RU138279U1 - WATER DRAINAGE MODULE - Google Patents

Abstract

1. A drainage module containing a lower element - a U-shaped tray with a tongue-and-groove system at the ends, on the upper part of each of the walls of which a longitudinal groove is made, and a flat upper element made with the possibility of bearing on the walls of the lower element, characterized in that the upper the element is made in the form of a parallelepiped with through culverts, which are chamfered in their upper part, a groove is placed on the ends of the upper element for laying sealant, and two rubber are fixed on one of the ends damping gaskets, and longitudinal grooves are made on the lower surface of the upper element on both sides of the through-flowing holes with the possibility of pairing the outermost of these grooves with the said grooves of the lower element and forming a channel for accommodating a gas-oil-resistant cord designed to fix the upper element relative to the lower. 2. The module according to claim 1, characterized in that the grooves are made semicircular in cross section. The module according to claim 1, characterized in that it is made of concrete or polymer concrete. 4. The module according to claim 1, characterized in that the damper pads at the end of the upper element are made of gas-oil-resistant rubber and fit snugly to the surface of the next upper element when connecting adjacent drainage elements to the drainage system. The module according to claim 1, characterized in that the upper element is located in the body of the road surface and works as a joint construct. The module according to claim 1, characterized in that the height of the upper element varies depending on the internal reinforcement of the product and the class of standard load,

Description

This utility model relates to drainage technology and is a module in the form of a massive case made of concrete or polymer concrete. A drainage channel is located in the housing. The housing has two opposite ends, designed to connect the drainage modules in the drainage system. Moreover, the upper element is installed on the lower element through the rubber damper cord laid in the semicircular groove of the tray. The upper element is laid with a longitudinal offset by half the lower element of the housing. The objective of this utility model is to create a drainage element with the ability to withstand heavy loads and used both individually and in combination with other drainage elements, including with drainage wells, cleaners.

According to the utility model, the housing of the drainage module completely covers the channel, therefore the housing has a very high strength. Unlike other U-shaped drainage elements open from above, on the upper side of which there is a frame for the supporting part of the upper element, this element does not have a frame and is replaced by a semicircular groove with a rubber sealing cord laid in it for laying the upper element on it. The upper element is equipped with through culverts with special chamfers on the front side, providing additional water collection and eliminating chips during operation, as well as longitudinal semicircular drainage grooves on the lower plane to prevent water from entering the interface between the upper housing element and the lower one. In addition, these grooves are assigned to the edges of the upper element for intercepting water passing through the culverts. A rubber damper is laid in a special semicircular groove on the upper plane of the lower element, after which the upper element is installed on the lower element with each upper element pressed against the end damper gasket of the adjacent upper element. The device for sealing the seam between the upper elements is traditionally performed. Therefore, this avoids a large number of additional embedded fasteners and simplifies the installation of the drainage system as a whole.

Known storm water inlet according to European patent 0081741, IPC ⁴ E01C 11/22, 05/07/86, g. The rain inlet tray is made of concrete and has a metal grill and a lock-connection of the metal grill with the tray. The cross-hopper tray made of concrete in cross section has a rectangular profile of the outer surface and a U-shaped profile of the inner surface, which together form longitudinal nozzles in the upper part of the storm hopper and the outer vertical longitudinal bounding protrusions for the metal grill. Niches are made on the inner surface of the side flanges of the tray to accommodate the lock thrust plate for securing the metal grill. The disadvantages of this element include the complexity of manufacturing a concrete tray with such a profile, as well as numerous protrusions, deflections in the metal supporting part of the tray, which increase the possibility of corrosion and reduce the life of the storm water inlet channel.

A known element of the storm water channel according to European patent 0761885, IPC ⁶ E01C 11/22, 03/12/97. It contains a concrete inlet tray, a metal grate and a lock for connecting the metal grate to the tray. The concrete inlet tray has longitudinal side flanges, in the upper part the side flanges have horizontal supporting sections and external vertical longitudinal limiting protrusions of metal for installing a metal grate. Longitudinal limiting protrusions rest on the horizontal supporting sections of the sides of the concrete tray, which significantly complicates the manufacturing technology of the concrete tray, and the support of the metal grid on the longitudinal protrusions with significant loads on the grid leads to the destruction of the concrete tray.

