KR20200069031A - Cooling apparatus of underground cable - Google Patents

Abstract

The present invention relates to a cooling apparatus of a pipeline-type underground cable comprising: a pipeline (310) for cooling installed on an upper side of a cable pipeline (210) in a pipeline-type underground line and provided with a cooling water outlet (310) formed along the outer circumference thereof; a main cooling pipe (320) which is inserted and installed in the pipeline (310) for cooling, and allows cooling water to move therethrough; an auxiliary cooling pipe (330) which is inserted and installed in the pipeline (310) for cooling, allows cooling water to move therethrough, and has a cooling water ejection port formed along the outer circumference thereof to eject cooling water; and a cooling plant (100) to create cooling water and circulate cooling water through the main cooling pipe (320) and the auxiliary cooling pipe (330). The present invention is applied to a pipeline-type underground line or a direct-burial underground line to supply cooling water to soil adjacent to an underground cable to directly reduce the thermal resistance of the soil and effectively exchange heat with the underground cable to effectively increase allowed power transmission capacity.

Description

Cooling system of pipeline type underground cable {COOLING APPARATUS OF UNDERGROUND CABLE}

The present invention relates to a cooling device for a pipelined underground cable, and more particularly, to a cooling device for a pipelined underground cable for cooling a pipelined underground transmission and distribution cable.

The transmission capacity of the underground line is determined by the ambient temperature and the heat resistance of the adjacent medium, and a section in which the transmission capacity is limited may occur depending on the laying method. For smooth power transportation, heat generated from the underground cable in a section where the power transmission capacity is limited must be discharged to the outside, and a cooling device is applied as a solution to this.

Underground cable lines are classified into electric power type, pipeline type, direct sale type, etc. according to the laying method. Commercialization of the cooling system is only for electric power type underground cable lines that have space for equipment, manpower in and out, work, and inspection in terms of construction and operation. have.

As shown in FIG. 1 and FIG. 2, the cooling device application method of the electric power underground type electric line is when the cooling water is made in the cooling station 10 and the cooling water is circulated through the cooling pipe 21 in the electric power sphere 20. 20) The temperature inside is lowered and exchanged with the heat generated from the underground cable (L), thereby increasing the allowable transmission capacity of the underground cable.

The cooling station 10 includes a cooling tower 11, a refrigerator 12, and a shrinking heat tank 13, and supplies cooling water to the cooling pipe 21 using the circulation pump 15 and circulates the cooling pipe 21 One cooling water is recovered and recirculated to the shrink heat bath (13).

2, the power tool 20 is provided with two cooling pipes 21 to the upper side where the underground cable (L) is located.

In terms of economics, the electric power old underground line has a disadvantage that it is 5 to 10 times more expensive to construct than the pipeline type underground line. On the other hand, the pipeline type underground cable has a disadvantage in that the allowable current is small and the transmission capacity is significantly limited.

As the number of lines increases, the difference between the allowable transmission capacity increases. Normally, the allowable current of the underground power cable is 1578[A]/line, whereas the allowable current of the underground cable is 154kV XLPE 2000 기준 885[A]/line is about 1.8 times different.

Nevertheless, it is true that no cooling device is applicable to the pipeline-type underground line so far, and the cooling device technology is concentrated only on the power-type underground line.

Patent Document 1: Registered Patent Publication No. 0660188 (registered on December 14, 2006)

An object of the present invention is to provide a cooling device for a pipeline-type underground cable that can be applied to a pipeline-type underground line or direct-selling underground line and can effectively increase the allowable transmission capacity.

According to the features of the present invention for achieving the above object, the present invention is installed on the upper side of the cable conduit in a conduit type underground electric line and is inserted into the cooling conduit and the cooling conduit where a cooling water outlet is formed along the outer diameter. The main cooling pipe and cooling water which are installed and inserted into the cooling pipe line are installed and the auxiliary cooling pipe and the cooling water are formed in which the cooling water moves and the cooling water is discharged along the outer diameter. It includes a cooling station to circulate the cooling water through.

