JP2000139019A - Cooling device for underground power transmission line - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a power transmission line inside a utility tunnel to properly be cooled without increasing the size of a cooling device and its cost. SOLUTION: This cooling device keeps the inside temperature of an utility tunnel 12 at a given temperature by cooling the inside of the utility tunnel 12, and cools the power transmission line 14 indirectly. Ice made by a dynamic ice making and freezing machine 23 of a cooling facility 21 is stored inside an ice heat storage tank 24. Then, cooling water containing this ice is sent out by a conveying pump 26 into a cooling pipe 22 extended inside the utility tunnel 12 and provided with a cold reserving member 30 on the outside circumference of its initial section. The inside of the utility tunnel is cooled by recycling the cooling water inside the tunnel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling device for an underground transmission line for indirectly cooling a transmission line disposed in a tunnel formed underground.

[0002]

2. Description of the Related Art FIG. 8 schematically shows a conventional underground transmission line cooling device. In the conventional underground transmission line cooling device, FIG.
As shown in the figure, a tunnel 101 having a predetermined diameter is formed in the ground,
A transmission line 102 is provided in the cave 101. on the other hand,
A cooling facility 105 having a cold water refrigerator 103 and a water heat storage tank 104 is provided on the ground, and the cooling water generated by the cold water refrigerator 103 is stored in the water heat storage tank 104. And
A cooling pipe 106 extends from the water heat storage tank 104 to the canal 101, and the cooling pipe 106 is disposed so as to return to the water heat storage tank 104 again. Is equipped with a water supply pump 107.

[0003] Therefore, in the cooling facility 105, the cold water refrigerator 103
The cooling water generated in is stored in the water heat storage tank 104, and the cooling water in the water heat storage tank 104 is sent out to the cooling pipe 106 by the water supply pump 107, and the cooling water in the cooling pipe 106 causes Cool inside. Therefore, the transmission line 102 provided in the tunnel 101 is indirectly cooled.

[0004]

As described above, the cooling water from the cooling facility 105 is introduced into the cave 101 through the cooling pipe 106, and the inside of the cave 101 is cooled, whereby the transmission line 1 is indirectly cooled.
02 is cooling. FIG. 9 shows a graph of the temperature in the tunnel and the temperature of the cooling water in the cooling pipe with respect to the distance between the tunnel and the cooling pipe. As shown in the graph of FIG. 9, generally, a specified temperature in the cave necessary for cooling the transmission line 102 is set, and the temperature of the cave is reduced by the cooling water in the cooling pipe 106 to a value equal to or lower than the specified temperature in the cave. Has been maintained.

[0005] In this case, the temperature of the cooling water supplied from the cooling equipment 105 to the cooling pipe 106 is low in the initial section, and as the distance becomes longer, the temperature of the cooling water increases to cool the inside of the cave 101. To go. On the other hand, the temperature in the sinus is also low in the initial section, and as the distance increases, the temperature rises and approaches the prescribed temperature in the sinus.

In order to properly cool the transmission line 102 disposed over a predetermined distance in the tunnel 101, it is necessary to maintain the temperature in the tunnel below the specified temperature in the tunnel.
If the length of the power transmission line 102 is long, the cooling efficiency will decrease.Therefore, it is necessary to increase the cooling water supply flow rate by increasing the size of the cooling pipe 106 or increasing the number of pipes. There is a problem that the cost and cost increase.

In the above-described underground power transmission line cooling device, a cooling water flow rate g _W shown below is required with respect to a required cooling heat quantity Q for cooling by sensible heat. Note that C
_P is the specific heat of water, the T _i cold water inlet temperature, T _o is the chilled water outlet temperature. g _W = Q / {C _P (T _o −T _i )}

Further, the ambient temperature T and the cold water inlet temperature T_i(1
Logarithmic average temperature difference ΔT _mWCan not take large
Therefore, the surface area A of the cooling pipe 106_W(Q / KΔT_mW, K is
The heat transmission rate) increases. Therefore, cooling piping
Water feed pons that supply cooling water to the 106 and increase the size of the cooling pipe 106
Cost increase due to high output of
High output and high cost by increasing the cooling water generated by the freezer 103
There is a problem that the cost is reduced.

