RU2483813C1 - Method and device for disinfection and flushing of pipelines after repair-and-renewal operations - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to water supply, particularly, to disinfection and flushing of pipelines and repair-and-renewal operations. Proposed method comprises shutting down of damaged pipeline section, draining water therefrom, sanitary treatment and flushing of said section, fitting moving plugs at section inlet and outlet to prevent diffusion of disinfectant into drinking water in pipeline upstream of recovered section. After recovery, pipeline is filled with disinfectant solution to flush recovered section. Clean water tank inlet is stopped to make connection of pipeline with repaired section to inlet of water treatment units to discharge disinfectant and flushing waters therein. Connection to clean water tank is performed proceeding from the results of analysis of flushing water for residual chlorine and bacteria.

EFFECT: reliable operation of water supply system.

2 cl, 1 dwg

Description

The invention relates to the field of water supply and for the disinfection and washing of pipelines of drinking water, which must be performed to restore the pipelines after the accident.

A known method and device for disinfection and washing of pipelines described in MDK 3-02.2001 "Rules for the technical operation of systems and structures of public water supply and sanitation" dated December 30, 1999, No. 168.

In the known method, the repaired area disconnected from the water supply system is filled with a disinfectant solution and the residual active chlorine is brought to a concentration of 75-100 mg / l in contact with water for 5-6 hours or at a concentration of 20-25 mg / l with daily contact, after which the pipeline is washed with water, while the entire volume of the disinfectant solution and wash water is discharged to the treatment plant. Washing is carried out by passing washing water to obtain three satisfactory water samples.

The known device for disinfection and washing of pipelines contains switching chambers, allowing to disconnect the emergency section from the water supply system using the valves located in the switching chambers.

The closest analogue of the method claimed as an invention is the technical solution described in the application of the Russian Federation No. 2009128006 for the invention: "Method for the removal and purification of water after pipeline repair", IPC C02F 1/00, priority dated July 20, 2009.

The known method is based on shutting down the emergency section, draining the water, repairing the emergency section of the pipeline, sanitizing the pipeline and flushing the disconnected restored section.

The closest analogue of the device claimed as an invention is the technical solution described in the patent of the Russian Federation No. 2288942 for the invention: "Multifunctional automated comprehensive educational research laboratory", IPC C02F 9/08, priority date July 14, 2003.

The known device contains a treatment plant, a clean water tank, first and second pipelines equipped with first and second switching chambers, jumper piping installed inside each switching chamber between the first and second pipelines, each of the switching chambers contains valves installed on the jumper pipeline, as well as valves installed on the first and second pipelines on both sides of the jumper pipeline.

A disadvantage of the known method and device is that when washing sections of water pipes after emergency restoration works, as well as main water pipes as a whole, drinking-quality water in the pipeline at the time the washing process begins is discharged to sewage treatment plants or to the sewer. At the same time, the volumes of high-quality drinking water can reach several thousand (up to tens of thousands) cubic meters, which is equivalent to providing drinking water during the day of the city with a population of several tens of thousands of people (at a rate of water consumption of 250 liters per person per day). In addition, when the disinfectant is removed from the water supply section restored after the accident, the process of active disinfectant diffusion into the wash water occurs, which ultimately leads to the following:

firstly, to increase the volume of flushing water, since the flushing process is completed only when the quality indicators of water for residual active chlorine and bacteriology meet GOST and SanPiN. That is, the diffusion process increases the washing time and, as a result, leads to an increase in the volume of washing water;

secondly, an increase in the volume of washing water leads to a serious additional load on the sewer system and sewage treatment facilities, as a result of which the costs of the cleaning process increase, and also makes it impossible to use such washing water for technological purposes.

Thus, the removal of a disinfectant solution and wash water is an economically costly measure.

The problem to which the present invention is directed is the creation of a method and device for disinfection and washing of pipelines, providing a reduction in unjustified losses of significant volumes of high-quality drinking water, a decrease in the volume of washing water while ensuring the reliability of the water supply system.

In the method for disinfecting and flushing pipelines after repair and restoration work, based on shutting down the emergency section, draining the water, repairing the emergency section of the pipeline, sanitizing the pipeline and flushing the disconnected restored section, according to the invention, they are additionally installed at the beginning and end before sanitizing on the restored section of the pipeline mobile plugs that prevent the disinfectant from diffusing into the drinking water in the pipeline before the restored section, and in the washing water after the restored section of the pipeline, the restored section of the pipeline is filled with a disinfectant solution, it is disinfected and then the restored section is flushed, while the volume of drinking water located in front of the first movable stopper in the direction of flow is sent to the clean water tank, after a period of time T, determined by the formula T = [t-τ], where t is the discharge time of drinking water into the clean water tank, which depends on the length of the pipeline between the main section of the pipeline and the entrance to the clean water tank, τ is the switching delay time, block the entrance to the clean water tank and connect the pipeline with the restored section to the inlet of the treatment plant, where the disinfectant and wash water are dumped, the pipeline is switched back from the restored section to the tank inlet pure water is carried out according to the results of the analysis of washing water for residual chlorine and bacteriology.

