KR102418223B1 - A method of cleaning for underground piping by using fire-hydrants - Google Patents

Abstract

The present invention relates to an underground pipe cleaning method for determining a cleaning target range of a buried underground pipe using an underground pipe installation drawing, performing cleaning by injecting high-pressure cleaning air and water into an underground pipe determined to be within the cleaning target range using fire hydrants and branch pipes already connected to the underground pipe determined to be within cleaning target range. According to the present invention, the underground pipe cleaning method using fire hydrants comprises: a first step (S100) of determining a cleaning target range of an underground pipe; a second step (S200) of determining a fire hydrant for input, a fire hydrant for discharge, and a branch pipe for replenishing air; a third step (S300) of determining the cleaning pressure; a fourth step (S400) of blocking a sluice valve; and a fifth step (S500) of supplying air and water at the determined cleaning pressure to the underground pipe determined to be within the cleaning target range.

Description

{A method of cleaning for underground piping by using fire-hydrants}

The present invention relates to a method for cleaning an underground buried pipe using a fire hydrant, and more specifically, determining the cleaning target range of the underground buried pipe using the underground buried pipe installation drawing, It is a technology related to a method of cleaning an underground buried pipe that uses branch pipes to inject high-pressure cleaning air and water into the underground buried pipe determined as the range to be washed, and then washes it.

Modern society has undergone urbanization centered on large cities, and people are living and living in cities, and in cities, various buildings and infrastructure facilities for residential, commercial, educational, industrial, transportation, health, etc. built and operated.

Among the various infrastructure facilities built in the city, there is a water supply pipe buried underground to supply tap water to each customer.

In particular, one of the factors contributing to the increase in human lifespan in modern society is the supply of cleanly managed tap water, and the supply of clean tap water is preventing water-borne infectious diseases such as cholera. is recognized

Meanwhile, in order for clean tap water to be supplied to each consumer, it is important to produce clean tap water at the water purification plant, but the inside of the water supply pipe connected to be supplied to each consumer must be cleaned regularly to remove foreign substances inside the pipeline.

In particular, if the inside of the water supply pipe is not properly cleaned, the quality of the tap water supplied to consumers is inevitably reduced due to foreign substances inside the pipe even when clean tap water is produced at the water purification plant.

Conventional pipe cleaning methods include a method of inserting a cleaning device into the pipe and a method of supplying high-pressure vortex water to the inside of the pipe. There is the inconvenience of having to wash foreign substances one by one using a cleaning device, and the method of supplying high-pressure vortex water into the pipe has a problem that the cleaning effect is reduced as the length of the pipe is longer due to the fast vortex dissipation characteristic. In order to be effective, it is necessary to supply a vortex having a fairly large pressure corresponding to the length of a long pipe into the pipe, but there is a problem in that a very large air compressor is required to generate a large pressure.

Therefore, in order to improve the conventional problems described above, the present invention determines the cleaning target range of the underground buried pipe using the underground buried pipe installation drawing, and uses the fire hydrant and branch pipes already connected to the underground buried pipe determined as the washing target range Then, high-pressure cleaning air and water are put into the underground landfill pipe determined as the cleaning target range, and cleaning is carried out. We would like to propose a cleaning method that can clean an underground landfill pipe. The following are prior art related to this.

1. Republic of Korea Patent Publication No. 10-2012-0046363 Method of cleaning water supply pipe using flushing valve 2. Republic of Korea Patent Publication No. 10-1690588 A method of cleaning a pipe using an air pig formed of water and compressed air 3. Republic of Korea Patent Publication No. 10-2233834 Pipeline washing device and water reduction system including the same

The present invention determines the washing target range of the underground buried pipe using the underground buried pipe installation drawing without installing a separate washing structure for washing and inserting a separate washing device into the pipe, and the existing The purpose is to clean the underground buried pipe by injecting high-pressure cleaning air and water into the underground landfill pipe determined as the cleaning target range using the fire hydrant and branch pipes (detail pipes that supply water to the consumer) installed in the

In addition, an object of the present invention is to enable washing of an underground buried pipe using a small or medium-sized air compressor regardless of the length of the underground buried pipe determined as a cleaning target range.

