KR100818955B1 - A cooling and heating system using geothermal - Google Patents

Abstract

A cooling and heating system using geotherm is provided to cool or heat a building using geotherm by forming a collection part having a vacuum state to collect air introduced from the underground which has a temperature different from that of the surface of the earth. A cooling and heating system using geotherm comprises an indoor unit(100), a heat exchanger(200), a duct(300), and a fan(400). The indoor unit is installed in a building to discharge air. The heat exchanger is buried in the earth at a predetermined depth from the surface of the earth. The duct connects between the heat exchanger and the indoor unit. The fan blows air, which passes through the heat exchanger, into the indoor unit. The heat exchanger includes a collection part buried in the earth and a connection part, which is formed in the center of the collection part to be connected to the duct.

Description

Geothermal heating and cooling system {A COOLING AND HEATING SYSTEM USING GEOTHERMAL}

The present invention relates to a cooling and heating system using geothermal heat, and more particularly, to a cooling and heating system using geothermal heat to enable cooling in summer and heating in winter without using energy.

If the temperature rises in midsummer, turn on the air conditioner. The air conditioner enables cooling by forcibly circulating the cooled air inside the building after cooling the air.

However, as described above, in the case of a cooling method using an air conditioner, a lot of energy is consumed for cooling, which causes a lot of economic burden. In addition, since the circulated cooling air is very dry, there was a problem that when using the air conditioner for a long time, the cooling disease such as nasal mucosa, allergic rhinitis, cold, various bronchitis.

On the other hand, if the temperature falls in winter, operate the boiler or heater. Boilers or heaters heat air, which is heated by circulating inside the building.

However, in the case of the heating method described above, there was a problem in that a lot of energy was consumed in order to operate a boiler or a heater.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a cooling and heating system using geothermal heat to minimize the amount of energy used in the cooling or heating process.

Another object of the present invention is to provide a cooling and heating system using geothermal heat, which can prevent the cooling process and air from drying out, and can fundamentally prevent cooling diseases and bacterial diseases.

In order to achieve the above object, an embodiment of a cooling system using geothermal heat according to the present invention,
An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; And a pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100.
The heat exchange part 210, the semi-cylindrical collecting end 211 is buried in the ground (G) and the connection portion 212 formed in the center of the collecting end 211 is connected to the duct 300 It is characterized by including.
In order to achieve the above object, another embodiment of the geothermal cooling system according to the present invention,
An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; And a pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100.
The heat exchange part 220 is a semi-cylindrical collecting end 221 embedded in the ground (G), and the connecting portion 222 is formed in the center of the collecting end 221 and connected to the duct 300 and It includes a porous coolant 223 is installed to extend to the outside of the collection 221 after being filled in the collection 221.
In order to achieve the above object, another embodiment of the cooling system using geothermal heat according to the present invention,
An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; And a pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100.
The heat exchanger 230 is a collection tank 231 embedded in the ground (G), a connecting portion 232 formed in the center of the collection tank 231 and connected to the duct 300, and the collection tank It is formed in communication with 231 and includes a porous pipe 233 formed with a plurality of pores (233a).
In order to achieve the above object, another embodiment of the geothermal cooling system according to the present invention,
An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; And an air supply unit 500 for supplying air to the heat exchange unit, wherein one end is positioned above the ground and the other end is connected to the heat exchange unit.
The heat exchange part 240, one side end is connected to the duct 300 and the other end is connected to the air supply 500, the labyrinth part 241 to form a labyrinth and the labyrinth part ( It is formed on the 241 and includes a heat radiation fin 242 for increasing the contact area with the ground (G).
In order to achieve the above object, another embodiment of the cooling system using geothermal heat according to the present invention,
An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; And an air supply unit 500 for supplying air to the heat exchange unit, wherein one end is positioned above the ground and the other end is connected to the heat exchange unit.
The heat exchange part 260 is a semi-cylindrical collection end 261 buried in the ground (G), and the first connection portion 262 formed in the center of the collection end 261 and connected to the duct 300. ), A distribution end 263 located opposite to the collection end 261, a second connection part 264 formed at the center of the distribution end 263 and connected to the air supply pipe 510, and And a porous coolant 255 disposed between the collecting section 261 and the distributing end 263.
In order to achieve the above object, another embodiment of the geothermal cooling system according to the present invention,
An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; And an air supply unit 500 for supplying air to the heat exchange unit, wherein one end is positioned above the ground and the other end is connected to the heat exchange unit.
The heat exchange part 270 is buried in the ground (G), the rainwater tank (271) is stored in the rainwater penetrated to the ground surface, and is installed in the rain tank 271, one end is the duct 300 It is connected to the other end is connected to the air supply pipe 510 includes a coil pipe 272 installed inside the rainwater.
In the present invention, the indoor unit 100 is embedded in the wall of the building, and the pressure feeding fan 400 is built in the indoor unit 100.

