CZ2011646A3 - Modular system for exact building development - Google Patents

Abstract

The modular system for precise construction is designed for fast and accurate realization of civil and industrial building. It consists of a set consisting of blocks (3, 4, 5, 6) in the shape of a cuboid of the same height (b), from the first basic block (3) with a square base of width (a), the second basic block (5) with a rectangular base (a) and width (c) smaller than the length (a), derived bricks (4, 6), and outer connecting strips (2) and inner connecting strips (22). Each base block (3, 5) is provided with at least three outer grooves (1) in its side walls over its entire height (b). The length of the derived blocks (4, 6) is determined to be at least twice the width (a). The derived blocks (4, 6) are provided with one inner groove (11) at their center along the entire height (b) and at least two and at most six outer grooves (1) in the side walls, with at most one outer groove in each shorter side wall (1) and in the longer side walls, there are at most two outer grooves (1). The outer connecting strips (2) and the inner connecting strips (22) are intended for self-locking engagement with the outer grooves (1) and the inner grooves (11).

Description

Technical field

The present solution relates to a system of accurate and rapid construction of walls without the necessity of using mortar mixtures or polyurethane foam for gluing the bed joints of building elements.

BACKGROUND OF THE INVENTION

Several methods of realization of structures based on the principle of dry masonry or gluing of building elements in one plane using rectangular grooves located in opposite side walls of the building elements are known from the practice. These grooves serve as guides to accurately connect the two side blocks in the wall body and serve to break the straight side joint of the adjacent blocks. One way of realizing buildings is a group of building elements characterized by a sandwich arrangement of a plurality of materials firmly joined together. An example of this design is a complete construction system for rough construction from Concrete constructions - Group s.r.o, which consists of thermal insulating blocks of internal bearing and non-bearing masonry, shuttering elements and ceiling structures. Wall panels are liaporbetónová sandwich blocks designed for single-layer peripheral bearing and filling masonry. The tongue and groove system is built into the sides only and is not self-locking in the wall body, thus ensuring only the connection of the blocks in one axis. This system does not eliminate the necessity of using mortar for loading joints under the actual walling. /

Another example of sandwich building elements is a self-supporting sandwich panel made by gluing OSB boards with an insulating foam polystyrene core. This system allows a high speed of construction. But the columns and girders made of solid wood are used for fixing within the walls. It does not have a built-in self-locking system of interconnection of individual panels and does not solve the preparation for installation of network distribution.

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Another way of realizing buildings is a group of shell building elements made up of one material. An example of this embodiment is concrete thin-walled shell blocks with rectangular locks on the side walls. These locks do not solve self-locking. The block is classic wall for concrete mortar, which must also be covered with locks on the sides. These blocks are mostly designed only for load-bearing walls, so they do not completely solve the shell construction. The blocks are connected to a separate sandwich insulation system, which is attached as part of the wall from outside or inside the load-bearing wall. Own blocks do not solve the preparation for the installation of network distribution, and these are, if possible, solved in the next sandwich layer.

Permanent shuttering systems are another way of realizing constructions. An example of this embodiment is expanded polystyrene building blocks which are inserted into each other by means of a special locking system, thus forming peripheral walls and partitions without the use of fasteners. The permanent shuttering thus constructed is filled with concrete and forms a compact wall. The fittings are not self-supporting and do not solve the network distribution. The bearing element itself has nothing to do with the fittings.

A separate group are drywall systems equipped with special locks in the form of concentric cylinders. An example of such a system is a dry brick block system, where the basic building blocks are lightweight concrete blocks that allow the construction of arbitrarily structured buildings. It is used primarily as load-bearing masonry of residential buildings and filling masonry of large-scale halls, for the construction of fences and walls. Using drywall fittings makes the construction faster and simple. The basic elements of the system are basic blocks and half blocks. The blocks are laid in the wall without any binder or sealant in vertical and horizontal joints. The fixing of individual blocks in the masonry and bracing of the wall as a whole is ensured by means of locks acting in all horizontal contact areas of the individual masonry layers. The locks form concentric cylinder-shaped depressions at the bottom of the block at the edge of the circular holes located in the block body. These bosses fit into the corresponding troughs on the upper side of the block at the edge of the circular holes located in the block body. These blocks cannot be arbitrarily placed on the bottom layer of blocks, but always in the given »w • · ♦ * rotation. The block does not solve the connection of partition walls or the installation of distribution systems. If the crimp is damaged by one block in the wall, the strength of the whole wall is damaged.