In order to achieve the above object, the underground landfill pipe cleaning method using the fire hydrant of the present invention is,

A first step (S100) of determining a cleaning target range of the underground buried pipe by using the underground buried pipe installation drawing;

a second step (S200) of determining a hydrant for input, a hydrant for discharge, and a branch pipe for replenishment of air, among hydrants and branch pipes connected to the underground landfill pipe determined as the range to be cleaned;

a third step (S300) of determining a washing pressure for washing the underground buried pipe determined as a washing target range;

a fourth step (S400) of blocking the septic tank so that water is not supplied to the underground buried pipe determined as the range to be washed (S400);

For cleaning the underground burial pipe determined as the range to be washed, the washing air of the pressure determined through the third step (S300) and the washing water of a certain pressure are put into the hydrant for input determined through the second step (S200), It characterized in that it comprises a fifth step (S500) of supplying the cleaning air of the pressure determined through the third step (S300) to the branch pipe for replenishing the air determined through the second step (S200).

The present invention determines the washing target range of the underground buried pipe using the underground buried pipe installation drawing without installing a separate washing structure for washing and inserting a separate washing device into the pipe, and the existing Using the fire hydrant and branch pipes (detailed pipelines that supply water to consumers) installed in the It provides the effect of quickly cleaning the pipeline to be cleaned at a simple and low cost because no construction of equipment or structures is required in the pipeline.

In addition, the present invention provides an effect that can wash the buried underground pipe using a small and medium-sized air compressor regardless of the length of the underground buried pipe determined as the cleaning target range.

1 is a conceptual diagram of the present invention;
2 is a flowchart of the present invention;
3 is a view illustrating a state in which a fire hydrant and a branch pipe are connected to the washing target pipe of the present invention;
4 is an exemplary view for determining the washing pressure of the present invention
5 is a view illustrating a state in which washing water and air of the present invention are input through a fire hydrant;
Figure 6 is an illustration of a state in which the cleaning air of the present invention is replenished through a branch pipe
7 is a view illustrating a state in which the drain water of the present invention is discharged to the outside of the underground buried pipe

An embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, the method for cleaning an underground buried pipe using a fire hydrant according to the present invention (hereinafter referred to as 'the present invention') is an installation drawing of an underground buried pipe without installing a separate washing structure for washing and inserting a separate washing device into the pipe. to determine the cleaning target range of the underground landfill pipe 20 using Therefore, it is possible to clean the underground buried pipe by injecting high-pressure cleaning air and water into the underground buried pipe 20 determined as the range to be washed, so it is convenient and convenient because there is no need for a separate cleaning device or construction to install a structure in the pipe. An invention that provides the effect of quickly cleaning the pipe to be washed at low cost, and provides the effect of washing the buried pipe using a small or medium-sized air compressor regardless of the length of the buried pipe determined as the cleaning target range to be.

Referring to Figure 2, the underground buried pipe cleaning method using the fire hydrant of the present invention,

A first step (S100) of determining a cleaning target range of the underground buried pipe by using the underground buried pipe installation drawing;

a second step (S200) of determining a hydrant for input, a hydrant for discharge, and a branch pipe for replenishment of air, among hydrants and branch pipes connected to the underground landfill pipe determined as the range to be cleaned;

a third step (S300) of determining a washing pressure for washing the underground buried pipe determined as a washing target range;

a fourth step (S400) of blocking the septic tank so that water is not supplied to the underground buried pipe determined as the range to be washed (S400);

For cleaning the underground burial pipe determined as the range to be washed, the washing air of the pressure determined through the third step (S300) and the washing water of a certain pressure are put into the hydrant for input determined through the second step (S200), It characterized in that it comprises a fifth step (S500) of supplying the cleaning air of the pressure determined through the third step (S300) to the branch pipe for replenishing the air determined through the second step (S200).

The first step ( S100 ) is a step of determining the cleaning target range of the underground buried pipe 20 using the underground buried pipe installation drawing.

