RU2588589C1 - Hollow wall - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction and can be used for construction of buildings, structures, fences. To achieve specified technical result in structure of known hollow wall, housing of which comprises two separate thin outer walls, each of which has thickness equal to width of wall elements, from which they are built, with gap between them filled with porous, low heat-conducting material, wherein wall elements stack arranged in walls of longitudinally, are made round, their housing are in form of rectangular parallelepipeds, equal width and height lateral wall elements are also round, their housings are in form of rectangular parallelepipeds, equal-length, width and height of which equals width and height of longitudinal wall elements masonry, transverse wall elements are built ends in external wall at wall thickness so that opposite ends of these elements form vertical and horizontal rows of ledges arranged in staggered order, on each of inner surfaces of outer walls so, that in each vertical row of ledges they alternate with each other through row of masonry, wherein ledges of one wall are located between projections of other wall without touching latter, third, inner wall made of longitudinal wall elements arranged between two outer walls, separated from them by gaps, and inner lateral wall element, which is equal to width and height of longitudinal wall elements built into third wall across its so that its opposite ends extend outward on each side of said wall to make ledges on them, which are arranged between appropriate ledges outer walls, without touching latter, wherein length of inner cross wall element is equal to double length of transverse wall element outer walls for width of latter.

EFFECT: proposed invention solves task of improving stability, carrying capacity, heat and sound insulation properties of hollow wall, simplifying its installation.

7 cl, 8 dwg

Description

The invention relates to the construction and can be used for the construction of buildings, structures, foundations and fences.

A brick wall is known comprising one wall made of bricks connected to each other. (V. Statsenko “Parts of buildings.” Moscow-Leningrad, 1930, p. 174.).

The disadvantages of such a wall is its excessive strength with the necessary frost resistance, which is uneconomical, because leads to excessive consumption of materials.

A wall is known that contains two separate, adjacent outer walls, 0.5-1 brick thick each with a gap between them of 9-25 cm, filled with some kind of porous, poorly conductive material. For stability, the thin walls are interconnected by iron brackets located in height after 4-5 rows of masonry, and in the plan after 1-1.5 m. The brackets are placed directly in the seams of the masonry and filled with mortar, (see V. Statsenko “Parts of buildings ", Ed. Moscow-Leningrad, 1930, p. 240).

The disadvantages of such a wall is its low stability and inconvenience of installation, because In addition to wall elements, brackets are also required. In this case, you must constantly monitor the location of the brackets.

The closest technical solution to the proposed invention is a hollow wall of the Gerard system. (see V. Statsenko “Parts of buildings.” Moscow-Leningrad, 1930, p. 240).

This wall contains two external separate thin walls with a gap between them, which is filled with porous, poorly conductive heat material. Each of the thin walls has a thickness equal to the width of the masonry wall element. In this case, the wall elements of the masonry are made full-bodied, having the shape of rectangular parallelepipeds, the same in height, width and length. The transverse wall element is made full-bodied, has the shape of a rectangular parallelepiped and is embedded by the ends into the walls to its thickness. Its opposite ends form protrusions on each of the inner surfaces of these walls, staggered. Moreover, in each horizontal row of masonry walls, these protrusions are placed between each other through two wall elements. In each vertical row, said protrusions alternate with each other through a series of masonry. The thin walls are interconnected by means of protrusions of one wall located between the protrusions of another wall. In this case, the protrusions of each of the walls do not touch the opposite walls.

However, the known hollow wall has a number of disadvantages. First of all, it is low stability, bearing capacity of the wall, its thermal and sound resistance, the complexity of its installation.

Structurally, the hollow wall is made in the form of two adjacent thin walls. Each of the thin walls individually has a very narrow footprint and is therefore unstable. To increase the transverse area of the wall support as a whole, thin walls are connected together. Moreover, the total wall thickness is not large and is limited by the length size of the transverse wall elements connecting these walls. Because of this, two thin walls, placed next to each other, have a small transverse area of the support and even interconnected form an unstable structure. A good example is the scaffolding built near the walls for their repair. These forests have a small transverse area of support, and despite the fact that they have a large number of spatial connections, they have low stability at a high height. Therefore, they are further strengthened.

The bearing capacity of a wall depends on the pressure acting on it and the material of the wall capable of withstanding this pressure. Pressure, as you know, is equal to the effective force assigned to the area over which it presses. The low bearing capacity of the known hollow wall is due to the distribution of load on two thin walls, and sometimes on one having a small total area. Therefore, the specific load on each of the walls is high. Hence its small bearing capacity.

A feature of the construction of hollow walls is that they should not have gaps. Otherwise, the wall will be blown and its thermal insulation properties will be low. The known hollow wall contains only one cavity bounded by thin walls. These walls consist of identical, small-sized wall elements. Therefore, in each horizontal row of the masonry of such a wall there is a large number of joints between its constituent wall elements. With such a large number of joints between the wall elements, it is difficult to avoid cracks in the walls forming a hollow wall. Therefore, the presence in the cavity wall of only one cavity between the walls forming it leads to its purging. In this case, there is no second safety cavity in the known wall.

