KR101483112B1 - Apparatus for Control Gap between Pump and Supply Pipe in Open type Underground Heat Exchanger - Google Patents

Abstract

The present invention relates to an opening and closing assembly for opening and closing a gap between a submerged pump and a supply pipe in an open type underground heat exchanger. According to the embodiment of the present invention, provided is an opening and closing assembly, capable of selectively opening and closing a gap between a submerged pump and a supply pipe to change the flow of fluid for switching a cooling mode or a heating mode of an open type underground heat exchanger. The opening and closing assembly according to the embodiment of the present invention is mounted in the submerged pump (30) which is arranged in the supply pipe (10) of the open type underground heat exchanger. The opening and closing assembly (300) according to the embodiment of the present invention includes a first fixing ring member (311), a first lifting ring member (312), a top blocking plate (310a), a second lifting ring member (322), a second fixing ring member (321), a bottom blocking plate (320a), and a connection beam (330).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an open type submerged heat exchanger,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an open / close assembly for opening / closing an interval between a heart pump and a supply pipe, which is coupled to a heart pump installed in a supply pipe in an underground heat exchanger buried in the ground to use underground heat for cooling or heating. To an opening / closing assembly capable of selectively opening / closing an interval between a heart pump and a supply pipe for the purpose of changing the flow of fluid for switching between a cooling mode or a heating mode of an open-type geophysical heat exchanger.

An example of an open-air geothermal heat exchanger according to the prior art is disclosed in Korean Patent No. 10-1150596, which is an underground heat exchanger using geothermal heat as an energy source for cooling and heating.

FIG. 1 is a schematic cross-sectional view showing a structure in which a conventional open-air geothermal heat exchanger according to the prior art is installed in the ground. As shown in the drawing, a conventional open-loop geothermal heat exchanger is provided with a supply pipe 10 in a well 100 formed in the ground vertically in the depth direction of the ground from the ground, The filler material 400 is filled in the space between the substrate 100 and the substrate 100. A return pipe 20 for introducing the heat-exchanged fluid from the heat pump (not shown) into the filler material 400 is provided for the space required for cooling and heating like the interior of the building, 10, a heart pump (30) for sending a fluid to a heat pump is disposed inside the supply tube (10). An inflow hole 11 through which the fluid can flow is formed at a lower end of the supply pipe 10 located at a lower end of the supply pipe 10, And a delivery pipe 31 for delivering the pumped fluid to the heat pump is connected. 1, the recovery pipe 20 and the discharge pipe 31 are shown in the form of bold arrows for the sake of convenience. On the other hand, the arrows shown by dotted lines in Fig. 1 indicate the flow direction of the fluid.

Therefore, in the conventional open type geotechnical heat exchanger having the above configuration, for example, the fluid recovered from the heat pump for the space requiring cooling and heating of a building such as a building or an apartment (hereinafter referred to as "building" for convenience) Is introduced into the filler material (400) through the return pipe (20), and this fluid is mixed with the groundwater in the well hole (100) and flows downward by gravity. The groundwater is sucked into the inside of the supply pipe 10 through the inflow hole 11 formed in the section of the perforated pipe of the supply pipe 10 from the lower part of the well hole 100 to be filled from below the supply pipe 10 , The heartbeat pump 30 pumps the fluid filled in the supply pipe 10 and sends the fluid to the bottom pump for heating and cooling the building or the like through the delivery pipe 31. In the heat pump, heat exchange is again performed, and the heat-exchanged fluid in the heat pump is recovered through the recovery pipe 20 again.

In the conventional open type geothermal heat exchanger having the above-described structure, the fluid returned to the return pipe 20 flows into the filler material 400 from the upper part of the wellbore 100, and flows downward to be mixed with the groundwater. (100) and sent to the heat pump through the delivery pipe (31). That is, in the case of the conventional open-loop geothermal heat exchanger according to the prior art, the fluid introduced into the ground through the return pipe has a "flow form from the top to the bottom ", and the fluid sent to the building is taken deep .

