KR102201922B1 - Geothermal heat circulation system possible to series connection - Google Patents

Abstract

As the disclosed geothermal circulation system capable of serial connection includes a first geothermal hole, a second geothermal hole, a filtering member, and a heat exchange member, the geothermal exchange water is circulated so that the first geothermal hole and the second geothermal hole are connected in series. As a result, it is possible to increase the amount of geothermal heat exchange without additional construction of the geothermal heat exchange hole, and while the filtering member can remove foreign substances such as sand contained in the geothermal exchange water, there is no need to apply a filter for removing the foreign substances. There is an advantage in that such filter replacement may not be required.

Description

Geothermal heat circulation system possible to series connection

The present invention relates to a geothermal circulation system that can be connected in series.

The geothermal circulation system refers to the supply of heat from the ground to the customer by supplying heat and hot water to the customer by supplying the heat from the ground to the customer, or discharging the heat from the customer to the ground and supplying cooling to the customer.

What can be presented as an example of such a geothermal circulation system is that of the patent literature presented below.

However, according to the conventional geothermal circulation system, in order to increase the amount of geothermal heat exchange, there is a problem that a geothermal heat exchange hole must be additionally constructed in the ground.

In addition, while the geothermal exchange water is heat-exchanged with the ground, foreign substances such as sand are contained in the geothermal exchange water, and these foreign substances must be removed because they cause malfunction of the geothermal circulation system.

However, according to the conventional geothermal circulation system, a filter is applied to remove foreign substances as described above, but such a filter has to be replaced periodically, and accordingly, there is a problem that the filter replacement cost is excessive.

Registered Patent No. 10-0927227, Registration Date: 2009.11.10., Title of Invention: Fluid Circulation Device of Closed Geothermal System Registration Patent No. 10-1855081, Registration Date: 2018.04.30., Title of Invention: Geothermal recovery circulation device and geothermal recovery system using the same

An object of the present invention is to provide a geothermal circulation system capable of serial connection capable of increasing the amount of geothermal heat exchange without additional construction of a geothermal heat exchange hole.

Another object of the present invention is to provide a geothermal circulation system capable of removing foreign substances such as sand contained in geothermal exchange water and capable of connecting in series in which filter replacement is not required.

A geothermal circulation system capable of connecting in series according to an aspect of the present invention comprises: a first geothermal hole; A second geothermal hole formed to be spaced apart from the first geothermal hole; A filtering member that is filtered while passing through the geothermal exchange water heat-exchanged with the ground in at least one of the first geothermal hole and the second geothermal hole; And a heat exchange member for exchanging heat with the refrigerant passing through the customer through the geothermal heat exchange water passing through the filtering member,

The geothermal heat exchanged water drawn from the first geothermal hole while being heat-exchanged with the ground in the first geothermal hole is filtered while passing through the filtering member and heat-exchanged with the refrigerant while passing through the heat exchange member, and heat exchange with the refrigerant The geothermal heat exchanged water is recharged in the second geothermal hole and circulated to the first geothermal hole while being heat-exchanged with the ground in the second geothermal hole, so that the first geothermal hole and the second geothermal hole are connected in series. Exchange water circulates,
The filtering member is a filtering case, and a filtering flow forming unit disposed inside the filtering case and configured to flow the geothermal exchange water in the filtering case so that foreign matters in the geothermal exchange water introduced into the filtering member are separable. And, by partitioning the inside of the filtering case, comprising a rise limiting member for limiting the rise of foreign matter in the geothermal exchange water flowing by the filtering flow forming unit,
The filtering flow forming part is disposed at a predetermined height inside the filtering case, and a scattering drop body configured to scatter and fall while colliding with the geothermal heat exchanged water flowing into the filtering case, and the scattering fall under the filtering case. A basin that is branched into a plurality of prongs at the lower part of the sieve and scattered and dropped by the scattering dropping body to branch and flow, and is formed to be curved along the inner shape of the filtering case so that the geothermal exchange water flows flexibly A fluid and a plurality of branch fluids are formed toward the inside of the filtering case, and are formed in an inclined form from the center of the filtering case toward an eccentric side in a direction spaced apart from the scattering body, and the branch fluid It characterized in that it comprises a vortex-forming spray body for spraying while forming a vortex into the interior of the filtering case, the geothermal heat exchange water flowing through.

