RU129957U1 - BUILDING EMPTY STONE - Google Patents

Abstract

1. Construction hollow stone in the form of a rectangular parallelepiped with a system of slotted voids and a checkerboard system of their position, consisting of voids of the main and additional lengths and lintels separated from each other along the row by length, characterized in that it has through horizontal voids made in the form of hyperparametric prisms and half-openings, open along the lower or lower and upper bed faces, oriented by the major axis, which is no less than three times the minor axis, parallel to the plane of the wall, separated from each other by about the length of the row with jumpers of constant or variable thickness. 2. A building hollow stone according to claim 1, characterized in that the bed faces of the hollow stone have grooves perpendicular to the side faces. A building hollow stone according to claim 1, characterized in that the lower bed side has a groove aligned with a horizontal through void open to the lower pastel face, and the upper bed side has an installation protrusion along the entire length of the hollow stone, congruent groove. 4. Construction hollow stone according to claim 1, characterized in that the front layer of the hollow stone has an invoiced surface.

Description

The utility model relates to the field of construction, namely, to the production of wall building materials, in particular, to the production of building hollow stones (PC) with a horizontal system of voids (GSP).

The GSP PC formats are known, recommended by GOST 530-2007 (Fig. A.1.17 - Fig. A.1.19), containing between the butt faces of the system of through prismatic voids. An essential feature that combines these PC formats is that three (Fig. A.1.17, Fig. A.1.18) or six (Fig. A.1.19) through voids located between the butt faces have a rectangular cross section and are located inside a rectangular contour formed by ceramic material.

The disadvantage of such forms is that the use of PCs for materials with high thermal conductivity (λ _m ≈ 0.6 ÷ 1.3 W / m ° C) is advisable only from the standpoint of production (material saving) - from the point of view of thermal physics, PCs do not have meaning [Ilyinsky V.M. Building Thermophysics. - M .: "Higher School", 1974. - S. 42]. In addition, PCs have geometrical parameters of voids significantly reducing the bearing capacity, and horizontal “cold bridges” on the material do not significantly reduce the reduced thermal conductivity coefficient λ _pr : λ _pr ≈ (0.70 ÷ 0.85) λ _m , where λ _m - coefficient of thermal conductivity of the material.

The closest in technical essence and the achieved effect and selected as a prototype is a brick (Patent RU 2183710 according to class Е04С 1/00, filed 03.06.1999) with a system of slot voids (SC) and a checkerboard system of their position. The voids are made of the main and additional lengths and are arranged in alternating rows, one of which contains two voids of the main length, and the other contains one cavity of the main length between two voids of additional length, separated from each other by the length of the row with jumpers.

The disadvantage of this form is that the geometric parameters of the alkali alloys declared by the author limit the capabilities of the device to more than three or four rows of voids and, therefore, the effective use of the thermal resistance of air gaps. In addition, the large length of the main voids and their incompatibility in adjacent masonry rows that are adjacent in height reduce the volumetric and spatial strength of the brick.

The technical result of the proposed utility model is to increase the strength, reduce the thermal conductivity and weight of the stone, increase the shear strength of the masonry, increase the consumer qualities of the stone.

The specified technical result is achieved by the fact that the construction PC in the form of a rectangular parallelepiped with a system of slotted voids and a checkerboard system of their position, consisting of voids of the main and additional lengths and separated by jumpers, are through horizontal voids made in the form of hyperparametric prisms and half-openings, open along the lower or lower and upper bed edges, oriented by the major axis, exceeding at least three times the minor axis, parallel to the plane of the wall, separated from each other along the length of the row with jumpers of constant or variable thickness. The bed faces of the PC have grooves perpendicular to the side faces. The lower bed side has a groove combined with a horizontal through void open to the lower pastel side, and the upper bed side has an installation protrusion along the entire length of the PC, congruent to the groove. The front layer of the PC has an invoiced surface.

Hyperparametric (GP) prismatic voids and the topology of their position in the stone ensure compatibility of the walls between the voids along the rows of masonry adjacent in height, which makes it possible to increase the voidness of the PC with minimal attenuation of the cross section - due to this, the thermal conductivity and weight of the stone are reduced.

