KR20010097325A - prevent pollution installa-tion And Produce Method of nunderground water a tube well - Google Patents

Abstract

An object of the present invention is to provide a pollution prevention device of the ground water intake pipe and its manufacturing method to install on top of the ground water development facilities, use facilities and the like to improve the function of the facilities and block external pollution from the ground.

The present invention provides a first intake pipe through the underground rock to contact the groundwater layer, and the ground water in the first intake pipe is discharged through the groundwater piping facilities as a motor pump, the upper portion of the first intake pipe Is a protective device for groundwater intake pipes to be protected by a concrete structure having an openable cover, and welds a second intake pipe of the same diameter having a hermetic watertight cover on an upper end of the first intake pipe; After opening the watertight cover of the groundwater discharge pipe is located through the opening to the inside of the intake pipes, the groundwater discharge to any one side of the connector having a discharge passage pre-installed at the corresponding position with the groundwater piping facilities of the second intake pipe By connecting a pipe, and on the other side of the connector by watertightly connecting the piping facility for contacting the discharge pipe, Prevent the contamination of underground water from flowing into the intake pipe and that will prevent water pollution of underground water, and improve the function of the state of the heart and facilities.

Description

Prevention pollution installa-tion and Produce Method of nunderground water a tube well}

The present invention relates to a pollution prevention device of a water intake pipe used to take ground water and a method of manufacturing the same, and in particular, an upper portion of the ground water intake pipe to close the inside of the water intake pipe so as to prevent contact with the outside. It is about the pollution prevention device of the intake pipe adopting and the manufacturing method.

In general, it is well known that groundwater intake facilities are being developed for drinking water or agricultural and industrial purposes, and examples of the groundwater intake facilities are shown in FIGS. 1 and 2. 1 is a cross-sectional view of a pollution prevention facility of a conventional groundwater intake pipe, Figure 2 is a plan view thereof.

As shown in the drawing, the iron intake pipe 1 passes through the underground rock bed to reach the flow position of the groundwater by rock excavation, and then cement grouting around the upper portion of the intake pipe 1 embedded in the ground. (Grouting) portion (2) is installed so that the intake pipe (Casing) (1) is firmly fixed and supported. Around the upper portion of the protective tube (1) is excavated as a predetermined depth (approximately 1050mm) width (approximately 1200mm) and then installed inside the concrete structure (3) of the rectangular structure. At this time, the water intake pipe 1 exposed to the outside is cut only leaving a length of approximately 30cm from the surface, and the structure cover 4 for blocking the inflow of contaminants is installed on the upper portion of the structure (3). .

In addition, the upper opening of the intake pipe (1) is placed on the intake pipe cover 5 made of steel for preventing the inflow of contaminants into the intake pipe (1), a part of the intake pipe cover (5) will be described later In order to insert and install the facilities to the inside of the intake pipe (1) is formed a cutout (11). Inside the intake pipe 1, the discharge pipe 6 for pumping and discharging the groundwater in the intake pipe 1 is installed as a state penetrating through the cutout portion 11 of the cover 5. And connected to the existing water metering facility 13, the pressure gauge 15, the water extraction device 16, and the groundwater piping facility 7 composed of the reverse side 17, and the lower end of the discharge pipe 6 The side is equipped with the submersible motor pump 8 for pumping groundwater. The motor pump 8 is connected to the power controller 9 installed in the structure 3 through a power line 10 injected through the cutout 11 installed in the intake pipe cover 5. The motor pump 8 is controlled to be automatically controlled by the controller 9. In addition, a water level measuring tube 18 having a length corresponding to the discharge tube 6 is built into the intake pipe 1 to penetrate the cutout 11 of the intake pipe cover 5. It protrudes.

When the motor pump 8 is driven by the power automatic controller 9 in this configuration, the underground rock water stored in the water intake pipe 1 is immediately discharged by the suction force of the motor pump 8. (6) and through the groundwater plumbing facility (7) to the destination.