The present invention solves such a problem, and an underground transmission line cooling device capable of appropriately cooling a transmission line in a tunnel without increasing the size and cost of the device is provided. The purpose is to provide.

[0010]

According to a first aspect of the present invention, there is provided a cooling apparatus for an underground power transmission line, which indirectly connects a transmission line disposed in a tunnel formed in the ground. A cooling device for generating cooling water and storing it in a heat storage tank, a cooling pipe disposed in the cave, and a cooling pipe for cooling water in the heat storage tank. And a cooling member attached to an outer peripheral portion of the cooling pipe only in an initial section of the cooling pipe extending from the heat storage tank into the cave. is there.

According to a second aspect of the present invention, there is provided an underground transmission line cooling device for indirectly cooling a transmission line disposed in a cave formed in the ground. Cooling equipment for generating cooling water and storing it in the heat storage tank, a first cooling pipe disposed in the cave, and branching off from the first cooling pipe for each predetermined section of the first cooling pipe. Multiple second
, A water pump for supplying cooling water in the heat storage tank to the first cooling pipe, and a cooling member attached to an outer peripheral portion of the first cooling pipe. Things.

According to a third aspect of the present invention, there is provided a cooling device for an underground transmission line for indirectly cooling a transmission line disposed in a cave formed underground. A cooling facility that generates cooling water and stores the cooling water in the heat storage tank; a plurality of cooling pipes disposed in the cave; a water pump that supplies cooling water in the heat storage tank to each of the cooling pipes; A plurality of cooling members each having a different length attached to the outer peripheral portion of each of the cooling pipes so as to gradually increase from an initial section of the cooling pipe extending from the tank into the cave. It is a feature.

Further, in the underground power transmission line cooling apparatus according to the present invention, the cooling facility discharges supercooled water from a nozzle and collides with a collision plate to generate ice by collision energy. It is characterized by comprising a refrigerator and an ice heat storage tank for storing ice generated by the dynamic ice making refrigerator together with cooling water.

Further, the underground power transmission line cooling device according to claim 5 is an underground power transmission line cooling device for indirectly cooling a power transmission line disposed in a cave formed in the ground. A dynamic ice chiller that generates ice by collision energy by discharging supercooled water from a nozzle and colliding with a collision plate, an ice heat storage tank that stores ice generated by the dynamic ice chiller together with cooling water, A cooling pipe is provided in the cave, and a water pump for supplying cooling water in the ice heat storage tank to the cooling pipe is provided.

[0015]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a schematic diagram of an underground power transmission line cooling device according to a first embodiment of the present invention, FIG. 2 is a cross section of the underground power transmission line, and FIG. 3 is a graph showing the temperature in a sinus and the temperature of cooling water in a cooling pipe with respect to the distance of the cooling pipe.

In the underground power transmission line cooling device of the present embodiment, as shown in FIG.
A sinus 13 having a predetermined diameter is formed between the tunnels 1 and 12, and a transmission line 14 is disposed in the sinus 13. This cave 13
As shown in detail in FIG. 2, has a vertically long rectangular cross section, a plurality of shelves 15 to 19 are formed on both sides,
19 support different types of transmission lines 14a to 14d.

On the other hand, a cooling facility 21 is provided on the ground, and a cooling pipe 22 extends from the cooling facility 21 into the cave 13. The cooling equipment 21 includes a cold water refrigerator 2
3, a water heat storage tank 24, and a water pump 25. The cold water refrigerator 23 generates cooling water using the cooling water supplied from the cooling water supply device 26, and stores the generated cooling water in the water heat storage tank 24. A water supply pump 25 is mounted on a pipe downstream of the water heat storage tank 24, and a cooling pipe 22 mounted on the water supply pump 25 is extended from the terminal 11 side to the canal 13, and
When it reaches the second side, it reverses, returns to the terminal 11 side, and is connected to the water heat storage tank 24. That is, the cooling water stored in the water heat storage tank 24 is guided into the cave 13 through the cooling pipe 22 and returned to the water heat storage tank 24 again.

In this embodiment, six cooling pipes 22 are provided, and are supported by shelves 15 in the sinus passage 13 as shown in detail in FIG. The six cooling pipes 22 extending from the water heat storage tank 24 into the cave 13 are provided with a cooling member 30 on the outer periphery only in the initial section.
Urethane or other heat insulating material is preferable as the cold insulating member 30.

