RU58126U1 - CONCRETE RAIN TRAIN (OPTIONS) - Google Patents

Abstract

Concrete storm water inlet tray refers to devices for collecting and draining water from ground road surfaces. The utility model solves the problem of increasing the strength properties of the tray and the possibility of its manufacture by pressing technology. The problem is solved in that the concrete inlet tray, in cross section, has a rectangular profile of the outer surface and a U-shaped profile of the inner surface, together forming longitudinal side walls with horizontal supporting surfaces of width t in the upper part of the inlet tray, while on one of the end surfaces at least one protrusion is made of the storm inlet tray, and at least one depression reciprocal in shape and location is made on the second end surface of the storm inlet tray ozhdeniyu ledge along limiting relative movement of adjacent trays in the coupling plane of their end faces, wherein the minimum thickness of the bottom tray dozhdepriemnogo A is selected from t 1.2 ÷ 2.0 range. The shape and dimensions of the protrusions and depressions on the end surfaces of the concrete tray can be different while providing specified strength characteristics of adjacent trays paired with each other during operation.

Description

The utility model relates to devices for collecting and draining water from ground pavements and can be used for landscaping yards, squares, gardens, parks, etc., for the formation of pedestrian zones, sidewalks, bicycle paths, etc.

A German patent is known No. 19526985, IPC7 E 01 11/22, 01/13/2000. The element of the rainwater channel according to this patent contains a concrete inlet tray in cross section having a rectangular profile of the outer surface and a U-shaped profile of the inner surface, together forming the upper part of the storm water inlet, longitudinal lateral sides with horizontal supporting surfaces. In addition, the element is equipped with two removable U-shaped nozzles made of a metal profile mounted on the sides of the storm water inlet tray, which on the outer surface forms a horizontal abutment surface under the metal grill. Nozzles are installed on the sides of the trays with a gap and are fixed with latches. And on the inner surface of the side flanges of the tray, niches are made for accommodating the thrust plate of the metal grid lock. The trays can dock with each other according to the principle: a protrusion is a depression, forming a rainwater channel. The disadvantages of this channel element include the difficulty of manufacturing a concrete tray with sides equally thick in height and with niches for nozzle latches and a lock. In addition, this profile of the concrete tray, as well as the small supporting surface for the metal grill, leads to its rapid destruction.

As a prototype, as closest to the claimed element of the rainwater drainage channel, the rainwater intake tray of the surface rainwater drainage channel according to the RF patent No. 2189419, IPC 7 E 01 C 11/00; E 01 C 11/22, publ. September 20, 2002

The concrete inlet tray, in cross section, has a rectangular profile of the outer surface and a U-shaped profile of the inner surface, together forming in the upper part of the stormwater inlet

tray longitudinal side walls with horizontal supporting surfaces of width t. In this case, protrusions are made on one of the end surfaces of the storm inlet tray, and depressions are made on the second end surface of the storm inlet chutes. The storm water inlet according to this patent is characterized by a certain profile geometry. Namely: the distance between the lateral sides of the tray in the upper part, the height of the sides, their shape, as well as the minimum thickness of the bottom of the concrete receiving tray, selected from the range of 0.9 ÷ 1.1 t. The protrusions on the concrete gutter tray are placed symmetrically in the corners at the bottom of its end and are made in the form of a triangular truncated pyramid with a height equal to or more than 8 mm. The geometry of this concrete storm water inlet tray was selected taking into account the technology of its manufacture by casting.

The disadvantages of the bottom tray include the insufficient thickness of its bottom, since when manufacturing a concrete tray by pressing technology, it is possible to destroy the bottom of the tray during its manufacture or operation.

This utility model solves the problem of increasing the strength properties of the tray and the possibility of its manufacture by pressing technology. In addition, it allows you to increase the life of the element of the storm water channel with the optimal geometry and dimensions of the concrete tray. The utility model also solves the problem of expanding the range of concrete inlet trays.

The problem is solved in that the concrete inlet hopper, in cross section, has a rectangular profile of the outer surface and a U-shaped profile of the inner surface, together forming longitudinal side flanges with horizontal supporting surfaces of width t in the upper part of the storm inlet, while on one of the end surfaces at least one protrusion is made of the storm inlet tray, and at least one depression reciprocal in shape and location is made on the second end surface of the storm inlet tray ozhdeniyu ledge along limiting relative movement of adjacent trays in their mating plane end surfaces, wherein the minimum thickness of the bottom tray dozhdepriemnogo Δ is chosen from the range 1.2 ÷ 2.0 t

In order to simplify the production of a concrete chute by pressing, as well as to increase its operational characteristics, it is advisable to lend the lateral sides of the inlet chute in the profile along the inner surface to its bottom at an angle a of 6 ° ÷ 20 ° and mate them together with each other in radius.

The shape and dimensions of the protrusions and depressions on the end surfaces of the concrete tray can be different while providing specified strength characteristics of adjacent trays paired with each other during operation.