However, the existing groundwater intake facility as described above is located in a state in which the discharge pipe 6 protrudes over the intake pipe cover 5 and is installed in the water intake pipe 1 (motor pump and water level measurement pipe, etc.). Since the intake pipe cover 5 does not block the inside and outside of the intake pipe 1 and is always open, contaminants in the atmosphere (bacteria, soot, dust, heavy metals, etc.) are supported. If there is a risk of this easily penetrating and if the waterproofing of the concrete structure 3 is not perfect or if the water is filled in the bottom of the structure 3 due to the careless management of the facility, the contaminated surface water is easily removed from the intake pipe 1. There is a risk of inflow into the interior, and there is a difficulty in water quality management, such as being unable to effectively prevent the influx of harmful microorganisms, bacteria, insects that may be propagated in the moist structure (3).

Particularly, when the groundwater use facility such as the above is flooded in a flooded area due to flooding in summer, soil and contaminants introduced into the concrete structure 3 are opened in the inlet pipe cover 5. Directly flowing into the intake pipe (5) through the (11) and accumulates on the bottom of the intake hole, which is a factor that directly contaminates the groundwater, and thus contaminated ground water intake pipe (1) is cleaned inside In addition to the disinfection work and maintenance of the pumping facilities and can be used after the enormous recovery costs, and if the pollution is severe, there is a problem that must be closed because the recovery is impossible.

In case of emergency, biological or chemical warfare or radioactivity is leaked and the surroundings are polluted. Infected germs, poison gas or radioactive material that can easily flow into the interior of the concrete structure 3 are opened in the incision of the protective tube cover 5. There is a possibility that the problem of contaminating the groundwater is easily penetrated into the inside of the intake pipe (1) through the unit (11), this type of groundwater contamination is not possible to improve and recover, which is fatal to the use of groundwater resources There is a distraction going crazy.

In addition, the discharge pipe (6) protruding and installed in the upper portion of the intake pipe cover (5) covering the upper end of the intake pipe (1) which is installed approximately 30 cm or more from the bottom of the concrete structure (3) according to the groundwater installation facility standards Existing groundwater plumbing facilities (7) and water pipes are as close to the ground as possible, so there is a risk of being easily exposed to freezing waves if the cold continues in winter.

Accordingly, an object of the present invention is to solve the above-mentioned problems, and by employing a sealing device for watertightly closing the upper end of the intake pipe as well as the newly installed intake pipe, the water quality of the groundwater is economical and always The present invention provides a pollution prevention device for a groundwater intake pipe and a method of fabricating the same, which can be maintained in a clean state.

It is another object of the present invention to provide an apparatus for preventing contamination of the groundwater intake pipe and a method of manufacturing the same, which improve the condition of the intake pipe and the function of the facility.

In order to achieve the above object, the pollution prevention device of the groundwater intake pipe of the present invention is buried in contact with the groundwater layer through the underground rock according to the invention of claim 1 and can be discharged through the groundwater piping facilities as a motor pump therein. A groundwater intake pipe protector provided with a first intake pipe through which ground water flows, wherein an upper portion of the first intake pipe is protected by a concrete structure having a cover, wherein an upper portion of the first intake pipe is a sealed watertight seal. A ground water discharge pipe which welds a second intake pipe of the same diameter having a cover and is completely embedded in the intake pipes through the second intake pipe opened by the watertight cover, and the ground water discharge pipe Among the intake pipes, the drilled hole is drilled at a position corresponding to the ground water piping facility of the second intake pipe, so that the discharge pipe and the ground water piping facility A through hole for locking and a discharge passage communicating with the groundwater discharge pipe and the groundwater piping facility, and mounted to the throughhole, the groundwater discharge pipe on one side of the discharge path, and the groundwater pipe on the other side of the discharge path. It characterized in that it comprises a connector for connecting each facility watertightly.

Wherein the connector is a first connection socket for connecting in contact with the ground water discharge pipe, and a second connection socket for connecting the first connection socket and the groundwater plumbing facility is installed in the through hole of the second intake pipe It is preferable to include.

In addition, the watertight cover for the water intake pipe is fastened to the water intake pipe via a watertight member, and the watertight cover is preferably provided with an automatic exhaust port having an antibacterial filter driven by a solenoid valve.

In addition, it is preferable to install a ground level sensor rod on the outer wall of the intake pipe.