According to the geothermal circulation system capable of connecting in series according to an aspect of the present invention, the geothermal circulation system capable of connecting in series includes a first geothermal hole, a second geothermal hole, a filtering member, and a heat exchange member. Since the geothermal exchange water can be circulated so that the ball and the second geothermal hole are connected in series, it is possible to increase the amount of geothermal heat exchange without additional construction of the geothermal heat exchange hole, and foreign matter such as sand contained in the geothermal exchange water in the filtering member Although it is possible to remove the filter, there is an effect that such a filter replacement may not be required because there is no need to apply a filter for removing the foreign matter.

1 is a view showing the configuration of a geothermal circulation system capable of serial connection according to an embodiment of the present invention.
2 is a view showing the internal configuration of a filtering tank constituting a geothermal circulation system capable of serial connection according to an embodiment of the present invention.
3 is a view showing the configuration of a geothermal circulation system capable of serial connection according to another embodiment of the present invention.

Hereinafter, a geothermal circulation system capable of serial connection according to embodiments of the present invention will be described with reference to the drawings.

1 is a diagram showing the configuration of a geothermal circulation system capable of serial connection according to an embodiment of the present invention, and FIG. 2 is an interior of a filtering tank constituting a geothermal circulation system capable of serial connection according to an embodiment of the present invention It is a drawing showing the composition.

1 and 2, the geothermal circulation system 100 capable of serial connection according to the present embodiment includes a first geothermal hole 110, a second geothermal hole 115, and a filtering member 150. , And a heat exchange member 120.

In addition, the geothermal circulation system 100 that can be connected in series includes a first geothermal heat extraction pipe 130, a first geothermal heat recharge pipe 138, a second geothermal heat recharge pipe 136, and a second geothermal heat recharge pipe ( 135), a geothermal filtering connection pipe 131, a filtering heat exchange connection pipe 132, a heat exchange discharge pipe 133, a discharge extension branch pipe 134, and a first bypass pipe 137. .

The first geothermal hole 110 is drilled and installed in the ground so that the geothermal heat exchange water can be exchanged with the ground.

The second geothermal hole 115 is perforated and installed in the ground, and is formed to be spaced apart from the first geothermal hole 110.

The filtering member 150 is filtered while passing through the geothermal exchange water heat-exchanged with the ground in at least one of the first geothermal hole 110 and the second geothermal hole 115, and the filtering case 151 and filtering It includes a flow-forming part 160 and a rising limiter 155.

The filtering case 151 is formed in the shape of a circular cylinder with an empty inside, the upper end thereof is blocked, and a funnel-shaped hopper 152 is formed at the lower end thereof, and the geothermal heat flowing into the filtering member 150 is exchanged. Foreign substances such as sand in water are filtered out, and the foreign substances filtered as described above remain in a state that sinks by the hopper 152 and are discharged to the outside when the hopper opening/closing valve 153 is opened.

The filtering flow forming part 160 is disposed inside the filtering case 151, and the foreign substances in the geothermal exchange water introduced into the filtering member 150 are separated from the inside of the filtering case 151. By flowing the geothermal exchange water, it includes a scattering drop 161, a branch fluid 162, and a vortex forming jet 163.

The scattering fall body 161 is disposed at a certain height inside the filtering case 151, and the inside of the scattering fall body 161 is empty, so that the geothermal heat exchanged flowing into the inside of the filtering case 151 When the water collides, it scatters and falls.

