, since when such rods are driven along their ends, they show their elasticity, dampen shock loads, bend and lose stability, while the ends of the rods made of composite reinforcement grind.

Thus, as practice shows, as well as the achieved technical level in the field of reinforcing block walls of buildings with vertical reinforcing bars, the known reinforcement is ineffective under the indicated operating conditions of buildings, especially in seismic conditions.

Another patent RU 2175702 C2 discloses a building system comprising separate building elements, each element having an upper and lower surface that are substantially parallel to each other and containing at least one opening extending from the upper surface to the lower surface , while the building elements are made with the possibility of their installation one on top of the other so that the holes of the different elements are located coaxially with respect to each other, and the connecting element is located in each hole, whereby the first building element belonging to it is pressed against the second building element located directly below the first building element, wherein the connecting element of each first building element acts on the upper surface of the first building element and is connected to the connecting element belonging to the second building element. The system is characterized in that a deformable element is installed between the lower surface of the first building element and the connecting element of the second building element, which is deformed by the first predetermined force, thus creating a stress in the connecting element of the first building element, and this force is substantially less than the second predetermined force. whereby each first building element is pressed with a second predetermined force against the second building element. The connecting element contains a rod, attached at one end, the lower end, to the immediately below-located building element, and its second end, the upper end, is provided with an expanded part pressing against the upper surface of the building element. At least the lower end of the rod is threaded. The upper end of each rod has a widened portion provided with a threaded hole for inserting the lower end of the threaded rod of the superimposed building element. Each hole in the building element near the upper surface and / or the lower surface is provided with a cutout for inserting an expanded portion of the upper end of the rod. The cutout in the upper and / or lower surface is positioned in such a way that the correct alignment of the building elements relative to each other can be obtained through the widened part. The extended part and the connecting piece form a single unit. The deformable element is made in the form of a ring with a conical body. In the upper and / or lower surface, grooves are made that end in the side walls, and these grooves are provided with threads, and the threaded rods are installed in the corresponding grooves of adjacent building elements to form a horizontal connection (RU 2175702 C2, 10.11.2001). This solution uses threaded connections of vertical reinforcing elements with each other, which significantly complicates the structure of the walls of buildings.

Known wall block and its variants, the first of which is characterized by the fact that it is made in the form of a faceted structure of a cured material, having a front surface located on the outer front side of the block, an inner surface located on the inner side of the block, the lower, upper and side surfaces, when this block contains a face layer, an intermediate layer and an inner layer sequentially located along its width, and the face layer has a thickness s1 that is less than the thickness s2 of the intermediate layer, and the thickness s3 of the inner layer is less than the thickness s1 of the face layer, the latter contains cement, plasticizer and crushed expanded clay with fractions ranging from 1 to 5 mm, the intermediate layer of the block contains cement, plasticizer and expanded clay with fractions ranging from 5 to 20 mm, the inner layer of the block contains sand, cement and plasticizer, the indicated thicknesses of the block layers are selected depending on the width S of the block and are in the ratio s1: s2: s3 = (0.10-0.17) S: (0.89-0.79) S: (0.007 -0.037) S, the block contains an L-shaped ridge made in the front layer and covering it from two adjacent lateral and lower sides, as well as an L-shaped ridge made in the front layer and covering from two other adjacent side and upper sides of the block, a ridge and the groove is located in one plane parallel to the front surface of the block, the surface of the ridge and the groove, the front and inner surfaces are solid and smooth, and the bottom, top and side surfaces of the block, located between the front and inner layers, are made rough with grooves extending into the block from 0 , 1 mm to 20 mm between fractions, while the length L of the block from its front side is chosen depending on the width S of the block within L = (0.99-1.01) S, the length Lwn of the block from its inner side is chosen equal to the length block from its front side, the block face is located at a distance s4 from the ridge axis, the inner surface of the block is located from the ridge axis at a distance s5 greater than m distance s4, while s4 and s5 are in the ratio s4 = (0.08-0.16) s5. The height h of the ridge is equal to the depth h1 of the depression, h = (0.05-0.12) H, where H is the height of the block, the ridge is made in one piece with the block by the method of its molding in the form during the manufacture of the block, the ridge has beveled surfaces relative to its longitudinal axis, the recess is made in the block mass, extends towards its middle and has beveled surfaces relative to the longitudinal axis, the recess has a reciprocal shape in cross section with respect to the ridge shape in its cross section, and the ridge length is equal to the recess length (RU 2465415 C1, 28.10.2012) ...

