KR101483524B1 - active type water curtain device of underground oil storage caverna - Google Patents

Abstract

Disclosed is an active water curtain device for an underground oil storage cavern. The active water curtain device according to the present invention includes a water tunnel excavated under the ground at an upper portion of the underground oil storage cavern; a plurality of water holes branched from the water tunnel to maintain air tightness of the underground oil storage cavern and supplying water to the upper portion of the underground oil storage cavern; and a water supply pipe installed to the water tunnel to supply water from a water source to the water holes. A supply area of the water through the water holes is divided into plural areas in a tunnel direction of the underground oil storage cavern. The water supply pipe may be installed separately for every supply region to adjust a water head in view of the underground water head condition for every supply area.

Description

[0001] The present invention relates to an active water wall device for an underground storage space,

The present invention relates to an active water wall device of an underground storage cavity provided underground for oil storage.

The oil underground storage cavity is for storing the oil in the underground cavity by the principle of groundwater. It is not mixed with water (crude oil, LPG, etc.) and is light in weight than water, ) Refers to a facility that excavates a joint to store oil.

In this case, it is essential to prevent the leakage of the oil stored in the underground storage cavity. The permeation control method and the hydro-dynamic containment method for controlling the permeability of the rock bed, . In the former case, the grouting or shotcrete method is applied. In the latter case, the airtightness of the underground storage cavity is maintained through the groundwater pressure.

In other words, the hydraulic dynamical concept is to maintain the groundwater pressure around the underground storage cavity higher than the underground cavity pressure in the pressurized state, thereby creating a condition in which the groundwater always flows into the cavity. Recently, in most cases, the oil underground storage cavity has been used as a hydraulic dynamical method to prevent leakage of oil to ensure airtightness.

In order to prevent the leakage of oil, the groundwater pressure around the underground storage cavity is kept higher than the operating pressure of the underground storage cavity. When only the natural groundwater pressure is used, if sufficient amount of groundwater is not supplied or cultivated , The groundwater level is continuously lowered, and eventually complete dehydration may occur.

Therefore, a water curtain is installed at the upper part of the underground storage compartment so that artificial groundwater pressure can be applied to the natural ground water pressure in a hydraulic dynamically preventing leakage of oil.

FIG. 1 shows a general oil underground storage cavity and a structure of a water wall system employed therein.

As shown in Fig. 1, a water wall system 1 installed above an underground storage cavity 2 is configured to include a water wall tunnel 1a and a water hole 1b. Here, the water hole 1b is a part for artificially injecting water into the upper part of the underground storage cavity 2, and the water wall tunnel 1a is a tunnel for excavating the water hole 1b at regular intervals.

Water supplied to the waterwall tunnel 1a is injected into the upper portion of the underground storage cavity 2 through the respective water vents 1b branching from the waterwall tunnel 1a. At this time, the natural underground water pressure around the underground storage cavity (2) or the injection pressure of the water hole (1b) depends on the distribution characteristic of the site-specific permeable insulation. In FIG. 1, reference numeral 3 denotes a flow path for guiding the flow of oil stored in the underground storage cavity 2, and reference numeral 4 denotes a natural underground water pressure and an injection pressure of the water hole 1b It represents the groundwater layer around the underground storage cavity (2).

Patent Registration No. 10-0249659

On the other hand, an underground storage cavity usually has one unit or two or three caves as a unit cavern, several unit cavities can be adjacent to each other and operate under different conditions. In the conventional water wall system, It is generally designed to inject the infusion water collectively through the pores into the unit cavity or the entire underground storage cavity.

Therefore, in the conventional water wall system, when the airtightness is deteriorated due to the lowering of the ground water pressure in the specific area of the underground storage cavity, the injection head of the total injection water injected into the upper part of the underground storage cavity has to be increased. On the other hand, There is a limit to improve the overall operational efficiency, such as that the injection head of the specific area can not be partially reduced due to the concern of the airtightness deterioration of the other area under high conditions.

An embodiment of the present invention is to provide an active water wall device of an underground storage cavity, which is capable of dividing the injection head of injection water injected into an underground storage cavity into a plurality of injection regions.