The scattering fall body 161 is formed in a shape bent at a certain curvature so that it can be abutted against the inner wall of the filtering case 151, and the inside of the scattering fall body 161 is formed in an empty form, and the geothermal heat The geothermal heat exchange water introduced through the filtering connector 131 is connected to the top of the scattering drop 161. Then, the geothermal heat exchange water introduced through the geothermal filtering connection pipe 131 flows into the inside of the scattering body 161 and then the geothermal filtering connection pipe 131 among the inner walls of the scattering body 161 and As it collides with the facing inner wall, it spreads to both left and right sides of the scattering dropping body 161 and falls below the scattering dropping body 161.

The branch fluid 162 is a lower portion of the filtering case 151 and is branched into a plurality of prongs under the scattering drop 161 and the geothermal exchange water scattered and dropped by the scattering drop 161 is branched. While flowing, it is formed to be curved along the inner shape of the filtering case 151 to allow the geothermal exchange water to be curved to flow.

The branch fluid 162 extends one by one at both side ends of the lower part of the scattering fall body 161, and is formed in a shape bent at a certain curvature so that it can be abutted against the inner wall of the filtering case 151, and accordingly The flow direction of the geothermal exchange water dropped through the scattering dropping body 161 is changed and flows through the branch fluids 162.

A plurality of foreign matter discharge holes 164 are formed in the lower portion of the branch fluid 162 in the longitudinal direction of the branch fluid 162, and accordingly, foreign matter such as sand remaining inside the branch fluid 162 After being discharged to the outside of the branch fluid 162 through the foreign matter discharge hole 164, it can be dropped into the hopper 152.

The vortex forming spray body 163 is formed in plural from the branch fluid body 162 toward the inside of the filtering case 151, and is spaced apart from the scattering drop body 161 from the center of the filtering case 151 It is formed in an inclined shape to face an eccentric in the direction, so that the geothermal exchange water flowing through the branch fluid 162 is sprayed while forming a vortex inside the filtering case 151.

Each of the vortex-forming spray bodies 163 may be formed in an inclined shape on the surface of the branch fluid 162, and each of the vortex-forming spray bodies 163 may be formed parallel to each other.

When configured as described above, the geothermal exchange water introduced through the geothermal filtering connector 131 falls in the direction of gravity through the scattering drop 161 and then through each branch fluid 162 in the direction of gravity By spraying through each of the vortex-forming jetting bodies 163 while flowing in a vertical direction, the geothermal heat exchange water rises while forming a vortex inside the filtering case 151. Then, the foreign matter in the geothermal exchange water is separated from the geothermal exchange water during such a vortex rise, falls to the bottom of the filtering case 151 and collects in the hopper 152.

The rise limiting member 155 partitions the inside of the filtering case 151 to limit the rise of foreign substances in the geothermal exchange water flowing by the filtering flow forming unit 160.

The lift restrictor 155 is formed in the form of a panel partitioning a central portion of the filtering case 151, and a plurality of through holes 156 are formed in the lift restrictor 155.

Then, while the geothermal heat exchange water, which has been raised by forming a vortex by the filtering flow forming unit 160, rises through the through hole 156 of the rise limiter 155, the foreign matter in the geothermal exchange water is It is blocked by the rising limiting body 155 and falling toward the bottom of the filtering case 151, and the eddy current of the geothermal exchange water is also rapidly extinguished by the rising limiting body 155, and the upper part of the rising limiting body 155 At, since the geothermal exchange water stops to fill the inside of the filtering case 151, some of the foreign matters that have passed through the through hole 156 cannot rise and fall, and fall through the through hole 156. .

Reference numeral 154 denotes a filtering suction nozzle connected to the filtering heat exchange connection pipe 132 and disposed above the rising limiter 155 in the filtering case 151, and the rising in the filtering case 151 The geothermal exchange water accommodated above the restrictor 155 may flow out through the filtering suction nozzle 154.