It is known the connection of building wall blocks located between the blocks of mounting foam, which has the properties of adhesion, expansion during curing and germination into the pores of the block, while each block contains a pair of outer layers and one middle layer, each outer layer of the block has smooth end surfaces, butted with smooth surfaces of the outermost layer of the adjacent block, in each middle layer of the block there are recesses and voids extending into the depth of this layer, the cured composition is located between the middle layers of blocks joined together so that it sprouts into the recesses and voids of the middle layers of the connected blocks, the composition is located along the abutting surfaces middle layers of blocks in the form of tape-like tracks, each of which is located at the edge of the middle layer adjacent to the extreme layer, while the connected blocks are made with ridges located in the recesses of adjacent blocks. The connection of building wall blocks is characterized by the use of polyurethane foam as a cured composition. The connection of building wall blocks is characterized by the fact that a binder solution is used as the cured composition, which increases in volume during curing (RU 134556 U1, 20.11.2013).

As a close analogue of the block presented in this description, a building wall block is adopted, which is characterized in that it is made in the form of a faceted structure of cured material having a front surface located on the outer face of the block, an inner surface located on the inner side of the block, a lower, an upper and side surfaces, while the block contains sequentially located along its width front, intermediate and back layers (RU 2465415 C1, 28.10.2012).

As a second close analogue of the block presented in this description, a building wall block is adopted, which is characterized in that a building block having the shape of a parallelepiped with at least two through holes located symmetrically from the edges of the building block, while the holes of the block are intended for location in them fasteners. The building blocks are pre-installed with embedded elements located at the locations of the through holes and having a height equal to the height of the building block, and the width and depth - greater than the diameter of the through hole, while the through holes are made in the embedded elements. Insulation is placed between the rows of building blocks and between the building blocks of one row. In building blocks, grooves are made to accommodate insulation (RU 2640527 C2, 01/09/2018).

The general features of the block presented in this description and close analogs are such features that each of them refers to building wall blocks, and each such block has the shape of a parallelepiped, and the blocks have holes for reinforcing elements.

As a prototype of the method for connecting a block with adjacent blocks of the wall, a method for connecting a block with adjacent blocks is adopted, characterized in that the blocks are connected by a cured composition located between them, the cured composition is located between the blocks joined together so that it is germinated into the voids of the connected blocks, the composition is located along the abutting surfaces of the middle layers of blocks in the form of tape-like tracks, each of which is located at the edge of the middle layer, and polyurethane foam is used as a cured composition, or a binder solution can be used that increases in volume during curing (RU 134556 U1, November 20, 2013 - prototype way).

The general features of the analogue of the method and the method presented in this description are such features that each method of connecting a building wall block with adjacent wall blocks is characterized by the fact that blocks with a porous structure are used to connect them with similar adjacent blocks with an adhesive composition having the properties of its germination in the pores blocks to be connected and block setting, while first the lower row of wall blocks is laid, then an adhesive composition is applied to the blocks of the lower row and the blocks of the upper row are laid on it.

As practice has shown, a significant disadvantage of the prototype of the method is the limited use of the known blocks and method, which can be used only in a limited volume for laying walls of buildings in seismic zones.

The technical result of the invention is to increase the seismic resistance of blocks and structures made from them.

The technical result is obtained by a building wall block, characterized in that it contains a front and back layers, between which there is an intermediate layer, a groove and a ridge in the front layer of the block on opposite lower and upper sides, the layers of the block have porous structures and are monolithically interconnected, in the intermediate layer of the block, which has pores more than the pores of the front and rear layers of the block, there are longitudinal and vertical grooves communicated with the pores of the intermediate layer, the longitudinal grooves are made for the flowable adhesive composition located in them, while the longitudinal grooves are connected with the vertical grooves at their convergence at the corners block, vertical grooves are located on the sides of the block, longitudinal grooves are located on the lower and upper sides of the block and are intended for free arrangement of longitudinal reinforcing elements and an adhesive composition in them, vertical grooves are made to form cavities between adjacent blocks under the them an adhesive composition connecting the lateral sides of adjacent blocks, and along the block height in its intermediate layer there are vertical holes communicated with the pores of the intermediate layer for the adhesive composition freely located in them and vertical reinforcing elements located in it, the holes are located symmetrically with respect to the longitudinal and transverse planes of symmetry of the block, while the width of each groove and the diameter of each hole are in the range of 8.0-26.0 mm, and the depth of each groove is in the range of 4.0-13.0 mm.

