RU201324U1 - TRAY FOR COLLECTION AND REMOVAL OF WATER FROM THE PASSAGE - Google Patents

Abstract

The utility model relates to trays for systems for collecting and removing water from the roadway. The chute is made with a one-piece monolithic body in the form of an elongated straight parallelepiped having an upper part, side walls and a bottom, and with through culverts. Inside the central part of the body there is a longitudinal partition with a longitudinal axial plane, which, together with the side walls of the tray, forms two internal longitudinal channels with longitudinal axes and longitudinal axial planes, while the cross-section of the partition together with the profile of the upper part of the tray and the profile of the tray bottom, located between the longitudinal channel axes, has an I-beam profile, and part of the bottom and the upper part of the tray, located between the longitudinal axial planes of the channels, form I-beam flanges, and the longitudinal partition - the I-beam wall. Through culverts are made in the upper part of the chute body on both sides of the axial longitudinal plane of the partition and above each longitudinal channel, and the ends of the chute partition are made with recesses. The technical result of the utility model consists in a significant increase in the strength properties of the tray for longitudinal loads or, while maintaining the strength properties, a significant decrease in the thickness of the upper part, side walls and weight of the tray, or while maintaining the weight of the tray and its strength properties, an increase in the flow area of the drainage channels. 4 p.p. f-ly, 4 dwg

Description

The tray for systems for collecting and removing water from the roadway is an element of the surface drainage channel and is designed to collect and drain water from ground road surfaces in the drainage system.

Known prefabricated drainage elements made of concrete, reinforced concrete, polymer concrete, polymer or other composite material, for example, according to RF patent No. 138279, IPC E01C 11/22, IPC E03F 3/00, published 03/10/2013 for the useful model "Module drainage system "and RF patent No. 151170, IPC Е01С 11/22, published 03/27/2015 for the useful model" Element of the surface drainage channel ". Both utility models contain two elements: a lower element - a U-shaped tray and a flat top element made with the possibility of supporting on the walls of the lower element. In the upper element, through culverts of slotted, cellular or point configuration can be made. The thickness of the upper element is selected depending on the material from which it is made and the class of standard load on it. The disadvantages of these utility models include insufficient strength when used on the carriageway. This limits the width of the channels of the drainage elements by increasing the support surface for the top element and due to the thickness of the top element. In addition, there may be cases of displacement of the upper element relative to the lower one when the car hits the drainage element.

Known RF patent No. 2471915, IPC E01C 11/22, published on January 10, 2013 for the invention "drainage element". The drainage element is made in the form of a one-piece monolithic part, that is, as a whole and has a single massive body. The body has a drainage channel for water drainage. The body has two opposite ends intended for connection with drainage elements of an identical design. When the elements are joined on the upper side of the body, formed by the part that closes the drainage channel from above, there is at least one inlet, i.e. perforation or a recess open at the end, so that when two drainage elements are assembled, two recesses of both elements located opposite each other form one hole, the larger size of which is oriented transversely to the drainage element. Due to the perforations, it becomes possible to drain surface water into the drainage channel. The part of the body that covers the drainage channel from above is made in the form of a vault, that is, the overlap above the drainage channel to the middle of the channel or drainage element becomes thinner. At its thinnest point, the height of the vault is at least 10% of the height of the drainage element. The disadvantages of this design include the insufficient strength of the entire structure due to transverse through slots for water drainage and a thinned central part of the upper part of the body.

As the closest analogue (prototype), the "Slotted drainage tray" was selected according to the utility model patent No. 102360, IPC E03F 3/04, published on February 27, 2010. The slotted drainage tray is made of reinforced concrete in the form of a solid monolithic part - an extended straight parallelepiped with an internal channel, in cross-section, having a rectangular profile of the external surface and an oval profile of the internal surface of the channel, with a continuous intermittent or non-intermittent culvert longitudinal slit of minimum thickness located in the upper part of the chute. In order to avoid clogging of the longitudinal through slot of the drainage tray, it is performed with a narrowing towards the outer surface of the tray. Due to the placement of the through culvert slot longitudinally to the axis of the drainage chute and its minimum width, its strength is higher than that of the previous analogue. However, its strength properties are still insufficient to ensure high throughput. This is due to the fact that the maximum stress in this tray is created on the inner side of its upper part, as well as on the side walls, since they work in tension when bending.

The objective of this utility model is, all other things being equal (properties of the materials from which the trays are made, external dimensions, weight, etc.), a significant increase in the strength properties of the tray for longitudinal loads. Or, while maintaining the strength properties, a significant decrease in the thickness of its upper part and side walls, and, consequently, the weight of the tray. It is possible, while maintaining the weight of the tray and its strength properties, to increase the flow area of the drainage channels.

Thus, the utility model makes it possible to increase the reliability of the drainage system, formed from the proposed trays that are capable of withstanding heavy loads with a large culvert capacity.

