KR102051353B1 - Geothermal heating and cooling system with compatible operation control technology of double underground heat exchanger - Google Patents

Abstract

Disclosed is a geothermal cooling and heating system with a compatible operation control technology of a double underground heat exchanger. The geothermal cooling and heating system with a compatible operation control technology of a double underground heat exchanger comprises: a three-way electric valve including a first port, a second port, and a third port; a first underground heat exchanger installed inside a first geothermal well hole and including a first submersible motor pump, a first heat exchange fluid pumping pipe, and a first heat exchange fluid return pipe; a second underground heat exchanger installed inside a second geothermal well hole and including a second submersible motor pump, a second heat exchange fluid pumping pipe, and a second heat exchange fluid return pipe; a ground heat exchanger connected to the first heat exchange fluid pumping pipe and the second heat exchange fluid pumping pipe through a heat exchange fluid supply pipe; and a control unit for controlling a heat exchange fluid circulation direction between the first underground heat exchanger and the second underground heat exchanger.

Description

GEOMEMAL HEATING AND COOLING SYSTEM WITH COMPATIBLE OPERATION CONTROL TECHNOLOGY OF DOUBLE UNDERGROUND HEAT EXCHANGER}

The present invention relates to a geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger, and more specifically, it is possible to maximize the heating and cooling efficiency by controlling the direction of the groundwater circulation according to the seasonal characteristics by the control unit. The present invention relates to a geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger.

In general, the heat exchange structure of an open geothermal system that performs cooling and heating using geothermal heat of groundwater develops geothermal holes of about 500m depth, that is, groundwater wells, and installs a submersible motor pump therein. The ground water having a temperature of about ℃ is sent, and the ground water exchanged with the heat exchanger has a structure that is recovered back to the geothermal hole.

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 is continuously recovered into the geothermal hole, thereby gradually increasing the temperature inside the geothermal hole, and thus, the groundwater temperature gradually increases, thereby decreasing the heat efficiency of the heat exchanger. Thrown away. In winter, the groundwater in the state where the temperature is lowered by the heat exchanger is continuously recovered into the geothermal hole, thereby gradually lowering the temperature of the geothermal hole, thereby decreasing the thermal efficiency of the heat exchanger.

Another problem with these geothermal systems is that they need to dig deep enough to have a depth of 500m 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, and this causes the excavation depth to be lowered frequently caused the problem of blocking the circulation passage of groundwater.

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.

In order to solve such a problem, the inventor has invented the Patent No. 10-1818927, "Two-well open geothermal system capable of seasonal compatibility and alternative operation." However, this patent has a problem in that the diameters of the first well and the second well are increased by connecting the first and second recovery pipes from the side of the first pumping pipe and the second pumping pipe. It took a lot of time for the drilling process of the well and the second well, there was a problem that the process cost increases as a lot of time.

The problem to be solved by the present invention is to maximize the cooling and heating efficiency by varying the direction of the groundwater circulation according to the seasonal characteristics through the control unit, even if the problem of the first submersible motor pump can immediately operate the second submersible motor pump Therefore, the circulation of the heat exchange fluid is continued without stopping, and therefore, to provide a geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger that allows the heating and cooling operation to continue.

Geothermal air conditioning system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention comprises a three-way electric valve comprising a first port, a second port and a third port; A first heat exchange fluid pumping pipe installed inside a first geothermal well hole and having a first submersible motor pump, a heat exchange fluid pumped from the first submersible motor pump, and a first heat exchange fluid return pipe connected to the first port. A first underground heat exchanger comprising a; A second heat exchange fluid pumping pipe installed inside a second geothermal well hole, into which a second submersible motor pump, a heat exchange fluid pumped from the second submersible motor pump, and a second heat exchange fluid return pipe connected to the second port are connected. A second underground heat exchanger including; The heat exchange fluid supplied from the first underground heat exchange unit is connected to the first heat exchange fluid pumping pipe and the second heat exchange fluid pumping pipe through a heat exchange fluid supply pipe, and connected to the third port through a heat exchange fluid return pipe. A ground heat exchanger configured to exchange heat with the load side and allow the heat exchange fluid supplied from the second underground heat exchange unit to exchange with the load side; And a control unit for controlling a heat exchange fluid circulation direction between the first underground heat exchange unit and the second underground heat exchange unit, wherein the control unit comprises: a main power controller to which commercial power is applied; A first power controller connected to the main power controller to supply power, and to apply power applied from the main power controller toward the first underground heat exchanger; A first electronic switch electrically connected to the first power controller; A first load protector electrically connected between the first electronic switch and the first submersible motor pump; A second power controller connected to the main power controller to supply power, and supplying power applied from the main power controller toward the second underground heat exchanger; A second electronic switch electrically connected to the second power controller; A second load protector electrically connected between the second electronic switch and the second submersible motor pump; The second electron when the first electronic switch is electrically connected to the second electronic switch and the first load protector is disconnected from the first submersible motor pump, thereby preventing the operation of the first electronic switch; An interlock circuit unit configured to operate the switch to operate the second submersible motor pump by supplying power from the main power controller to the second submersible motor pump; A first relay unit electrically connected to the first load protector and configured to open the second port when the first submersible motor pump is operated; And a second relay unit electrically connected to the second load protector and opening the first port when the second submersible motor pump is operated.