Another type of block designed for dry walling - KB Blok - has a molding in the longitudinal axis of the block on its upper side. The boss fits into this notch in the longitudinal axis of the block on its underside. These blocks do not allow universal adjustment of the blocks in the upper row within the wall with respect to the blocks placed in the lower row. The block does not solve the connection of partition walls or the installation of distribution systems. If the crimp is damaged by one block in the wall, the strength of the whole wall is damaged.

A solution according to patent CN 201040891 is known. This system consists of three basic types of blocks. Two types are fitted with vertical self-locking grooves only on the shorter opposite side walls of the block. One basic type of block is twice as long as the other basic type and has an internal groove formed centrally in the upper surface of the block. The depth of this inner groove extends to half the height of the block and a lock is inserted, which protrudes half its height above the base block. To align the wall, a second basic type of block of equal width and half length is used at the edge compared to the first basic block with vertical self-locking grooves over the entire height of the block located on two opposite side walls. This block is not anchored in the row by a vertical lock. Since the basic blocks for wall construction are fixed only in the middle in vertical self-locking grooves located on the shorter opposite side walls, the flatness of the wall cannot be ensured during construction. For horizontal connection of the blocks in a row and to ensure the flatness of the wall, two grooves are installed in the upper surface along the entire length of the block on both edges, in which several reinforcements are laid side by side across several blocks. Vertical locks are used in construction only in some parts of blocks, which can lead to worse strength of the built wall. In this way, walls can only be built with the width given by the width of the block. For turning the wall or building a corner, a special third basic block is used, which has three vertical self-locking grooves. One on the shorter side and two opposite each other on the longer sides so that the base block can be attached to them.

Another solution dealing with this area is a document

The system consists of four basic types of blocks with vertical self-locking grooves over the entire height of the blocks located on the shorter side walls. The system is working

M t ♦ · i * * »with one type of lock. The blocks in a row are connected horizontally by a lock. The lock is as tall as a block. Since the basic blocks for wall construction have vertical self-locking grooves only on the shorter opposite side walls, the flatness of the wall cannot be assured during construction. To vertically connect the blocks of the upper and lower row of the wall, the system uses the projections on the upper side of the blocks and their corresponding recesses on the lower side of the blocks. These protrusions and depressions also ensure the flatness of the built wall. In the longitudinal axis of the upper surface of the block, troughs are built over the entire length of the block. The trough is also built into the longitudinal axis of the upper surface of the lock. The trough is inserted reinforcement, which keeps the inserted key against vertical movements and mainly serves to turn the wall or to connect special corner blocks to the wall. Such a connection of the wall at the corners or at the turning points is not sufficient. Therefore, the strength of the wall is solved by reinforced concrete filling of internal vertical channels formed within the blocks.

A US patent is also known

Here the system consists of three basic types of blocks and two derived blocks with vertical self-locking grooves over the entire height of the blocks located on the shorter side walls. The system works with two types of internal locks. Both types of locks are self-locking on both sides and serve only for internal use within the built wall. Blocks in a row are connected horizontally by one type of lock. The locks are as high as the blocks. In addition, the two basic blocks have a vertical self-locking groove over the entire height of the block on the longer side wall in the middle or in its quarter. These grooves serve for lateral holding of two separate walls with a gap. Both walls are held by a second type of lock. It is thus a system similar to permanent shuttering with distance definition for reinforced concrete. The grooves on the sides of the walls cannot, by themselves, have a strength meaning, nor can they ensure the flatness of the connected walls. The wall is connected to the corner by a derived square-shaped block with two vertical self-locking grooves on two adjacent side walls of the block. Therefore, the wall corner cannot be bound using the system blocks.

The system in the US patent

551 consists of a basic block type and a separate lock. The block is fitted with vertical self-locking grooves on the shorter opposite side walls of the block and has an internal groove located in the middle in the upper surface of the block. The depth of this inner groove extends to • a quarter of the height of the block. Two horizontal self-locking grooves are placed symmetrically on one long side wall of the block. They serve to fasten the face plate, which has the dimensions of the side wall of the block and visually cleans the block on the outside of the wall. The system uses one type of lock having a height consisting of the height of the block and the depth of the internal groove. Since the basic wall blocks have vertical self-locking grooves only on the shorter opposite side walls and partly in the middle of the upper wall of the block, it is not possible to ensure sufficient wall flatness during construction. The system does not solve the construction of the corner and the connection of the side wall. Of these blocks, a wall of only one width can be built. The blocks can be placed within the wall just in a predetermined position, they are not universal.

