KR20060080135A - Cable cooling device by forced circulation of insulating oil between parallel OF cables - Google Patents

Abstract

The present invention relates to an OF cable cooling device for cooling a cable by forming a closed circuit closed by the forced circulation cooler 69 through the insulating oil space between the parallel OF cables.

Currently installed OF cables are cooled by convection of heat generated from the conductors without the forced circulation of the insulating oil. In addition, the hydraulic tanks used for OF cables are installed only to maintain the hydraulic pressure generated by the cable laying path. As shown in FIG. 5, there is one oil pipe 51 connected to the cable in the hydraulic tank, which indicates that there is no forced circulation of the insulating oil.

In the present invention, the hydraulic tank for maintaining the hydraulic pressure in the forced circulation cooler (69) to be cooled by the refrigeration cycle is connected via the hydraulic tank oil pipe (71) and the insulating oil circulation fan 160 to the insulation oil injection connector 35 of the strand of OF cable Connect the cooler inlet pipe (72) and the cooler inlet pipe (73) connected to another insulated inlet connector (35) of the OF cable, and connect the cooling device on the opposite side of the cooling section to the opposite side to the cooling closed circuit. By cooling the OF cable effectively. The insulating oil cooled in the forced circulation cooler 69 circulates through the flow path 18 formed at the center of the conductor to cool the center of the conductor, thereby significantly removing the thermal problem of the OF cable.

As the refrigerant in the refrigerating cycle was evaporated in the evaporator, a device for obtaining electric power or physical energy from the generator (or mechanism) 78 connected to the turbine shaft by turning the turbine 77 with the kinetic energy of the gaseous refrigerant was added. The cable's one-year operation shows that heavy loads take only a few hours, so effective cooling of the cables in the refrigeration cycle during these short periods will increase cable capacity even further.

OF cable, distribution channel, hydraulic tank, PT, BPT, refrigeration cycle, cooling system

Description

Cable cooling device by forced circulation of insulating oil between parallel OF cables

1 is a cross-sectional view of a conventional OF cable.

FIG. 2 is an explanatory diagram of a connection state of an OF cable stop joint (SJ) connection member. FIG.

3 is a cross-sectional view of an OF cable stop joint (SJ) junction box.

4 is an explanatory view of the existing hydraulic tank (PT, BPT).

5 is an explanatory view of connecting the existing OF cable and the hydraulic tank.

6 is an explanatory view of a forced circulation cooler according to the present invention.

7 is an explanatory diagram of a forced forced circulation cooling system for insulated oil between parallel cables.

FIG. 8 is an explanatory diagram of a forced forced circulation cooling system for insulated oil between three parallel cables. FIG.

9 is an explanatory diagram of a 345 kV OF cable year continuous operating current curve.

<Explanation of symbols for main parts of drawing>

11: anticorrosive layer 12: sheath

13: inner space of the sheath 14: outer semiconducting layer

15 insulation layer 16 internal semiconducting layer

17: conductor 18: distribution channel

21: connecting member 22: insulating oil leakage groove

31: semi-soft part 32: insulating oil space

33: Bell mouse 34: insulation reinforcement layer

35: Insulation oil injection connector 36: Connection box

41: enclosure 42: N ₂ gas

43: insulating oil 44: insulating oil cell

45: foreign oil 46: N ₂ gas cell

47: bellows 51: related

60: insulation 61: evaporator

62: expansion valve (or capillary tube) 63: refrigerant storage tank

64: condenser 65: compressor

66: motor (or engine) 67: turbine

68: generator (or machinery) 69: forced circulation cooler

71: hydraulic tank oil pipe 72: cooler outflow pipe

73: cooler inlet pipe 160: insulated circulation fan

OF cable reinforces insulation by ground insulation and fills the insulating oil in the distribution center of the conductor center or inside the sealed sheath and releases the heat generated inside the conductor through the convection of the insulating oil to the outside of the cable. However, the heat exiting the cable accumulates in the power outlet or the pipe in which the cable is installed, which does not increase the cable capacity. Recently, a water cooling system has been introduced to remove this heat to the outside space, but heat exchange is not effective and a new water cooling system must be provided, which causes a lot of cost. In addition, superconducting cables are in the production stage, but the power loss is about half of existing cables, and the technology is not completed, so the price is expensive and there are technical problems.