However, the temperature of the earth rises from the surface to the ground. According to actual cases, the underground temperature in the basement, which is about 50m below the surface, is about 15 degrees Celsius, but the underground temperature in the basement about 500 degrees below the surface is about 24 degrees Celsius. As such, the ground temperature is higher at the bottom of the ground than at the ground level. Therefore, when heating the building, it is effective to use a fluid that is relatively warmer and deeper than the surface. On the contrary, it is preferable to use the low temperature of the surface during cooling of the building. Therefore, it is more advantageous to suck the fluid existing near the surface of the ground by the heart pump 30 and send it to the heat pump of the building. That is, when it is necessary to heat the space such as a building or the like warmly, the fluid introduced into the supply pipe 10 from the deep hole of the well hole 100 is sucked into the centrifugal pump 30 through the delivery pipe 31 Conventional open-loop geothermal heat exchangers that send out a building's heat pump are advantageous. However, when cooling a building or the like coolly, a conventional open-loop geothermal heat exchanger is not as advantageous as in the case of heating.

Therefore, it is preferable to send the fluid near the surface of the building to the heat pump of the building when the cooling is required, In order to configure the open-loop geothermal heat exchanger to operate in the above-described manner, a means for controlling the flow of the fluid is required. That is, in order to form the open-loop geothermal heat exchanger capable of switching between the cooling state and the heating state, when the fluid is sucked by the heart pump disposed in the supply pipe, the flow of the fluid is changed in accordance with the cooling mode and the heating mode In order to achieve this, it is necessary to open and close the supply pipe and the heart pump appropriately in accordance with the necessity, and such a means is desperately required.

Korean Patent Registration No. 10-1150596 (issued on June 08, 2012).

The present invention has been developed in order to satisfy the above-mentioned necessity. Specifically, when heating is required, the fluid in the deep underground is sent to the heat pump of the building. However, when cooling is required, In order to change the flow of fluid in an open-loop geothermal heat exchanger for the purpose of constructing an open-loop geothermal heat exchanger capable of switching between a cooling mode and a heating mode capable of sending the fluid to the building's heat pump, And an apparatus (assembly) capable of opening and closing between the supply pipe and the heart pump.

In order to achieve the above object, according to the present invention, there is provided an open / close assembly mounted on a heart pump disposed in a supply pipe of an open-air geothermal heat exchanger, An upper shielding member provided at an upper position of the inlet of the heartbeat pump to close or open the gap between the heartbeat pump and the inner surface of the supply tube, an upper shielding member provided below the inlet of the heartbeat pump to close the gap between the heartbeat pump and the inner surface of the supply tube And an interlocking beam interlocking the upper blocking member and the lower blocking member; The upper shielding member includes a first stationary ring member and a first riser ring member that are sequentially spaced from above, and an outer surface of the heart pump, which connects the first stationary ring member and the first riser ring member, And an upper blocking plate made of an elastic member which is bent and bent outwardly of the outer surface of the heartbeat pump; The lower blocking member includes a second lifting ring member and a second fixing ring member which are sequentially spaced apart from a lower position of the inlet of the heartbeat pump and a second fixing ring member provided between the second fixing ring member and the second lifting ring member And a lower blocking plate which is installed to surround the outer surface of the heart pumping pump while being connected to the inner surface of the heart pumping pump, and is made of an elastic member bent and outwardly bent outwardly of the outer surface of the heart pumping pump; The interlocking beam connects the first lifting ring member and the second lifting ring member to each other; When the second rising ring member is lowered, the lower blocking plate is bent to come in close contact with the inner surface of the supply pipe to close the gap between the heart pump and the supply pipe. At the same time, the first rising ring member is also lowered, And the supply pipe is opened; When the second rising ring member is lifted, the lower blocking plate is opened to open the gap between the heart pump and the supply pipe. At the same time, the first rising ring member is also raised while the upper blocking plate is bent to come in close contact with the inner surface of the supply pipe, And an opening / closing assembly that closes the opening / closing assembly.

According to a first embodiment of the present invention, a rotary screw member having an outer threaded portion is provided at a lower portion of the heartbeat pump; And the second lifting / lowering ring member is screwed to the outer threaded portion of the rotating screw member, so that the second lifting / lowering ring member is moved up and down according to the rotation of the rotating screw member .

