JPH08196029A - Cryogenic cable terminating equipment - Google Patents

Abstract

(57) Abstract: [configuration] and conductor 29 of the superconducting cable 11 connecting portions of the conductive lead 47 is placed in a LN ₂ container 13 is insulated by LN _2.
The temperature gradient part of the lead-out conductor 47 and the stress cone 65 are installed in the vacuum container 15 and the porcelain insulator 17, and the insides of the vacuum container 15 and the porcelain insulator 17 are evacuated. [Effect] The heat inflow from the outside to the cryogenic region can be reduced. The connection between the lead conductor and the conductor of the cryogenic cable is L
Since it is electrically insulated by N ₂ and the temperature gradient portion of the lead conductor is electrically insulated by vacuum with the stress cone provided around it, stable electrical insulation performance can be obtained. The entire terminal connection device can be made compact.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a terminal connecting device for a cryogenic cable (superconducting cable, cryogenic resistance cable, etc.) cooled by a cryogenic liquid such as LN ₂ (liquid nitrogen).

[0002]

2. Description of the Related Art A terminal connecting device for a cryogenic cable has a lead conductor having one end connected to a conductor of the cryogenic cable and the other end exposed to the atmosphere. Since the lead conductor is usually made of copper, which is a good conductor of electricity and heat, heat flows from the room temperature region to the cryogenic region through the lead conductor. In the terminal connection device for a cryogenic cable, it is important to minimize the heat inflow through the lead conductor.

As a means for reducing the flow of heat into the cryogenic region, it has been proposed to provide a vacuum heat insulating layer around the lead conductor (Japanese Utility Model Publication No. 2-30232). When such a vacuum insulation layer is provided, the peripheral surface of the lead conductor is thermally insulated from the room temperature region, so the amount of heat flowing from the periphery of the lead conductor is reduced, and therefore the heat flow to the cryogenic region through the lead conductor is reduced. Can be made smaller.

[0004]

However, the conventionally proposed vacuum heat insulation type terminal connection device has a stress cone on the outer periphery of the vacuum heat insulation layer, and the upper half of the stress cone is exposed to the atmosphere and the lower half is exposed. Since the part is located in the cryogenic region, the heat inflow through the stress cone is large, and it is difficult to sufficiently reduce the heat inflow from the outside. Also, since the temperature difference inside the stress cone is large, cracks may occur in the stress cone due to thermal strain, and there is room for improvement in terms of electrical insulation.

An object of the present invention is to provide a terminal connecting device for a cryogenic cable which has a small heat inflow from the outside, a stable electric insulation and a relatively compact size as a whole.

[0006]

To achieve this object, a terminal device for connecting a cryogenic cable according to the present invention comprises a cryogenic liquid container attached to an end of the cryogenic cable and a tip of the cryogenic liquid container. , A porcelain tube attached to the end of the vacuum container, an insulating partition wall for blocking the interior of the cryogenic liquid container from the interior of the vacuum container, and one end of the cryogenic liquid container Connected to the conductor of the cryogenic cable through the partition wall in an air-tight and liquid-tight manner, and through the inside of the vacuum container and the porcelain tube, the other end airtightly penetrating the tip of the porcelain tube The outer circumference is provided with a stress cone installed so that one end side is located inside the vacuum container and the other end side is located inside the porcelain tube, and the cryogenic liquid container is filled with the cryogenic liquid and the extraction conductor and the cryogenic temperature are provided. Cable guide With electrically insulate the connecting portion between the electrical lead conductors to the inside of the vacuum vessel and porcelain bushing evacuated and thermally insulated, it is characterized in.

As a cryogenic liquid, L which has a good electric insulation property
It is preferable to use N ₂ (liquid nitrogen). The partition wall arranged between the cryogenic liquid container and the vacuum container is L
In order to increase the creepage distance with N ₂ , it is preferable to use a tapered cylindrical shape.

[0008]

With the above construction, the temperature gradient part of the lead conductor and the entire stress cone are installed in a vacuum,
Since it is thermally insulated from the outside, heat inflow from the outside is reduced. Also, the connection between the lead conductor and the conductor of the cryogenic cable must be installed in a cryogenic liquid such as LN ₂ that has good insulation properties, and the temperature gradient part of the lead conductor and the entire stress cone must be installed in a vacuum. From that,
It is also electrically stable.

Furthermore, since the connecting portion between the lead conductor and the conductor of the cryogenic cable is installed in the cryogenic liquid having a good insulating property, the periphery of the connecting portion can be made compact and the temperature gradient portion of the lead conductor can be formed. Since the stress cone wraps in the longitudinal direction, the length can be shortened. For this reason, it is possible to make it compact as a whole.

