KR200433566Y1 - Geothermal air communication structure with groundwater leakage prevention function - Google Patents

Abstract

The present invention relates to a geothermal communication structure having a groundwater leakage prevention function of groundwater. When groundwater is supplied from a plurality of geothermal holes and heat exchanged, the geothermal holes are used even if the groundwater utilization and storage capacity of each geothermal hole are different. By allowing groundwater to flow, groundwater does not overflow to the ground even if the valve is not manipulated one by one, and consists of a plurality of geothermal holes formed in the ground and an outer diameter smaller than the inner diameter of the geothermal holes, and an inlet hole is formed at the bottom. A pump is inserted into the center of the geothermal holes, so that the return portion is formed in the portion, the pump is installed in each of the inside of the pump and pumps the groundwater of the return portion through the inlet hole, the return pipe in communication with the return portion Continuously circulating and supplying groundwater through the pump pipe and return pipe Groundwater circulation means (10); Heat exchange means 20 connected to the pumping pipe and the return pipe through manifolds 30 and 40 for receiving ground water and exchanging heat; Both ends are connected to each of the return portion of the plurality of geothermal holes in fluid communication is configured to include a level control pipe to guide the flow of groundwater in the return portion to maintain a constant level of the geothermal holes.

Geothermal, Heat Exchanger, Pump Pipe, Water Level Control Pipe

Description

Ground-air communication structure with groundwater prevention function of groundwater {AN INTER-CONNECTED GEO-THERMAL HOLE FOR PREVENTING EFFLUENCE OF UNDERGROUND WATER}

1 is a block diagram showing a geothermal air communication structure having a function of preventing groundwater leakage of groundwater according to the present invention.

Figure 2 is an enlarged view of the geothermal air communication structure having a function of preventing the ground outflow of groundwater according to the present invention.

Figure 3 and Figure 4 is a pipe joint structure diagram of the pumping pipe respectively applied to the geothermal air communication structure having a function of preventing groundwater outflow of the groundwater according to the present invention.

<Description of the major signs used in the drawings>

10: groundwater circulation means, 11: geothermal hole

12: pump, 13: return part

14: submersible pump, 15: return pipe

16: casing, 17: coupler

18: diameter part, 20: heat exchange means

30,40: manifold,

The present invention relates to a geothermal communication structure having a groundwater leakage prevention function of groundwater, and more particularly, when groundwater is supplied from a plurality of geothermal holes formed in the ground and heat exchanged, the groundwater usage and storage capacity of each geothermal hole is increased. Even though it is different, it is possible to allow groundwater to flow between geothermal cooperatives, so that groundwater does not overflow to the ground, and it is communicated with each other in the heat exchange process so that the heat exchange is carried out through the entire geothermal hole to maximize efficiency. It is about the communication structure.

Most commonly used energy sources are fossil fuels such as coal, petroleum, natural gas, or nuclear fuels.

However, fossil fuels pollute the environment due to various pollutants generated during the combustion process, and nuclear fuels generate harmful substances such as water pollution and radioactivity, and these energy sources have a limited amount of reserves.

Therefore, in recent years, the development of alternative energy to replace this has been actively progressed.

Among these alternative energy, researches on natural energy such as wind, solar, geothermal, etc. have been conducted for a long time and practically installed and used air-conditioning and heating system. These natural energies have almost no influence on environmental pollution and climate change. While there is an advantage in obtaining energy, it is a key factor in the development of natural energy technology to increase the density and convert it into a usable form due to the drawback of very low energy density.

One of such natural energy technologies is known as a heat pump system that performs cooling and heating using geothermal heat as a heat source. Heat pump system using geothermal heat is a technology that uses heat exchanger to install heat exchanger to recover heat in the ground of 10 ~ 20 ℃ or discharge heat into the ground.

In general, as a heat source of a heat pump, an air heat source method of obtaining or discharging heat in the air, such as an air conditioner, and a water heat source method of discharging heat through a cooling tower are used. The use of geothermal sources has the advantage that the energy efficiency is very high compared to air heat sources.