In one embodiment, the first underground heat exchange unit is inserted into the first geothermal well hole, the first pump housing having a diameter smaller than the diameter of the first geothermal well hole and the first connected to the lower end of the first pump housing A first groundwater pumping pipe including a housing entrance nozzle; The heat exchange fluid is connected to the upper end of the first ground water pumping pipe, the heat exchange fluid flowing into the first ground water pumping pipe is discharged toward the outer ground heat exchanger of the first ground water well, and the outside of the first ground water well. A first heat exchange fluid guide chamber configured to guide and drop the heat exchange fluid flowing from the ground heat exchanger toward the first ground water pumping pipe to the inner space of the first ground water pumping pipe; The first underwater is accommodated in the first ground water pumping pipe, connected to the lower portion of the first heat exchange fluid guide chamber to introduce heat exchange fluid inside the first geothermal well hole into the first heat exchange fluid guide chamber. Motor pump; A heat exchange fluid having a lower end connected to an upper portion of the first heat exchange fluid guide chamber and an upper end connected to the heat exchanger, the heat exchange fluid guided from the first heat exchange fluid guide chamber toward the outer ground heat exchange part of the first geothermal well hole A first heat exchange fluid pumping pipe which is discharged toward the outer ground heat exchanger of the geothermal well ball and supplied to the heat exchanger; A lower end portion is connected to an upper portion of the first heat exchange fluid guide chamber, an upper end portion is connected to the heat exchanger, and is disposed to be adjacent to the first heat exchange fluid pumping pipe, and the heat exchange fluid heat exchanged in the heat exchanger is the first heat exchange fluid guide. A second heat exchange fluid return pipe configured to be introduced into the chamber, wherein the second underground heat exchange part is inserted into the second geothermal well hole and has a diameter smaller than the diameter of the second geothermal well hole; A second groundwater pumping pipe including a second housing inlet and outlet nozzle connected to a lower end of the second pump housing; The heat exchange fluid connected to the upper end of the second ground water pumping pipe and introduced into the second ground water pumping pipe is discharged toward the outer ground heat exchanger of the second ground water well, and the outside of the second ground water well. A second heat exchange fluid guide chamber configured to guide and drop the heat exchange fluid flowing from the ground heat exchanger toward the second ground water pumping pipe to the inner space of the second ground water pumping pipe; The second underwater is accommodated in the second ground water pumping pipe and connected to the lower portion of the second heat exchange fluid guide chamber to introduce heat exchange fluid inside the second geothermal well hole into the second heat exchange fluid guide chamber. Motor pump; A heat exchange fluid having a lower end connected to an upper portion of the second heat exchange fluid guide chamber and an upper end connected to the heat exchanger, the heat exchange fluid guided from the second heat exchange fluid guide chamber toward the outer ground heat exchange part of the second geothermal well hole, A second heat exchange fluid pumping pipe which is discharged toward the outer ground heat exchanger of the geothermal well ball and supplied to the heat exchanger; And a lower end connected to an upper portion of the second heat exchange fluid guide chamber, an upper end connected to the heat exchanger, and arranged to be adjacent to the second heat exchange fluid pumping pipe, wherein the heat exchange fluid heat exchanged in the heat exchanger is the second heat exchange fluid. And a second heat exchanging fluid return pipe for introducing the inside of the guide chamber, wherein each of the first heat exchanging fluid guide chamber and the second heat exchanging fluid guide chamber is eccentric from the center of the cylindrical part and the center of the cylindrical part. An upper plate portion including a pumping pipe through-hole and a pumping pipe through-hole adjacent to the pumping pipe-hole, and covering an upper end of the cylindrical part, an groundwater pumping pipe connecting hole connected to an upper end of the first groundwater pumping pipe, and the groundwater pumping It is disposed around the pipe connection hole and the first heat exchange fluid guide chamber or the second row A chamber including a lower plate portion including a plurality of fluid drop holes to allow the heat exchange fluid flowing into the circular fluid guide chamber to fall into the inner space of the first ground water pumping pipe or the second ground water pumping pipe. part; And an inlet portion connected to the groundwater pumping pipe connection hole and communicating with the first groundwater pumping pipe or the second groundwater pumping pipe, a bent portion extending from the inlet portion in the direction of the pumping pipe, and extending from an upper portion of the bent portion. And a twist pipe connected to the pumping pipe through-hole and having an outlet portion communicating with the first heat exchange fluid pumping pipe and the second heat exchange fluid pumping pipe.

In the geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to another embodiment of the present invention, the pumping pipe through-holes of the upper plate of each of the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber communicate with each other. And an array structure in which a plurality of subunit holes are arranged along the circumferential direction of the upper plate, wherein the upper plate of each of the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber has an inner side of an edge adjacent to the edge of the top plate. Further comprising a circular slit, wherein the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber, each of the pipe coupling hole is coupled to the upper portion of the twisted pipe, the lower surface is inserted into the circular slit at the bottom surface to the circular slit Guide protrusions slid along, and the first heat exchange fluid return pipe in the state connected with the upper plate Words Related position varying twist plate comprises a hole into which the pipe to prevent interference, which is disposed over the upper plate with a wrap mode; A handle coupling column connected to one side of an upper surface of the twisted pipe position variable plate and extending a predetermined length in an upper direction of the first geothermal well hole or the second geothermal well hole; And a rotation operation handle inserted into the first geothermal well ball or the second geothermal well ball from the outside of the first geothermal well ball and the second geothermal well ball and screwed to an upper end of the handle coupling pillar. When the rotation operation handle is operated to the left and the right, the twist pipe position variable plate may rotate to change the position at which the twist pipe is coupled to the subunit holes.

According to the geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to the present invention, there is an advantage that can maximize the cooling and heating efficiency by varying the direction of the groundwater circulation according to the seasonal characteristics by the control of the controller, 1 Even when the submerged motor pump is operated and the first submersible motor pump has a problem in the cooling operation process, the second submersible motor pump can be operated immediately, so that the circulation of the heat exchange fluid can be continued without stopping.

In addition, there is an advantage that it is easy to install the heat exchange fluid pumping pipe and heat exchange fluid return pipes for circulation of the heat exchange fluid in the first geothermal well hole and the second geothermal well hole of the narrow diameter.

In addition, compared with the conventional groundwater recovery and heat recovery in one geothermal well hole, the heat recovery effect is superior to the conventional one, and the geothermal well hole depth is shorter than the conventional one, so that the workability is improved and the construction cost can be reduced. have.

1 is a view for explaining a geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention.
FIG. 2 is an enlarged view of the first underground heat exchanger and the second underground heat exchanger illustrated in FIG. 1.
FIG. 3 is a block diagram illustrating the control unit shown in FIG. 1.
4 is a plan view of a top plate of the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber shown in FIG. 2.
5 is a plan view of a lower plate of the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber shown in FIG. 2.
6 is a cross-sectional view for explaining a configuration of a geothermal air conditioning system equipped with a compatible operation control technology of a double underground heat exchanger according to another embodiment of the present invention.
FIG. 7 is a perspective view illustrating the upper plate and the twisted tube variable plate illustrated in FIG. 6.

Hereinafter, with reference to the accompanying drawings will be described in detail a geothermal air-conditioning system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention. As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the drawings, similar reference numerals are used for similar elements. In the accompanying drawings, the dimensions of the structures are shown in an enlarged scale than actual for clarity of the invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

1 is a view for explaining a geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention, Figure 2 is a first underground heat exchanger and a second underground 3 is an enlarged view of the heat exchanger, and FIG. 3 is a block diagram for describing the control unit illustrated in FIG. 1.

1 to 3, a geothermal air conditioning system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention includes a three-way electric valve 600, a first underground heat exchanger 100, The second underground heat exchanger 200, the ground heat exchanger 300, the control unit 400, and the ground heat pump 500 are included.

The three-way electric valve 600 includes a first port 610, a second port 620, and a third port 630.