Figure 1 shows thickened bricks (Fig. 1a and Fig. 1b), an ordinary facing stone (Fig. 1c) and an ordinary stone (Fig. 1d) with textured face faces with GP air layers (VP) having a ratio of the cross-sectional sizes more than three across the direction of the heat flux to dimensions along the direction of the heat flux —Ilyinsky V.M. Building Thermophysics. - M .: "Higher School", 1974. - S. 42.

Figure 2 presents the options for GP cross-sections of the VP:

- figa - elliptical (hyperelliptic) with three parameters a, b, k, described by the equation:

where k is the order of the "hyperellipse": k = 2, 4, 6, ...; a, b - semiaxes of ellipses.

- figb - rectangular with semi-elliptical ends and three parameters of the section: a, b, a _e ;

- figv - cellular with rounding corners and five parameters of the section: a, b, c, R, r.

With the position of the centers of the circumference rounding angles on the horizontal axis of symmetry (Fig.2B, the x axis) we have

where a ₁ = a · b / (b-s) is the auxiliary size.

Figure 3 (for products, in particular, subjected to heat treatment) and figure 4 (for ceramic products subjected to firing) presents the topology of the position of the GP VP in the cross sections of the PC, where: 1 - voids of the main size; 2 - large and 3 - small additional voids; 4, 5 - voids of the extreme ranks of the airspace; 6 - direction of heat flow; 7, 8 - “bridges of cold” based on CPC material.

The dimensions of the stone (figure 3, figure 4) are determined by the following relationships:

where L _to , N _to , In _k - respectively, the length, height and thickness of the PC;

L ₁ , B ₁ , H ₁ - overall dimensions (length, width and height) of small-format, standard brick: L ₁ = 250 mm; B ₁ = 120 mm; H ₁ = 65 mm;

Δ _in , Δ _g , Δ _k - the thickness of the vertical, horizontal and inter-row joints of the "classical" masonry: Δ _in = 10 mm; Δ _g = 12 mm; Δ _k = 10 mm;

K, M, N - size parameters: K = 1; 1.5; 2; M = 3; N = 1, 2, ..., 5.

.GP VP (Fig. 3, Fig. 4) are arranged with alternating i (i = 1, 2, ..., m) rows so that between the two side rows (i = 1 and i = m) of voids at the spoon faces of the PC are alternately located the main row containing n-2 (n = 4, 6 ...) voids of the main length 2a located between two small voids of additional length 2a ₂ , and the additional row containing n-1 voids of the main length located between two small voids of additional length a ₃ , open on the lower or lower and upper bed edges of the PC. In the lateral rows of the GP GP, there are 2n-1 voids 2a ₁ long and

.

The geometric parameters of the PC are connected by dependencies (see figure 3, figure 4):

for the main and additional series of airspace (i = 2, ..., m-1):

for the side rows of the airspace (i = 1 and i = m):

, а₂ - полуоси основных и доборных ГП ВП;where a, a ₁ ,

, and ₂ - semiaxes of the main and additional GP GP;

δ ₁ , δ ₂ , Δ ₂ - the minimum wall thickness at the edges of the stone;

Δ, Δ ₁ , Δ ₃ - the minimum wall thickness between the GP GP in the rows;

δ is the distance between the rows of the GP VP;

δ _g - the thickness of the horizontal adhesive, mortar seam.

, b_э=b) или комбинированные (фиг.4), образованные элементами контура ГП (внутренние части контура) и полуэллипса (части контура, обращенные к боковым граням ПК), описываемого уравнением (1), при этом k=2, а_э=а₁ или

.The cross sections of the side rows of the VP are simple (Fig. 3) are described by equation 1 with k = 2, and _e = a ₁ or

, b _e = b) or combined (figure 4) formed by elements of the contour of the GP (inner parts of the contour) and a semi-ellipse (parts of the contour facing the lateral faces of the PC) described by equation (1), with k = 2, and _e = a ₁ or

.

Cross sections of VP - GP (figure 2), which, with particular values of the parameters of the topology represent:

- hyperelliptic (figa) with plastic molding sand and heat treatment of products;

- "slotted" (fig.2b) - are used for highly plastic molding sand and heat treatment of products;

- "cellular" (pigv) - are used when firing products, the structure of the VP in the PC.