And geotextiles surrounding the outer diameter of the cooling conduit.

The cooling conduit has an outer diameter in which convex portions and concave portions are continuous so that a space is formed between the cooling conduit and the geosynthetic fiber.

The cooling conduit is laid during construction of the underground conduit, and the main cooling pipe and the auxiliary cooling conduit are inserted and installed in the cooling conduit, if necessary.

It includes a waterproof member for preventing the leading end and the rear end of the cooling conduit in the state where the main cooling tube and the auxiliary cooling tube are inserted and installed in the cooling conduit.

The cooling water spout is formed only in a portion of the auxiliary cooling pipe located inside the cooling pipe.

The cooling station includes a cooling tower, a freezer, a shrinking heat tank and a circulation pump, and the circulation pump simultaneously supplies cooling water to the main cooling pipe and the auxiliary cooling pipe, or selectively supplies one of the two.

The cooling station is installed on one side or both sides of the pipeline type underground line section.

Two of the cooling conduits are installed on the upper side of the cable conduit in the conduit type underground electric line,

The main cooling pipe and the auxiliary cooling pipe are inserted and installed in each cooling conduit and connected to cooling stations installed on one side of the pipeline type underground line section or respectively connected to cooling stations installed on both sides so that cooling water can circulate. do.

The main cooling tube and the auxiliary cooling tube may be made of polyethylene.

In the present invention, the cooling conduit is laid in the construction of the underground conduit and is included in advance in the conduit type underground line. The cooling conduit is laid after wrapping it with geotextile, and the cooling conduit is provided with a main cooling pipe and an auxiliary cooling pipe to supply cooling water to adjacent soil, thereby directly reducing the thermal resistance of the soil in adjacent media and effectively exchanging underground cables and heat exchange. There is an effect that can increase the allowable transmission capacity of the underground cable.

In addition, according to the present invention, when the water content of the soil is high, only the cooling water is circulated through the main cooling pipe to cool the adjacent soil, thereby selecting a cooling method according to the water content of the soil.

In addition, the present invention has an effect of easy replacement and maintenance because the main cooling pipe and the auxiliary cooling pipe are easily removed from the cooling pipe.

In addition, according to the present invention, when cooling of a conduit-type underground electric line is not required, the cooling conduit can be utilized as a preliminary hole, thereby effectively utilizing a cooling conduit.

1 is a view showing a cooling device of an electric power underground cable.
Figure 2 is a cross-sectional view showing the location and number of cooling pipe installation of the electric power.
Figure 3 is a view showing the installation position and number of the cooling pipe in the pipeline-type underground electric wire according to the present invention.
Figure 4 is a block diagram showing a cooling device for a pipeline type underground cable according to the present invention.
Figure 5 is a partial perspective view showing a state in which the main cooling pipe and the auxiliary cooling pipe is installed in the cooling pipe according to the present invention.
Figure 6 is a partial perspective view showing a cooling conduit according to the present invention.
7 is a partial perspective view showing a main cooling tube according to the present invention.
8 is a partial perspective view showing an auxiliary cooling tube according to the present invention.
9 is a view for explaining a method of laying a cooling pipe in a cooling pipe according to the present invention.

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

The cooling device for the pipeline type underground cable of the present invention is for cooling the underground cable installed in the pipeline type underground cable. Pipeline type underground line has lower allowable current than electric power type underground line. One of the reasons is that the heat dissipation of the underground cable is very difficult and the heat dissipation of the underground cable is very difficult. Accordingly, a cooling device for the pipeline type underground cable is provided to effectively increase the allowable transmission capacity of the pipeline type underground line.

3 and 4, the cooling device 300 of the pipeline type underground cable includes a cooling channel 310, a main cooling tube 320, an auxiliary cooling tube 330, and a cooling station 100 do.

The cooling conduit 310 is installed on the upper side of the cable conduit 210 in the conduit type underground electric line. Pipeline underground cables are constructed by constructing manholes at appropriate intervals and laying underground pipes between manholes to put underground cables in the underground pipes. And underground cables are connected in the manhole.