In addition, it is preferable to install a power line outlet inclined downward on the second intake pipe side of the intake pipes.

In order to achieve the above object, the manufacturing method of the pollution prevention device of the groundwater intake pipe of the present invention is to install a first intake pipe to be in contact with the groundwater layer through the underground rock and groundwater in the first intake pipe as a motor pump. In the manufacturing method of the protective device for ground water intake pipe to be discharged through the ground water piping facility, the upper portion of the first intake pipe is protected by a concrete structure having a cover that can be opened, Closed watertight at the top of the first intake pipe Welding a second intake pipe of the same diameter having a cover, opening the watertight cover of the second intake pipe, and then positioning the groundwater discharge pipe through the opening into the intake pipes; Connecting the groundwater discharge pipe to one side of the connector having a discharge passage pre-installed at a corresponding position with the groundwater piping facility of the; The other side is a step for watertightly connecting the plumbing facilities for contacting the discharge pipe, and covering the upper part of the intake pipe as a watertight cover and fastening as a fastening bolt to block the inside and outside of the intake pipe. It is characterized by including.

1 is a cross-sectional view of a pollution blocking facility of a conventional groundwater intake pipe,

2 is a plan view thereof;

3 is a cross-sectional view of the facility of the pollution prevention device of the groundwater intake pipe according to the present invention,

4 is a plan view thereof

5 is an enlarged view of a portion A of the display of FIG. 3;

6A to 6H are views for implementing the manufacturing method of the pollution prevention device of the ground water intake pipe according to the present invention.

* Explanation of symbols for the main parts of the drawings *

100,110: first and second intake pipe (Casing) 115: power line outlet

116: fastening bolt 120: watertight cover

122: watertight member 130: concrete structure

140: groundwater discharge pipe 144: submersible motor pump

146 power cable 148 automatic controller

150: groundwater plumbing facility 160: connector

162: passage 164,166: socket for first and second connection

170: air vent 172: solenoid valve

174: antibacterial filter 180: water level detection rod

190: level gauge

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the pollution prevention device of the groundwater intake pipe according to the present invention and a method of manufacturing the same.

3 is a cross-sectional view of the facility of the pollution prevention apparatus of the groundwater intake pipe according to the present invention, FIG. 4 is a plan view thereof, and FIG. 5 is an enlarged view of portion A of FIG.

As shown in the drawing, the pollution prevention apparatus of the groundwater intake pipe according to the present invention includes a first intake pipe 100 made of steel embedded in contact with the groundwater layer by excavating through the underground rock. The upper portion of the first intake pipe 100 is protected by a concrete structure 130 forming a working room 134, and the upper portion of the concrete structure 130 is in a cover 132 having a work tool 134 It is closed so that opening and closing is possible.

The upper end of the first intake pipe 100 is welded to the second intake pipe 110 of the same diameter having a sealed watertight lid 120 to be integrated. The second intake pipe 110 is preferably made of stainless steel to prevent corrosion. The first intake pipe 100 is preferably cut to protrude approximately 5cm from the bottom in the concrete structure 130 in advance for the installation of the second intake pipe (110).

The watertight cover 120 is detachably fastened by fastening means 116 such as a fastening bolt to the flange portion 112 formed in the second intake pipe 110, and the watertight cover 120 and the fran A watertight member 122 such as a packing for maintaining watertightness is provided between the branches 112. The watertight cover 120 is introduced into the protection pipes 100 and 110 in which contaminated surface water or air pollutants may be introduced into the concrete structure 130 due to neglect of management of groundwater facilities or other special circumstances. It completely blocks you from being.

The ground water discharge pipe 140 is completely immersed in the intake pipes 100 and 110 in a state in which the cover 120 is opened before the cover 120 is installed in the second intake pipe 110. The groundwater discharge pipe 140 corresponds to the groundwater piping facility 150 including the integrated water meter 151, the pressure gauge 152, the water discharge device 153, and the reverse valve 154 in the second intake pipe 110. The passage 162 is watertightly installed in the through-hole 118 perforated at the connector 160 to form a passage 162 for communicating with the discharge pipe 140 and the groundwater piping facility 150. Are in contact with Therefore, the groundwater discharged from the discharge pipe 140 is supplied to the destination through the connector 160 and the groundwater piping facility 150.

