KR20150126188A - Thermal energy storage system using depth defference of aquifer - Google Patents

Abstract

The present invention relates to a thermal energy storage heating and cooling system using depth difference of an underground aquifer and, more specifically, relates to a thermal energy storage heating and cooling system using depth difference of an underground aquifer, which can improve thermal efficiency by using depth difference of an underground aquifer having different geothermal heat in accordance with a depth. According to the present invention, a first tubular well and a second tubular well are formed in an alluvial aquifer and a bedrock aquifer which have a different depth to have different geothermal heat, thereby improving heating and cooling efficiency compared to a conventional method by utilizing underground water with a relatively proper temperature in case of heating and cooling.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermal storage and cooling system using a depth difference of an underground aquifer,

The present invention relates to a thermal storage and cooling system of a groundwater aquifer, and more particularly, to a thermal storage heating and cooling system using a depth difference of an underground aquifer which can improve thermal efficiency by using a difference in depth of a groundwater aquifer having different geothermal depths .

In recent years, regenerative heating and cooling systems have been developed to utilize geothermal heat with constant temperature irrespective of seasonal changes as a heat source for heating and cooling.

Such a heat storage system is a method of pumping underground water of an aquifer having a certain geothermal heat and using it as a heat source for cooling or heating through heat exchange through a heat pump and supplying the groundwater after heat exchange to the aquifer to store heat.

Here, the underground aquifer is divided into an alluvial aquifer and a rock aquifer depending on depth.

Alluvial aquifers are composed of sand, gravel, silt, clay, and groundwater containing sedimentary groundwater. The groundwater exists while saturating the pores of the rocks constituting these groundwater layers. The geothermal heat of these alluvial aquifers maintains a constant temperature throughout the year, and ground water of constant water temperature (about 15 ° C) is used for cooling and heating in places where ground water is abundant.

The rock aquifer is a rock layer containing deep water with depths greater than the alluvial aquifer. These rocky aquifers are formed deeper than the depths of alluvial aquifers and therefore have higher geothermal heat than those of alluvial aquifers.

On the other hand, there is an aquifer heat storage cooling / heating system disclosed in Korean Patent Registration No. 10-1021578, which was filed and registered by the applicant of the present invention as a prior art.

As shown in FIG. 1, a cold crystal 10 is formed in a groundwater aquifer as shown in FIG. 1, in which groundwater stored in cold and heat is pumped during cooling in summer, groundwater is taken in heat in winter season to cool and store heat. An on-quartz (20) which is formed at an underground aquifer and is spaced apart by a predetermined distance limited by the cold quartz and the thermal interference, groundwater which is heat-accumulated in the winter season is pumped, groundwater absorbed in the summer cooling is injected, and heat is accumulated; A groundwater conduit 30 for supplying the pumped groundwater to the heat pump from the cold crystal and the on crystal, for collecting the heat-exchanged groundwater from the heat pump, and for injecting the ground water into the on crystal and the cold crystal; And a heat pump (50) for transferring the cold heat of the cold and warm groundwater pumped from the cool quartz for cooling and delivering the heat of the pumped warm groundwater to the heating.

However, since the cold crystal 10 and the on crystal 20 are located in the aquifer of the same depth as shown in FIG. 1, the prior art can not effectively utilize the difference of the geothermal heat due to the depth difference.

Korean Patent Publication No. 10-1021578

The present invention has been made in order to overcome the problems of the prior art as described above, and it is an object of the present invention to provide a geothermal power generation system and a geothermal power generation system, which utilize geothermal heat of alluvial aquifers and rock aquifers having different geothermal depths, It is an object of the present invention to provide a thermal storage heating / cooling system using depth differences of underground aquifers that can improve efficiency.

In addition, it is also possible to use the difference in the depth of the underground aquifers to recover the heat exchanged cool air and heat by heating the ground water heated by the heat exchange in the rock aquifer by heat- The purpose of this is to provide.