Referring to FIG. 3 , an underground buried pipe 20 such as a water pipe is installed in a complicated way, and a drawing of an underground buried pipe installed in a complex underground is provided in advance.

Therefore, the state of the underground buried pipes 20 complexly installed underground is identified through the underground filling pipe installation drawing, and the range of the underground buried pipe 20 corresponding to the cleaning target range to be cleaned is determined. In particular, when determining the cleaning target range of the underground buried pipe 20, the range of the underground buried pipe 20 in which a plurality of fire hydrants and a plurality of branch pipes (a detailed pipe supplying water to each customer) is connected is determined as the cleaning target range do.

The present invention is an invention that proceeds with washing without installing a separate washing structure for washing and inserting a separate washing device into the pipeline. 30) and the branch pipe 40 are used as inlets for introducing cleaning air and water. Therefore, a plurality of hydrants 30 and a plurality of branch pipes 40 must be connected to the range of the underground buried pipe 20 determined as the range to be washed.

For example, when determining the cleaning target range of the underground buried pipe as shown in FIG. 3 using the underground buried pipe installation drawing, a plurality of hydrants 30 and a plurality of branch pipes ( 40) must be connected and installed. 3 shows an example in which three hydrants and seven branch pipes are connected and installed in an underground buried pipe in the range to be washed.

In the second step (S200), among the hydrant 30 and branch pipe 40 connected to the underground buried pipe 20 determined as the range to be cleaned, the hydrant 30 for input and the hydrant 30 for discharge and the minute for replenishment of air It is a step to determine the institution (40).

As described above, a plurality of hydrants 30 and a plurality of branch pipes 40 are connected to the underground buried pipe 20 determined as the cleaning target range. Among the plurality of hydrants 30 , an input hydrant and a discharge A fire hydrant is determined, and a branch pipe for replenishment of air into which replenishment air is injected among the plurality of branch pipes 40 is determined.

Specifically, the input hydrant is a hydrant to which cleaning air and water are supplied when cleaning the underground buried pipe, and means a hydrant located at the tip of the underground buried pipe determined as the cleaning target range. It may be the #1 fire hydrant located at the tip of the range of the underground landfill pipe determined as the range to be cleaned.

In addition, the discharge hydrant is a hydrant that discharges drain water generated inside the buried pipe according to the cleaning of the underground buried pipe when cleaning the underground buried pipe. 3 may be, for example, #3 fire hydrant located at the rear end of the range of the underground landfill pipe determined as the range to be cleaned.

In addition, the branch pipe for replenishment of air is a water supply pipe connected to each consumer to which cleaning air is supplemented when cleaning the underground buried pipe. It refers to some of the water supply pipes among the plurality of water supply pipes that supply water to each consumer located between the hydrants 30, and in FIG. Among the plurality of water supply pipes (#1 to #7) that supply water to each customer located between the #1 fire hydrant 30 and the #3 fire hydrant 30, which is a hydrant for discharge, some of the #1, #2, #3 It can be a water supply pipe.

The reason why the plurality of branch pipes 40 are required for cleaning the underground buried pipe 20 determined as the cleaning target range will be described.

For cleaning the underground buried pipe 20, the pressure of the cleaning air injected into the underground buried pipe 20 through the input hydrant 30 is proportional to the length of the underground buried pipe to be cleaned. That is, in order to generate a cleaning effect, the longer the length of the underground buried pipe to be cleaned, the greater the pressure of the cleaning air.

That is, a pressure generating device (such as an air compressor) that generates an ultra-high pressure is required to clean the long length of the underground buried pipe 20, but in reality, an underground buried pipe using a pressure generating device (such as an air compressor) that generates an ultra-high pressure Cleaning is uneconomical, so small and medium-sized air compressors are generally used, which limits the pressure level of the air injected into the underground landfill pipe and shortens the length of the underground landfill pipe that can be washed at once. there is

Therefore, if cleaning air can be replenished in the middle of the underground landfill pipe to be cleaned when cleaning the underground landfill pipe, the length of the underground landfill pipe to be cleaned is not limited even if an air compressor with a small capacity is used.