In a particular case, a protrusion in the form of a truncated pyramid with a height of 6 ÷ 12 mm is made in the central lower part of the end surface of the concrete tray, and the larger base of the pyramid adjacent to the end surface of the storm inlet tray is made in the form of an isosceles trapezoid with a height of 0.3 ÷ 0, 6 Δ and a large base, selected from the range of 2.5 ÷ 5.5 t. The lateral sides, the trapezoid are inclined to the larger base at an angle β = 30 ° ÷ 60 °, while one side face of the protrusion lies in the same plane as the outer surface of the bottom of the storm water inlet tray, and the side faces of the protrusion, conjugated with the end surface of the storm inlet tray, are inclined to it at an angle γ = 35 ° ÷ 55 °.

Two protrusions can be made on the end surface of the concrete tray, placed symmetrically at the corners in the lower part of the end of the storm inlet tray and made in the form of a triangular truncated pyramid with a height of 6 ÷ 12 mm, and the larger base of the pyramid adjacent to the end surface of the storm inlet tray is made in the form of a rectangular isosceles triangle, whose equal sides have a length selected from the range of 1.2 ÷ 2.5 t. Two lateral faces of each pyramid lie in the same plane, respectively, with the lateral outer surface and with the outer surface of the bottom of the storm water inlet tray, and the third side of the pyramid is inclined to the end surface of the storm water inlet tray at an angle γ = 35 ° ÷ 55 °.

In the lower part of the end surface of the tray, a ledge with a height of 6 ÷ 12 mm can be made in the form of a truncated pyramid, the larger base of which

made in the form of a non-convex polygon symmetric to the longitudinal axis of the end surface of the tray, with a width in the central part selected from the range 0.2 ÷ 0.5 Δ, and at the corners at the bottom of the end of the rain-receiving tray with a width uniformly increasing to the sides of the tray to a value equal to 1 , 2 ÷ 2.5 t. The corresponding lateral faces of the protrusion lie in the same plane with the lateral external surfaces and with the outer surface of the bottom of the storm inlet tray, and the lateral face of the protrusion, conjugated with the end surface of the storm inlet tray, is inclined to it at an angle γ = 35 ° ÷ 55 °.

The examples of protrusions given do not exhaust other possible options for their execution.

In any case, for any form of protrusions, in the corresponding longitudinal sections of the concrete tray, the depth and width of the depression are greater than at least 1 mm in height and width of the corresponding protrusion.

In FIG. 1: a), b), c) presents options for the execution of concrete storm water inlet tray, top view; figure 2 - the same options - view from the side of the end surface where the protrusion is located; figure 3 - shows a longitudinal section aa of the inlet tray.

The concrete storm water inlet tray 1, in cross section, has a rectangular profile of the outer surface and a U-shaped profile of the inner surface 2, together forming longitudinal lateral sides 3 in the upper part of the storm inlet tray with horizontal supporting surfaces 4 of width t. The lateral sides 3 of the storm water inlet tray in the profile are tapered to its bottom 7 at an angle α equal to 6 ° ÷ 20 ° and are interconnected along the radius R. At least one protrusion 5 is made on one of the end surfaces of the storm water inlet, and at least one depression b is made on the second end surface of the storm inlet tray in response to the shape and location of the protrusion 5. The bottom 7 of the storm inlet tray 1 has a minimum thickness selected from the range 1.2 ÷ 2.0 t.

The protrusion 5 can be made in the form of a truncated pyramid 8 (Figure 1-a and Figure 2-a), and the larger base of the pyramid adjacent to the end surface of the rain-receiving tray is made in the form of an isosceles trapezoid,

height equal to 0.3 ÷ 0.6 Δ and a large base, selected from the range of 2.5 ÷ 5.5 t.

On the end surface of the concrete tray, two protrusions 9 can be made, placed symmetrically at the corners in the lower part of the end of the storm receiving tray 1 (Fig. 1-b and Fig. 2-b). In this case, the protrusions 9 are made in the form of a triangular truncated pyramid, and the larger base of the pyramid adjacent to the end surface of the storm inlet tray is made in the form of a rectangular isosceles triangle, whose equal sides have a length selected from the range 1.2 ÷ 2.5 t.

The protrusion can be made in the form of a truncated pyramid 10 (Fig. 1-c and Fig. 2-c), the larger base of which is made in the form of a non-convex polygon symmetric to the longitudinal axis of the end surface of the tray, with a width in the central part selected from the range of 0.2 ÷ 0.5 Δ, and at the corners in the lower part of the end of the storm water inlet tray with a width that uniformly increases towards the sides of the tray to a value equal to 1.2 ÷ 2.5 t.

The specific size of the width t of the horizontal supporting surfaces 4 of the longitudinal lateral sides 3 of the concrete inlet tray 1 is selected taking into account the strength properties of concrete and in practice may be 15 ÷ 30 mm. The length of concrete tray 1 may vary.

The indicated geometrical parameters of the protrusions are optimal for ensuring their shaping by pressing and ensuring the strength properties of the “lock”: the protrusion is the depression of the tray during its operation.