U.S. Pat. No. 3,192,131 discloses a system comprising a basic type of block. The block is fitted with vertical self-locking T-shaped grooves on the shorter opposing side walls of the block and has an internal cylindrical groove positioned centrally in the upper surface of the block over the entire height of the block. The system works with two types of locks. The first type is a self-locking lock for horizontal connection of side-by-side blocks. The second type is a cylindrical lock with a fitting that connects vertically the blocks placed in rows above each other. The system does not allow blocking of the blocks and does not ensure the flatness of the wall. Of these blocks, a wall of only one width can be built.

The system described in U.S. Pat. No. 6,189,482 consists of three basic types of blocks. One type of block is fitted with two vertical narrow self-locking grooves over the entire block height located on the shorter side walls. The second type of blocks is also fitted with a pair of internal grooves located centrally in the upper surface of the block over the entire height of the block. This type of blocks allows to tie blocks in rows one above the other. The first type of blocks does not allow to tie the blocks in rows one above the other and can also serve to end the wall. The system uses one type of lock. To connect the wall to the corner or to turn the wall, use a third rectangular base block with two pairs of vertical self-locking grooves on the two opposite shorter side walls of the block, one pair of inner grooves located in the middle of the block walls over the entire height of the block and shifted to one half of this longer side wall. Blocks in a row are connected horizontally and vertically.

.....

always by means of a pair of narrow locks inserted in each side or center of the block through the loading gap to the half height of the upper blocks. Such a connection ensures a certain flatness of the wall, but does not guarantee sufficient bond strength of the blocks in all directions. Therefore, this system is preferably designed to reinforce a reinforced concrete wall structure using massive two centered holes over the entire height of the block.

In all of the above systems, the blocks can only be placed within the wall in a predetermined position. Of these blocks, a wall of only one width can be built. Blocks are not spatially versatile. They cannot be used when rotated by + -90 degrees around a vertical axis, and usually even when rotated 180 degrees around a horizontal axis.

SUMMARY OF THE INVENTION

The above-mentioned disadvantages are overcome by the modular system for precision construction according to the present invention. This system contains two basic and two derived blocks in the shape of blocks of equal height. The first base block always has one outer groove in one pair of opposed side walls and the second base block also has one outer groove in its shorter side walls. These outer grooves extend along the entire height of said block and are formed symmetrically about a plane of symmetry passing through the vertical axis of said and opposite side walls. For all blocks, at least one inner width of each outer groove in a plane parallel to the surface of the side wall in which it is formed is greater than its width in the plane of the surface of the side wall on the same cross-section. The derived blocks have an inner groove at their center for the tight fit of the inner connecting rails for self-locking connection, which is formed symmetrically about a plane of symmetry passing through the vertical axes of the shorter side walls and corresponds in shape and size to the two outer grooves of the two blocks. consecutive stacking in a row. It is an object of the invention that the first base block has a square base of side width (a) and is provided on one and / or the other side wall of the second pair of opposite side walls with one outer groove formed all along its height symmetrically about a plane of symmetry passing through the vertical. the axis of the given and opposite side walls. The first derived block derived from the first basic block has a rectangular base of side width (a) and length (2a). The inner groove in the center of the base of the first derived block is formed over the entire height (b). The first derived block is provided with at least two and a maximum of six outer grooves along its entire height. In each of its shorter side walls, there is at most one outer groove symmetrically about the symmetry plane passing through the vertical axis of the given and opposite shorter side walls, and in the longer side walls there are at most two outer grooves formed symmetrically around the planes of symmetry parallel to the shorter side walls. The outer grooves are spaced (a / 2) from the shorter side walls and the planes of symmetry are spaced apart in width (a). The second base block has a rectangular base with a side length (a) and a width (c) of less than (a) and is provided with one outer groove on one and / or the other longer side wall. This outer groove is formed along the entire height of the second base block symmetrically about a plane of symmetry passing through the vertical axis of the given and opposite longer side walls. The second derived block, starting from the second base block, has a rectangular base with a side length (2a) and a width (c) of less than (a). The inner groove in the center of its base is formed over its entire height. This second derived block is provided with at least two and at most six outer grooves over its entire height. In the shorter side walls, there is at most one outer groove symmetrically about the symmetry plane passing through the vertical axis of the given and opposite shorter side walls, and in the longer side walls there are at most two outer grooves formed symmetrically around the symmetry planes parallel to the shorter side walls. The outer grooves in the longer side walls are spaced (a / 2) from the shorter side walls, the planes of symmetry being spaced apart in width (a). The system also includes external connecting strips for tight fit into the outer grooves (1) for self-locking connection.

In a preferred embodiment, the outer and inner connector strips to be used in the two lowest rows and the two highest rows of the wall have a height (x + 1/2) b, where x is an integer positive including zero. The outer and inner rails for use in other rows have a height yb where y is a positive integer.