In addition, the first aquifer and the second aquifer in the separated state are constructed in the same manner as the alluvial aquifer and the rock aquifer, and a channel connecting the aquifer of the two aquifers with the heat pump is formed in a symmetrical state, It is another object of the present invention to provide a heat storage and cooling /

In order to accomplish the above object, the present invention provides a cooling / heating system using geothermal heat of an underground aquifer including an alluvial aquifer and a rock aquifer having a deeper depth than the alluvial aquifer, A first facility installed in the alluvial aquifer to supply cooling water during cooling, and the heating water cooled by heat exchange during heating is stored in a cold state; A first water pipe extending through the another aquifer which is separated from the first pipe and extending to the rock aquifer and being installed at a deeper depth than the first pipe, And a second conduit in which the cooling water of the first conduit heated by heat exchange during cooling is stored in a hot state; A heat pump for heat-exchanging the cooling water or heating water supplied from the first pipe and the second pipe according to cooling and heating; A first conduit connecting the heat pump and the first conduit to supply the cooling water of the first conduit to the heat pump or the heating water of the second conduit heat-exchanged in the heat pump to the first conduit; A second conduit connecting the heat pump and the second conduit to supply the heating water of the second conduit to the heat pump or the cooling water of the first conduit heat-exchanged in the heat pump to the second conduit; A packer installed in the second well and isolating the alluvial aquifer and the aquifer from each other while passing the second channel through the aquifer; And a second conduit connected to the first conduit and the second conduit respectively in a state where the first conduit and the second conduit are installed respectively, wherein the number of cooling of the first conduit or the number of the conduits of the second conduit is divided by the heat And a supply pump for pumping with the pump.

For example, the first conduit and the second conduit may be connected to the respective supply pumps so that the number of cooling of the first conduit or the number of heating of the second conduit is supplied to the heat pump, tube; And a heat storage tube which is supplied by the pumping pipe and supplies cooling water or heating water heat-exchanged in the heat pump to the second pipe or the first pipe.

The pumping pipe may be formed to have a diameter smaller than that of the heat storage tube and to be accommodated in the heat storage tube and to have a double pipe shape together with the heat storage tube, Can be connected to the end of the tube.

The first conduit and the second conduit may further include a clog prevention communication path for communicating the cooling water or the heating water to a part of the heat storage tube while preventing clogging of the heat storage tube end.

For example, the clog-prevention communication path may include a plurality of communication slits formed in a slot-like clearance along the outer peripheral surface on the end side of the heat storage tube and communicating the number of cooling water and the number of heating water to the heat storage tube.

According to the present invention, the first well is constructed so as to be deeper than the alluvial aquifer and extended to the rock aquifer, and is constructed in the same shape as the second well, and the rock water aeration of the first well is connected to the heat pump, And supplying the heating water of the rock aquifer extended in the first duct to the heat pump or supplying the cooling water of the second duct heat-exchanged in the heat pump to the rock aquifer of the first duct in a symmetrical state with the second duct, A third conduit for storing heat by heating; The heat pump is connected to the alluvial aquifer of the second conduit and is symmetrical to the first conduit while supplying the cooling water of the alluvial aquifer constituting the second conduit to the heat pump, A fourth conduit for supplying the heating water of the first conduit to the alluvial aquifer of the second conduit, which is supplied to the heat pump and heat- An additional supply pump connected to the third conduit and the fourth conduit to pump the heating water of the first conduit or the cooling water of the second conduit to the heat pump according to cooling and heating; And an additional packer for inserting the third duct into the rock aquifer of the first duct while isolating the alluvial aquifer of the first duct from the aquifer aquifer.

In the thermal storage and cooling system using the depth difference of the underground aquifers according to the present invention, the first and second reservoirs are formed in the alluvial aquifer and the rock aquifer having different depths, Accordingly, the utilization efficiency of the cooling and heating efficiency can be improved by using the ground water having a relatively suitable temperature in the heating and cooling.

