RU145270U1 - LIQUID PROTECTIVE SHAFT - Google Patents

Abstract

A protective shaft for a liquid barrier, comprising a flexible, fluid-filled casing adjacent to the ground, and a portion of the casing adjacent to the ground that is capable of exerting a vertical force on it, which presses it to the surface and holds it in place, the protective shaft has an edge of the first long side facing the side of the liquid spill, and the opposite side, the second long side facing the dry side, characterized in that as the casing are made of polyethylene with a thickness of more than 1-2 mm several to autonomous reservoirs with a length of the order of several meters, having a triangle cross-section, which contain an inlet and an outlet with a sealing device on the upper side of the corner, several electric motors by the number of reservoirs for filling them with surrounding water with hoses paired with the reservoir inlet hoses, each of the reservoirs contains along the end edges a continuation of the material in the form of protrusions with holes intended for the mechanical connection of several reservoirs together, creating constituent single monoblock and power source or from the mains, or from an independent power generator, and a spacer pin which is fixed between the bottom and the planes of adjacent tanks protrusions vertices of triangles end portion.

Description

This utility model relates to the field of hydraulic engineering and is designed to deal with floods and water spills, as well as to create temporary dams for small rivers.

Frequent floods can damage buildings located close to water bodies, such as lakes and rivers, temporarily overflowing due to excessive rainfall. In this case, water can flow along the ground to the house and cause various troubles, for example, pouring basement in the house or partially penetrating the first floor. Repairing damage caused by water is always very expensive. To deal with spills, regardless of their nature, they create obstacles to the flow of liquid in order to reduce the extent of the spill. In particular, a protective shaft is constructed that stops the flow of liquid. The homeowner constructs a shaft around the house to prevent water from entering.

Known methods for erecting shafts utilize solid materials, usually of an inorganic nature. The traditional method involves manually stacking sandbags with more or less high rows. Another way is to build shafts from the ground using suitable mechanisms. However, these methods have disadvantages. When building protective shafts using excavation or excavation, wherever possible, a lot of time is wasted and the use of this method is often possible only when it is already too late. In addition, pits and other damage appear in the ground as a result. The method in which sandbags are used requires not only a lot of time, but also a lot of labor. Very often, during a flood, there are no mechanisms or sandbags nearby, and therefore, before starting the construction of the shaft, you have to spend a lot of time on transportation. This means that the protective shaft may be erected too late. In order to eliminate the shortcomings associated with the use of soil shafts and shafts of sandbags, shafts have recently been developed that are made of mobile barriers in the form of sleeve-like casings that can be stored, taken and transported when folded, but directly in the flood area, fill with liquid, usually water. Numerous examples of such sleeve casing can be found in the patent literature, see, for example, FR 1375854, EP 496519, US 3246474, US 3855800, US 4799821 and US 5040919. A significant advantage of such sleeve casing is that when folded, they occupy very small volume, and the heavy material that is needed to fix the shields of the protective shaft is usually present in excess in the form of water at the site of the flood. Therefore, an almost unlimited number of devices for liquid barriers in the form of sleeves-casings can be quickly and easily delivered to the place that is flooding, and installed simply by filling them with water. Most of the known obstruction devices in the form of sleeve-casings also include an apron facing the liquid spill and having a more or less defined width. This apron is usually secured with nail-like or stud-like fasteners that provide tight contact with the ground. The protective shaft for the liquid barrier includes a part that adheres to a surface, for example, to the ground, and on which a vertical force acts, pressing it to this surface and holding it in place.

The closest analogue of the present invention is the invention according to the patent of the Russian Federation No. 2156846 from 09/27/2000 g according to the application 97116267 \ 13 from 02/09/1996, the Protective shaft for barriers against liquids, contains adjacent to the surface, for example, to the ground part, for example, flexible, a liquid-filled casing and / or a flexible apron, and a vertical force acts on this part, pressing it to the surface and holding it in place, said protective shaft has an edge of the first long side facing the spill of the liquid, and an edge of the opposite, second long torons, facing the dry side of the protective shaft, between the surface and the indicated part there is an axially extending liquid draining means that can seep under the specified part from the spill side to maintain a section on the lower side of this part extending from the edge of the long side of the means drainage of fluid that is closest to the spill side to the dry side.

The disadvantage of this device is the complexity of the installation, which requires considerable time, and the unreliability of the installation, which is determined by the small size of the casing, to keep it in the working position, an additional apron is required, fixed by means of nail-like or stud-like fasteners and means for draining the liquid.

The aim of the present invention is to provide a protective shaft that is quickly installed, well held in place, provides good contact with the bottom surface, and allows you to quickly increase the size of the protective shaft.

This goal is achieved by the fact that in the known device containing a part adjacent to the ground, for example, a flexible, liquid-filled casing, and a vertical force acts on this part, pressing it to the surface and holding it in place, said protective shaft has an edge of the first long the side facing the spill of the liquid, and the edge of the opposite, second long side facing the dry side of the protective shaft, new features are introduced, namely, the casing is made of polyethylene or close there are several autonomous reservoirs with a thickness of more than 1-2 mm, several meters long, having a triangle cross-section, which contain an inlet and an outlet with a sealing device and a check valve on the upper side of the corner, several electric motors according to the number of reservoirs to fill their surrounding water with hoses associated with the inlet hoses of the tanks, each of the tanks contains along the end edges of the continuation of the material in the form of protrusions with holes, designed for mechanically connecting several tanks together, creating a single monoblock and an electric source, either from the network or from an autonomous electric generator, as well as a spacer in the form of a pin, which is attached between the lower planes of adjacent tanks and the protrusions of the vertices of the triangles of the end parts of the connected tanks.

