KR200436840Y1 - An air conditioning device using an underground airspace - Google Patents

Abstract

The present invention relates to a waste heat mixed air-conditioning apparatus using an underground air layer, the air intake pipe 10 to suck the air of the underground air layer 101, the air of the underground air layer 101 to the air intake pipe 10 forcibly introduced Compressed air injection pipe 20 for discharging compressed air to the underground air layer 101 so that it can be, a pressurized pump 30 for supplying compressed air to the compressed air injection pipe 20, the compressed air injection pipe 20 From the intake pump 40 for forcibly transferring the air to the air conditioning space 102, the auxiliary heating means 50 for heating the air moving from the underground air layer 101 to the air conditioning space 102, and the underground air layer 101. By including the auxiliary cooling means 60 for cooling the air moving to the air conditioning space 102, by applying compressed air to the underground air layer it is possible to increase the inflow rate of the air flowing into the air suction pipe from the underground air layer Due to geothermal It is possible to increase the utilization rate of, and to maximize the heat exchange efficiency of the air supplied to the air conditioning space from the underground air layer by using the air in the air conditioning space as compressed air.

Geothermal, underground air layer, compressed air, suction, pump

Description

An air conditioning device using an underground airspace

1 is a block diagram showing a waste heat mixing type heating and cooling device using an underground air layer according to an embodiment of the present invention,

2 is an enlarged view of a portion “A” of FIG. 1;

3 is an enlarged view of a portion “B” of FIG. 1;

4 is a cross-sectional view taken along line C-C of FIG. 3.

※ Explanation of code about main part of drawing ※

10 air intake pipe 11: intake hole

12: suction line 13: bypass line

13a: on-off valve 15: support

16: coupler 16a: male thread

16b: female thread 17: coupling piece

20: compressed air injection pipe 21: exhaust hole

22 cover 30 pressurized pump

35 discharge line 35a, 35b on-off valve

40: intake pump 50: auxiliary heating means

60: auxiliary cooling means 70: filter

The present invention relates to a cooling and heating device using geothermal heat, in particular to a cooling and heating device using the air of the underground air layer.

In general, technology for heating and cooling by using geothermal heat is widely used in the development of energy sources, including heat pumps.

On the other hand, the geological composition of volcanic ash found in Korea is black to dark gray dense basic volcanic rocks made of basalt, with many porosities, and is distributed in Baekdusan, Jeju-do, Yeoncheon and Ulleungdo.

These geological characteristics are young volcanic soils that formed most of the surface lipids by the volcanic activity of the 4th Neo-episode period. The main rocks are basal rocks and are distributed in red cluster (Scoria), a volcanic debris.

In addition, the permeable geological structure has a very high geological structure and geological media with high inflow of precipitation, lava caves, hides (where the common or hot poles are exposed to the surface, and precipitation is infinite) , Uphill, river, and seaweed deposits are formed, and there is an air layer of about 15 ° C in the underground space.

Conventionally, as a cooling and heating facility using such geological characteristics, in the "cooling and heating facility using the underground air layer" disclosed in Korean Patent No. 628466 (Announcement Date 2006.09.27), the underground air layer is provided with a suction pipe and a blower is used to suck underground air. It is configured to.

As such, the method of sucking air by generating a negative (-) pressure in the suction pipe through the blower does not have a large suction force and thus does not move the heat energy.

On the other hand, when the temperature of the air conditioning space rises higher than the temperature of the underground air layer in the summer, the heat of the air layer can be used as cooling energy. When the temperature difference between the air conditioning space and the underground air layer is large, only the thermal energy of the underground air layer can exert a cooling effect. There was no problem.

Therefore, the present invention was devised to improve the problems of the conventional waste heat-mixed air-conditioning apparatus using the conventional underground air layer as described above. The purpose is to provide a waste heat mixed air-conditioning system using the underground air layer.

In order to achieve the object as described above, the waste heat mixed air-conditioning apparatus using the underground air layer according to the present invention includes an air intake pipe having an intake hole and introduced into the underground air layer so as to suck the air from the underground air layer; A compressed air injection pipe having an exhaust hole and discharging the compressed air to the underground air layer through the exhaust hole so that the air of the underground air layer is forced into the intake hole of the air suction pipe; And a pressurized pump for supplying compressed air to the compressed air injection pipe.

Preferably, the compressed air injection pipe is provided through the inside of the air suction pipe.

More preferably, the pressure pump supplies the air discharged from the air conditioning space to the compressed air injection pipe.

In addition, the present invention, the auxiliary heating means for heating the air moving from the underground air layer to the air conditioning space; And auxiliary cooling means for cooling the air moving from the underground air layer to the air conditioning space.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the waste heat mixed air-conditioning apparatus using the underground air layer according to the present invention.