Also, as shown in FIG.
A temperature sensor 31 for detecting the temperature of the cooling water is provided at an outlet portion of the apparatus, and a temperature sensor 32 for detecting the internal temperature is provided at a predetermined position of the sinus passage 13. The detection results of the temperature sensors 31 and 32 are transmitted to the control unit 33.
Output to The controller 33 adjusts the supply flow rate of the cooling water to the cooling pipe 22 by the water supply pump 25 based on the temperature of the cooling water and the temperature in the cave 13 so as to maintain the temperature in the cave 13 at a predetermined temperature.

In the cooling device for underground transmission lines configured as described above, in the cooling facility 21 on the ground, a cooling water supply device 26
The cooling water is circulated and supplied to the chilled water refrigerator 23, and the chilled water chiller 23 guides the cooling water in the water heat storage tank 24 to the chilled water refrigerator 23 to generate the cooling water, thereby forming the water heat storage tank 24.
It is stored in. Then, the cooling water stored in the water heat storage tank 24 is sent out to the cooling pipe 22 by the water supply pump 25, and circulates in the cave 13 to cool the inside. In this case, the cooling capacity of the cooling pipe 22 is suppressed by suppressing the heat radiation in the initial section covered by the cool insulating member 30, and the cooling pipe 22 has the normal cooling capacity in the section where the cooling pipe 22 is a bare pipe. The cooling water whose temperature has risen by cooling the inside of 13 is returned to the water heat storage tank 24. At this time, the controller 33 adjusts the supply flow rate of the cooling water to the cooling pipe 22 by the water supply pump 25 based on the supply temperature of the cooling water from the water heat storage tank 24 and the temperature in the cave 13, and The inside temperature of the transmission line 13 is maintained at a predetermined temperature, and the transmission line 14 is appropriately cooled.

As described above, in the underground transmission line cooling device of the present embodiment, the cooling water generated by the nest refrigerator 23 of the cooling facility 21 is stored in the water heat storage tank 24, and this cooling water is The water is sent to the cooling pipe 22 by the water supply pump 25, and the passage 1
3, and at this time, the cooling pipe 22 is
The cooling capacity is suppressed in the initial section covered with the cooling pipe, and the normal cooling capacity is set in the section where the cooling pipe 22 is a bare pipe, thereby cooling the inside of the cave 13 and setting the internal temperature to a predetermined temperature. Can be maintained and the transmission line 14 can be indirectly cooled.

In this case, as shown in the graph of FIG. 3, in the initial section where the cooling pipe 22 is covered with the cooling member 30,
Since the cooling water in the cooling pipe 22 is kept cool to some extent, the temperature in the sinus (solid line in FIG. 3) is higher than the conventional temperature in the sinus (dotted line in FIG. 3), but is lower than the prescribed temperature in the sinus. I have. On the other hand, in the section in which the cooling pipe 22 becomes a bare pipe after the initial section, the temperature in the sinus (solid line in FIG. 3) is reduced by the cooling water kept by the cool insulating member 30 (see FIG. 3). 3 (dotted line). As a result, the transmission line 14 disposed over a long distance in the tunnel 13 can be appropriately cooled, and the cooling pipe 2
2 and the number of pipes can be reduced to reduce the supply flow rate of the cooling water, so that the size and cost of the device can be reduced.

In the above-described embodiment, the water heat storage tank 2
The cooling water stored in 4 is passed through the cooling pipe 22 to the passage 13.
After the cooling water was returned to the water heat storage tank 24 after being guided into the cooling water storage tank 24, the cooling water returned to the cooling equipment 21 through the cooling pipe 22 was directly cooled by the cold water freezer 23 to generate cooling water. You may.

FIG. 4 shows an outline of an underground power transmission line cooling device according to a second embodiment of the present invention, and FIG. 5 shows an outline of a dynamic ice making refrigerator and an ice heat storage tank. Note that members having the same functions as those described in the above-described embodiment are denoted by the same reference numerals, and redundant description will be omitted.