Also, the present invention provides an active water wall device having an underground storage cavity in which the injection head structure can be simplified for each injection region so that operation and maintenance of the system can be facilitated.

According to an aspect of the present invention, there is provided a water tunnel tunnel which is excavated underground in an upper part of an underground storage cavity for oil storage and water is injected into the upper part of the underground storage cavity by branching from the waterwall tunnel to maintain the underground storage cavity. And an injection water supply pipe installed in the water wall tunnel to supply injection water of the water supply source to the water hole, wherein an injection area of the injection water injected through the water hole is formed in the underground storage cavity And the infusion water supply pipe is individually provided for each of the individual injection areas so as to adjust the injection head according to the two conditions of the ground water for each of the individual injection areas. A device may be provided.

The water wall tunnel is excavated in a direction perpendicular to the tunnel direction of the underground storage cavity and the water wall holes are arranged along the longitudinal direction of the water wall tunnel to both sides of the water wall tunnel to be formed along the tunnel direction of the underground storage cavity And the injection region may be divided into two sides of the water wall tunnel with respect to the water wall tunnel.

Wherein the injection water supply pipe includes an introduction pipe portion for guiding the introduction of the injection water delivered from the water supply source and a supply pipe portion for supplying the injection water introduced through the introduction pipe portion to the water hole portions belonging to the injection region Wherein the supply pipe portion includes a first supply pipe portion and a second supply pipe portion that are branched from the introduction pipe portion, and the first supply pipe portion is connected to the inlet pipe portion in the longitudinal direction of the water wall tunnel And the second supply piping section is configured to supply the infusion water delivered from the introduction piping section to the sidewall spaced from the introduction piping section at the farthest distance from the inlet piping section So that the ends of the first and second supply pipe portions can communicate with each other.

Wherein the injection water supply pipe includes an introduction pipe portion for guiding the introduction of the injection water delivered from the water supply source and a supply pipe portion for supplying the injection water introduced through the introduction pipe portion to the water hole portions belonging to the injection region Wherein the supply pipe portion includes a first supply pipe portion and a second supply pipe portion, wherein the first supply pipe portion is provided such that a midway between both ends thereof communicates with the end of the introduction pipe, The two middle points may be connected to both ends of the first supply pipe portion in a state where both ends thereof are closed to communicate with the respective water holes in the array direction of the water holes of the region.

The active water wall device of the underground storage cavity may further include an injection head region regulating unit including the injection water supply pipes for measuring the groundwater level of the water hole by the injection region and controlling the injection head by the injection region .

Wherein the control unit for each injection head region comprises a plurality of water tanks for supplying the injection water of the water supply source to the injection water supply pipe assigned for each injection region, A plurality of water level meters, a plurality of open / close valves arranged to intermit flow of inflow water flowing into the respective water tanks from the water supply source, an injection head measuring device arranged to measure the inflow head of water for each of the infusion areas, And a controller for comparing the injection head of each injection region measured by the injection head with the reference injection head of the predetermined injection region and measuring the injection head of each injection region, And a control unit for controlling the operation of the water tank to control the water pressure of each of the water tanks.

Wherein the control unit for each injection head region comprises a plurality of water tanks configured to receive water of the water supply source and supply the water to a plurality of the injection water supply pipes provided for each injection region, A plurality of open / close valves arranged to interrupt the flow of inflow water flowing into the respective water tanks from the water supply source; an injection head measurement device provided to measure the injection head of water for each injection region; The injection head of each injection region is measured by comparing the measured injection head of each injection region with the reference injection head of the predetermined injection region, Selectively combine the water for injection of the assigned water tanks to obtain at least one The injection of the water supply flow channel switching pipe and the flow channel switching valve provided to supply to the pipe may be further included.

The injection head may include a flow meter and a pressure gauge installed to be assigned to the injection region, the flow meter including a digital flow meter, and the hydraulic meter may include a gap hydraulic system.

In the active water wall device of the underground storage cavity according to the embodiment of the present invention, the injection region of the injection water injected through the water hole is divided into a plurality of parts along the unit cavity and the tunnel direction of the underground storage cavity, The infusion water supply piping installed in the water wall tunnel for supplying to the wall is individually installed in each injection area. Therefore, according to the active water wall apparatus of the underground storage cavity according to the embodiment of the present invention, the injection head of the injection water injected into the underground storage cavity can be divided into a plurality of injection regions and controlled according to the underground water pressure conditions So that the operating efficiency of the system can be improved.