In the present invention, an air replenishment branch pipe capable of replenishing the cleaning air in the middle of the underground buried pipe to be washed is configured so that the length of the underground buried pipe to be washed is not limited while using an air compressor of a small capacity. In particular, the branch pipe for replenishment of air is characterized in that it uses a water supply pipe previously installed in connection with an underground buried pipe to supply water to each consumer rather than separately installed in the underground buried pipe to be washed.

Taking Figure 3 as an example, in order to supply water to each consumer, #1 to 3 water supply pipes among #1 to #7 water supply pipes that are already connected to the underground buried pipe 20 in the range to be washed are branch pipes for replenishment of air. (40) is used.

The third step (S300) is a step of determining a washing pressure for washing the underground buried pipe 20 determined as a washing target range.

The washing pressure determined in the present invention is not a pressure corresponding to the entire length of the underground buried pipe 20 determined as the washing target range, but effectively cleans the underground buried pipe in a portion of the entire underground buried pipe 20 determined as the washing target range It means the pressure that can be done, and is determined as described below.

That is, the washing pressure determined through the third step (S300) is the length of the underground buried pipe 20 connected to the input hydrant 30 and the branch pipe 40 for replenishing the air closest to the input hydrant 30, which One air replenishment branch pipe 40 and the other branch for air supplementation closest to one air supplement branch pipe 40 are connected to the underground buried pipe 20 length, the discharge hydrant 30 and the discharge hydrant 30. Among the lengths of the underground buried pipe 20 to which the closest branch pipe for replenishing air 40 is connected, it is characterized in that it is a pressure that can give a washing effect to the underground buried pipe 20 of the longest length.

Hereinafter, a process of determining the washing pressure will be described in detail with reference to FIGS. 3 and 4 as an example.

3, for example, for replenishing air closest to the hydrant 30 (#1 hydrant) and the hydrant 30 for input on the underground buried pipe 20 (eg, total length of 1.350 m) that is the range to be cleaned. The branch pipe 40 (#1 branch pipe) is connected to the underground buried pipe 20 length (① in FIG. 3), any one air supplement branch pipe 40 and the other closest to any one air supplement branch pipe 40 The length of the underground buried pipe 20 to which the air supplemental branch is connected (②, ③ in Fig. 3), the underground buried pipe in which the exhaust hydrant 30 and the air supplemental branch 40 closest to the exhaust hydrant 30 are connected (20) Calculate the length (④ in Fig. 3) using the underground reclaim pipe installation drawing. For example, as shown in FIG. 4, ①: 400 m, ②: 350 m, ③: 300 m, ④: 300 m may be calculated.

At this time, a pressure capable of giving a cleaning effect to the underground buried pipe of the longest length (400 m) among the calculated lengths is calculated. 4, for example, a pressure A that can give a washing effect to the underground buried pipe corresponding to the longest length of 400 m is calculated, and the calculated pressure A is used as a washing pressure for cleaning the underground buried pipe 20 decide

It goes without saying that the diameter of the buried pipe should be considered when calculating the washing pressure, and the diameter information can be obtained using the installation drawing of the underground buried pipe.

When the cleaning pressure is determined as described above, the hydrant 30 (#1 fire hydrant) and the branch pipe 40 (#1, #2) for supplying air having the pressure determined through the fifth step to be described later are introduced. , #3 branch pipe) for cleaning the pipeline.

If, without the configuration of the branch pipe 40 for replenishment of air, a fairly large high pressure washing pressure D (≫A) is required for washing the underground buried pipe (eg, total length of 1,350 m) to be washed as shown in FIG. 3 . However, in the present invention, only the pressure A (≪D) that can give a cleaning effect to the underground buried pipe having a length (eg, 400 m) smaller than the total length of the underground buried pipe to be washed is required, so the equipment for generating pressure for washing is required. Since it is possible to use a general air compressor, there is an advantage in that it is not necessary to use an expensive ultra-high pressure air compressor.

The fourth step (S400) is a step of blocking the drain valve 50 so that water is not supplied to the underground buried pipe 20 determined as the cleaning target range.