The problem is also solved by the fact that the device for disinfection and flushing of pipelines after repair and restoration work, containing treatment facilities and a reservoir of clean water, the first and second pipelines equipped with the first and second switching chambers, jumper piping installed inside each switching chamber between the first and second pipelines, while each of the switching chambers contains valves installed on the pipelines of the jumpers, as well as valves installed on the first and second pipes the wires on both sides of the jumper pipelines, according to the invention further comprises, in the pipelines between the second switching chamber and the clean water tank, a residual chlorine sensor, a sampler for sampling water for bacteriological analysis and shut-off and control valves, and additionally installed in the first and second chambers switching boxes with movable plugs placed in them, made with the possibility of movement under pressure created in the pipeline flow m of water, moreover, the movable plugs are made of materials of the food product category, while the switching chambers are equipped with additional valves installed in front of the boxes, and fittings with shutoff valves installed between the additional valves and boxes, and an additional shut-off valve is installed on the branch from the pipeline to the treatment facilities control valve.

The drawing shows a device that implements the proposed method, which presents a possible emergency situation on the second (TP-2) or on the first (TP-1) pipelines. The device comprises pipelines Tr-1 and Tr-2 equipped with a first KP-a and a second KP-b switching chambers, jumper piping installed inside each switching chamber between the first Tr-1 and the second Tr-2 pipelines, while the first KP switching chamber -a contains a valve 5a installed on the jumper pipeline, as well as valves 1a, 2a, 3a, 4a, installed on both sides of the jumper pipeline, and the second switching chamber KP-b contains a valve 5b installed on the jumper pipeline, as well as valves 1b , 2b, 3b, 4b, y tanovlenii on both sides of the pipeline jumper. On the Tr-2 (or Tr-1) pipeline section between the second KP-b switching chamber and the clean water tank (RCHV), a residual chlorine sensor 20-2 (or 20-1), a sampler 21-2 (or 21-1) are sequentially installed ) and a shut-off and regulating valve 18-2 (or 18-1). When the number of switching chambers is more than two, which is determined by the length of the water conduit, residual chlorine sensors and samplers are installed after the last switching chamber at the inlet of the RF. In the first KP-a switching chamber, on the Tr-2 (or Tr-1) pipeline, boxes 14a, 15a (or 16a, 17a) are located, and in the second KP-b switching chamber, boxes 14b, 15b (or 16b, 17b) are located movable plugs placed in them. The switching chamber KP-a is equipped with additional valves 6a, 7a (or 8a, 9a) installed in front of boxes 14a, 15a (or 16a, 17a), fittings with shut-off valves 10a, 11a (or 12a, 13a) installed between the additional valves 6a , 7a and boxes 14a, 15a, respectively (or between additional gate valves 9a, 8a and boxes 16a, 17a, respectively). The KP-b switching chamber is equipped with additional valves 6b, 7b (or 8b, 9b) installed in front of boxes 14b, 15b (or 16b, 17b) and fittings with shut-off valves 106, 116 (or 12b, 13b) installed respectively between the additional valves and boxes 14b, 15b, 16b, 17b. The following are installed in series on the Tr-2 (or Tr-1) pipeline between the second KP-b switching chamber and the clean water tank (RCHV): residual chlorine sensor 20-2 (or 20-1), sampler 21-2 (or 21-1 ) and a shut-off and regulating valve 18-2 (or 18-1). On the branch from the Tr-2 (or Tr-1) pipeline to the treatment facilities (OS) located behind the sampler 21-2 (or 21-1), an additional shut-off and regulating valve 19-2 (or 19-1) is installed.