1 to 4, the waste heat mixed air-conditioning apparatus using the underground air layer according to an embodiment of the present invention, the air suction pipe 10 for sucking the air of the underground air layer 101, the air suction pipe 10 Pressurized pump for supplying compressed air to the compressed air injection pipe 20, the compressed air injection pipe 20 to discharge the compressed air to the underground air layer 101 so that the air of the underground air layer 101 is forcibly introduced into 30, an intake pump 40 for forcibly transferring the air of the compressed air injection pipe 20 to the air conditioning space 102, and auxiliary heating for heating the air moving from the underground air layer 101 to the air conditioning space 102. Means 50, and auxiliary cooling means 60 for cooling the air moving from the underground air layer 101 to the air conditioning space (102).

The air suction pipe 10 is inserted into the underground air layer 101 and installed at the bottom thereof, and an intake hole 11 through which air from the underground air layer 101 flows is formed.

The air suction pipe 10 is firmly supported by the support 15 on the ground. The support 15 is to support the outer circumferential surface of the air suction pipe 10 as a concrete structure.

Here, the air suction pipe 10 may be formed by connecting a plurality of segmented pipes, the segmented pipes are connected to the coupler (16). The coupler 16 is composed of a male screw portion 16a and a female screw portion 16b.

As shown in FIG. 2, the male screw portion 16a and the female screw portion 16b are fitted to the outer peripheral surfaces of the distal ends of the different tubes, respectively, and the female screw portion 16b is screwed to the outside of the male screw portion 16a. After the screwing is made, the male screw portion 16a and the female screw portion 16b are respectively fixed to the outer circumferential surface of the pipe by fixing means. The fixing means is a welding or coupling piece 17. That is, one end of the male screw portion 16a and the female screw portion 16b may be welded to and coupled to the outer circumferential surface of the tube, and the outer peripheral surface of the tube penetrates the male screw portion 16a and the female screw portion 16b with the coupling piece 17. Can be coupled to

The air suction pipe 10 transfers the air of the underground air layer 101 to the air conditioning space 102 through the suction line 12.

The suction line 12 is provided with an intake pump 40 to accelerate the movement of the air in the basement air layer 101 by generating a negative pressure inside the air suction pipe 10.

The bypass line 13 is connected to the suction line 12 to bypass the intake pump 40 without passing through it. Therefore, the bypass line 13 is connected at both ends before and after the intake pump 40 to bypass the intake pump 40 to move the air. One side of the bypass line 13 is provided with an on-off valve (13a) to bypass the air only when opened.

When the on-off valve 13a is opened when the intake pump 40 stops, air is moved by atmospheric pressure. This allows the air of the underground air layer 101 to be supplied to the air conditioning space 102 even when the intake pump 40 breaks down.

In addition, the open / close valve 13a may be opened even when the intake pump 40 is operated so that air may branch and move toward the intake pump 40 and the bypass line 13.

In the suction line 12 located in the air conditioning space 102, a discharge hole through which the conveyed air is discharged is formed. The air discharged into the air conditioning space through the discharge hole of the suction line 12 is heat exchanged with the air of the air conditioning space.

The compressed air injection pipe 20 extends through the air suction pipe 10 from the ground to the underground air layer 101. That is, the compressed air injection pipe 20 is inserted into the air suction pipe 10 and is provided to penetrate along the longitudinal direction of the air suction pipe 10.

As shown in FIG. 3, the compressed air injection pipe 20 is exposed to the outside of the lower end of the air suction pipe 10, and an exhaust hole 21 is formed at the exposed end thereof. The compressed air inside the compressed air injection pipe 20 is injected into the underground air layer 101 through the exhaust hole 21. Compressed air forcedly discharged through the exhaust hole 21 increases the pressure in the adjacent area, whereby air of the underground air layer 101 is forced into the intake hole 11 of the air suction pipe 10.

That is, the intake hole 11 of the air suction pipe 10 is provided adjacent to the exhaust hole 21 of the compressed air injection pipe 20 so that the compressed air is discharged to the exhaust hole 21 to the intake hole 11. Since the earth pressure in the adjacent area is increased, the air is pressurized and introduced into the intake hole 11.

As shown in Figure 3, the lower end of the compressed air injection pipe 20 is provided with a conical cover 22 to prevent the intrusion of foreign matter from the underground air layer (101).

The compressed air flowing into the compressed air injection pipe 20 is supplied by the pressure pump 30.

The pressurized pump 30 supplies the air discharged from the air conditioning space 102 to the compressed air injection pipe 20. Therefore, the temperature difference between the compressed air and the air of the underground air layer 101 can be reduced, thereby minimizing the temperature change of the air of the underground air layer 101 due to the compressed air. Therefore, the temperature difference between the air in the basement air layer 101 and the air conditioning space 102 is maximized, thereby increasing heat exchange efficiency.