In the heat exchange member 120, the geothermal heat exchange water passed through the filtering member 150 is heat-exchanged with a refrigerant passing through a consumer, and the geothermal exchange water and the refrigerant heat exchange, and may additionally heat exchange with external air.

The heat exchange member 120 in a state in which the geothermal exchange water extracted from the first geothermal hole 110 is filtered while passing through the filtering member 150 while being heat-exchanged with the ground in the first geothermal hole 110 The geothermal heat exchanged water heat-exchanged with the refrigerant and heat-exchanged with the refrigerant is recharged in the second geothermal hole 115 and heat-exchanged with the ground in the second geothermal hole 115. By circulating to 110), the geothermal exchange water is circulated so that the first geothermal hole 110 and the second geothermal hole 115 are connected in series, which will be described in detail below.

The first geothermal heat extraction pipe 130 is a pipe through which the geothermal heat exchange water is extracted from the first geothermal hole 110, and the geothermal heat exchange in the first geothermal hole 110 in the first geothermal heat extraction pipe 130 A first withdrawal pump 111 capable of withdrawing water through the first geothermal heat withdrawal pipe 130 is installed.

The first geothermal recharge pipe 138 is a pipe in which the geothermal exchange water is recharged by the first geothermal hole 110.

The second geothermal heat extraction pipe 136 is a pipe through which the geothermal heat exchange water is extracted from the second geothermal hole 115, and the geothermal heat exchange in the second geothermal hole 115 in the second geothermal heat extraction pipe 136 A second withdrawal pump 116 capable of withdrawing water through the second geothermal heat withdrawal pipe 136 is installed.

The second geothermal recharge pipe 135 is a pipe in which the geothermal exchange water is recharged through the second geothermal hole 115.

The geothermal filtering connection pipe 131 is the first geothermal extraction pipe 130 and the second geothermal extraction pipe 136 are laminated to each other, the first geothermal extraction pipe 130 and the second geothermal extraction pipe 136 ) Is a pipe through which the geothermal heat exchange water flows through at least one of) flows to the filtering member 150.

Reference numeral 140 denotes a first geothermal withdrawal open/close valve capable of opening and closing the first geothermal heat withdrawal pipe 130, and reference numeral 145 denotes a second geothermal withdrawal open/closed valve capable of opening and closing the second geothermal heat withdrawal pipe 136 to be.

The filtering heat exchange connection pipe 132 is a pipe through which the geothermal heat exchange water filtered by the filtering member 150 flows to the heat exchange member 120, and the filtering heat exchange connection pipe 132 includes the filtering member 150 A connection pump 141 is installed to flow the geothermal exchange water to the heat exchange member 120 through the filtering heat exchange connection pipe 132.

The heat exchange discharge pipe 133 is a pipe through which the geothermal exchange water passed through the heat exchange member 120 is discharged.

In the heat exchange discharge pipe 133, the discharge extension branch pipe 134 and the bleeding connection pipe 128 are branched.

The bleeding connection pipe 128 supplies the geothermal exchange water flowing through the heat exchange discharge pipe 133 to the bleeding tank 125.

Reference numeral 129 denotes a bleeding opening/closing valve capable of opening and closing the bleeding connection pipe 128.

The bleeding tank 125 accommodates a portion of the geothermal exchange water discharged through the heat exchange member 120 and, if necessary, the customer, the first geothermal hole 110, and the second geothermal hole 115 ), you can bleed.

Reference numeral 126 is a bleeding discharge pipe capable of discharging the geothermal exchange water accommodated in the bleeding tank 125, and reference numeral 127 indicates the geothermal heat in the bleeding tank 125 through the bleeding discharge pipe 126. It is a bleeding pump that can flow exchange water to other places.

The discharge extension branch pipe 134 extends from the heat exchange discharge pipe 133 and is branched so as to be connected to the first geothermal recharge pipe 138 and the second geothermal recharge pipe 135.

