RU210408U1 - Building block for modular structures - Google Patents

Abstract

The utility model relates to the field of construction on land and on water, namely, building blocks used for the construction of load-bearing and / or self-supporting structures, in particular walls, partitions, foundations, supports, pontoons, platforms on the water and other structures. Building block for modular structures, having the form of a right triangular prism, including two bases in the form of right triangles, the first and second side faces perpendicular to each other, and one diagonal side limited by the diagonals of the bases and side edges of the first and second side faces, and the block is made two through mounting holes, the first of which extends from the diagonal side face to the first side face, and the second extends from the diagonal side face to the second side face. The technical result achieved as a result of solving the problem is to expand the arsenal of tools for the construction of modular structures.

Description

Technical field

The utility model relates to the field of construction on land and on water, namely, building blocks used for the construction of load-bearing and / or self-supporting structures, in particular, walls, partitions, foundations, supports, pontoons, platforms on the water and other structures.

State of the art

In the prior art, various building blocks are known that provide the possibility of mutual collapsible or non-separable connection with the formation of modular structures. For example, brick, foam concrete blocks, plastic pontoon blocks, etc.

A disadvantage of many known building blocks is the difficulty of interconnecting identical blocks to form modular structures in two or three planes. To solve this problem, various corner connecting elements are usually used, or sawing of building blocks is required, which reduces the manufacturability of the installation of structures under construction, and also excludes or makes it difficult to completely dismantle the modular structure to obtain building blocks in their original state, which can be used to form other structures. . Obviously, when sawing, some of the blocks cannot be reused, and when using connecting corner elements, after dismantling, there may be extra elements that are not required for the construction of another modular structure.

Therefore, increasing the versatility of building blocks is still an urgent task.

The objective of the claimed utility model is to develop a building block design that provides improved manufacturability and versatility when assembling various modular structures, as well as expanding the arsenal of tools for building modular structures.

Disclosure

The technical result in the claimed building block for modular structures is achieved by the fact that the building block has the shape of a right triangular prism, including two bases, in the form of right triangles, the first and second side faces perpendicular to each other, and one diagonal side face limited by the diagonals of the bases and side ribs of the first and second side faces, wherein the block has two through mounting holes, the first of which passes from the diagonal side face to the first side face, and the second passes from the diagonal side face to the second side face.

Possible clarifying features of the claimed utility model are listed below.

The block is made hollow, and bushings are inserted into the first and second mounting holes, which are installed to ensure the tightness of the block cavity. The block is made using rotational molding technology. The block is made of polymer material. A mounting notch is made at the junction of one of the bases and the diagonal side face. Mounting grooves are made on the surface of one of the bases parallel to one of the base ribs. Mounting slots have a rectangular cross section and are made with the possibility of installing a T-beam flange.

In the context of the present description, the words "first", "second", etc. were used as ordinal numbers only to show the difference between nouns that are different from each other, and not for the purpose of describing any particular relationship between these nouns or their sequence.

In the context of the present description, the terms "triangular prism", "right triangle" mean shapes essentially close to these geometric figures. As it will be clear to a specialist, taking into account various technologies and materials of manufacture, the implementation of fillets, chamfers, the presence of seams, etc. the shape of the product may differ from the shape of the corresponding geometric figure.

The technical result achieved as a result of solving the problem is to expand the arsenal of tools for the construction of modular structures.

Brief description of the drawings

In FIG. 1 - the design of the proposed building blocks (general view from the bottom of two identical blocks to form a modular structure).

In FIG. 2 - the design of the proposed building blocks (general top view of two identical blocks to form a modular structure).

In FIG. 3 is an example of a modular structure formed from two building blocks connected to each other.

In FIG. 4 is an example of a modular structure formed from eight building blocks connected to each other by means of rods.

In FIG. 5 is an example of a railway platform, the base of which is a modular structure of the inventive building blocks installed on supporting pile platforms.

Description

In FIG. 1 and FIG. 2 shows the construction of the inventive building block 100. In order to provide a better understanding of the construction, FIG. 1-2 show two identical building blocks 100.

Building block 100 for modular structures, having the form of a right triangular prism, including two bases 1021 and 1022, in the form of right triangles, the first 1041 and second 1042 side faces perpendicular to each other, and one diagonal side face 106, limited by the diagonals of the bases 1021, 1022 and side ribs of the first 1041 and second 1042 side faces.

The block 100 has two through mounting holes, a first 1081 and a second 1082. The first through mounting hole 1081 extends from the diagonal side face 106 to the first side face 1041, and the second through mounting hole 1082 extends from the diagonal side face 106 to the second side face 1042.

An embodiment is possible in which the building block 100 is made hollow, and bushings are inserted into the first 1081 and second 1082 mounting holes, installed to ensure the tightness of the cavity of the block 100.

