KR101025296B1 - Open type geothermal system intake well and injection well is connection - Google Patents

Abstract

PURPOSE: An open type geothermal system connecting an intake well and an injection well is provided to maximize the heat efficiency of underwater and smoothly guide the underwater from the injection well to a connection pipe. CONSTITUTION: An open type geothermal system is composed of an intake well(10), an underwater guiding pipe(11), a submerged motor pump(12), a heat exchanger(15), an underwater supplying pipe(13), a heat insulating pipe(14), an injection well(17), an underwater injecting pipe(18), an underwater collecting pipe(16), and a connecting pipe(19). The intake well is vertically installed to the ground. The underwater guiding pipe is installed in the intake well. The submerged motor pump transfers the underwater from the lower side of the intake well to the underwater guiding pipe and pumps the underwater to the heat exchanger. The heat exchanger cools and warms an indoor space using the underwater. The heat insulating pipe blocks the loss of heat from the underwater. The injection well is formed at one side of the intake well. The underwater collecting pipe guides the underwater from the heat exchanger to the underwater injecting pipe.

Description

Open type geothermal system intake well and injection well is connection}

The present invention relates to an open-type geothermal device in which the intake well and the injection well are in contact. More specifically, it is possible to minimize the depth of excavation formed in the ground, to maximize the thermal efficiency of the groundwater, and to smoothly guide the groundwater of the injection well into the contact pipe. An open geothermal device in which a water well and an injection well communicate with each other.

In general, the heat exchange structure of an open geothermal system that performs cooling and heating using geothermal heat of groundwater develops geothermal holes, that is, groundwater wells 300m to 500m deep, and installs a submersible motor pump therein and installs a submersible motor pump to the heat exchanger. The groundwater having a temperature of about 15 ° C. is sent throughout the year, and the groundwater, which has undergone heat exchange with the heat exchanger, is recovered to the geothermal holes.

In the conventional heat exchange structure of the geothermal system, the ground heat exchanged while continuously circulating the geothermal hole and the heat exchanger, the heat recovery capacity of the geothermal hole is gradually reduced, there is a problem that the thermal efficiency is lowered.

For example, in the summer, the groundwater in the state where the temperature is elevated by the heat exchanger continues to be recovered into the geothermal hole, thereby gradually increasing the temperature inside the geothermal hole, and thus, the temperature of the groundwater in which the heat restoration is gradually increased. Will lower the thermal efficiency. In winter, the groundwater in which the temperature is lowered by the heat exchanger continues to be recovered into the geothermal hole, thereby gradually lowering the temperature in the geothermal hole. As a result, the temperature of the groundwater which has been restored is gradually lowered, thereby reducing the heat efficiency of the heat exchanger. Drop.

Another problem with such geothermal systems is that they need to dig deeper into the geothermal pores in order to increase thermal efficiency.

The deeper the geothermal hole is sold, the higher the thermal efficiency, but the construction cost increases. Geothermal construction is the largest part of the construction cost of geothermal systems, and the deeper the geothermal hole, the higher the construction cost of geothermal systems.

In addition, when digging deep in the excavation depth of the geothermal hole, the loss of the vacant wall occurs during or after excavation, thereby lowering the depth of excavation has frequently caused a problem that the ground passage of the groundwater is blocked.

In addition, there are often cases in which rocks are not deeply drilled vertically by various factors of buried ground, and thus there is a limit in improving thermal efficiency of geothermal systems using geothermal holes.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide an open geothermal device in which a water well and an injection well are contacted to minimize the excavation depth formed in the ground.

Another object of the present invention is to provide an open type geothermal device in which a water extraction well and an injection well are contacted to maximize the thermal efficiency of groundwater.

It is still another object of the present invention to provide an open type geothermal device in which a water well and an injection well are connected so that the groundwater of the injection well is guided smoothly to the contact pipe.