The concrete inlet tray 1 can be equipped with two removable U-shaped nozzles made of a metal profile (not shown) mounted on its sides 4.

The assembly of the rainwater channel from the storm water inlets is as follows. Concrete inlet trays 1 are laid in a previously dug trench in such a way that they are joined by the end surfaces of the protrusion 5 of one tray and the cavity 6 of the other tray on the basis of the "protrusion-cavity" principle. The implementation of the protrusion 5 with the inclination of its face to the end surface allows you to align the supporting surface 4 of the side

sides 3 of the mating concrete receiving trays 1 on one surface while maintaining the support of one tray with another.

The selected range of the minimum thickness of the bottom Δ = 1.2 ÷ 2.0 t of the inlet tray, on the one hand, allows the production of a high-quality durable product by pressing, and on the other hand, minimizes the consumption of concrete material for the manufacture of trays.

During the operation of the surface rainwater channel, rainwater freely enters the concrete inlet tray 1 and is discharged into the sewer or other collection tank.

Compared with the well-known rainwater drainage channels, this concrete storm water inlet tray, with its structural simplicity, has increased strength properties, which allows it to withstand heavy loads and extend its life.

Claims (10)

1. Concrete storm water inlet tray, characterized in that it has a rectangular profile of the outer surface and a U-shaped profile of the inner surface in cross section, together forming longitudinal side flanges with horizontal supporting surfaces of width t in the upper part of the storm inlet, in the central lower part of one of the end surfaces of the storm inlet tray are made a protrusion in the form of a truncated pyramid adjacent to the end surface of the storm inlet tray, the larger base of which has the shape of an isosceles trapezoid, moreover, one side face of the protrusion lies in the same plane with the outer surface of the bottom of the storm water inlet tray, and the side faces of the protrusion are conjugated with the end surface of the storm water inlet tray and tilted to it at the same time, while a shape reciprocal depression is made on the second end surface of the storm inlet tray and the location of the protrusion, together with it restricting the relative movement of adjacent trays in the plane of interface of their end surfaces. 2. The tray according to claim 1, in which the minimum bottom thickness Δ of the inlet tray is selected from a range of 1.2 ÷ 2.0t. 3. The tray according to claim 1, in which the side walls in the profile along the inner surface are tapered to its bottom at an angle of 6 ÷ 20 ° and are interconnected along the radius. 4. The tray according to claim 1, in which the protrusion is made of a height equal to 6 ÷ 12 mm, while in the corresponding longitudinal sections of the tray, the depth and width of the depression is greater than at least 1 mm of the height and width of the protrusion. 5. The tray according to claim 2, in which the trapezoid of the larger base of the pyramid adjacent to the end surface of the inlet tray is made of a height of 0.3 ÷ 0.6 Δ and a large base selected from the range of 2.5 ÷ 5.5 t, side the sides of the trapezoid are inclined to its larger base at an angle of 30 ÷ 60 °, and the side faces of the protrusion, conjugated with the end surface of the storm water inlet tray, are inclined to it at an angle of 35 ÷ 55 °. 6. Concrete storm water inlet tray, characterized in that it has a rectangular profile of the outer surface and a U-shaped profile of the inner surface in cross section, together forming longitudinal side flanges with horizontal supporting surfaces of width t in the upper part of the storm inlet tray, at the bottom of one of the end the surface of the inlet tray is made a protrusion in the form of a truncated pyramid, the larger base of which is made in the form of a non-convex polygon symmetrical to the longitudinal axis of the end surface and a tray, a width that uniformly increases from the central part to the sides of the tray, while the corresponding side faces of the protrusion lie in the same plane with the side external surfaces and with the outer surface of the bottom of the storm inlet tray, and the side face of the protrusion, conjugated with the end surface of the storm inlet tray, tilted to it at an angle, while on the second end surface of the storm water inlet tray, a depression is made that is responsive in shape and location to the protrusion, together with it limiting relative Extension of adjacent trays in the interface plane of their end surfaces. 7. The tray according to claim 6, in which the minimum bottom thickness Δ of the inlet tray is selected from the range of 1.2 ÷ 2.0t. 8. The tray according to claim 6, in which the side walls in the profile along the inner surface are tapered to its bottom at an angle of 6 ÷ 20 ° and are interconnected along the radius. 9. The tray according to claim 6, in which the protrusion is made of a height equal to 6 ÷ 12 mm, while in the corresponding longitudinal sections of the tray, the depth and width of the depression are greater than at least 1 mm of the height and width of the protrusion. 10. The tray according to claim 7, in which the non-convex polygon of the larger base of the pyramid in the central part has a width selected from the range 0.2 ÷ 0.5 Δ, and at the corners a width that uniformly increases towards the sides of the tray to a value of 1.2 ÷ 2.5 t, while the lateral edge of the protrusion, conjugated with the end surface of the storm water inlet tray, is inclined to it at an angle of 35 ÷ 55 °.