Reference numeral 142 is a first geothermal rechargeable opening/closing valve capable of opening and closing the first geothermal rechargeable pipe 138, and reference numeral 143 is a second geothermal rechargeable opening/closing valve capable of opening and closing the second geothermal rechargeable pipe 135 to be.

The first bypass pipe 137 is a pipe connecting the second geothermal heat extraction pipe 136 and the first geothermal recharge pipe 138.

Reference numeral 144 denotes a first bypass opening/closing valve capable of opening and closing the first bypass pipe 137.

Hereinafter, the operation of the geothermal circulation system 100 capable of serial connection according to the present embodiment will be described with reference to the drawings.

First, an operation when any one of the first geothermal hole 110 and the second geothermal hole 115 is required to be used will be described. Here, for convenience of description, a case where the first geothermal hole 110 is required to be used will be described.

In this case, the first geothermal withdrawal open/close valve 140 and the first geothermal rechargeable open/close valve 142 are opened, and the second geothermal draw open and close valve 145, the second geothermal rechargeable open/close valve 143, the The first bypass opening/closing valve 144 and the bleeding opening/closing valve 129 are closed.

In this state, when the first withdrawal pump 111 and the connection pump 141 are operated, the geothermal heat exchange water in a heat exchanged state with the ground in the first geothermal hole 110 is the first geothermal heat extraction pipe 130 ) And the geothermal filtering connector 131 through the filtering member 150.

Then, the geothermal heat exchange water, which has been filtered and stored in the filtering member 150, flows through the filtering heat exchange connection pipe 132 to exchange heat with the refrigerant while passing through the heat exchange member 120.

Then, the geothermal heat exchange water passed through the heat exchange member 120 flows through the heat exchange discharge pipe 133 and the discharge extension branch pipe 134, and then the first geothermal heat recharge pipe 138 It is reinforced with the first geothermal hole 110.

Hereinafter, the first geothermal hole 110 and the second geothermal hole 115 are arranged so that the geothermal heat exchange water first passes through the second geothermal hole 115 and then faces the first geothermal hole 110. The operation operated in series connection will be described.

In this case, the first geothermal withdrawal open/close valve 140, the second geothermal rechargeable open/close valve 143 and the first bypass open/closed valve 144 are opened, and the first geothermal rechargeable open/close valve 142, the The second geothermal drawing on/off valve 145 and the bleeding on/off valve 129 are closed.

In this state, when the first withdrawal pump 111, the second withdrawal pump 116, and the connection pump 141 are operated, the geothermal heat exchange in a state of heat exchange with the ground in the first geothermal hole 110 Water is drawn into the filtering member 150 through the first geothermal extraction pipe 130 and the geothermal filtering connector 131.

Then, the geothermal exchange water introduced into the filtering member 150 is filtered by the filtering member 150, and then flows through the filtering heat exchange connector 132 to pass through the heat exchange member 120, while the refrigerant Heat exchange with.

Then, the geothermal heat exchange water heat-exchanged with the refrigerant flows through the heat exchange discharge pipe 133 and the discharge extension branch pipe 134, and then the second geothermal hole through the second geothermal recharge pipe 135 It is refilled with 115 and heat-exchanged with the ground in the second geothermal hole 115.

Then, the geothermal heat exchanged water heat-exchanged with the ground in the second geothermal hole 115 is drawn out through the second geothermal extraction pipe 136 and then flows through the first bypass pipe 137.

Then, the geothermal heat exchange water flowing through the first bypass pipe 137 is recharged into the first geothermal hole 110 through the first geothermal recharge pipe 138 and the first geothermal hole 110 By exchanging heat with the ground in, the geothermal exchange water can be circulated so that the first geothermal hole 110 and the second geothermal hole 115 are connected in series.