According to the second aspect of the present invention, there is provided a second embodiment of the above-described open / close assembly, wherein a rotating screw member having an outer threaded portion is provided on an upper portion of the heartbeat pump; Wherein the first lifting ring member is screwed to an outer threaded portion of the rotating screw member; When the first lifting ring member is lowered in accordance with the rotation of the rotary screw member, the upper blocking plate is opened to open the gap between the heartbeat pump and the supply pipe. At the same time, the second lifting ring member also descends while the lower blocking plate is bent, So as to close the gap between the heart pump and the supply pipe; When the first lifting ring member is lifted in accordance with the rotation of the rotary screw member, the upper blocking plate is bent to come in close contact with the inner surface of the supply pipe to close the gap between the heart pump and the supply pipe. At the same time, And the shield plate is spread to open a gap between the heart pump and the supply pipe.

In the underground heat exchanger having the open / close assembly of the present invention, when heating of a building or the like is required, a "flow pattern from upper to lower direction" When a cooling of a building or the like is required, a fluid is formed in a "flow form from the bottom to the upper direction ", and the fluid near the surface where the temperature is relatively low is sent to the heat pump of the building to maximize the cooling efficiency, Not only the efficiency of the air conditioner but also the efficiency of the air conditioner is greatly improved.

That is, according to the present invention, since the open / close assembly capable of opening / closing the interval between the supply pipe and the heart pump is provided in accordance with the cooling mode and the heating mode, when the underground heat exchanger is constructed using the open / If necessary, the fluid in the deep underground is sent to the building's heat pump. However, if cooling is required, the fluid near the surface with lower temperature than the deep underground can be sent to the building's heat pump, An open-type geothermal heat exchanger can be made.

1 is a schematic cross-sectional view showing a structure in which a conventional open-air geothermal heat exchanger is installed in the ground.
FIG. 2 is a schematic cross-sectional view illustrating a structure in which an open type geophysical heat exchanger having an open / close assembly according to the present invention is installed in the ground.
3 is a schematic perspective view of an open / close assembly according to the present invention.
4 is a schematic cross-sectional perspective view along line BB of FIG.
5 is a schematic perspective view showing a state in which the opening and closing assembly according to the present invention shown in FIG. 3 is assembled to a heart pump.
FIG. 6 is a schematic cross-sectional perspective view showing only a part of the structure of the opening and closing assembly according to the present invention, in a sectional view, in a state shown in FIG.
7 is a schematic front view showing a state in which a lower side blocking member is expanded in an open / close assembly according to an embodiment of the present invention.
8 is a schematic front view showing a state in which the upper side blocking member expands in the open / close assembly according to an embodiment of the present invention.
9 is a schematic front view showing a state in which a lower blocking member is expanded in an opening / closing assembly according to another embodiment of the present invention in which a rotating motor and a rotating screw member are provided on a top of a heart pump.
FIG. 10 is a schematic front view showing a state in which the upper side blocking member expands in the open / close assembly according to another embodiment of the present invention shown in FIG. 9;
FIG. 11 is a schematic cross-sectional view corresponding to FIG. 2 showing the state when the open-loop geothermal heat exchanger having the open / close assembly according to the present invention operates in the heating mode.
FIG. 12 is a schematic cross-sectional view corresponding to FIG. 2 showing a state in which an open-loop geothermal heat exchanger having an open / close assembly according to the present invention operates in a cooling mode.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

Before describing the open / close assembly 300 according to the present invention, the construction of the open-loop geothermal heat exchanger provided with the open / close assembly 300 of the present invention will be described with reference to FIG.

FIG. 2 is a schematic cross-sectional view showing a structure in which an open-loop geothermal heat exchanger in which an open / close assembly 300 according to the present invention is used is installed in the ground. As shown in the figure, an open-loop geothermal heat exchanger is provided with a supply pipe 10 in a well 100 formed in the ground vertically in the direction of the depth of the ground from the ground, and a supply pipe 10 and a well 100 The filling material 400 is filled. The filler material 400 may be a different material from the ground, but it may also be a ground soil material.