The open type geothermal device in which the water intake well and the injection well of the present invention are in contact with each other, the injection well is formed perpendicular to the ground so that the ground water exchanged through the heat exchanger is introduced into the primary heat recovery; A water well is formed on one side of the well to supply the heat exchanger after the first heat-restored ground water flows through the injection well and is secondly heat-restored; The injection well and the water well are characterized in that the liaison pipe is formed so that the groundwater first heat-restored by the well is guided to the water well.

An open type geothermal device in which the water extraction well and the injection well of the present invention are in contact with each other includes: a water well provided perpendicular to the ground to be in contact with the groundwater layer; A groundwater induction pipe installed in the intake well and recovered to recover the groundwater recovered from the ground by sucking the groundwater and the restored groundwater; An underwater motor pump installed in the groundwater induction pipe and pumping heat-restored groundwater to the outside; A heat exchanger installed in the room and connected to the water intake well for cooling and heating the room using heat-restored ground water; A groundwater supply pipe connected to the groundwater induction pipe and the heat exchanger and supplying groundwater pumped by the submersible motor pump to the heat exchanger; An insulation tube installed around the ground water supply pipe to block heat loss of the ground water supplied to the heat exchanger; An injection well formed perpendicular to the ground to be in contact with the groundwater layer and formed on one side of the intake well and into which the ground water through the heat exchanger flows; An underground water inlet pipe installed inside the injection well and discharging the ground water flowing from the heat exchanger to the lower portion of the injection well so that the ground water is moved to the top of the injection well to restore heat; An groundwater recovery pipe having one end connected to the heat exchanger and the other end connected to the groundwater injection pipe to guide groundwater through the heat exchanger to the groundwater injection pipe; One end is connected to the top of the well and the other end is connected to the top of the injection well, and moved to the upper side of the well to supply the ground-restored groundwater to the top of the well, and the ground water is supplied to the top of the well, Characterized in that it consists of a liaison tube to secondary heat recovery.

Another feature of the open-type geothermal apparatus in which the water well and the injection well of the present invention are in communication is, the horizontal interval between the water well and the injection well is 8 to 10 m.

Another feature of the open geothermal device in which the water well and the injection well of the present invention communicate with each other is that the vertical distance between the ground and the communication pipe is 1 to 2 m.

Another feature of the open-type geothermal device in which the intake well and the injection well of the present invention is in contact, the guide groove is formed in the injection well connected to the injection well and the contact pipe to guide the ground water moved to the upper side of the injection well into the inside of the contact pipe.

Another feature of the open-type geothermal device in which the intake well and the injection well of the present invention is in contact, inside the injection well connected to the injection well and the contact pipe, the blocking plate is formed so that the ground water to be moved upward through the communication pipe is blocked, In the blocking plate, a curved surface is formed so that the groundwater guided to the upper side is led to the inside of the communication pipe.

In the present invention as described above, the injection well is formed perpendicular to the ground so that the ground water heat exchanged through the heat exchanger is introduced, the ground water through the injection well is introduced into the water injection well to be supplied to the heat exchanger after heat recovery The injection pipe and the water well are formed in the contact pipe so that the groundwater through the injection well is led to the water well. Therefore, the groundwater through the heat exchanger enters the lower part of the injection well through the groundwater injection pipe and then moves upwards along the injection well, and is thermally restored first, and the thermally restored groundwater is supplied to the upper part of the intake well through the contact pipe and then moved downward. As it moves, it is heat-restored secondarily, and the heat-restored groundwater is supplied to the heat exchanger through the groundwater induction pipe. Therefore, since the groundwater passing through the heat exchanger is restored twice through the injection well and the intake well, heat recovery of the groundwater can be improved, thereby maximizing the thermal efficiency of the heat exchanger.

In addition, the present invention is heat-restored while the heat-exchanged ground water via the injection well and the intake well, so that the excavation depth does not need to be dug deep as in the conventional geothermal hole. Therefore, by forming the excavation depth deeply prevents the conventional problem that the void wall loss occurred during or after excavation. In addition, the present invention can be applied to strata in which the excavation depth cannot be deeply sold due to the instability of the strata or the excavation depth cannot be deeply sold due to rocks in the ground.

