KR200417382Y1 - Ground heat exchange system for high quality heat pump - Google Patents

Abstract

The present invention relates to a high-efficiency geothermal heat exchanger for a heat pump, and to maximize heat exchange efficiency by configuring a closed heat medium storage unit wrapped in groundwater in a borehole excavated into the ground to allow heat exchange by conduction and convection. .

Geothermal heat exchanger of the present invention for realizing this, by drilling a hole in the vertical direction in the ground, the borehole 10 is formed, the borehole 10 is a heat medium storage tube 20 in which the heat medium 21 is stored therein It is inserted and installed in the heat medium storage tube 20, the inlet pipe 31 and the outlet pipe 32, which are circulation pipes 30 for circulating the heat medium 21 stored therein, to the heat medium using place 60, are respectively inserted. The space between the heat medium storage tube 20 outer wall and the borehole 10 inner wall is characterized by being filled with a grouting portion 40.

Heat Pump, Geothermal Heat Exchanger, High Efficiency, Groundwater, Borehole, Grouting

Description

High efficiency geothermal heat exchanger for heat pump {GROUND HEAT EXCHANGE SYSTEM FOR HIGH QUALITY HEAT PUMP}

1 is a cross-sectional view of the geothermal heat exchanger installation state according to an embodiment of the present invention.

Figure 2 is a cross-sectional view of the geothermal heat exchanger installation state according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: borehole 11,11 ': groundwater

20: heat medium storage tube 21: heat medium (water or antifreeze)

22: waterproof grouting 30: circulation pipe

40: grouting section 50: steel pipe casing

60: where the heat medium is used

The present invention relates to a geothermal heat exchanger, and more particularly, to effectively use a geothermal heat pump having a temperature lower than the atmospheric temperature in the summer and higher than the atmospheric temperature in the winter.

Generally, fossil fuels such as coal, petroleum, and natural gas are used as energy sources for cooling and heating, or electric energy produced using these fossil fuels or nuclear power is mainly used.

However, since fossil fuels have a disadvantage of polluting water quality and the environment due to various pollutants generated in the combustion process, recent development of alternative energy to replace them has been actively conducted.

Among these alternative energies, research on wind power, solar heat, geothermal energy, etc., which have infinite energy sources, and air-conditioning devices using them are used. These energy sources have the advantage of obtaining energy with little effect on air pollution and climate change. On the other hand, the energy density is very low.

In particular, in order to obtain energy by using wind and solar heat, a large area must be secured along with the limit of the installation site, and these devices have a low energy production capacity per unit and are expensive to install and maintain.

Therefore, many air-conditioning and heating devices using geothermal energy, which require relatively low cost for installation and maintenance, are used, which is a technology using underground thermal energy having a temperature of 10 to 20 ° C.

Commonly used geothermal heating and cooling device is composed of a geothermal heat exchanger for recovering the geothermal heat, and a heat pump to move the collected geothermal heat to a necessary place to perform the cooling and heating.

Among them, the geothermal heat exchanger is installed in the form of digging a heat-exchange pipe by digging a bore-hole in a substantially vertical direction after securing a ground with a margin.

Such a geothermal heat exchanger installation is well suited for larger buildings with no rock near the surface or little slope collapse. The installation of such a geothermal heat exchanger excavates a borehole 50 ~ 200m deep underground at predetermined intervals, and each borehole is wound once or twice to bury a U-shaped pipe.

After the pipe is installed, each bore hole is filled with bentonite or cement, which is an impermeable material, and then grouted. In the grouting process, the borehole is filled with a special material to prevent the ingress of surface water into the aquifer or the infiltration of adjacent aquifers.

However, since the conventional geothermal heat exchanger uses a method in which geothermal heat is transferred directly to the circulation pipe by conduction by inserting a heat exchange pipe into the borehole and grouting, it is impossible to impart a heat storage function and reduce the amount of heat recovered. There was a problem that the heat exchange performance is inevitably deteriorated.