In the underground power transmission line cooling device of this embodiment, as shown in FIG.
A sinus 13 having a predetermined diameter is formed between the tunnels 1 and 12, and a transmission line 14 is disposed in the sinus 13. On the other hand, a cooling facility 41 is provided on the ground, and a cooling pipe 42 extends from the cooling facility 41 into the tunnel 13. The cooling equipment 41 includes a dynamic ice making refrigerator 43, an ice heat storage tank 44, an IPF regulator 45, and water pumps 46 and 47.
And The dynamic ice making refrigerator 43 generates supercooled water by using the cooling water supplied from the cooling water supply device 48, discharges the supercooled water from the nozzles to collide with the collision plate, thereby forming ice by the collision energy. To generate. The ice heat storage tank 44 stores the ice generated by the dynamic ice making refrigerator 43 together with the cooling water. The IPF adjuster 45 adjusts a supply flow rate of cooling water containing ice (hereinafter referred to as ice cooling water) to the cooling pipe 42.

The ice heat storage tank 44 and the IPF adjuster 45
A water supply pump 46 is interposed in a pipe between the water supply pump 47 and a water supply pump 47 is mounted on a pipe on the downstream side of the IPF regulator 45. The cooling pipe 42 mounted on the water supply pump 47 is connected to the passage 13 from the terminal 11 side. When it reaches the terminal 12 side, it reverses and returns to the terminal 11 side.
4. That is, the ice cooling water stored in the ice heat storage tank 44 is guided into the tunnel 13 through the cooling pipe 42 and returned to the ice heat storage tank 44 again.

In the present embodiment, the six cooling pipes 42 are provided, and the six cooling pipes 42 extending from the ice heat storage tank 44 into the cave 13 are provided on the outer peripheral portion only in the initial section. The cold insulator 30 is mounted.

Here, the dynamic ice making refrigerator 43 and the ice heat storage tank 44 will be specifically described. As shown in FIG. 5, cooling water in which sherbet-shaped ice floats is stored in the upper part of the ice heat storage tank 44, and the ice making pump 51, the filter 52, and the A pipe 54 having a flow meter 53 is connected. A pipe 55 is connected from the dynamic ice making refrigerator 43 to the ice heat storage tank 44, and a nozzle 56 is attached to a tip of the pipe 55. The nozzle 56 is opposed to the nozzle 56 and collides above the ice heat storage tank 44. A plate 57 is mounted. Cooling water is circulated from the cooling water supply device 58 to the dynamic ice making refrigerator 43 through a pipe 59 having a cooling water pump 58.

Therefore, cooling water stored in the lower portion of the ice heat storage tank 44 is supplied to the dynamic ice making refrigerator 43 through the pipe 54 by the ice making pump 51, and the cooling water is supplied from the cooling water supply device 48 to the dynamic ice making device 43. Refrigerator 4
The cooling water circulated through the cooling water 3 becomes supercooled water, and is supplied to the ice heat storage tank 44 through the pipe 55. At this time, the supercooled water is discharged from the nozzle 56 toward the collision plate 57, and dynamic ice is generated by the collision energy, and is sequentially stored in the ice heat storage tank 44.

Further, as shown in FIG.
Temperature sensor 61 for detecting the temperature of ice cooling water at the outlet
Are provided, and a temperature sensor 62 for detecting an internal temperature is provided at a predetermined position of the sinus 13.
The detection results of the temperature sensors 61 and 62 are transmitted to the control unit 6.
3 is output. The control unit 63 controls the IPF regulator 45 based on the temperature of the ice cooling water and the temperature in the cave 13 so as to maintain the temperature in the cave 13 at a predetermined temperature. Adjust the cooling water supply flow rate.

In the underground power transmission line cooling device thus configured, the cooling water supply device 48
The cooling water is circulated and supplied to the dynamic ice chiller 43 from the chiller 43. The dynamic ice chiller 43 guides the cooling water in the ice heat storage tank 44 to the dynamic ice chiller 43 to generate dynamic ice. It is stored in the heat storage tank 44. Then, the ice cooling water stored in the ice heat storage tank 44 is sent out to the cooling pipe 42 by the water supply pumps 46 and 47, and circulates in the cave 13 to cool the inside. In this case, the cooling capacity of the cooling pipe 42 is suppressed in the initial section covered with the cooling member 30, and the cooling capacity is set to the normal cooling capacity in the section where the cooling pipe 42 is a bare pipe.
The cooling water that has cooled the inside and has increased in temperature is returned to the water heat storage tank 44. At this time, the control unit 63 determines the water supply pump 4 based on the supply temperature of the cooling water from the water heat storage tank 44 and the temperature in the cave 13.
5, the flow rate of the cooling water supplied to the cooling pipe 42 is adjusted to maintain the temperature in the tunnel 13 at a predetermined temperature.
4 is properly cooled.

