KR101020070B1 - Bank filtrtion use geothermal system that consider position special quality - Google Patents

Abstract

PURPOSE: A bank-filtered water used geothermal air-conditioning apparatus considering location properties is provided to maximize the thermal efficiency of a heat exchanger by preventing the reduction of thermal efficiency of bank-filtered water in a well. CONSTITUTION: A bank-filtered water used geothermal air-conditioning apparatus considering location properties comprises a well(10), a intake pipe(11), a submerged pump(13), a heat exchanger(14), a supply pipe(15), an inlet well(16), an outlet conduit(17), and a discharge pipe(19). The intake pipe is installed inside the well and equipped with a strainer(12) which underground bank-filtered water flows in. The submerged pump is installed in the intake pipe and pumps out the bank-filtered water which is thermally restored by being delivered along the intake pipe. The heat exchanger is installed in an indoor space and connected to the submerged pump in order to cool or heat the indoor space using the bank-filtered water provided by the submerged pump. The supply pipe is connected to the heat exchanger and the submerged pump in order to supply the bank-filtered water of the intake pipe to the heat exchanger. The inlet well prevents the heat-lost bank-filtered water from flowing into the well.

Description

Bank filtrtion use geothermal system that consider position special quality}

The present invention relates to a geothermal heating and cooling system using a riverside filtration in consideration of the location characteristics, more specifically, the low-efficiency riverside filtration water is prevented from flowing into the intake well side, only the high-efficiency riverside filtration water is introduced into the intake well side, groundwater depletion is prevented The present invention relates to a geothermal heating and cooling system using riverside filtration.

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

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

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

Another problem with such geothermal systems is that they need to dig deeper into the geothermal pores in order to increase thermal efficiency. The deeper the geothermal hole is sold, the higher the thermal efficiency, but the construction cost increases. Geothermal construction is the largest part of the construction cost of geothermal systems, and the deeper the geothermal hole, the higher the construction cost of geothermal systems.

On the other hand, when ground heat is repeatedly circulated through the geothermal hole and heat exchanger, when the heat recovery power is lowered, some groundwater is discharged to the outside so that the groundwater in the ground is introduced as much as the discharged groundwater. However, this method leads to depletion of groundwater in the long term, making it impossible to operate the geothermal system.

An object of the present invention for solving the above-mentioned problems is to provide a geothermal heating and cooling system using a riverside filtration in consideration of the location characteristics that prevents the low-efficiency riverside filtration water from flowing into the intake well side and only the high-efficiency riverside filtration water flows into the intake well side.

Another object of the present invention is to provide a geothermal heating and cooling system using riverside filtration considering the location characteristics to prevent the groundwater exhaustion.

It is still another object of the present invention to provide a geothermal heating and cooling system using riverside filtration in consideration of the positional characteristics of the riverside filtration water flowing smoothly into the intake well side.

In order to achieve the above object, the geothermal heating and cooling system using the riverside filtration water in consideration of the positional characteristics of the present invention is formed so that the intake well and the injection well are spaced in the ground where the riverside filtration water flows, and the inflow well is supplied with the upstream side riverside filtration water to the heat exchanger. The supply pipe is connected to the injection pipe, and the discharge pipe is connected to the injection well to discharge the riverside filtration water through the heat exchanger, so that the heat lost riverside filtration water flowing into the injection well is prevented from entering the intake well side. It is formed on the upstream side, and the injection well is characterized in that it is formed on the downstream side of the ground flowing riverside filtration.