Some geometric, physico-mechanical and thermal characteristics of PCs of various formats are presented in Table 1, where: λ _pr is the reduced coefficient of thermal conductivity of PCs; R _CR - reduced thermal resistance of the PC; k _n - coefficient of volume porosity of the PC:

where a _i , b _i are the parameters of the GP GP (see above); - µ _{I is} the shape factor of the GP VP.

The geometrical dimensions of the PC are adapted to the brick of the normal (single) format (GOST 530-2007, Table 2) and laying on glue.

To increase the reliability and shear strength of PC joints, grooves are created on its bed faces perpendicular to the side faces, when filled with glue, “dowels” are formed that prevent shear - Fig. 5: Fig. 5a is a longitudinal section of a PC, where e is the number of grooves; with - step "keys"; figb is a cross section of the "keys".

Individual variants of the PC shown in Fig.6 - Fig.8:

- on figa shows an ordinary facing silicate PC format B _to / H _to / L _to = 12/10/26 cm with an invaded facade surface;

- Fig.6b, shows an ordinary facing ceramic PC format B _to / H _to / L _to = 12/10/26 cm with an invaded facade surface;

- on figa shows an ordinary silicate PC format B _to / H _to / L _to = 38/23/26 cm with an invaded facade surface;

- Fig.7b shows an ordinary polymer concrete foundation PC of format B _k / H _k / L _k = 38/15/40 cm with an off-front facade surface;

- Fig. 8 shows an ordinary facing silicate PC of format B _k / H _k / L _k = 12/23/52 cm with an invaded facade surface.

In Fig.6 - Fig.8 are indicated: 10 - a groove combined with a void open to the lower pastel face, and a protrusion for the lock connection of rows of masonry adjacent in height; 11 - holes for finger grip; 12 - holes for tick-borne (carrying devices) capture PC.

A wall made of a PC with GSP 38/26 format can fully satisfy the most stringent requirements of heat engineering - R _pr up to 3.80 ° С · m ² / W.

The masonry of PK-12/23/52 and PK-38/23/26 suggests the presence of angular (right and left) PK (CPC) - figa, CPC 12/23/38 × 26. The CPC, which consists of two parts, has the format 12/23/38 or 12/23/26 with GPS systems identical to PCs of the 12/23/52 format. The CPC is carried out by “left” and “right” (the first is a mirror image of the second).

The front layer of the Code of Criminal Procedure, similarly to PK-12/23/52 and PK-38/23/26, has various textured surfaces imitating masonry from: single brick; natural sawn stone; natural chipped stone, etc. FIG. 9b shows a 38/23/38 × 26 CCP format with a single-brick surface baked.

High voidness and overall dimensions of bricks and stones provide a weight acceptable for hand masonry.

The main advantages of the claimed utility model:

- the optimal parameters of the “hyperparametric" VP cross sections and the topology of their position in the stone make it possible to efficiently use the thermal resistance of the VP with a rational ratio of conflicting PC characteristics (thermal resistance - surface and volume strength - weight of the stone), design and fabricate stones with thermal conductivity coefficients significantly lower in Compared with the best known analogues;

- the off-stained surface of the stone allows preserving the “classic” architectural appearance of the structure, increasing the durability of the structures from the PC, and eliminating the plastering of the facade of structures.

A PC can be manufactured at any enterprise specializing in this industry. Such a stone can be widely used in the construction of industrial and civil facilities, i.e. is industrially applicable.

Claims (4)

1. Construction hollow stone in the form of a rectangular parallelepiped with a system of slotted voids and a checkerboard system of their position, consisting of voids of the main and additional lengths and lintels separated from each other along the row by length, characterized in that it has through horizontal voids made in the form of hyperparametric prisms and half-openings, open along the lower or lower and upper bed faces, oriented by the major axis, which is no less than three times the minor axis, parallel to the plane of the wall, separated from each other by about the length of the row with jumpers of constant or variable thickness. 2. Construction hollow stone according to claim 1, characterized in that the bed faces of the hollow stone have grooves perpendicular to the side faces. 3. The construction hollow stone according to claim 1, characterized in that the lower bed side has a groove aligned with a horizontal through void open to the lower pastel face, and the upper bed side has an installation protrusion along the entire length of the hollow stone, congruent to the groove. 4. Construction hollow stone according to claim 1, characterized in that the front layer of the hollow stone has an invoiced surface.

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