KR200204536Y1 - Pipe for transfer the heat of the earth - Google Patents

Abstract

The present invention relates to a pipe for geothermal heat transfer, the pipe is a waste heat inlet pipe having a predetermined length so as to pass through the waste heat in the building to the upper and lower, and the waste heat inlet pipe connected to the waste heat inlet pipe Geothermal outflow pipe having a predetermined length so as to penetrate the underground waste heat flowing along the pipe and flows out to the building side, and is addressed to one end of the waste heat inflow pipe and the lower region of the geothermal outflow pipe. It characterized in that it further comprises a recycle tube formed in an inverted U-shape to recirculate the waste heat and geothermal heat. Accordingly, by recycling the waste heat in the basement for a predetermined period and a predetermined time, there is an effect that can obtain the appropriate geothermal heat for cooling and heating, pipe insertion work and grouting work by inserting the support bar in the lower region of the geothermal heat transfer pipe. There is provided a geothermal transport pipe that can be conveniently performed.

Description

Pipe for transfer the heat of the earth}

The present invention relates to a geothermal heat transfer pipe, and more specifically, it is buried underground to repeat the inflow and outflow of geothermal heat into and out of the building by heating and cooling the inside of the building, in particular, geothermal heat up / down underground The present invention relates to a geothermal heat transfer pipe that is capable of obtaining proper geothermal heat for cooling and heating by recirculating by water.

In general, geothermal heat transfer pipes are used for air-conditioning heat exchange systems using geothermal heat, and are buried underground or installed in rivers or lakes, and serve to inflow and outflow geothermal heat to buildings.

Here, the inflow to the building side means that underground heat is introduced into the building side for cooling and heating, and the outflow means that the ground heat used inside the building becomes waste heat and flows out to the basement again.

The geothermal transport pipe used in the conventional geothermal heating and cooling system is composed of a U-type pipe to be buried underground to inflow and outflow of underground heat to the building side, and the inside of the U-shaped pipe is a fluid such as water or antifreeze. Is accepted and serves as a medium to transfer geothermal heat.

By the way, the conventional geothermal transport pipe is simply formed in a U-shape, so that the geothermal heat is transferred to the inside of the building only while the waste heat used inside the building circulates the pipe of a predetermined length.

Therefore, the short distance and time for waste heat to be recycled underground has the disadvantage that it is not possible to obtain geothermal heat suitable for use in air conditioning.

In addition, the conventional geothermal transport pipe has a problem in that the pipe installation is difficult because the pipe is moved to the upper side when the pipe is embedded in the pipe buried hole drilled by a predetermined depth from the ground and then grouting the remaining empty space.

Therefore, an object of the present invention is to provide a geothermal heat transfer pipe that can obtain geothermal heat suitable for heating and cooling.

Still another object of the present invention is to provide a geothermal transport pipe that can be easily grouted by embedding a pipe in a pipe embedding hole drilled to a predetermined depth from the ground.

1 is a cross-sectional view of the geothermal heat transfer pipe according to the present invention,

Figure 2 is an exploded perspective view of the geothermal heat transfer pipe according to the present invention,

Figure 3 is an enlarged cross-sectional view of the connector according to the present invention.

Explanation of symbols on the main parts of the drawings

10: geothermal heat transfer pipe 11: waste heat inlet pipe

13: geothermal outflow pipe 15: recirculation pipe

17: Euro 19: connector

21: support interval 23: insertion hole

According to the present invention, in the geothermal heat transfer pipe, the pipe is a waste heat inflow pipe having a predetermined length so as to penetrate up and down to transfer waste heat in the building underground, and connected with the waste heat inflow pipe Geothermal outflow pipe having a predetermined length so as to circulate the waste heat introduced along the waste heat inflow pipe underground and outflow to the building side, and the waste heat inflow pipe and the lower region of the geothermal outflow pipe. It is achieved by a geothermal heat transfer pipe further comprising a recirculation tube formed at an inverted U-shape so as to be circulated at one end and recirculating the waste heat and geothermal heat.

Here, it is preferable that the lower region of the waste heat inflow pipe, the geothermal outflow pipe, and the recirculation pipe are welded and connected to the upper region of the connection pipe in which a plurality of U-shaped flow paths are formed.

In addition, the geothermal heat transfer pipe may further include an inter-support insertion hole formed in the lower region of the connection pipe, and a support interval inserted into the support tube insertion hole.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention. 1 is a cross-sectional view of the geothermal transfer pipe according to the present invention, Figure 2 is an exploded perspective view of the geothermal transfer pipe according to the present invention, Figure 3 is an enlarged cross-sectional view of the connector according to the present invention.