When cleaning the underground buried pipe 20 determined as the cleaning target range, it is effective when there is no inflow of water from the neighboring underground buried pipe 20 that is not a target of washing or a discharge of water from the neighboring underground buried pipe 20 that is not a target of washing. washing takes place To this end, as shown in FIG. 1 , water supply and entry are blocked using a septic valve so that there is no water flow or entry into the underground buried pipe 20 determined as the cleaning target range.

If, when cleaning the underground buried pipe 20, water flow to and from the underground buried pipe 20 determined as the cleaning target range is not blocked, the drain generated by washing in the underground buried pipe 20 determined as the cleaning target range Water flows out to the adjacent underground landfill pipe 20 that is not a target for washing, and drain water, which is contaminated water, is supplied to each consumer connected to the neighboring underground reclamation pipe 20 that is not a target for washing, causing various civil complaints, and the range of washing target. The pressure of the cleaning air injected into the underground buried pipe 20 determined as

When the cleaning of the underground buried pipe 20 determined as the cleaning target range is completed, the drain valve is opened again to return water to and from the underground buried pipe 20 determined as the cleaning target range.

In the fifth step (S500), the pressure determined through the third step (S300) is applied to the hydrant 30 for input determined through the second step (S200) for cleaning the underground buried pipe 20 determined as the cleaning target range. In a step of supplying washing air and water for washing at a predetermined pressure, and supplying air for washing at a pressure determined through the third step (S300) to the branch pipe 40 for replenishing the air determined through the second step (S200) , Specifically, the fifth step (S500) is,

Step 5-1 (S510) of generating cleaning air having a cleaning pressure determined through the third step (S300) using an air compressor;

Step 5-2 (S520) of filtering foreign substances and oil contained in the cleaning air using a filter;

Step 5-3 (S530) of distributing the cleaning air having the filtered cleaning pressure using the air distributor;

Step 5-4 (S540) of supplying washing air having a washing pressure distributed to the input fire hydrant and washing water at a predetermined pressure;

It is characterized in that it comprises a 5-5 step (S550) of supplying the cleaning air having the distributed cleaning pressure to the air replenishment branch pipe.

Step 5-1 ( S510 ) is a step of generating cleaning air having the cleaning pressure determined through the third step ( S300 ). As shown in FIG. 1 , the third step using the air compressor 110 is used. The cleaning air having a cleaning pressure (eg, pressure A) determined through step S300 is generated.

At this time, the pressure of the air generated by the air compressor 110 is not the pressure that can wash the total length of the underground buried pipe in the range to be washed (eg, 1,350 m), but the total length of the buried pipe 20 determined by the range to be washed. It means the pressure that can effectively clean the underground buried pipe in some sections, and as described above, the hydrant 30 for input and the branch pipe 40 for replenishment of the air closest to the hydrant 30 for input are connected to the buried underground. The length of the pipe 20, the length of the underground buried pipe 20 connected to the branch pipe for replenishing air 40 and the branch pipe for replenishing the air closest to the branch pipe 40 for replenishment of one air, the hydrant 30 for discharge and Among the lengths of the underground buried pipe 20 to which the branch pipe 40 for replenishment for air closest to the discharge hydrant 30 is connected, the longest length of the underground buried pipe 20 (a length corresponding to ① in FIG. 4) ), characterized in that it is a pressure that can give a cleaning effect.

Step 5-2 ( S520 ) is a step of filtering foreign substances and oil contained in the cleaning air generated by the air compressor 110 . As shown in FIG. 1 , a filter 120 is used for cleaning. Remove foreign substances and oil contained in the air.

If the cleaning air is supplied to the air distributor 130 in a state in which foreign substances and oil are included, or is put into the underground buried pipe 20, the foreign substances and oil block the distribution pipes of the air distributor 130 to prevent air distribution. This is not done properly, and foreign substances and oils act as factors that interfere with the cleaning of the underground burial pipe, and the cleaning efficiency is lowered. 120) to remove it.