Within the same block, not all outer grooves need to be identical in shape and size. Thus, it is possible that the at least one outer groove has different dimensions and / or a different shape from the remaining outer grooves. A sufficient condition for the correct use of such blocks is that the adjacent external and internal grooves within the wall have the same shape and the same dimensions.

The inner connecting strip, intended to connect two adjacent grooves made of different dimensions and cross sections, is symmetrical on each of its cross sections only on one axis.

The basis of the new solution is the principle of self-locking joining of building elements, blocks, within the wall by means of a system of grooves and connecting rails inserted into them so that the ends of the joining rails are located other than on the lower and upper side of the blocks. The blocks are fixed to each other within the wall in the space in all three axes. This results in a better connection of the blocks to each other in the space by means of several connecting surfaces, while at the same time ensuring the dimensional and angular accuracy of the walls being built. Appropriate groove shapes and suitable placement within the used blocks serve for better connection of blocks within the wall. For the system of joining the blocks by means of grooves and connecting strips, it is not essential to what material the grooved blocks and connecting strips are made in particular.

Both basic and derived blocks are characterized by their ground plan dimensions and well-defined placement and number of vertical self-locking outer grooves on the side walls and inner grooves in the center of the block and using two types of vertical connecting rails in a row next to each other, so the vertical interconnection of blocks in rows above each other. The advantage of the solution is the spatial universality of the blocks, which can be used in the building when rotated by + -90 degrees around the vertical axis or even when rotated 180 degrees around the horizontal axes. Thanks to these properties, a wall can be built in which one layer of blocks is aligned with a longer side wall, and in the next layer the blocks are stacked together with shorter side walls in two rows side by side and still moving one row half the block compared to the other row. This leads to the interlocking of the blocks within the walls being built. The system does not need any special blocks for building wall corners and the corners are always tied together. The same is true with the option of turning the load-bearing or partition walls at any time.

Another advantage is that walls with widths given by multiple widths of the base block can be built with the help of base and derived blocks. Thus, it is possible to build a lower part of a house with a wall thickness of, for example, 3 x block width, on the middle floors of the house can continue with a wall width of 2 x block width and the last floors can have a wall as wide as a block. This avoids unnecessary congestion of the constructions, it saves material and therefore the system takes more care of the environment.

Thanks to the external vertical rails, it is possible to clean the outer wall and the inner wall of the wall by using face panels directly mounted on these rails.

Pr & h / ad turn to / Clarify drawings /

The modular system according to the present invention will be further elucidated by means of the attached drawings. Fig. 1 is a top view of the first base block; Fig. 2 is a side view of the first base block. Fig. 3 shows a top view of the second base block. Fig. 4 shows a cross-section of the outer groove with variants of the lateral side solutions with selected dimensions ensuring the self-locking of the connection with the outer connecting rail and Fig. 5 shows the cross-section of the outer groove together with the self-locking of this connection. Fig. 6 is a top view of the first derived block and Fig. 7 is a side view of its

longer wall. Figure 8 shows a top view of the second derived block and Figure 9 is a side view of its longer wall. Fig. 10 shows the cross-section of the outer groove in the shape of a regular isosceles trapezoid with selected dimensions ensuring the self-locking of the connection with the outer connecting bar. Fig. 11 shows a view of the location of an external groove with a cross-section in the shape of a regular isosceles trapezoid in the side wall of a block with a marked vertical axis. Fig. 12 shows a cross-section of the inner groove formed by assembling two blocks together by side walls with outer grooves with a cross-section in the shape of a regular isosceles trapezoid that form an inner groove in such an assembly. Giant. 13 shows a cross-section of a regular isosceles trapezoidal groove together with a cross-section of a regular isosceles trapezoid outer connector with selected self-locking dimensions.

-r of this connection. Fig. 14 shows the cross-section of the inner groove formed by assembling two blocks together by side walls with outer grooves with a cross-section in the shape of a regular isosceles trapezoid, which in such an assembly forms an inner groove together with shape and dimensional corresponding cross-section represents a self-locking connection. Qbr.15 shows another possible example of the cross-section of the inner groove formed by assembling two blocks together by side walls with different outer grooves with a cross section in the shape of a regular isosceles trapezoid, which in such an assembly forms an inner groove together with shape and dimensionally corresponding inner cross-section connecting rails, which represent a self-locking connection. Fig. 16 is a perspective view of a portion of a wall equal to the width of a first base block composed of four first derived blocks interconnected by inserting the outer tie bars into the outer grooves and sliding the inner tie bars into the inner grooves by extending from each row of blocks connecting rails for the upper or lower rows of blocks.