The connector 160 has a first connection socket 164 for connecting in contact with the groundwater discharge pipe 140. The first connection socket 164 is attached to the through hole 118 of the second intake pipe 110 for a second connection for contacting the first connection socket 164 and the groundwater piping facility 150 It is tightly coupled to the socket 166. The other side of the second connection socket 166 is hermetically coupled to be in contact with the groundwater piping facility 150. The first and second connection sockets 164 and 166 communicate with the discharge pipe 140 and the groundwater piping facility 150 by a passage 162 formed therein.

The connector 160 is separated into a first connection socket 164 and a second connection socket 166, and installs the pumping facility (motor pump, discharge pipe, etc.) integrally inside the water intake pipes (100, 110). By the role of fixing to enable the installation of the watertight cover 120, and the discharge pipe 140 is connected to the reference facility directly in the intake pipes (100, 110), the concrete structure of the current groundwater facility ( The facility (water meter, pressure gauge, water extraction device, reverse side) and the water supply pipe connected thereto can be installed close to the bottom of the concrete structure 130 at the bottom of 130). The risk of freezing of groundwater facilities can be reduced.

A motor pump 144 for pumping ground water is mounted at a lower end of the discharge tube 140, and a power wire 146 connected to the motor pump 144 is any one side of the second intake pipe 110. It is to be connected to the automatic controller 148 installed in the side wall portion of the concrete structure 130 through the downwardly inclined outlet 115 installed in the main wall. The outlet 115 is completely closed except for the portion where only the power wire 146 is drawn, thereby completely closing the inflow of contaminants into the intake pipes 100 and 110. The motor pump 144 is driven by a control signal by the automatic controller 148 to suck the ground water from the discharge pipe 140 to discharge to the outside. Since the technology for driving or stopping the motor pump 144 by the automatic controller 148 is a general one, a detailed description thereof will be omitted.

The watertight cover 120 has a solenoid valve for maintaining a vacuum state by constantly adjusting the pressure generated therein by closing the water intake pipes (100,110) as a watertight cover (120). An automatic exhaust port 170 having a 172 is provided.

The solenoid valve 172 is connected to a power supply to the automatic controller 148, the solenoid valve 172 is opened when the motor pump 144 is operated to the inside of the intake pipe (100, 110) When the air pump is introduced and the motor pump 144 is stopped, the valve 172 is closed to block the inflow of outside air and pollutants. Therefore, the groundwater development facility and utilization facility in the area where the flooding occurs due to extreme weather or flooding Even if all are submerged in water, contaminants are prevented from flowing into the intake pipes 100 and 110 to completely prevent water pollution. Therefore, when water falls into the concrete structure 130, At any time, the motor pump 144 may be operated to reuse high quality ground water.

In addition, the solenoid valve 172 forms a vacuum of a constant pressure inside the intake pipes 100 and 110 together with the automatic exhaust port 170 for automatically adjusting the pressure in the intake pipes 100 and 110. Suppresses the possibility of bacteria propagation inside the pipes (100, 110), prevents the formation of mucus, and when pumping groundwater, by increasing the outflow rate of groundwater by the suction force according to the vacuum to expand the water vein cleaning and expansion effect To maximize groundwater production and to maintain a sanitary well at all times. Since a series of configurations in which the solenoid valve 172 is opened and closed is a general technology, description thereof will be omitted.

The automatic exhaust port 170 having the valve 172 is provided with a built-in antibacterial filter 174. The built-in antimicrobial filter 174 is the same material as the filter medium used for a general gas mask, the antimicrobial filter 174 is the solenoid valve 172 for the pumping of ground water is opened so that the outside air is the intake pipe (100,110) ) It filters the pollutants in the air (bacteria, soot, dust, heavy metals, chemicals, etc.) that flow together when it enters the inside of) and prevents the occurrence of everyday groundwater contamination as well as the leakage of biological, chemical warfare or radioactivity in case of emergency. Effectively deal with accidents, etc., to minimize water pollution.

