RU2054102C1 - Tile for roofing cover - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: tile is made in the form of irregular hexagonal plate and is provided with vertical and horizontal stiffness ribs placed at lower plate surface, through openings originated in a stiffness rib, and a projection placed on one line with vertical stiffness rib. Stiffness ribs are made so that they are smaller than length and width of the plate, and are placed so that flat edge sections are formed between ends of the ribs and lateral plate faces. When one edge section is imposed on another one a gap-free ceiling is formed. EFFECT: gap-free ceiling. 4 cl, 5 dwg

Description

 The invention relates to building materials, and more specifically relates to tiles for roofing, which can be used as a tile coating for roofs of residential and farm buildings in urban and rural areas.

To form the roof of buildings, tile tiles made of various materials are widely used: clay, cement-sand mixture, asbestos cement, glass [1]
Such tiles are usually made with grooves, grooves, longitudinal through holes, channels, protrusions, spikes on the upper and / or lower surface for mutual engagement of the tiles with each other when applying the plates one on top of the other and for mounting on the crate in the process of forming the roof [2]
Also known is a tile for roofing, having a flat plate that is attached to the crate with special nails or by means of spring shaped elements covering one end of the tile with one end of the crate and the other side of the crate [3]
Also known is a tile made in the form of a plate with a flat upper surface and a protrusion on its lower surface for engagement with the roof lath [4]
However, each of the known tiles used to cover the roof has either complex structural design (the presence of various grooves, channels, protrusions, spikes), or complex means for fastening to the crate, and also requires means for sealing the joints. All this reduces the strength of the tiles, complicates their manufacture and mounting on the crate. In addition, such tiles are made in a rectangular or trapezoidal shape and are laid on the crate with a partial overlap one another in each row and a partial overlap of the plates of the superior row on the tiles of the lower row.

 The roof made of such plates has durability, fire resistance, water resistance and frost resistance.

However, the disadvantage of the roof of such plates is the large weight and fragility of the tile. This is due to the presence in the tiles of grooves, gutters, through longitudinal channels, which weakens the cross-section of the tiles. Therefore, to increase the strength of the tiles, the average density of the tile material increases to 2.2-2.3 g / cm ³ , for example, for cement-sand tiles. The execution of tiles with such an average density of the material only leads to an increase in the weight of the tile and does not affect the reduction of the fragility of the tile, especially in the placement of grooves and through channels. All this limits the size of the tiles, which are made in the size of 400x240x10 mm. As a result, a large number of tiles is required for the formation of the roof, and the need to overlap them on one another with an overlap to overlap significantly increases the weight of the roof and requires an increased consumption of material for the manufacture of roof battens.

 The basis of the present invention is the task of creating such a tile for roofing, the constructive implementation of which will increase the rigidity of the tile while reducing the average density of its material, which in turn will reduce its weight and increase dimensions.

 The problem is solved in that in the tile for roofing, made in the form of a plate having a flat upper surface and a protrusion on its lower surface for fixing the tile on the roof lath, according to the invention, the plate is made in the form of an irregular hexagon and is equipped with vertical and horizontal stiffeners placed on the lower surface of the plate along its vertical and horizontal axes, and through holes made in at least one of the stiffeners parallel to the upper surface, and the stiffeners are made in length less than the height and width of the tile and are located so that between the ends of the ribs and the side faces of the tile formed flat edge sections, which, when applying the plates one on top of another, form a gapless overlap. The stiffeners are made reinforced, the protrusion of the plate and the vertical stiffener are placed on the same line. In a tile, the length of each of the opposite faces of the plate is less than the length of each of two adjacent side faces, while the horizontal edge of the plate is symmetrical about the axis connecting the adjacent side faces of each pair, and the vertical edge is symmetrical about the axis passing through the midpoints of two opposite side faces.

 Such a constructive implementation of the tiles ensures the simplicity of their manufacture and mounting on the crate. At the same time, the implementation of stiffeners intersecting in the center of the tile allows to increase the stiffness and strength of the tile over almost its entire area, and reinforcing the stiffeners reinforces the design of the tile to the perceived load.

The implementation of through holes in a vertical or horizontal stiffener parallel to the upper surface of the plate made it possible to significantly simplify the means of fixing the tiles on the crate, as well as to abandon grooves and channels in the tile, as a result, the tile is made over its entire area of the same cross section and accordingly has the same strength. All this, accordingly, allowed to increase the dimensions of the tile without increasing its thickness, which reduced the average density of the tile material to 1.5-1.6 g / cm ³ compared with cement-sand tiles having an average density of 2.2-2.3 g / cm ³ , as a result, the weight of each tile is significantly reduced.

 Placing the protrusion and the vertical stiffener in one line (vertical axis) allows you to fix each of the tiles on the transverse and longitudinal planks of the crate at least three points, which clearly fixes the tiles one relative to the other, keeping the specified pattern in the coating.

 The hexagonal shape of the proposed tile allows the most rational implementation of the laying of tiles during the formation of the roof, given its increased dimensions, which are 1000x1000x10 mm, which significantly exceeds the size of the tiles used.