As described above, in the underground power transmission line cooling device of the present embodiment, the ice made by the dynamic ice making refrigerator 43 of the cooling facility 41 is stored in the ice heat storage tank 44 and contains this ice. The cooling water is sent out to the cooling pipe 42 by the water supply pumps 46 and 47 and circulates in the cave 13. At this time, the cooling capacity is suppressed in the initial section where the cooling pipe 42 is covered with the cooling member 30. By setting the normal cooling capacity in the section where the pipe 42 is a bare pipe, the inside of the sinus 13 is cooled, the internal temperature is maintained at a predetermined temperature, and the transmission line 14 can be indirectly cooled.

In this case, in the initial section in which the cooling pipe 42 is covered with the cooling member 30, since the cooling water in the cooling pipe 42 is kept to a certain extent, the temperature in the cave is higher than before, but is lower than the specified temperature in the cave. It has become. On the other hand, in the section where the cooling pipe 42 has become a bare pipe after this initial section, the temperature in the cave is lower than in the past due to the cooling water kept cool by the cool keeping member 30. As a result, Cave 1
3, the transmission line 14 disposed over a long distance can be appropriately cooled, and the cooling pipe 42 can be thinned or the number of pipes can be reduced to reduce the supply flow rate of the cooling water. The size and cost of the device can be reduced.

The temperature of the ice cooling water supplied into the cooling pipe 42 is 0 ° C., and the cooling efficiency is higher than the cooling water temperature of 10 ° C. That is, since the sensible heat is used for cooling, the flow rate g _S of the ice cooling water with respect to the required amount of cooling heat Q can be reduced. Incidentally, h is sensible ice cooling water, the C _P the specific heat of water, T _i 'is the cold water inlet temperature, the T _o a coolant outlet temperature. g _S = Q / {h + C _P (T _o −T _i ′)} Also, since the logarithmic average temperature difference ΔT _mS between the ambient temperature T and the chilled water inlet temperature T _i ′ (about 0 ° C.) can be large, the cooling pipe 42 surface area a _S of the (Q / KΔT _mS, K is the thermal transfer coefficient) can be small is.

Therefore, the transmission line 14 can be cooled with a small flow rate, and the power of the water supply pumps 46 and 47 can be reduced, and the diameter of the cooling pipe 42 can be reduced to reduce the size and cost of the apparatus. Can be achieved.

In the embodiment described above, the ice heat storage tank 4
The ice-cooled water stored in the storage channel 4 is passed through the cooling pipe 42 to the tunnel 1
The cooling water returned to the cooling facility 41 through the cooling pipe 42 is directly cooled by the dynamic ice making refrigerator 43 to generate supercooled water after being guided into the inside 3 and cooling the inside. You may make it.

FIG. 6 shows an outline of a cooling device for an underground transmission line according to a third embodiment of the present invention. Note that members having the same functions as those described in the above-described embodiment are denoted by the same reference numerals, and redundant description will be omitted.

In the underground power transmission line cooling device of this embodiment, as shown in FIG.
A cave 13 is formed between 1 and 12, and a transmission line 14 is provided in the cave 13. On the other hand, a cooling facility 41 is provided on the ground, and this cooling facility 41 generates ice by the collision energy by colliding supercooled water with the collision plate, as in the above-described embodiment, and stores ice heat. The tank stores ice and cooling water. A first cooling pipe 71 and second cooling pipes 72a to 72e extend from the cooling facility 41 in the tunnel 13, and the cooling water stored in the ice heat storage tank is supplied by a water pump (not shown). It can be supplied to the first cooling pipe 71.

That is, in this embodiment, the first cooling pipe 7
1 is guided from the cooling facility 41 into the cave 13,
4 and extends from terminal 11 to terminal 12, circulates and is connected to cooling facility 41. On the other hand, the second cooling pipes 72a to 72e
The first cooling pipe 71 is connected to the supply side and the return side so as to be divided into two sections A to F. The first cooling pipe 71 is provided with a cooling member 30 on the outer periphery in sections A to E. Although the first cooling pipes 71 are not shown, actually six are provided, and a plurality of second cooling pipes 72 a to 72 are provided for each first cooling pipe 71.
72e is branched and connected.

