RU53330U1 - BUILDING STONE - Google Patents

Abstract

The utility model relates to the field of construction, namely, building stones, and can be used in the construction of external and internal walls of buildings and structures. Building stone with longitudinal and end walls and a cavity open from below differs from the known ones in that to increase its heat-insulating properties, the cavity is made through and has at least one vertical dividing wall dividing the cavity into separate parts, for simplification and acceleration The process of walling the stone is equipped with fasteners that allow you to build walls without the use of mortar. The fasteners are a groove made on one, for example, an end wall and a protrusion made on the opposite wall, as well as several vertical blind mounting holes located in the walls coaxially and towards each other. In this case, the stone is made of thermoplastic composite material in the following ratio of components. (the weight.%):

Polymer 20.0-30.0 Mineral filler 65.0-75.0 Stabilizing additives 2.0-5.0.

If necessary, an inorganic coloring pigment of any color in an amount of 1.0-2.0% and a means for imparting fire resistance (1-5%) can be added to the composition. As the polymer, at least one polymer from the group consisting of: polyethylene, polypropylene, polyethylene terephthalate, polystyrene, polyamide, polyolefins, or their secondary raw materials can be used. As the mineral filler, quartz sand, clay, talc, crushed stone screening or a mixture of at least two components can be used. Shungite concentrate can be used as stabilizing additives to increase bending strength and a titanium-based ultraviolet absorber. Fireproofing agent - antipyrine.

Description

The utility model relates to the field of construction, namely, building stones and can be used in the construction of external and internal walls of buildings and structures.

Known building stone with longitudinal and end walls and open bottom cavities. See paragraph 2148694, RU, E 04 C 1/00, claimed on 06.22.98.

The specified stone contains several slit-like voids separated from each other, arranged in rows throughout the volume of the stone. The specified stone has many jumpers that separate the voids. These jumpers form “cold bridges” that conduct heat flow well, which leads to a decrease in the thermal resistance of the stone. Therefore, for reliable thermal insulation of buildings built from the proposed stone, it is necessary to erect thicker walls, which increases the cost of construction.

When erecting buildings and structures, stones are bonded to each other with a mortar, which reduces the speed of construction and increases its cost. Also known is a building stone with longitudinal and end walls and with a cavity open from below, which is closest to the claimed one according to its technical nature (prototype). See A.S. USSR No. 50276, E 04 C 1/06, decl. 03/15/34. Such a brick, with a void size corresponding to a large part of its internal volume of a brick, has good thermal resistance, but it is quite fragile, because It is made of clay and, under the influence of applied loads, is at risk of chips, cracking, breaking of its thin walls, etc.

In addition, when erecting walls of buildings and structures from bricks, bricks are bonded to each other with mortars, which increases the complexity of the work. In this case, a lot of vertical and horizontal through seams are formed, perceiving bending moments and weight loads, which reduces the strength of the masonry.

It should be noted that despite the higher thermal conductivity (compared to stones without voids), for the reliable thermal insulation of buildings, it is necessary to erect walls with a thickness of 800 mm, which further increases the complexity of the masonry and its cost. It should also be noted that a known stone collapses with time under the influence of temperature extremes, precipitation, etc.

The objective of the utility model is the creation of building stones with increased strength and thermal insulation properties, the use of which significantly reduces the complexity of the construction of buildings and structures and the cost of construction.

This problem is solved in that in a known building stone with longitudinal and end walls and a cavity open from below, according to a utility model, the cavity is made through and has at least one vertical dividing wall dividing the cavity into separate parts, the stone is additionally equipped with elements for fastening it to other stones during masonry, while the stone is made of thermoplastic composite material in the following ratio of components. (the weight.%):

polymer 20.0-30.0 mineral filler 65.0-75.0 stabilizing additives 2.0-5.0

The problem is also solved by the fact that:

- the elements for fastening stones are made in the form of a protrusion on at least one wall and a corresponding groove on the opposite wall and several vertical blind mounting holes located in the walls coaxially and towards each other;