In the present invention, the groundwater passing through the heat exchanger is not only heat-restored in two stages through the injection well and the intake well, but also the groundwater flowing into the lower side of the injection well and the groundwater which is moved to the upper side of the injection well after the heat recovery are blocked by the groundwater injection pipe. The groundwater flowing into the lower side of the intake well and the ground water pumped to the upper side of the intake well are blocked by the groundwater induction pipe, and the groundwater supplied to the groundwater supply pipe is reliably blocked by heat insulation from the outside. Therefore, the ground water flowing into the injection well and the well is already blocked and the ground water supplied out of the well and the well is reliably blocked, thereby minimizing heat transfer between them, thereby improving the heat efficiency of the heat exchanger.

Inside the injection well where the injection well and the contact pipe are connected, a blocking plate is formed so that the groundwater guided by the injection well only rises up to the end of the contact pipe, and the blocking plate has a curved surface to guide the ground water filling along the injection well into the contact pipe. Is formed. Therefore, the groundwater filling the upper side of the injection well is naturally led to the inside of the contact pipe while contacting along the curved surface of the blocking plate. Therefore, the curved surface of the blocking plate facilitates the fluid flow in the bottle cap at the end of the contact tube, so that the groundwater in the injection well is led to the contact tube of narrow diameter than the injection information.

1 is a schematic cross-sectional view showing an open-type geothermal device in which the water extraction well and the injection well are in contact with the present invention;
Figure 2 is a schematic partial cross-sectional view showing another embodiment of the present invention
Figure 3 is a schematic partial cross-sectional view showing another embodiment of the present invention
Figure 4 is a schematic partial enlarged cross-sectional view showing a state that the insulation pipe is covered around the ground water injection pipe

Specific features and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings.

1 is a schematic cross-sectional view showing an open geothermal device in which the water extraction well and the injection well is in contact with the present invention, Figure 2 is a schematic partial cross-sectional view showing another embodiment of the present invention, Figure 3 is a schematic view showing another embodiment of the present invention It is a partial cross section.

In the open type geothermal device in which the water extraction well and the injection well of the present invention are in contact with each other, the injection well 17 is formed perpendicular to the ground 1 so that the groundwater heat-exchanged via the heat exchanger 15 flows in and heat is restored first. In addition, a water extraction well 10 is formed at one side of the injection well 17 so that the groundwater first thermally restored via the injection well 17 flows in and is then secondarily restored and supplied to the heat exchanger 15. . In addition, the injection pipe 17 and the water well 10 are formed with a contact pipe 19 so that the groundwater primarily heat-restored by the injection well 17 is guided to the water well 10.

Referring to Figure 1, the configuration of the present invention in more detail as follows.

The ground (1) is formed with a water intake well (10) formed vertically in contact with the groundwater layer. The groundwater induction pipe 11 is installed in the intake well 10. The groundwater induction pipe 11 serves to supply the groundwater introduced into the intake well 10 to the heat exchanger 15 by suctioning it when the heat is restored along the intake well 10. In addition, the groundwater induction pipe 11 serves to minimize the heat transfer between the groundwater flowing into the intake well 10 and the groundwater supplied to the heat exchanger 15 after being restored.

The groundwater induction pipe 11 is provided with an underwater motor pump 12. The submersible motor pump 12 is installed above the groundwater induction pipe 11 so that the groundwater in the lower part of the heat recovery well 10 is sucked into the groundwater induction pipe 11 and pumps the sucked groundwater to the heat exchanger 15. do.

The heat exchanger 15 is installed indoors. The heat exchanger 15 is connected to the groundwater induction pipe 11 of the intake well 10 and heats and heats the room by using heat-restored groundwater.

The ground water supply pipe 11 and the heat exchanger 15 are connected to the ground water supply pipe 13. The groundwater supply pipe 13 supplies the groundwater pumped by the submersible motor pump 12 to the heat exchanger 15.