Also, according to the embodiment of the present invention, since the groundwater level of the water hole is measured for each divided injection region and the injection head is adjusted for each injection region by reflecting the measurement result of the groundwater level of the water hole, It is possible to operate the water wall device more actively considering the rock property.

Further, in the active water wall device of the underground storage cavity according to the embodiment of the present invention, the injection head of the injection water is uniformly formed in the individual injection region through the injection water supply pipe provided for each injection region, The control structure is simplified, and the operation and maintenance of the water wall device can be facilitated.

FIG. 1 shows the structure of a general oil underground storage cavity.
FIG. 2 is a plan view of an active water wall device of an underground storage cavity according to an embodiment of the present invention together with an underground storage cavity. FIG.
FIG. 3 is a plan view showing a connection structure between a water supply pipe for supplying water for injection and a water hole in the active water wall device according to the embodiment of the present invention.
Fig. 4 is a graph comparing the injection head variation of the sieve holes in the injection region when using the injection water supply pipe shown in Fig. 3 and a common single straight pipe. Fig.
FIG. 5 is a view illustrating a configuration of a control unit for each injection head region in an active water wall device of an underground storage cavity according to an embodiment of the present invention.
6 is a circuit block diagram of a control unit for each injection head region in an active water wall device of an underground storage cavity according to an embodiment of the present invention.
FIG. 7 is a plan view showing a modified example of the connection structure of the infusion water supply pipe and the sidewall spacers according to the injection area in the active water wall device according to the embodiment of the present invention.
FIG. 8 is a view showing a modified example of a control unit for each injection head region in an active water wall device of an underground storage cavity according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided to fully convey the spirit of the present invention to a person having ordinary skill in the art to which the present invention belongs.

The present invention is not limited to the embodiments shown herein but may be embodied in other forms. For the sake of clarity, the drawings are not drawn to scale, and the size of the elements may be slightly exaggerated to facilitate understanding.

2 to 6, an active water wall device 10 of an underground storage cavity according to an embodiment of the present invention includes an underwater storage cavity 11, A water tunnel tunnel 12 which is excavated in the lower part of the upper part of the underground storage cavity 11 and a water tunnel 12 which is installed in the upper part of the underground storage cavity 11 to maintain the airtightness of the underground storage cavity 11. [ A plurality of water holes 13 branched from the water wall tunnel 12 for injecting water for infusion water to be supplied to the water tunnel 13 so as to supply infusion water of the water supply source 17 to the water hole 13, And a pipe (14). In FIG. 2, reference numerals 15 and 16 denote construction tunnels for the attachment of the waterwall tunnel 12 and construction entrance, respectively, and reference symbol a denotes a dotted line for showing the permeable rescue structure of the underground rock.

The underground storage cavities 11 may be arranged so that two or three cavities may form a single unit cavity, and in some cases, a single underground storage cavity 11 may form a cavity of a single stage. 2, the three underground storage cavities 11 form a first unit cavity A and the two underground storage cavities 11 below the second unit cavity B form a third unit cavity B, (C) can be formed.

The active water wall device 10 of the underground storage cavity according to the present embodiment includes a plurality of injection holes 20 for dividing the injection head of injection water injected into the underground storage cavity 11 into a plurality of injection regions 20, And the infusion water supply pipe 14 is installed separately for each injection region 20. The infusion water supply piping 14 is divided into a plurality of regions along the tunnel direction of the underground storage cavity 11,

Therefore, according to the present embodiment, the injection head can be raised or lowered for each of the plurality of injection regions 20. Therefore, even in the underground storage cavity 11 in the same unit cavity, the geological engineering or hydrogeological characteristics It is possible to operate the injection head conditions of the injection regions 20 differently in consideration of the state of the groundwater pressure according to the operation of the water wall apparatus 10, and thus the usage amount of the injection water and the overall operation efficiency of the water wall apparatus 10 can be improved.