As shown in Figure 3, the pipeline-type underground electric line includes a cable pipeline 210 and a communication pipeline 220, and the pipeline is fixed by backfilling it with sand, the upper part of which is filled with earth and sand, and the upper part of the earth and sand is wrapped. To close.

The cooling conduit 310 is installed on the upper side of the cable conduit 210 in the conduit type underground electric line. In the embodiment, the cooling conduit 310 is installed on the upper side of the cable conduit 210 in the conduit type underground electric line with the communication conduit 220 interposed therebetween.

The cooling conduit 310 circulates cooling water or supplies cooling water to the soil to directly reduce the thermal resistance of the underground cable and the adjacent medium, the soil being laid in the cable conduit, and to effectively perform heat exchange between the cooling water and the underground cable. At this time, the cooling conduit 310 should be installed on the upper side of the cable conduit 210 so that the cooling water supplied from the cooling conduit 310 to the soil moves downward to cool the cable conduit 210.

As shown in Figure 4, the cooling conduit 310 is formed with a cooling water outlet 311 at regular intervals along the outer diameter. The cooling water outlet 311 is a hole for supplying cooling water to the soil.

The main cooling pipe 320 and the auxiliary cooling pipe 330 are inserted and installed in the cooling pipe 310. The cooling conduit 310 is laid in the construction of the underground conduit, and the main cooling conduit 320 and the auxiliary cooling conduit 330 are inserted and installed in the cooling conduit 310 when cooling is required.

The main cooling tube 320 is a tube that allows cooling water to move and circulate.

The auxiliary cooling pipe 330 is a pipe through which the cooling water moves and the cooling water is ejected along the outer diameter. The auxiliary cooling tube 330 is provided with cooling water jets 331 at regular or irregular intervals along the outer diameter. The cooling water ejected from the auxiliary cooling pipe 330 may be received from the cooling pipe 310 and may be supplied to the surrounding soil through the cooling water outlet 311 of the cooling pipe 310.

The cooling conduit 310 is enclosed in the outer diameter of the geosynthetic fiber 340. The geosynthetic fiber 340 functions to reinforce the strength of the cooling pipe 310 together with a filter function by retaining proper water permeability and strength while preventing foreign matter such as soil from being introduced into the cooling pipe 310.

The cooling station 100 makes cooling water and circulates the cooling water through the main cooling tube 320 and the auxiliary cooling tube 330.

The cooling station 100 includes a cooling tower 110, a freezer 120, a heat shrink tank 130, and a circulation pump 150.

The cooling tower 110 and the freezer 120 are configured to cool the cooling water stored in the shrink heat storage tank 130. The circulation pump 150 circulates the cooling water by simultaneously supplying cooling water stored in the shrinking heat storage tank 130 to the main cooling tube 320 and the auxiliary cooling tube 330 or selectively to one of the two. When the water content of the soil is high, the supply of cooling water to the auxiliary cooling tube 330 may be stopped and cooling water may be supplied only to the main cooling tube 320.

The cooling water supplied to the main cooling pipe 320 and the auxiliary cooling pipe 330 is supplied to one side of the main cooling pipe 320 and the auxiliary cooling pipe 330 and is provided to the main cooling pipe 320 and the auxiliary cooling pipe 330. It is re-supplied to the shrink heat storage tank 130 through the opposite side, and the cooling water supplied to the shrink heat storage tank 130 is re-cooled by the cooling tower 110 and the refrigerator 120.

The cooling station 100 may be installed on one side or both sides of a pipeline type underground line section.

Two cooling conduits 310 may be installed on the upper side of the cable conduit 210 in the conduit type underground electric line, and the main cooling conduit 320 and the auxiliary cooling conduit 330 are respectively provided in the conduit 310 for cooling. This can be embedded. In addition, the main cooling pipe 320 and the auxiliary cooling pipe 330 may be connected to the cooling stations 100 installed on one side of the pipeline-type underground electric line section or to cooling stations installed on both sides to allow cooling water to circulate. have.