The step 5-3 (S530) is a step of distributing the washing air having the filtered washing pressure. As shown in FIG. 1, the washing air having the washing pressure using the air distributor 130 is used. distribute the

As described above, the cleaning air generated by the air compressor 110 must be supplied to the hydrant 30 for input and the branch pipe 40 for replenishment, respectively. For this purpose, cleaning using the air distributor 130 Distributing cleaning air having a working pressure.

In step 5-4 (S540), washing air having a washing pressure distributed to the input hydrant 30 and washing water at a predetermined pressure for washing the underground buried pipe 20 determined as the washing target range This is the supply stage.

Water for washing at a constant pressure is supplied to the hydrant 30 for input through the water supply device 140 as shown in FIG. 1 .

As shown in FIG. 5 , the washing air having a washing pressure supplied to the input fire hydrant 30 and washing water at a predetermined pressure are injected into the underground buried pipe 20 to perform a pipe cleaning function.

Step 5-5 (S550) is a step of supplying cleaning air having a pressure for cleaning distributed to the branch pipe 40 for air supplementation.

The pressure of the washing air injected into the underground landfill pipe 20 through the above-described step 5-4 (S540) is not the pressure capable of washing the total length of the underground landfill pipe in the range to be washed, but the entire underground determined by the range to be washed. A pressure that can effectively clean the underground buried pipe in some sections of the buried pipe 20 (the hydrant 30 for input and the branch pipe 40 for replenishment of the air closest to the hydrant 30 for input is connected to the underground buried pipe 20 ) length, the length of the underground buried pipe 20 connected to one of the air supplement branch pipes 40 and the other air supplement branch pipe closest to any one air supplement branch pipe 40, the discharge hydrant 30 and the discharge hydrant Among the lengths of the underground buried pipe 20 to which the branch pipe 40 for replenishment of air closest to (30) is connected, the pressure that can give a washing effect to the underground buried pipe 20 of the longest length) is buried in the range to be cleaned Not enough to wash the total length of the tube.

Therefore, as shown in FIGS. 1 and 6, the cleaning air having the pressure for cleaning distributed to the branch pipes 40 for replenishing the air determined through the second step is supplemented and supplied.

At this time, in order to supply the cleaning air distributed to the air supplementary branch pipes 40 , the air supply coupler 150 is installed in the air supplementary branch pipes 40 , and the installed air supply coupler 150 is installed. The cleaning air having a cleaning pressure is supplied to the branch pipes 40 for replenishing the air.

On the other hand, when air and water for cleaning are injected into the underground buried pipe 20 determined as the cleaning target range through the fifth step (S500), the underground buried pipe is washed, and the underground buried pipe is buried as a result of the underground buried pipe cleaning Drain water, which is contaminated water, is generated inside the pipe.

The generated drain water, which is polluted water, is discharged to the outside through the hydrant 30 for discharge. When the drain water, which is the contaminated water, is discharged to the outside through the hydrant 30 for discharging as it is, various pollutants contained in the drain water Various complaints arise due to excessive noise and exhaust noise.

Therefore, the present invention is configured to further include a sixth step (S600) of treating the drain water discharged to the outside through the hydrant 30 for discharge.

The sixth step (S600) is,

Step 6-1 (S610) of filtering foreign substances contained in the drain water using a filter;

It characterized in that it comprises the step 6-2 (S620) of reducing the noise generated by the drain water discharge pressure using the dust collector.

The 6-1 step (S610) is a step of filtering foreign substances contained in the drain water discharged to the outside through the hydrant 30 for discharge by using the drain filter 210, as shown in FIGS. 1 and 7, If the drain water is discharged outside as it is in an unfiltered state, civil complaints may occur due to contamination of the surroundings, so that foreign substances contained in the drain water are filtered using the drain filter 210 .

The 6-2 step (S620) is a step of reducing the noise generated by the drain water discharge pressure using the dust collector 220. When the drain water is discharged to the outside through the discharge hydrant 30, the Noise is generated, and the noise can cause civil complaints, and the noise generated by the drain water discharge pressure is reduced by using the dust collector 220 .