Each longitudinal and vertical groove has in cross-section the shape of a semi-oval or semicircle, or the shape of a rectangular recess, or the shape of a trapezoidal recess, and each end of the block opening has a conical flare extending outwardly located in the intermediate layer of the block.

The grooves and vertical holes are made in an intermediate layer containing expanded clay gravel, granulated foam glass, vermiculite, dispersed fiber-reinforced concrete, which are impregnated with a binder material.

The length L of the block is set in the range of 0.1-4.0 m, the width S of the block is in the range of 0.08-0.6 m, and the height H of the block is in the range of 0.1-0.6 m.

A method of connecting a building wall block with adjacent blocks of a wall, characterized by the fact that blocks with a porous structure are used to connect them with similar adjacent blocks with an adhesive composition that has the properties of its germination in the pores of the blocks to be connected to set the blocks and press them to each other during the curing of the adhesive composition, when this first, the lower row of wall blocks is laid, then an adhesive composition is applied to the blocks of the lower row and the blocks of the upper row are laid on it, blocks with horizontal grooves on the lower and upper sides of the block are used for laying the wall, with vertical grooves on the sides of the block and from, along at least one pair of vertical holes in each block, then the blocks of each row of wall blocks are joined together by their lateral sides without gaps between them, and after joining, the adhesive composition is introduced under pressure into the vertical channels between adjacent blocks formed after aligning the vertical grooves of adjacent blocks, and in the horizontal grooves of the upper row of blocks, extended longitudinal reinforcing elements are placed, which are closed with tracks of the adhesive composition, then the blocks of the upper row are placed on the blocks of the lower row and at the same time the vertical holes of the blocks of two rows are combined, after which the aligned vertical holes are filled from top to bottom under pressure with an adhesive composition blocks and after that, vertical reinforcing elements are introduced into the aligned holes of the blocks until they are completely or partially immersed in the holes of the blocks to be connected and until the end of each reinforcing element is flush with the plane of the upper block, then the described cycle of connecting adjacent blocks is repeated.

Between the longitudinal reinforcing elements, a non-woven fabric made of springy fibers is placed in the form of a strip.

Each vertical reinforcing element is selected with a cross-sectional area equal to or less than the cross-sectional area of the opening of each block of the upper and lower rows of blocks.

Each horizontal reinforcing element is selected with a cross-sectional area equal to or less than the cross-sectional area of the two aligned longitudinal grooves of the upper and lower blocks.

As reinforcing elements, composite reinforcement based on fiberglass bundles impregnated with epoxy resin is used.

FIG. 1 shows a wall block in perspective, front view.

FIG. 2 shows the connected wall blocks of the first row in perspective.

FIG. 3 - a wall block in perspective view with horizontal reinforcing elements laid in its horizontal grooves.

FIG. 4 - wall blocks of the lower and upper rows of the wall in the process of laying.

FIG. 5 - blocks of the lower and upper rows connected by vertical reinforcing elements in the process of laying the wall.

FIG. 6 is a cross-section of two connected blocks of the lower and upper rows.

FIG. 7 is a view of a block, one hole of which is filled with glue-foam, and in the other hole, filled with glue-foam, a reinforcing element is located.

FIG. 8 - connection of blocks with glue-foam and a vertical reinforcing element located in it, located in the through hole of the upper block and in the blind hole of the lower block. FIG. 9 - connection of blocks with glue-foam and two vertical reinforcing elements located in it in through-holes of blocks with conical sockets at the ends of the upper and lower blocks, with the formation of a sleeve in the connection zone of hardened glue-foam.

FIG. 10 - connection of blocks with glue-foam and a vertical reinforcing element located in it, located in the through holes of the upper and lower blocks. FIG. 11 - connection of blocks with glue-foam and a vertical reinforcing element located in it in the through hole of the upper block and the blind hole of the lower block with conical sockets at the ends of the holes.

Building wall block 1 (Fig. 1) has the shape of a parallelepiped with a ridge 2 and a groove 3 on the opposite upper side 4 and lower side 5 of the block. In this case, the block consists of three monolithically interconnected layers: the front layer 6 located on the front side of the block, the back layer 7 located on the back side of the block, and also the intermediate layer 8 located between the front and back layers. The intermediate layer has a porous structure. The groove 3 and the ridge 2 are located in the face layer 6 of the block.

