KR101363977B1 - Inside casing of geothermal hole for slime removal - Google Patents

Abstract

The present invention relates to an inner casing of a geothermal hole for easily removing slime. The casing includes: a non-hollow pipe which is inserted into the inside of a geothermal hole formed underground; a support grid which includes a plurality of distribution holes; and a collection grid of which the outer diameter is smaller than the inner diameter of the non-hollow pipe or the support grid and which is installed inside the support grid, includes a plurality of small distribution holes, and has a hook engaging unit at the top to be lifted up by being combined to a hook from above the ground. By doing so, the present invention enables easy removal of slime.

Description

Inside Casing of Geothermal Hole for Slime Removal

The present invention relates to an internal casing of geothermal holes, and more particularly, to an internal casing of geothermal holes for easy removal of slime that can facilitate the removal of slime generated inside the geothermal holes.

Geothermal heat refers to the natural heat and ground heat of groundwater that is excavated by excavating groundwater. Generally, the ground surface is excavated to a deep depth of about 100 meters or more and 500 meters to form a geothermal hole and then heat exchanged to the geothermal hole. Buried internal casing in the form of pipes to utilize the heat of the groundwater.

If you use this geothermal method for a long time, a large amount of slimes will be attached around the inner casing, so you need to remove the slime. Conventionally, as shown in FIG. 1, compressed air is blown into the inner casing 2 by the air compressor 1, and the compressed air is blown out through the screen 2a formed at the lower end of the inner casing 2. The slime attached to the inner casing 2 is removed.

However, this method has a problem that the slime attached to the geothermal hole and the inner casing cannot be removed effectively.

Patent Application No. 10-2011-0123173 (Registration No .: 10-1187863, Title of the Invention: Open type underground heat exchanger system in which the return pipe is installed at the bottom of the geothermal hole)

The present invention has been made in order to solve the above problems of the prior art, having a recovery grid which is pulled up from the bottom of the geothermal hole and then removed from the slime and put back into the bottom of the geothermal hole for easy removal of the slime. The purpose is to provide an inner casing of the tear.

The inner casing of the geothermal hole for easy removal of slime according to the present invention for solving the above problems is a non-pore pipe inserted into the geothermal hole formed in the ground; A support grid installed at a lower end of the non-porous pipe and seated on the bottom surface of the geothermal hole and having a plurality of large distribution holes; The outer diameter is formed smaller than the inner diameter of the non-porous pipe and the support grid is installed inside the support grid, a plurality of small distribution holes are formed, the hook at the top to be coupled to the hook to be introduced from the ground to be pulled upwards The recovery grid formed with a fastening portion.

Here, the support grid is formed so that the seating portion protrudes toward the center at the top, and the recovery grid is formed with a protrusion mounted on the seating portion at the top.

The recovery grid has a lower end spaced apart from the bottom surface of the geothermal hole by a predetermined distance.

The inner casing of the geothermal hole for easy removal of the slime of the present invention configured as described above is to lift the recovery grid to the hook to remove the slime attached to the recovery grid from the ground, and then using the hook back to the support grid inside the geothermal hole Since it is inserted inside, there is an advantage that it is easy to remove the slime.

1 is a view showing a slime removal method according to the prior art.
Figure 2 is a view showing the installation of the inner casing of geothermal holes for easy removal of slime according to the present invention.
Figure 3 shows a support grid of the inner casing of geothermal holes for easy removal of slime according to the present invention.
Figure 4 is a view showing a recovery grid of the inner casing of geothermal holes for easy removal of slime according to the present invention.
5 is a view showing a support grid and recovery grid of geothermal pores for easy removal of slime according to the present invention.

Hereinafter, embodiments of the inner casing of the geothermal hole for easy removal of slime according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing the installation of the inner casing of the geothermal hole for easy removal of slime according to the present invention, Figure 3 is a view showing a support grid of the inner casing of the geothermal hole for easy removal of slime according to the present invention. It is also.

4 is a view showing a recovery grid of the inner casing of the geothermal hole for easy removal of slime according to the present invention, and FIG. 5 is a support grid and recovery of the geothermal hole for easy removal of slime according to the present invention. The grid is shown.

The inner casing of the geothermal hole for easy removal of the slime according to the present invention is for easily removing the slime attached to the inner casing inserted into the geothermal hole (G), the no-pipe (10) and The support grid 20 is installed at the lower end of the airless pipe 10, and the recovery grid 30 is inserted into the support grid 20.