In particular, the year-round air temperature in the areas where the four seasons are obviously changed greatly varies from -20 to 40 ℃, while the underground temperature is almost constant at 10-20 ℃ during the year below 5m underground.

Therefore, in the case of cooling in summer, the air heat source temperature is consumed a lot of power to discharge the cooling heat to 30 ℃ or more, while the geothermal heat source is smoothly discharged to 10 ~ 20 ℃ shows a high efficiency. On the contrary, in the case of heating in winter, the air heat source is difficult to supply the heat necessary for heating at the lowest temperature of -20 ° C, while the underground heat source is 10 to 20 ° C, which can stably supply the heating heat to the heat pump.

The geothermal heat pump system is known to have the highest energy efficiency among all air-conditioning technologies. Therefore, it is an essential technology in a situation where energy resources are scarce and energy costs are high.

Another advantage of heat pump systems using geothermal sources is that they can store cooling or heating heat underground. In other words, the soil or rock in the ground has a low thermal conductivity, so the heat is not easily diffused and stored. Therefore, when heat is released into the ground due to summer cooling, the heat is stored in the ground without disappearing.

On the other hand, the geothermal heat exchanger has a method of allowing the heat exchange medium to circulate underground and supplying ground water to the heat exchanger to heat exchange with the heat exchange medium.

As is well known, groundwater [地下水; ground water is water that fills or runs through gaps between underground strata and rocks. geothermy] refers to the amount of heat released from the inside of the earth to the outside through the surface. Geothermal heat is emitted from the entire surface of the earth to the outside. Higher value in the zone. The outflow methods are based on heat conduction, gas, hot water and volcanic eruptions. Geothermal energy is often used for power generation in places where there is a large amount of crustal heat, such as New Zealand, Italy and Japan. Geothermal heat is also based on the thermal energy generated by the natural collapse of radioactive materials in the earth's crust. On the other hand, heat is hardly released to the surface because the mantle is thermally insulated in the hot earth, where iron and nickel are melted. Appropriate use of the geothermal heat is quite advantageous in terms of environment. There are no carbon dioxide emissions and few pollutants. And geothermal heat can be used in many forms, including direct heating, power generation, heating and cooling through heat pumps, and heat for manufacturing.

The geothermal heat exchanger using the groundwater will be described schematically, and it is largely composed of groundwater circulation means and heat exchange means. Groundwater circulation means is a geothermal hole formed in the ground, a pumping pipe inserted into the geothermal hole, the submersible pump installed in the interior of the pumping pipe pumps the groundwater in the geothermal hole to supply to the heat exchange means, the heat exchange means It is configured to include a return pipe for returning the ground water heat exchanged through the geothermal hole again.

On the other hand, in the geothermal heat exchanger having such a structure, a plurality of groundwater circulation means is connected to one heat exchange means.

However, the geothermal heat exchanger according to the prior art has the following problems.

A plurality of groundwater circulation means connected to one heat exchange means is formed in the ground so that each geothermal hole is close to each other, but the groundwater use and storage capacity may be different depending on the development of subsurface soil and aquifer. However, since the pumping and returning amount of groundwater is the same in all geothermal holes, more water can be replenished than its own storage capacity, which causes the groundwater in the geothermal hole to overflow into the ground through the geothermal hole inlet as the level rises. On the contrary, if the amount less than its storage capacity is replenished, the water level drop causes idle motor pump idling, causing a failure and a phenomenon in which the heat exchange capacity is significantly reduced.

In order to prevent this phenomenon, each of the pumping pipe and the return pipe is used to install a valve, the operator has to operate the valve by hand to adjust the amount of return of the groundwater is very inconvenient management.

In addition, when only some geothermal holes of the plurality of geothermal holes are used to close the unused geothermal holes through the valve operation every time, and the management of the return of the groundwater through the valve of the remaining geothermal holes is also very inconvenient management.