 The water wall tunnel 12 is excavated in a direction perpendicular to the tunnel direction of the underground storage cavity 11 and the water wall holes 13 are drilled in the water tunnel tunnel 12 And the injection region 20 can be divided into two sides with respect to the water wall tunnel 12.

Wherein the individual injection areas 20 can be included together with one upper side area of the underground storage cavities 11 belonging to the same unit cavity, In the case of forming a unit cavity, the individual injection region 20 can be one side region above a single underground storage cavity 11. In addition, the water tunnel 12 may be excavated by a plurality of spaced apart unit cavities 11 in the underground storage cavity 11.

In addition, in the active water wall device 10 of the underground storage cavity in which the injection head can be separately controlled by the injection region 20, the operation and maintenance of the active water wall device 10 can be easily performed. So as to simplify the control structure.

Therefore, in the embodiment of the present invention, the injection head of the injection water in the individual injection region 20 is formed uniformly through the single injection water supply pipe 14 provided for each injection region 20.

To this end, the infusion water supply pipe 14 is provided with an introduction pipe portion 14a for guiding the introduction of the infusion water delivered from the external water supply source 17 and an injection pipe portion 14b for introducing the infusion water introduced through the introduction pipe portion 14a into the infusion The supply pipe portion 14b may be configured to include a supply pipe portion 14b provided to supply water to the water hole 13 belonging to the region 20 and the supply pipe portion 14b may be configured to include the first supply portion branched from the introduction pipe portion 14a A pipe portion 14c and a second supply pipe portion 14d. The water supply source 17 may be a storage tank installed so that a large amount of water for injection is stored outside the gang around the active water wall device 10.

The first supply pipe portion 14c is connected to the inlet pipe portion 14a through the inlet pipe portion 14a along the longitudinal direction of the water wall tunnel 12 in the order from the inlet pipe portion 14a And the second supply pipe portion 14d is provided so as to guide the injection water received from the introduction pipe portion 14a to the water hole 13 located at the farthest distance from the introduction pipe portion 14a, And the ends of the second supply pipe portions 14c and 14d may be provided so as to communicate with each other. The first and second second supply piping portions 14c and 14d may be arranged in a flat manner with respect to the water wall tunnel 12 in consideration of space utilization of the water wall tunnel 12. [

Therefore, in the connection structure of the injection water supply pipe 14 and the water hole 13 according to each injection region, the injection water delivered from the introduction pipe portion 14a to the first supply pipe portion 14c flows into the introduction pipe portion 14a, Even if the injection pressure of the injection water to be injected into the remotely located sidewall 13 is lower than the design value in the process of being supplied to the plurality of sidewall 13 in order, A more uniform injection pressure can be provided through all the vents 13 in the injection region 20 as being compensated by the injection water guided through the second supply pipe portion 14d.

4 shows a graph comparing the injection head variation of the water vents 13 measured in the injection region 20 when the injection water supply pipe 14 and a general single straight pipe are applied. In Fig. 4, the sidewalls 13 are located far away from the introduction pipe portion 14a toward the right.

4, in the case of the infusion water supply pipe 14, almost the same injection pressure as the entire sidewall 13 in the injection region 20 is shown, whereas when a single straight pipe is applied, It can be confirmed that as the distance from the piping 14a is increased, the injection head of the water hole 13 is sharply lowered.

The injection water supply pipe 14 can be variously modified within a range such that the injection pressure of the injection water injected through the plurality of water holes 13 in the injection region 20 is uniformly formed as a whole.

7, which shows a modification of the connection structure of the injection water supply pipe 14 and the water hole 13 according to the present embodiment, the injection water supply pipe 14 ' The introduction pipe portion 14a 'for guiding the introduction of the injection water delivered from the circle 17 and the inlet water portion introduced through the introduction pipe portion 14a' And the supply pipe portion 14b 'may include a first supply pipe portion 14c' and a second supply pipe portion 14d '.

At this time, the first supply pipe portion 14c 'is provided so that the middle between the both ends thereof communicates with the end of the introduction pipe portion 14a', and the second supply pipe portion 14d ' Two middle points may be connected to communicate with both ends of the first supply pipe portion 14c 'in a state in which both ends are closed to communicate with the respective water hole 13 in the arrangement direction of the first supply pipes 13, Two points of the second supply pipe portion 14d 'to which both ends of the pipe portion 14c' are connected are respectively a quarter point and a third point of the entire length of the second supply pipe portion 14d ' .