And a heart pump (30) for sending the fluid to the heat pump of the building is disposed in the supply pipe (10) at an upper position of the supply pipe (10). The ventilation pump 30 is connected to a discharge pipe 31 for discharging the fluid pumped by the supply pipe 10 to the heat pump of the building. A lower inflow hole 11 through which the fluid can flow is formed at a lower end of the supply pipe 10 located at a deep end of the supply pipe 10. The open bottom heat exchanger 10, in which the assembly of the present invention is used, An upper inflow hole 10 is formed at an upper portion of the supply pipe 10 to be positioned below the groundwater and at an upper portion of the supply pipe 10 located near the surface of the inflow pipe 10 to allow the fluid to flow into the supply pipe 10 from the filler material 400, (12) are further formed.

The open subsea heat exchanger is provided with a return pipe 20 for returning the heat-exchanged fluid from the heat pump to the filler material 400. The return pipe 20 is provided with a fluid returning from the heat pump A communication pipe 210 communicating with the supply pipe 10 to directly supply the fluid recovered from the heat pump to the inside of the supply pipe 10, And a flow conversion device (21) for selectively controlling the flow of the fluid recovered from the upper inflow pipe (220) or the communication pipe (210). The flow converter 21 may be a three-phase valve. In this case, the pipe connected to the heat pump, the upper inflow pipe 220, and the communication pipe 210 are connected to the three-phase valve. Accordingly, in accordance with the operation of the three-phase valve, the fluid recovered from the heat pump flows into the upper portion of the filler material 400 in the order of the pipe connected with the heat pump, the three-phase valve and the upper inflow pipe 220, or is connected to the heat pump The three-phase valve, and the communicating tube 210 in this order.

A heart pump 30 is disposed inside the supply pipe 10 and the heart pump 30 has a cylindrical shape and an inlet 32 for sucking fluid is formed. There is a gap between the heart pump (30) and the inner surface of the supply pipe (10).

The open / close assembly 300 according to the present invention is coupled to the outside of the heart pump 30 and is disposed above and below the inlet 32 in accordance with the operating mode (cooling mode / heating mode) of the open channel heat exchanger, (30) and the inner surface of the supply pipe (10).

FIG. 3 is a schematic perspective view of an open / close assembly 300 according to the present invention, and FIG. 4 is a schematic cross-sectional perspective view taken along line B-B of FIG. 5 is a schematic perspective view showing a state in which the open / close assembly 300 according to the present invention is assembled to a rod-shaped heart-shaped pump 30 having a circular cross section, and FIG. 6 is a schematic perspective view of the heart- Is not a sectional view, but is a schematic cross-sectional perspective view showing only a partial configuration of the open / close assembly 300 according to the present invention in a cross-sectional form. 7 is a schematic front view showing a state in which the lower shield plate 320a expands outward in the open / close assembly 300 according to the present invention, and FIG. 8 is a schematic front view showing a state in which the upper shield plate 320a, Is a schematic front view showing a state in which the outer casing 310a is expanded outward. In FIGS. 7 and 8, the upper shielding member 310 and the lower shielding member 320 are shown in cross section for convenience.

As shown in the drawing, the opening and closing assembly 300 according to the present invention is attached to the outside of the rod-shaped heart pump 30. Specifically, the openable and closable assembly 300 of the present invention includes an upper block member 310 positioned above the suction port 32 of the heart pump 30, and an upper block member 310 positioned below the suction port 32 of the heart pump 30 A lower shielding member 320 and an interlocking beam 330 for interlocking the upper shielding member 310 and the lower shielding member 320.

The upper shielding member 310 is composed of two ring members and an upper shielding plate 310a provided therebetween. Among the two ring members constituting the upper blocking member 310, the upper ring member is a first retaining ring member 311, which is installed so as not to be vertically movable on the outer surface of the heart pump 30, Another ring member spaced downwardly from the first stationary ring member 311 is a first ascending / descending ring member 312, which is vertically movable on the outer surface of the heart pump 30. The upper blocking plate 310a is a member that winds the outer surface of the heart pump 30 while connecting the first fixing ring member 311 and the first lifting ring member 312. The upper blocking plate 310a has elasticity, That is, a member bent outwardly from the outer surface of the heartbeat pump 30 and then stretched out again. The upper shield plate 310a may be formed of a rubber plate or the like.