delete

delete

delete

delete

delete

delete

delete

delete

delete

The air-conditioning and heating system using geothermal heat according to the present invention includes an indoor unit installed inside a building (B), a heat exchange part embedded in the ground (G), a duct connecting the heat exchange unit and the indoor unit, and air through the heat exchange unit. By including a pressurized fan forced to the indoor unit, cool air in summer and warm air in winter can be introduced into the building without the input of energy, thereby enabling cooling and heating.

In addition, the air can be prevented from drying during the cooling process to protect the occupants from the threat of cooling diseases and various respiratory diseases, there is an effect, the effect.

Hereinafter, a cooling system using geothermal heat according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a cooling system using geothermal heat according to the present invention, Figure 2 is a graph showing the geothermal temperature change according to the depth change.

1 is a configuration diagram of an embodiment of a heating and cooling system using geothermal heat according to the present invention.

As shown, an embodiment of the air-conditioning system using geothermal heat according to the present invention, the indoor unit 100 is installed in the building (B) inhabited by people to discharge air; A heat exchange part 200 embedded in the ground G above a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; It includes; a pressure feeding fan 400 for forcibly conveying the air passing through the heat exchange unit 200 to the indoor unit (100).

The indoor unit 100 is located inside the building and is embedded in the wall when constructing the building. The indoor unit 100 is preferably provided with a filter 110 for filtering foreign matter contained in the air. In the present embodiment, the indoor unit 100 is an example that is embedded in the wall, but the indoor unit 100 is of course movable in the building.

The duct 300 provides a flow path for guiding the air cooled or warmed by the heat exchanger to be described later when the pressure feeding fan 400 is operated to the indoor unit 100. This duct 300 is also preferably constructed in the wall.

The pressure feeding fan 400 allows the air cooled or warmed by the heat exchanger to flow to the indoor unit 100 through the duct 300, so that noise is not generated during operation. The pressure feeding fan 400 is installed inside the indoor unit 100.

The heat exchanger is buried in the ground (G) where the temperature is kept constant even in summer or winter, and it is preferable to be buried at a depth of 5m or more based on the ground. In general, the temperature of the ground (G) is always maintained at a temperature of 10 ~ 15 ℃ even in the summer when the temperature of the ground rises or falls 30 ° C or in the winter below freezing, the heat exchanger buried in the ground (G) After passing through the air, it is possible to obtain relatively cool air in the summer than the upper surface of the earth without additional energy input, and relatively warm air in the winter. Such a heat exchange part may be implemented in various forms, and when described separately, it is as follows.

FIG. 2 is a view for explaining a first embodiment of the heat exchanger according to FIG. 1.

As shown, the first embodiment of the heat exchanger 210 according to the present invention, the semi-cylindrical collecting end 211 is buried in the ground (G), and formed in the center of the collecting end 211 duct It includes a connection portion 212 connected to (300).

Due to this structure, when the pressure feeding fan 400 is operated, a vacuum pressure is formed inside the collecting stage 211, and in this state, air introduced into the ground G through the ground surface is collected in the vacuum stage 211. It is collected inside and collected at the connection portion 212. Thereafter, the air collected from the connection part 212 is discharged into the building through the indoor unit 100 after passing through the duct 300. At this time, the temperature of the ground (G) is lower than the temperature of the ground surface in the summer, and higher than the temperature of the ground surface in the winter, the air passing through the heat exchanger 210 of the ground (G) is cool in summer and warm in winter The air inside the building is cooled or heated by this air.