When the cooling station 100 is installed on both sides of the pipelined underground line section, the cooling water circulation is easier and the cooling efficiency can be higher than when the cooling station 100 is installed on one side of the pipelined underground line section. . In the embodiment, for example, a case where the cooling station 100 is installed on one side of a pipeline-type underground electric line section is illustrated.

5 and 6, the cooling conduit 310 has a convex portion 310a and a concave portion 310b so that a space is formed between the cooling conduit 310 and the geosynthetic fiber 340. It has an outer diameter of the form. Cooling water can be smoothly discharged from the cooling water outlet 311 through a space between the cooling conduit 310 and the geosynthetic fiber 340 and can flow to the soil through the geosynthetic fiber 340.

Geotextile 340 may include a geotextile that is a porous product, a geomembrane that is a water-repellent product, a geogrid and a geotextile that are high-strength products. Geotextile 340 protects the cooling conduit 310 by retaining proper permeability and strength while preventing foreign matter from entering the cooling conduit 310.

The main cooling pipe 320 and the auxiliary cooling pipe 330 may be inserted and installed side by side in the cooling pipe 310. Alternatively, only the auxiliary cooling tube 330 may be inserted and installed in the cooling conduit 310 or only the main cooling tube 320 may be inserted and installed. The main cooling tube 320 and the auxiliary cooling tube 330 may be tubes having the same diameter. The main cooling tube 320 and the auxiliary cooling tube 330 may be made of polyethylene material.

It includes a waterproof member 350 to prevent the leading and trailing ends of the cooling conduit 310 in a state where the main cooling tube 320 and the auxiliary cooling tube 330 are inserted and installed in the cooling conduit 310.

The waterproof member 350 is to prevent the inflow of cooling water into the manholes (M1, M2 in FIG. 9) located on both sides of the pipeline. To this end, the cooling water jetting port 331 in the auxiliary cooling pipe 330 is formed only in a portion located inside the cooling pipe 310.

As shown in FIG. 7, the main cooling tube 320 has a shape without a hole in the outer diameter, and as shown in FIG. 8, the auxiliary cooling tube 330 has cooling water spouts 331 at regular intervals along the outer diameter. Is formed.

The main cooling tube 320 and the auxiliary cooling tube 330 may be formed by dividing one tube into two. This allows the main cooling pipe 320 and the auxiliary cooling pipe 330 to be inserted into the cooling pipe 310 to be easily installed.

As illustrated in FIG. 9, a method of installing a cooling pipe in the cooling pipe 310 supports the cooling pipe drum 410 with a drum support 420 or the like on one side of the cooling pipe 310 and supports scaffolding and structures ( 430) to maintain the allowable radius of curvature of the cooling tubes 320 and 330. In order to minimize the tension of the cooling pipes 320 and 330 during installation, the rollers 440 support the cooling pipes 320 and 330, and the ends of the cooling pipes 320 and 330 are connected by clamps or pulling eyes 450, for pulling. It is connected to the wire 470 to pass the cooling conduit 310. On the other side of the cooling conduit 310, a circumference 480 is installed to connect the pulling wire 470 passing the cooling conduit 310.

At this time, in order to monitor the installed tension, a tension meter 460 is installed inside the lower manhole (M2) or inside the original teeth (480) to measure the tension, and the cooling pipes (320,330) are driven by driving the original teeth (480). It can be safely installed inside the cooling conduit (310).

At this time, the cooling pipes 320 and 330 are respectively inserted into the cooling pipes 320 and 330 into two cooling pipes 310 through the manhole M1 on one side of the cooling pipe 310 and the other side of the cooling pipe 310 on the other side. The two cooling tubes 320 and 330 may be interconnected in the manhole M2.

Here, the cooling pipes are the main cooling pipe 320 and the auxiliary cooling pipe 330.