The first lifting ring member 312 is a member which vertically moves from the outer surface of the heart pump 30. Since the first fixing ring member 311 adheres to the original position, the first lifting ring member 312 The upper blocking plate 310a is bent outward from the outer surface of the heart pump 30 when the first fixing ring member 311 and the first ascending / descending ring member 312 are brought close to each other. The upper shield plate 310a is bent from the outer surface of the heart pump 30 to the inner surface of the supply tube 10 so that the upper shield plate 310a is bent outward from the outer surface of the heart pump 30, So that the gap between the heart pump 30 and the inner surface of the supply pipe 10 is closed. Conversely, when the first lifting ring member 312 is lowered, the first lifting ring member 311 and the first lifting ring member 312 are separated from each other, and the upper blocking plate 310a, which is bent along the first lifting ring member 311, do. The gap between the heart pump 30 and the inner surface of the supply pipe 10 is opened again as the upper shield plate 310a is expanded as described above in a state where the heart pump 30 is located inside the supply pipe 10. [

The lower shielding member 320 of the openable and closable assembly 300 of the present invention includes two ring members and a lower shielding plate 320a wound on the outside of the heartbeat pump 30 below the suction port 32 of the heartbeat pump 30, . Of the two ring members positioned below the suction port 32 of the heart pump 30, the ring member positioned at the upper side is the second lift ring member 322, which is vertically moved on the outer surface of the heart pump 30 And another ring member spaced downwardly from the second lift ring member 322 is a second retaining ring member 321 which is vertically movable on the outer surface of the heart pump 30 . The lower blocking plate 320a is a member that winds the outer surface of the heartbeat pump 30 while connecting the second fixing ring member 321 and the second lifting ring member 322. The lower blocking plate 320a has elasticity, That is, it is a member which is bent outwardly from the outer surface of the heartbeat pump 30 and then spreads out again. The lower shield plate 320a may also be made of a rubber plate or the like.

The second lifting ring member 322 is a member that moves vertically on the outer surface of the heart pump 30. Since the second retaining ring member 321 adheres to the original position, the second lifting ring member 322 The lower blocking plate 320a is bent outwardly from the outer surface of the heart pump 30 when the second locking ring member 321 and the second lifting ring member 322 are brought close to each other. The lower shield plate 320a is curved outwardly from the outer surface of the heart pump 30 and the inner surface of the supply tube 10 is bent So that the gap between the heart pump 30 and the inner surface of the supply pipe 10 is closed. On the contrary, when the second lifting ring member 322 is lifted, the second lifting ring member 321 and the second lifting ring member 322 move away from each other, and the lower blocking plate 320a, which has been bent along the second lifting ring member 322, do. The gap between the heart pump 30 and the inner surface of the supply pipe 10 is opened again as the lower side block member 320 is expanded as described above in the state where the heart pump 30 is located inside the supply pipe 10. [

The heart pump 30 is provided with the concave portion 38 so that the outer surface of the heart pump 30 is wound around the first ring member 311 and the second ring member 321 without being moved up and down. And the first and second stationary ring members 311 and 321 can be located in the recesses 38 and 39. [ The interlocking beam 330 is provided so that the operation of the upper block member 310 and the lower block member 320 are interlocked with each other. Down ring member 312 and the second lift-up ring member 322. The first lift-

For operation of the open / close assembly 300 according to the present invention, the second screw-down ring member 322 or the first screw-down ring member 312, which has an external thread portion, (35) can be rotatably provided on the heart pump (30). Further, a rotation motor 36 may be further provided on the heart pump 30 for rotating the rotation screw member 35. [ Therefore, when the rotation motor 36 is driven, the rotating screw member 35 is rotated, and the second lifting / lowering ring member 322 or the first and second lifting / lowering ring members 322, The descending ring member 312 is moved in a screwing manner.

7 and 8 show a schematic front view of a case where the opening and closing assembly 300 according to the present invention is coupled to the heart pump 30 having the rotating screw member 35 and the rotary motor 36 at the bottom, FIG. 7 shows a state in which the lower shield plate 320a expands outwardly, and FIG. 8 shows a state in which the upper shield plate 310a expands outward. In FIGS. 7 and 8, the upper shielding member 310 and the lower shielding member 320 are shown in cross section for convenience.