The non-porous pipe 10 refers to a pipe inserted into the geothermal hole (G) formed in the ground. Since the depth of the geothermal hole (G) usually reaches 300 ~ 500m by connecting a plurality of pipes having a predetermined length in the vertical direction and then inserted into the geothermal hole (G) is a non-porous pipe (10). The non-porous pipe 10 refers to a pipe without a through-hole such as a screen at the bottom as can be seen from the name.

The support grid 20 is fixed to the lower end of the airless pipe 10 by a coupling means such as a clamp. The support grid 20 is inserted into the geothermal hole (G) to be seated on the bottom surface of the geothermal hole (G), and serves to support the airless pipe (10).

The support grid 20 was made by bending and connecting wires of metal or synthetic resin having strength sufficient to support several hundred meters of non-porous pipes. In more detail, the support grid 20 arranges circular wires up and down at regular intervals, and then connects the circular wires with straight wires to form a grid. Accordingly, the support grid 20 is formed with a plurality of large distribution holes 21 between the wires.

The recovery grid 30 has an outer diameter smaller than the inner diameters of the airless pipe 10 and the support grid 20, and is installed inside the support grid 20. In more detail, the retrieval grid 30 is formed in a grid form by arranging circular wires up and down at regular intervals and then connecting the circular wires with straight wires, wherein the support grid 20 is formed. Narrower than the spacing of the wires, i.e., the gap between the circular wires and the straight wires connecting the circular wires is denser than the supporting grid 20 so that a plurality of small distribution holes 31 are formed between the wires. do. As can be seen from the term, the small distribution hole 31 formed in the recovery grid 30 is smaller in size than the large distribution hole 21 formed in the support grid 20.

In addition, the support grid 20 is formed so that the seating portion 22 made of a wire on the top protrudes toward the center in a ring shape, the upper end of the recovery grid 30 to the ring-shaped seating portion 22 Is mounted. That is, a ring-shaped protrusion 32 protrudes outward from the upper end of the recovery grid 30, and the protrusion 32 of the recovery grid 30 is a seating part 22 of the support grid 20. ), The recovery grid 30 is installed on the support grid 20. When the recovery grid 30 is installed inside the support grid 20, the recovery grid 30 has a lower end spaced apart from the bottom surface of the geothermal hole G by a predetermined distance. That is, when the vertical length of the recovery grid 30 is smaller than the vertical length of the support grid 20 and the upper end of the recovery grid 30 is mounted on the upper end of the support grid 20, the recovery grid 30 is formed. It will be in the air.

In addition, the hook grid 33 is formed on the recovery grid 30. Since the object of the present invention is for the easy removal of slimes (Slime) in order to easily and cleanly remove the slime attached to the recovery grid 30, the recovery grid 30 from the inner lower side of the geothermal hole (G) to the ground You need to take it out. Hook fastening portion 33 is formed on the upper end of the recovery grid 30 for this need, the hook (H) is introduced from the ground coupled to the hook fastening portion 33, the recovery grid 30 is pulled to the ground It is raised. The recovery grid 30 raised to the ground cleans the slime attached to the periphery, and then hooks the hooks H to the hook fastening portions 33 and inserts them into the airless pipe 10 to seat the support grid 20. It rests on the part 22.

10: airless pipe 20: support grid
21: large distribution hall 22: seating part
30: recovery grid 31: small distribution hole
32: protrusion 33: hook fastening
G: geothermal hole H: hook

Claims (3)

An airless pipe 10 inserted into the geothermal hole G formed in the ground;
A support grid 20 installed at a lower end of the non-porous pipe 10 and seated on the bottom surface of the geothermal hole G, and having a plurality of large distribution holes 21 formed therein;
The outer diameter is formed smaller than the inner diameter of the non-porous pipe 10 and the support grid 20 is installed in the support grid 20, a plurality of small distribution holes 31 are formed, the hook is introduced from the ground ( The inner casing of the geothermal hole for easy removal of the slime, characterized in that consisting of ;; recovery grid 30, the hook fastening portion 33 is formed on the top so as to be coupled to the H to be pulled upward.
Claim 1
The support grid 20 is formed so that the seating portion 22 protrudes toward the center at the top,
The recovery grid (30) is the inner casing of the geothermal hole for easy removal of the slime, characterized in that the projecting portion (32) is mounted on the seating portion 22 is formed on the top.
The method according to claim 2,
The recovery grid 30 is the inner casing of the geothermal hole for easy removal of slime, characterized in that the bottom is spaced apart a predetermined distance from the bottom surface of the geothermal hole (G).

Images