After the main cooling pipe 320 and the auxiliary cooling pipe are installed in the cooling pipe 310, the front and rear ends of the cooling pipe 310 are blocked with a waterproof member 350, and then the main cooling pipe 320 and the auxiliary pipe are supplemented. The cooling station 100 is connected to the cooling tube 330.

Hereinafter, the operation of the present invention will be described.

In the present invention, the cooling conduit 310 is laid in the construction of the underground conduit, and is included in advance in the conduit type underground electric line. The cooling conduit 310 is laid after wrapping it with a geosynthetic fiber 340 having adequate water permeability and strength in order to prevent foreign matter from entering the inside of the cooling conduit 310 and the uniform ejection of cooling water.

The main cooling pipe 320 and the auxiliary cooling pipe 330 are inserted and installed in the cooling pipe 310 when the underground cable needs to be cooled. The main cooling pipe 320 is formed so that the cooling water moves and circulates, and the auxiliary cooling pipe 330 is formed with cooling water ejection openings 331 at regular intervals so that the cooling water can be ejected while moving.

While the main cooling pipe 320 and the auxiliary cooling pipe 330 are inserted and installed in the cooling pipe 310, the front and rear ends of the cooling pipe 310 are blocked with a waterproof member 350, thereby manholes M1 and M2. Prevent the inflow of cooling water into the interior.

The cooling water to be supplied to the main cooling pipe 320 and the auxiliary cooling pipe 330 may selectively use groundwater together with cooling water of the cooling station according to the conditions of securing the flow rate of the water collection wells in the manholes M1 and M2 located on both sides of the pipeline.

For example, the operation method of the cooling station precedes the operation for improving the cooling efficiency by supplying cooling water to the auxiliary cooling pipe 330 in one step to increase the moisture content of the soil around the cooling pipe 310 and reduce heat resistance. .

In 2 stages, the cooling water is supplied to the main cooling pipe 320 and circulated to perform continuous operation to continuously lower the temperature of the underground cable installed in the surrounding soil and the cable pipe 210. It can be cooled very efficiently.

This is based on the principle that the soil's heat resistance is greatly affected by the water content, and the higher the water content, the less the soil's heat resistance.The coolant supplied to the soil directly reduces the heat resistance of the adjacent medium soil and heat exchanges with underground cables. This effectively increases the permissible transmission capacity of the underground cable.

The present invention can provide cooling water to adjacent soil by laying a cooling conduit in advance on a conventional conduit type underground electric line and, if necessary, installing a cooling conduit on the cooling conduit. This directly reduces the extreme heat resistance of the adjacent medium, soil, and facilitates efficient operation and management of the cooling system in order to increase the transmission capacity of the pipelined or direct sale underground cable.

In addition, the present invention further expands the construction of a pipeline type underground electric line that is economical and absolutely advantageous in terms of construction, such as air, and is absolutely advantageous in terms of construction, such as air, without the need to construct only a high-priced electric power underground cable. I can go out.

In addition, the present invention can effectively increase the permissible power transmission capacity by cooling only a portion of the power line and the pipeline required, such as the underground section of the underground line and the hot spot of the pipeline-type underground line, effectively cooling the cooling station in both directions of the cooling line. In conjunction, the cooling performance can be further improved.

In addition, the present invention does not need to install a cooling device such as a main cooling tube and an auxiliary cooling tube at the beginning of the pipeline construction, and when necessary, the main cooling tube and the auxiliary cooling tube can be installed and connected to the cooling station, If cooling is not required, a cooling conduit can be used as a spare hole. In this case, the main cooling pipe and the auxiliary cooling pipe are easy to be removed and replaced in the cooling pipe and easy to maintain.

The present invention has been described with the best embodiments in the drawings and specifications. Here, although specific terms are used, they are used for the purpose of describing the present invention only, and are not used to limit the scope of the present invention described in the meaning limitation or the claims. Therefore, the present invention will be understood by those skilled in the art that various modifications and other equivalent embodiments are possible. Therefore, the true technical scope of the present invention should be defined by the technical spirit of the appended claims.