As described above, since the first lifting ring member 312 and the second lifting ring member 322 are connected to each other by the interlocking beam 330 in the open / close assembly 300 of the present invention, The second lift ring member 322 is lowered so that the lower shield plate 320a is moved downward by the rotation of the rotary pump 36. As a result, At the same time, the first ascending / descending ring member 312 also descends while the upper blocking plate 310a is expanded. 8, when the second lift ring member 322 is lifted, the lower shield plate 320a is expanded as described above, but at the same time, the first lift ring member 312 is also lifted, The plate 310a is bent outwardly from the outer surface of the heart pump 30. [ That is, when the second ascending / descending ring member 322 descends, the first ascending / descending ring member 312 also descends, so that the lower blocking plate 320a bends and the upper blocking plate 310a expands simultaneously When the second lift ring member 322 rises, the first lift ring member 312 also rises together with the expansion of the lower shield plate 320a and the bending of the upper shield plate 310a simultaneously .

9 and 10 are schematic front views schematically showing the case where the opening and closing assembly 300 according to the present invention is coupled to the heart pump 30 having the rotating screw member 35 and the rotary motor 36 at the top, FIG. 9 shows a state in which the lower shield plate 320a expands outwardly, and FIG. 10 shows a state in which the upper shield plate 310a expands outward. 9 and 10, the upper shielding member 310 and the lower shielding member 320 are shown in sectional form for convenience.

9 and 10, when the opening / closing assembly 300 of the present invention is installed in the heart pump 30 having the rotating screw member 35 and the rotating motor 36 at the upper portion thereof, the rotating screw member 35 The first lifting ring member 312 is lifted and lowered. 9, when the first rising ring member 312 is lowered and the upper shielding plate 310a is expanded, the second lifting ring member 322 is also lowered while the lower shielding plate 320a is lowered, Is bent outward from the outer surface of the heartbeat pump (30). 10, the upper shield plate 310a is bent outwardly from the outer surface of the electrostatic pump 30, but at the same time, the second rising and falling ring member 312 is bent, The lower blocking plate 320a is expanded while the lower blocking plate 322 is also lifted.

The lower shielding plate 320a is bent and brought into close contact with the inner surface of the supply pipe 10 in a state where the heart pump 30 having the opening and closing assembly 300 according to the present invention is positioned inside the supply pipe 10 When the lower shielding member 320 closes the gap between the cardiothoracic pump 30 and the inner surface of the supply pipe 10 below the suction port 32, the upper shielding plate 310a is expanded at the same time, The lower shielding plate 320 is opened to open the gap between the heart pump 30 and the inner surface of the supply pipe 10 at the upper portion of the suction port 32, The upper shielding plate 310a is curved so as to be in close contact with the inner surface of the supply pipe 10 so that the upper shielding member 310 is in contact with the inner surface of the supply pipe 10, The gap between the heart pump 30 and the inner surface of the supply pipe 10 is closed at a position above the suction port 32, It will be good.

11 and 12, the process of switching to the heating mode and the cooling mode by changing the fluid flow in the open-loop geothermal heat exchanger having the open / close assembly 300 of the present invention will be described. Fig. 11 is a schematic cross-sectional view corresponding to Fig. 2 showing the state when the open-loop geothermal heat exchanger having the open-and-close assembly 300 of the present invention operates in a heating mode, Lt; RTI ID = 0.0 > 2 < / RTI > In the drawing, arrows in dotted lines indicate the flow of the fluid.

First, referring to FIG. 11, when the building is heated, the fluid that has flowed into the ground through the return pipe 20, like the conventional open-type geothermal heat exchanger, " That is, in the heating mode, the flow conversion device 21 is operated to open the upper inflow pipe 220, but the communication pipe 210 is closed. The upper inflow pipe 220 is opened by the flow converter 21 but the communicating pipe 210 is closed so that the fluid recovered from the heat pump is circulated through the pipe connected to the heat pump, the three-phase valve, and the upper inflow pipe 220 So that the flow of the fluid directly into the supply pipe 10 through the communication pipe 210 is blocked. In this way, the flow converter 21 is operated to control the flow of the fluid recovered through the return pipe 20, and in the heart pump 30, the open / close assembly 300 according to the present invention operates, The lower shielding member 320 closes the gap between the outer surface of the heart pump 30 and the inner surface of the supply tube 10 and the gap between the outer surface of the heart pump 30 and the inner surface of the supply tube 10 Open. That is, in the open / close assembly 300 of the present invention, the upper shielding plate 310a is bent outward and is brought into close contact with the inner surface of the supply pipe 10, so that the gap between the outer surface of the heart pump 30 and the inner surface of the supply pipe 10 The lower shield plate 320a is opened and the gap between the outer surface of the heartbeat pump 30 and the inner surface of the supply tube 10 is opened.

