RU94238U1 - BUILDING ELEMENT BASED ON CELLULAR FRAME - Google Patents

Abstract

 1. A building element consisting of a cellular frame with spatial cells and a filler, characterized in that the cellular frame is a honeycomb structure made of polymer elements interconnected, and a mixture of an inorganic binder material, an inert material, complex polymeric additives of multifunctional action and water, while the building element as a whole has an elastic modulus from 1500 to 21000 MPa. ! 2. The building element according to claim 1, characterized in that the frame is made hollow. ! 3. The building element according to claim 1, characterized in that the frame walls have perforation. ! 4. The building element according to claim 1, characterized in that cement is used as an inorganic binder material. ! 5. The building element according to claim 1, characterized in that the earth and / or sand, and / or gravel, and / or crushed stone, and / or expanded clay, and / or asphalt crumb, and / or battle are used as an inert material. brick, and / or ferroalloy waste. ! 6. The building element according to claim 1, characterized in that the polymer additive is made on the basis of latex. ! 7. The building element according to claim 1, characterized in that the amount of the polymer additive is 5-50% by weight of the inorganic binder material.

Description

The invention relates to industrial and civil engineering and can be used in the construction of the upper structure of the railway track, the top layer of the road and pedestrian roads, as strip foundations under panel houses, frame cottages and wooden houses.

A building element is known, consisting of a cellular frame with spatial cells, and a filler, while the frame is made of wood, and reed stems or reed mats and polyurethane foam, which are a monolithic mass connected with its entire surface to the frame, are used as filler cells (patent RF №54983 for the utility model "Building panel and method of its manufacture", priority from 2004.12.28, published 2006.07.27).

The well-known building element has insufficient strength and elasticity for the construction of rail, road and pedestrian roads, strip foundations.

Also known is a building element based on a cellular frame described in RF patent No. 2224854 for the invention “Building panel and method for its manufacture” with priority dated 2002.02.04, published 2004.02.27) and selected as a prototype.

This building element consists of a cellular frame with spatial cells and a filler, while the frame is made of steel wire, and Izolan 101 polyurethane foam, thickness is used as a filler located at a distance of at least 10-50 mm from the planes determining its thickness. which is (0.1-0.9) of the thickness of the frame.

Before the manufacture of this building element, it is necessary to clean the metal surfaces of exfoliating rust, dust and dirt, and in the presence of grease, degrease. Then, inside the metal frame, at a predetermined distance from the plane formed by the side of the frame, a support surface is created in the form of an embankment of a given height from dry bulk material, for example, dry sand, and this embankment is leveled to obtain a surface on it parallel to the corresponding plane of the framework. Using a spraying device, a mixture of Izolan 101 components is supplied, and then the supporting surface is removed, and the mixture is fed by scanning the supporting surface by moving the nozzles of the spraying unit above it, and the thickness of the filler obtained depends on the scanning speed and the flow rate of the mixture.

The well-known building element has good heat-insulating properties, but at the same time is quite complicated in the manufacture, which affects its cost. This building element does not have sufficient strength and elasticity, which are necessary for the construction of rail, road and pedestrian roads, strip foundations.

The technical problem to which the claimed solution is directed is to create a building element structurally and technologically simple, cheap and having the necessary strength and elasticity indicators, allowing the use of the claimed building element in conditions of increased static and dynamic loads, for example, in the construction of the railway track superstructure , the top layer of the coating of roads and pedestrian roads, as strip foundations under the shield houses, frame cottages and wooden houses.

The solution to this problem is the claimed building element, consisting of a cellular frame with spatial cells and a filler, new in which the cellular frame is a honeycomb structure made of polymer elements interconnected, and a mixture of an inorganic binder is used as an elastic filler material, inert material, complex polymer additives of multifunctional action and water, while the building element as a whole has an elastic modulus of 1500 m Pascal's ega to 21,000 mega-pascal.

In the building element, the frame can be made hollow, and the walls of the frame can have perforation.

Cement can be used as an inorganic binder material, and earth and / or sand and / or gravel and / or crushed stone and / or expanded clay and / or crushed stone and / or brick bricks and / or ferro-alloy waste can be used as an inert material. production. The polymer additive used can be made on the basis of latex, and the amount of polymer additive can be 5-50% by weight of the inorganic binder.