The first underground heat exchange unit 100 is installed in the first geothermal well hole 10, and the first submersible motor pump 140 for pumping heat exchange fluid, ie, groundwater, in the first geothermal well hole 10, and 1 is connected to the first heat exchange fluid pumping pipe 150 and the first reverse side 710 into which the heat exchange fluid pumped from the submersible motor pump 140 flows in the first geothermal heat exchange unit 300. It includes a first heat exchange fluid return pipe 160 to return to the well hole (10).

The second underground heat exchange unit 200 is installed inside the second geothermal well hole 20, and the second underwater motor pump 240 for pumping heat exchange fluid, that is, groundwater, in the second geothermal well hole 20 is formed. 2 is connected to the second heat exchange fluid pumping pipe 250 and the second reverse valve 720 into which the heat exchange fluid pumped from the submersible motor pump 240 flows and the second geothermal heat exchanger And a second heat exchange fluid return pipe 260 for supplying the well hole 20.

The ground heat exchanger 300 is connected to the first heat exchange fluid pumping pipe 150 and the second heat exchange fluid pumping pipe 250 through a heat exchange fluid supply pipe 310, and a third port through the heat exchange fluid return pipe 320. The heat exchange fluid supplied from the first underground heat exchange unit 100 is exchanged with the load side, and the heat exchange fluid supplied from the second underground heat exchange unit 200 is also heat exchanged with the load side.

The controller 400 controls the heat exchange fluid circulation direction between the first underground heat exchange unit 100 and the second underground heat exchange unit 200. The controller 400 may include a main power controller 410, a first power controller 420, a first electronic switch 430, a first load protector 440, a second power controller 450, and a second electronic switch 460. ), A second load protector 470, an interlock circuit unit 480, a first relay unit 491, and a second relay unit 492.

The main power controller 410 is connected to commercial power and commercial power is applied.

The first power controller 420 may be connected to the main power controller 410 to receive power, and may apply power applied from the main power controller 410 toward the first underground heat exchanger 100.

For example, the main power controller 410 and the first power controller 420 may be an earth leakage breaker (ELB).

The first electronic switch MC 430 is electrically connected to the first power controller 420.

The first load protector 440 is electrically connected between the first electronic switch 430 and the first submersible motor pump 140. For example, the first load protector 440 may be an overcurrent protector (EOCR).

The second power controller 450 may be connected to the main power controller 410 to supply power, and may apply power applied from the main power controller 410 toward the second underground heat exchanger 200.

The second electronic switch MC 460 is electrically connected to the second power controller 450.

The second load protector 470 is electrically connected between the second electronic switch 460 and the second submersible motor pump 240. For example, the second load protector 470 may be an overcurrent protector (EOCR).

The interlock circuit unit 480 is electrically connected to the first electronic switch 430 and the second electronic switch 460, and the first load protector 440 is disconnected from the first submersible motor pump 140. When the operation of the electronic switch 430 is blocked, by operating the second electronic switch 460 so that power from the main power controller 410 is applied to the second submersible motor pump 240, the second submersible motor pump 240 )).

The first relay unit 491 is electrically connected to the first electronic switch 430, and opens the second port 620 when the first submersible motor pump 140 is operated.

The second relay unit 492 is electrically connected to the second electronic switch 460 and opens the first port 610 when the second submersible motor pump 240 is operated.

Ground heat pump 500 is a device for heating and cooling the room using the heat exchanged in the ground heat exchange unit (300).

Hereinafter, the first underground heat exchanger 100 and the second underground heat exchanger 200 will be described in more detail with reference to FIGS. 2, 4, and 5. 4 is a plan view of a top plate of the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber shown in FIG. 2, and FIG. 5 is a view of the first heat exchange fluid guide chamber and the second heat exchange fluid guide chamber shown in FIG. Top view of the bottom plate.

The first underground heat exchanger 100 includes a first groundwater pumping pipe 120, a first heat exchange fluid guide chamber 130, a first submersible motor pump 140, a first heat exchange fluid pumping pipe 150, and a first heat exchange. It includes a fluid return pipe 160.

The first ground water pumping pipe 120 is inserted into the first geothermal well hole 10 formed in the ground, and has a first pump housing 121 and a diameter smaller than the diameter of the first geothermal well hole 10. Is connected to the lower end of the first pump housing 121, the heat exchange fluid flows from the first geothermal well hole 10 or the heat exchange fluid is discharged from the first pump housing 121 to the first geothermal well hole 10 1 housing inlet and outlet nozzle portion 122 is included.

The first heat exchange fluid guide chamber 130 is connected to an upper end of the first ground water pumping pipe 120, and the heat exchange fluid introduced into the first ground water pumping pipe 120 is the first geothermal well hole 10. The heat exchange fluid is discharged in the direction of the outer ground heat exchanger 300, and flows in the direction of the first groundwater pumping pipe 120 from the outside of the first geothermal well hole 10 is the first groundwater pumping pipe 120 It is configured to lead to the inner space of). The first heat exchange fluid guide chamber 130 will be described in more detail below.

The first submersible motor pump 140 is accommodated in the first groundwater pumping pipe 120 and is connected to the lower portion of the first heat exchange fluid guide chamber 130 to exchange heat exchange fluid in the first geothermal well hole 10. It is introduced into the first heat exchange fluid guide chamber 130.

The first heat exchange fluid pumping pipe 150 has a lower end connected to an upper portion of the first heat exchange fluid guide chamber 130, and an upper end connected to the ground heat exchanger 300, and the first heat exchange fluid guide chamber 130 is provided in the first heat exchange fluid guide chamber 130. 1 The heat exchange fluid that is guided to the outside of the geothermal well hole 10 is discharged to the outside of the first geothermal well hole 10 to be supplied to the ground heat exchange unit 300.

The first heat exchange fluid return pipe 160 has a lower end connected to the upper part of the first heat exchange fluid guide chamber 130, and an upper end connected to the ground heat exchange part 300, and the first heat exchange fluid pumping pipe 150 is adjacent to the first heat exchange fluid return pipe 150. The heat exchange fluid heat-exchanged in the ground heat exchange unit 300 is introduced into the first heat exchange fluid guide chamber 130.

The second underground heat exchanger 200 includes a second groundwater pumping pipe 220, a second heat exchange fluid guide chamber 230, a second submersible motor pump 240, a second heat exchange fluid pumping pipe 250, and a second heat exchange. Fluid return pipe 260 is included.

The second groundwater pumping pipe 220 is inserted into the second geothermal well hole 20 formed in the ground, and has a second pump housing 221 and a second diameter smaller than the diameter of the second geothermal well hole 20. A second housing connected to the lower end of the pump housing 221 so that the heat exchange fluid flows from the first geothermal well hole 10 or the heat exchange fluid is discharged from the first pump housing 121 to the first geothermal well hole 10. Inlet and outlet nozzle portion 222 is included.