- grooves protrusions are made along the entire height of the walls;

- the thickness of its walls and dividing walls is 8-15 mm;

- 3-4 pairs of said blind holes are made in the walls;

- the diameter of the blind holes is 5-6 mm;

- end walls of corner stones are made on adjacent sides and perpendicular to each other;

- at least one polymer from the group consisting of: polyethylene, polypropylene, polyethylene terephtholate, polystyrene, polyamides, polyolefins is used as a polymer;

- as a polymer, secondary raw materials can be used;

- at least one of the following materials is used as a mineral filler: quartz sand, clay, talc, crushed stone screening of a fraction of 1-3 mm;

- the stone additionally contains an inorganic coloring pigment and a flame retardant - antipyrine, in the following ratio of components, (weight%):

polymer 20.0-30.0

mineral filler 65.0-75.0 stabilizing additives 2.0-5.0 inorganic coloring pigment !, 0-2.0 flame retardant 1.0-5.0

- as stabilizing additives use means to increase strength, for example, shungite concentrate and anti-aging agents of the polymer, mainly a titanium-based ultraviolet absorber;

- as an inorganic coloring pigment, pigments of yellow, red, blue, blue, black, lilac, green and other colors selected from the group of: including:

iron oxide yellow, ocher, iron oxide red, iron oxide, iron blue, chromium pigment, etc.

- end walls of corner stones are made on adjacent sides and perpendicular to each other;

- the thickness of the walls and dividing walls is 8-15 mm;

- the number of holes in the walls is 3-4 pairs;

- the diameter of the mounting holes is 5-6 mm.

In the future, the utility model is illustrated by a brief description of its specific implementation and drawings, where: in Fig. 1 shows a view of the stone from the side of the longitudinal wall, in Fig. 2 - the same, bottom view, in Fig. 3 - angular building stone (top view) .

The building stone contains longitudinal 1 and end 2 walls defining the through cavity 3. In the cavity 3 there is a vertical dividing partition 4 dividing the specified cavity 3 into two parts. 3-4 pairs are made above and below in the side (in this example) walls 1 (depending on the size and configuration of the stone of the blind mounting holes 5 for pins (shown). The diameter of the holes is 5-6 mm and the depth is 20-25 mm, which is selected from the condition of the strength of the walls of the stone and the strength of the assembled wall, a protrusion 6 is made on one of the end walls 2 of each stone, and a corresponding groove 7 is made on the opposite end wall, so that when assembling the protrusion 6 of one stone enters the groove of another stone. In the embodiment, the grooves and protrusions can only be made longitudinally 1 walls or on longitudinal 1 and end walls. Slots 7 and protrusions 6 are made along the entire height of the walls. The width of the protrusion 6 and, accordingly, the groove 7 is calculated in a known manner based on the strength of the connection. In this example, when the stone is 200 mm wide, the protrusion width and the groove, respectively, amounted to 60 and 62 mm, the thickness of the walls and dividing walls

8-15 mm. With a smaller thickness, the walls of the stone can bend. With a greater thickness, the safety margin exceeds the standardized and unnecessarily spent more material, which increases the cost of construction.

Building stones are made by pressing in molds of the appropriate configuration under a pressure of at least 100 tons. For the manufacture of stones using a thermoplastic material of the following composition (wt.%):

polymer 20.0-30.0 mineral filler 65.0-75.0 stabilizing additives 2.0-5.0

The mixture is prepared according to known technology.

In this case, one or several polymers from the group including polyethylene, polypropylene, polyethylene terephtholate, polystyrene, polyamide, polyolefins are used as the polymer in the preparation of the mixture.

When the polymer content in the mixture in an amount exceeding 30%, the mixture will be excessively viscous, which reduces the bearing capacity of the products. When the polymer content in the mixture in an amount less than 20%, the filler will not be fully bound, the material after pressing will be excessively brittle, which reduces its strength.

A similar effect when the filler content, respectively, less than 65% and more than 75%.