In addition, the known wall element has only one size and shape. This circumstance leads to the fact that when changing the direction of the wall and at the end of its length in length, it is difficult to lay the corner and end of the hollow wall. In other words, it is difficult to complete the continuation of the wall in length (as, for example, for a window or doorway) or lay out the corner of a hollow wall without adjusting the wall elements to the required size (splitting them). Therefore, well-known wall elements and often crack. This is explained by the fact that due to the proportions between the known wall element and the width of the known hollow wall in these places, it is impossible to place these wall elements as a whole without splitting them. Its length will either not be enough, or part of this wall element will protrude beyond the wall. When cracking wall elements, in order to maintain the desired size, an even greater number of joints between them arise in the walls. In addition, the cleaved surface may be uneven. All these circumstances further increase the likelihood of cracks in the walls, and hence their blowing. Thus, the thermal insulation properties of the wall as a whole are significantly impaired.

As mentioned above, the thickness of the known hollow wall is limited. Its overall size is less than the sum of the lengths of two transverse wall elements. This limitation is caused by the dimensions of these wall elements. If the thickness of a known hollow wall is increased at least to a size equal to two lengths of the transverse wall element, then the protrusions of the opposite walls will come out of the joint with each other and there will be no connection between the walls. Due to the limited thickness of the known hollow wall, its thermal resistance is low. This is due to the fact that there is only one heat-insulating cavity between the walls. In addition, the path of cold from one wall to another, which runs through the protrusions of the walls, which are formed by transverse solid wall elements connecting them, is not great. The thermal conductivity of these bonds is good, so the cold from one wall through these short “cold bridges”, being little absorbed, is transmitted and distributed over the area of the opposite wall.

The sound insulation of the known hollow wall is also small due to the fact that, as mentioned above, the thickness of the known hollow wall is limited. Moreover, the wall structure includes only one cavity with soundproofing material. Because of this, the noise level drop is negligible.

For the construction of a hollow wall, a large number of small-sized wall elements are required, which must be laid down. In addition, due to the structural features of the wall and the proportions between the dimensions of the wall elements and the wall thickness when installing a hollow wall, wall elements must often be adapted to the dimensions of the hollow wall. For these works, it is necessary to spend additional time and money. All this taken together complicates, makes the installation of the famous hollow wall laborious.

When creating the “hollow wall” invention, the goal was to achieve such a technical result as increasing: stability, bearing capacity, heat and sound insulation properties of the hollow wall; simplification of its installation.

In order to achieve the indicated technical result, the body of the known hollow wall contains two separate thin external walls, each of which has a thickness equal to the width of the wall elements of which they are built, with a gap between them filled with porous, poorly heat-conducting material, while masonry elements placed longitudinally in the walls are made solid, their bodies look like rectangular parallelepipeds, identical in width and height, transverse wall elements are also made full their bodies are in the form of rectangular parallelepipeds of equal length, the width and height of which are equal to the width and height of the longitudinal wall elements of the masonry, the transverse wall elements are embedded with the ends into the outer walls to the wall thickness so that the opposite ends of these elements form vertical and horizontal rows of staggered protrusions on each of the inner surfaces of the outer walls so that in each vertical row of protrusions they alternate with each other through a series of cells dyka, while the protrusions of one wall are located between the protrusions of the other wall, without touching the latter, an additional third wall is introduced, made of longitudinal wall elements, placed between two external walls, separated by gaps, and an internal transverse wall element of equal width and height of the longitudinal wall elements, built into the third wall across it so that its opposite ends protrude outward from each side of this wall, forming protrusions on them, which are located between the protrusions of the outer walls corresponding to them, without touching the latter, while the length of the inner transverse wall element is equal to the double length of the transverse wall element of the outer walls minus the width of the latter.

In addition, the transverse wall elements embedded in the outer walls have a length equal to 2.2-2.4 of their width, wall masonry elements placed longitudinally in the walls, are made different in length, and in the horizontal rows of the masonry of each of the three walls protrusions on the surface of the walls formed by transverse wall elements alternate through the length of one of the longitudinal wall elements placed in the walls between the protrusions.

And also for fixed values of the thickness of the hollow wall and the width of the longitudinal wall elements that make up its walls, their lengths have such three different values that in one case two lengths of the longitudinal wall element and one width fit into the value of the thickness of the declared hollow wall in another case, in the thickness value of the declared hollow wall, one length of the longitudinal wall element and its two widths fit, and in the third case its length is equal to the sum of its lengths indicated in the first two cases.

Moreover, to change the direction of the hollow wall, the inner transverse wall element connecting the walls is made curved in half so that its internal angle is equal to the angle of deviation of the wall direction from the straight line, while if the value of the internal angle is equal to the straight line, then the lengths of the sides of the internal transverse wall element are equal the length of the transverse wall element embedded in the outer walls, and are measured from the outside of the curved element; if the value of the internal angle is different from the straight line, then the lengths of the sides of the internal wall element are calculated for each specific value of the angle.

In addition, to change the direction of the hollow wall, the body of the longitudinal wall element is made curved in half so that its internal angle is equal to the difference in the angles of 180 degrees and the angle of deviation of the direction of the wall from straight, while if the value of the internal angle is straight, then the lengths of the sides of this curved longitudinal wall element are measured on the outside of the element and equal to half the difference between the thickness of the declared hollow wall and the width of the longitudinal wall element; if the value of the internal angle is different from the straight line, then the lengths of the sides of the curved longitudinal wall element are calculated for each specific angle value.

As well as the contact surfaces of the transverse and longitudinal wall elements of the walls, they are equipped with means for fixing the position of these elements from displacement in the direction perpendicular to the length of the wall, increasing the stiffness and fracture resistance of the butt joints between the transverse and longitudinal wall elements in the wall masonry.