Building block 100 in some embodiments, the implementation can be made solid or contain one or more cavities separated from each other. The presence of a sealed cavity can help reduce the weight and size of the building block 100, as well as ensure its buoyancy for use, including in pontoon structures.

Building block 100 may be rotationally molded. The building block 100 may be made of a polymeric material. In addition, the building block 100 may be made from one or more materials selected from: wood, rubber, metal, plastic, polystyrene foam.

An embodiment is possible in which a mounting recess 110 is formed at the junction of one of the bases 1021, 1022 and the diagonal side face 106. The mounting recess 110 may be, for example, a rectangular-shaped recess, as shown in FIG. 1, or a recess of a different shape, for example, in the form of a semicircle, triangle, polygon, etc. (not shown). The mounting recess 110 can be used, for example, to install the building block 100 on a support platform, made, for example, in the form of a plate 200, as shown in FIG. 1, or other supports, in particular piles, foundation platforms, etc. (not shown).

In FIG. 3 shows an illustrative example of joining two building blocks 100 to form a cube-shaped modular structure. By means of mounting recesses 110 provided in each building block 100 at the junction of one of the bases 1021, 1022 and the diagonal side face 106, the modular structure can be mounted on a support platform as shown in FIG. 3.

In FIG. 4 shows an illustrative example of connecting eight building blocks 100 to form a modular structure in the form of a platform or pontoon. At the same time, building blocks 100 are interconnected by means of fasteners 400 made in the form of rods inserted into the first 1081 and second 1082 mounting holes of each of the building blocks 100. Similarly, any necessary number of building blocks 100 can be connected to form a platform, pontoon, panel, support or other structure with the required overall dimensions, as well as, for example, the required strength and / or buoyancy.

As the skilled person will appreciate, more complex modular designs are also possible, for example a railway platform as shown in FIG. 5.

An embodiment is possible in which mounting slots 112 (FIG. 2) are made on the surface of one of the bases 1021, 1022 parallel to one of the ribs of the base 1021, 1022. Mounting slots 112 may be rectangular, as shown in FIG. 2 and can be configured to mount a T-beam flange in them (shown in FIG. 5). Mounting slots 112 may also have a different shape and/or overall dimensions to allow the installation of other structural elements, such as wooden beams, metal profiles, composite profiles, etc. to enable the use of building blocks 100 in combination with standard or specially designed building profiles. In the illustrative example in FIG. 5 shows the installation of T-beams and I-beams in the respective mounting slots 112 for mounting the platform deck. As will be clear to the specialist, it is possible to create other structures based on building blocks 100.

The blocks can be connected to each other by introducing fasteners into the respective through holes 1081 and 1082.

As fasteners can be used, including cables, profiles (rods as shown in Fig. 4, pipes, etc.) with end clamps that provide a screed and prevent movement of building blocks 100 relative to each other or without end clamps due to installation in an interference fit (with an interference fit) or pressing.

The connection of building blocks 100 can be carried out at various angles, allowing the creation of modular structures with the location of blocks 100 in two or three planes.

This building block 100 can perform both enclosing and load-bearing functions. For the production of the building block 100, depending on the material of manufacture, known standard methods and standard equipment can be selected. For example, a standard rotational molding machine can be used to produce the building block 100 from a resin material by rotational molding. For the production of building blocks 100 by casting or welding, injection molds or welding equipment can also be used, respectively. When manufacturing the building block 100 from wood, appropriate woodworking equipment can be used.

The presented illustrative embodiments, examples and description serve only to provide an understanding of the claimed technical solutions and are not limiting. Other possible embodiments will be clear to the skilled person from the description presented. The scope of this utility model is limited only by the appended claims of the utility model.

Claims (7)

1. Building block for modular structures, having the shape of a right triangular prism, including two bases, in the form of right triangles, the first and second side faces perpendicular to each other, and one diagonal side face limited by the diagonals of the bases and the side edges of the first and second side faces , wherein the block has two through mounting holes, the first of which extends from the diagonal side face to the first side face, and the second passes from the diagonal side face to the second side face. 2. The building block according to claim 1, in which the block is made hollow, and bushings are inserted into the first and second mounting holes, installed to ensure the tightness of the block cavity. 3. Building block according to claim 1 or 2, in which the block is made using rotational molding technology. 4. The building block according to claim 2, in which the block is made of a polymeric material. 5. The building block according to claim 1, in which a mounting recess is made at the junction of one of the bases and the diagonal side face. 6. The building block according to claim 1, in which mounting grooves are made on the surface of one of the bases, parallel to one of the edges of the base. 7. The building block according to claim 6, in which the mounting slots have a rectangular cross section and are configured to install a T-beam flange.

Images