RU2612431C2 - Method for sealing damages of impervious screen - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method for sealing the damages of the impervious screen includes laying polymeric material, dumping the protective layer, integrity testing from fixed soil moisture sensors to the portable data logger with subsequent transfer of information by GPS navigation to a personal computer, sealing the detected damage 8 in an impervious polymeric element with the injection of bentonite solution supplied under pressure by the pump 11 into the damaged openings 8. Patches 15 of a polymeric material are arranged on the damages with the opening diameter d_op≥20 cm. The screen integrity testing is performed automatically and remotely, all the necessary information about leaks comes to the operator's personal computer, and sealing the damages is done punctually by means of the bentonite solution injection, and in case of detecting significant places of damages, besides the injection, patches of a polymeric material are additionally arranged.

EFFECT: increased testing convenience, improving the accuracy of the damage sealing.

2 cl, 4 dwg

Description

The invention relates to hydraulic engineering and environmental construction, can be used to repair damage to the antifiltration coatings of channels, ponds and waste storage, by preliminary monitoring the integrity of the screens remotely.

A known method for determining the locations of focal filtration of liquids from storages with an insulating screen (see copyright certificate SU 410164, publ. 01/05/1974), which consists in the fact that one of the supply electrodes is lowered into the store, and then the maximum gradient of the electromagnetic field is measured, the location of which corresponds to focal filtration.

The disadvantage of this method is the complexity and complexity of the process of finding damage to the screen. Along with this, this method can be used only during the operation of the structure and is characterized by a sufficiently large error during measurements.

A known method of controlling the quality of a film screen (see copyright certificate SU 1308683, published 07.05.1987), including electrical insulation of the coating along the contour of the screen, measuring the electrical resistance between the coating and the base of the screen and evaluating the measured value of the screen continuity.

The disadvantage of this method is the complexity of the work to control the continuity of the film screen, the inability to remotely monitor the integrity of the anti-filter screen and obtain information about the presence of certain damages, which is especially important for waste accumulators, since even the smallest losses from them can lead to pollution of underground and ground water

A known method of sealing the source of filtering deformation in the dam of the channel (patent RU No. 2562487, publ. 09/10/2015), including laying under water with a crane using a finished gabion structure with a protective coating and thereby sealing free filtration in the dam of the channel.

The disadvantage of this technical solution is the complexity of the work associated with the installation using a crane under the water of the finished gabion-geomembrane design. In addition, when closing the source of filtering deformations in the channel dam in this way, there is a possibility of a mismatch between the gabion-geomembrane structure and the free filtration path, as well as its slipping along the slope with time during operation of the channel, during wind (surge) and other phenomena.

The closest technical solution is a method for monitoring the integrity of a two-layer anti-filtration screen (see copyright certificate SU 1151642, publ. 04.23.1985), including laying polymer material, filling the protective layer, controlling the continuity of the screen by determining the place of damage by the exit of the bubbles to the outer surface and sealing damage.

The disadvantage of this prototype is a large error in determining the damage to the impervious screen, as perforated flexible hoses are not laid on the entire surface under the coating, but only in insulated compartments formed by discrete fastening of two layers of the film. In addition, during the laying of the film coating, the device of the protective layer and discrete fastening of the film, various damage will occur (due to the small thickness of the film panel), which will be practically impossible to repair.

The purpose of this invention is the sealing of damage to the filter screen by preliminary monitoring the continuity of the coating remotely, with the receipt of information about damage to a personal computer.

The technical result to which the invention is directed is to develop a method for sealing damage to an anti-filter screen.

The technical result is achieved due to the method of sealing damage to the anti-filter screen, and before closing the damage, the polymer material is laid, the protective layer is poured, the screen is monitored by determining the location of the damage and its sealing. At the same time, the continuity of the anti-filter screen is monitored remotely from stationary soil moisture sensors to a portable data logger, followed by the transmission of GPS navigation information to a personal computer, after which the damage is repaired by injection of a bentonite solution supplied under pressure by a pump into the damaged hole, and on damage with d _ot ≥20 cm, patches made of polymer material are additionally arranged. Soil moisture sensors are installed in the cavity under the anti-filter element in the underlying soil layer to a depth of 8-10 cm, in the amount of 1 sensor per 4 m ² .

The invention is illustrated by the following drawings: FIG. 1 is a diagram of remote data transmission from humidity sensors to a personal computer; FIG. 2 - installation of humidity sensors under the anti-filter screen; FIG. 3 - anti-filter screen with damage; FIG. 4 - sealing damage in the anti-filter screen.