[0010]

FIG. 1 shows an embodiment of the present invention. In this embodiment, the present invention is applied to a terminal connecting device for a superconducting power cable. This terminal connecting device comprises an LN ₂ container 13 attached to the end of a superconducting power cable 11. A vacuum vessel 15 is attached to the tip of the LN ₂ vessel 13, and a porcelain tube 17 is attached to the tip (upper end) of the vacuum vessel 15. In the illustrated example, the LN ₂ container 13 is horizontally arranged, and the vacuum container 15 and the insulator 17 are vertically arranged. However, when the end of the superconducting cable 11 rises vertically, the LN ₂ container 13 is also vertically arranged. .

The LN ₂ container 13 is in the form of a cryostat having a vacuum insulation layer 23 between the inner container 19 and the outer container 21. Reference numeral 25 is a vacuum suction port, and 27 is an LN ₂ supply port (or a discharge port). The conductor 29 of the superconducting cable 11 is introduced into the LN ₂ container 13 with the insulating layer 31 stripped off.

The superconducting cable 11 in this embodiment is, for example, an AC 66 kV superconducting power cable. The conductor 29 of this cable is a superconducting conductor of Bi type silver sheath cooled by LN ₂ , and the insulating layer 31 is biaxially oriented polypropylene semi-synthetic paper (OPPL paper) impregnated with LN ₂ .
An epoxy bell mouth 33 for relaxing an electric field is attached to the outer periphery of the insulating layer 31 located inside the LN ₂ container 13.

On the tip side of the LN ₂ container 13, LN ₂
An insulative partition wall 35 that blocks the inside of the container 13 from the inside of the vacuum container 15 is installed. The partition wall 35 is an epoxy FRP (fiber reinforced plastic) or EPR
It is in the form of a tapered cylinder made of (ethylene propylene rubber) or the like.

The vacuum container 15 comprises a stainless steel inner container 37 and a heat insulating layer 3 made of super insulation or the like.
9 and a stainless steel outer container 41. Reference numeral 43 is a vacuum outlet. The porcelain bushing 17 is made of porcelain used for a normal power cable terminating connection portion, and although not shown in the drawings, a plurality of umbrella-shaped flanges are formed on its outer peripheral surface. The upper end of the porcelain bushing 15 is sealed by a cover plate 45.

Reference numeral 47 is a lead conductor drawn from the cryogenic region to the room temperature region. This lead conductor 47 is of a type that does not allow a cryogenic liquid such as LN ₂ to flow inside, unlike the lead conductor in Japanese Utility Model Laid-Open No. 2-30232. The lead conductor 47 includes a multi-contact (sliding type connector) 49, a lower current lead 51, a flexible connecting conductor 53, and an upper current lead 55. Each component is made of copper.

The multi-contact 49 is located inside the LN ₂ container 13 and is soldered to the conductor 29 of the superconducting cable 11 with solder 57. The lower current lead 51 penetrates the center of the partition wall 35 in an airtight and liquidtight manner. A shield 59 covers the outer circumference of the flexible connecting conductor 53. The upper current lead 55 passes through the centers of the vacuum vessel 15 and the porcelain tube 17, and its upper end penetrates the cover plate 43 in an airtight manner and projects into the atmosphere. A shield ring 61 is attached to the upper end of the upper current lead 55 protruding into the atmosphere.

In the lead conductor 47, the portion protruding into the atmosphere is normal temperature, the portion located in the LN ₂ container 13 is extremely low temperature, and the interval is a temperature gradient portion from normal temperature to extremely low temperature.

A stainless steel tube 63 is coaxially arranged on the outer circumference of the upper current lead 55 located in the vacuum vessel 15 and the porcelain tube 17 with a minute gap. Stainless tube 6
The upper and lower ends of 3 are supported by the upper current lead 55. A stress cone 65 made of silicon is integrally formed on the outer circumference of the stainless pipe 63. The lower end side of the stress cone 65 is located inside the vacuum container 15, and the upper end side is located inside the porcelain insulator 17. A ground electrode 67 is embedded in the middle portion of the stress cone 65,
The collar portion 69 of No. 7 is fixed between the vacuum container 15 and the porcelain insulator 17. A large number of holes are formed in the flange portion 69, and the inside of the vacuum container 15 and the inside of the porcelain tube 17 communicate with each other.

A large number of holes are also formed in the upper end and the lower end of the stainless steel pipe 63, and the minute gap inside the stainless steel pipe 63 communicates with the inside of the insulator 17 and the vacuum container 15 outside the stainless steel pipe 63. ing.