Another feature of the riverside filtration-use geothermal heating and cooling apparatus considering the location characteristics of the present invention includes: a water well formed on an upstream side of the ground through which the riverside filtration water flows; An inlet pipe installed inside the intake well and formed with a strainer such that riverside filtration water in the underground flows; An underwater motor pump installed inside the inflow pipe to guide the lower side along the inflow pipe to heat the restored riverside filtrate; A heat exchanger installed in the room and connected to the submersible motor pump to heat and cool the room using the riverside filtration water supplied therefrom; A supply pipe connected to the heat exchanger and the submersible motor pump to supply the riverside filtered water inside the inlet pipe to the heat exchanger side; An injection well formed on the downstream side of the ground through which the riverside filtration water is prevented from flowing into the intake well side when the heat lost riverside filtration water is discharged; Discharge pipe is installed inside the injection well to prevent the loss of the empty wall of the injection well formed strainer to discharge the river filtration water flowing into the injection well into the ground; It is characterized in that it comprises a discharge pipe connected to the heat exchanger and the discharge pipe for discharging the riverside filtered water via the heat exchanger to the discharge pipe.

Another feature of the riverside filtration-use geothermal heating and cooling apparatus considering the positional characteristics of the present invention is that a water collecting space is formed around the intake well so that the riverside filtration water in the ground is guided around the intake well.

Another feature of the geothermal heating and cooling system using the riverside filtration water in consideration of the location characteristics of the present invention, the filter is built in the catchment space so that the strainer of the inlet pipe is not blocked by the riverside filtration water flowing into the inlet pipe, the filter is made of gravel.

Another feature of the geothermal heating and cooling system using the riverside filtration water in consideration of the positional characteristics of the present invention, the catchment space is formed in the middle of the intake well, the bottom surface of the catchment space flows into the catchment space to the lower side of the intake well It is formed to be inclined downward so as to be induced.

The geothermal heating and cooling system using the riverside filtration water in consideration of the positional characteristics of the present invention, the strainer of the inlet pipe is formed only around the inlet pipe corresponding to the upstream side so that the riverside filtration water flowing from the upstream to the inlet pipe side smoothly flows into the inlet pipe. The strainer of the discharge pipe is formed only around the discharge pipe corresponding to the downstream side so that the riverside filtration water discharged into the discharge pipe is prevented from being discharged to the inlet pipe side and discharged only to the downstream side.

In the present invention as described above, the water well is formed on the upstream side of the river flow water flowing through the river side filtration water, the injection well is formed on the underground downstream side of the river side filtration water to prevent the heat loss of the riverside filtration water flowing into the injection well flows into the intake well side Is formed. Therefore, the riverside filtration of the ground flows from the intake well to the injection well, so that the riverside filtration flowed into the well is discharged in the opposite direction of the well, so it does not affect the riverside filtration of the well. Therefore, the riverbank filtrate on the injection well side, which has low thermal efficiency, does not flow into the riverbank filtrate side on the intake well, so that the thermal efficiency of the riverbank filtrate in the well is not reduced, thereby maximizing the thermal efficiency of the heat exchanger.

The present invention is to discharge the riverside filtration water supplied from the intake well to the heat exchanger side to the intake well without being recovered back to the intake well, but the flow characteristics of the riverside filtration water flowing in the ground and the position characteristics of the intake well and the injection well Consideration should be made to ensure that the water wells are not affected. Therefore, the thermal efficiency of the riverside filtration water flowing into the intake well is not deteriorated, and the riverside filtration water passing through the heat exchanger is discharged to the vicinity of the intake well again to prevent depletion of groundwater.

At the periphery of the well, a collection space is formed so that river-side filtration in the ground is guided around the well. Therefore, underground river filtration is smoothly introduced into the catchment space around the well, thus increasing the catchment capacity of the well.

The strainer of the inflow pipe is formed only on a part of the circumference of the inflow pipe opposite to the upstream, and the strainer of the discharge pipe is formed only on a part of the circumference of the discharge pipe opposite to the downstream. Therefore, the riverside filtration water flowing from the upstream side to the inflow pipe flows smoothly into the inflow pipe through the strainer of the inflow pipe facing upstream, but the riverside filtration water from the downstream side does not flow into the inflow pipe. In addition, the riverside filtered water flowing into the discharge pipe is discharged to the downstream side through the strainer of the discharge pipe facing downstream, but is not discharged to the intake well side. Therefore, due to the unique structure of the inlet pipe installed in the intake well and the discharge pipe installed in the injection well, heat exchange is prevented between the riverside filtration water on the intake well side and the riverside filtration water on the intake well side, thereby increasing the thermal efficiency of the heat exchanger.