In the underground transmission line cooling device thus configured, the cooling equipment 41 on the ground uses supercooled water to make ice and stores dynamic ice in an ice heat storage tank. Then, the ice cooling water stored in the ice heat storage tank is sent out to the first cooling pipe 71 by a water supply pump, and circulates in the cave 13. In this case, in the section A, the second cooling pipe 72a branches from the first cooling pipe 71 and is attached to the transmission line 14, and similarly, in the sections BE, the second cooling pipes 72b to 72e branch and transmit. It is attached to the electric wire 14. In addition, the first cooling pipe 71 is covered with the cooling member 30 in sections A to E to suppress the cooling capacity, and the first cooling pipe 71 has a normal cooling capacity in section F in which the first cooling pipe 71 is a bare pipe. The cooling water whose temperature has risen after cooling the inside of the canal 13 is returned to the cooling facility 41.

Accordingly, the inside of the canal 13 is divided into six sections A to F, and the cooling pipes 71 and
72a to 72e, and the airway 1
The transmission line 14 can be appropriately cooled while maintaining the temperature in the inside 3 at a predetermined temperature. As a result, it is possible to appropriately cool the power transmission line 14 disposed in the canal 13 over a long distance, and to make the cooling pipes 71, 72a to 72e thinner or to reduce the number of pipes, thereby making the cooling water. The supply flow rate can be reduced, and the size and cost of the apparatus can be reduced.

FIG. 7 schematically shows an underground transmission line cooling device according to a fourth embodiment of the present invention. Note that members having the same functions as those described in the above-described embodiment are denoted by the same reference numerals, and redundant description will be omitted.

In the underground power transmission line cooling device of the present embodiment, as shown in FIG.
A cave 13 is formed between 1 and 12, and a transmission line 14 is provided in the cave 13. On the other hand, a cooling facility 41 is provided on the ground, and this cooling facility 41 generates ice by the collision energy by colliding supercooled water with the collision plate, as in the above-described embodiment, and stores ice heat. The tank stores ice and cooling water. Then, four cooling pipes 81a to 81d extend from the cooling facility 41 into the cave 13 so that the cooling water stored in the ice heat storage tank can be supplied to the cooling pipe 81 by a water supply pump (not shown). .

That is, in this embodiment, each cooling pipe 81a
To 81d are guided into the cave 13 from the cooling equipment 41, and U is divided in the middle so as to divide the cave 13 into four sections A to D.
It is turning. The cooling pipe 81a is provided with a cooling member 30a on the outer peripheral portion up to just before the section A.
Makes a U-turn. Further, the cooling pipe 81b is provided with a cooling member 30b on the outer peripheral portion up to just before the section B, and makes a U-turn in this section B. Similarly, the cooling pipe 81c has a cold insulation member 30c attached to the outer periphery thereof before section C and makes a U-turn in section C, and the cooling pipe 81d has an outer periphery provided with the cold insulation member 30d just before section D and has section d. Makes a U-turn. In addition, although illustration was omitted, each cooling pipe 81a-
Both 81d are connected to the cooling facility 41.

In the underground transmission line cooling device thus constructed, the cooling equipment 41 on the ground uses supercooled water to make ice and stores dynamic ice in the ice heat storage tank. Then, the ice cooling water stored in the ice heat storage tank is sent out to each of the cooling pipes 81 a to 81 d by a water supply pump, and circulates in the canal 13. In this case, the cooling pipe 78a is attached to the transmission line 14 in the section A, and similarly, the cooling pipe 81 in the sections BD.
b to 81 d are attached to the transmission line 14, and the cooling ability is suppressed by being covered with the cold insulation members 30 a to 30 d before the attachment.

Accordingly, the inside of the tunnel 13 is divided into four sections A to D, and each of the cooling pipes 81b in which the sections A to D are kept cool.
As a result, the transmission line 14 can be appropriately cooled while maintaining the temperature in the tunnel 13 at a predetermined temperature. As a result, the transmission line 14 disposed over a long distance in the canal 13 can be appropriately cooled, and the cooling pipe 8 can be cooled.
It is possible to reduce the supply flow rate of the cooling water by reducing the width of 1b to 81d or reducing the number of pipes, so that the size and cost of the device can be reduced.