On the other hand, when the cleaning of the underground buried pipe to be cleaned is completed, the blocked drain valve 50 is opened to allow water flow and access to the underground buried pipe 20 that has been cleaned.

Although the technical idea of the present invention has been described together with the accompanying drawings, the preferred embodiment of the present invention is exemplarily described and does not limit the present invention. In addition, it is a clear fact that various modifications and imitations are possible by anyone with ordinary skill in the art without departing from the scope of the technical idea of the present invention.

10: Cleaning method of underground landfill pipe using fire hydrant

Claims (6)

In the underground landfill pipe cleaning method using a fire hydrant,
A first step (S100) of determining a cleaning target range of the underground buried pipe by using the underground buried pipe installation drawing;
a second step (S200) of determining a hydrant for input, a hydrant for discharge, and a branch pipe for replenishment of air, among hydrants and branch pipes connected to the underground landfill pipe determined as the range to be cleaned;
a third step (S300) of determining a washing pressure for washing the underground buried pipe determined as a washing target range;
a fourth step (S400) of blocking the septic tank so that water is not supplied to the underground buried pipe determined as the range to be washed (S400);
For cleaning the underground burial pipe determined as the range to be washed, the washing air of the pressure determined through the third step (S300) and the washing water of a certain pressure are put into the hydrant for input determined through the second step (S200), A fifth step (S500) of supplying the cleaning air of the pressure determined through the third step (S300) to the branch pipe for replenishing the air determined through the second step (S200),
The hydrant for input determined through the second step (S200) is a hydrant to which water and air for washing are supplied when cleaning an underground buried pipe, and is a hydrant located at the tip side of the underground buried pipe determined as the cleaning target range,
The hydrant for discharge determined through the second step (S200) is a hydrant that discharges drain water generated by washing the underground burial pipe when cleaning the underground burial pipe. ,
The branch pipe for replenishment of air determined through the second step (S200) is a water supply pipe to which cleaning air is supplied when cleaning the underground buried pipe, and is located between the input hydrant and the discharge hydrant on the underground buried pipe determined as the cleaning target range. A method of cleaning an underground buried pipe using a fire hydrant, characterized in that it is a part of the water supply pipe among a plurality of water supply pipes that supply water to each of the consumers located there.
According to claim 1,
The first step (S100) is,
A method of cleaning an underground buried pipe using a fire hydrant, characterized in that a plurality of hydrants and a plurality of branch pipes are connected as a cleaning target range.
delete According to claim 1,
The washing pressure determined through the third step (S300) is,
The length of the underground buried pipe where the input hydrant and the branch for replenishment closest to the hydrant for input are connected, the length of the underground buried pipe where one air replenishment branch and the other branch for replenishment closest to one branch for replenishment of air are connected, the discharge A method of cleaning an underground buried pipe using a fire hydrant, characterized in that it is the pressure that can give a cleaning effect to the longest length of the underground buried pipe in which the branch pipe for replenishing the air closest to the hydrant for discharge and the hydrant for discharge is connected.
The method of claim 1,
The fifth step (S500) is,
Step 5-1 (S510) of generating cleaning air having a cleaning pressure determined through the third step (S300) using an air compressor;
Step 5-2 (S520) of filtering foreign substances and oil contained in the cleaning air using a filter;
Step 5-3 (S530) of distributing the cleaning air having the filtered cleaning pressure using the air distributor;
Step 5-4 (S540) of supplying washing air having a washing pressure distributed to the input fire hydrant and washing water at a predetermined pressure;
A method of cleaning an underground buried pipe using a fire hydrant, characterized in that it comprises a 5-5 step (S550) of supplying washing air having a distributed washing pressure to the air replenishment branch pipe.
According to claim 1,
Further comprising a sixth step (S600) of treating the drain water discharged from the hydrant for discharge,
The sixth step (S600) is,
Step 6-1 (S610) of filtering foreign substances contained in the drain water using a filter;
A method of cleaning an underground buried pipe using a fire hydrant, comprising the step 6-2 (S620) of reducing the noise generated by the drain water discharge pressure using a dust collector.

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