The essence of the proposed utility model is as follows. The advantage of casing hoses from previously used bulk protective shafts or protective shafts created with bulk bags is that when folded they occupy a very small volume, and the heavy material that is needed to fix the protective shaft casings is usually available at the flood site in excess in the form of water.

The present utility model proposes to use tanks made of polyethylene or a similar material having a sufficient thickness so as not to be torn by a mass of filled water. In cross section, the tank is a triangle, on the upper corner of which there are holes for connecting the hose from the pump and an air outlet. The tank is located with the long side to the incoming water, filled with water using an electric pump connected via a hose to the interface device. As a rule, the outlet of the water electric pump has a diameter of about 20 mm, which will provide a fairly quick filling of the tank at a speed of about 150 liters per minute. As the first tank is filled, you can determine the location of the second and subsequent tanks, connect them with mechanical bonds, and begin to fill with water. The tanks can be located both in line to cover a large body of water, and one after another to ensure reliability and durability when exposed to incoming water. The mass of liquid filling the tank is large enough to ensure tight contact with the bottom surface due to the triangular section. The presence of a triangular section will provide a smooth rather than sharp impact on the side facing the water and reduce the impact of the abiding water. The flexible lateral surface of the tank will allow it to contact fairly closely with neighboring parts of other tanks and limit the flow of water at the joints. The bulk of the water in the tank will act normal down to a large lower plane, and will not tear the side surface of the material. In addition, since the material is sufficiently plastic and occupies a large contact area with the bottom surface, it will limit water leakage in irregularities at the bottom, which eliminates the need for additional means for water drainage, as used in the prototype. The tanks can also perform a purely protective function, restricting the flow of water directly into the house through the front door or window. You can use the tanks autonomously to block the flow of water in those parts of continuous embankments where there are descents to the water. In the event that the flood is formed due to the flow of water from small rivers, it is possible to block the source using tanks and reduce the amount of incoming water into the main river, which will additionally gain time for taking the necessary protective measures. Each long side is connected to the adjacent side by an end plane, which ensures the tightness of the entire tank structure. The long side forms a small extension of the side plane, forming protrusions relative to the end plane. Holes of at least 3 are formed on these protrusions to ensure connection with similar protrusions of similar reservoirs that form a protective shaft along the water spill line. The connection is made by superimposing the protruding planes with overlapping and sequential pulling of the rope through the side holes along the entire line of connection of the planes. It is advisable to start pulling the connecting rope from the lower plane of the joint in two opposite directions, followed by the joint at the top. A vertical pin can be driven into the center hole of the outer protrusion of the lower plane of the tank on the ground, focusing on the upper corner of the outer protrusion of the tank to provide a more stable fastener for the entire structure.

In FIG. 1 shows the design of the proposed utility model.

In FIG. 1 is indicated: 1 - protective tank; 2 - hydraulic pump; 3 - power supply; 4 - a hose of a hydraulic pump; 5 - tank spacer; 6 - outer ledge of the tank; 7 - water surface; 8 - shore.

The sequence of assembly of the protective shaft is as follows. A place is selected that has a flat plane, located near the incoming water. The rolled-up tank 1 is expanded across the incoming water 7, the hydraulic pump 2 is installed in the water, the pump hose 4 is connected to the inlet of the tank 1, the power supply 3 is turned on (or an external network is connected), the hydraulic pump 2 for pumping water is turned on and the tank is filled correctly. The second, rolled-up reservoir is folded back to back with the first, a pin is installed between the protrusions of the lower planes of the reservoirs superimposed on each other and the upper corners of the triangles of the adjoining sides superimposed on each other, the reservoirs are connected through openings with each other using any connecting devices, the second pump is connected to the hose the inlet of the tank, the power supply of the second pump is connected, a pin is installed between the protrusions of the lower side to be connected and the upper corners of the soy inyaemyh tanks, there is a reservoir fill is correct. The need for a third tank is assessed.

In this way, the flow of water can be limited.

Claims (1)

A protective shaft for a liquid barrier, comprising a flexible, fluid-filled casing adjacent to the ground, and a portion of the casing adjacent to the ground that is capable of exerting a vertical force on it, which presses it to the surface and holds it in place, the protective shaft has an edge of the first long side facing the side of the liquid spill, and the opposite side, the second long side facing the dry side, characterized in that as the casing are made of polyethylene with a thickness of more than 1-2 mm several to autonomous reservoirs with a length of the order of several meters, having a triangle cross-section, which contain an inlet and an outlet with a sealing device on the upper side of the corner, several electric motors by the number of reservoirs for filling them with surrounding water with hoses paired with the reservoir inlet hoses, each of the reservoirs contains along the end edges a continuation of the material in the form of protrusions with holes intended for the mechanical connection of several reservoirs together, creating constituent single monoblock and power source or from the mains, or from an independent power generator, and a spacer pin which is fixed between the bottom and the planes of adjacent tanks protrusions vertices of triangles end portion.