The present invention is proposed to improve the above problems in the prior art, to have a heat storage function through the structural change of the heat exchange pipe buried in the ground and to maximize the heat exchange efficiency to improve the economics of the heat pump The purpose is to.

The purpose is to excavate a hole in the vertical direction in the ground, the borehole is formed, the borehole is inserted into the heat medium storage tube is stored therein the heat medium, the heat medium body is stored in the heat medium body heat pump body The heat exchange pipe circulated to the side is inserted, and the separation space between the heat medium storage tube outer wall and the borehole inner wall is filled with a grouting portion to achieve a high efficiency geothermal heat exchanger for a heat pump.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, looking at the installation structure of the closed geothermal heat exchanger according to an embodiment of the present invention through Fig. 1, the drilling hole drilled a predetermined depth into the ground to form a rock layer (B) of the soil layer (A) and the lower layer of the ground side ( 10) was formed in the vertical direction, and the borehole 10 has a heat medium storage tube 20 in which a heat medium 21 such as water or an antifreeze is stored therein is inserted, and a heat pump is installed in the heat medium storage tube 20. The circulation pipe 30 is configured to draw in a circulation pipe with a heat medium use destination 60, such as a main body or an underground heat storage tank, to allow forced circulation by a pump (not shown).

Then, the groundwater 11 is filled with a predetermined level in the internal space of the borehole 10 into which the heat medium storage tube 20 is inserted, and the grouting portion 40 is formed by filling bentonite or cement, which is an impermeable material, in the upper space of the water level. do.

In addition, the steel pipe casing 50 to the depth corresponding to the soil layer (A) of the borehole 10 has been configured to surround the grouting portion (40).

On the other hand, it is preferable to improve the heat medium utilization efficiency by providing different heights of the first pipe 31 and the second pipe 32 among the circulation pipe 30 introduced into the heat medium storage pipe 20. Done.

In the figure, reference numeral 41 denotes a support plate fixed to the outer wall surface stop of the heat medium storage tube 20 to support the grouting material of the grouting part 40.

The effect of the construction process and use after construction of the present invention geothermal heat exchanger constituting such a structure will be described.

First, in constructing the borehole 10, the excavation is carried out while driving the steel pipe casing 50 to the depth of the soil layer A. In the rock layer B having groundwater, the excavation is performed without installing a casing.

Thereafter, the heating medium 20 is inserted into the borehole 10 to store the heating medium 21 in which the heating medium 21 is stored. At this time, the heating medium 20 includes a circulation pipe guiding circulation of the heating medium 21 ( 30) is to be drawn in, the bottom is sealed by a waterproof grouting (22).

At this time, the circulation pipe 30 is installed to the height of the first pipe 31 and the second pipe 32 different from each other, the piping path of the circulation pipe 30 is preferably to be embedded in the ground.

When the installation of the heat medium storage tube 20 is completed as described above, grouting is performed in the inner space of the borehole 10. At this time, when there is no groundwater inside, grouting is performed for the entire space. However, when the groundwater 11 is filled with a predetermined water level as shown in FIG. 1, the grouting part 40 may be formed only at a height above the ground water level to increase heat exchange performance.

On the other hand, when there are two or more boreholes and the amount of groundwater is large, water pumps are installed in the boreholes to circulate the groundwater to use geothermal heat or groundwater as living water.

The geothermal heat exchanger of the present invention, which has been installed through such a process, can be heat-exchanged while the heat medium is circulated through the circulation pipe 30 in the state where heat storage or heat storage is primarily performed in the heat medium storage tube 20. It can be seen that it is possible to maximize the geothermal heat transfer by the influence of conduction and convection by the groundwater surrounding the heat medium storage pipe (20).

In particular, during the summer cooling in the circulation pipe 30, water having a high temperature is supplied into the heat medium storage pipe 20 through the first pipe 31, and water having a low temperature in the heat medium storage pipe 20 is supplied to the second pipe. Through the 32 to form a circulation cycle for supplying to the heat medium using place 60, when heating in winter to achieve the reverse cycle to the reverse it is possible to increase the heat exchange efficiency.