On the other hand, the pressure pump 30 can also compress the air in the atmosphere. In this case, since the temperature difference between the air in the atmosphere and the air in the underground air layer 101 is large, the temperature change of the underground air layer 101 due to the compressed air is increased, and thus the heat exchange of the underground air layer 101 air introduced into the air conditioning space. The efficiency is lowered.

In other words, the pressurized pump 30 compresses and supplies air discharged from the air conditioning space 102, rather than compressing and supplying air in the atmosphere, thereby exchanging heat of the underground air layer 101 air in the air conditioning space 102. It will increase the efficiency. Therefore, the pressurized pump 30 preferably compresses the air discharged from the air conditioning space 102 and supplies the compressed air to the compressed air injection pipe 20.

For example, the underground air layer 101 temperature of the volcanic ash geology found in Korea maintains a predetermined average value (about 15 degrees), so in winter, the air temperature of the underground air layer 101 is higher than that of the air conditioning space 102. Higher, the air in the underground air layer 101 can be used for heating. On the contrary, in summer, the air temperature of the underground air layer 101 is lower than the air conditioning space 102 so that the air of the underground air layer 101 can be used for cooling.

In addition, in winter, since the temperature of the atmosphere is lower than the temperature of the air conditioning space 102, it is preferable to make the air of the air conditioning space 102 having a relatively small temperature difference from the air of the underground air layer 101 as compressed air. In the same principle, since the temperature of the atmosphere is higher than the temperature of the air conditioning space 102 in the summer, it is preferable to make the air of the air conditioning space 102 compressed air.

The pressurized pump 30 receives air from the air conditioning space 102 through the discharge line 35 and supplies the compressed air to the compressed air injection pipe 20.

The auxiliary heating means 50 and the auxiliary cooling means 60 are connected to the discharge line 35.

The auxiliary heating means 50 is a heater or a heat exchanger connected to the heater, the air in the air conditioning space 102 through the discharge line 35 is heated and supplied to the compressed air injection pipe 20 by It will raise the temperature.

The auxiliary cooling means 60 is a refrigeration cycle, by cooling the air in the air conditioning space 102 through the discharge line 35 and then supplying it to the compressed air injection pipe 20 to lower the temperature of the compressed air.

The auxiliary heating means 50 and the auxiliary cooling means 60 are open and closed valves in the discharge line 35 introduced into the auxiliary heating means 50 and the auxiliary cooling means 60 so as to selectively operate one of them. 35a and 35b are provided.

In winter, the auxiliary heating means 50 is operated, the auxiliary cooling means 60 is stopped, and the on / off valve 35a connected to the auxiliary cooling means 60 is closed.

In the summer, the auxiliary cooling means 60 is operated, the auxiliary heating means 50 is stopped, and the on / off valve 35b connected to the auxiliary heating means 50 is closed.

A filter 70 is provided between the air conditioning space 102 and the pressure pump 30 to filter foreign substances contained in the air discharged from the air conditioning space 102 to supply the pressure pump 30.

As described above, according to the waste heat mixed air-conditioning apparatus using the underground air layer according to the present invention, by applying compressed air to the underground air layer, it is possible to increase the inflow rate of the air flowing into the air intake pipe from the underground air layer, and thus the utilization rate of geothermal heat. And it is possible to increase the heat exchange efficiency of the air supplied from the underground air layer to the air conditioning space by using the air discharged from the air conditioning space as compressed air.

Claims (5)

In the air-conditioning device for cooling and heating the air conditioning space using the air of the underground air layer, An air suction pipe having an intake hole and introduced into the underground air layer so as to suck air from the underground air layer; A compressed air inlet pipe having an exhaust hole exposed to the underground air layer and discharging the compressed air to the underground air layer through the exhaust hole so that the air of the underground air layer is forcibly introduced into the intake hole of the air suction pipe; And Waste heat-mixed heating and cooling device using an underground air layer, comprising a; a pressurized pump for supplying compressed air to the compressed air injection pipe. According to claim 1, The compressed air injection pipe, Waste heat-mixing and heating device using an underground air layer, characterized in that provided through the interior of the air suction pipe. According to claim 1 or claim 2, wherein the pressure pump, Waste heat-mixing and heating system using an underground air layer, characterized in that to supply the air of the air conditioning space to the compressed air injection pipe. The method according to claim 1 or 2, Waste heat-mixing and heating apparatus using the underground air layer, further comprising; auxiliary heating means for heating the air moving from the underground air layer to the air conditioning space. The method according to claim 1 or 2, A waste heat-mixing and heating apparatus using the underground air layer, further comprising a secondary cooling means for cooling the air moving from the underground air layer to the air conditioning space.

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