The intermediate layer of the block contains fillers with a low bulk density - expanded clay gravel, granulated foam glass, vermiculite, perlite and / or dispersed fiber-reinforced concrete and a binder - in different combinations and ratios of these components. In this case, the intermediate layer of the block has pores - voids and cavities within 1.0-5.0 mm and more, depending on the dimensions of the block.

The front layer of the block contains quartz and / or expanded clay and / or foam glass sand, granite and / or stone chips, cement, plasticizer, fiber fibers, glass fiber concrete, plates made of natural or artificial stone or porcelain stoneware, crushed expanded clay, gypsum mixtures, dyes, mineral and / or synthetic additives, while the groove and the block ridge are located in the face layer of the block, a hyper-pressed slab, painted over in the mass of sand concrete, gypsum mixtures, dyes and other mineral and / or synthetic additives - in different combinations and ratios of these components.

The back layer 7 in composition contains fillers: sand, cement, plasticizer. The surface of the back layer is made conditionally smooth, with pores for finishing, it is facing the side of the building.

The length L of the block has a range of 0.1-4.0 m, the width S of the block has a range of 0.08-0.60 m, and the height H has a range of 0.1-0.60 m.The dimensions are related to the bearing capacity of each block ...

In the manufacture of blocks in the composition of the mixtures of all layers of the block introduced such reinforcing elements as fiber 9 to prevent cracks in the block.

The block has parallel and symmetrically located horizontal grooves 10 and 11 located on the upper and / or lower sides of the block at the same distance from the longitudinal plane of symmetry of the intermediate layer of the block. On the lateral sides of the block, vertical grooves 12 and 13 are made, communicated at the corners of the block with horizontal grooves 10 and 11. The vertical grooves 12 and 13 are located symmetrically at the same distance from the longitudinal plane of symmetry of the block. Each said groove communicates with the pores of the block intermediate layer.

The grooves 12 and 13 form, when two adjacent blocks are connected horizontally, channels 14 (Fig. 2), filled with an adhesive composition such as glue-foam, with the properties of its expansion and growth in the pores of the intermediate layer of the block during curing. The adhesive composition, in addition to the functions of gluing, has the properties of sealing vertical and horizontal joints between blocks.

Each longitudinal groove is located in the same plane with a vertical groove, while each horizontal groove communicates at the corners of the block with its corresponding adjacent vertical groove.

Each groove of the block has the shape of a semi-oval, semi-circle, rectangular or trapezoidal tray in cross-section. The longitudinal grooves are designed to accommodate the adhesive composition and the longitudinal reinforcing elements located in it.

In the presented example of the execution of the method used as the specified adhesive composition, glue-foam. As the specified composition can also be used any other liquid mixtures having properties of expansion during their curing, growth in the pores and voids of the structure of the connected blocks and adhesion to the blocks. As an adhesive composition, polyurethane foam or a fluid mass of a binder can be used, which has the properties of adhesion of blocks to each other due to the adhesive properties of a fluid mass, which, when the blocks are adhered, expands in its volume and fills the pores of the intermediate layers of adjacent blocks. The adhesive composition, in particular the foam adhesive 15, conventionally shown in FIG. 6 and other figures in multiple dots.

The block has at least one pair of through vertical holes 16 and 17 (Fig. 1), located on longitudinal or transverse lines along or across the block symmetrically from the center of the intermediate layer of the block. The holes are located along the block height, symmetrically from the edges of the block intermediate layer. In the particular case presented in this description, these holes are located on the longitudinal axis 18 of the intermediate layer of the block (Fig. 1). The center of each hole in the block is located on the axis 18 at a distance from the center of the block 0.25L, where L is the block length. To ensure reliable connection of the masonry with an increase in the width S of the block, the number of through holes can be increased from two to six or more holes. The diameter of each hole in the block is in the range of 8.0-24.0 mm for the reinforcing elements located in them, having diameters in the range of 6.0-22.0 mm.