1 is a schematic cross-sectional view showing a geothermal heating and cooling system using a river filtration considering the positional characteristics of the present invention
Figure 2 is a schematic partial cross-sectional view showing a state in which the collection space is formed around the water intake well
3 and 4 are schematic partial cross-sectional view showing another embodiment of the collecting space
5 is a schematic plan view showing another embodiment of the inlet and outlet pipes;

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

1 is a schematic cross-sectional view showing a geothermal heating and cooling system using a riverside filtration in consideration of the positional characteristics of the present invention, which is formed so that the intake well 10 and the injection well 16 are spaced apart in the ground through which the riverside filtration water flows. The supply pipe 15 is connected to supply the upstream side riverside filtered water to the heat exchanger 14, and the discharge pipe 19 is discharged to the injection well 16 to discharge the riverside filtered water via the heat exchanger 14. It is connected.

In the present invention, the water well 10 is formed on the upstream side of the underground flow through the river filtration, so that the heat loss of the river filtration flowing into the injection well 16 is prevented from flowing to the intake well 10 side, the injection well 16 ) Is formed on the downstream side of the ground where riverside filtration flows.

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

A water intake well 10 is formed on an upstream side of the ground through which riverside filtration water flows.

An inlet pipe 11 having a strainer 12 formed therein is installed in the intake well 10 so that the riverside filtrate in the ground flows in.

An underwater motor pump 13 is installed inside the inlet pipe 11 to pump the heat-restored riverside filtrate while being guided downward along the inlet pipe 11 to the outside.

A heat exchanger (14) is installed in the room, and the heat exchanger (14) is connected to the submersible motor pump (13) to cool and heat the room using the riverside filtered water supplied therefrom.

The supply pipe 15 is connected to the heat exchanger 14 and the submersible motor pump 13, and the supply pipe 15 supplies the river filtration water inside the inflow pipe 11 to the heat exchanger side.

An injection well 16 is formed on the downstream side of the ground through which riverside filtration water flows. The injection well 16 is formed on the downstream side of the ground to prevent the loss of the riverside filtered water from being introduced into the intake well 10.

The discharge pipe 17 is installed inside the injection well 16. The discharge pipe 17 is formed with a strainer 18 to prevent the loss of the wall of the injection well 16 and to discharge the river filtration water flowing into the injection well 16 into the ground.

A discharge pipe 19 is connected to the heat exchanger 14 and the discharge pipe 17. The discharge pipe 19 discharges the riverside filtered water via the heat exchanger 14 to the discharge pipe 17.

The geothermal heating and cooling system using the riverside filtration in consideration of the positional characteristics of the present invention having such a configuration is operated as follows.

The riverside filtration water flowing into the ground flows from the upstream to the downstream side and passes through the intake well 10 formed on the upstream side. The riverside filtered water passing through the intake well 10 is introduced into the inlet pipe 11 through the strainer 12 of the inlet pipe 11.

In this state, when the submersible motor pump 13 and the heat exchanger 14 are operated by operating a controller (not shown), the groundwater below the intake well 10 is sucked into the inlet pipe 11 and then heat exchanged through the supply pipe 15. Supplied to the unit 14.

The ground water supplied to the heat exchanger 14 is heat exchanged by the heat exchanger 14 and then discharged to the injection well 16 through the discharge pipe 19. River filtration water discharged to the injection well 16 is discharged to the ground through the strainer 18 of the discharge pipe (17).

The riverbank filtrate discharged to the ground is a state in which thermal efficiency is reduced while passing through the heat exchanger (14), and the riverbank filtrate is heat-restored by the ground heat as it is discharged to the ground.

On the other hand, the riverbank filtration water in the ground flows from the upstream to the downstream side, the riverbank filtration water discharged through the injection well 16 flows to the downstream side without going upstream.

The geothermal heating and cooling system using the riverside filtration in consideration of the positional characteristics of the present invention has the following advantages.