As described above, the series-connectable geothermal circulation system 100 includes the first geothermal hole 110, the second geothermal hole 115, the filtering member 150, and the heat exchange member 120. As a result, it is possible to circulate the geothermal heat exchange water so that the first geothermal hole 110 and the second geothermal hole 115 are connected in series, thereby increasing the amount of geothermal heat exchange without additional construction of the geothermal heat exchange hole. In addition, although the filtering member 150 can remove the foreign substances such as sand contained in the geothermal exchange water, there is no need to apply a filter for removing the foreign substances, so that such a filter replacement may not be required.

On the other hand, the first geothermal withdrawal open/close valve 140, the first geothermal rechargeable open/close valve 142, the second geothermal rechargeable open/close valve 143 and the second geothermal draw open and close valve 145 are all open, and the When the first bypass opening/closing valve 144 and the bleeding opening/closing valve 129 are closed, when the first withdrawal pump 111, the second withdrawal pump 116 and the connection pump 141 are operated, By connecting the first geothermal hole 110 and the second geothermal hole 115 in parallel, the serial connection is possible so that both the first geothermal hole 110 and the second geothermal hole 115 are used. System 100 may be operated.

Hereinafter, a geothermal circulation system capable of serial connection according to another embodiment of the present invention will be described with reference to the drawings. In carrying out this description, descriptions that are already described in the above-described embodiment of the present invention and overlapping descriptions will be replaced therewith, and will be omitted herein.

3 is a diagram showing the configuration of a geothermal circulation system capable of serial connection according to another embodiment of the present invention.

Referring to FIG. 3, the geothermal circulation system 200 capable of serial connection according to the present embodiment further includes a second bypass pipe 270.

The second bypass pipe 270 is a pipe connecting the second geothermal recharge pipe 235 and the first geothermal extraction pipe 230.

Reference numeral 271 denotes a second bypass opening/closing valve capable of opening and closing the second bypass pipe 270.

When configured as described above, the first geothermal rechargeable on/off valve 242, the second geothermal draw on/off valve 245 and the second bypass on/off valve 271 are opened, and the first geothermal draw on/off valve 240, 2 When the geothermal recharge on/off valve 243, the first bypass on/off valve 244 and the bleed on/off valve 229 are closed, the first withdrawal pump 211, the second withdrawal pump 216 and the connection pump 241 ) Is operated, the geothermal heat exchange water passing through the heat exchange member 220 first passes through the first geothermal hole 210 and then flows through the second bypass pipe 270 toward the second geothermal hole 215. While doing so, the first geothermal hole 210 and the second geothermal hole 215 may be connected in series to be operated.

In the above, the present invention has been shown and described with respect to specific embodiments, but those of ordinary skill in the art variously modify the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. And it will be appreciated that it can be changed. However, it is intended to clearly reveal that all of these modifications and variations are included within the scope of the present invention.

According to the geothermal circulation system capable of being connected in series according to an aspect of the present invention, it is possible to increase the amount of geothermal heat exchange without additional construction of the geothermal heat exchange hole, and to remove foreign substances such as sand contained in the geothermal exchange water while replacing the filter. May not be required, so the industrial applicability is high.

100: Geothermal circulation system with serial connection
110: 1st geothermal hole
115: second geothermal hole
120: heat exchange member
150: filtering member

Claims (4)