The second heat exchange fluid guide chamber 230 is connected to the upper end of the second ground water pumping pipe 220, and the heat exchange fluid introduced into the second ground water pumping pipe 220 is external to the second geothermal well hole 20. The heat exchange fluid discharged in the direction of the ground heat exchange unit 300 and introduced into the second groundwater pumping pipe 220 from the outside of the second geothermal well hole 20 is led to the internal space of the second groundwater pumping pipe 220. Is configured to.

The second submersible motor pump 240 is accommodated in the second groundwater pumping pipe 220 and is connected to the lower portion of the second heat exchange fluid guide chamber 230 to exchange heat exchange fluid inside the second geothermal well hole 20. It is introduced into the second heat exchange fluid guide chamber 230.

The second heat exchange fluid pumping pipe 250 has a lower end connected to the upper portion of the second heat exchange fluid guide chamber 230, and an upper end connected to the ground heat exchanger 300, and the second heat exchange fluid guide chamber 230 is connected to the second heat exchange fluid guide chamber 230. The heat exchange fluid that is guided to the outside of the geothermal well hole 20 is discharged to the outside of the second geothermal well hole 20 to be supplied to the ground heat exchange unit 300.

The second heat exchange fluid return pipe 260 has a lower end connected to an upper portion of the first heat exchange fluid guide chamber 130, and an upper end connected to the ground heat exchange part 300 so as to be adjacent to the second heat exchange fluid pump 250. The heat exchange fluid disposed in the heat exchange unit 300 is introduced into the second heat exchange fluid guide chamber 230.

Meanwhile, each of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230 includes chamber portions 131 and 231 and twist pipes 132 and 232.

The chamber portions 131 and 231 include cylindrical portions 1311 and 2311, upper plate portions 1312 and 2312, and lower plate portions 1313 and 2313. The cylindrical portions 1311 and 2311 have internal spaces. The upper plate portions 1312 and 2312 cover the upper ends of the cylindrical portions 1311 and 2311. The upper plate portions 1312 and 2312 are pumped pipe through holes 1312a and 2312a and pumped pipe through holes 1312a and 2312a which are eccentrically positioned from the centers of the cylinders 1311 and 2311. 2312b). The lower plate portions 1313 and 2313 cover lower ends of the cylindrical portions 1311 and 2311. The lower plate portions 1313 and 2313 are groundwater pumping pipe connection holes 1313a and 2313a and groundwater pumping pipe connection holes 1313a and 2313a to which upper ends of the first groundwater pumping pipe 120 and the second groundwater pumping pipe 220 are connected. The heat exchange fluid flowing into the first heat exchange fluid guide chamber 130 or the second heat exchange fluid guide chamber 230 is disposed around the first groundwater pumping pipe 120 or the second ground water pumping pipe 220. It includes a plurality of fluid drop holes (1313b, 2313b) to fall into the inner space.

Twist pipes (132, 232) is connected to the groundwater pumping pipe connection holes (1313a, 2313a) inlet portion (1321, 2321), the inlet communicating with the first groundwater pumping pipe 120 or the second groundwater pumping pipe 220 Extending from the upper portions of the bent portions 1322 and 2322 and the bent portions 1322 and 2322 in the direction of the pumping pipe through holes 1312a and 2312a from the parts 1321 and 2321 and connected to the pumping through holes 1312a and 2312a. And outlet portions 1323 and 2323 communicating with the first heat exchange fluid pumping pipe 150 or the second heat exchange fluid pumping pipe 250.

Each combination of the first heat exchange fluid guide chamber 130 and the first pump housing 121 connected thereto, the second heat exchange fluid guide chamber 230, and the second pump housing 221 connected thereto constitute a doublet housing. Done.

The geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention is capable of seasonal compatibility and alternative operation by a control process of the control unit 400, and the control unit 400 will be described below. The seasonal operation process by the control process is explained.

In summer, the control unit 400 controls the first underground heat exchange unit 100 to be a supply well and the second underground heat exchange unit 200 to be a return well.

To this end, the controller 400 drives the first submersible motor pump 140 and the underground ground heat exchanger 300. At this time, the power applied to the main power controller 410 of the control unit 400 is applied to the first power controller 420, by the power applied to the first power controller 420, the first electronic switch 430 and The first load protector 440 is sequentially operated to operate the first submersible motor pump 140.

When the first submersible motor pump 140 operates, the heat exchange fluid under the first geothermal well hole 10, that is, the groundwater is pumped, through the first housing inlet and outlet nozzle part 122 of the first groundwater pumping pipe 120. 1 is introduced into the pump housing 121, the heat exchange fluid is sucked and discharged into the first submersible motor pump 140 is supplied into the first heat exchange fluid guide chamber 130.

The heat exchange fluid supplied into the first heat exchange fluid guide chamber 130 flows into the inlet portion 1321 of the twist pipe 132 accommodated in the cylindrical portion 1311 of the chamber portion 131 to thereby form the twist pipe 132. It moves along and is supplied to the first heat exchange fluid pumping pipe 150 through the outlet portion 1323 of the twisted pipe 132.

Subsequently, the heat exchange fluid is supplied to the ground heat exchange unit 300 along the first heat exchange fluid pumping pipe 150 to be heat-exchanged by the ground heat exchange unit 300, and then the second heat exchange is performed through the second heat exchange fluid return pipe 260. The heat exchange fluid introduced into the cylindrical portions 1311 and 2311 of the fluid guide chamber 230 and introduced into the cylindrical portion 2311 of the second heat exchange fluid guide chamber 230 is the second heat exchange fluid guide chamber 230. It is dropped into the inner space of the second groundwater pumping pipe 220 through the plurality of fluid drop holes 2313b of the lower plate portion 2313 of the lower plate portion 2313 and is discharged into the second geothermal well hole 20. At this time, the control unit 400 operates the first relay unit 491 to open the second port 620 of the three-way electric valve 600 so that the heat exchanged heat exchanged fluid is transferred to the second heat exchange fluid return pipe 260. To be supplied.

The heat exchange fluid supplied into the second geothermal well hole 20 is gradually restored from the second geothermal well hole 20, and is thermally restored first by the geothermal heat in the second geothermal well hole 20. The heat exchange fluid gradually filling up in the well hole 20 is recovered to the first geothermal well hole 10 through the well communication passage 170.

The heat exchange fluid recovered to the first geothermal well hole 10 is secondaryly restored while being guided to the lower side of the first geothermal well hole 10 along the first geothermal well hole 10. The groundwater flowing downward of the first geothermal well hole 10 is pumped to the first submersible motor pump 140 and the recycling process is supplied to the ground heat exchange unit 300.