FIG. 3 is a view for explaining a second embodiment of the heat exchanger according to FIG. 1.

As shown, the second embodiment of the heat exchange unit 220 according to the present invention, the semi-cylindrical collecting end 221 is buried in the ground (G), and formed in the center of the collecting end 221 duct The connection part 222 connected to the 300 and the porous coolant 223 is installed to extend to the outside of the collection 221 after being filled in the collection 221. At this time, the porous coolant 223 may be implemented in various ways, for example, may be implemented in a building material such as tuscon.

By such a structure, when the pressure feeding fan 400 is operated, a vacuum pressure is formed inside the collection unit 221, and the air introduced into the ground G through the ground surface passes through the porous coolant 223 in this state. A vacuum pressure is collected in the collected collecting portion 221 and collected at the connecting portion 222. Thereafter, the air collected from the connecting portion 222 is discharged into the building through the indoor unit 100 after passing through the duct 300. At this time, since many pores are formed in the porous coolant 223, the air in the ground (G) is more effectively absorbed so that the collecting unit 211 can collect more air.

4 is a view for explaining a third embodiment of the heat exchanger according to FIG. 1. As shown, the third embodiment of the heat exchanger 230, the collecting tank 231 is buried in the ground (G), the connection portion formed in the center of the collecting tank 231 and connected to the duct 300 ( 232 and a porous pipe 233 formed in communication with the collection tank 231 and having a plurality of pores 233a formed therein.

By this structure, when the pressure feeding fan 400 is operated, a vacuum pressure is formed inside the collection tank 231, and in this state, air introduced into the ground G through the ground surface is formed through the porous pipe 233a. 233 is introduced into the collection tank 231 is collected. Thereafter, the air collected at the connecting portion 232 is discharged into the building through the indoor unit 100 after passing through the duct 300. At this time, since the porous pipe 233 has a large number of pores 233a, the air in the ground G is more effectively absorbed to allow the collection tank 231 to collect a larger amount of air.

5 is a configuration diagram of another embodiment of a cooling and heating system using geothermal heat according to the present invention.

As shown, another embodiment of the geothermal heating and cooling system according to the present invention, the indoor unit 100 is installed in the building (B) inhabited by people to discharge air; A heat exchange part 200 embedded in the ground G above a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; One end is positioned above the ground and the other end is connected to the heat exchanger to include an air supply unit 500 for supplying air to the heat exchanger.

Here, in the case where the structure of the soil is dense and the air does not flow well, the air supply unit 500 for supplying air to the heat exchange unit may be installed. The air supply unit 500 is installed at the end of the air supply pipe 510 and the air supply pipe 510 which is connected to the heat exchanger and is exposed to the ground, and the inflow which prevents rainwater or snow from entering the air supply pipe 510. The prevention part 520 is included.

In the present embodiment, since the indoor unit 100, the duct 300, and the pressure feeding fan 400 are the same as those described in the first embodiment, a detailed description thereof will be omitted.

FIG. 6 is a view for explaining a fourth embodiment of the heat exchanger according to FIG. 5.

As shown, the fourth embodiment of the heat exchanger 240 according to the present invention, the one end is connected to the duct 300 and the other end is connected to the air supply pipe 510 to form a tortuous maze The labyrinth part 241 and the heat radiation fin 242 which are formed in the labyrinth part 241 and increase the contact area with the ground G are included. At this time, the labyrinth unit 241 may be manufactured by bending the tube to bend, or may be manufactured by dividing the inside of the flat rectangular tank in a zigzag manner.

By this structure, when the pressure feeding fan 400 is operated, a vacuum pressure is formed in the labyrinth unit 241, and the air introduced into the labyrinth unit 241 through the air supply pipe 510 in this state is the labyrinth unit 241. After passing through the duct 300 and then through the indoor unit 100 is discharged into the building. At this time, since the heat dissipation fins 242 are formed in the labyrinth part 241, the temperature of the ground G is effectively transmitted to the labyrinth part 241, so that the air passing through the labyrinth part 241 is cool in summer. It gets warm in winter.