In addition, since the heat or cold heat of the groundwater exchanged in the heat pump is collected and collected in the allotment aquifer or the rock aquifer of another facility, the recovered cool air or heat can be recycled without loss.

Furthermore, since the heat accumulating pipe and the pumping pipe constituting the pipe are formed in the form of a double pipe, the volume of the pipe is reduced, so that the workability of the pipe can be improved.

In addition, since the communication slit constituting the clogging prevention communication path is formed on the outer circumferential surface of the heat storage tube, the ground water can be communicated even when the end of the heat storage tube is clogged.

In addition, as the alluvial aquifer and the rock aquifer constituting the reservoir are isolated by the packers, groundwater in each aquifer is not mixed, so that the chilled air or heat stored in each aquifer can be maintained.

The first aquifer is extended to the rock aquifer in the same way as the second aquifer, and the aquifers of the two reservoirs are symmetrically connected to the heat pump by the pipelines. Therefore, groundwater is simultaneously pumped and heat exchanged in the same aquifer of both reservoirs The cooling / heating capacity can be improved.

1 is a front view showing the construction of a crane according to the prior art;
BACKGROUND OF THE INVENTION Field of the Invention [0001]
Fig. 3 is a perspective view showing the piping shown in Fig. 2; Fig.
4 is a configuration diagram showing another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted.

As shown in FIG. 2, the thermal storage heating / cooling system using the depth difference of the underground aquifers according to the present invention includes a first conduit 10, a second conduit 20, a heat pump 30, a first conduit 100, 2 pipe 200 and a feed pump 40. The feed pump 40 may be a two-

As shown in FIG. 2, the first conduit 10 is installed in the allotment aquifer 1 having a depth lower than that of the rock aquifer 2.

That is, since the first conduit 10 is installed in the allotment aquifer 1 having a temperature lower than that of the rock aquifer 2, the first conduit 10 provides a relatively low temperature of cooling water during cooling.

The first conduit 10 may be shielded by a cover (not shown), and a grouting portion 10a may be formed in the upper (ground) portion to prevent groundwater or foreign matter from entering the ground surface.

Also, as shown in FIG. 1, the first conduit 10 may be formed by forming a strainer portion 10b in the form of a net in the lower portion of the grouting portion 10a to filter foreign matter.

In the meantime, the first conduit 10 is supplied with the heating water of the second conduit 20, which is cooled by the heat exchange of the heat pump 30 in the state supplied from the second conduit 20, which will be described later, And stored.

As shown in FIG. 2, the second conduit 20 supplies the heating water at a relatively high temperature in the winter season. The second conduit 20 is separated from the first conduit 10 by a depth greater than that of the first conduit 10, (1) and the rock aquifer (2).

Since the second conduit 20 is installed in the rock aquifer 2 having a higher temperature than the allotment aquifer 1, the second conduit 20 provides heating water at a temperature higher than that of the first conduit 10 at the time of heating.

That is, the alluvial aquifer 1 provides cooling water during cooling and the rock aquifer 2 provides heating water during heating.

The heat pump 30 is connected to the first conduit 10 and the second conduit 20 through pipelines 100 and 200 to be described later to heat-exchange the cooling water or heating water with a separate heating medium according to the cooling / Exchanged cooling water or heating water.

Such a heat pump 30 may be applied to any configuration known in the art to which the present invention belongs.

For example, the heat pump 30 may include a plurality of heat exchangers that act as a condenser or an evaporator in the cooling / heating mode, a compressor that compresses the refrigerant and provides the refrigerant to a heat exchanger serving as a condenser, and a refrigerant that passes through the heat exchanger And an expansion valve provided for the expansion valve.

The first conduit 100 is a component for connecting the heat pump 30 and the first conduit 10 to supply the cooling water of the first conduit 10 to the heat pump 30 during cooling, The heating water of the second conduit 20, which is heat-exchanged in the pump 30, is supplied to the first conduit 10 for storage.