In addition, the structure of directly using the groundwater according to another embodiment of the present invention as a heat medium forms the shape shown in FIG. 2.

That is, as shown in the case where the amount of groundwater is large, by using the groundwater 11 ′ introduced into the borehole 10 as a heat medium, the groundwater by closing the groundwater level above the borehole 10 with a grouting part 40. (11 ') The storage space is composed of a heat medium storage unit 20'.

In addition, the circulation pipe 30 circulating through the heat medium use place 60 has the heights of the first pipe 31 and the second pipe 32 different from each other, so that the groundwater 11 'is directly used as the heat medium. .

The geothermal heat exchanger installation structure is such that the entire wall surface of the borehole 10 forms a heat transfer surface for the geothermal heat, and thus the heat transfer area can be maximized, and the heat exchange heat amount due to conduction and convection of groundwater can be increased.

In addition, when the amount of groundwater is large, it is possible to use the groundwater as water for daily use, thereby providing economic advantages.

 In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the geothermal heat exchanger structure of the present invention may be variously modified and implemented by those skilled in the art.

For example, in addition to the heat pump body, an underground heat storage tank or a fire water tank combined storage tank may be applied as a heat medium using the heat medium to be circulated through the circulation pipe.

In addition, by installing a heat exchange pipe inside the concrete pillar by the earthquake construction method (CIP method) when building new construction it is possible to use geothermal heat as a heat source of the heat pump without a separate grouting process.

Therefore, such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments shall fall within the appended utility model registration claims of the present invention.

The present invention as described above has the effect that the heat transfer efficiency per unit heat transfer area can be maximized by being able to maximize the heat transfer area of the borehole at the minimum construction cost.

In particular, by configuring a separate closed heat medium storage unit that absorbs or dissipates geothermal heat itself in the borehole as in one embodiment, it has an advantage of maximizing heat exchange efficiency of the circulating heat medium by having a geothermal heat storage function.

Claims (7)

In the ground, a borehole 10 is formed by digging a hole in a vertical direction; The borehole 10 has a heating medium storage tube 20 in which the heating medium 21 is stored therein; An inlet pipe 31 and an outlet pipe 32 which are circulation pipes 30 for circulating the heat medium 21 stored therein into the heat medium use destination 60 are inserted into the heat medium storage pipe 20; High efficiency geothermal heat exchanger for a heat pump, characterized in that the space between the heat medium storage tube 20 and the borehole 10 the inner wall is filled with a grouting portion (40). The method according to claim 1, The circulation pipe 30 is a high-efficiency geothermal heat exchanger for heat pump, characterized in that the installation of the heat medium inlet pipe 31 and outlet pipe 32 are different from each other. The method according to claim 1, The grouting portion 40 is a high efficiency geothermal heat exchanger for a heat pump, characterized in that formed above the water level of the ground water (11) in the borehole (10). The method according to claim 1 or 3, High efficiency geothermal heat exchanger for a heat pump, characterized in that the steel pipe casing (50) is installed in the soil layer (A) position in the borehole (10). In the ground, a borehole 10 is formed by digging a hole in a vertical direction; The borehole 10 forms a heat medium storage part 20 'by storing a heat medium 11' therein; An inlet pipe 31 and an outlet pipe 32 which are circulation pipes 30 for circulating the heat medium 11 'stored therein to the heat medium use destination 60 are inserted into the heat medium storage part 20'; High efficiency geothermal heat exchanger for a heat pump, characterized in that the heat medium storage portion 20 'top is filled with a grouting portion (40). The method according to claim 5, The heat exchange pipe 30 is a high efficiency geothermal heat exchanger for the heat pump, characterized in that the installation of the heat medium inlet pipe 31 and outlet pipe 32 differently. The method according to claim 5, The heat medium (11 ') is a high-efficiency geothermal heat exchanger for heat pump, characterized in that the ground water or cooling water can be used as domestic water.

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