In the present invention, it is intended to increase the effect of cooling by forced circulation of the insulating oil of the OF cable. However, even if a new cooling system is constructed, additional equipment is minimized and existing equipment can be recycled as it is to minimize investment costs. Therefore, in the forced circulation of OF cable insulation oil, use the space of the oil of parallel OF cable installed in the periphery instead of using a separate return line. It also adds energy production by installing turbines in refrigeration cycles.

1 is a cross-sectional view of a conventional OF cable. There is a channel 18 at the center of the OF cable and a sheath inner space 13 outside the insulator.

Fig. 2 is an explanatory diagram of a connection state of an OF cable stop joint (SJ) connection member. Insulating oil flow through the flow path 18 is stopped in the connecting member 21 and the insulating oil flow is connected into the junction box through the insulating oil outflow groove 22.

Fig. 3 is a cross-sectional view of the OF cable stop joint (SJ) junction box. Insulating oil flow through the flow path 18 is stopped inside the connecting member 21, and the insulating oil is not drawn out vertically to the conductor through the insulating oil outflow groove 22 due to the risk of insulation breakdown. It flows into the insulating oil space 32. The insulating outflow groove 22 and the upper portion of the connection conductor form an insulating reinforcement layer to prevent insulation weakening. The OF cable forms one ties connected from one maintenance connection (SJ) to several maintenance connections (NJ) and insulated joints (IJ) and again connected to the maintenance connection (SJ). do.

4 is an explanatory view of the existing hydraulic tank (PT, BPT). Insulating oil inlet cell type PT injects the outer oil 45 into the lower portion of the sealed oil tank enclosure 41, arranges the insulating oil cell 44 therein, and fills the upper portion with N ₂ gas to apply pressure to the cable insulating oil. When the insulating oil in the cable is thermally expanded, the insulating oil flows into the PT and the insulating oil cell 44 expands. On the contrary, when the insulating oil heat shrinks, the insulating oil cell 44 contracts. Gas inlet cell type PT is disposed a N ₂ gas cell 46 filled with the N ₂ gas inside the closed enclosure an oil bath (41), injecting the insulating oil in the remaining space. When the insulating oil in the cable thermally expands, the insulating oil flows into the PT and the N ₂ gas cell 46 contracts. On the contrary, when the insulating oil heat shrinks, the N ₂ gas cell 46 expands. The BPT installs the bellows 47 inside the sealed oil tank enclosure 41, fills the inside of the enclosure 41 with N ₂ gas, and imports insulating oil 43 into the bellows 47. When the insulating oil in the cable thermally expands, the insulating oil flows into the BPT and the N ₂ gas contracts. When the insulating oil heat shrinks, N ₂ gas expands on the contrary.

5 is an explanatory diagram of connecting the existing OF cable and the hydraulic tank. One strand of oil pipe 51 flowing out of the hydraulic tank is connected to the OF cable through the insulated oil injection connector 35. One stranded conduit cannot form a closed circuit, so the cooling method by insulating oil circulation is not applicable and only depends on the convection of insulating oil. The hydraulic tank only serves to overcome the hydraulic pressure due to the high and low level of cable laying. Moreover, the semi-perforated part 31 and the taping in the vicinity separate the insulating oil system of the sheath inner space 13 and the insulating oil system of the flow path 18 and the insulating oil space 32 of the junction box 36, thereby insulating oil between the two spaces. The distribution depends on the space between the tightly wound insulating paper.

6 is an explanatory view of the forced circulation cooler 69 according to the present invention. The forced circulation cooler 69 is installed between the parallel OF cables. Forced circulation cooler 69 installs the insulation 60 inside the enclosure and injects insulating oil therein. Inside the insulating oil, an evaporator 61 having a structure in which much heat exchange takes place was installed, and other equipment of the refrigeration cycle was disposed outside the forced circulation cooler 69. At the outlet of the insulating oil flows into the cable is installed an insulating oil circulation fan 160 to force the insulating oil. The coolant outflow pipe 72 is provided continuously to the insulated oil circulation fan 160, and a cooler inflow pipe 73 through which insulation oil flows from another cable is installed, and a hydraulic tank oil pipe 71 is connected from the hydraulic tank. . At this time, the refrigeration cycle is composed of a compressor (65), a condenser (64), a refrigerant storage tank (63), an expansion valve (or capillary tube), an evaporator (61), a turbine (67), and a compressor (65) again. do. The compressor 65 compresses the gaseous refrigerant, and in the condenser 64, the compressed refrigerant dissipates heat to become liquid, and the refrigerant, which becomes liquid, collects in the refrigerant storage tank 63 installed to increase the inertia of the cooling system. Then, the refrigerant in the liquid state passes through the expansion valve (or capillary tube) 62, changes into a gaseous state, and the volume starts to expand. The refrigerant exiting the expansion valve (or capillary tube) 62 absorbs heat of vaporization from the insulating oil in the evaporator 61 connected to the expansion valve (or capillary tube) 62 and becomes a gas. The gas passing through the evaporator 61 rotates the turbine 67 and enters the compressor 65 to be compressed and ends one cycle of the refrigeration cycle. It is also within the scope of the present invention to remove the refrigerant storage tank 63 and to add a control device that senses the insulating oil temperature and smoothly operates the refrigeration cycle according to the user's will. The open circuit refrigeration cycle changes the volume of the liquid refrigerant into the gas while passing through the expansion valve (or capillary tube) 62 in the refrigerant storage tank 63 of the externally made refrigerant. The refrigerant exiting the expansion valve (or capillary tube) 62 becomes a gas while absorbing heat of vaporization from the insulating oil in the evaporator 61 connected to the expansion valve (or capillary tube) 62. Although only the bellows type BPT is illustrated as the hydraulic tank, the installation of another type of hydraulic tank PT is also included in the scope of the present invention.