Therefore, in the connection structure of the injection water supply pipe 14 'and the water hole 13 according to each injection region, the injection water introduced through the introduction pipe portion 14a' is connected to both ends of the first supply pipe portion 14c ' (13) of the injection region (20) from the second supply pipe portion (14d) as it flows into the second supply pipe portion (14d ') through two points of the second supply pipe portion (14d' The injection pressure of the injection water to be injected into the injection port can be made uniform throughout.

3 and 7, a reference numeral 14e denotes a packer for connecting between the second supply pipe portions 14d and 14d 'and the water hole 13.

In addition, the active water wall device 10 of the underground storage cavity according to the present embodiment is provided with a control unit 30 for each injection head region including the injection water supply pipes 14, The operation can be automatically controlled.

5 and 6, a plurality of the infusion water supply piping 14 assigned to the injection region 20 and the plurality of infusion water supply piping 14 arranged in the inflow region 20 A plurality of water tanks 31 provided to supply infusion water to each infusion water supply pipe 14, a plurality of water level measurement devices 32 provided to measure the water level of infusion water for each water tank 31, A plurality of opening and closing valves 33 arranged to intermit the flow of inflow water flowing from the circulating water 17 into the respective water tanks 31 and an infusion head measuring device And the measured injection head 20 of the injection region 20 measured by comparing the injection head of each injection region 20 measured by the injection head measurement device 34 with the reference injection head of the predetermined injection region 20, Closing valve 33 so as to satisfy the reference injection head condition And a control unit (35) for controlling the water pressure of each of the water tanks (31) by controlling the water tank (31).

The water tanks 31 may be installed in the construction tunnel 15 and may be connected to the external water supply source 17 through piping on which the water tanks 3 and the valves b are installed. The water level measuring device 32 may be a conventional water level sensing valve capable of sensing the upper and lower limits of the water level of the water tank 31. The opening and closing valve 33 is connected to the water supply source 17 and the water tank 31). ≪ / RTI & gt ; A valve driving unit 33a may be connected to each on / off valve 33. [

The injection head 32 is provided with a plurality of flow meters 34a arranged to measure the injection amount of the injection water injected through the sidewall apertures 13 and a plurality of hydraulic pressure gauges 34b.

The flowmeter 34a may be a digital flowmeter, and the pressure gauge 34b may be a pore pressure gauge. Digital flowmeters and pore pressure gauges have the advantage of real-time monitoring of measured flow rate and pressure measurements and convenient recording using wired communications.

The injection head information of the individual injection region 20 measured through the injection head measurement device 34 can be delivered to the control unit 35 in real time and the control unit 35 can measure the injection head specific injection area The operation of each on / off valve 33 is controlled through the valve driving unit 33a until the measured injection head for each injection area measured in comparison with the predetermined reference injection head for each injection area satisfies the reference injection head condition, Thereby adjusting the water pressure of the tank 31.

At this time, the control unit 35 receives the level information of each water tank 31 through the water level measuring device 32, and controls the opening / closing valve 33 so that the injection head injected into the injection region B can satisfy the reference value. Off period of the water tank 31 so that the water level of the water tank 31 is automatically controlled.

Meanwhile, the injection head region control unit 30, which automatically controls the injection head by injection region, may be manually operated to reduce the construction cost of the system 10.

FIG. 8 is a structural diagram of a control unit 30 'for each injection head, which is a modification of this embodiment and is adapted to manually adjust the injection head by injection region.

The injection head region regulating unit 30 'is provided with a plurality of the infusion water supply pipes 14 assigned to the injection regions and at least a part of which is provided so as to have different heights for forming a water level difference with each other, A plurality of water tanks 31 'adapted to supply infusion water from the water supply source 17 to each of the infusion water supply pipes 14 and a flow control valve 32 for controlling the flow of inflow water flowing into the respective water tanks 31' An injection head measurement device 34 provided to measure the injection head of the ground water pressure in each injection region, and an injection head for each injection region measured through the injection head measurement device 34 in advance The water injection amount of each of the water tanks 31 'assigned to each of the injection water supply pipes 14 is adjusted so that the measurement injection head of each injection region measured in comparison with the reference injection head of the set injection region satisfies the reference injection head condition. To And a flow path switching pipe 38 and a flow path switching valve 39 which are selectively arranged in combination so as to be supplied to at least one of the infusion water supply pipes 14.