As can be seen in these figures, the geothermal heat transfer pipe 10 is connected to the waste heat inflow pipe 11 and the waste heat inflow pipe 11 capable of transferring waste heat in the building underground, and the waste heat inflow pipe 11 Geothermal outflow pipe 13 for circulating the waste heat introduced along the) underground and outflow to the building side.

In addition, between the waste heat inflow pipe 11 and the geothermal outflow pipe 13, a recycling pipe 15 formed in an inverted U-shape to recirculate waste heat and geothermal heat is connected.

Here, the geothermal heat transfer pipe is preferably formed of polyethylene or synthetic resin to prevent rupture and have a long service life.

The waste heat inflow pipe 11 and the geothermal outflow pipe 13 are hollow and have a tubular shape which is vertically penetrated, and the length of the geothermal heat transfer pipe 10 is formed in an appropriate length that is convenient for use and heat welded as necessary. Or it can be extended by using a connecting socket.

Meanwhile, the lower regions of the waste heat inflow pipe 11, the geothermal outflow pipe 13, and the recirculation pipe 15 may be formed at the upper region of the upper portion of the connection pipe 19 in which a plurality of U-shaped flow paths 17 are formed ( It is formed by thermal welding with 30).

In addition, an insertion hole 23 into which a support bar 21 having elastic force can be inserted is formed in a lower region of the geothermal heat transfer pipe 10, that is, a predetermined position of the connection pipe 19.

The geothermal transfer pipe 10 of the present invention configured as described above transfers the geothermal heat transferred to the antifreeze contained in the geothermal transfer pipe 10 in a state buried underground to the basement and the ground.

Geothermal heat is discharged into the building through the geothermal outflow pipe 13 and the discharged geothermal air is heated and cooled inside the building by a cooling and heating heat exchange system (not shown).

On the other hand, since the geothermal heat used inside the building becomes waste heat, the ground heat flows back into the ground through the waste heat inflow pipe 11.

Waste heat flowed into the basement is circulated for a predetermined time in the basement through the recirculation pipe 15 formed in an inverted U shape. At this time, the geothermal heat is discharged into the building through the geothermal outflow pipe 13.

That is, the waste heat moves downward through the waste heat inflow pipe 11 and the moved waste heat starts to be transferred to geothermal heat from the moment it is transferred underground, and is transferred upward through the recirculation pipe 15 welded to the connecting pipe 19. Geothermal heat is transferred to the moment until it is conveyed to the lower side again through the recycle pipe (15).

Therefore, it is leaked into the building through the geothermal heat pipe 13 while maintaining a temperature suitable for use in cooling and heating.

On the other hand, in order to embed the geothermal transfer pipe 10 in the pipe buried hole perforated on the ground support rod 21 in the insertion hole 23 of the connection pipe 19 welded to the lower region of the geothermal transfer pipe 10 Insert).

The support section 21 is elastically supported on both side walls of the hole by an elastic force in a state located at the lower end of the pipe embedding hole. Therefore, even if the grouting work is performed in the empty space of the pipe embedding hole, the geothermal heat transfer pipe 10 does not move upwards, thereby facilitating the installation work.

As described above, according to the present invention, by recycling the waste heat in the basement for a predetermined period of time, it is effective to obtain the appropriate geothermal heat for cooling and heating, by inserting the support rod in the lower region of the geothermal heat transfer pipe There is provided a geothermal transport pipe for easy pipe installation and grouting.

Claims (3)

In geothermal transport pipe, The pipe is A waste heat inflow pipe having a predetermined length and configured to penetrate up and down to transfer waste heat in the building underground; A geothermal outflow pipe connected to the waste heat inflow pipe and having a predetermined length to penetrate the waste heat introduced along the waste heat inflow pipe underground and outflow to the building side; And a recirculation pipe which is addressed to one end of the waste heat inflow pipe and the lower region of the geothermal outflow pipe and formed in an inverted U shape to recirculate the waste heat and geothermal heat. The method of claim 1, And the lower region of the waste heat inflow pipe, the geothermal outflow pipe, and the recirculation pipe are welded to and connected to an upper region of a connection pipe in which a plurality of U-shaped flow paths are formed. The method of claim 1, The geothermal transport pipe An inter-support insertion hole formed in the lower region of the connection pipe; Geothermal transfer pipe further comprises a support interposed between the support interposer insertion hole.