As described above in summer, the first submersible motor pump 140 and the ground heat exchanger 300 are used to cool the room. As described above, when the first submersible motor pump 140 and the ground heat exchanger 300 are driven throughout the summer, the heat recovery capacity of the second geothermal well ball 20 on the return side is gradually reduced by the heat storage. The temperature in the second geothermal well hole 20 is higher than the first geothermal well hole 10. Therefore, in the winter time, the present invention operates in the opposite manner to the summer time, thereby supplying heat exchange fluid, ie, groundwater, in the second geothermal well hole 20 at a high temperature to the ground heat exchange part 300, thereby improving heating thermal efficiency.

That is, in winter, the control unit 400 controls the second underground heat exchange unit 200 to be a supply well and the first underground heat exchange unit 100 to be a return well.

To this end, the controller 400 drives the second submersible motor pump 240 and the underground ground heat exchanger 300. At this time, the power applied to the main power controller 410 of the control unit 400 is applied to the second power controller 450, the second electronic switch 460 by the power applied to the second power controller 450 and The second submersible motor pump 240 is operated by sequentially moving the second load protector 470.

When the second submersible motor pump 240 is operated, the heat exchange fluid, that is, the groundwater of the lower part of the second geothermal well hole 20, is pumped through the second housing inlet and outlet nozzle part 222 of the second groundwater pumping pipe 220. 2 is introduced into the pump housing 221, and the heat exchange fluid introduced into the pump housing 221 is sucked and discharged into the second submersible motor pump 240 and is supplied into the second heat exchange fluid guide chamber 230. At this time, the control unit 400 operates the second relay unit 492 to open the first port 610 of the three-way electric valve 600 so that the heat-exchanged heat exchange fluid is transferred to the first heat exchange fluid return pipe 160. To be supplied.

The heat exchange fluid supplied into the second heat exchange fluid guide chamber 230 flows into the inlet portion 2321 of the twist pipe 232 accommodated in the cylindrical portion 2311 of the chamber portion 231 to thereby form the twist pipe 232. It moves along and is supplied to the second heat exchange fluid pumping pipe 250 through the outlet 2323 of the twisted pipe 232.

Subsequently, the heat exchange fluid is supplied to the ground heat exchange part 300 along the second heat exchange fluid pumping pipe 250, and heat exchanged by the ground heat exchange part 300, and then the first heat exchange through the first heat exchange fluid return pipe 160. The heat exchange fluid introduced into the cylindrical portion 1311 of the fluid guide chamber 130 and introduced into the cylindrical portion 1311 of the first heat exchange fluid guide chamber 130 is a lower plate of the first heat exchange fluid guide chamber 130. It is dropped into the inner space of the first groundwater pumping pipe 120 through the plurality of fluid drop holes 1313b of the part 1313 and is discharged into the first geothermal well hole 10.

The heat exchange fluid supplied to the inside of the first geothermal well hole 10 is gradually restored from the first geothermal well hole 10 and heat-restored primarily by geothermal heat in the first geothermal well hole 10. The heat exchange fluid gradually filling up in the well hole 10 is recovered to the second geothermal well hole 20 through the well communication passage 170.

The heat exchange fluid recovered to the second geothermal well hole 20 is guided to the lower side of the second geothermal well hole 20 along the second geothermal well hole 20 to be secondly heat-restored. The groundwater flowing to the lower side of the second geothermal well hole 20 is pumped to the second submersible motor pump 240 and the recirculation process supplied to the ground heat exchange unit 300 is repeated.

On the other hand, while the operation is in progress by the controller 400, a problem occurs in the first submersible motor pump 140, the first load protector 440 is disconnected from the first submersible motor pump 140, the first When the operation of the electronic switch 430 is interrupted, the interlock circuit unit 480 of the controller 400 operates the second electronic switch 460 to supply power from the main power controller 410 to the second submersible motor pump 240. (2) to operate the second submersible motor pump (240). Accordingly, even if a problem occurs in the operation of the first submersible motor pump 140, the circulation of the heat exchange fluid is continued without stopping, thus cooling operation can be continued.

Using a geothermal air conditioning system equipped with a compatible operation control technology of a double underground heat exchanger according to an embodiment of the present invention has the following advantages.

First, by varying the circulation direction of the groundwater in the summer and winter through the control process by the control unit 400, in the summer of the first geothermal well ball 10 to maintain a lower temperature than the first geothermal well ball (10) Ground water is supplied to the ground heat exchange unit 300, and in the winter, ground water of the second geothermal well hole 20, which is formed at a higher temperature than the first geothermal well hole 10, is driven by the cooling system in summer. To be supplied. Therefore, there is an advantage of maximizing the cooling and heating efficiency because the direction of the groundwater is different depending on the seasonal characteristics.

Second, even if a problem occurs in the first submersible motor pump 140 during the cooling operation by operating the first submersible motor pump 140 by the interlock circuit unit 480 of the controller 400, the second submersible motor pump ( 240 can be operated, the circulation of the heat exchange fluid is continued without stopping, thus the cooling operation can be continued.

Third, adjacent to the cylindrical portion (1311, 2311) having the inner space, the pumping pipe through hole (1312a, 2312a) and the pumping pipe through hole (1312a, 2312a) eccentrically located from the center of the cylindrical portion (1311, 2311) Groundwater pumping pipe connection holes 1313a including upper and lower plates 1312 and 2312 covering the upper ends of the cylindrical parts 1311 and 2311 and including the water return pipe through holes 1312b and 2312b. ) And the heat exchange fluid disposed in the periphery of the groundwater pumping pipe connection hole 1313a and introduced into the first heat exchange fluid guide chamber 130 or the second heat exchange fluid guide chamber 230 may include the first ground water pumping pipe 120 or A chamber including a plurality of fluid drop holes (1313b, 2313b) to be dropped into the inner space of the second ground water pumping pipe 220 and the lower plate portion (1313, 2313) covering the lower end of the cylindrical portion (1311, 2311) Parts 131 and 231; And inlet parts 1321 and 2321 and inlet parts 1321 and 2321 connected to the groundwater pumping pipe connection holes 1313a and 2313a to communicate with the first groundwater pumping pipe 120 or the second groundwater pumping pipe 220. Extending from the upper portions of the bent portions 1322 and 2322 and the bent portions 1322 and 2322 in the direction of the pumping pipe through holes 1312a and 2312a, and connected to the pumping pipe through holes 1312a and 2312a to connect the first heat exchange fluid pumping pipe. The first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230 including the twist pipes 132 and 232 including the outlet portions 1323 and 2323 communicating with the 150 are provided. Located in the geothermal well hole (10) to circulate the heat exchange fluid in the first heat exchange fluid pumping pipe 150 and the second heat exchange fluid return pipe 260 and the second geothermal well hole (20) to circulate the heat exchange fluid The second heat exchange fluid pumping pipe 250 and the second heat exchange fluid return pipe 260 are respectively a first groundwater pumping pipe ( 120 and the second groundwater pumping pipe 220 may be disposed in parallel to each other in parallel with each other, and thus the circulation of the heat exchange fluid in the first geothermal well hole 10 and the second geothermal well hole 20 having a narrow diameter. For the heat exchange fluid pumping pipe (150, 250) and the heat exchange fluid return pipe (160, 260) there is an advantage that it becomes easy to install.