In one embodiment of the block, vertical through holes 16 and 17 are made with tapered sockets 19 at the ends (Figs. 9, 11) to facilitate the introduction of reinforcing elements into the holes, as well as for the location of the hardened mass of glue-foam 15 in them, which is shown by many points in fig. 6, 8-11. Adhesive foam is injected into grooves 10 and 11, channels 14, bells 19 and holes 16,17 with a nailer through an elongated nozzle 20 shown in FIG. 2. The grooves 10 and 11 are designed to accommodate the adhesive foam and longitudinal reinforcing elements 21 in the adhesive foam (Fig. 4). When laying the walls and connecting the blocks to each other, a non-woven fabric 22 made of elastic fibers is used (Fig. 4). In the case of the introduction of the glue-foam into the horizontal grooves after the location of the longitudinal reinforcing elements 21 in them, they are closed with the glue-foam tracks 23 during the laying of the wall. Blocks 1 in a vertical position are connected by a cured foam adhesive and vertical reinforcing elements 24 located in it (Fig. 4).

At the ends of the holes in the sockets 19 (Fig. 9, 11), the cured adhesive composition, when cured, encompasses the ends of vertical reinforcing elements 24 joined together and represents a coupling 25 at the joints.

Holes 16 and 17 of some blocks can be made blind, and other blocks connected to them can be through, and in one block one of its holes can be made blind, and the other hole can be made through (Fig. 8). The specified versions of the blocks are associated with the block connection diagrams when laying the walls of buildings.

The method of connecting a block with adjacent wall blocks is intended exclusively for connecting blocks, the design of each of which is identical to the structure of the above-described block and the block presented in the analogue of the patent RU 2465415 C1, as well as in the analogue of the method described in the patent RU 134556 U1, from which it follows, that the intermediate (heat-insulating) layer of the block is made porous with pores sufficient for the glue composition to grow in them during the connection of the blocks.

The method is explained by the sequence of actions and the use of such an adhesive composition as glue-foam with a selected coefficient of its volumetric expansion during curing.

When implementing the method, first the first lower row of blocks 1 is laid without gaps between their lateral sides (Fig. 4), while in the process of laying the first row of blocks they are connected to the foundation in a known manner.

When the vertical grooves 12 and 13 of one block 1 are aligned with the vertical grooves 12 and 13 of another similar block 1, channels 14 (Fig. 2) are formed between the contacting lateral sides of adjacent blocks. These channels 14 are filled under pressure with an adhesive composition, in particular with foam glue 15, through the nozzle of the assembly gun.

Next, the horizontal grooves 10 and 11 of the blocks of the lower row are filled with glue-foam, a pair of reinforcing elements 21 is selected, the length of each of which corresponds to the length of the stacked row of blocks of the lower row, and these reinforcing elements 21 are placed in a horizontal position in the glue-foam located in the horizontal grooves 10 and 11 of the lower row of blocks (Fig. 3). In another case, reinforcing elements are first placed in the grooves of the blocks of the lower rows, and then these elements are closed with tracks 23 of adhesive-foam (Fig. 4).

Each elongated reinforcing element 21 is selected such that it has a cross-sectional area less than or equal to the cross-sectional area of one horizontal groove of the upper row of blocks and the cross-sectional area of another horizontal groove of the blocks of the lower row.

Further, between the horizontal reinforcing elements 21 along the entire length of the laid lower row of blocks, a non-woven fabric 22 made of elastic fibers is placed and after that the blocks of the upper row are placed on the blocks of the lower row with an offset equal to half the length of the lower block.

When laying the upper row of blocks on the lower row of blocks, the vertical holes 16 and 17 of the blocks of the lower and upper rows are aligned due to the fact that each hole in the block is located at a distance from the center of the block equal to 0.25L, where L is the block length.

At least one vertical through hole of the upper row unit is injected under pressure with adhesive foam until it completely fills the upper row unit hole and until it fills the lower row unit hole. Then the element 24 is immersed in the adhesive foam located in the hole of the upper row. The reinforcing element 24 is introduced into the glue-foam located in the hole of the lower block until the element is completely or partially immersed in the glue-foam and until the upper end of the reinforcing element 24 is flush with the plane of the upper block (Fig. 8).

In this position, the reinforcing element 24 is surrounded by adhesive foam, which, when solidified, begins to grow into the pores of the intermediate layers of the blocks to be joined. After curing of the glue-foam, it turns into a solidified tube firmly put on the reinforcing element 24, gripped with the reinforcing element 24 and the arrays of intermediate layers of the blocks to be connected and at the same time being in a compressed position between the blocks.