In addition, a reinforced concrete frame is integrated in one of the two spaces between the walls of the hollow wall, which is closer to the interior, so that its main supports are placed in the corners of the wall, and the intermediate supports are placed in the cavity of the wall between the main supports, while the horizontal reinforced , the reinforced concrete belt separating the first floor of the building from the second connects the supports into a single whole, and the adjacent wall gap is located between the inner wall of the hollow wall and its wall in contact street, filled with a porous, poorly heat conductive material, isolates the frame from the outside, besides, the vertical walls of the hollow column formed by opposite walls of the hollow wall and the vertical rows of the projections of these walls, are non-removable formwork for the vertical supports of reinforced concrete frame.

The presence in the proposed hollow wall of a distinguishing feature from the aforementioned known wall, such as the additional introduction of the third inner wall into the wall housing, made of longitudinal wall elements placed between two outer walls, separated by gaps, and an internal transverse wall element of equal width and the height of the longitudinal wall elements embedded in the third wall across it so that its opposite ends protrude outward from each side of this wall, forming on them the protrusions that are placed between the corresponding protrusions of the outer walls, without touching the latter, while the length of the inner transverse wall element is equal to the double length of the transverse wall element of the outer walls minus the width of the latter allows to achieve a technical result such as increased stability, bearing capacity, thermal and acoustic resistance of the wall, as well as simplification of its installation.

Increasing the stability of the wall occurs because a third, internal wall is added to the construction of the known wall, increasing the transverse area of the support of the claimed wall on the foundation. In this connection, the outer two walls with the inner, third wall on each side are equal. This is due to the fact that the length of the inner transverse wall element is equal to the double length of the transverse wall element of the outer walls minus the width of the latter. This proportion of this element allows these bonds to be symmetrical about the axis of symmetry passing along the middle of the declared wall, and therefore equal. This ensures equal stability of each of the walls of the claimed hollow wall. An additional introduction to the construction of the known wall of the third wall increases both the area of its support on the foundation and the area of its contact with the load acting on it. This reduces the load acting on each of the walls, increasing the bearing capacity of the wall.

In addition, the introduction into the design of the known hollow wall of the inner, third wall divides the gap between its walls into two isolated cavities (chambers), while the thickness of the wall as a whole increases. This additional second cavity, when it is backfilled with a porous, poorly conductive material or filled with foam, increases the thermal insulation properties and the soundproofness of the hollow wall. At the same time, the filling of the hollow cavities of the claimed wall with foam eliminates the presence of any cracks in the wall in general, thereby preventing their purging. Therefore, the filling of the hollow cavities of the wall with foam is more preferable than filling them with a porous substance. In addition, an additional introduction to the construction of the known wall of the internal transverse wall element embedded in the third wall allows you to connect all the walls together into a single whole. This increases the absorption of cold by the increased mass of the wall, as its heat capacity increases. In this case, the path of cold from the outer surface of the claimed wall to its inner surface becomes larger by the length of the inner transverse wall element. Thus, the heat and sound insulation of the claimed wall is increased.

For the convenience of mounting a hollow wall to the end surfaces of the transverse wall elements connecting the walls to each other, as an embodiment, heat-insulating gaskets (for example, foam) are attached, which separate each protrusion of these elements from one wall from the contact with the surface of the opposite wall. In another embodiment, thermally insulating gaskets are attached only to the inner vertical surfaces of the longitudinal wall elements. In this case, each protrusion of the transverse wall element from one wall is separated from contact with the surface of the opposite wall, in this case already insulating gaskets, which are attached only to the inner vertical surfaces of the longitudinal wall elements. Thermal insulating gaskets can be included with the listed wall elements, and can be attached to them in advance.

Placing insulation and soundproofing material in the voids between the three walls allows you to build a wall cheaper and easier, because funds are saved for installation work related to the insulation of the outer side of the wall, and for plastering.

The presence in the proposed hollow wall of a distinctive feature from the above-mentioned known wall, indicating that the transverse wall elements embedded in the outer walls have a length equal to 2.2-2.4 of their width, wall masonry elements placed longitudinally in the walls are made different in length, the protrusions formed in the horizontal rows of masonry of each of the three walls by transverse wall elements, alternate through the length of one of the longitudinal wall elements located in the walls between the protrusions, which allows to bend such a technical result as increasing stability, bearing capacity, thermal and acoustic resistance in the proposed hollow wall, as well as simplifying its installation.

The execution of the lengths of the transverse wall elements in proportion to their width as 2.2-2.4 (for known transverse wall elements this ratio is 2) allows you to have a large contact area of the contact surfaces of the transverse wall elements embedded in the outer walls with the contact surfaces of the internal transverse wall elements, with a fixed value of the thickness of the hollow wall. Therefore, the connection of the walls with each other by means of transverse wall elements in the claimed hollow wall is stronger than in the known one, which increases the stability of the wall.