A known drainage element according to patent RU 2471915 (IPC: E01C 11/22, application 2010151512/03, publication date of the application: 06.27.2012, patent - 01.10.2013). This invention relates to a drainage element containing a single massive body. In the housing there is a drainage channel for water drainage. The housing has two opposite ends, designed to connect with drainage elements of identical design. When connecting elements on the upper side of the housing, formed by a part covering the drainage channel from above, there is at least one inlet, i.e. perforation or a recess open at the end, so that when collecting two drainage elements, two recesses of both elements located opposite each other form one hole. Thanks to perforations, surface water can be diverted to the drainage channel. This technical solution has disadvantages, because elements have a small length and significant mass. Due to the small length of the elements, it is often necessary to seal the seams, and a large mass of elements requires special grips during installation and has poor logistics over long distances. Cleaning the closed drainage channel can only be done mechanically and is not always possible. Repair is possible only by dismantling part of the drainage system. These shortcomings significantly limit the possibility of using this drainage system.

Consequently, U-shaped channels with a metal nozzle and a metal grill have the advantage of easy access to the tray and simple mechanical cleaning. However, they have significant problems in the places where the embedded parts are connected to the walls of the concrete tray and in the places where they work together with metal gratings, especially in areas of intense load: the structure generally loses its bearing capacity. The advantage of massive channels can be attributed to the fact that they do not have connecting elements, due to which they are more durable. But at the same time, maintenance and access to the drainage channel are limited, only mechanical cleaning is possible, and in the case of repair, they require a shift of the entire drainage line.

The closest analogue of the claimed device is a drainage module containing a lower U-shaped element with a groove-ridged system at the ends, on the upper part of each of the walls of which a longitudinal groove is made, and a flat upper element made with the possibility of support on the walls of the lower element JP 2001049728 , IPC E03P 5/04, publication date 02/20/2001). Here, the body of the drainage module completely covers the channel, which increases the strength of the channel. However, this device has a drawback consisting in the complexity of the design of the upper and lower elements in terms of connecting them together and fixing relative to each other. This complicates the operation of the drainage system, the dismantling of its elements, and also limits the range of materials for the manufacture of the system. In particular, it makes impossible the use of concrete.

This useful model due to the technical solution and the materials used allows us to solve the problem of servicing culverts and ensure the achievement of the technical result, which consists in increasing the service life of the storm water inlet channel with the simplicity of the structural solution of the entire element of the storm water inlet channel.

The technical result is achieved due to the fact that in the drainage module containing a lower U-shaped element with a groove-ridge system at the ends, a longitudinal groove is made on the upper part of each of its walls, and a flat upper element made with the possibility of support on the lower walls element, the upper element is made in the form of a parallelepiped with through culverts, which are chamfered in their upper part, a groove is made on the ends of the upper element for laying sealant, moreover, on one of the ends CREPLA two rubber damping pads, and the lower surface of the upper member to either side of the through culvert holes formed longitudinal grooves to mate extremes of said grooves with said grooves of the lower element and the formation of the channel for placing benzomaslostojkie cord intended for locking the upper member relative to the bottom.

The grooves can be made semicircular in cross section, and the module itself is made of concrete or polymer concrete.

Damper gaskets on the end face of the upper element are made of gas-oil-resistant rubber and fit snugly to the surface of the next upper element when connecting adjacent drainage elements to the drainage system

The upper element can be located in the body of the road surface and work as a joint construct.

The height h of the upper element is selected depending on the internal reinforcement of the product and the class of standard load perceived by the drainage module.

Figure 1 shows a general view of the proposed drainage module. Figure 2 shows the sharing of the proposed module with other drainage devices.