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DETAILED DESCRIPTION OF THE INVENTION

The present modular system for precise construction consists of a set ï.

blocks, 0br. 1,2,3,6,7,8,9, provided with outer grooves 1, 0br. 4,5,10,11,13, and 1d by internal grooves 11, Qbr. 12,14,15 and from the set of outer connecting strips 2, 0br. 5.13 and the inner connecting strips 22, 0br. 14.15. By means of the outer connecting strips 2 and the inner connecting strips 22, the blocks are self-locking. The outer groove 1 and outer connecting strip 2 and inner groove 11 and inner connecting strip 22 respectively form a self-locking element.

The set of blocks is predominantly made up of two types of base block, namely the first block 3, Qbr. 1,2, and a second base block 5, pbr 2,3, and a first derived block 4, Qbr 6,7 and a second derived block 6, pbr 8,9. Both the basic blocks 3.5 and the derived blocks 4.6 have the same height b.

The first base block 3 has a square base of width a. The second base block 5 has a rectangular base of width c less than aa length and coincident with the width and bases of the first base block 3. The first derived block 4 has the same width as the first base block. The second dimension, i.e. the length of both the first derived block 4 and the second derived block 6 is 2a. In general, it is possible to derive other types of derived blocks, which always have the same width and respectively c, and their length is given by an integral multiple of the width and the first basic block 3 greater than 2, ie 3a, 4a, 5a etc.

Blocks 3,4,5,6 can be made of various materials, such as concrete, cellular concrete, aerated concrete, wire-reinforced concrete, brick clay, plastic, composite material, wood, hard rubber, and the like; its suitable strength and compatibility with the material of which the outer tie bars 2 and the inner tie bars 22 are made. For the operation of the whole system, the placement and number of outer grooves 1, inner grooves 11 and outer dimensions of the blocks 3,4,5,6 are essential. From a functional point of view, it is completely irrelevant whether and to what extent the blocks 3,4,5,6 inside the block body are lightened, for example, by several large openings or a set of slots or, conversely, reinforced.

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The first basic block 3, 0br. 1,2, has the shape of a regular quadrilateral prism with a height b and a square base with a width of the side of the base a and is intended for use in load-bearing and partition walls. This first base block 3 comprises a maximum of four outer grooves 1 spaced so that each is positioned in one side wall of the regular quadrilateral prism over the entire height b. The vertical axis of the front wall of the outer groove 1, located on the side wall of the regular quadrilateral prism is identical with a vertical axis of the side wall in which the outer groove 1 is located. Each first base block 3 comprises at least three outer grooves 1, in one pair of opposed side walls each one and one on one and / or the other side wall of the other pair of opposing side walls.

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Starting from the first basic block 3, the first derived block 4, FIG. 6,7, which has a cuboid shape with a height b and a rectangular base with a side width a and a side length 2a and is also intended for use in load-bearing and partition walls. This first derived block 4 comprises a maximum of seven connecting holes, namely six outer grooves 1 and one inner groove 11. The first derived block 4 is formed by two side-by-side first basic blocks 3 formed in one piece. This corresponds to the location of the outer grooves 1 and the location of the inner groove 11 within the body

I t 4) * · * ♦ * 1 | 4. In the middle of its base, it has one internal groove formed symmetrically around the plane of symmetry about the plane of symmetry along the vertical axes of the shorter side walls along its entire height b. A maximum of two outer grooves 1 are arranged in the two longer side walls of the box so that the vertical axis of the front wall of the outer groove 1, which is located in the longer side wall of the box, coincides with a vertical line on the surface of this longer side wall. the edge of the cube and which is located from the vertical edge of this side wall of the cube at a / 2 distance, the entire height b of the cube. In each shorter side wall of the cuboid, a maximum of one outer groove 1 is arranged such that the vertical axis of the front wall of the outer groove 1 coincides with the vertical axis of the shorter side wall of the cuboid in which the outer groove 1 is located. Each first derived block 4 comprises at least two outer grooves 1 and one inner groove 11.

The second basic block 5, 0br. 2,3 has a cuboid shape with a height b and a rectangular base with side length a and side width c less than length a and is intended for use in partition walls and load-bearing walls. The second base block 5 comprises a maximum of four outer grooves 1 spaced so that each is located in one side wall of the cuboid. The vertical axis of the front wall of the outer groove 1, which is located on the side wall of the cuboid, is identical to the vertical axis of the side wall in which the outer groove 1 is formed, over the entire height b of the cuboid. Each second base block 5 comprises at least three outer grooves 1, in one pair of opposed side walls each one and one on one and / or the other side wall of the other pair of opposing side walls.