The numbers in the drawings indicate:

1 - soil (natural) base; 2 - sand dumping; 3 - soil moisture sensor; 4 - non-woven geotextile; 5 - antifiltration polymer material; 6 - woven geotextile; 7 - a protective layer; 8 - damage (holes) in the coating; 9 - portable data logger; 10 - personal computer; 11 - pump; 12 - a polyethylene hose; 13 - screw; 14 - polymer jumper; 15 - patch.

The method of sealing damage to the filter screen is as follows (Fig. 1-4).

During the construction period of the structure (canal, reservoir or drive), an anti-filter screen is arranged, which includes the following operations: preparation of a soil (natural) base 1 (removal of vegetation, stones, roots and other large inclusions), installation of a base layer of fine-grained sand 2 (sand filling 20-30 cm thick, with a fraction of 0.1-0.25 mm), in which soil moisture sensors (10 HS or 5TE) are installed at a depth of 8-10 cm, in the amount of 1 sensor per 4 m ² . On top of fine-grained sand 2 and moisture sensors 3 installed in it, a non-woven geotextile 4 cloth is placed (Dornit, manufactured according to TU 8397-003-21506643-2003, with a surface density of 300 g / m ² and a thickness at a load of 2 kPa - 3.3 mm), and an anti-filtration element is made of polymer material 5 (geomembrane in the form of polymer sheets, manufactured according to TU 2246-001-56910145-2004 "Techpolymer"). To protect the anti-filter element 5 from damage, a protective lining of woven geotextile 6 and filling of the protective layer 7 are performed (for irrigation canals, the protective coating is made of concrete, for water bodies - from the ground, and waste accumulators - from crushed stone or stone).

With the formation of through damages in the antifiltration polymer element and the filtration of water through openings 8, the moisture sensor 3 measures the dielectric constant, the value of which directly depends on the volumetric moisture content in the soil or soil. It operates at a frequency of 70 MHz, which allows you to accurately measure the moisture content of any type of soil. To calculate the volumetric moisture content, the equations (“Topp Equations”) are used, which make it possible to convert dielectric quantities to volumetric ones. Further, information from stationary soil moisture sensors is remotely transmitted to a portable data logger 9 and then transmitted via GPS navigation to a personal computer 10. Thus, in case of damage and water filtration through them, the information is automatically transmitted to a personal computer, which helps to control the flatness of the anti-filter screen remotely.

If damage is detected at the facility, they are repaired by injection of a bentonite solution, which, under pressure, is pumped to a damaged area using a pump 11 equipped with a polyethylene hose 12 and a valve 13 for regulating the pressure.

When injuries are injected into waste ponds with sodium bentomats, the pH of the filtrate must be taken into account, since Na-bentonite practically does not hydrate in a strongly acidic and strongly alkaline environment and, as a whole, embedding can become ineffective. Therefore, the bentonite solution for injection is made and used in the following ratio: 90% Na-bentonite and 10% cement for irrigation canals and ponds, 80% Ca-bentonite and 20% cement for waste storage. If significant lesions are detected (with a hole diameter of d _ot ≥20 cm), in addition to the injection, patches made of polymer material are additionally arranged.

When repairing damage on irrigation canals operating in a rapid flow of water, jumpers 13 are made made of polymer anti-filter material 5. To prevent the demolition of the polymer jumpers by the water flow, they are fixed with cables.

The advantage of the developed method is that the integrity of the screen is monitored automatically and remotely, all the necessary information about leaks is sent to the operator on a personal computer, and damages (holes, cracks, fumes, etc.) are repaired by injection of a bentonite solution or with polymer patch

In addition, the proposed method is recommended for the reconstruction of existing especially hazardous facilities (sludge collectors, sedimentation tanks, tailing dumps, ash dumps, mining sites) to prevent the filtration of highly mineralized and polluted effluents into groundwater.

Claims (2)

1. A method of sealing damage to an anti-filter screen, including laying polymer material, filling the protective layer, monitoring the continuity of the screen by determining the location of damage and sealing damage, characterized in that the monitoring of the integrity of the anti-filter screen is carried out remotely from stationary soil moisture sensors to a portable data logger with subsequent transfer information on GPS navigation to a personal computer, after which they repair the injuries by injection of bentonite ra create, supplied under pressure by a pump in a damaged hole, and damage to d ≥20 cm _holes are arranged further from a polymeric material patches. 2. The method according to claim 1, characterized in that the soil moisture sensors are installed in the cavity under the anti-filter element in the underlying soil layer to a depth of 8-10 cm, in the amount of 1 sensor per 4 m ² .

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