The cellular frame in the form of a honeycomb structure made of polymer elements interconnected is a compact element in which the cell walls and the joints of the elements are stiffeners that increase the strength of the structure, the degree of stability in horizontal and vertical directions and resistance to bending. The cellular frame has a low material consumption, which affects its cost. The depth of the cells of the frame determines the thickness of the building element. Performing a hollow frame further reduces its material consumption.

In each cell of the frame, the filler is in contact only with its walls, and if there are perforations in the walls of the frame, an additional connection is formed between the fillers of adjacent cells, and when the cells of the frame are hollow, the filler is directly connected to the base (soil) on which the building element is laid . Thus, for any of the above embodiments, the frame, the cells of which are filled with filler, is a plate that, when operating under increased static and dynamic loads, distributes the loads acting on it over large surfaces of the base (soil), as a result of which the vertical stress on this base.

It is known that with an increase in the elastic properties of concrete (in this case, filler), the strength properties of concrete decrease. For reliable operation of the claimed building element in conditions of increased static and dynamic loads, the elastic modulus (from 1,500 mega pascals to 21,000 mega pascals) of the building element as a whole is determining. At the same time, the strength properties of a building element for operation under high loads are regulated by regulatory documents: the tensile strength to mechanical destruction is 2.5–20 mega pascals. The elasticity of the building element is ensured by the construction of the frame and the filler associated with it, the elastic and strength properties of which are determining and optimized by a complex polymer additive of multifunctional action (complex modifier of concrete), the amount of which (5-50% by weight of the inorganic binder material - cement) is selected depending on the type and properties of the inert material used. A polymer additive simultaneously with an increase in the elasticity of the filler also increases its strength, in particular by increasing the water resistance and resistance to cracking, and reducing shrinkage deformations. A polymeric additive of multifunctional action is selected from among known additives, for example, the complex concrete modifier according to the patent of the Russian Federation No. 2288197, or the Renolit additive, made on the basis of latex, which acts as a cementitious material in addition to an inorganic cementitious material (cement), which allows to achieve predetermined elastic properties of the filler to reduce the proportion of additives, that is, to reduce the cost of the building element. So when using sand as an inert material, the proportion of polymer additives is 5-8%, and for hard inert materials (crushed stone) - 10-40%. This proportion is obtained empirically.

The use of improvised materials as inert materials (available in sufficient quantities) also reduces the cost of the claimed building element.

For the manufacture of the inventive building element based on a cellular frame having a simple and compact design, does not require any special equipment.

The authors know the use of a cellular frame made of polymer elements for volumetric reinforcement (reinforcement) of soils (in the construction of roads and railways, airfields), to protect them from erosion, in particular, to protect the slopes of embankments and excavations from erosion (STO 218.3.005 / 2-2007 "Geotext frame lattice of the Geomat brand). For any of the above options for using a cellular frame, the traditional approach is used: the cells are filled with soil, crushed stone or sand, then the filler is compacted, and in order to protect the filled frame from destruction, a surface coating (asphalt, crushed stone) is formed that takes up the main load. This approach leads to cost overruns of building materials.

The authors are not aware of the use of a building element on the basis of a cellular frame without a surface protective coating when working under high static and dynamic loads, for example, as a basement for the construction of railways, the top layer of roads and pedestrian roads, as strip foundations. The proposed technical solution overcomes the stereotypical thinking of specialists in this field and takes the use of building elements based on a cellular frame to a new stage of development without a surface protective coating under high loads, providing new opportunities, which allows us to talk about compliance of the claimed technical solution with the patentability condition "inventive step" .

When conducting a search in the sources of patent and scientific and technical literature, no solutions were found containing the totality of the proposed features for solving the task, which allows us to conclude that the claimed technical solution meets the patentability criterion of "novelty."

The claimed technical solution is illustrated by drawings, where is schematically shown: figure 1 - mesh frame; figure 2 - building element assembly.