In this state, the fluid flows into the filler material 400 outside the supply pipe 10 through the return pipe connected to the heat pump, the flow converter 31 and the upper inflow pipe 220, And is mixed with ground water and flows into the inside of the supply pipe 10 through the lower inflow hole 11 existing at the lower end of the supply pipe 10 to be filled. The gap between the outer surface of the heart pump 30 and the inner surface of the supply pipe 10 is closed above the suction port 32 of the heart pump 30 by the operation of the opening and closing assembly 300 of the present invention, The gap between the outer surface of the heartbeat pump 30 and the inner surface of the supply tube 10 is opened below the heartbeat pump 32 so that when the heartbeat pump 30 is operated, 32 to be pumped and sent to the heat pump through the delivery pipe 31. That is, when heating is required, the open-type underground geothermal heat exchanger according to the present invention is such that, as in the case of a conventional open-air geothermal heat exchanger, a fluid that is relatively warmer than the surface of the ground is deeply discharged.

On the other hand, when the building is cooled, the open-loop geothermal heat exchanger with the open-and-close assembly 300 of the present invention, unlike the conventional open-loop geothermal heat exchanger, Flow direction ", and the fluid near the surface, which is relatively lower in temperature than the deep underground, is sucked by the centrifugal pump 30 and sent to the heat pump of the building. Specifically, as shown in Fig. 12, in the cooling mode requiring cooling of the building, the flow converter 21 is operated to open the communication pipe 210, but the upper inflow pipe 220 is closed. Therefore, the fluid recovered from the heat pump is directly supplied to the inside of the supply pipe 10 through the return pipe connected to the heat pump, the flow converter 21 and the communicating pipe 210. The flow switching device 21 is operated to control the flow of the fluid recovered through the recovery pipe 20 and the lower blocking member 320 of the openable and closable assembly 300 of the present invention is actuated, 30 and the inner surface of the supply pipe 10 and the upper blocking member 310 opens the gap between the outer surface of the heart pump 30 and the inner surface of the supply pipe 10. [ That is, in the open / close assembly 300 of the present invention, the lower shielding plate 320a is bent outward and brought into close contact with the inner surface of the supply pipe 10 to close the gap between the outer surface of the heart pump 30 and the inner surface of the supply pipe 10 However, the upper shielding plate 310a is opened and the gap between the outer surface of the heartbeat pump 30 and the inner surface of the supply tube 10 is opened.

In this state, the fluid flows directly into the interior of the supply pipe 10 through the return pipe connected to the heat pump, the flow converter, and the communicating pipe 210, and flows downward from the inside of the supply pipe 10 by gravity, And flows out of the supply pipe 10 through the lower inflow hole 11 existing at the lower end of the supply pipe 10 and flows into the filler material 400. Therefore, the recovered fluid flows from the lower side of the filler material 400 to the upper side.

 At this time, the gap between the outer surface of the heart pump 30 and the inner surface of the supply pipe 10 is closed below the suction port 32 of the heart pump 30, but at the upper side of the suction port 32, The fluid near the surface of the filler material 400 flows into the upper inflow hole 12 formed in the upper portion of the supply pipe 10 when the heartbeat pump 30 is operated, So that the fluid in the vicinity of the surface that has entered the supply pipe 10 is sucked into the suction port 32 and is pumped to be sent to the heat pump through the discharge pipe 31. [ In other words, when the cooling is required, the open-loop geothermal heat exchanger according to the present invention pumps the fluid near the surface, which is relatively lower in temperature than the deep underground, to the heat pump 30, . Therefore, in the present invention, the cooling efficiency is greatly improved as compared with the conventional open-type geothermal heat exchanger in which the fluid having a relatively high temperature is delivered to the heat pump even during cooling.