and

Second derived block Qbr. 8,9, starting from the second basic block 5, has a cuboid shape with a height b and a rectangular base with a side length 2a and a side width c less than length a and is intended for use in partition walls and load-bearing walls. The second derived block 6 comprises a maximum of seven connecting holes, namely six outer grooves 1 and one inner groove 11. The second derived block 6 is formed by two successive lengthwise second base blocks 5 made in one piece. This corresponds to the placement of the outer grooves 1 and the location of the inner groove 11. At the center of its base, it has one inner groove formed symmetrically around the plane of symmetry about the plane of symmetry passing through the vertical axes of the shorter side walls. A maximum of two outer grooves 1 are located in the two longer side walls of the cuboid so that the vertical axis of the front wall of the outer groove 1 is located at »· ♦ ·

the long side wall of the cuboid is coincident with the vertical line on the surface of the longer side wall, which is parallel to the vertical edge of the cuboid side wall and which is a distance of a / 2 from the vertical edge of the cuboid side wall, . In each shorter side wall of the cuboid, a maximum of one outer groove 1 is arranged such that the vertical axis of the front wall of the outer groove 1 coincides with the vertical axis of the shorter side wall of the cuboid in which the outer groove 1 is located. Each second derived block 6 comprises at least two outer grooves 1 and one inner groove 11.

Further derived blocks are either based on the first base block 3 or the second base block 5 and have the shape of a block with a rectangular base. The further derived blocks are formed in shape by three or more lengthwise built-in first base blocks 3 or second base blocks 5, produced in one piece. This corresponds to the placement of the outer grooves 1 and inner grooves 11 within each further derived block.

For each outer groove 1, © br. 4,5 is characterized in that in any cross section thereof perpendicular to the side wall of any of the blocks 3,4,5,6 in which the outer groove 1 is located, and at the same time perpendicular to the vertical plane of symmetry passing through the side wall, is the width d of this cross-section located in the side wall of the block 3, 4, 5, 6, shorter than the width e of at least one inner connecting line of the lateral sides of this cross-section of the outer groove 1. Na © br. 4 shows the basic possible cross-sectional shapes of the outer groove 1, wherein the lateral sides of this cross-section form sinusoids, cosinusoids, concave or convex curves, or the lateral sides of this cross-section form segments forming a block 3,4,5,6 with width (d> in the plane of the side wall surface of the block, the cross-section may also be T-shaped or in the shape of a regular isosceles trapezoid.

For each inner groove 11, it is characterized in that its shape and cross-section is derived from the shape and cross-section of the two outer grooves T The inner groove 11 is formed by applying two outer grooves 1 to each other so that the cross-sections of the two The outer grooves 1 have common widths d, the widths * of the widths d need not be identical. The cross-section of the inner groove 11 is symmetrical about the axis by a half-width dd resulting from the common widths d, FIG. 14.15.

10, 11 and 13, some possible shapes of the outer groove 1 are shown. 10 has a cross-section in the shape of a regular isosceles trapezoid. Fig. 13 shows an external groove 1 with a cross-section in the shape of a regular isosceles trapezoid with an inserted external connecting bar 2 with a cross-section also in the form of a regular isosceles trapezoid. One of the possible cross-sectional shapes of the inner groove 11 on Fig.12 can be obtained by rotating the cross-section of the outer groove 1 about an axis passing through the shorter parallel side of the regular isosceles trapezium by 180 °. Na 0br. 14 shows the specific shape of the inner groove 11 with the inner connecting rail 22 inserted. The cross-section of the inner connecting rail 22 is smaller than the cross-section of the inner groove 11 and there is a self-locking condition that at least one width ff parallel to width dd which is greater than width dd.

The system comprises outer connecting strips 2 and inner connecting strips 22. For each outer connecting strips 20b. 5,13, characterized in that, in any of the same cross-sections perpendicular to the vertical plane of symmetry, at least one inner width f of that cross-section of the outer tie bar 2 given by the lateral side link is longer than the width d of this cross-section of the outer groove 1 3,4,5,6 and on the same cross-section at the same time for these widths f, they are parallel to the width d of the cross-section of the outer groove 1. In FIG. 5 shows the basic possible cross-sectional shapes of the outer groove 1 and their corresponding basic cross-sectional shapes of the outer tie-rod 2 inserted into the outer groove 1. The cross-section of the outer tie-rod 2 must always be smaller than the cross-section of the outer groove 1.

For each inner connecting rail 22, its shape and cross-section is derived from the shape and cross-section of two outer connecting rails 2 joined together so that the cross-sections of the two adjacent connecting rails 2 made in one piece have common widths g , the widths of g need not be the same. The cross-section of the inner tie bar 22 is symmetrical about the axis by a half-width gg formed from the common widths g, FIG. 14.15.