An insulation tube 14 is provided around the groundwater supply pipe 13. The heat insulated pipe 14 blocks the ground water and the ground water supply pipe 13 flowing into the intake well 10 to minimize the heat loss of the ground water supplied along the ground water supply pipe 13, thereby reducing the thermal efficiency of the heat exchanger 15. Improve.

On the other hand, the injection well 17 is formed on one side of the water extraction well (10). The injection well 17 is formed perpendicular to the ground 1 to be in contact with the groundwater layer, and the groundwater passing through the heat exchanger 15 is introduced.

The horizontal spacing H between the water extraction well 10 and the injection well 17 is preferably 8 to 10 m.

If the horizontal spacing (H) is less than 8m, the thermal interference between the water extraction well 10 and the injection well 17 is generated, the geothermal effect of the water well 10 and the injection well 17 is halved. If the horizontal distance (H) between them exceeds 10m, a large space should be secured for installing the geothermal device of the present invention, and the time and cost of installing other parts including the installation of the liaison pipe 19 will increase accordingly. do. Therefore, the horizontal spacing H between the water extraction well 10 and the injection well 17 is preferably 8 to 10 m.

The groundwater injection pipe 18 is installed inside the injection well 17. The groundwater injection pipe 18 guides the groundwater via the heat exchanger 15 to the lower portion of the injection well 17 so that the groundwater rises to the top of the injection well 17 and is heated by geothermal heat in the injection well 17. To be restored.

The insulation pipe 24 may be covered around the groundwater injection pipe 18 as shown in FIG. 4. The insulation pipe 24 blocks the heat exchange between the groundwater flowing into the groundwater injection pipe 18 from the groundwater recovery pipe 16 and the groundwater restored to the top of the injection well 17. Therefore, the thermal efficiency of the groundwater supplied to the contact pipe 19 is improved by that much.

In the upper part of the injection well 17, the blocking plate 20 is formed so that the groundwater filling up the top of the injection well 17 only rises to the end of the communication pipe 19.

The groundwater recovery pipe 16 is connected to the heat exchanger 15 and the groundwater injection pipe 18. The groundwater return pipe 16 is connected to the heat exchanger 15 at one end thereof and connected to the groundwater injection pipe 18 to guide groundwater through the heat exchanger 15 to the groundwater injection pipe 18.

Contact pipe 19 is connected to the water intake well 10 and the infusion well. The contact pipe 19 is connected to the upper end of the intake well 10 and the other end is connected to the upper portion of the infusion well 17, the primary water-restored ground water is moved to the upper side of the infusion well 17 ), And the ground water to be supplied to the upper portion of the intake well (10) to be moved to the lower side of the intake well (10) to be secondly restored.

The vertical spacing V between the ground 1 and the connecting pipe 19 is suitably 1 to 2 m.

If the vertical spacing (V) is less than 1m, the groundwater passing through the contact tube 19 is affected by the ground heat, so the thermal efficiency of the groundwater is reduced by that and the contact tube 19 is affected by the pressure applied to the ground 1. Problems such as breakage occur. If their vertical spacing (V) exceeds 2m, the above-mentioned problem is avoided, but it takes a lot of time and expense to form the contact tube 19 to a depth exceeding 2m. Therefore, in consideration of various matters, the vertical spacing V between the ground 1 and the contact pipe 19 is preferably 1 to 2 m.

Meanwhile, as shown in FIG. 2, in the injection well 17 to which the injection well 17 and the liaison tube 19 are connected, groundwater moved to the upper side of the injection well 17 is guided into the communication pipe 19. Guide groove 21 is formed so as to.

Therefore, the groundwater guided to the lower portion of the injection well 17 hits the blocking plate 20 as it rises along the injection well 17. At this time, the ground water is guided to the end of the contact tube 19 widened by the guide groove 21. It flows smoothly into the contact pipe (19).