The execution of the wall masonry elements placed longitudinally in the walls, different in length, when alternating the protrusions formed on the surfaces of these walls by transverse wall elements in the horizontal rows of the masonry of each of the three walls, through the length of one of the longitudinal wall elements placed between adjacent protrusions in each wall, allows you to reduce the number of joints between the wall elements in each of the walls. A feature of the construction of hollow walls is that they should not have gaps, otherwise the wall will be blown through. Therefore, the fewer joints in the wall between its constituent elements, the better. This increases the integrity of the wall. This reduces the likelihood of cracks in the joints between the elements that make up the walls. Due to this, the heat and sound insulation properties of the hollow wall are increased and its installation is simplified, because to build a wall from large wall elements is easier and faster than from small ones. In addition, the use of longitudinal wall elements of different lengths for mounting a hollow wall makes it possible to increase the interval between the vertical rows of protrusions on the inner surfaces of the walls. Thus, the wall, as it were, is stretched in length, and thereby the number of joints between the wall elements is thinned out within reasonable limits, without prejudice to the strength of the wall. Thinning the number of wall connections between each other in the wall makes the wall generally more economical, because material consumption is reduced. Faster is its installation, which simplifies its construction.

The presence in the proposed hollow wall of a distinctive feature from the above-mentioned known wall, indicating that for fixed values of the thickness of the hollow wall and the width of the longitudinal wall elements that make up its walls, their lengths have such three different values that in the first case, the value the thickness of the declared hollow wall is laid two lengths of the longitudinal wall element and one of its width, in the second case, in the value of the thickness of the declared hollow wall, one length of the longitudinal wall is laid about the element and its two widths, and in the third case its length is equal to the sum of its lengths specified in the first two cases, it allows to achieve such a technical result as increasing thermal and acoustic resistance and simplifying its installation.

This is because the indicated proportions between the dimensions of the declared longitudinal wall elements and the thickness of the declared hollow wall make it possible to place these wall elements in the walls that make up the hollow wall, when laying the corners and ends of the wall as a whole, without sawing them. This, firstly, simplifies the installation of the wall, and secondly, reduces the number of joints in the wall, thereby preventing the appearance of cracks in the wall. Due to the above, the wall properties indicated in the technical result are achieved, such as increasing thermal insulation, sound insulation and simplifying the installation of the wall.

The presence in the proposed hollow wall of a distinctive feature from the above-mentioned known wall, indicating that for changing the direction of the hollow wall, the inner transverse wall element connecting the walls is made curved in half so that its internal angle is equal to the angle of deviation of the wall from the straight line, when moreover, if the value of the inner angle is equal to the straight line, then the lengths of the sides of the inner transverse wall element are equal to the length of the transverse wall element embedded in the outer walls u, measured from the outer side of the curved element; if the value of the internal angle is different from the direct one, then the lengths of the sides of the internal wall element are calculated for each specific value of the angle, which allows achieving such technical result as increasing the stability, thermal and acoustic resistance of the wall and simplifying its installation.

This is due to the fact that the element of complex shape is made monolithic, and not composite, which eliminates the appearance of cracks in the corner of this element. In this case, the body of the inner transverse wall element in a monolithic version is harder than the composite version of this element, and therefore more stable. It becomes easier to change the direction of the wall to a given project. It all comes down to the fact that a corner element is simply attached to the wall, which rotates the direction of the wall to the desired one. In addition, the specified length of the sides of this individual element at a right angle of rotation of the wall eliminates the need for fitting wall elements under each other by splitting them to rotate. This simplifies the installation of the wall and allows you to increase the heat-insulating, sound-proofing properties of the wall.

The presence in the proposed hollow wall of a distinctive feature from the above-mentioned known wall, indicating that for changing the direction of the hollow wall, the casing of the longitudinal wall element is made curved in half so that its internal angle is equal to the difference in angle of 180 degrees and the angle of deviation of the direction of the wall from rectilinear, while if the value of the internal angle is equal to the straight line, then the lengths of the sides of this curved longitudinal wall element are measured from the outside of the element and equal about half the difference between the thickness of the declared hollow wall and the width of the longitudinal wall element; if the value of the internal angle is different from the direct one, then the lengths of the sides of the curved longitudinal wall element are calculated for each specific value of the angle, which allows achieving such technical result as increasing the stability, thermal and acoustic resistance of the wall and simplifying its installation.

This is due to the fact that the element of complex shape is made in advance in the desired shape and monolithic, and not composite, which eliminates the appearance of cracks in the corner of this element. In this case, the body of the inner transverse wall element in a monolithic version is harder than the composite version of this element, and therefore more stable. It becomes easier to change the direction of the wall to a given project. It is enough to attach a monolithic corner to the straight wall, turning it in a given direction. In addition, the specified lengths of the sides of this element at a right angle of rotation of the wall eliminate the need for fitting wall elements to each other by splitting them to rotate. All of the above allows us to simplify the installation of the wall, to increase its heat-insulating and sound-insulating properties.

The presence in the proposed hollow wall of a distinguishing feature from the aforementioned known wall, indicating that the contact surfaces of the transverse and longitudinal wall elements of the walls are provided with means for fixing the position of these elements from displacement in the direction perpendicular to the length of the wall, increasing rigidity and resistance to fracture of butt joints between the transverse and longitudinal wall elements in the masonry of the wall, it is possible to achieve such a technical result as increasing the stability of the bearing lities wall and simplify its installation.

