RU137566U1 - BUILDING UNIT (OPTIONS) AND WALL Masonry - Google Patents

Abstract

1. A building block for spoon masonry, the basis of the formation of which is a rectangular parallelepiped, with spoon, poke and bed faces, provided with at least one through vertical hole in the body of a rectangular parallelepiped from the side of one spoon face, while on each bonded face perpendicular to the bed faces, at least one recess is formed which is capable of forming, when laying together with the corresponding recess of an adjacent building block, an additional of a vertical hole, characterized in that one spoonful face is made in the form of a part of a rectangular parallelepiped, in which at least one through hole is made and which is connected by a jumper to another part of a rectangular parallelepiped, in which a groove is opened along the spoon face, open from the side one bed side and from the side of the butt faces and made with all flat walls or with flat side walls and a bottom on which transversely arranged protrusions are made. 2. The block according to claim 1, characterized in that it is provided with a liner of heat-insulating material that is placed in at least one through hole and repeats the shape of the through hole in the body of a rectangular parallelepiped and is made with a height equal to the height of this through hole or greater than the height a through hole to the thickness of the horizontal seam of the masonry mortar. 3. The block according to claim 2, characterized in that the liner is made solid or hollow in the form of a thin-walled shell or in the form of a tubular element. The block according to claim 1, characterized in that the well

Description

The utility model relates to the field of construction, namely to the construction of wall masonry from large-format building blocks or bricks having a large number of through voids in the body, and can be used in the construction of external load-bearing walls of buildings and structures.

Large-format ceramic blocks with various options for internal partitions and a large number of them along the length and width of the block are currently being produced on the market. Such blocks have only through voids. Multi-hollow stone or silicate blocks made by the same technology are on the market. This technical solution is aimed at forming a longer path of heat flow inside the block, and air in the through voids is used as a natural heat insulation inside the blocks. There are blocks that show good thermal conductivity and can be suitable even for laying single-layer walls. But large-format blocks also have a drawback: the design of all blocks is such that with spoon laying in any case 1: 1 or 1: 2 or 1: 3/4 always leads to the formation of a cold bridge in the horizontal masonry joint, which negates all the advantages of such blocks, making the wall freezing / warming up and low heat-efficient.

A known building block with through vertical voids of rectangular cross section, in which heat-insulating liners are installed (RU 2352733, publ. 20.04.2009).

The presence of through holes in the building block provides a sufficiently high percentage of voidness, which allows the block to perform both structural and heat-insulating functions in the outer walls of buildings, leading to a reduction in energy consumption for heating buildings. However, the arrangement of the rows of through holes of such a building block causes its increased thermal conductivity in both the poke and spoon directions of the heat flow, and reduces the thermal properties of the building block in the outer 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 the hole of one to be combined with 1/2 or 2/3 of the brick hole below or top 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.

Another disadvantage of this unit is that it cannot be used to form horizontal concrete power belts in masonry and in areas of formation of openings for windows and doors or walkways. A building block with voids can be the size of a standard brick. But all the advantages of a hollow block are manifested with an increase in its size, which allows you to form a large block masonry with pronounced channels and a long path of heat flow. But for such a masonry, the organization of power jumpers - inserts over openings becomes problematic.

The technical result of the utility model is to increase the operational properties of a building block with masonry from such building blocks by providing the possibility of forming power jumpers and horizontal stiffening belts in the masonry directly in the body of the building block.

The specified technical result is achieved by the fact that in the building block for spoon masonry, the basis of the formation of which is a rectangular parallelepiped, with spoon, poke and bed edges, provided with at least one through vertical hole in the body of the rectangular parallelepiped from the side of one spoon face, at the same time, on each bonded face perpendicular to the bed faces, at least one recess is formed, which is possible to form when laying together with the corresponding with a recess of an adjacent building block of an additional vertical hole, one spoon face is made in the form of a part of a rectangular parallelepiped, in which at least one through hole is made and which is connected by a jumper to the other part of the rectangular parallelepiped, in which a groove is opened along the spoon face, open from the side one bed face and from the side of the bonder faces and made with all flat walls or with flat side walls and a bottom on which are transversely arranged suspended protrusions.