In the present invention, the water extraction well 10 is formed on the upstream side of the underground flow where the riverside filtration flows so that the heat lost riverside filtration flowing into the injection well 16 is prevented from entering the intake well 10. Riverside filtrate is formed on the downstream side of the ground.

Therefore, the river filtration in the ground flows from the intake well 10 to the injection well 16 side, so the riverside filtration flowed into the injection well 16 is discharged in the opposite direction of the intake well 10, It will not affect.

Therefore, since the riverbank filtration on the injection well 16 side, which has low thermal efficiency, does not flow into the riverbank filtration side of the intake well 10, the thermal efficiency of the riverbank filtration in the well 10 is not lowered, and thus the thermal efficiency of the heat exchanger 14 is reduced. Can be maximized.

In addition, the present invention is supplied to the heat exchanger 14 in the intake well 10 to discharge the riverside filtered water that has undergone heat exchange into the ground around the intake well 10 through the injection well 16 without again being recovered to the intake well 10. Here, in consideration of the flow of the riverside filtration water flowing in the ground and the position characteristics of the intake well 10 and the injection well 16 is discharged so as not to be affected by the intake well 10.

Therefore, the thermal efficiency of the riverside filtration water flowing into the intake well 10 is not lowered, and the riverside filtration water passing through the heat exchanger 14 is discharged to the periphery of the intake well 10 again to prevent depletion of groundwater.

Figure 2 is a schematic partial cross-sectional view showing another embodiment of the present invention, the catchment space 20 is formed in the periphery of the water well 10 so that the riverside filtration of the ground is guided around the water well 10. Here, the collecting space 20 is formed over the entire circumference of the water extraction well 10.

Therefore, the riverside filtration of the ground smoothly flows into the water collecting space 20 around the water intake well 10, thereby increasing the water collecting capacity of the water well 10.

In the water collecting space 20, a filter 21 is incorporated so that the strainer 12 of the inflow pipe 11 is not blocked by the riverside filtered water flowing into the inflow pipe 11. The filter 21 is made of gravel.

The present invention is introduced into the strut 12 of the inlet pipe 11 after passing through the filter 21 made of gravel, the riverside filtered water introduced into the collecting space (20). Therefore, the relatively thick foreign matter is filtered by the gravel to prevent the problem that the strainer 12 of the inlet pipe 11 is blocked by the foreign matter.

FIG. 3 is a schematic partial cross-sectional view showing another embodiment of the water collecting space 22. The water collecting space 22 is formed only at the center of the periphery of the water collecting well 10, and thus the water collecting well 10 as shown in FIG. Construction time and construction cost are reduced compared with when it is formed in the whole perimeter.

The catchment space 22 has a filter 21 built therein so that the strainer 12 of the inlet pipe 11 is not blocked by the riverside filtered water flowing into the inlet pipe 11, and the riverside flowed into the catchment space 22. After the filtered water passes through the filter 21 made of gravel, the filtered water flows into the stator 12 of the inlet pipe 11.

4 is a schematic partial cross-sectional view showing another embodiment of the water collecting space 23. The water collecting space 23 is formed in the middle of the water extraction well 10, and the bottom surface 24 of the water collecting space 23 is shown in FIG. The riverside filtration flowing into the collecting space 23 is formed to be inclined downward so as to be directed to the lower side of the intake well 10.

Therefore, the riverside filtration water introduced into the collecting space 23 passes through the filter 21 made of gravel and then flows into the stator 12 of the inlet pipe 11, so that the bottom surface 24 of the collecting space 23 is downward. Since it is formed to be inclined, the riverside filtered water introduced into the collecting space 23 is led to the circumferential side of the inflow pipe (11).

Therefore, the riverside filtration water introduced into the collecting space 23 flows along the bottom surface 24 and is led to the circumferential side of the inflow pipe 11, and thus is smoothly collected into the inflow pipe 11 through the strainer 12.