The task is solved by the fact that in the tray for the systems for collecting and removing water from the roadway, made with a one-piece monolithic body in the form of an extended rectangular parallelepiped having an upper part, side walls, a bottom and through culverts, a longitudinal partition with longitudinal axial plane, which together with the side walls of the tray forms two internal longitudinal channels with longitudinal axes and longitudinal axial planes. In this case, the cross-section of the partition, together with the profile of the upper part of the tray and the profile of the bottom of the tray, located between the longitudinal axes of the channels, has an I-beam profile, and the part of the bottom and the upper part of the tray, located between the longitudinal axial planes of the channels, form the shelves of the I-beam, and the longitudinal partition - the I-beam ... Through culverts are made in the upper part of the chute body on both sides of the axial longitudinal plane of the partition and above each longitudinal channel, and the ends of the chute partition are made with recesses.

Through culverts can be made oval with a larger axis of symmetry, oriented longitudinally or transversely to the longitudinal axial plane of the channel.

Through culverts can be made in the form of continuous through slots.

On the outer surface of the side sides of the tray, a longitudinal recess with a depth equal to 0.1 ... 0.5 of the side wall thickness can be made.

The thickness of the partition, which is the wall of the I-beam, is 0.2 ... 1.0 of the thickness of the side wall of the chute, the thickness of the bottom of the chute is 1.0 ... 3.0 of the thickness of the side wall of the chute, and the thickness of the upper part of the chute in the zone of through culverts is 1.0 ... 4.0 thickness of the side wall of the tray, while the thickness of the bottom and top of the tray are made uniformly increasing from the longitudinal axes of the channels to the partition and mating with it along a radius equal to 0.2 ... 3.0 of the thickness of the partition.

The essence of the utility model is illustrated by an example of the proposed tray using the accompanying drawings. FIG. 1 shows the inventive tray in perspective: a) a tray in which the major axis of symmetry of the through culverts is oriented longitudinally to the longitudinal axial plane of the channels; b) - a tray in which the major axis of symmetry of the through culverts is oriented transverse to the longitudinal axial plane of the channels. FIG. 2 shows a view of the formed drainage channel: a) from the trays of FIG. 1 a, b) from the trays of Fig. 1 b). FIG. 3 shows a cross-section of the tray. FIG. 4 shows one of the many options for using the proposed tray in systems for collecting and removing water from the carriageway of roads, in particular with the use of a storm water inlet and drainage system.

Tray 1 for systems for collecting and removing water from the roadway is made in the form of a one-piece monolithic body - an extended rectangular parallelepiped with side walls 2 and 3, bottom 4 and top part 5.

Tray 1 can be made of concrete, reinforced concrete, polymer concrete, fiber reinforced concrete, polymer or other similar composite material. Inside the central part of the body of the tray 1, there is a longitudinal partition 6, which forms with the side walls 2 and 3 of the tray two internal longitudinal channels 7 and 8 having an oval profile. The partition 6 in cross-section, together with the profile of the upper part 5 of the tray and the profile of its bottom 4, which are located between the longitudinal axes O ₁ and O _{2 of the} channels 7 and 8, has an I-beam profile. In this case, part of the bottom 4 and the upper part 5 of the tray 1, located between the longitudinal axial planes O ₁ and O _{2 of the} channels, form the I-beam shelves, and the longitudinal partition 6 - the I-beam wall.

In the upper part 5 of the body of the chute 1 on both sides of the axial longitudinal plane Y of the partition 6 and above each longitudinal channel 7 and 8 there are through culverts 9 and 10.

Through culverts 9 and 10 can be made oval with a larger axis of symmetry oriented both longitudinally (holes 9) and transversely (holes 10) of the longitudinal axial plane Y of the channel.

Through culverts can be made in the form of continuous through slots (not shown).

The ends of the partition 6 of the tray 1 are made with recesses 11, which together with the recess 11 of the adjacent end of the partition 6 of the connected tray form an overflow opening connecting two internal longitudinal channels 7 and 8. In this example, the recess 11 has an oval profile.

On the outer surface of the side sides 2 and 3 of the tray 1 between the bottom 4 and the upper part 5 of the tray 1, a longitudinal recess 12 can be made, which has a U-shaped profile of the channel with horizontal shelves oriented outward and formed by a part of the bottom 4 and the upper part 5 of the tray 1 The depth of the longitudinal recess 12 is equal to 0.1 ... 0.5 of the thickness of the side wall of the tray 1.

Tray 1 can have different geometric dimensions, both in external dimensions and in the thickness of its elements, depending on the provision of the necessary loads and the volume of the drain.