FIG. 7 is a view for explaining a fifth embodiment of the heat exchanger according to FIG. 5.

As shown, the fifth embodiment of the heat exchanger 250 according to the present invention, the first tank 251 is connected to the duct 300, and the second tank 252 is connected to the air supply pipe 510. And a plurality of cooling tubes 253 connected in communication between the first tank 251 and the second tank 252.

Due to this structure, when the pressure feeding fan 400 is operated, a vacuum pressure is formed in the first tank 251 and the cooling pipe 253, and in this state, the vacuum pump flows into the second tank 252 through the air supply pipe 510. After the air is distributed and passes through the cooling pipe 253, the air is collected in the first tank 251 and then introduced into the indoor unit 100 through the duct 300. At this time, since a plurality of cooling pipes 253 are buried in the ground (G), the temperature of the ground (G) is effectively transmitted to the cooling pipe 253, whereby the air passing through the plurality of cooling pipes 253 is summer Cool in winter and warm in winter.

FIG. 8 is a view for explaining a sixth embodiment of the heat exchanger according to FIG. 5.

As shown, the sixth embodiment of the heat exchanger 250 according to the present invention is formed in the center of the semi-cylindrical collection group 261 and the first collection 261 buried in the ground (G) And a first connection portion 262 connected to the duct 300, a distribution end 263 positioned opposite to the collecting end 261, and formed at the center of the distribution end 263 to be connected to the air supply pipe 510. And a second connection portion 264, and a porous coolant 265 installed between the collection unit 261 and the distribution end 263. In this case, the porous coolant 265 may be variously implemented, for example, a building material such as tuscon.

Due to this structure, when the pressure feeding fan 400 is operated, a vacuum pressure is formed in the collection unit 261, and the air supplied to the air supply pipe 510 in this state is the porous coolant 265 in the distribution stage 263. After being penetrated by), it is collected in the collecting section 261 in which the vacuum pressure is formed and collected at the first connection portion 262. Thereafter, the air collected from the connection part 212 is discharged into the building through the indoor unit 100 after passing through the duct 300.

FIG. 9 is a view for explaining a seventh embodiment of the heat exchanger according to FIG. 5.

As shown, the seventh embodiment of the heat exchanger 270 according to the present invention, which is buried in the ground (G), storm tank (271) and storm rain tank (2) that is stored in the rain (impregnated water) is stored, 271) As installed inside, one end is connected to the duct 300 and the other end is connected to the air supply pipe 510 includes a coil pipe 272 installed inside the rainwater. Rainwater shank (271) is a rainwater (rainwater) is stored in the ground (G) after falling to the ground, and is stored a lot when building a rural house or eco-friendly house. Since the excellent tank 271 is widely constructed in various fields, detailed description thereof will be omitted.

By this structure, when the pressure feeding fan 400 is operated, a vacuum is formed in the coil pipe 272, and in this state, the air supplied to the air supply pipe 510 enters the coil pipe 272 and then the duct 300 And then it is discharged into the building through the indoor unit (100).

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a configuration diagram of an embodiment of a heating and cooling system using geothermal heat according to the present invention,

2 is a view for explaining a first embodiment of the heat exchanger applied to FIG.

3 is a view for explaining a second embodiment of the heat exchanger applied to FIG.

4 is a view for explaining a third embodiment of the heat exchanger applied to FIG.

5 is a configuration diagram of another embodiment of a heating and cooling system using geothermal heat according to the present invention;

6 is a view for explaining a fourth embodiment of the heat exchanger applied to FIG. 5;

FIG. 7 is a view for explaining a fifth embodiment of the heat exchanger according to FIG. 5;

FIG. 8 is a view for explaining a sixth embodiment of a heat exchanger according to FIG. 5;

9 is a view for explaining a seventh embodiment of the heat exchanger unit applied to FIG.