First geothermal hole;
A second geothermal hole formed to be spaced apart from the first geothermal hole;
A filtering member that is filtered while passing through the geothermal exchange water heat-exchanged with the ground in at least one of the first geothermal hole and the second geothermal hole; And
And a heat exchange member for exchanging heat with the refrigerant passing through the customer through the geothermal heat exchange water through the filtering member,
The geothermal heat exchanged water drawn from the first geothermal hole while being heat-exchanged with the ground in the first geothermal hole is filtered while passing through the filtering member and heat-exchanged with the refrigerant while passing through the heat exchange member, and heat exchange with the refrigerant The geothermal heat exchanged water is recharged in the second geothermal hole and circulated to the first geothermal hole while being heat-exchanged with the ground in the second geothermal hole, so that the first geothermal hole and the second geothermal hole are connected in series. Exchange water circulates,
The filtering member is
Filtering case,
A filtering flow forming unit disposed inside the filtering case and flowing the geothermal exchange water in the filtering case so that foreign substances in the geothermal exchange water introduced into the filtering member are separable,
And a rise limiting body that partitions the inside of the filtering case and restricts the rise of foreign substances in the geothermal exchange water flowing by the filtering flow forming unit,
The filtering flow forming part
A scattering falling body disposed at a certain height inside the filtering case, and scattering and falling while colliding with the geothermal exchange water flowing into the filtering case,
The geothermal exchange water, which is a lower part of the filtering case and is branched into a plurality of prongs from the lower part of the scattering fall body, is branched and flows, and is formed to be bent along the inner shape of the filtering case. A branch fluid that allows the geothermal exchange water to flow flexibly, and
A plurality of branch fluids are formed toward the inside of the filtering case, and are formed in a form inclined from the center of the filtering case toward an eccentric side in a direction spaced apart from the scattering body, and flow through the branch fluid. A geothermal circulation system capable of serial connection, characterized in that it comprises a vortex-forming spray body for spraying the used geothermal exchange water while forming a vortex into the inside of the filtering case. The method of claim 1,
The geothermal circulation system that can be connected in series
A first geothermal extraction pipe, which is a pipe through which the geothermal exchange water is extracted from the first geothermal hole;
A first geothermal recharge pipe, which is a pipe in which the geothermal heat exchange water is recharged by the first geothermal hole;
A second geothermal extraction pipe, which is a pipe through which the geothermal exchange water is extracted from the second geothermal hole;
A second geothermal recharging pipe that is a pipe in which the geothermal heat exchange water is recharged with the second geothermal hole;
Geothermal filtering, which is a pipe through which the first geothermal heat extraction pipe and the second geothermal heat extraction pipe are combined to flow the geothermal heat exchange water flowing through at least one of the first geothermal heat extraction pipe and the second geothermal heat extraction pipe to the filtering member Connector;
A filtering heat exchange connection pipe, which is a pipe through which the geothermal exchange water filtered by the filtering member flows to the heat exchange member;
A heat exchange discharge pipe which is a pipe through which the geothermal heat exchange water passed through the heat exchange member is discharged;
A discharge extension branch pipe extending from the heat exchange discharge pipe and branched to be connected to the first geothermal heat recharge pipe and the second geothermal heat recharge pipe; And
Including; a first bypass pipe connecting the second geothermal heat extraction pipe and the first geothermal recharge pipe,
The geothermal heat exchange water drawn from the first geothermal hole through the first geothermal heat extraction pipe in a state of being heat-exchanged with the ground in the first geothermal hole is introduced into the filtering member through the geothermal filtering connection pipe,
The geothermal exchange water introduced into the filtering member is filtered by the filtering member, and then flows through the filtering heat exchange connection pipe to exchange heat with the refrigerant while passing through the heat exchange member,
The geothermal exchange water heat-exchanged with the refrigerant flows through the heat exchange discharge pipe and the discharge extension branch pipe, and then is recharged into the second geothermal hole through the second geothermal recharge tube to exchange heat with the ground in the second geothermal hole. Become,
The geothermal heat exchange water heat-exchanged with the ground in the second geothermal hole is drawn out through the second geothermal extraction pipe, and then flows through the first bypass pipe,
The geothermal heat exchange water flowing through the first bypass pipe is recharged into the first geothermal hole through the first geothermal heat refilling pipe and heat-exchanged with the ground in the first geothermal hole, so that the first geothermal hole and the second geothermal hole A geothermal circulation system capable of serial connection, characterized in that the geothermal exchange water is circulated so that the hot holes are connected in series. delete delete

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