[0048]

As described above in detail in the embodiment, according to the underground transmission line cooling device of the first aspect of the present invention, cooling water is generated by the cooling equipment and stored in the heat storage tank. The cooling water in the heat storage tank is supplied to the cooling pipe arranged in the cave by the water supply pump, and only in the initial section of the cooling pipe extending from the heat storage tank into the cave, the cooling member is provided on the outer periphery of the cooling pipe. In the section past the initial section, the inside of the canal will be cooled by the cooling water kept cool by the cold insulation member, and the inside of the canal can be cooled with a small flow rate, reducing the power of the water pump. Also, by reducing the size of the cooling pipe, the transmission line in the sinus can be appropriately cooled while reducing the size and cost of the apparatus.

Further, according to the underground transmission line cooling device of the second aspect of the present invention, cooling water is generated by the cooling equipment and stored in the heat storage tank, and the cooling water in the heat storage tank is conveyed by the water pump. The first cooling pipe provided in the road is supplied to a plurality of second cooling pipes branched from the first cooling pipe at predetermined intervals of the first cooling pipe. Because the cooling member was attached to the outer peripheral portion of the cooling pipe, the inside of the cave was divided into a plurality of sections, cooling water was transported to each section by the first cooled cooling pipe, and each section was formed by the second cooling pipe. It will be cooled, and the inside of the canal can be cooled with a small flow rate, while reducing the power of the water pump and reducing the diameter of the cooling pipe, while reducing the size and cost of the device The transmission line in the cave can be properly cooled .

Further, according to the underground transmission line cooling device of the third aspect of the present invention, the cooling water is generated by the cooling facility and stored in the heat storage tank, and the cooling water in the heat storage tank is conveyed by the water pump. Supply to multiple cooling pipes arranged in the road,
Since a cooling member was attached to the outer periphery of a plurality of cooling pipes having different lengths on the outer periphery of each cooling pipe so as to gradually increase from the initial section of the cooling pipe extending from the heat storage tank into the cave, The inside of the cave is divided into a plurality of sections, each section is cooled by each cooling pipe kept cool until then, the inside of the cave can be cooled with a small flow rate, reducing the power of the water pump and cooling By reducing the diameter of the pipe, it is possible to appropriately cool the transmission line in the sinus while reducing the size and cost of the device.

According to the underground power transmission line cooling device of the present invention, the cooling equipment discharges supercooled water from the nozzle and collides with the collision plate to generate ice by collision energy. Since it is composed of an ice making refrigerator and an ice heat storage tank that stores the ice generated by the dynamic ice making refrigerator together with the cooling water, the cooling efficiency is improved by using ice compared to the cooling water, and the ice with respect to the required cooling heat amount is improved. The cooling water flow rate can be reduced, and the logarithmic average temperature difference between the ambient temperature and the cooling water supply temperature can be large, so the surface area of the cooling pipe can be small, and as a result, the inside of the cave can be cooled with a small flow rate. By reducing the power of the water pump and reducing the diameter of the cooling pipe, it is possible to appropriately cool the transmission lines in the tunnel while reducing the size and cost of the equipment. .

Further, according to the underground power transmission line cooling device of the present invention, ice is generated by collision energy by discharging supercooled water from the nozzle and colliding with the collision plate by the dynamic ice making refrigerator. Then, ice generated by the dynamic ice making refrigerator is stored in an ice storage tank together with cooling water,
Since the cooling water containing ice in the ice storage tank is supplied to the cooling pipe arranged in the tunnel by the water supply pump, the cooling efficiency is improved by using ice compared to the cooling water,
The cooling water flow rate for the required cooling heat amount can be small, and the logarithmic average temperature difference between the ambient temperature and the cooling water supply temperature can be large, so the cooling pipe surface area can be small,
As a result, the inside of the sinus can be cooled with a small flow rate,
By reducing the power of the water pump or reducing the diameter of the cooling pipe, it is possible to appropriately cool the transmission line in the sinus while reducing the size and cost of the device.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a device for cooling an underground transmission line according to a first embodiment of the present invention.