The specified technical result is achieved, for example, by grooves made on the planes of the longitudinal and transverse wall elements in contact with each other, for placement in the space formed by these grooves when connecting the longitudinal and transverse wall elements, embedded segments of the reinforcement. The above grooves are located on the contact surfaces of the listed wall elements so that when mounting a hollow wall in a masonry, they are oriented along the wall, one above the other. In the space formed by the grooves of the connected wall elements, reinforcement segments are laid. They make it possible to fix the position of these wall elements from displacement in the direction perpendicular to the length of the wall, increase the stiffness and fracture resistance of the butt joints between the transverse and longitudinal wall elements in the wall masonry, thereby increasing the bearing capacity of the wall. This is due to the fact that the wall elements of the masonry are not able to change their position in the wall in the direction perpendicular to the length of the wall. The pieces of reinforcement placed in the space formed by the grooves of the connected wall elements do not allow them to change this position. Therefore, thin walls of a hollow wall, consisting of longitudinal wall elements and interconnected by transverse wall elements, cannot diverge when installing the wall to the sides. This increases the stability of the wall as a whole. Embedded segments of reinforcement to increase stiffness and fracture resistance of butt joints between transverse and longitudinal wall elements in the masonry walls are placed at the junction of these wall elements with each other. This increases the bearing capacity of the wall, because the fracture resistance of the butt joints between the transverse and longitudinal wall elements in the wall masonry from the load acting on it increases. If, in the space formed by the grooves of the wall elements to be connected, when installing the hollow wall, not reinforcement segments are placed, but whole reinforcement rods along the thin walls, then pouring concrete into the gaps between the thin walls, we obtain a reinforced foundation. Thus, it becomes easier to build a wall without having special skills for this. The above increases the stability, the bearing capacity of the wall and simplifies its installation, which was indicated in the achieved technical result.

The presence in the proposed hollow wall of a distinctive feature from the above-mentioned known wall, indicating that in one of the two spaces between its walls, located closer to the internal premises, a reinforced concrete frame is built in such a way that its main supports are located in the corners of the wall, and the intermediate the supports are placed in the hollow space of the wall between the main supports, while the horizontal reinforced, reinforced concrete belt separating the first floor of the structure from the second connects the supports into a single whole, and the adjacent the wall gap located between its inner wall and the wall in contact with the street, filled with porous, poorly heat-conducting material, isolates this frame from the external environment, moreover, the vertical walls of the hollow column formed by the opposite walls of the hollow wall and the vertical rows of protrusions of these walls are a fixed formwork for vertical supports of a reinforced concrete frame, it allows to achieve such technical result as increasing stability, bearing capacity of the wall and simplifying it installation.

The introduction into the device of the hollow wall of the reinforced concrete frame built into it allows the design of the hollow wall to significantly increase its strength and rigidity, while maintaining its thermal insulation properties. At the same time, the horizontal reinforced reinforced concrete belt located in the hollow wall and connecting the supports into a single unit has two versions. In one case, interfloor slabs are laid on its outer surface, and in the other case, it is itself a continuation of a monolithic, poured reinforced concrete slab. In addition, all the wall elements of the masonry of the hollow wall due to the reduction of the load acting on them are made thinner, i.e. in a lightweight version. This significantly reduces the consumption of materials for the manufacture of wall elements of the masonry of a hollow wall. In addition to the fact that mounting a wall is cheaper in this case, it is even more simple and convenient, because partially eliminates the need for formwork, wall masonry elements become easier and more convenient to work with. The above increases the bearing capacity, stability of the wall and simplifies its installation, while maintaining the thermal and sound insulation properties of the hollow wall, which was indicated in the achieved technical result.

All declared wall elements of a hollow wall are made of concrete, but at the same time they can be made of any material suitable in strength for a given wall structure.

The proposed hollow wall is illustrated by drawings, where on:

FIG. 1 shows a masonry diagram (top view) of an even row of the claimed hollow wall and the right angle of the wall from the claimed wall elements;

FIG. 2 shows a masonry diagram (top view) of an odd row of the claimed hollow wall and a right angle of the wall from the claimed wall elements;

FIG. 3 shows a diagram of the masonry of an obtuse corner of the wall (top view) of an even row of masonry of the claimed hollow wall from the claimed wall elements;

FIG. 4 shows a diagram of the masonry of an obtuse corner of the wall (top view) of an odd row of masonry of the claimed hollow wall from the claimed wall elements;

FIG. 5 shows a diagram of the masonry of an acute angle of the wall (top view) of an even row of masonry of the claimed hollow wall from the claimed wall elements;

FIG. 6 shows a diagram of the masonry of an acute angle of the wall (top view) of an odd row of masonry of the claimed hollow wall from the claimed wall elements;

FIG. 7 shows a segment of a masonry scheme (top view) of the claimed hollow wall with the image of options for attaching thermally insulating gaskets to the wall elements and the location of the grooves on the contact surfaces of the longitudinal and transverse wall elements, the placement of segments of reinforcement in them;

FIG. 8 shows a cross-sectional diagram of the claimed hollow wall with the image of the space formed by the grooves of the contact planes of the longitudinal and transverse wall elements when they are connected, to accommodate embedded segments of the reinforcement.

The body of the hollow wall (see Fig. 1-8) contains two separate thin outer walls 1; 2, each of which has a thickness equal to the width of the wall elements 10; eleven; 12 of which they are built. Wall elements 10; eleven; 12 masonry placed longitudinally in the walls, made solid, their bodies are in the form of rectangular parallelepipeds, the same in width and height. The transverse wall elements 5 are also made solid. Their bodies have the form of rectangular parallelepipeds, the same in length, the width and height of which is equal to the width and height of the longitudinal wall elements of the masonry 10; eleven; 12. The transverse wall elements 5 are integrated by the ends into the outer walls 1; 2 to the wall thickness. The opposite ends of these elements 5 form vertical and horizontal rows of protrusions 6. The protrusions 6 are staggered on each of the inner surfaces of the outer walls 1; 2. Moreover, in each vertical row of protrusions 6, they alternate with each other through a series of masonry.