The specified technical result is achieved by the fact that in the building block for spoon masonry, the basis of the formation of which is a rectangular parallelepiped, with spoon, poke and bed edges, provided with at least one through vertical hole in the body of the rectangular parallelepiped from the side of one spoon face, at the same time, on each bonded face perpendicular to the bed faces, at least one recess is formed, which is possible to form when laying together with the corresponding with a recess of an adjacent building block of an additional vertical hole, one spoon face is made in the form of a part of a rectangular parallelepiped, in which at least one through hole is made and which is connected by a jumper to the other part of the rectangular parallelepiped, in which a groove is opened along the spoon face, open from the side one bed face and from the side of the bonder faces and made with all flat walls or with flat side walls and a bottom on which are transversely arranged protrusions, while in the jumper a through hole is made, made along the length along the bed edge equal to the sum of the depths of the recesses on the bonded faces and the thickness of the seam of the masonry mortar between adjacent building blocks.

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 first example of a building block;

FIG. 2 - a second example of a building block;

FIG. 3 is a third example of a building block;

FIG. 4 is a fourth example of a building block;

FIG. 5 is a fifth example of a building block;

FIG. 6 - the sixth example of the construction block;

FIG. 7 is a seventh example of a building block;

FIG. 8 is an eighth example of a building block;

FIG. 9 - wall masonry with the organization of horizontal stiffeners along the rows of masonry with one reinforcing element in the groove;

FIG. 10 - wall masonry with the organization of horizontal stiffeners along the rows of masonry with three reinforcing element in the groove

FIG. 11 - wall masonry with the organization of horizontal stiffeners along the rows of masonry with four reinforcing element in the groove before pouring concrete;

FIG. 12 - masonry with the organization of horizontal stiffeners along the rows of masonry in the embodiment with three and four reinforcing elements in the groove after pouring concrete.

According to the present invention, the construction of a building block (Fig. 1-8) or a brick with voids for spoon masonry is considered, which is a rectangular parallelepiped in shape with two spoon 1, two poke 2 and two bed 3 faces. In the body of such a block, at least one or two vertical through holes 4 are made of square or rectangular or round or other shape (oval or polygonal) in plan. At least one recess 5 is formed on each of the bonded faces perpendicularly to the bed faces to form, when spoon laying, together with the corresponding recess of the adjacent block, one vertical hole (as shown in Fig. 9). At the same time, at least one of the recesses on the bonding faces is made through, and the vertically directed holes in the block are arranged in rows, some of which are located opposite the recesses.

A feature of the shape of the hole 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. This is due to the fact that when masonry two adjacent building blocks can be joined to each other through a mortar layer 15 (the seam is shown in Fig. 9) both on the butt faces and on the butt face of one building block and of the spoon face of another building block.

Another feature of the building block is that its voids (through holes 4) are designed to form vertical channels in the masonry, 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 1/2 laying offset allow vertically oriented channels to form.

When using the proposed building block in the outer walls, the direction of the heat flux is perpendicular to the spoon face. The heat flux, crossing the block body in the spoon direction, passes along a curved path, while gradually losing its strength and, as a result, the heat transfer intensity is guaranteed to decrease to the thermal conductivity values for the selected construction region. Due to the implementation on the bonded faces of the recesses 5 forming blocks of the subsequent row from the top when the spoon is laid, overlapping 1/2 block in the underlying row with the adjacent block, the through void equal to the through void 14 (Fig. 1, Fig. 2.) is guaranteed to eliminate the disadvantage of many building structures blocks, which consists in the possibility of formation during the laying of cold bridges.