Fourth, the ground-restored groundwater is supplied to the ground heat exchange unit 300 through the first geothermal well hole 10 or the second geothermal well hole 20 and the groundwater that has passed through the ground heat exchange unit 300 is the second geothermal well. Since it is introduced into the ball 20 or the first geothermal well ball 10, the geothermal well ball to which the ground water is supplied and the geothermal well ball to which the ground water passing through the ground heat exchange unit 300 are recovered are separately provided. In addition to the excellent heat recovery effect compared with the conventional ground water recovery and heat restoration in the well hole, the depth of the geothermal well hole is shorter than the conventional one, thereby improving the workability and construction cost.

Hereinafter, a two-well open type geothermal system including a doublet housing according to another embodiment of the present invention will be described with reference to FIGS. 6 and 7 and a two-well open type geothermal system including a doublet housing according to an embodiment of the present invention. Explain the difference between. 6 is a cross-sectional view for explaining the configuration of a geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to another embodiment of the present invention, Figure 7 is a top plate and twisted tube variable plate shown in FIG. It is a perspective view which shows.

6 and 7, a geothermal air conditioning system equipped with a compatible operation control technology of a double underground heat exchanger according to another embodiment of the present invention includes a first heat exchange fluid guide chamber 130 and a second heat exchange fluid guide chamber. (230) The pumping pipe through holes 1312a and 2312a of each of the top plates 1312 and 2312 communicate with each other and a plurality of subunit holes 1312a-1 and 2312a-1 along the circumferential direction of the top plates 1312 and 2312. The upper plate portions 1312 and 2312 of each of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230 are formed inside an edge adjacent to the edges of the top plates 1312 and 2312. Further comprising circular slits 1312c, 2312c, each of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230, the pipe coupling hole is coupled to the upper portion of the twisted pipe (132, 232) (181, 281), inserted into the circular slit (1312c, 2312c) on the bottom surface Guide protrusions 182 and 282 sliding along 1312c and 2312c, and a pipe interference prevention hole 183 provided in a form surrounding the first heat exchange fluid return pipe 160 in a state of being connected to the top plates 1312 and 2312. 283, the twisted pipe position variable plate (180, 280) disposed above the upper plate portion (1312, 2312); Handle coupling columns (191, 291) connected to one side of the upper surface of the twisted pipe position variable plates (180, 280) and extend a predetermined length in the upper direction of the first geothermal well ball 10 or the second geothermal well ball (20) ; And the handle coupling pillars 191 and 291 are inserted into the first geothermal well hole 10 or the second geothermal well hole 20 from the outside of the first geothermal well hole 10 and the second geothermal well hole 20. It is the same as the two-well open geothermal system including the doublet housing according to an embodiment of the present invention except that it further includes a rotary operation handle (192, 292) screwed to the upper end of the).

The rotation operation handles 192 and 292 may be stored separately from the handle coupling columns 191 and 291 after the positions of the upper ends of the twist pipes 132 and 232 are changed.

The geothermal heating and cooling system equipped with a compatible operation control technology of a double underground heat exchanger according to another embodiment of the present invention may vary the positions of the upper ends of the twisted pipes (132, 232). That is, when the rotary operation handles 192 and 292 are operated on the ground to the left and the right side, the twist pipe position variable plates 180 and 280 rotate so that the twist pipes 132 and 232 are rotated in the small unit holes 1312a-1, The position at which 2312a-1) is coupled is variable. Accordingly, when connecting the first heat exchange fluid pumping pipe 150 or the second heat exchange fluid pumping pipe 250 with the heat exchanger 110, the upper end portions of the twisted pipes 132 and 232 according to the position of the heat exchanger 110. By varying the position, the position of the upper end portions of the twisted pipes 132 and 232 can be adjusted closer to the heat exchanger 110, so that the first heat exchange fluid pumping pipe 150 or the second heat exchange fluid pumping pipe 250 exchanges heat. It is possible to further narrow the distance connected to the machine 110, so that the process of connecting the first heat exchange fluid pumping pipe 150 or the second heat exchange fluid pumping pipe 250 with the heat exchanger 110 may be facilitated. have.

Meanwhile, the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 240 may be made of a synthetic resin material, but may be made of a metal material for strength. The anti-corrosion coating layer may be applied to the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 240 of the metal material to prevent corrosion of the metal surface.

The anti-corrosion coating layer is 20% by weight of guanadino benzoimidazole, 15% by weight of oxycarboxylic acid leaves, 10% by weight of imidazoline thione, 15% by weight of hafnium, 10% by weight of molybdenum (MoS2), and 25% by weight of aluminum oxide. %, Diglycidyl aniline 5% by weight, the coating thickness can be formed to 7㎛.

Guanadino benzoimidazole, oxycarboxylic acid leaf, imidazoline thione, and diglycidyl aniline serve as corrosion protection and discoloration prevention.

Hafnium is a corrosion-resistant transition metal element that serves to have excellent waterproofness and corrosion resistance.

Molybdenum emulsion plays a role of imparting slidability and lubricity to the surface of the coating film.

Aluminum oxide is added for the purpose of fire resistance, chemical stability, and the like.

The reason for limiting the numerical value of the ratio and the coating thickness of the components as described above, the inventors analyzed through the test results several times, showed the optimum anti-corrosion effect at the ratio.

In addition, the first groundwater pumping pipe 120 and the second groundwater pumping pipe 220 may be coated with an antifouling coating layer made of an antifouling coating composition to effectively achieve the prevention and removal of contaminants.

The antifouling coating composition includes ampodiglycinate and sorbitol ester in a 1: 0.01 to 1: 2 molar ratio, and the total content of ampodiglycinate and sorbitol ester is 1 to 10% by weight based on the total aqueous solution. to be.

The ampodiglycinate and sorbitol esters are preferably 1: 0.01 to 1: 2 as the molar ratio. When the molar ratio is out of the range, the first groundwater pumping pipe 120 and the second groundwater pumping pipe 220 are applied. There is a problem that the coating film is removed due to deterioration or increase of moisture absorption of the surface after coating.