In another case, in the process of connecting the blocks with vertical reinforcing elements 24, first the elements 24 are introduced into the holes of the upper and lower blocks, and then the adhesive foam is injected under pressure into the gaps between each vertical reinforcing element 24 and the wall of each vertical opening of the blocks to be connected. Adhesive foam is introduced into the specified gaps until the gaps are completely filled with glue foam.

Vertical reinforcing elements 24 are installed in subsequent rows of blocks in the holes of the previous row. Each vertical reinforcing element 24 is selected to have a cross-sectional area equal to or less than the cross-sectional area of the opening of each block of the upper and lower rows of blocks.

In the process of hardening, the adhesive foam expands most effectively in the pores of the expanded clay intermediate layers of the blocks, in which the reinforcing element 24 is located, by its germination, while the adhesive foam adheres to the elements 24 so that it creates permanent joints of the upper and lower blocks.

The holes 16 and 17 of the block and the channels 14 between the blocks are filled under pressure with glue-foam 15 by means of an elongated nozzle (Fig. 2) of an assembly gun.

If the holes of the blocks are made through, then the vertical reinforcing elements 24 are installed in the subsequent rows of blocks in the holes of the previous row so that the adjacent ends of a pair of vertical reinforcing elements 24 are located end-to-end with respect to each other, as shown in Fig. 9. With such a joining scheme, the hardened adhesive foam tightly fixes the ends of the reinforcing elements 24 in the conical sockets 19 of the blocks, while the array of hardened adhesive foam in the sockets of the block holes acts as a rigid coupling 25, firmly connecting the ends of the upper and lower reinforcing elements 24, having reinforcing screw-shaped hooks in the form of coils.

Adhesive foam is introduced into holes 16 and 17 through the bell of each block into the gap between the vertical reinforcing element 24 and the wall of each vertical hole 16 and 17 of the block in the case when reinforcement elements 24 are first placed in the holes 16 and 17. In this case, the adhesive foam 15 is introduced into the gap until the specified gap is completely filled with adhesive foam.

When the reinforcing elements 24 are positioned end-to-end in relation to each other (Fig. 9) in the sockets of the holes of the blocks located at the ends of the holes, the ends of the elements 24 are fixed in the sockets 19 filled with cured glue-foam, and firmly enclosed by it in the volume of two butted sockets 19. In the sockets of the two connected blocks, a double-cone sleeve 25 of hardened glue-foam is essentially formed, expanding along the junction line of the elements 24 - the most loaded place from displacement or bending loads on the connected blocks. At the junction of the two reinforcing elements 24, the sleeve 25 prevents the blocks from being pulled apart from each other in the vertical direction. During the curing of the adhesive foam and after its growth in the pores of the intermediate layers of the connected blocks, the sleeve 25 in the conical bells 19 is in a compressed state in the closed volume of the bells.

During the curing process, the adhesive foam expands and grows into the pores of the blocks to be connected, while it encompasses the reinforcing elements 24 and seizes with the spiral hooks of the elements so that it creates permanent connections of the reinforcing elements and the reinforced blocks.

In the process of masonry, mainly composite reinforcement based on beams of fiberglass impregnated with epoxy resin, having spiral hooks on the outer surface, is used as reinforcing elements.

If the blocks of the lower row have blind holes with a depth of 0.3-0.5H, where H is the height of the block, and the blocks of the upper row have through holes, then the length D of each reinforcing bar 24 for connecting the blocks of the upper and lower rows is chosen depending on the depth of the hole of each lower block, D = H + (0.3-0.5) H. In this case, the reinforcing elements do not fit together - they are located in the blocks of the building wall as shown in Fig. 8. At the same time, the hardened glue-foam in the holes of the blocks turns into strong tubes, significantly strengthening the joints of the blocks of the lower and upper rows.

The block and its connection with adjacent blocks work as follows. When the wall perceives bending, shear or shear loads in the horizontal and vertical directions, the loads from the interconnected blocks are transferred to the reinforcing elements, which perceive them and redistribute them to adjacent blocks. As a result, the resistance of the wall to the specified loads increases significantly, and the strength of structures such as houses and cottages with a reduced number of storeys in the zone of seismic effects increases.