High heat-insulating properties of the building block and wall masonry from such blocks are ensured by introducing into the through holes heat-insulating inserts 6, which are guaranteed to break the cold bridge in the direction from the outer surface of the wall to the inner one.

A feature of this building block is that it can be equipped with inserts 6, repeating the shape of the through hole in the body of a rectangular parallelepiped and made with a height equal to the height of this through hole. Such inserts 6 can be inserted into all the through holes in the body of the unit or only to part of them (Fig. 3). The inserts 7 shown in FIG. 4 and FIG. 8 repeating in shape the shape of the through hole in the body of a rectangular parallelepiped and made with a height equal to the height of this through hole plus a height equal to the thickness of the horizontal masonry seam specified by the project (usually 8-15 mm). When laying, the insert 7 is also inserted into the newly formed void by recesses 5 of two neighboring blocks in a row horizontally (Fig. 9-12) that are formed with spoon masonry when the recess on the bonded edge of one building block adjoins the recess of an adjacent stacked building block.

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 liner is made of insulating material or insulating material.

In the process of laying holes in the building blocks, whole (or partially broken, but interconnected) vertical rows can be formed in the form of certain geometric figures in the form of single heat and sound insulating posts over the entire height of the wall. These holes, if they are not filled with inserts, can be used to backfill bulk insulation: expanded clay, vermiculite, chips of foam glass, polystyrene foam, expanded polystyrene, expanded polystyrene, etc., or to reinforce masonry with reinforcing elements, to connect rigid heaters in the vertical channels of the end-to-end walls , without penetration of masonry mortar / glue.

During the laying process, through vertical holes and grooves of blocks can be formed through vertical channels to the entire height of the wall. These channels can be used for laying communications - electrical wiring, pipes, telephone cables, etc. The purpose of these channels can be taken into account during 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).

A feature of the considered building blocks is that in the building block according to the first embodiment (Fig. 1-4), one spoon face is made in the form of a part of a rectangular parallelepiped, in which at least two through holes 4 are made and which is connected by a jumper 8 to the other part of a rectangular parallelepiped, in which a groove is made along the spoon face 9. This groove 9 is made open from the upper side of the bed face of the block (upper from the side of laying the masonry mortar) and from the side of one or both of the pokes O faces. The groove 9 can be made with all flat walls, as shown in FIG. 1, or with flat side walls and a bottom on which transversely arranged protrusions 10 are made (Figs. 3-4), or with vertical protrusions on the side walls 11 and a bottom on which transverse protrusions are made 10. This groove 9 is used for laying concrete 12 (Fig. 9) (masonry mortar or special reinforcing concrete mixture) to form a horizontal stiffening belt 13, organized along a number of masonry in the masonry itself in Fig. 9-12. This groove 9 is also used for laying reinforcing elements 14 and 15 of FIG. 9 for forming a reinforced concrete stiffening belt. These reinforcing vertical elements 14 and horizontal elements 15 are stacked in compliance with the requirements of the distances to the bottom and side walls of the block to form a reinforced concrete element in the groove 9 of the block (Fig. 1-4).

In the block according to the first embodiment (Fig. 1-4), to fulfill the condition of combining the through holes vertically with a row of masonry with overlapping ½ in the higher stacked block, the hole 14 is made along the length along the bed edge equal to the sum of the depths of the recesses 5 (equal to or not equal) on the bonded faces plus the specified thickness of the vertical seam 16 (Fig. 9) of the masonry mortar between adjacent building blocks.

A feature of the considered building blocks is that in the building block according to the second embodiment (Figs. 5-8), one spoon face is made in the form of a part of a rectangular parallelepiped, in which at least one through hole 4 is made and which is connected by a jumper 17 to another part of a rectangular parallelepiped, in which a groove 9 is made along the spoon side, open from the side of one bed side and from the side of the butt faces and made with all flat walls or with flat side walls and ohms, which is provided with transversely extending projections. This block can be executed in length equal to half the block according to the first embodiment. Using the block of FIG. 5-8 are the same as those considered with respect to the block according to the first embodiment of FIG. 1-4.