FIG. 2 is a sectional view of the inside of a sinus.

FIG. 3 is a graph of the temperature in the cave and the temperature of the cooling water in the cooling pipe with respect to the distance between the cave and the cooling pipe in the underground transmission line cooling device of the present embodiment.

FIG. 4 is a schematic view of a device for cooling an underground transmission line according to a second embodiment of the present invention.

FIG. 5 is a schematic view of a dynamic ice making refrigerator and an ice heat storage tank.

FIG. 6 is a schematic diagram of a device for cooling an underground transmission line according to a third embodiment of the present invention.

FIG. 7 is a schematic diagram of a device for cooling an underground power transmission line according to a fourth embodiment of the present invention.

FIG. 8 is a schematic diagram of a conventional underground power transmission line cooling device.

FIG. 9 is a graph of the temperature in the tunnel and the temperature of the cooling water in the cooling pipe with respect to the distance between the tunnel and the cooling pipe in the conventional underground power transmission line cooling device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 13 Cave 14 Transmission line 21 Cooling equipment 22 Cooling pipe 23 Cold water refrigerator 24 Water storage tank 25 Water pump 26 Cooling water supply device 30 Cooling member 31, 32 Temperature sensor 33 Control part 41 Cooling equipment 42 Cooling pipe 43 Dynamic ice making refrigerator 44 ice heat storage tank 45 IPF regulator 46,47 water pump 48 cooling water supply device 61,62 temperature sensor 63 control unit 71 first cooling pipe 72a-72e second cooling pipe 81a-81d cooling pipe 30a-30d cooling member

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Shuji Kadoya 2-1-1, Shinhama, Araimachi, Takasago-shi, Hyogo F-term in Takasago Works, Mitsubishi Heavy Industries, Ltd. 5G369 AA01 BA05 CB05 CB12 EA04

Claims (5)

[Claims] An underground transmission line cooling device for indirectly cooling a transmission line disposed in a tunnel formed in the ground, comprising: a cooling facility that generates cooling water and stores the cooling water in a heat storage tank; A cooling pipe disposed in the cave, a water pump for supplying cooling water in the heat storage tank to the cooling pipe, and only an initial section of the cooling pipe extending from the heat storage tank into the cave. A cooling device for an underground power transmission line, comprising: a cooling member attached to an outer peripheral portion of the cooling pipe. 2. An underground transmission line cooling device for indirectly cooling a transmission line disposed in a tunnel formed in the ground, comprising: a cooling facility for generating cooling water and storing the generated cooling water in a heat storage tank; A first cooling pipe disposed in the cave, a plurality of second cooling pipes branched from the first cooling pipe for each predetermined section of the first cooling pipe, and cooling in the heat storage tank Water the first
A cooling device for an underground transmission line, comprising: a water supply pump for supplying cooling water to a cooling pipe; and a cooling member attached to an outer peripheral portion of the first cooling pipe. 3. A cooling device for an underground transmission line for indirectly cooling a transmission line disposed in a tunnel formed in the ground, comprising: a cooling facility for generating cooling water and storing it in a heat storage tank; A plurality of cooling pipes disposed in the cave, a water pump for supplying cooling water in the heat storage tank to each cooling pipe, and an initial state of the cooling pipe extending from the heat storage tank into the cave. A cooling device for an underground power transmission line, comprising: a plurality of cold insulation members having different lengths, each of which is attached to an outer peripheral portion of each of the cooling pipes so as to gradually increase from a section. 4. The underground transmission line cooling device according to claim 1, wherein said cooling equipment generates ice by collision energy by discharging supercooled water from a nozzle and colliding against a collision plate. A cooling device for an underground power transmission line, comprising: a dynamic ice chiller that performs cooling; and an ice heat storage tank that stores ice generated by the dynamic ice chiller together with cooling water. 5. An underground transmission line cooling device for indirectly cooling a transmission line disposed in a tunnel formed in the ground, wherein supercooled water is discharged from a nozzle to collide with a collision plate. A dynamic ice making refrigerator for generating ice by collision energy, an ice heat storage tank for storing ice generated by the dynamic ice making refrigerator together with cooling water, a cooling pipe disposed in the cave, and the ice heat storage. A cooling device for an underground power transmission line, comprising: a water pump for supplying cooling water in a tank to the cooling pipe.