The ampodiglycinate and sorbitol esters are preferably 1 to 10% by weight of the total composition aqueous solution, if less than 1% by weight of the first groundwater pumping pipe 120 and the second groundwater pumping pipe 220 is deteriorated There is a problem, and when it exceeds 10% by weight, crystal precipitation is likely to occur due to an increase in the thickness of the coating film.

On the other hand, as a method for applying the present antifouling coating composition to the first ground water pumping pipe 120 and the second ground water pumping pipe 220 is preferably applied by a spray method. In addition, the final coating film thickness of the first ground water pumping pipe 120 and the second ground water pumping pipe 220 is preferably 500 to 2000 kPa, more preferably 1000 to 2000 kPa. If the thickness of the coating film is less than 500 kPa, there is a problem of deterioration in the case of high temperature heat treatment, and if the thickness of the coating film exceeds 2000 kPa, crystal precipitation of the coated surface is liable to occur.

In addition, the present antifouling coating composition may be prepared by adding 0.1 mol of ampodiglycinate and 0.05 mol of sorbitol ester to 1000 ml of distilled water, followed by stirring.

In addition, the first submersible motor pump 140 and the second submersible motor pump 240 are provided with packing. The packing may be made of a rubber material, and the raw material content ratio of the packing is 60% by weight of rubber, 33 to 36% by weight of carbon black, 2 to 5% by weight of antioxidant, and 1 to 3% by weight of sulfur as an accelerator. .

Carbon black is added to increase the wear resistance, but if the content is less than 33% by weight, the elasticity and wear resistance is reduced, if the content exceeds 36% by weight, the rubber content of the main component is relatively small, there is a fear that the elastic force is lowered , 33 to 36% by weight.

Antioxidants add 2-5% by weight of 3C (N-PHENYL-N'-ISOPROPYL-P-PHENYLENEDIAMINE) or RD (POLYMERIZED 2,2,4-TRIMETHYL-1,2-DIHYDROQUINOLINE) If it is less than the weight%, the product is easy to oxidize, and if it is added too much, if it exceeds 5 weight%, the rubber content of the main component is relatively small, and the elastic force may be reduced. ~ 5% by weight is appropriate.

Sulfur, an accelerator, is mixed with 1-3 wt%. Less than 1% by weight is a slight vulcanization effect in the heating step during molding, so 1% by weight or more is added. If it exceeds 3% by weight, the content of rubber, which is a main component, is relatively low, and there is a possibility that the elastic force may drop, so 1 to 3% by weight is appropriate.

Therefore, since the present invention is reinforced with synthetic rubber having elasticity in various directions, the elasticity, toughness, and rigidity of the packing is increased, so that durability is improved, and thus the life of the packing is increased.

The description of the presented embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention should not be limited to the embodiments set forth herein but should be construed in the broadest scope consistent with the principles and novel features set forth herein.

100: first underground heat exchanger 200: second underground heat exchanger
300: ground heat exchanger 400: control unit
500: ground heat pump 600: three-discharge electric valve

Claims (3)