The third, inner wall 7, made of longitudinal wall elements 10; eleven; 12, placed between two outer walls 1; 2 and separated from them by gaps 3; 8 filled with porous, poorly heat-conducting material 4. The inner transverse wall element 9 is equal in width and height to the longitudinal wall elements 10; eleven; 12. It is embedded in the inner third wall 7 across it. The opposite ends of the inner transverse wall element 9 protrude outward from each side of this wall 7, forming protrusions 6. The length of the inner transverse wall element 9 is equal to the double length of the transverse wall element 5 of the outer walls 1; 2 minus its width. The protrusions 6 of each of the walls 1; 2; 7 are located between their respective protrusions 6 opposite walls, without touching the latter. For ease of installation of the hollow wall to the end surfaces of the transverse wall elements 5; 9, connecting walls 1; 2; 7 with each other, as an embodiment, thermally insulating gaskets 22 are attached (for example, foam), which separate each protrusion 6 of these elements 5; 9 from one wall from contact with the surface of the opposite wall. In another embodiment, thermally insulating gaskets 23 are attached only to the inner vertical surfaces of the longitudinal wall elements 10; eleven; 12. In this case, each protrusion 6 formed by transverse wall elements 5; 9, from one wall it is separated from the contact with the surface of the opposite wall in this case by heat-insulating spacers 23, which are attached only to the inner vertical surfaces of the longitudinal wall elements 10; eleven; 12. Thermal insulation pads 22; 23 may be included with the listed wall elements 5; 9 and 10; eleven; 12, but can be attached to them in advance.

In addition (see Fig. 1; 2), transverse wall elements 5 embedded in the outer walls 1; 2, have a length equal to 2.2-2.4 of the size of their width. Wall elements of masonry 10; eleven; 12, placed longitudinally in the walls, are made different in length. The protrusions 6 formed in the horizontal rows of masonry of each of the three walls 1; 2; 7 transverse wall elements 5; 9 alternate through the length of one of the longitudinal wall elements 10; eleven; 12, placed in the walls 1; 2; 7 between the protrusions.

And also (see Fig. 1; 2) at fixed values of the thickness of the hollow wall and the width of the longitudinal wall elements 10; eleven; 12, of which its walls 1 consist; 2; 7, their lengths have such three different meanings that in the first case, two lengths of the longitudinal wall element 10 and one width fit in the thickness value of the declared hollow wall, in the second case, one length of the longitudinal wall element 11 and two fit in the thickness value of the declared hollow wall its width, and in the third case, the length of the declared wall element 12 is equal to the sum of the lengths of the elements 10 and 11 specified in the first two cases.

Moreover, to change the direction of the hollow wall (see Fig. 1-6), the inner transverse wall element 13 connecting the walls 1; 2; 7, is made curved in half so that its internal angle is equal to the angle of deviation of the direction of the wall from straight. Moreover, if the value of the internal angle is equal to the straight line, then the lengths of the sides of the inner transverse wall element 13 are equal to the length of the transverse wall element 5 embedded in the outer walls 1; 2, and are measured from the outside of the curved element 13; if the value of the internal angle is different from the straight line, then the lengths of the sides of the internal wall element 13 are calculated for each specific value of the angle.

In addition, to change the direction of the hollow wall (see Fig. 1-6), the casing of the longitudinal wall elements is made curved in half. Its internal angle is equal to the angle difference of 180 degrees and the angle of deviation of the direction of the wall from the rectilinear. Moreover, if the value of the internal angle is equal to the straight line, then the lengths of the sides of this curved longitudinal wall element are measured from the external side of the element. They are equal to half the difference between the thickness of the declared hollow wall and the width of any of the longitudinal wall elements 10; eleven; 12. If the value of the internal angle is different from the straight line, then the lengths of the sides of the curved longitudinal wall element are calculated for each specific value of the angle.

And also (see Fig. 7; 8) the contact surfaces of the transverse 5; 9 and longitudinal 10; eleven; 12 wall elements of the walls 1; 2; 7 are equipped with means for fixing the position of these elements from displacement in the direction perpendicular to the length of the wall, increasing the rigidity of the butt joints between the transverse 5; 9 and longitudinal 10; eleven; 12 wall elements in masonry walls, for example, due to grooves 18 made on the planes of longitudinal 10; eleven; 12 and transverse 5; 9 wall elements in contact with each other for placement in the space 19 formed by these grooves 18 when connecting the longitudinal 10; eleven; 12 and transverse 5; 9 wall elements, embedded segments of reinforcement 20. If in the space 19 formed by the grooves 18 of the connected wall elements 5; 9 and 10; eleven; 12, when installing the hollow wall, place not the reinforcement sections 20, but the whole reinforcement bars 21 along the thin walls 1; 2; 7, then, filling in gaps 3; 8 between the thin walls 1; 2; 7 concrete, we get a reinforced foundation.

In this case (see Fig. 1; 2) in the gap 3 between the walls 1; 7, located closer to the internal premises, a reinforced concrete frame 15 is integrated in such a way that its main supports 16 are located in the corners of the wall, and the intermediate supports 17 are placed in the hollow space 3 of the wall between the main supports 16. In this case, a horizontal reinforced, reinforced concrete belt separating the first floor of the building from the second, connects the supports 16; 17 into a single whole. The adjacent wall gap, located between its inner wall 7 and the wall 2 in contact with the street, filled with porous, poorly heat-conducting material 4, isolates this frame 15 from the external environment. The vertical walls of the void column formed by the opposite walls 1; 7 of the hollow wall and the vertical rows of protrusions 6 of these walls, are fixed formwork for vertical supports 16; 17 reinforced concrete frame 15.