The open geothermal device in which the water extraction well and the injection well of the present invention are in contact is operated as follows.

When the submersible motor pump 12 and the heat exchanger 15 are operated by operating the controller, the groundwater below the intake well 10 is sucked into the groundwater induction pipe 11 and then pumped into the groundwater supply pipe 13 and then the heat exchanger 15 Is supplied.

The ground water supplied to the heat exchanger 15 is heat-exchanged by the heat exchanger 15 and then injected into the ground water injection pipe 18 of the injection well 17 through the ground water recovery pipe 16. The groundwater injected into the groundwater injection pipe 18 is discharged to the lower portion of the injection well 17 and gradually filled to the upper side of the injection well 17.

Groundwater is initially restored by the geothermal heat in the injection well 17 as it rises above the injection well 17. The groundwater filling upwards is guided to the end side of the contact tube 19 while hitting the blocking plate 20, is moved along the contact tube 19, and is recovered to the upper side of the water intake well 10.

The groundwater recovered to the upper side of the intake well (10) is secondly heat-restored while being guided to the lower side along the intake well (10). Underground water flowing down the intake well 10 is sucked into the groundwater induction pipe 11 by the submersible motor pump 12 and then supplied to the heat exchanger 15 again.

The open geothermal device in which the water extraction well and the injection well of the present invention are in contact are characterized as follows.

First, in the present invention, the injection well 17 is formed perpendicular to the ground 1 so that the ground water heat exchanged through the heat exchanger 15 is introduced, and the ground water passing through the injection well 17 is introduced to restore heat. After the injection well (10) is formed on one side of the injection well (17) to be supplied to the heat exchanger (15), and the injection well (17) and the well well (10) through the injection well (17) A liaison tube 19 is formed to guide to 10).

Therefore, the groundwater passing through the heat exchanger 15 flows into the lower portion of the injection well 17 through the groundwater injection pipe 18 and then moves upwards along the injection well 17 and is thermally restored first. The ground water is supplied to the upper portion of the intake well 10 through the contact pipe 19 and then moved downward. The ground water is supplied to the heat exchanger 15 through the ground water induction pipe 11.

Therefore, since the groundwater passing through the heat exchanger 15 is restored twice through the injection well 17 and the intake well 10, the heat recovery of the groundwater can be improved, thereby improving the thermal efficiency of the heat exchanger 15. It can be maximized.

Second, the present invention is heat-restored while the heat exchanged ground water via the injection well (17) and the intake well (10) without having to dig a deep excavation depth like conventional geothermal holes.

Therefore, by forming the excavation depth deeply prevents the conventional problem that the void wall loss occurred during or after excavation.

In addition, the present invention can also be applied to strata in which the excavation depth cannot be deeply sold due to the unstable strata or the excavation depth can not be deeply sold due to rocks in the ground 1 or the like.

Thirdly, the present invention not only heat-restores the groundwater via the heat exchanger 15 through the injection well 17 and the intake well 10 in two stages, but also the groundwater and the heat-restored inflow below the injection well 17. After the ground water is moved to the upper side of the injection well 17 is blocked through the groundwater inlet pipe 18, the groundwater flowing into the lower side of the intake well 10 and the ground water pumped to the upper side of the intake well 10 is groundwater induction pipe Blocked by (11), the ground water is supplied to the ground water supply pipe 13, the heat transfer to the outside is surely blocked by the heat insulating pipe (14).

Therefore, between the groundwater flowing into the injection well (17) and the water well (10) and the ground water that has already been heat-restored and supplied out of the injection well (17) and the well (10) can be surely blocked, thereby minimizing heat transfer between them. Therefore, the thermal efficiency of the heat exchanger 15 can be improved by that much.

3 is a schematic partial cross-sectional view showing another embodiment of the blocking plate 20, the ground water is moved upwards in the injection well 17 is connected to the injection well 17 and the contact pipe 19 is connected to the contact pipe (19) Block plate 22 is formed so that the movement to the upper side is blocked, the curved surface 23 is formed in the blocking plate 22 so that the groundwater guided to the upper side is guided to the interior of the communication pipe (19).