The building blocks of FIG. 1-8 are intended for masonry in a single row, sequentially presented in FIG. 9-12. Rows are obtained only spoon. Transverse vertical seams 16 of each upper row overlap with blocks of the other row 1/2 block in the spoon rows. Blocks in dimensions can have both square and rectangular shapes. Blocks are connected using various building mixtures or adhesives (masonry mortar, mortar). In the process of laying holes in the building blocks, whole (or partially broken, but interconnected) vertical rows can be formed in the form of certain geometric figures in the form of single heat and sound insulating posts over the entire height of the wall.

For the construction of spoon masonry, building blocks are used, the description of which was given earlier in FIGS. 1-8. In the General case, such a building block is made in the form of a rectangular parallelepiped with spoon, poke and bed faces, with at least one through vertical hole in the body of the rectangular parallelepiped and with at least one recess on each poke face made with the possibility of formation when laying together with the corresponding recess of the adjacent building block of an additional vertical hole. Also for laying use liners.

The formation of wall masonry consists of placing on the supporting surface of the base row interconnected masonry mortar through the bonded edges of the building blocks, in which the notch on the bonded edge of one building block forms an additional vertical hole with the corresponding hollow of the adjacent building block.

In this case, the building blocks are placed in a row so that the spoon face of the blocks along which the groove 9 is made is always located on one side of the masonry. This makes it possible to form in the masonry row the message of the groove cavities of all building blocks in one row and to obtain a long lodgement for laying horizontally and vertically into the cavity of the grooves of the reinforcement 14 of FIG. 9 and pouring it with a strengthening solution (concrete). After hardening, a reinforced horizontal monolithic reinforced concrete element 13 forms, forming a common stiffening belt for masonry, connecting all the blocks in a row in a horizontal plane.

Such reinforced concrete masonry reinforcing masonry belt 13 can be organized both completely in the entire horizontal plane of the masonry row, and locally on part of the length of the spoon row, for example above the opening. Such short-sized reinforced reinforced concrete stiffening belts can be arranged in any order along the length of each spoon row from the blocks of Figs. 1-8.

In FIG. 9 shows wall masonry with the organization of horizontal reinforced concrete reinforced stiffening belts along rows of masonry with vertical reinforcing elements 14 in a groove in the form of a horizontal single reinforcing element 15.

In FIG. 10 shows the masonry with the organization of horizontal reinforced concrete reinforced stiffening belts along the rows of masonry with vertical reinforcing elements 14 and horizontal reinforcing elements 18 in the form of three connected reinforcing elements in a groove.

In FIG. 11 shows the masonry with the organization of horizontal reinforced concrete reinforced stiffening belts in rows of masonry with vertical reinforcing elements 14 and horizontal reinforcing elements 19 with four reinforcing element in the groove before pouring concrete.

In FIG. 12 shows the masonry with the organization of horizontal stiffening belts along the rows of masonry in the embodiment with three reinforcing horizontal elements 18 and horizontal elements 19 of the connected four reinforcing elements and with reinforcing vertical elements 14 in the groove after pouring concrete.

For each stacked spoon row in the masonry, the next row can be the same as stacked, that is, with a belt or stiffening belts, or it can be made of building blocks that do not carry grooves (for example, such as those described in RU 120115 or RU 121838).

When using inserts 6 equal to the height of the through hole, the masonry mortar overlaps these inserts. And when using liners 7 (Fig. 4, Fig. 8, Figs. 9-12) equal to the height of the through hole plus the thickness of the masonry mortar, the liners are protruding by protruding parts in the masonry mortar, organizing complex connected heat flow paths already in the masonry mortar itself . Placing in at least part of the through holes of all or part of the building blocks of the liners 7, protruding above the bed faces of the blocks of the spoon row forms the condition for guaranteed retention of the thickness of the masonry mortar between the rows.