The present invention is devised to solve the problems as described above, it is perforated in the ground and connected to one heat exchange means to maintain a constant level of water in a plurality of geothermal holes supplying groundwater without a separate valve operation The purpose of the present invention is to provide a geothermal communication structure with groundwater prevention function of groundwater to improve the heat exchange capacity.

Geothermal hole communication structure having a function of preventing the ground outflow of groundwater according to the present invention for achieving the above object, a plurality of geothermal holes perforated in the ground, a pump for supplying groundwater in the geothermal hole, supplying groundwater from the pump A heat exchange means for receiving heat exchange, a return pipe for returning the groundwater heat exchanged through the heat exchange means to the geothermal holes, and connecting the geothermal holes to each other so that the groundwater in the geothermal holes flows with each other to maintain a constant water level in the geothermal holes Characterized in that it comprises a water level adjusting means to maintain.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms or words used in the present specification and claims are defined in the technical spirit of the present invention based on the principle that the inventor can appropriately define the concept of the term in order to best describe his or her own design. It must be interpreted to mean meanings and concepts.

As shown in Figure 1, the geothermal air communication structure having a groundwater leakage prevention function of the groundwater according to the present invention, geothermal holes (11A, 11B) A groundwater circulating means (10A, 10B, 10C) that circulates groundwater in 11C) and groundwater that is heat-exchanged after receiving ground water from a plurality of groundwater circulating means (10A, 10B, 10C) are exchanged to groundwater circulation means ( Heat exchange means 20 for returning back to 10A, 10B, 10C, and groundwater circulation means 10A, 10B, 10C, water level control pipe 50A, 50B

It is configured to include, hereinafter, each component will be described in detail.

Groundwater circulation means (10A, 10B, 10C) is the same structure, only the installation location is different, so only one will be described as an example.

As shown in Figure 2, the groundwater circulation means is formed in the ground (G) geothermal hole 11, the outer diameter smaller than the inner diameter of the geothermal hole 11 while the inlet hole (12a) is formed at the lower end to return to the circumference Inserted into the center of each geothermal hole 11 so that the portion 13 is formed and is connected to the heat exchange means 20 and mounted in the interior of the pumping pipe 12 and the pumping pipe 12 to supply groundwater, respectively, the inlet hole ( A submersible pump 14 for pumping the groundwater in the return unit 13 through 12a), and a return unit 13 for connecting the return unit 13 and the heat exchange means 20 to guide the return of the groundwater exchanged by the heat exchange means 20. It consists of a tube 15. Here, the bottom inlet hole (12a) of the pump pipe 12 is close to the bottom portion of the geothermal hole 11 and the outlet of the return pipe 15 is disposed at the inlet side of the geothermal hole 11, return pipe 15 Underground water discharged from the heat exchanged downwards to the inlet hole (12a) is supplied to the pumping pipe 12 again.

As shown in FIG. 1, the heat exchange means 20 is connected to the pumping pipes 12A, 12B, 12C and the return pipes 15A, 15B, and 15C of the groundwater circulation means 10A, 10B, and 10C. 12B, 12C) through the ground water is supplied to the heat exchange medium and the ground water heat exchange, and the same as the conventional heat exchange means will be omitted here a detailed description.

Since a plurality of groundwater circulation means (10A, 10B, 10C) is connected to one heat exchange means 20, the supply side for collecting a plurality of lines of pumping pipes (12A, 12B, 12C) and return pipes (15A, 15B, 15C) The manifold 30 and the discharge side manifold 40 are provided, respectively.

The supply-side manifold 30 and the discharge-side manifold 40, like the heat exchange means 20, are not related to the technical gist of the present invention, and thus the same description as the conventional one is omitted.

The present invention is characterized in that the groundwater level (amount) of each geothermal hole is kept constant even if the amount of groundwater in the plurality of geothermal holes (11A, 11B, 11C) is different, for example, the water level control pipe (50A) (50B) (Because the present invention has been described as three geothermal holes 11A, 11B, 11C), only two water level control tubes 50A, 50B are shown).