The outer circumferential wall portion of the intake pipe 110 is provided with a sensing rod 180 for detecting the level of groundwater. The water level detection rod 180 is electrically connected to the automatic controller 148, so that when the water is filled in the interior of the concrete structure 130 or emergency evacuation due to heavy rain due to extreme weather conditions artificially automatic When the power of the controller 148 is not cut off, the automatic controller 148 is automatically cut off by detecting the level of water that is pushed into the interior of the concrete structure 130 to fill up. This is because when the motor pump 144 operates as usual despite the state of the water filled inside the concrete structure 130, the water contaminated by the opening of the solenoid valve 172 is the intake pipe Even the situation that may be introduced into the interior of the field (100,110) to prevent in advance to protect the groundwater quality inside the intake pipe (100,110).

The water intake pipes 100 and 110 are provided with a water level gauge 190. The water level measuring system 190 has a length corresponding to the discharge pipe 140, and serves to read the ground water level inside the water intake pipes 100 and 110, so that the watertight cover 120 is withdrawn. Even when the pipe is closed tightly, the groundwater level inside it can be accurately known.

The reference numeral 200 denotes a cement grouting portion installed to firmly support the intake pipe (Casing).

6A to 6H are diagrams for implementing a method for manufacturing a pollution prevention apparatus for groundwater intake pipe according to the present invention, with reference to this figure will explain the manufacturing process of the pollution prevention apparatus for groundwater of the present invention.

FIG. 6A illustrates the buried operation of the first water intake pipe 100 forming the water intake hole by rock excavation, and the first water intake around the upper part excavated in the ground together with the installation of the first water intake pipe 100. Cement grouting (200) for fixing and supporting the pipe (100) is constructed.

6B shows that the concrete structure 130 is installed to the upper portion of the first water intake pipe 100, and is disposed around the upper portion of the first water intake pipe 100 to be approximately horizontal, vertical, and height based on an internal reference. Is installed to protrude more than 30cm from the ground above the concrete structure 130 each having a size of more than 100cm thickness 15cm or more.

6C shows that the first intake pipe 100 is cut, and the first intake pipe 100 has an upper portion of the first intake pipe 100 after completion of the installation of the concrete structure 130. The cut is made so as to protrude about 5 cm from the bottom of the structure 130. The reason is to facilitate the welding work with the second intake pipe 110 to be described later.

FIG. 6D illustrates welding the second intake pipe 110 to the first intake pipe 100. The upper portion of the first intake pipe 100 has the same diameter as that of the first intake pipe 100. The second intake pipe 110 of stainless material is positioned and welded by electric welding. The first intake pipe 110 in the state in which the outlet 115, the watertight cover 120, the connector 160, the automatic exhaust port 170 and the water level measuring instrument 190 is mounted and integrated in the second intake pipe 110 in advance. It is welded integrally to the 100.

6E illustrates a process of embedding the discharge pipe 140 and the power wire 146 in the intake pipes 100 and 110, and discharge the watertight cover 120 of the second intake pipe 110 after opening. The water motor pump 144 and the power wire 146 are integrally connected to the pipe 140 and inserted into the intake pipes 110 and 110 to a predetermined depth.

6F illustrates a process of installing the discharge pipe 140 and the water level measurement system 190. The second intake pipe 110 is inserted into the discharge pipe 140 by inserting the first connection socket 164 of the connector 160. ) Is coupled to the second connection socket 166 pre-installed, and the water level measuring tube is coupled to the water level gauge (190).

6G illustrates connecting the existing plumbing facility 150 to the connector 160. By connecting the plumbing facility 150 to the connector 160, the discharge pipe 140 and the plumbing facility 150 are connected to each other. To be connected through the connector 160, the upper portion of the second water intake pipe 110 is coupled to the water level measuring tube toward the water level measuring system 190 side, and cover the watertight cover 120 and then fastened as a bolt to protect the tube Block the inside and outside of the field (100,110). In addition, the power wire 146 and the water level sensing line are connected to the power controller 148 pre-installed in the concrete structure 130 through the outlet 115 of the second intake pipe 110 to form an electrical circuit.

6H shows that the cover 132 is installed on the upper portion of the concrete structure 130, and the method of manufacturing the pollution prevention device of the groundwater intake pipe is completed by covering the cover 132 on the concrete structure 130. .