The application of this invention 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 allows 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 block body with the simultaneous formation of reinforcing stiffening belts in the horizontal direction of the masonry in the body of the blocks themselves.

Claims (11)

1. A building block for spoon masonry, the basis of the formation of which is a rectangular parallelepiped, with spoon, poke and bed faces, provided with at least one through vertical hole in the body of a rectangular parallelepiped from the side of one spoon face, while on each bonded face perpendicular to the bed faces, at least one recess is formed which is capable of forming, when laying together with the corresponding recess of an adjacent building block, an additional of a vertical hole, characterized in that one spoonful face is made in the form of a part of a rectangular parallelepiped, in which at least one through hole is made and which is connected by a jumper to another part of a rectangular parallelepiped, in which a groove is opened along the spoon face, open from the side one bed side and from the side of the butt faces and made with all flat walls or with flat side walls and a bottom on which transversely arranged protrusions are made. 2. The block according to claim 1, characterized in that it is provided with a liner made of heat-insulating material that is placed in at least one through hole and repeats the shape of the through hole in the body of a rectangular parallelepiped and is made with a height equal to the height of this through hole or greater than the height of the through hole by the thickness of the horizontal seam of the masonry mortar. 3. The block according to claim 2, characterized in that the liner is made solid or hollow in the form of a thin-walled shell or in the form of a tubular element. 4. The block according to claim 1, characterized in that the through vertical hole in the cross section has the shape of a triangle, or rectangle, or a polyhedron, or a circle, or an ellipse. 5. Block 1, characterized in that the walls of the through vertical hole are convex or the corners in the through vertical hole are rounded. 6. Building block for spoon masonry, the basis of the formation of which is a rectangular parallelepiped, with spoon, poke and bed faces, provided with at least one through vertical hole in the body of a rectangular parallelepiped from the side of one spoon face, while on each bonded face perpendicular to the bed faces, at least one recess is formed which is capable of forming, when laying together with the corresponding recess of an adjacent building block, an additional of a vertical hole, characterized in that one spoonful face is made in the form of a part of a rectangular parallelepiped, in which at least one through hole is made and which is connected by a jumper to another part of a rectangular parallelepiped, in which a groove is opened along the spoon face, open from the side one bed side and from the side of the bonder faces and made with all flat walls or with flat side walls and a bottom on which transversely arranged protrusions are made, while in the jumper Execute the through hole formed lengthwise along a bed faces equal to a sum of depths of the recesses on the faces of the binder and the thickness of the masonry mortar joint between adjacent spaced building blocks. 7. The block according to claim 6, characterized in that it is provided with inserts of heat-insulating material placed at least in the part of the through holes, repeating the shape of the through hole in the body of the rectangular parallelepiped and made with a height equal to the height of this through hole or greater than the height of the through hole by the thickness of the seam of the masonry mortar. 8. The block according to claim 7, characterized in that the liner is made solid or hollow in the form of a thin-walled shell or in the form of a tubular element. 9. The block according to claim 6, characterized in that the through vertical hole in the cross section has the shape of a triangle, or rectangle, or a polyhedron, or a circle, or an ellipse. 10. The block of claim 6, characterized in that the walls of the through vertical hole are convex or the corners in the through vertical hole are rounded. 11. Wall masonry containing in-line placement of building blocks, each of which is a rectangular parallelepiped in shape with at least one through hole in the body of this parallelepiped and with at least one recess on each bonded face and with a groove along in one row, the building blocks in each row are hollowed up and connected by a masonry mortar horizontally laid between rows and vertically in laid between the joined bonded faces of the building blocks in each row, characterized in that, in at least one row, at least on a part of its length, the building blocks are successively stacked with grooves on one side of the masonry and adjacent to each other through a masonry mortar vertically laid between the bonded butt faces of building blocks to form a long lodgement for filling with a reinforcing mortar or for laying reinforcement and filling with a reinforcing mortar.

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