The opening and closing balancer 33 and the injection head measurement device 34 may be provided in the same manner as the control unit 30 for each injection head region in the control unit 30 ' The water tanks 31 'may be installed in the construction tunnel 15 to have different heights so as to form a water level difference between the unit cavities of the underground storage cavity 11.

The water tanks 31 'may be divided into units of the underground storage cavity 11, and the water tanks in the same unit cavity may be installed to have different heights so that a water level difference therebetween is formed. It is not necessary that the number of water tanks 31 'belonging to the unit cavity of the same underground storage cavity 11 coincides with the number of injection regions 20 in the unit cavity. Also, the water tanks 31 'belonging to the same unit cavity can be divided into the first to third water tanks in order of decreasing water level difference, and the water supply water supply pipes 14 in the same unit cavity can be divided into the first to third water tanks And a fourth infusion water supply line.

And the flow path switching pipe 38 can be configured to connect all the water tanks 31 'in the same unit cavity individually to all the infusion water supply pipes 14 in the unit cavity. For example, the flow path switching pipe 38 includes a plurality of first flow path switching pipes 38a connecting the first water tank 31 'having the lowest water level and the first to fourth water supply pipes 14, A plurality of second flow path switching pipes 38b connecting the second water tank 31 'with a low water level and the first flow path switching pipes 38a and a third water path switching pipe 38b connecting the third water tank And a plurality of third flow path switching pipes 38c connecting between the second flow path switching pipes 38a and 31 'and the second flow path switching pipes 38b.

The flow path switching valve 39 may include a plurality of flow path switching valves 39 arranged to intermittently flow the flow of the infusion water through the first to third flow path switching lines 38a, 38b, 38c. It can be installed so that operation is possible from outside the gang.

Therefore, according to the control unit 30 'for each injection head region, an operator who confirms the injection head information of the individual injection region 20 measured through the injection head measuring apparatus 34 operates the flow path switching valves 39 The injection water supply pipe 14 corresponding to the injection region 20 in which the measured injection head is lower than the reference injection head is used as the injection water of the water tank 31 ' The water for injection of the water tank 31 having a low water pressure is supplied to the water supply pipe 14 corresponding to the water injection area 20 where the measured injection head is higher than the reference water injection head It is possible to adjust the injection head of the individual injection region 20 within an appropriate range by selectively combining the water for injection of the water tanks 31 supplied to the individual injection region 20. [

10: Underwater storage cavity active water wall device 11: Underground storage joint
12: Waterwall tunnel 13: Water hole
14: infusion water supply pipe 14a: introduction pipe section
14b: supply pipe portion 14c: first supply pipe portion
14d: second supply pipe section 15: construction tunnel
17: Water source 20: Individual area
30: control unit for injection head region 31: water tank
32: level meter 33: open / close valve
33a: valve drive unit 34: injection head measurement device
34a: Flow meter 34b: Water pressure meter
35: control unit

Claims (8)