Therefore, the groundwater filling the upper side of the injection well 17 is naturally guided along the curved surface 23 of the blocking plate 22 into the interior of the contact tube 19.

Therefore, the curved surface 23 of the blocking plate 22 facilitates the fluid flow in the bottle cap at the end of the contact tube 19 so that the groundwater in the injection well 17 has a diameter smaller than that of the injection well 17. 19) is guided smoothly.

1: Ground 10: Water Well
11: groundwater induction pipe 12: submersible motor pump
13: groundwater supply pipe 14: heat insulation pipe
15: heat exchanger 16: groundwater recovery pipe
17: injection well 18: groundwater injection pipe
19: liaison officer 20, 22: blocking plate
21: guide groove 23: curved surface

Claims (6)

delete A water intake well 10 formed perpendicular to the ground 1 to be in contact with the groundwater layer;
A groundwater induction pipe 11 installed in the intake well 10 and recovered and recovered from the groundwater recovered by the heat recovery, and the groundwater and the thermally restored groundwater are recovered and supplied to the outside;
Submersible motor pump 12 is installed in the upper portion of the ground water induction pipe 11 to allow the ground water in the lower part of the heat recovery well 10 to be sucked into the ground water induction pipe 11 and pump the sucked ground water to the heat exchanger 15 side. ;
A heat exchanger 15 installed in the room and connected to the groundwater induction pipe 11 of the intake well 10 to heat and cool the room using the restored ground water;
A groundwater supply pipe 13 connected to the groundwater induction pipe 11 and the heat exchanger 15 to supply groundwater pumped by the submersible motor pump 12 to the heat exchanger 15;
An insulating tube 14 installed around the ground water supply pipe 13 to block heat loss of the ground water supplied to the heat exchanger 15;
An injection well (17) formed perpendicular to the ground (1) to be in contact with the groundwater layer and formed on one side of the water intake well (10) and into which groundwater flows through the heat exchanger (15);
It is installed in the injection well 17 and discharges the ground water flowing from the heat exchanger 15 to the lower portion of the injection well 17 so that the ground water is moved to the upper portion of the injection well 17, and the ground water recovery pipe Improvement of the thermal efficiency of the groundwater supplied to the liaison tube 19 by blocking heat exchange between the groundwater flowing into the groundwater injection pipe 18 from the 16 and the groundwater restored to the top of the injection well 17. A groundwater injection pipe 18 in which an insulation pipe 24 is covered around the groundwater injection pipe 18 so as to be provided;
An groundwater recovery pipe 16 having one end connected to the heat exchanger 15 and the other end connected to the groundwater injection pipe 18 for directing groundwater via the heat exchanger 15 to the groundwater injection pipe 18;
One end is connected to the upper portion of the intake well 10 and the other end is connected to the upper portion of the infusion well 17, and the ground water is first restored to the intake well 10 while being moved to the upper side of the injection well 17, and groundwater Is made up of a contact pipe 19 to be supplied to the upper portion of the intake well 10 to move to the lower side of the intake well 10 to restore the heat secondary;
The horizontal spacing H between the water extraction well 10 and the injection well 17 is 8 to 10 m;
The vertical gap V between the ground 1 and the connecting pipe 19 is 1 to 2 m;
In the injection well 17, which is connected to the injection well 17 and the contact pipe 19, the guide groove 21 is formed so that the ground water moved to the upper side of the injection well 17 is guided into the inside of the contact pipe 19. ;
In the injection well 17, which is connected to the injection well 17 and the contact pipe 19, the blocking plate 22 is formed so that the groundwater guided to the injection well 17 is filled only to the end of the contact pipe 19, Opening geothermal device is in contact with the water intake well and injection well is formed in the blocking plate 22, the curved surface 23 is formed so that the ground water guided to the upper side is guided into the interior of the contact pipe (19). delete delete delete delete

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