Reinforcement of the walls of buildings has the greatest effect if the walls of buildings are reinforced with composite reinforcement, each rod of which has the properties of significant elasticity - restoring the straightness of the rod in the event of its bending. At the same time, the adhesive foam in combination with the epoxy resin of the composite aroma has the highest bond strength with the surface of the composite reinforcement covered with a layer of epoxy resin. In the case of reinforcing the walls of buildings with composite reinforcement, such walls, which have elastic reinforcing elements, have elastic properties and, in the case of bending of the walls from the specified loads within the established limits, the walls have the ability to self-restore them to the design position. The use of the presented earthquake-resistant blocks of the described design and the method of connecting blocks with adjacent blocks makes it possible to use them in the construction of buildings in areas with increased seismicity.

Claims (9)

1. A building wall block, characterized in that it contains a front and back layers, between which there is an intermediate layer, a groove and a ridge in the front layer of the block on opposite lower and upper sides, the layers of the block have porous structures and are monolithically interconnected, in the intermediate the layer of the block, which has pores more than the pores of the front and rear layers of the block, there are longitudinal and vertical grooves connected with the pores of the intermediate layer for the flowable adhesive composition located in them, while the longitudinal grooves are connected with the vertical grooves at their convergence points at the corners of the block, the vertical grooves are located on the lateral sides of the block, longitudinal grooves are located on the lower and upper sides of the block, longitudinal grooves are made for longitudinal reinforcing elements and adhesive composition freely located in them, vertical grooves are made to form cavities between adjacent blocks for an adhesive composition located in them, connecting the side walls the sides of adjacent blocks, and along the block height in its intermediate layer there are vertical holes communicated with the pores of the intermediate layer for the adhesive composition freely located in them and vertical reinforcing elements located in it, the holes are located symmetrically with respect to the longitudinal and transverse planes of symmetry of the block, while the width of each groove and the diameter of each hole are in the range of 8.0-26.0 mm, and the depth of each groove is in the range of 4.0-13.0 mm. 2. Building wall block according to claim 1, characterized in that each longitudinal and vertical groove has a semi-oval or semicircle shape in cross section, or a rectangular recess shape, or a trapezoidal recess shape, and each end of the block opening has a conical bell-shaped expanding outwardly located in the intermediate layer of the block. 3. The building block according to claim 1, characterized in that the grooves and vertical holes are made in the intermediate layer containing expanded clay gravel, granulated foam glass, vermiculite, dispersed fiber-reinforced concrete, which are impregnated with a binder material. 4. Building wall block according to claim 1, characterized in that the length L of the block is set within 0.1-4.0 m, the width S of the block is within 0.08-0.6 m, and the height H of the block is in within 0.1-0.6 m. 5. A method of connecting a building wall block with adjacent blocks of a wall, characterized by the fact that blocks with a porous structure are used to connect them to similar adjacent blocks with an adhesive composition that has the properties of its germination in the pores of the blocks to be connected, adhesion of the blocks and pressing them to each other during the curing of the adhesive compositions, while first the lower row of wall blocks is laid, then an adhesive composition is applied to the blocks of the lower row and the blocks of the upper row are laid on it, blocks with horizontal grooves on the lower and upper sides of the block, with vertical grooves on the sides of the block and with at least one pair of vertical holes in each block, then the blocks of each row of wall blocks are joined together by their lateral sides without gaps between them, and after joining, the adhesive composition is injected into the vertical channels between adjacent blocks formed after aligning the vertical grooves of adjacent blocks y, and in the horizontal grooves of the upper row of blocks, extended longitudinal reinforcing elements are placed, which are closed with tracks of the adhesive composition, then the blocks of the upper row are placed on the blocks of the lower row and at the same time the vertical holes of the blocks of two rows are combined, after which they are filled from top to bottom under pressure with an adhesive composition. vertical holes of the blocks and after that vertical reinforcing elements are introduced into the aligned holes of the blocks until they are completely or partially immersed in the holes of the blocks to be connected and until the end of each reinforcing element is flush with the plane of the upper block, then the described cycle of connecting adjacent blocks is repeated. 6. The method according to claim 5, characterized in that between the longitudinal reinforcing elements a non-woven fabric made of springy fibers is placed in the form of a strip. 7. A method according to claim 5, characterized in that each vertical reinforcing element is selected with a cross-sectional area equal to or less than the cross-sectional area of the opening of each block of the upper and lower rows of blocks. 9. The method according to claim 5, characterized in that each horizontal reinforcing element is selected with a cross-sectional area equal to or less than the cross-sectional area of the two aligned longitudinal grooves of the upper and lower blocks. 10. The method according to claim 5, characterized in that composite reinforcement based on fiberglass bundles impregnated with epoxy resin is used as reinforcing elements.

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