The LN ₂ container 13 is filled with LN ₂ 71 in a pressurized supercooled state (about 5 atm, about 68 K). The connection between the lead conductor 47 and the conductor 29 of the cryogenic cable is cooled and electrically insulated by this LN ₂ 71. Since LN ₂ 71 has a pressure resistance equivalent to that of insulating oil, the LN ₂ container 13 can be sufficiently miniaturized. The design stress of LN ₂ can be about 9 kV / mm, and the design stress along the surface of LN ₂ -epoxy (partition wall) can be about 1 kV / mm. By forming the partition wall 35 into a tapered cylindrical shape, the creepage distance between the LN ₂ 71 and the partition wall 35 can be increased and the electrical insulation can be stabilized.

The inside of the vacuum vessel 15 and the porcelain tube 17 is 10 ^-5 T
A high vacuum of orr or higher is maintained. This allows the vacuum container 1
5 and the lead conductor 47 in the porcelain tube 17 are electrically and thermally insulated from the outside. Vacuum design stress is 3kV /
The design stress on the surface of the vacuum-silicon (stress cone) can be about 1 kV / mm.

With the above configuration, the current is 3000 A and the voltage is 6
It is possible to configure a termination device for a superconducting cable that can withstand a 6 kV energization test and a 350 kV impulse test. Although the above embodiments have been described with respect to the terminal connecting device for the superconducting cable, the present invention is similarly applicable to the terminal connecting device for the cryogenic resistance cable.

[0023]

As described above, according to the present invention, since the temperature gradient portion of the lead conductor and the entire stress cone are installed in a vacuum, the heat inflow from the outside to the cryogenic region can be sufficiently reduced. . Also, the connection between the lead conductor and the conductor of the cryogenic cable should be electrically insulated with a cryogenic liquid such as LN ₂ which has good electrical insulation, and the temperature gradient part of the lead conductor should be provided with a stress cone around it. Since it is electrically insulated by vacuum, stable electrical insulation performance can be obtained. Furthermore, by insulating the connection between the lead conductor and the conductor of the cryogenic cable with a cryogenic liquid, the insulation structure of the connection can be made compact, and the temperature gradient part of the lead conductor and the stress cone are wrapped in the longitudinal direction. As a result, since the length of the lead conductor can be shortened, the entire terminal connecting device can be made compact.

[Brief description of drawings]

FIG. 1 is a sectional view showing a termination connecting device for a superconducting power cable according to an embodiment of the present invention.

[Explanation of symbols]

11: Superconducting power cable 13: L
N ₂ container 15: Vacuum container 17: Insulator tube 29: Conductor of superconducting power cable 11 35: Partition wall 47: Lead conductor 57: Solder 63: Stainless tube 65: Stress cone 71: LN ₂ (liquid nitrogen)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tsukushi Hara 4-1, Egasaki-cho, Tsurumi-ku, Yokohama-shi, Kanagawa Prefecture Electric Power Technology Laboratory (72) Inventor Hideo Ishii Egasaki-cho, Tsurumi-ku, Yokohama-shi, Kanagawa No. 4-1 Electric Power Technology Laboratory, Tokyo Electric Power Company

Claims (3)

[Claims] 1. A cryogenic liquid container (13) attached to an end of a cryogenic cable (11), a vacuum container (15) attached to a tip of the cryogenic liquid container (13), and a vacuum container ( Insulator pipe (17) attached to the tip of 15)
The inside of the cryogenic liquid container (13) and the vacuum container (15)
An insulating partition wall (35) for shutting off the inside of the container, and one end of the partition wall (35) is connected to the conductor (29) of the cryogenic cable in the cryogenic liquid container (13), and the partition wall (35) is hermetically and liquid-tightly connected thereto. Through the vacuum container (15) and the porcelain insulator (17)
A lead-out conductor (47) whose other end passes through the inside of the porcelain tube (17) in an airtight manner and penetrates the tip end of the porcelain tube (17);
5) and a stress cone (65) installed so that the other end is located in the porcelain tube (17), and the cryogenic liquid container (13) is filled with the cryogenic liquid (71) And electrically insulates the connecting portion between the lead conductor (47) and the conductor (29) of the cryogenic cable, and the vacuum conductor (15) and the porcelain tube (17) are evacuated to electrically connect the lead conductor (47). A terminal connection device for cryogenic cables, which is electrically and thermally insulated. 2. The terminal connection device according to claim 1, wherein the cryogenic liquid (71) is liquid nitrogen. 3. The terminal connection device according to claim 1, wherein the partition wall (35) has a tapered cylindrical shape.