The amount of stabilizing additives is selected in a known manner, in accordance with the amount of polymer in the mixture. As a polymer, recycled materials (products from soft and hard polymer: film, bottles, buckets, etc.) can be used. As a mineral filler, one or a mixture of the following materials is used: quartz sand, clay, talc, crushed stone screening of a fraction of 1-3 mm.

If necessary, 1-5% by weight of an inorganic coloring pigment can be added to the mixture, for example, iron oxide yellow, ocher, iron oxide red, iron minium, iron blue, chromium pigment, chromium oxide, phthalocyanine pigment, soot, pyrite cinder, manganese ore waste etc. The color intensity depends on the amount of pigment added (within the specified limits). In large quantities, the pigment is impractical to add.

2-5% stabilizing additives are added to the mixture. This is shungite concentrate to increase strength and anti-aging agent of the polymer, mainly titanium-based ultraviolet absorber (1-3%). Fireproofing agent - antipyrine up to 5% can be introduced. The amount of additives calculated according to known dependencies.

EXAMPLE 1

For the manufacture of building stone, polyethylene terephthalate was crushed to a fraction of 10 mm, then it was extruded in a known extruder with a shaft rotation speed of 10 rpm, the outlet mass temperature was 200 ° C. After cooling, the polymer was crushed again to a fraction of 5 mm. Then 30 kg of crushed polymer was mixed with 65 kg of quartz sand and two kg of schungite concentrate and 2 kg of antipyrine (as a stabilizing additive), the mixture was loaded into a heating and melting unit, and the mixture was heated to 250 ° C with stirring using a screw. The resulting hot mass was filed for pressing by loading a matrix of an appropriate shape and a hollow stone was made at a punch pressure of 120 kg / cm ² and holding for 1 min 30 sec. The thickness of the side walls and dividing walls was 10 mm. In each side wall of the stone, the top and bottom coaxially, facing each other, made during the pressing of eight holes (four on each side) with a diameter of 6 mm and a depth of 25 mm for the assembly pins. The grooves and protrusions were made with a width of 60 mm and 58 mm, respectively, the depth of the groove was 18 mm, and the height of the protrusion was 20 mm.

EXAMPLE 2

The technology is similar to example 1, only the mixture for the manufacture of stone contains 25 kg of polypropylene, 70 kg of quartz sand and two kg of schungite concentrate, 2 kg of anti-aging polymer and 1 kg of antipyrine.

EXAMPLE 3

The technology is similar to example 1, only when mixing the components was added 0.5 kg of iron minium, got red stones.

EXAMPLE 4

The technology is similar to example 1, only as a polymer used secondary raw materials of polyethylene (agglomerate) in an amount of 20 kg, as a filler used clay in an amount of 75 kg, a stabilizer (1 kg of schungite concentrate), 1 kg of anti-aging polymer and 5 kg of antipyrine were added .

EXAMPLE 5

The technology is similar to example 1, only 30 kg of polystyrene were used as polymer, 65 kg of crushed stone screenings, 2 kg were used as filler

schungite concentrate, 2 kg of anti-aging polymer and 3 kg of antipyrine and 0.6 kg of chromium pigment. Received after pressing a building stone of light green color.

EXAMPLE 6

The technology is similar to example 2, only 0.15 kg of phthalocyanine pigment was added, and a building stone of blue color was obtained.

The tests showed that the strength of the stones was 4.69 MPa, the frost resistance of the stones corresponds to the brand F 200 (the strength of the stones after 200 cycles of freezing did not change, weight loss was not detected). In addition, the proposed building stones have a beautiful surface, can be any color. They are chemically inert, i.e. do not collapse under the influence of acids and alkalis when exposed to precipitation. They have very high thermal insulation properties. The thermal insulation of the wall of one row of stones (200 mm thick) corresponds to the thermal insulation of the wall with a thickness of 1200 mm from known stones.