A three-discharge electric valve 600 including a first port 610, a second port 620, and a third port 630;
Installed in the first geothermal well hole 10, the first submersible motor pump 140, the first heat exchange fluid pumping pipe 150 and the heat exchange fluid pumped from the first submersible motor pump 140 and the A first underground heat exchanger (100) including a first heat exchange fluid return pipe (160) connected to the first port (610);
A second heat exchange fluid pumping pipe 250 installed inside the second geothermal well hole 20 and into which a heat exchange fluid pumped from the second submersible motor pump 240 and the second submersible motor pump 240 is introduced. A second underground heat exchange part 200 including a second heat exchange fluid return pipe 260 connected to the second port 620;
Is connected to the first heat exchange fluid pumping pipe 150 and the second heat exchange fluid pumping pipe 250 through a heat exchange fluid supply pipe 310, and the third port 630 through the heat exchange fluid return pipe 320 By connecting, the heat exchange fluid supplied from the first underground heat exchange unit 100 to heat exchange with the load side, the ground heat exchange unit 300 so that the heat exchange fluid supplied from the second underground heat exchange unit 200 heat exchange with the load side ; And
A control unit 400 for controlling a heat exchange fluid circulation direction between the first underground heat exchange unit 100 and the second underground heat exchange unit 200,
The control unit 400,
A main power controller 410 to which commercial power is applied;
A first power controller 420 connected to the main power controller 410 to supply power, and for applying power applied from the main power controller 410 toward the first underground heat exchange unit 100;
A first electronic switch 430 electrically connected to the first power controller 420;
A first load protector 440 electrically connected between the first electronic switch 430 and the first submersible motor pump 140;
A second power controller (450) connected to the main power controller (410) to receive power and for applying power applied from the main power controller (410) toward the second underground heat exchanger (200);
A second electronic switch 460 electrically connected to the second power controller 450;
A second load protector 470 electrically connected between the second electronic switch 460 and the second submersible motor pump 240;
The first electronic switch 430 and the second electronic switch 460 are electrically connected to each other, and the first load protector 440 is disconnected from the first submersible motor pump 140 to the first electron. When the operation of the switch 430 is blocked, the second electronic switch 460 is operated so that the power from the main power controller 410 is applied to the second submersible motor pump 240 so that the second submersible motor is operated. An interlock circuit unit 480 for operating the pump 240;
A first relay unit 491 that is electrically connected to the first load protector 440 and opens the second port 620 when the first submersible motor pump 140 is operated; And
A second relay unit 492 electrically connected to the second load protector 470 and opening the first port 610 when the second submersible motor pump 240 is operated;
The first underground heat exchange unit 100,
A first pump housing 121 inserted into the first geothermal well hole 10 and connected to a lower end of the first pump housing 121 having a diameter smaller than the diameter of the first geothermal well hole 10; A first groundwater pumping pipe (120) including a housing inlet and nozzle unit (122);
The heat exchange fluid connected to the upper end of the first ground water pumping pipe 120 and introduced into the first ground water pumping pipe 120 is directed toward the outer ground heat exchanger 300 of the first geothermal well hole 10. The heat exchange fluid flowing in the direction of the first ground water pumping pipe 120 from the ground heat exchange unit 300 outside of the first geothermal well hole 10 is the inside of the first ground water pumping pipe 120. A first heat exchange fluid guide chamber 130 configured to guide and drop into the space;
It is accommodated in the first groundwater pumping pipe 120, is connected to the lower portion of the first heat exchange fluid guide chamber 130, the heat exchange fluid in the first geothermal well hole 10, the first heat exchange fluid guide A first submersible motor pump 140 flowing into the chamber 130;
A lower end portion is connected to an upper portion of the first heat exchange fluid guide chamber 130, and an upper end portion is connected to the ground heat exchange unit 300, and the first geothermal well hole 10 is formed in the first heat exchange fluid guide chamber 130. Heat exchange fluid guided toward the external ground heat exchanger 300 of the first ground heat exchanger 300 is discharged toward the external ground heat exchanger 300 of the first geothermal well hole 10 to be supplied to the ground heat exchanger 300. Fluid pumping pipe 150; And
A lower end portion is connected to an upper portion of the first heat exchange fluid guide chamber 130, and an upper end portion is connected to the ground heat exchange part 300, and disposed to be adjacent to the first heat exchange fluid pumping pipe 150. And a first heat exchange fluid return pipe 160 through which the heat exchange fluid exchanged at 300 is introduced into the first heat exchange fluid guide chamber 130.
The second underground heat exchange unit 200,
A second pump housing 221 inserted into the second geothermal well hole 20 and connected to a lower end of the second pump housing 221 having a diameter smaller than the diameter of the second geothermal well hole 20; A second groundwater pumping pipe 220 including a housing inlet and outlet nozzle unit 222;
The heat exchange fluid connected to the upper end of the second groundwater pumping pipe 220 and introduced into the second groundwater pumping pipe 220 is directed toward the outer ground heat exchanger 300 of the second geothermal well hole 20. The heat exchange fluid flowing in the direction of the second groundwater pumping pipe 220 from the external ground heat exchanger 300 of the second geothermal well hole 20 is the internal space of the second groundwater pumping pipe 220. A second heat exchanging fluid guide chamber 230 configured to be guided and dropped;
The second groundwater pumping pipe 220 is accommodated inside the second heat exchange fluid guide chamber 230 and is connected to a lower portion of the heat exchange fluid inside the second geothermal well hole 20 to the second heat exchange fluid guide. A second submersible motor pump 240 introduced into the chamber 230;
A lower end portion is connected to an upper portion of the second heat exchange fluid guide chamber 230, and an upper end portion is connected to the ground heat exchange unit 300, and the second geothermal well hole 20 is formed in the second heat exchange fluid guide chamber 230. Heat exchange fluid guided in the direction of the external ground heat exchanger 300 of the second ground heat exchanger 300 is discharged in the direction of the external ground heat exchanger 300 of the second geothermal well hole 20 is supplied to the ground heat exchanger 300 Fluid pumping pipe 250; And
A lower end portion is connected to an upper portion of the second heat exchange fluid guide chamber 230, and an upper end portion is connected to the ground heat exchange part 300, and disposed to be adjacent to the second heat exchange fluid pumping pipe 250. And a second heat exchange fluid return pipe 260 allowing the heat exchange fluid heat exchanged at 300 to flow into the second heat exchange fluid guide chamber 230.
The heat exchange fluid in the first geothermal well hole 10 and the second geothermal well hole 20 is between the first geothermal well hole 10 and the second geothermal well hole 20. 10) or the water well communication passage 170 to be guided to the second geothermal well hole 20 is connected,
Each of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230,
Adjacent to the cylindrical portions 1311 and 2311 having an inner space, the pumping pipe through holes 1312a and 2312a and the pumping pipe through holes 1312a and 2312a which are eccentrically positioned from the centers of the cylinders 1311 and 2311. Groundwater pumping pipe connection hole including a top pipe portion (1312, 2312) including the water return pipe through hole (1312b, 2312b) and the upper end of the first ground water pumping pipe (120) to cover the upper end of the cylindrical portion (1311, 2311) 1313a and 2313a and the groundwater pumping pipe connection holes 1313a and 2313a disposed around the heat exchange fluid flowing into the first heat exchange fluid guide chamber 130 or the second heat exchange fluid guide chamber 230 A plurality of fluid drop holes (1313b, 2313b) to be dropped into the inner space of the first ground water pumping pipe 120 or the second ground water pumping pipe 220, and the lower end of the cylindrical portion (1311, 2311) Chamber portions 131, 23 including covering lower plate portions 1313, 2313 One); And
Inlets 1321 and 2321 connected to the groundwater pumping pipe connection holes 1313a and 2313a and communicating with the first groundwater pumping pipe 120 or the second groundwater pumping pipe 220, and the inlet part 1321, 2321 extending from the upper portions of the bent portions 1322 and 2322 and the bent portions 1322 and 2322 in the direction of the amniotic fluid pipe through holes 1312a and 2312a, and are connected to the amniotic pipe through holes 1312a and 2312a. A twist pipe (132, 232) including outlet portions (1323, 2323) in communication with the first heat exchange fluid pumping pipe (150) and the second heat exchange fluid pumping pipe (250);
Pumping through holes 1312a and 2312a of the upper plates 1312 and 2312 of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230 communicate with each other, and the upper plates 1312 and 2312 communicate with each other. Has an array structure in which a plurality of subunit holes 1312a-1 and 2312a-1 are arranged along the circumferential direction,
The top plates 1312 and 2312 of each of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230 are circular slits 1312c formed at an inner side of an edge adjacent to the edges of the top plates 1312 and 2312. 2312c),
Each of the first heat exchange fluid guide chamber 130 and the second heat exchange fluid guide chamber 230,
Piping coupling holes 181 and 281 coupled to the upper portions of the twist pipes 132 and 232, and guide protrusions inserted into the circular slits 1312c and 2312c at the bottom thereof and sliding along the circular slits 1312c and 2312c. 182, 282, and pipe interference preventing holes 183 and 283 provided in a form surrounding the first heat exchange fluid return pipe 160 in a state of being connected to the top plates 1312 and 2312, and the top plate 1312. , 2312, the balance weight pipe position variable plate (180, 280) disposed above;
The handle coupling column 191 connected to one side of the upper surface of the balance weight pipe position variable plates 180 and 280 and extending a predetermined length in the upper direction of the first geothermal well hole 10 or the second geothermal well hole 20. , 291); And
The handle coupling column 191 is inserted into the first geothermal well hole 10 or the second geothermal well hole 20 from the outside of the first geothermal well ball 10 and the second geothermal well ball 20. Rotation operation handles (192, 292) are further screwed to the upper end of the 291,
When the rotary operation handles 192 and 292 are operated to the left and the right, the balance weight pipe position variable plates 180 and 280 rotate so that the twist pipes 132 and 232 are moved to the subunit holes 1312a-1 and 2312a-. Characterized in that the position coupled to the 1) is variable,
Geothermal air-conditioning system with compatible operation control technology of double underground heat exchanger. delete delete

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