Water level control pipe (50A, 50B) is buried between the geothermal holes (11A, 11B, 11C) can be in fluid communication with the return portion (13A, 13B, 13C) of the geothermal holes (11A, 11B, 11C) with different ends Pipe joints. That is, geothermal holes (11A, 11B, 11C) of different groundwater circulation means (10A, 10B, 10C) are connected through the water level control pipe (50A, 50B) to ground geothermal holes (11A, 11B, 11C) different groundwater It can flow.

Water level control pipe (50A, 50B) is piped to tubular casing (16A, 16B, 16C) provided on the inner peripheral surface of the inlet side of geothermal hole (11A, 11B, 11C), respectively. For example, at the periphery of the casing 16A, a pipe joint 16D (one or two pipe joints are formed depending on the quantity of the water level control tubes 50A and 50B) is formed to protrude, and the water level control tube 50A is formed. Is a diameter larger than that of the pipe joint 16D and is fitted to the pipe joint 16D with an index ring or the like interposed therebetween.

However, in order for the groundwater to flow by the water level control pipes 50A and 50B, even if the geothermal holes 11A, 11B and 11C have different heights, the water level control pipes should be formed to be horizontal.

In the drawings, reference numerals V1 and V2 denote valves.

Referring to the operation of the geothermal communication structure having a groundwater leakage prevention function of groundwater according to the present invention configured as described above are as follows.

Underground water G flows into the return portions 13A, 13B, and 13C of the geothermal holes 11A, 11B, and 11C of the groundwater circulation means 10A, 10B, and 10C, respectively. Submersible pumps 14A, 14B, and 14C in each geothermal hole 11A, 11B, and 11C pump the groundwater present in return portions 13A, 13B, and 13C through pumping pipes 11A, 11B, and 11C, respectively. The ground water collected through the supply side manifold 30 and collected through the supply side manifold 30 is supplied to the heat exchange means 20 and heat exchanged with the heat exchange medium of the heat exchange means 20, and then through the discharge side manifold 40. The groundwater branched into a plurality of return pipes 15A, 15B, and 15C, and returned back to each of the return pipes 15A, 15B, and 15C is heat-exchanged while flowing through the geothermal holes 11A, 11B, and 11C, and then pumps again. 12A, 12B, and 12C.

As such, each of the geothermal holes 11A, 11B, and 11C while ground water is supplied to and returned to the heat exchange means 20 may have different use capacity and storage capacity of the groundwater, and thus, may be returned through the return pipes 15A, 15B, and 15C. When a uniform amount is filled, the storage capacity may be exceeded at some point, and ground water flows into other geothermal holes 11A, 11B, and 11C through the water level control pipes 50A and 50B. For example, when the groundwater above the storage capacity is filled in the first geothermal hole 11A, the groundwater flows to the second geothermal hole 11B through the first water level control pipe 50A without overflowing to the ground outside the ground G. On the contrary, if the groundwater above the storage capacity is filled in the second geothermal hole (11B), the groundwater is the first geothermal hole (11A) or the first through the first water level control pipe (50A) or the second water level control pipe (50B) It flows into 3 geothermal holes 11C. Therefore, while the groundwater above the storage capacity is supplied to other geothermal holes, the groundwater level in all geothermal holes 11A, 11B, and 11C can be constantly adjusted according to the capacity of each geothermal hole.

On the other hand, geothermal air communication structure having a groundwater leakage prevention function of the groundwater according to the present invention, the pumping pipe 12 is a structure in which a plurality of unit pipes (12-1, 12-2) are piped, insertion and withdrawal is It is configured to smoothly and not damage the pipe joint of the pump 12, as shown in Figure 3, the unit pipes (12-1, 12-2) are provided with inclined guides (17a, 17b) at the upper and lower ends of the outer peripheral surface, respectively It is piped through the coupler (17). The coupler 17 may be fastened to the unit tubes 12-1 and 12-2 by an adhesive or a screw 17c or the like. According to this structure, even when the coupler 17 is larger than the pumping pipe 12 when the pumping pipe 12 is drawn out or inserted, the inclined guides 17a and 17b slide through the inner wall surface of the geothermal hole. No breakage of pipe joint occurs.