Thus, in the underground heat exchanger equipped with the open / close assembly 300 of the present invention, when the heating of a building or the like is required, the fluid has a "flow pattern from the top to the bottom" However, when cooling of a building or the like is required, the fluid has a "flow shape from the bottom to the upper direction ", so that the fluid near the surface where the temperature is relatively low can be sent to the building heat pump to maximize the cooling efficiency So that not only efficiency at the time of heating but also efficiency at the time of cooling is greatly improved. That is, in the geothermal heat exchanger provided with the open / close assembly 300 of the present invention, the flow direction of the fluid flowing back into the ground is changed again through the return pipe 20, and is sent to the heat pump through the delivery pipe 31 It is possible to maximize the cooling / heating efficiency by operating the heating mode in which the fluid is taken from the deep underground, or in the cooling mode taken in the vicinity of the surface.

10: supply pipe
20: Recovery pipe
30: heart pump
21: Flow converter
210: communicating tube
220: Upper inlet pipe
310: upper side blocking member
320: Lower side blocking member

Claims (3)

An openable and closable assembly (300) mounted on a heart pump (30) disposed in a supply duct (10) of an open-air geothermal heat exchanger,
An upper shielding member 310 provided at an upper position of the suction port 32 of the heartbeat pump 30 to close or open the gap between the heartbeat pump 30 and the inner surface of the supply tube 10, A lower blocking member 320 provided at a lower position of the upper blocking member 310 and the lower blocking member 320 for closing or opening the gap between the heartbeat pump 30 and the inner surface of the supply pipe 10, And an interlocking beam (330) interlocking the interlocking beam (330);
The upper blocking member 310 includes a first retaining ring member 311 and a first ascending / descending ring member 312, and a first retaining ring member 311 and a second retaining ring member 311, The upper shield plate 310a is formed of an elastic member which is installed to surround the outer surface of the heart pump 30 while connecting between the first ascending / descending ring member 312 and the outer surface of the heart pump 30, );
The lower blocking member 320 includes a second lifting ring member 322 and a second fixing ring member 321 which are sequentially disposed at intervals below the suction port 32 of the heartbeat pump 30, And the first and second lifting ring members 321 and 322. The first and second lifting and lowering ring members 321 and 322 are disposed to surround the outer surface of the heart pump 30 and are bent outwardly of the outer surface of the heart pump 30 And a lower shield plate (320a) made of an elastic member to be stretched again;
The interlocking beam 330 connects the first lifting ring member 312 and the second lifting ring member 322 to each other;
When the second rising ring member 322 is lowered, the lower blocking plate 320a is bent and is brought into close contact with the inner surface of the supply pipe 10 to close the gap between the heartbeat pump 30 and the supply pipe 10. At the same time, The first rising ring member 312 also descends while the upper blocking plate 310a is expanded to open the gap between the heartbeat pump 30 and the supply pipe 10;
When the second lift ring member 322 is lifted, the lower shield plate 320a is expanded to open the gap between the heart pump 30 and the supply pipe 10, but at the same time, the first lift ring member 312 also rises And the upper shielding plate 310a is bent so as to be brought into close contact with the inner surface of the supply pipe 10 so as to close the gap between the heart pump 30 and the supply pipe 10. [
The method according to claim 1,
A rotating screw member 35 having an outer threaded portion is provided at a lower portion of the heartbeat pump 30;
The second ascending / descending ring member 322 is screwed to the outer threaded portion of the rotating screw member 35 so that the second ascending / descending ring member 322 ascends and descends in accordance with the rotation of the rotating screw member 35 Wherein the open / close assembly has a configuration.
The method according to claim 1,
A rotating screw member 35 having an outer threaded portion is provided on the upper portion of the heartbeat pump 30;
The first lifting ring member 312 is screwed to the outer threaded portion of the rotating screw member 35;
The first lifting ring member 312 ascends and descends in accordance with the rotation of the rotating screw member 35;
When the first up / down ring member 312 is lowered, the second up / down ring member 322 is lowered, and when the first up / down ring member 312 is raised, the second up / down ring member 322 is also raised And an open / close assembly.

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