Hollow wall work

The work of a hollow wall on stability when exposed to a load occurs as follows. Walls 1; 2; 7 hollow walls, interconnected transverse 5; 9 wall elements, located strictly vertically. The force from the load acts on the hollow wall from above, distributed over the area of the hollow wall on which this load rests. In this case, the pressure on the foundation from the load is transmitted by three walls 1; 2; 7, consisting of longitudinal wall elements 10; eleven; 12, and transverse wall elements 5; 9, connecting the walls 1; 2; 7. Contact surfaces transverse 5; 9 and longitudinal 10; eleven; 12 wall elements of the walls 1; 2; 7 provided with grooves 18 made on the planes of the longitudinal 10; eleven; 12 and transverse 5; 9 wall elements in contact with each other for placement in the space 19 formed by these grooves 18 when connecting the longitudinal 10; eleven; 12 and transverse 5; 9 wall elements, embedded segments of reinforcement 20. Grooves 18 are located on the contact surfaces of the listed wall elements 5; 9 and 10; eleven; 12 so that when mounting a hollow wall, they are oriented in masonry along the wall, one above the other. In the space 19, formed by the grooves 18 of the connected wall elements 5; 9 and 10; eleven; 12, reinforcement segments are laid. They allow you to fix the position of the wall elements 5; 9 and 10; eleven; 12 from displacement in a direction perpendicular to the length of the wall. Embedded segments of the reinforcement 20 are placed in the places of the butt joints between the transverse 5; 9 and longitudinal 10; eleven; 12 wall elements in the masonry wall to increase stiffness and resistance to kink of the joints of these wall elements with each other. This increases the stability and bearing capacity of the wall. This is due to the fact that the wall elements 5; 9 and 10; eleven; 12 masonry are not able to change their position in the wall in the direction perpendicular to the length of the wall. The segments of the reinforcement 20, placed in the space 19, formed by the grooves 18 of the connected wall elements 5; 9 and 10; eleven; 12, do not give them the opportunity to change this situation. Therefore, thin walls 1; 2; 7 hollow walls, consisting of longitudinal 10; eleven; 12 wall elements and interconnected transverse 5; 9 wall elements, can not be diverged when mounting the walls to the sides, which increases the stability of the wall. The placement of embedded segments of the reinforcement 20 in the places of the butt joints between the transverse 5; 9 and longitudinal 10; eleven; 12 wall elements in the masonry of the wall increases the rigidity and resistance to kink of the joints when exposed to the wall load. This increases the bearing capacity of the wall. If in the space 19 formed by the grooves 18 of the connected wall elements 5; 9 and 10; eleven; 12, when installing the hollow wall, place not the reinforcement sections 20, but the whole reinforcement bars 21 along the thin walls 1; 2; 7, then, filling in gaps 3; 8 between the thin walls 1; 2; 7 concrete, we get a reinforced foundation.

Another of the criteria for the stability of the wall is its transverse area of the support. A wall consisting of three separately located walls 1; 2; 7 combined by transverse 5; 9 wall elements in one rigid structure, has a wider area of support on the foundation than the famous wall. Therefore, the claimed wall is more stable compared to the known. In addition, the pressure acting on a wall is defined as the ratio of the force to the surface area on which it acts. The introduction of the third wall 7 in the design of the hollow wall increases the surface area and the area of its support on the foundation. This decreases the specific pressure on each of the walls 1; 2; 7 from the effect of cargo on them. This increases the bearing capacity and stability of the hollow wall (the latter was indicated as a technical result in the description of the "Summary of the invention"). In addition, the implementation of the claimed hollow wall with two gaps 3; 8 between the three walls 1; 2; 7 allows the reinforced concrete frame 15 to be embedded in it. Vertical main supports 16 of this frame are built into the inner cavity cavity 3 of the wall at the corners of the building, and intermediate supports 17 with calculated distances between them are built into the gap 3 between the inner 1 and middle 7 walls between the main supports 16 A horizontal reinforced reinforced concrete belt located in a hollow wall connects the supports 16; 17 into a single whole. On its outer surface, floor slabs are laid in one case, and in the other case, it is itself a continuation of a monolithic, poured reinforced concrete floor. The design of the hollow wall due to the integration of reinforced concrete frame 15 in one of the spaces 3 between the walls 1; 7 of a hollow wall significantly increases its strength and stability, while maintaining its thermal insulating properties of the neighboring gap 8, which is filled with porous, poorly heat-conducting material 4. The claimed hollow wall when subjected to a load on stability when embedded in a reinforced concrete frame 15 is much superior these parameters are at the famous wall. At the same time, the sound and heat insulation properties of a wall with a frame 15 are no worse than these properties of a wall without a frame.