A water tunnel tunnel which is excavated in the lower part of the underground storage cavity for oil storage; a plurality of water holes branched from the water wall tunnel for injecting water into the upper part of the underground storage cavity to maintain the airtightness of the underground storage cavity; And an infusion water supply pipe installed in the sidewall tunnel to supply the infusion water of the inflow water to the sidewall, the active sidewall apparatus comprising:
Wherein the upper area of the underground storage cavity through which the injection water is injected is divided into a plurality of injection areas along the direction of the tunnel of the underground storage cavity and the injection water supply pipe has two groundwater conditions Wherein the plurality of injection regions are separately provided so that the injection head can be adjusted individually,
Wherein the injection water supply pipe includes an introduction pipe portion for guiding the introduction of the injection water delivered from the water supply source and a supply pipe portion for supplying the injection water introduced through the introduction pipe portion to the water hole portions belonging to the injection region Including,
Wherein the supply pipe portion includes a first supply pipe portion and a second supply pipe portion branched from the introduction pipe portion,
Wherein the first supply pipe portion is arranged to supply the injection water delivered from the introduction pipe portion to the water hole in order along the longitudinal direction of the water wall tunnel in the order from the introduction pipe portion,
And the ends of the first and second supply piping portions are provided so as to communicate with each other so that the second supply piping portion can guide the injection water received from the introduction piping portion to the water porthole located at the farthest distance from the introduction piping portion The active water wall device of the underground storage cavity. The method according to claim 1,
Wherein the water wall tunnel is excavated in a direction perpendicular to the tunnel direction of the underground storage cavity,
The water hole is arranged along the longitudinal direction of the water wall tunnel to both sides of the water wall tunnel so as to be formed along the tunnel direction of the underground storage cavity,
Wherein the injection area is divided into two sides of the water wall tunnel with respect to the water wall tunnel.
delete A water tunnel tunnel which is excavated in the lower part of the underground storage cavity for oil storage; a plurality of water holes branched from the water wall tunnel for injecting water into the upper part of the underground storage cavity to maintain the airtightness of the underground storage cavity; And an infusion water supply pipe installed in the sidewall tunnel to supply the infusion water of the inflow water to the sidewall, the active sidewall apparatus comprising:
Wherein the upper area of the underground storage cavity through which the injection water is injected is divided into a plurality of injection areas along the direction of the tunnel of the underground storage cavity and the injection water supply pipe has two groundwater conditions Wherein the plurality of injection regions are separately provided so that the injection head can be adjusted individually,
Wherein the injection water supply pipe includes an introduction pipe portion for guiding the introduction of the injection water delivered from the water supply source and a supply pipe portion for supplying the injection water introduced through the introduction pipe portion to the water hole portions belonging to the injection region Including,
Wherein the supply pipe portion includes a first supply pipe portion and a second supply pipe portion,
Wherein the first supply pipe portion is provided so that the middle between both ends thereof communicates with the end of the introduction pipe,
Wherein the second supply pipe portion is connected to both ends of the first supply pipe portion in such a manner that two middle points thereof are closed while both ends thereof are closed so as to communicate with the respective water hole portions in the arrangement direction of the water hole portions of the injection region Active water wall device of underground storage cavity. 5. The method according to any one of claims 1 to 4,
Further comprising an injection unit for each injection port, wherein the injection water supply pipes are arranged to control the injection head by each injection region by measuring the groundwater in the injection port by the injection region. Device. 6. The method of claim 5,
Wherein the control unit for each injection head region comprises a plurality of water tanks for supplying the injection water of the water supply source to the injection water supply pipe assigned for each injection region, A plurality of water level meters, a plurality of open / close valves arranged to intermit flow of inflow water flowing into the respective water tanks from the water supply source, an injection head measuring device arranged to measure the inflow head of water for each of the infusion areas, And a controller for comparing the injection head of each injection region measured by the injection head with the reference injection head of the predetermined injection region and measuring the injection head of each injection region, Further comprising a control unit for controlling the operation of the water tank to control the water pressure of each of the water tanks An active device of the water wall underground storage cavity. 6. The method of claim 5,
Wherein the control unit for each injection head region comprises a plurality of water tanks configured to receive water of the water supply source and supply the water to a plurality of the injection water supply pipes provided for each injection region, A plurality of open / close valves arranged to interrupt the flow of inflow water flowing into the respective water tanks from the water supply source; an injection head measurement device provided to measure the injection head of water for each injection region; The injection head of each injection region is measured by comparing the measured injection head of each injection region with the reference injection head of the predetermined injection region, Selectively combine the water for injection of the assigned water tanks to obtain at least one Water wall of the active device of an underground storage cavity, characterized in that it further comprises the injection water supply flow channel switching pipe and the flow channel switching valve provided to supply to the pipe. The method according to claim 6,
Wherein the injection head measurement device includes a flow meter and a pressure gauge installed to be allocated to each injection region,
Wherein the flow meter includes a digital flow meter,
Wherein the hydraulic pressure gauge includes a pore pressure gauge.

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