The thickness s of the partition 6, which is the I-beam wall, is advisable to choose from the range 0.2 ... 1.0 of the thickness t _{2 of the} side wall 2 (3) of the tray 1. The thickness t of the bottom 5 of the tray 1 is selected from the range of 1.0 ... 3.0 of the thickness t _{2 of the} side wall 2 (3) of the tray 1. The thickness t _{1 of the} upper part 5 of the tray 1 in the zone of the through culverts 9 and 10 is selected from the range 1.0 ... 4.0 of the thickness t _{2 of the} side wall 2 (3) of the tray 1, when The thicknesses of the bottom 4 and the upper part 5 of the tray 1 increase uniformly from the longitudinal axes O ₁ and O _{2 of the} channels 7 and 8 to the partition 6, mating with it along a radius equal to 0.2 ... 3.0 of the thickness of the partition s.

On the sides 2 and 3 of the tray 1, on its outer surface between the bottom 4 and the upper part 5 of the tray 1, a longitudinal recess 12 with a depth Δ equal to 0.1 ... 0.5 of the thickness t2 of the side wall 2 (3) of the tray 1 can be made.

In particular, a concrete tray can have the following dimensions:

- width b, height h and length L are equal to 500 mm;

- the thickness of the side walls t ₂ is 50 mm;

- bottom thickness t is 70 mm;

- the thickness of the upper part t ₁ is equal to 120 mm;

- the thickness of the partition s is 50 mm;

- radius r of rounding of the inner surfaces of the bottom and the upper part with the partition is 80 mm.

The described exemplary embodiment of the tray cannot be considered a limitation of the scope of legal protection of the proposed utility model. For trays made of polymer concrete, polymer or other similar composite materials, the thickness of the tray elements can be significantly less while maintaining the strength properties of the trays.

Within the framework of the features set forth in the claims of the utility model, other versions of the example described above are possible.

The connection of the trays 1 to each other during the formation of the drainage system can be carried out in a standard way, for example, by means of protrusions and corresponding depressions made on the opposite ends of the trays 1. The proposed tray 1 can be used both individually and in assembly with other drainage elements, easily being built in into complex drainage systems (see Fig. 4).

During the operation of the surface drainage system formed from the proposed tray 1, rainwater freely enters through the through culverts 9 and 10 into the internal channels 7 and 8 and is discharged into the sewage system or other collecting containers.

In case of clogging of holes 9 or 10 above one of the channels 7 or 8, it will still work thanks to the overflow holes formed by the recesses 11 at the ends of the partition 6 of the trays 1.

The main advantage of tray 1 with partition 6 is stress transfer from the inner side of the upper part of the tray and from the side walls 2 and 3 to the central partition 6, which has an I-beam profile. This design of tray 1 allows it to withstand stresses up to 10 times greater, because stresses change from tensile bending in trays without a partition to compressive stresses for a tray with a partition. Tray 1 with a central partition 6 surpasses the load capacity of a tray without a central partition due to its shape, namely, the presence of a central partition, the selection of the radius and thickness of the walls of the product, which makes it possible to make products lighter in weight in the ratio from 1.5 to 2 times, while provide the required load class. With equal strength (the same material) and throughput properties of the proposed tray with a central partition and a tray without a partition, the weight of the proposed tray can be reduced by 65% -70%.

Claims (5)

1. Tray for systems for collecting and removing water from the roadway, made with a one-piece monolithic body in the form of an extended rectangular parallelepiped having an upper part, side walls and a bottom, and with through culverts, characterized in that a longitudinal partition is placed inside the central part of the body with a longitudinal axial plane, which together with the side walls of the chute forms two internal longitudinal channels with longitudinal axes and longitudinal axial planes, while the cross-section of the partition together with the profile of the upper part of the chute and the profile of the bottom of the chute, located between the longitudinal axes of the channels, has an I-beam profile, moreover, part of the bottom and the upper part of the chute, located between the longitudinal axial planes of the channels, form the flanges of the I-beam, and the longitudinal partition - the wall of the I-beam, while the through culverts are made in the upper part of the chute body on both sides of the axial longitudinal plane of the partition and above each longitudinal channel, and the ends of the tray partition are made with recesses. 2. A tray according to claim 1, characterized in that the through culverts are oval in shape with a larger symmetry axis oriented longitudinally or transversely to the longitudinal axial plane of the channel. 3. A tray according to claim 1, characterized in that the through culverts are made in the form of continuous through slots. 4. A tray according to claim 1, characterized in that a longitudinal recess with a depth equal to 0.1-0.5 of the side wall thickness is made on the outer surface of the sides of the tray. 5. The tray according to claim 1, characterized in that the thickness of the partition, which is the wall of the I-beam, is equal to 0.2-1.0 of the thickness of the side wall of the tray, the thickness of the bottom of the tray is 1.0-3.0 of the thickness of the side wall of the tray, and the thickness the upper part of the chute in the zone of through culverts is equal to 1.0-4.0 of the thickness of the side wall of the chute, while the thickness of the bottom and upper part of the chute is made uniformly increasing from the longitudinal axes of the channels to the partition and mating with it along a radius of 0.2 -3.0 baffle thickness.

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