The work of a hollow wall with temperature and acoustic effects on it occurs as follows. Three separately located walls 1; 2; 7 at intervals of 3; 8 between them form two successive cameras isolated from each other. The chambers are filled with heat and sound insulating material, for example expanded clay or foam. Therefore, when sound vibrations pass through them, they quickly decay. At the same time, the poor thermal conductivity of these materials retains heat for a long time. Heat loss through jumpers formed by individual wall elements 5; 9, connecting the walls 1; 2; 7 among themselves compared with the known hollow wall, is negligible. This is due to the increase in the path of the cold from the outer surface of the hollow wall to its inner surface due to the additional introduction of the third wall 7 with the inner transverse wall element 9. The path of the cold from the outer surface of the declared wall to its inner surface becomes longer by the length of the declared internal transverse wall element 9. Thus, the two-chamber hollow wall is a reliable protection against thermal and acoustic effects I am on it (the latter was indicated as a technical result in the description of the "Summary of the invention").

Gaps 3; 8, separating the third, inner wall 7 from two outer 1; 2, if necessary, have uneven sizes. This change may be local in nature, for example, for the installation of some equipment inside the wall. The total thickness of the hollow wall in this case remains the same or can be changed. In the usual case, these gaps are 3; 8 equal. If necessary or for other reasons, wall 1; 2; 7 can be made different in thickness. Hence the wall elements that make up walls 1; 2; 7, will have different thicknesses, the remaining sizes of these elements remain unchanged. As usual, the thickness of all wall elements 10; eleven; 12 and, accordingly, three walls 1; 2; 7 is the same.

Claims (7)

1. A hollow wall, the casing of which contains two separate thin outer walls, each of which has a thickness equal to the width of the wall elements of which they are built, with a gap between them filled with porous, poorly conductive heat material, while the masonry wall elements placed the walls are longitudinally made full-bodied, their bodies are in the form of rectangular parallelepipeds, identical in width and height, the transverse wall elements are also full-bodied, their bodies are in the form of rectangular parallelepipeds in the same length, the width and height of which is equal to the width and height of the longitudinal wall elements of the masonry, the transverse wall elements are embedded with the ends into the outer walls to the wall thickness so that the opposite ends of these elements form vertical and horizontal rows of staggered protrusions , on each of the inner surfaces of the outer walls in such a way that in each vertical row of protrusions they alternate with each other through a series of masonry, while the protrusions of one wall are located between blunting the other wall, not touching the latter, characterized in that a third, inner wall made of longitudinal wall elements, placed between two outer walls, separated by gaps, and an internal transverse wall element of equal width and height is additionally introduced into the wall casing longitudinal wall elements embedded in the third wall across it so that its opposite ends protrude outward from each side of this wall, forming protrusions on them, which are located between their respective the protrusions of the outer walls, without touching the latter, while the length of the inner transverse wall element is equal to the double length of the transverse wall element of the outer walls minus the width of the latter. 2. A hollow wall according to claim 1, characterized in that the transverse wall elements embedded in the outer walls have a length equal to 2.2-2.4 times their width, the masonry wall elements placed longitudinally in the walls are made different in length , the protrusions formed in the horizontal rows of masonry of each of the three walls by transverse wall elements alternate through the length of one of the longitudinal wall elements placed in the walls between the protrusions. 3. The hollow wall according to claim 2, characterized in that for fixed values of the thickness of the hollow wall and the width of the longitudinal wall elements that make up its walls, their lengths have such three different values that in the first case, the thickness of the declared hollow wall is laid two lengths of the longitudinal wall element and one width thereof, in the second case, in the value of the thickness of the declared hollow wall, one length of the longitudinal wall element and its two widths are laid, and in the third case, its length is equal to the sum of its lengths, indicated in the first two cases. 4. A hollow wall according to claim 1, characterized in that for changing the direction of the hollow wall, the inner transverse wall element connecting the walls is made curved in half so that its internal angle is equal to the angle of deviation of the wall from the straight line, while if the value of the internal angle equal to the straight line, the lengths of the sides of the inner transverse wall element are equal to the length of the transverse wall element embedded in the outer walls, and are measured from the outside of the curved element; if the value of the internal angle is different from the straight line, then the lengths of the sides of the internal wall element are calculated for each specific value of the angle. 5. A hollow wall according to claim 1, characterized in that for changing the direction of the hollow wall, the casing of the longitudinal wall element is made curved in half so that its internal angle is equal to the difference of the angles of 180 degrees and the angle of deviation of the direction of the wall from straight, if the value of the internal angle is equal to the straight line, the lengths of the sides of this curved longitudinal wall element are measured on the external side of the element and are equal to half the difference between the thickness of the declared hollow wall and a longitudinal wall element; if the value of the internal angle is different from the straight line, then the lengths of the sides of the curved longitudinal wall element are calculated for each specific angle value. 6. The hollow wall according to claim 1, characterized in that the contact surfaces of the transverse and longitudinal wall elements of the walls are equipped with means for fixing the position of these elements from displacement in the direction perpendicular to the length of the wall, increasing the rigidity and fracture resistance of the butt joints between the transverse and longitudinal wall elements in the masonry wall. 7. The hollow wall according to claim 1, characterized in that in one of the two spaces between its walls, located closer to the internal premises, a reinforced concrete frame is built in such a way that its main supports are placed in the corners of the wall, and the intermediate supports are placed in the hollow gap walls between the main supports, with a horizontal reinforced, reinforced concrete belt separating the first floor of the structure from the second, connects the supports into a single whole, and the adjacent wall gap, located between its inner wall and the wall, is a contact guide street, filled with a porous, poorly heat conductive material, isolates the frame from the outside, besides, the vertical walls of the hollow column formed by opposite walls of the hollow wall and the vertical rows of the projections of these walls, are non-removable formwork for the vertical supports of reinforced concrete frame.

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