100: cooling station 110: cooling tower
120: refrigerator 130: heat shrink tank
150: circulation pump 200: pipeline
210: cable conduit 220: communication conduit
300: cooling device 310: cooling channel
310a: Convex portion 310b: Concave portion
320: main cooling tube 330: auxiliary cooling tube
331: cooling water spout 340: geotextile
350: waterproof member 410: cooling tube drum
420: drum stand 430: scaffolding and structures
440: roller 450: clamp or pulling eye
460: tension meter 470: pulling wire
480: Want

Claims (14)

A cooling conduit installed on the upper side of the cable conduit in the pipeline-type underground electric line and having a cooling water outlet along an outer diameter;
A main cooling pipe inserted and installed in the cooling pipe and to which cooling water moves; And
Included in the cooling channel is inserted into the cooling channel, the cooling water is moved and an auxiliary cooling tube is formed with a cooling water spout through which cooling water is ejected along an outer diameter.
Cooling apparatus of a pipeline type underground cable, characterized in that the cooling water circulates through the main cooling pipe and the auxiliary cooling pipe. The method according to claim 1,
Cooling apparatus of a pipeline type underground cable, characterized in that it comprises a geotextile surrounding the outer diameter of the cooling pipe. The method according to claim 2,
A cooling device for a conduit type underground cable, characterized in that the cooling conduit has an outer diameter with a convex portion and a concave portion continuously so that a space is formed between the cooling conduit and the geosynthetic fiber. The method according to claim 1,
The cooling pipe is laid in the construction of the underground pipe,
The main cooling pipe and the auxiliary cooling pipe is a cooling device for a pipeline type underground cable, characterized in that inserted into the cooling pipe if necessary. The method according to claim 4,
A cooling device for a pipeline type underground cable, characterized in that it comprises a waterproof member for blocking the leading and trailing ends of the cooling conduit in a state where the main cooling tube and the auxiliary cooling tube are inserted and installed in the cooling conduit. The method according to claim 5,
The cooling water spout is a cooling device for a pipeline type underground cable, characterized in that it is formed only in a portion located inside the cooling pipe in the auxiliary cooling pipe. The method according to claim 1,
And a cooling station for circulating the cooling water by supplying cooling water to the main cooling tube and the auxiliary cooling tube. The method according to claim 7,
The cooling station
It includes a cooling tower, a freezer, a heat shrink tank and a circulation pump,
The circulation pump is a cooling device for a pipeline type underground cable, characterized in that the cooling water is simultaneously supplied to the main cooling pipe and the auxiliary cooling pipe or selectively supplied to one of the two. The method according to claim 8,
The cooling station
A cooling device for a pipeline type underground cable, characterized in that it is installed on one side or both sides of the pipeline type underground line section. The method according to claim 1,
The main cooling pipe and the auxiliary cooling pipe is a cooling device of a pipeline type underground cable, characterized in that made of polyethylene material. A cooling conduit installed on the upper side of the cable conduit in the pipeline-type underground electric line and having a cooling water outlet along an outer diameter;
An auxiliary cooling pipe inserted into and installed in the cooling pipe and formed with a cooling water spout through which cooling water moves and cooling water spouts along an outer diameter; And
A cooling station that creates cooling water and circulates cooling water through the auxiliary cooling pipe;
Cooling apparatus of the pipeline type underground cable, characterized in that it comprises a. The method according to claim 11,
Cooling apparatus of a pipeline type underground cable, characterized in that it comprises a geotextile surrounding the outer diameter of the cooling pipe. The method according to claim 11,
Cooling apparatus of a pipeline type underground cable, characterized in that it comprises a waterproof member for blocking the leading and trailing ends of the cooling pipe in the state where the auxiliary cooling pipe is inserted and installed in the cooling pipe. The method according to claim 11,
A cooling device for a pipeline type underground cable, characterized in that it includes a main cooling tube through which the cooling water moves, being inserted and installed in parallel to the auxiliary cooling tube.

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