The second conduit 200 is a component for connecting the heat pump 30 and the second conduit 20 to supply the heating water of the second conduit 10 to the heat pump 30 during heating, The cooling water of the first conduit 10 to be heat-exchanged in the pump 30 is supplied to the second conduit 20 for storage.

Here, the first conduit 100 and the second conduit 200 may include a pumping conduit 110 and a heat storage conduit 120, as shown in FIG.

The pumping pipe 110 supplies the cooling water and the heating water of the pipes 10 and 20 to the heat pump 30 in accordance with the pumping of the supply pump 40 to be described later.

The heat storage tube (120) supplies cooling water and heating water discharged from the heat pump (30) to the respective tubes (10) (20) in the state of heat exchange and accumulates the heat.

That is, the cooling water located in the alluvial aquifer 1 of the first conduit 10 is pumped through the pumping pipe 110 of the first conduit 100 during cooling and is supplied to the heat pump 30 for heat exchange, Is supplied to the rock aquifer (2) of the second conduit (20) through the heat storage pipe (120) of the second conduit (200)

The heating water located in the rock aquifer 2 of the second conduit 20 is pumped through the pumping pipe 110 of the second conduit 200 during heating and supplied to the heat pump 30 for heat exchange, Is supplied to the alluvial aquifers (1) of the first conduit (10) through the heat storage tube (120) of the first conduit (100) and stored.

The supply pump 40 is connected to the pumping pipe 110 of the first pipe 100 and the second pipe 200 as shown in Figure 2 and is connected to the first pipe 10 and the heating water of the second conduit 20 are pumped to the heat pump 30.

Such a supply pump 40 can be applied to a conventional configuration known in the art to which the present invention belongs, and thus a detailed description thereof will be omitted.

3, the pumping pipe 110 may have a diameter smaller than that of the heat storage tube 120 and may be formed as a double tube together with the heat storage tube 120. [

That is, the heat storage tube 120 moves the cooling water or the heating water through the space separated from the pumping pipe 110 while receiving the pumping pipe 110.

3, the first conduit 100 and the second conduit 200 may be provided with an anti-clogging communication path 130 at the ends of the heat storage tubes 120, respectively.

The clog-preventing communication path 130 is a component for preparing the case where the end of the heat storage tube 120 is clogged.

The heat storage tube 120 is formed of a tubular body having an open end so that when the end portion is clogged as the pumping tube 110 is received, the groundwater supplied from the heat pump 30 is communicated and supplied to the pumping tube 110 It becomes impossible to communicate groundwater.

The clogging prevention communication path 130 prevents the clogging of the heat storage tube 120 by communicating the number of cooling water and the number of heating water as a part except for the end portion of the heat storage tube 120.

For example, the clog-preventing communication path 130 may include a communication slit 131 formed along the outer circumferential surface on the end side of the heat storage tube 130 as shown in FIG.

The communication slit 131 is formed along the outer circumferential surface of the heat storage tube 120 while being formed as a slot-like gap as shown in the figure, so that even when the end of the heat storage tube 120 is clogged,

Meanwhile, the present invention may further include a packer 50 as shown in FIG.

The packer 50 is a component that penetrates the second channel 200 into the rock aquifer 2 while isolating the alluvial aquifer 1 and the rock aquifer 2 from each other.

That is, the packer 50 shields the interface between the alluvium aquifer 1 and the aquifer aquifer 2 to prevent the groundwater of the two layers from mixing.

The packer 50 may be formed of, for example, a hollow body and may be configured to penetrate the second conduit 200 to block the interface of the second conduit 20 while being expanded by a filler filling the interior of the second conduit 200. In addition, Known configurations can be applied to the field to which they belong.

4, the first conduit 10 is extended to the rocky aquifers layer 2 in the same manner as the second conduit 20, and the third conduit 300, the fourth conduit 400, , An additional feed pump 40 'and an additional packer 50'.

That is, the first vessel 10 may be extended to the rock aquifer 2 as shown in FIG. 4, and the interface may be shielded by the additional packer 50 '.