The problem is solved in that the casing of the drainage module is made of two elements (see Fig. No. 1): 1 - the lower element forming the U-shaped tray is made of concrete or polymer concrete and is equipped with a tongue-and-groove system on both sides (1.1) for fixing trays and the possibility of forming a drainage line. On the upper plane of the walls of the lower element, special longitudinal semicircular grooves (1.2) are made for laying a rubber damper cord (1.3) in them, which performs the function of sealing and damper gasket between the upper and lower elements of the drainage body. The upper housing element (2) is made of concrete or polymer concrete with through-holes (2.1), which in the upper part have bevels (2.2), which increase the throughput and prevent chips during operation. On the lower plane of the upper element there are longitudinal semicircular recesses (2.3) to prevent the penetration of water between the upper and lower elements of the housing. On opposite ends in the upper part of the upper element there is a shaping groove (2.4) for laying the sealant. At one end, the upper element is equipped with two rubber damper gaskets (2.5) that absorb longitudinal braking loads.

New in the claimed drainage element, first of all, is the technical solution for pairing the lower element with the upper element, namely: on the upper plane of the walls of the lower element there is a solid rubber oil and petrol resistant cord, under which longitudinal semicircular grooves are made in the lower element, which form a single groove throughout drainage system. When installing the upper element on the lower element on this cord, the upper element can not move freely and is fixed due to its mass and high roughness of the oil-resistant cord. The lower plane of the upper element is provided with longitudinal recesses, which serve as droppers and do not allow moisture to enter at the interface between the lower and upper elements. Damper gaskets located at one of the ends of the upper element allow the most comfortable installation of the upper element on the drain line. After installation, the groove, which is formed between two adjacent upper elements, must be sealed to prevent moisture from entering, especially in the autumn-winter period. The novelty also applies to the use of end damper gaskets, the main function of which is to extinguish the energy of longitudinal braking of a vehicle located directly on the drainage housing. In the process of extinguishing braking energy, two structural elements are involved - a damper cord and a damper gasket. With a sharp longitudinal loading, the upper element is inverted (lifted) and the end damper gasket begins to work, which gently transfers the arisen force to the adjacent upper element. And so on according to the "domino principle." Therefore, the height of the upper element h allows you to compensate for all the longitudinal forces arising from the braking process. Transverse forces are insignificant, because the upper element is located in the body of the road surface and lies freely on the damper cord on the lower element.

In comparison with the known storm water inlets, this drainage element, with its structural simplicity, has increased strength properties, including due to the increase in the supporting surface between the upper and lower elements, the commissioning of additional damper gaskets, as well as the manufacture of each housing element from high-strength reinforced concrete or polymer concrete. Various reinforcement of the upper element allows to withstand all the necessary regulatory loads that comply with DIN-EN 1433. Thus, this technical solution extends the life of the drainage system.

This drainage element (see Fig. No. 2) is well interfaced with existing structures of known drainage devices, such as wells, sand traps (3), which makes it easy to fit into previously developed design solutions (see photo No. 1). In addition, the laying depth (H) of the lower element, taking into account that it can be made with a slope along the lower plane, allows to increase the throughput of the tray by reducing the extreme outlet point, which is formed due to the height AND of the second element.

Claims (6)

1. A drainage module containing a lower element - a U-shaped tray with a tongue-and-groove system at the ends, on the upper part of each of the walls of which a longitudinal groove is made, and a flat upper element made with the possibility of bearing on the walls of the lower element, characterized in that the upper the element is made in the form of a parallelepiped with through culverts, which are chamfered in their upper part, a groove is placed on the ends of the upper element for laying sealant, and two rubber are fixed on one of the ends damper gaskets, and longitudinal grooves are made on the lower surface of the upper element on both sides of the through-flowing holes with the possibility of pairing the outermost of these grooves with the said grooves of the lower element and forming a channel for accommodating a gas-oil-resistant cord designed to fix the upper element relative to the lower one. 2. The module according to claim 1, characterized in that the grooves are made semicircular in cross section. 3. The module according to claim 1, characterized in that it is made of concrete or polymer concrete. 4. The module according to claim 1, characterized in that the damper pads on the end of the upper element are made of gas-oil-resistant rubber and fit snugly to the surface of the next upper element when connecting adjacent drainage elements to the drainage system. 5. The module according to claim 1, characterized in that the upper element is located in the body of the road surface and works as a joint construct. 6. The module according to claim 1, characterized in that the height of the upper element varies depending on the internal reinforcement of the product and the class of standard load perceived by the drainage module.

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