«» · 9 · · 9 9 9 9 9 a a a a a a a a a a a a a a a a a

The height of the outer tie bars 2 and the inner tie bars 22 is such that two outer tie bars 2 or two inner tie bars 22 are never joined together in an integer multiple of the height b of the block 3,4,5,6, so that the tie bars do not end and do not start in the gap between two stacked blocks 3,4,5,6.

The outer tie bars 2 and inner tie bars 22 may be made of a variety of materials, for example, concrete, lightweight concrete, aerated concrete, wire-reinforced concrete, iron, plastic, composite material, wood, hard rubber, etc., suitable strength and compatibility with the material from which the blocks 3,4,5,6 are made.

The external shape of their cross-section and its dimensions is essential for the correct functioning of the outer connecting strips 2 and the inner connecting strips 22. From a functional point of view, it is immaterial whether and to what extent these strips are lightened differently, for example, by a single hole or a set of slots or, conversely, reinforced.

The basic principle of the system of the outer groove 1 in connection with the inserted outer connecting rail 2 or the inner grooves 11 in connection with the inserted inner connecting rail 22 is their self-locking connection.

When the blocks 3, 4, 5, 6 are placed side by side at the point of contact of the two outer grooves 1, a shaped inner groove 11 is formed. The connection of the side-by-side and stacked blocks 3,4,5,6 is formed by inserting the outer connecting strips 2 into the outer grooves 1 and J by inserting the inner connecting strips 22 into the inner slots 11, 16b. The blocks 3, 4, 5, 6 are positioned in such a way that the outer grooves 1 and the inner grooves 11 of the neighboring blocks are dimensionally connected in vertical planes of symmetry of the widths d and width dd respectively of the cross-sections of the grooves. This achieves a solid spatial connection during construction. Moreover, the perpendicularity and flatness of the walls with respect to the mat is automatically ensured, but also the right angles between the adjacent walls are maintained.

• Μ ·

The outer tie bars 2 and inner tie bars 22 used first in the two lowest rows and the two highest rows of the wall may have a height (x + 1/2) b where x = 0,1,2,3, ... and the outer the connecting strips 2 and the inner connecting strips 22 to be used in the other rows of the wall may have a height yb where y = 1,2,3,4, ... i.e., the connecting strips which are inserted into a particular block in a row of blocks, they extend into the lower and / or upper rows of blocks. Such a construction principle ensures a firm anchoring of the wall to all three axes in the space. The construction of the wall follows the method of tying the derived blocks 4.6, that is, each horizontal row of blocks 4.6 is offset from the previous row by an overlap of a. When building a wall with thickness a there are rows of first derived blocks or second derived blocks In the construction of a wall with a thickness 2a, the lower row of the first derived blocks 4 is laid by the longer side wall in the direction of the wall construction and the upper row of the first derived blocks 4 is laid by the shorter side wall in the wall. direction of construction wall. This results in the interconnection of the first derived blocks 4 within the wall body.

Within the block 3, 4, 5, 6, all outer grooves need not have identical cross-sections in shape and size. Sufficient conditions for proper use are that the adjacent outer grooves 1 and the inner grooves 11 within the wall have the same cross-sectional shape and dimensions.

The resulting space between the walls of the outer groove 1 and the walls of the outer connecting strip 2 and the inner groove 11 and the inner connecting strip 22, respectively, can advantageously be filled either continuously or discontinuously with sealant, eg polyurethane foam, cementitious compound, chemical anchor etc., or any glue.

In the manufacture of blocks 3, 4, 5, 6 by casting material into molds or by vibrating and compressing the material into molds, outer grooves 1 and inner grooves 11 evenly tapered over the entire height b with a standard bevel can be advantageously used. The tapered outer grooves 1 and inner grooves 11 allow easier and non-destructive release and ejection of the block 3,4,5,6 from the mold.

Some of the outer grooves 1 on the side of the wall can be advantageously used to attach and anchor other perpendicular elements, for example an existing wall to the existing wall, by means of the inner connecting strips 22. Similarly, using the inner connecting strips 22 frames and door frames for construction openings, or they can be used for distribution of utility networks - water pipes, heating distribution, power electrical cabling and cabling for communication technology. In such cases, the outer tongue 2 does not slide into the outer groove 1.