The third conduit 300 is symmetrical with the second conduit 200 and connects the rock aquifer 2 of the first conduit 10 to the heat pump 30 as shown in FIG. 10 is supplied to the heat pump 30 and the cooling water having been heat-exchanged by the heat pump 30 during cooling is supplied to the rock aquifer 2 of the first duct 10 And store it.

The fourth duct 400 is symmetrical with the first duct 100 and connects the allotment aquifer 1 of the second duct 20 to the heat pump 30 as shown in FIG. 20 is supplied to the heat pump 30 and the heating water heat exchanged in the heat pump 30 is supplied to the alluvial aquifers layer 1 of the second conduit 20 And store it.

The third and fourth conduits 300 and 400 may include a pumping pipe 110 and a heat accumulating pipe 120 in the same manner as the conduits 100 and 200 described above, The cooling water or the heating water is supplied by the operation of the additional supply pump 40 '.

The third duct 300 and the fourth duct 400 are symmetrically arranged with the second duct 200 and the first duct 100 so that the ducts 300 and 400 are symmetrical with respect to the second duct 200 and the first duct 100, 20) by simultaneously moving the groundwater located in the same aquifer layer.

The operation and operation of the present invention including the above-described components will be described.

When the heat pump 30 is in the cooling mode, the number of cooling water located in the alluvial aquifers 1 of the first and second wells 10 and 20 is controlled by the operation of the supply pumps 40 and 40 ' And is supplied to the heat pump 30 through the pumping pipe 110 of the first conduit 100 and the fourth conduit 400.

The cooling water heated and heat-exchanged in the heat pump 30 flows through the first pipe 10 and the second pipe 20 through the second pipe 200 and the heat storage pipe 120 of the third pipe 300, The aquifer is supplied to the rock aquifer 2 and stored.

When the heat pump 30 is in the heating mode, the heating water located in the rock aquifer 2 of the first and second tunnels 10 and 20 is heated by the operation of the supply pumps 40 and 40 ' And is supplied to the heat pump 30 through the pumping pipe 110 of the second pipe 200 and the third pipe 300.

The cooling water that has been heat-exchanged and cooled by the heat pump 30 flows through the first pipe 10 and the second pipe 20 through the first pipe 100 and the heat pipe 120 of the fourth pipe 400, And is stored in the aquifer 1.

As described above, according to the thermal storage and cooling system using the depth difference of the underground aquifers according to the present invention, the first aquarium 10 and the second aquarium 20 have an alluvial aquifer 1 and a rock aquifer 2, And the groundwater having a relatively suitable temperature at the time of cooling and heating is used as the groundwater has different geothermal heat, so that the cooling and heating efficiency can be improved compared with the conventional method.

In addition, since the cold heat or the heat of the heat-exchanged groundwater in the heat pump 30 is collected and recovered in the other alluvial aquifer 1 or the rock aquifer 2, the recovered cool air or heat can be recycled without loss.

In addition, since the heat accumulation pipe 120 and the pumping pipe 110 constituting the conduits 100 and 200 are formed in the form of a double pipe, the volume of the conduit is reduced, so that the workability of the conduit can be improved.

In addition, since the communication slit 131 constituting the clog-preventing communication path 130 is formed on the outer circumferential surface of the heat storage tube 120, the groundwater can be communicated even when the end of the heat storage tube 120 is clogged.

Since the aquifer aquifer 1 and the rock aquifer 2 constituting the canisters 10 and 20 are isolated by the packer 50 and groundwater of each aquifer 1 and 2 is not mixed, 1) and (2).

The first aquifer 10 is extended to the rock aquifer 2 in the same manner as the second aquifer 20 and the aquifers 1 and 2 of the two canisters 10 and 20 are symmetrically disposed in the ducts The groundwater is pumped and heat-exchanged in the same aquifer of both the tanks 10 and 20 at the time of cooling and heating, and is then recovered at the time of cooling and heating, .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made therein without departing from the spirit of the invention.