5 is a schematic cross-sectional view showing another embodiment of the inflow pipe 25 and the outflow pipe 27, in which the strainer 26 of the inflow pipe 25 is formed only in a part of the circumference of the inflow pipe 25 facing upstream The strainer 28 of the discharge pipe 27 is formed only in a part of the circumference of the discharge pipe 27 facing downstream.

Therefore, the riverside filtered water flowing from the upstream side to the inlet pipe 25 flows smoothly into the inlet pipe 25 through the strainer 26 of the inlet pipe 25 facing the upstream, but the riverside filtered water on the downstream side is the inlet pipe ( 25) Does not flow into the interior.

In addition, the riverside filtered water flowing into the discharge pipe 27 is smoothly discharged to the downstream side through the strainer 28 of the discharge pipe 27 facing downstream, but is not discharged to the intake well 10 side.

Therefore, due to the unique structure of the inlet pipe 25 installed in the intake well 10 and the discharge pipe 27 installed in the intake well 16, the riverside filtrate on the intake well 10 side and the riverside filtrate on the intake well 16 side are provided. Heat exchange may be prevented, thereby further increasing the thermal efficiency of the heat exchanger 14.

10: intake well 11,25: inlet pipe
12,18,26,28: strainer 13: submersible motor pump
14: heat exchanger 15: supply pipe
16: injection well 17,27: discharge pipe
19: discharge pipe 20,22,23: collecting space
21 filter 24 bottom surface

Claims (6)

delete A water intake well 10 formed on an upstream side of the ground through which riverside filtration water flows;
An inlet pipe (11) (25) installed in the intake well (10) and formed with strainers (12) and (26) so as to introduce river-side filtrate in the ground;
An underwater motor pump 13 installed inside the inflow pipes 11 and 25 to pump the heat-restored riverside filtrate while being guided downward along the inflow pipes 11 and 25 to the outside;
A heat exchanger (14) installed in the room and connected to the submersible motor pump (13) for cooling and heating the room using the riverside filtered water supplied therefrom;
A supply pipe 15 connected to the heat exchanger 14 and the submersible motor pump 13 to supply the riverside filtered water inside the inlet pipes 11 and 25 to the heat exchanger side;
An injection well 16 formed on a downstream side of the ground through which the riverside filtration water is prevented from flowing into the intake well 10 side when the heat lost riverside filtration water is discharged;
Discharge pipe 17 is provided inside the injection well 16, the strainer 18, 28 is formed to prevent the loss of the empty wall of the injection well 16 and to discharge the river filtration water flowing into the injection well 16 to the ground (27);
A discharge pipe (19) connected to the heat exchanger (14) and the discharge pipes (17) (27) to discharge the riverside filtered water via the heat exchanger (14) to the discharge pipes (17) (27);
The water well 10 is formed upstream of the underground flow where the riverside filtration water flows, so that the riverside filtration water lost to the injection well 16 is prevented from entering the intake well 10 side. A geothermal heating and cooling system using riverside filtration considering the positional characteristics, characterized in that formed on the downstream side of the flowing underground. The method of claim 2,
In the periphery of the water intake well 10, a water collecting space 20 is formed such that the riverside filtrate in the ground is guided around the water intake well 10;
In the collecting space 22, the filter 21 is built so that the strainer 12 of the inlet pipe 11 is not blocked by the river filtration water flowing into the inlet pipe 11, but the filter 21 is made of gravel. Geothermal heating and cooling system using riverside filtration considering location characteristics. delete delete The method of claim 2,
The strainer 26 of the inflow pipe 25,
It is formed only in the periphery of the inlet pipe 25 corresponding to the upstream side so that the riverside filtration water flowing from the upstream to the inlet pipe 25 side smoothly flows into the inlet pipe 25,
The strainer 28 of the discharge pipe 27,
Position characteristic characterized in that the riverbank filtration water discharged into the discharge pipe 27 is formed only on the circumference of the discharge pipe 27 corresponding to the downstream side to prevent discharge to the inlet pipe 25 side and discharged only to the downstream side. Geothermal heating and cooling system using riverside filtration considering

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