Industrial applicability

The modular system for precise construction can be used everywhere in the realization of residential and industrial buildings instead of the existing walls and building systems. Unlike the existing construction principles, the system provides the possibility of carrying walls and partition walls, including the installation of window and door frames at the same time within the built-up floor, and also allows the installation of utility lines, including cabling, without mechanical interventions into already built walls. From the outside it allows easy installation of thermal insulation systems and surface decors. Thanks to these features, a significant time and cost saving can be achieved with the modular system for precise construction compared to existing building systems. Within the realization of the construction, the system of precise construction minimizes the demands on the use of fasteners. Pure dry walling can be considered when using suitable material for the production of tie-rods and ensuring sufficient accuracy of the blocks. Otherwise, it is advisable to use a material that continuously or discontinuously fills the space between the groove walls and the walls of the connecting rail. With the new technology of mutual bonding of building elements within the construction by means of several grooves and connecting strips, it is possible to achieve greater strength and cohesion of the built objects.

Claims (5)

PATENT CLAIMS A modular system for precision construction, the system comprising two basic blocks (3,5) and two derived blocks (4,6) in the form of blocks of equal height (b), wherein the first basic blocks (3) have in one pair the opposing side walls each have one outer groove (1) and the second base block (5) also has in its shorter side walls one outer groove (1), the outer grooves (1) extending over the entire height (b) of said block (1). 3,4,5,6) and are formed symmetrically about a plane of symmetry passing through the vertical axis of the given and opposite side walls, with all blocks (3,4,5,6) having at least one internal width ( e) each outer groove (1) in a plane parallel to the surface of the sidewall in which it is formed, greater than its width (d) in the plane of the surface of the sidewall, and wherein the derived blocks have an inside a groove (11) for sealingly engaging the inner connecting strips (22) for self-locking connection formed symmetrically about a plane of symmetry passing through the vertical axes of the shorter side walls and corresponding in shape and size to the two outer grooves (1) of the two blocks a successive row-side mounting, characterized in that the first base block (3) has a square base of side width (a) and is provided on one and / or the other side wall of the second pair of opposite side walls with one outer groove (1) formed over the entire height (b) of said block symmetrically about a plane of symmetry passing through the vertical axis of said and opposite side walls, said first derived block (4) extending from said first block (3) has a rectangular base of side width (a) and length (2a); an inner groove (11) in the center of its base is formed by a the whole height (b) and this first derived block (4) has at least two and a maximum of six outer grooves (1) along the whole height (b), with each shorter side wall symmetrically about the symmetry plane passing the vertical axis of the given and opposite shorter side walls with a maximum of one outer groove (1) and in longer side walls with a maximum of two outer grooves (1) formed symmetrically about planes of symmetry parallel to the shorter side walls and located in the side walls. The distances (a / 2) from the shorter side walls, the planes of symmetry being spaced apart in width (a), the second base block (5) having a rectangular base of side length (a) and width (c) ) smaller than (a) and is provided on one and / or the other long side wall with one outer groove (1) formed over the entire height (b) symmetrically around the plane the symmetry passing through the vertical axis of said and opposite longer side walls, and the second derived block (6), originating from the second base block (5), has a rectangular base with a side length (2a) and a width (c) of less than (a) and internal groove (11) in the center of its base is formed along its entire height (b) and this second derived block (6) is provided along its entire height (b) with at least two and a maximum of six outer grooves (1). planes of symmetry passing through the vertical axis of the given and opposite shorter side walls at most one outer groove (1) and in the longer side walls there are at most two outer grooves (1) formed symmetrically around the planes of symmetry parallel to the shorter side walls and spaced (a / 2) from the shorter side walls, the planes of symmetry being spaced apart in width (a), and they are part of the outer connecting rail system (2). A modular system according to claim 1 _, characterized in that the outer connecting strips (2) and the inner connecting strips (22), for use in the two lowest rows and the two highest rows of the height (x + 1/2) b, wherein x is an integer positive integer including zero, and the outer tie bars (2) and inner tie bars (22) for use in the other rows have a height yb where y is an integer positive integer. Third modular system according to claims 1 or 2 _{wherein it further contains other related blocks are identical in height (b), and it blocks the width (a) and / or blocks of a width (c), whose length is N multiply the width (a) of the first base block (3), wherein n is an integer equal to or greater than 3, wherein the spacing of the outer grooves (1) and the inner grooves (11) corresponds to the sequential order of three or more first base blocks (3) ) or second base blocks (5) produced in one unit. • t tft <i _t t ₉ Fourth modular system according to any of claims 1 to 3 _F, characterized in that within one block (3,4,5,6) has at least one outer groove (1), other dimensions and / or a different shape than the remaining outer groove ( 1), wherein the adjoining outer grooves (1) and the inner grooves (11) within one wall have the same shape and the same dimensions. 5. The modular system of claim 4 _; characterized in that the inner connection strip (22) is symmetrical on each of its cross-sections only along the longitudinal axis (o).