7 is an explanatory diagram of the forced forced circulation cooling oil between two cables according to the present invention. The insulating oil flows into the forced circulation cooler 69 from the lower OF cable through the cooler inflow pipe 73. The introduced insulating oil is cooled by the refrigeration cycle, and the cooled insulating oil is cooled by the insulating oil circulation fan 160 through the coolant outlet oil pipe 72 and through the left insulating oil injection connector 35 of the upper OF cable to the upper OF cable. Inflow. The introduced insulating oil cools the conductor while moving to the opposite junction through the channel 18 of the upper cable conductor center. Insulating oil which absorbs the heat of the conductor moves to the right connection of the upper cable. The insulating oil is continuously introduced into the right forced circulation cooler 69 through the cooler inlet pipe 73 of the right forced circulation cooler 69 connected to the right insulated oil injection connector 35. The insulating oil is cooled again by the refrigeration cycle and the cooled insulating oil is introduced into the lower cable right connector through the lower cable right insulating oil injection connector 35 connected to the cooler outlet oil pipe 72 by the insulating oil circulation fan 160. This insulating oil absorbs the heat of the lower cable conductor while moving to the left junction through the channel 18 formed at the center of the lower cable conductor. The insulating oil flows into the left cooler through the cooler inflow pipe 73 connected to the lower cable left insulated oil injection connector 35 to terminate one cycle of cooling. If the number of strands of parallel operation cable is even, the cooling system can be configured in this way.

8 is an explanatory view of the forced oil circulating cooling device between three parallel cables according to the present invention. When the number of strands of the parallel operation cable is odd, the remaining strands cannot be cooled by the cooling system as shown in FIG. Therefore, in this case, the cooling system can be completed by using the insulating oil space of one strand as the recovery space and the two strands as the injection space of the three parallel operation cables. The principle is as described in FIG.

Fig. 9 is an explanatory diagram of the annual operating current sustain curve of the 345kV OF cable currently in operation. As shown, the middle of the year is limited to a very short time. Therefore, even in this short time, if the conductor is directly cooled by a refrigeration cycle with excellent cooling performance, the cable capacity will increase enormously.

In the present invention, by using the existing equipment of the OF cable as possible without changing the structure as much as possible while reducing the cost forced circulation of the cooled insulating oil directly to increase the cooling effect to maximize the capacity of the OF cable. In addition, by installing the turbine 67 in the refrigeration cycle and the generator (or machinery) 68 in the turbine shaft to be able to produce additional power or physical energy.

Claims (2)

Connect the insulation oil system of multiple parallel OF cables at each end of the oil supply section of the OF cable with a pipe to form a closed circuit so that the parallel OF cable flow path 18 becomes part of the insulation oil circulation circuit. How to cool it. The coolant outflow connected to one of the OF cable insulation oil inflow connectors 35 connected to one strand of OF cable insulated oil inflow connector 35 and the other of the OF cable insulation oil inflow connector 35 of the parallel OF cable. The insulated oil system of the parallel OF cable is connected by the forced circulation cooler 69 having the oil pipe 72 and the hydraulic tank oil pipe 71 connected to the hydraulic tank. And an insulating oil circulating closed circuit of the parallel OF cable by connecting the same, forcibly circulating the insulating oil cooled by the insulating oil circulating closed circuit to cool the OF cable.

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