1: Alluvial aquifer 2: Rock aquifer
10: first view 20: second view
30: Heat pump 40, 40 ': Feed pump
50, 50 ': Packer 100: First channel
110: pumping pipe 120: heat storage pipe
130: clog prevention communication path 131: communication slit
200: second conduit 300: third conduit
400: fourth pipe

Claims (4)

1. An air-conditioning system using geothermal heat of an underground aquifer including an alluvial aquifer and a rock aquifer having a depth deeper than the alluvial aquifer,
A first facility installed in the alluvial aquifer to supply cooling water during cooling, and the heating water cooled by heat exchange during heating is stored in a cold state;
A first water pipe extending through the another aquifer which is separated from the first pipe and extending to the rock aquifer and being installed at a deeper depth than the first pipe, And a second conduit in which the cooling water of the first conduit heated by heat exchange during cooling is stored in a hot state;
A heat pump for heat-exchanging the cooling water or heating water supplied from the first pipe and the second pipe according to cooling and heating;
A first conduit connecting the heat pump and the first conduit to supply the cooling water of the first conduit to the heat pump or the heating water of the second conduit heat-exchanged in the heat pump to the first conduit;
A second conduit connecting the heat pump and the second conduit to supply the heating water of the second conduit to the heat pump or the cooling water of the first conduit heat-exchanged in the heat pump to the second conduit;
A packer installed in the second well and isolating the alluvial aquifer and the aquifer from each other while passing the second channel through the aquifer; And
And a second conduit connected to the first conduit and the second conduit respectively in a state where the first conduit and the second conduit are installed respectively and the number of cooling of the first conduit or the number of conduits of the second conduit is connected to the heat pump And a supply pump for pumping the water to the groundwater aeration tank.
The method according to claim 1,
Wherein the first conduit and the second conduit are connected to each other,
A pumping pipe connected to the respective supply pumps for supplying the number of cooling of the first pipe or the number of heating pipes of the second pipe to the heat pump according to the pumping of the supply pump; And
And a heat storage tube that is supplied by the pumping pipe and supplies cooling water or heating water heat-exchanged in the heat pump to the second pipe or the first pipe,
The pumping tube includes:
A tube having a diameter smaller than that of the heat storage tube and being accommodated in the heat storage tube and forming a double tube together with the heat storage tube,
Wherein the feed pump comprises:
And is connected to an end of the pumping pipe while being accommodated in the heat storage pipe.
The method of claim 2,
Wherein the first conduit and the second conduit are connected to each other,
And a clog prevention communication passage for communicating the cooling water and the heating water to a part of the heat storage tube while preventing clogging of the heat storage tube end,
The clog-
And a plurality of communication slits formed in a slit-like clearance along an outer circumferential surface of the end portion of the heat storage tube and communicating the number of cooling water and the number of heating water to the heat storage tube.
The method according to claim 1,
The system comprises:
The first well is constructed so as to be deeper than the alluvial aquifer and extending to the rock aquifer,
Wherein the heat pump is connected to the rock aquifer of the first conduit and is symmetrical with the second conduit while supplying the heating water of the rock aquifer extended to the first conduit to the heat pump, A third conduit for supplying the cooling water of the second conduit to the rock aquifer of the first conduit to heat the conduit;
The heat pump is connected to the alluvial aquifer of the second conduit and is symmetrical to the first conduit while supplying the cooling water of the alluvial aquifer constituting the second conduit to the heat pump, A fourth conduit for supplying the heating water of the first conduit to the alluvial aquifer of the second conduit, which is supplied to the heat pump and heat-
An additional supply pump connected to the third conduit and the fourth conduit to pump the heating water of the first conduit or the cooling water of the second conduit to the heat pump according to cooling and heating; And
Further comprising an additional packer for inserting the third channel into the rock aquifer of the first channel while isolating the at least one alluvial aquifer and the at least one aquifer aquifer of the first channel.

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