In the above embodiment has been described step by step to help the understanding of the present invention, in fact, it is revealed that the work is continuously performed.

As described above, according to the present invention, since the groundwater pumping facility is completely installed inside the intake pipe, the upper concrete structure is not installed in the extremely narrow space or special conditions, and only the upper portion of the intake pipe is exposed to the ground. Even in special cases where groundwater must be used in a state, the water supply pipe is buried in the ground and a sealed watertight cover is installed at the upper part of the intake pipe to prevent the impact from the ground, the weight load, and the inflow of external pollution sources. When repair due to a breakdown or cleaning of the intake pipe is required, the watertight cover can be opened at any time, and the pumping facility can be separated from the discharge pipe connector to perform necessary work after lifting. ① Easy installation method ② Easy installation even in small space ③We can install without changing groundwater facility in use. ④ The product can be selected arbitrarily according to the diameter of the water intake hole of the existing protective tube. ⑤Made of stainless steel, semi-permanent life. ⑥ Low production and installation cost.

In the above description, but detailed description of the pollution prevention device of the groundwater well according to the present invention and the manufacturing method thereof as described in the accompanying drawings, which is described by way of example only the most preferred embodiment of the present invention This technical content is limited to the present invention It is not. In addition, it can be easily understood that those of ordinary skill in the art that the pollution prevention device of the groundwater well according to the present invention and its manufacturing method can be variously modified and imitated without departing from the scope of the claims.

Claims (6)

It is provided with a first intake pipe through which underground water flows through the underground rock to be in contact with the groundwater layer and allows the groundwater to be discharged through the groundwater piping facility as a motor pump. In the protective device for ground water intake pipe to be protected by a concrete structure having a, The upper end of the first intake pipe is welded and integrated with a second intake pipe of the same diameter having a hermetic watertight cover, and is completely embedded in the intake pipes through the second intake pipe opened by the watertight cover. One groundwater discharge pipe; A through hole which is drilled at a corresponding position with the ground water piping facility of the second intake pipe among the intake protection pipes in which the ground water discharge pipe is embedded, for contacting the discharge pipe and the ground water piping facility; And The groundwater discharge pipe and a discharge passage communicating with the groundwater piping facility are provided in the through hole, and the groundwater discharge pipe on one side of the discharge path and the groundwater piping facility on the other side of the discharge path are closed. Contamination prevention device of groundwater intake pipe including a connector for connecting. According to claim 1, The connector is a first connection socket for connecting in contact with the ground water discharge pipe, and the second intake pipe is attached to the first connection socket and the groundwater piping facility for communicating with the first connection socket Contamination prevention device of groundwater intake pipe, characterized in that it comprises a two connection socket. According to claim 1, The watertight cover is fastened to the water intake pipe via a watertight member, the watertight cover is contaminated with the groundwater intake pipe further comprises an automatic exhaust port having an antibacterial filter driven by a solenoid valve Prevention device. The contamination prevention device of the ground water intake pipe of claim 1, wherein the outer circumferential wall portion of the intake pipe is further provided with a level sensor rod for ground water. The contamination prevention apparatus of the ground water intake pipe according to claim 1, wherein a power line outlet formed to be inclined downward is further installed on the second intake pipe side of the intake pipes. A first intake pipe is installed through the underground rock to contact the groundwater layer, and the groundwater in the first intake pipe is discharged through the groundwater piping facility as a motor pump, and the upper portion of the first intake pipe is openable and closed. In the manufacturing method of the protective device for ground water intake pipe to be protected by a concrete structure having a, Welding a second water collecting pipe having the same diameter to the upper end of the first water collecting pipe; Positioning the groundwater discharge pipe into the intake pipes through the opening after opening the watertight cover of the second intake pipe; Connecting the groundwater discharge pipe to one side of the connector having a discharge passage pre-installed at a corresponding position with the groundwater piping facility of the second intake pipe; Connecting the piping facility to be in contact with the discharge pipe on the other side of the connector; Covering the upper portion of the intake pipe as a watertight cover and fastening with a fastening bolt to block the inside and outside of the intake pipe manufacturing method of the pollution prevention device of the ground water intake pipe.