And, as shown in Figure 4, the upper end of the unit pipe 12-2 is formed with an enlarged diameter portion 18 that gradually increases the inner diameter toward the end, the inclined guide 18a is formed at the upper circumference of the enlarged diameter portion 18 It is provided, and the lower end part of the upper unit pipe 12-1 is fitted to the enlarged diameter part 18 of the lower unit pipe 12-2, and is engaged. In order to increase the unity of the unit pipes (12-1, 12-2) may be further fastened to the joint with an adhesive or screw.

Therefore, when the amniotic tube 12 is inserted, the enlarged diameter portion 18 slides along the inner wall surface of the geothermal hole so that the pipe joint portion is held, and the pipe joint portion is pulled out by the inclined guide 18a. It is withdrawn while sliding.

As described above, according to the geothermal air communication structure having a groundwater leakage prevention function of the groundwater according to the present invention, groundwater use capacity and storage of each geothermal hole when the ground water is supplied and heat exchanged from a plurality of geothermal holes formed in the ground Even if the capacity is different, groundwater flows between geothermal holes, so that groundwater does not overflow to the ground even if the valves are not manipulated one by one, thereby making it very easy to manage and maximizing efficiency due to heat exchange.

The present invention has been described and illustrated with reference to preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, those skilled in the art will appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes, modifications, and equivalents should be considered to be within the scope of the present invention.

Claims (4)

A plurality of geothermal holes formed in the ground, the outer diameter smaller than the inner diameter of the geothermal hole is formed in the inlet hole in the lower end is formed in the center of the geothermal hole so that the return portion is formed in the periphery, respectively in the interior of the pump A groundwater circulation means, comprising: an underwater pump for pumping the groundwater of the return portion through the inlet hole, and a return pipe communicating with the return portion to continuously circulate the groundwater through the pumping pipe and the return pipe; A supply side manifold connected to the pumping pipes of the groundwater circulation means and collecting ground water supplied by the pumping pipes; Heat exchange means for receiving ground water from the supply side manifold and exchanging heat with the ground water; In the geothermal heat exchanger comprising a discharge side manifold connected to the plurality of return pipes and distributes the ground water passed through the heat exchange means to the plurality of return pipes, Between the plurality of geothermal holes, the water level control pipe is connected to each other in fluid communication with the return portion is piped to guide the flow of groundwater in the geothermal hole to maintain the level of groundwater in the geothermal holes Geothermal air communication structure having a groundwater leakage prevention function of groundwater, characterized in that the structure. According to claim 1, wherein the inner wall surface of the inlet of the geothermal hole is provided with a casing provided with a pipe joint, the water level control pipe of the groundwater, characterized in that both ends are piped to the pipe joint of the casing Geothermal hole communication structure with ground leakage prevention function. According to claim 1 or 2, wherein the pumping pipe of the groundwater circulation means is a plurality of unit pipes are pipe, the unit pipe is a structure that is piped through a coupler is provided with inclined guide at each of the upper and lower ends Geothermal air communication structure having a function of preventing groundwater outflow of groundwater. According to claim 1 or claim 2, wherein the pumping pipe of the groundwater circulation means is a plurality of unit pipes are pipe, the unit pipe is gradually increased in the inner diameter toward the upper end of the upper and lower both ends of the upper end portion at the upper periphery An enlarged diameter portion provided with an inclined guide is formed, and the lower end portion of the other unit pipe is inserted into the enlarged diameter portion, and the pipe is connected to the structure by fastening with an adhesive or a screw. Hot air communication structure.

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