The walls of the proposed stones are erected as follows: the stones are fastened together horizontally by means of a groove-ledge connection, and vertically by means of pins (not shown) entering the holes of the upper surface of the longitudinal walls of the lower row and the holes of the lower surface of the side walls of the upper row. In this case, it is not necessary to fasten the stones with a solution, which significantly reduces the cost of construction and the time of erection of walls.

It should also be noted that the use of recycled polymer raw materials for the manufacture of building stones also significantly reduces the cost of construction.

The stone works as follows: heat is transferred from the inner surface of the heated room when the temperature of the outside air is lowered through the inner side wall and the air gap to the outer side wall. Heat is transmitted through the air layer by thermal radiation due to the thermal conductivity of the air and due to its convection. In this case, the dimensions of the cavities, due to the size of the stone and its wall thickness, are calculated in a known manner, so that the thermal resistance provides the heat flux, in accordance with the latest standards, no more than 15 W (m ² h).

Thus, the implementation of the stone with through voids can significantly reduce the thermal conductivity of the erected walls.

The execution of grooves and protrusions on the end walls or on all the walls of the stones, and inside the longitudinal (if necessary also end) walls — holes located coaxially and towards each other allows you to quickly “assemble” the wall without the use of fastening solutions, which speeds up and reduces the cost of construction.

The implementation of building stones from a thermoplastic composite material consisting of a mixture of polymer or polymer waste, filler (sand, clay, gravel sifting) and stabilizing additives and dyes makes it possible to reduce the cost of construction compared to the construction of composite stones with individual voids made from Portland cement. The manufacture of stones by pressing without closing the voids simplifies the process, especially compared to the process of manufacturing stacked stones with voids, which must be closed from the open side, and fasten parts of the stacked stones together.

Claims (13)

1. Building stone with longitudinal and end walls and with a cavity open from below, characterized in that the cavity is made through and has at least one vertical dividing wall that divides the cavity into separate parts, and the stone is additionally equipped with elements for fastening it to other stones during masonry, while the stone is made of thermoplastic composite material in the following ratio of components, wt.%: Polymer 20.0-30.0 Mineral filler 65.0-75.0 Stabilizing additives 2.0-5.0 2. The building stone according to claim 1, characterized in that the elements for fastening the stones are made in the form of a protrusion on at least one wall and a groove on the opposite wall, and several vertical blind mounting holes located in the walls coaxially and towards each other to a friend. 3. The building stone according to claim 2, characterized in that the grooves and protrusions are made along the entire height of the walls. 4. The building stone according to claim 2, characterized in that the thickness of its walls and dividing walls is 8-15 mm. 5. The building stone according to claim 2, characterized in that 3-4 pairs of said blind holes are made in the walls. 6. Building stone according to claim 5, characterized in that the diameter of the blind holes is 5-6 mm 7. Building stone according to claim 1, characterized in that the end walls of the corner stones are made on adjacent sides and perpendicular to each other. 8. The building stone according to claim 1, characterized in that at least one polymer from the group comprising polyethylene, polypropylene, polyethylene terephtholate, polystyrene, polyamide, polyolefins is used as the polymer. 9. Building stone according to claim 1, characterized in that at least one of the following materials is used as a mineral filler: quartz sand, clay, talc, crushed stone screening of a fraction of 1-3 mm. 10. The building stone according to claim 1, characterized in that it further comprises an inorganic coloring pigment and a flame retardant, mainly antipyrine, in the following ratio of components, wt.%: Polymer 20.0-30.0 Mineral filler 65.0-75.0 Stabilizing additives 2.0-5.0 Inorganic Coloring Pigment 1.0-2.0 Flame retardant 1.0-5.0 11. The building stone according to claim 1, characterized in that, as stabilizing additives, means are used to increase strength, for example, schungite concentrate and anti-aging agents of the polymer, mainly a titanium-based ultraviolet absorber. 12. Building stone according to claim 1, characterized in that secondary materials can be used as polymer. 13. The building stone according to claim 1, characterized in that at least one pigment from the group consisting of iron oxide yellow, ocher, iron oxide red, iron red oxide, light blue, chromium pigment and can be used as an inorganic coloring pigment. etc.