The inventive method and operation of the device that implements it, we consider the example of an accident section of the pipeline TR-2 located between the switching chambers KP-a and KP-b. Pipelines Tr-1 and Tr-2 operate in pressure mode using a pumping station (not shown in the drawing), and due to the difference in geodetic marks associated with the terrain. To perform work in the emergency section, the valve 2a in the switching chamber KP-a and the valve 2b in the switching chamber KP-b are closed. Then open the valve on the nozzle 10a in the switching chamber KP-a, as well as the valve on the fitting 11b in the switching chamber KP-b, drain the water from the emergency section and repair it. After that, a disinfectant solution is introduced through the open valve on the nozzle 11b located at the lowest point of the disconnected section of the Tr-2 pipeline, while air is discharged outside the Tr-2 pipeline through the open valve on the nozzle 10a, located at the upper point of the end-length section . Then, the valve 6a and the valve on the fitting 10a in the switching chamber KP-a, the valve 7b, the valve on the fitting 11b in the switching chamber KP-b are closed and the disinfectant solution is kept in the restored section of the pipeline for 5-6 hours. After the emergency site has been sanitized, movable plugs are introduced into the boxes 14a and 14b located respectively in the switching chambers KP-a and KP-b, and the valve 2a in the switching chamber KP-a and the valve 2b in the switching chamber KP-b are opened, having previously closed valves 5a in the switching chamber KP-a and 5b in the switching chamber KP-b. After this, the washing process begins. The main water flow, moving through the Tr-2 pipeline and pressing on the cork in box 14a, causes the movement of water with a disinfectant solution, squeezing out a disinfectant solution enclosed between movable plugs located in boxes 14a and 14b. At the same time, behind the cork from box 14b, pure water moves. The volume of drinking water in front of the first movable stopper located in the box 14b in the direction of flow is sent to the clean water tank. After a period of time T, determined by the formula T = [t-τ], where t is the time of discharge of the volume of drinking water into the clean water tank (RCHV), which depends on the length of the pipeline between the restored section of the pipeline and the entrance to the clean water tank; τ is the delay time of switching, block the entrance to the RF from the pipeline with the restored section using valves 18-2 (or 18-1) and connect the pipeline with the restored section to the entrance of the treatment plant, where the disinfectant and wash water are discharged using valves 19 -2 (or 19-1). The reverse switching of the pipeline with the restored section to the inlet of the pure water reservoir (RCHV) is carried out according to the results of the analysis of washing water for residual chlorine, performed using sensors of residual chlorine 20-2 (or 20-1), as well as bacteriology, performed using samplers 21 -2 (or 21-1). A positive analysis of the wash water is the presence of residual chlorine in the wash water of not more than 20-25 mg / l and the absence of bacteria in the water samples.

The technical advantage of the method and device claimed as an invention lies in the fact that they allow you to save drinking water located in the pipeline from the repaired area to the RFW for use and to reduce the volume of washing water due to the prevention of the diffusion of the disinfectant into the washing water.

In addition, the inventive method and device significantly reduces the pollution of the wash water due to the prevention of diffusion of the disinfectant into the wash water, which ultimately simplifies the process of cleaning this water, reduces the cost of its treatment and makes it possible to use the purified wash water for technological purposes.

Claims (2)

1. The method of disinfection and washing of pipelines after repair and restoration work, based on shutting down the emergency section, draining the water, repairing the emergency section of the pipeline, sanitizing the pipeline and flushing the disconnected restored section, characterized in that before sanitizing the restored section of the pipeline is additionally installed in at the beginning and at the end of the section, movable plugs that prevent the disinfectant from diffusing into the drinking water in the pipeline before being restored section, and into the washing water after the restored section of the pipeline, fill the restored section of the pipeline with a disinfectant solution, disinfect it and then flush the restored section, while the volume of drinking water located in front of the first moving plug in the flow direction is sent to the clean water tank after a period of time T, determined by the formula: T = [t-τ], where: t is the discharge time of drinking water into the clean water tank, depending on the length of the pipeline between the pipeline section and the entrance to the clean water tank, τ is the switching delay time, block the entrance to the clean water tank from the pipeline with the restored section and connect the pipeline with the restored section to the inlet of the treatment plant, where the disinfectant and wash water are dumped, the pipeline is switched back with the restored the site at the entrance to the clean water tank is carried out according to the results of the analysis of the wash water for residual chlorine and bacteriology. 2. A device for disinfecting and flushing pipelines after repair work, comprising a treatment plant, a clean water tank, first and second pipelines equipped with first and second switching chambers, jumper piping installed inside each switching chamber between the first and second pipelines, each of the switching chambers contains valves installed on the jumper pipeline, as well as valves installed on the first and second pipelines on both sides of the pipeline lintels, characterized in that it further comprises, in the pipeline between the second switching chamber and the clean water tank, sequentially installed residual chlorine sensor, a sampler and a shut-off and control valve installed on the pipeline in the first and second switching chambers with boxes fitted with movable plugs made with the ability to move under pressure created in the pipeline by a stream of water, moreover, the movable plugs are made of materials of the food category, while The switching valves are equipped with additional valves installed in front of the boxes, and fittings with shutoff valves installed between the additional valves and boxes, and an additional locking and regulating valve is installed on the branch from the pipeline to the sewage treatment plants.