<Description of Symbols for Major Parts of Drawings>

100 ... indoor unit 110 ... filter

210 ... heat exchanger 211 ... collection

212 ... Connections 220 ... Heat Exchanger

221 ... collection 222 ... connections

223 ... porous coolant 230 ... heat exchanger

231 ... collection tank 232 ... connections

233 ... porous pipe 240 ... heat exchanger

241 ... Labyrinth 242 ... Heat sink fin

250 ... heat exchanger 251 ... first tank

252 ... 2nd tank 253 ... Cooling pipe

260 ... heat exchanger 261 ... collection

262 ... first connection 263 ... distribution stage

264 ... second connection 265 ... porous coolant

270 Heat exchanger 271 Excellent tank

272 ... coiled pipe 300 ... duct

400 ... pressure feeding fan 500 ... air supply

510 .. Air supply pipe 520 ... Ingress prevention

Claims (10)

delete An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; And And a pressure feeding fan (400) for forcibly feeding air passing through the heat exchange part (200) to the indoor unit (100). The heat exchange part 210, the semi-cylindrical collecting end 211 is buried in the ground (G) and the connection portion 212 formed in the center of the collecting end 211 is connected to the duct 300 Geothermal heating and cooling system using a. An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; And And a pressure feeding fan (400) for forcibly feeding air passing through the heat exchange part (200) to the indoor unit (100). The heat exchange part 220 is a semi-cylindrical collecting end 221 embedded in the ground (G), and the connecting portion 222 is formed in the center of the collecting end 221 and connected to the duct 300 and And a porous coolant (223) which is installed inside the collection group (221) and is installed to extend to the outside of the collection group (221). An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; And And a pressure feeding fan (400) for forcibly feeding air passing through the heat exchange part (200) to the indoor unit (100). The heat exchanger 230 is a collection tank 231 embedded in the ground (G), a connecting portion 232 formed in the center of the collection tank 231 and connected to the duct 300, and the collection tank The cooling and heating system using geothermal heat is characterized in that it comprises a porous pipe 233 is formed in communication with the plurality of pores (233a) formed in communication. delete An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; And And an air supply unit 500 for supplying air to the heat exchange unit, the one end of which is located above the ground and the other end of which is connected to the heat exchanger. The heat exchange part 240, one side end is connected to the duct 300 and the other end is connected to the air supply 500, the labyrinth part 241 to form a labyrinth and the labyrinth part ( 241 is formed in the air conditioning heating system using a geothermal heat, characterized in that it comprises a heat radiation fin (242) for increasing the contact area with the ground (G). delete An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; And And an air supply unit 500 for supplying air to the heat exchange unit, the one end of which is located above the ground and the other end of which is connected to the heat exchanger. The heat exchange part 260 is a semi-cylindrical collection end 261 buried in the ground (G), and the first connection portion 262 formed in the center of the collection end 261 and connected to the duct 300. ), A distribution end 263 located opposite to the collection end 261, a second connection part 264 formed at the center of the distribution end 263 and connected to the air supply pipe 510, and Geothermal heating and cooling system characterized in that it comprises a porous coolant (255) is installed between the collecting section (261) and the distribution stage (263). An indoor unit 100 installed in a building inhabited by people (B) to discharge air; A heat exchange part 200 embedded in the ground G more than a predetermined depth from the ground; A duct 300 connecting between the heat exchanger 200 and the indoor unit 100; A pressure feeding fan 400 for forcibly feeding air passing through the heat exchange part 200 to the indoor unit 100; And And an air supply unit 500 for supplying air to the heat exchange unit, the one end of which is located above the ground and the other end of which is connected to the heat exchanger. The heat exchange part 270 is buried in the ground (G), the rainwater tank (271) is stored in the rainwater penetrated to the ground surface, and is installed in the rain tank 271, one end is the duct 300 And connected to the other end is connected to the air supply pipe 510, the heating and cooling system using geothermal heat, characterized in that it comprises a coil pipe (272) installed inside the rainwater. The method according to any one of claims 2, 3, 4, 6, 8, and 9, The indoor unit (100) is embedded in the wall of the building, and the pressure feeding fan 400 is built in the indoor unit (100).

Images