 Thus, an increase in the strength and dimensions of the tile and a decrease in the average density of the tile material made it possible to reduce the number of tiles used to form the roof; as a result, the amount of tile material going to overlap the tiles one another decreased. This significantly reduced the weight of the roof, and also allowed to reduce the consumption of material for the manufacture of roof battens.

 In FIG. 1 shows a tile for roofing material, general view; in FIG. 2, section AA in FIG. 1; in FIG. 3 section BB in FIG. 1; in FIG. 4 option of placing tiles during coating formation; in FIG. 5 is a view along arrow B in FIG. 4.

 The proposed tile for roofing is made in the form of a plate 1 (Fig. 1-3), having a flat upper surface 2 and a protrusion 3, made on the lower surface 4 of the plate 1 and designed to fix the tiles on the crate 5 (Fig. 4, 5).

The plate 1 (Fig. 1) is made in the shape of an irregular hexagon and is equipped with vertical 6 and horizontal 7 stiffeners, shown in FIG. 1 dotted line and placed on the lower surface 4 of the plate 1, respectively, along its vertical 0-0 and horizontal 0 ₁ -0 ₁ axes, as a result of which the ribs 6 and 7 intersect in the center of the plate 1.

 In the vertical 6 (or horizontal 7) stiffener parallel to the upper surface 2 of the plate 1 are made, for example, two through holes 8 (Fig. 2).

The ribs 6 and 7 of stiffness are made along a length l less than the height h and width h _{1 of the} plate 1, respectively, as a result, the ends of the ribs 6 and 7 are separated from the side faces of the plate 1 at a distance l ₁ . As a result, flat edge sections are formed between the ends of the ribs 6 and 7 and the side faces of the tile, which, when the plates are superimposed, form a gapless overlap, as shown in FIG. 5.

 The ribs 6 and 7 are reinforced, for example, with metal rods 9 or wire, or any other material.

 The protrusion 3 (Fig. 1, 2) of the plate 1 and the vertical stiffening rib 6 are located on one line coinciding with the vertical axis 0-0. The protrusion 3 borders one side face with the side face of the plate 1, and the rod 9 of the rib 6 has a bent end, which is located in the protrusion 3, as shown in FIG. 2.

In a hexagonal plate, two opposite side faces 10 are made in length shorter than the length of each of the other two adjacent pairs of side faces 11, while the horizontal axis 0 ₁ -0 ₁ passes through the edge 12 connecting the adjacent side faces 11 of each pair, and the vertical axis 0-0 passes through the middle of two opposite side faces 10.

 Due to this shape of the plate 1, the tiles are laid rationally on the roof crate 5, as shown in FIG. 4, while the side faces 10 are located along the longitudinal planks 13 of the crate 5.

 For fastening the tiles on the crate 5, fasteners 14 are used (Fig. 5), for example, a wire that is threaded into each through hole 8 and with its ends covers the transverse lath 15 of the lath (or the longitudinal bar 13, if the holes 8 are made in the horizontal stiffener 7 not shown). The ends of the wire are connected together in a knot in any known manner.

 The formation of the roof of the proposed tiles is as follows.

 Laying tiles on the crate during the formation of the roof is carried out in rows, starting from the bottom edge, as well as when laying tiles. In this case, each of the tiles with the protrusion 3 clings to the longitudinal strip 13 of the crate and is fixed with fasteners 14 with a wire that is threaded through the holes 8, covers the transverse strip 15 and connects the ends into a knot. Such fastening allows each tile to be clearly oriented relative to the battens and to maintain the relative position of the tiles, since each of them is fixed at three points: a protrusion and two fasteners.

 When overlaying the next row, tiles are laid with partial overlap on the tiles of the row below, as shown in FIG. 4, 5. In this case, the overlapping of the tiles is gapless, which is facilitated by the edge sections 16 of the tiles, and at the same distance, since the ends of the ribs 6 and 7 serve as stops, limiting the displacement of the tiles relative to one another. The increased dimensions of the tiles allowed to reduce the number of tiles that go to the formation of the roof.

Claims (4)

 1. TILE FOR ROOF COATING, made in the form of a plate having a flat upper surface and a protrusion on its lower surface for fixing tiles on the roof lath, characterized in that the plate is made in the shape of an irregular hexagon and is equipped with vertical and horizontal stiffeners placed at the bottom the surface of the plate along its vertical and horizontal axes, and through holes made in at least one of the stiffeners parallel to the upper surface, the length being vertically o and horizontal ribs are respectively smaller than the height and width of the tile.  2. The tile according to claim 1, characterized in that the stiffeners are reinforced.  3. The tile according to claim 1, characterized in that the protrusion of the plate and the vertical stiffener are placed on the same line.  4. The tile according to claim 1, characterized in that the length of each of the opposite faces of the plate is less than the length of each of two adjacent side faces, while the horizontal edge of the plate is symmetrical about the axis connecting the adjacent side faces of each pair, and the vertical edge is symmetrical about the axis passing through the middle of two opposite side faces.

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