The building element consists of a cellular frame 1 with spatial cells 2. The cellular frame 1 is a honeycomb structure made of polymer elements 3 connected to each other. Cells 2 of the frame 1 are filled with an elastic filler 4. As a flexible filler 3, a mixture of an inorganic binder material, an inert material, a complex polymer additive of multifunctional action and water is used. The finished building element as a whole has a modulus of elasticity from 1,500 mega pascals to 21,000 mega pascals.

The depth of the spatial cells 2 corresponds to the desired thickness of the manufactured building element, and the wall thickness of the cells 2 is selected based on the specific operating conditions and properties of the filler and may be equal to 1.5-10 mm.

The inventive building element is made as follows:

- make up a mixture (filler) of an inorganic binder material, an inert material, a polymer additive and water;

- mixed in a mixer;

- fill cells 2 of the frame 1 with a prepared filler;

- compacted.

After the filler dries, the building element is considered ready for use.

To give the building element the necessary elastic properties (elastic modulus from 1,500 mega pascals to 21,000 mega pascals) and preserve strength properties (tensile strength to mechanical destruction of 2.5-20 mega pascals), the amount of each of the filler components is determined based on the type of inert material selected.

Example 1. The frame is made of high pressure polyethylene. When using cement as an inorganic binder, as an inert material - sand, as a complex polymer additive - an additive based on latex Renolit, the quantitative ratio of the components will be as follows: cement - 8-10% by weight of sand, Renolit - 5% by weight of cement, water - 12% by weight of sand. A building element based on a cellular frame made with this filler has an elastic modulus of 6500 mega pascals.

Example 2. The frame is made of high pressure polyethylene. When using cement as an inorganic binder, as an inert material - crushed stone of small or medium fractions, as a polymer additive - an additive based on Renolit latex, the quantitative ratio of the components will be as follows: cement - 10-16% by weight of crushed stone, " Renolit ”- 10% by weight of cement, water - 5% by weight of crushed stone. A building element made with this filler has an elastic modulus of 9000 mega pascals.

The method of selecting specific ratios of the components of the filler is the author's and is based on personal knowledge and experience of the authors.

Ready-made building elements are brought to the place of application and subsequently laid them directly on the prepared base (for example, on compacted soil) or on the sealing layer close to each other. After laying the building elements, a single structure is formed, suitable for operation and not requiring additional surface protective coating.

Building elements can be made directly on the spot: the cellular frame is laid on the prepared base, filled with the prepared mixture, compacted.

Under the action of static and dynamic loads, the polymer elements 3 of the carcass 1 take on part of these loads, and the remaining load is transferred to adjacent cells 2 with filler 4. Cells 2 connected to each other in the spatial structure of the carcass 1 distribute the load on large surfaces of the base, as a result the value of the vertical stress on the base decreases, that is, the probability of its destruction decreases. Due to the elastic properties of the filler, the level of destructive elastic vibrations in the building element is reduced, which also increases the protection of the base.

The resulting building element has high strength and elasticity required for the construction of railways and highways, strip foundations, protective fences, etc.

Thus, the proposed building element on the basis of a cellular frame is structurally and technologically simple, has a low cost and has the necessary indicators of strength and elasticity, allowing the use of the claimed building element without a protective coating under conditions of increased static and dynamic loads.

Claims (7)

1. A building element consisting of a cellular frame with spatial cells and a filler, characterized in that the cellular frame is a honeycomb structure made of polymer elements interconnected, and a mixture of an inorganic binder material, an inert material, complex polymeric additives of multifunctional action and water, while the building element as a whole has an elastic modulus from 1500 to 21000 MPa. 2. The building element according to claim 1, characterized in that the frame is made hollow. 3. The building element according to claim 1, characterized in that the walls of the frame are perforated. 4. The building element according to claim 1, characterized in that cement is used as an inorganic binder material. 5. The building element according to claim 1, characterized in that the earth and / or sand, and / or gravel, and / or crushed stone, and / or expanded clay, and / or asphalt crumb, and / or battle are used as an inert material. brick, and / or ferroalloy waste. 6. The building element according to claim 1, characterized in that the polymer additive is made on the basis of latex. 7. The building element according to claim 1, characterized in that the amount of the polymer additive is 5-50% by weight of the inorganic binder.