JPH07154970A - Air-insulated thyristor valve - Google Patents

Abstract

PURPOSE:To enhance the creeping insulation strength of a light guide and to sharply reduce the height of a thyristor valve by a method wherein the light guide which transmits an optical signal to control a thyristor element inside a multistage-stacked module is formed in such a way that it is housed, together with an insulating gas, inside a corrugated insulation tube made of a polymer material. CONSTITUTION:A light guide 6 which transmits an optical signal used to control a thyristor element inside a multistage-stacked module 4 is formed in such a way that it is housed, together with an insulating gas (e.g. SF6 gas), inside an insulation tube 12 which is provided with a corrugation 11 formed of a polymer material. Consequently, the creeping insulation strength of a light guide device is enhanced, and the height of the light guide device can be reduced. Thereby, the height of a thyristor bulb can be reduced, and the thyristor bulb can meet a high voltage and a high capacity needs.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air-insulation type thyristor valve used in an AC / DC converter for DC power transmission, and particularly to an improved insulation structure for a light guide device, a water cooling device, and an anode-cathode lightning arrester. The present invention relates to an air-insulation type thyristor valve which is capable of coping with high voltage and large capacity by improving its creeping dielectric strength and significantly reducing the height of the thyristor valve.

[0002]

2. Description of the Related Art Recently, DC power transmission, which has many advantages in system operation such as large capacity, long-distance power transmission, and different frequency interconnection, has been used in various fields. And now, in Japan, in some areas, the grids are interconnected 2
50 kV DC power transmission is being implemented. This DC transmission is
It is expected that the capacity and voltage will be further increased in the future.

In this type of DC power transmission, an AC / DC conversion station for converting AC into DC or DC into AC is usually installed. As shown in the single-line connection diagram in FIG. 4, this AC / DC converter converts the AC voltage input from the AC bus 24 into the transformers 25, 26 for the upper and lower converters, the upper and lower thyristor valve groups 27, The voltage is converted into a DC voltage through 28, and the DC voltage is transmitted through the DC reactor 31. Of these, the thyristor valve 32 forming the upper and lower thyristor valve groups 27, 28 is
As described above, it is the main element that converts AC voltage into DC voltage or DC voltage into AC voltage.
From the viewpoint of operating results, maintenance, and inspection, air insulation type is often used. This air-insulated thyristor valve is usually housed in a building called a valve hole.

In FIG. 4, 29 and 30 are lightning arresters (hereinafter referred to as A-K pole arresters) for protecting the anode-cathode (AK) poles of the thyristor valve 32 from excessive voltage. Shows.

FIG. 5 is a schematic view showing a structural example of the air insulation type thyristor valve 32. In FIG.
Thyristor valves are thyristor elements that are rectifying elements,
A module 4 formed by accommodating capacitors, resistors, etc. for improving voltage sharing in a certain unit is formed in series in an electric circuit and in a multi-stage structure so that a light for electrically controlling a thyristor element is formed. A light guide housing cylinder 34 for transmitting signals, a thyristor element, a water cooling device for cooling resistance, and a lightning arrester (hereinafter, referred to as A-) for protecting the anode-cathode pole of the thyristor valve body from an excessive voltage.
It is formed of a lightning arrester 33 between K poles) and the like.

In FIG. 5, 1 is a top shield, 2 is an insulating column, and 5 is a pedestal. by the way,
As described above, the thyristor valve is an air-insulated electric device, and is disliked from humidity and dust, so that it is installed in a clean room valve hole.

As described above, the thyristor valve 32 currently adopts the air insulation method because of its operational record, ease of maintenance and inspection. At present, the direct current transmission record in Japan is up to 250 kV direct current, and thyristor valves corresponding to this have been produced by domestic manufacturers. And all of them are of the air insulation type.

However, the height is about 10 m in the 250 kV class, and for the 500 kV DC power transmission which will be realized in the near future, there is a concern that if it is manufactured as it is, it will be a large-sized device exceeding 20 m in height. This means that the strength against earthquakes becomes a big problem, and the valve hole to be housed becomes large as the thyristor valve becomes larger. In Japan, which is a narrow country in an earthquake-prone country, it is expected that further increase in size of the thyristor valve will be a hindrance in promoting DC power transmission. Therefore, from such a background, it is becoming a big problem at present to reduce the height of the thyristor valve.

In particular, as described above, the air-insulated thyristor valve is reduced in height because future increase in voltage causes concern about seismic strength and economic loss due to increase in size. There is a strong demand for this.

Up to now, the insulation distance between the upper and lower sides of the module 4 tends to be reduced due to the improvement of the creeping dielectric strength of the insulating support column 2 supporting the module 4 and the improvement of the electric field analysis technique. The reduction of the insulation distance between the upper and lower sides of the module 4 means that the height of the thyristor valve 32 is reduced, and the purpose is achieved.

However, since the height of the thyristor valve 32 is reduced between the upper and lower sides of the module 4, as shown in the schematic view of FIG. For example, it means that the electrical stress received by 35 (made of Teflon), the light guide device, the AK inter-pole arrester 33 located between the thyristor valve poles, and the like becomes large. Therefore, from such a background, it is necessary to improve the dielectric strength of the water pipe 35, the light guide storage cylinder 34, and the AK pole arrester 33.

[0012]

As described above, in the conventional air insulation type thyristor valve, when it is attempted to reduce the height of the thyristor valve, a water cooling device, a light guide device, and an AK. Although it is necessary to improve the dielectric strength of the inter-pole arrester, there is a problem that it is difficult at this stage.

An object of the present invention is to improve the creeping dielectric strength of the light guide device, the water cooling device, and the lightning arrester between the anode and the cathode electrode, and to greatly reduce the height of the thyristor valve to achieve a high voltage and a large capacity. An object of the present invention is to provide an extremely reliable air-insulated thyristor valve that can deal with the problem.

[0014]

In order to achieve the above object, in an air insulation type thyristor valve used in an AC / DC converting station, firstly, in the invention according to claim 1, the thyristors in the modules stacked in multiple stages are used. The light guide device for transmitting an optical signal for controlling the device is provided with a light guide device formed by accommodating an insulating gas together with an insulating gas in a pleated insulating cylinder made of a polymer material.

Further, in the invention according to claim 3, the lightning arrester for protecting the anode-cathode electrode of the thyristor valve body is housed together with the insulating gas in the pleated insulating cylinder made of a polymer material. And a lightning arrester between the anode and the cathode.

Further, the invention according to claim 5 is provided with a water cooling device formed by flowing cooling water for cooling the thyristor element through an insulating cylinder having a fold formed of a polymer material.

Further, in the invention according to claim 7, a plurality of water pipes for flowing the cooling water for cooling the thyristor element are housed together with the insulating gas in the pleated insulating cylinder made of a polymer material. And a water cooling device formed.

Here, the folds made of a polymer material attached to the insulating cylinder are attached at the upper, middle, and
Each one is attached to the bottom, or several are concentrated and attached. As the material of the insulating cylinder, any one of FRP, Teflon, acrylic, and epoxy is used.

[0019]

Therefore, in the air insulation type thyristor valve of the invention according to the first aspect, the light guide for transmitting the optical signal for controlling the thyristor elements in the multi-layered modules is formed of a polymer material. By providing a light guide device that is formed by accommodating it with an insulating gas in an attached insulating cylinder, the inner surface of the insulating cylinder improves pressure resistance by being filled with the insulating gas, and the outer surface of the insulating cylinder has a fold formed of a polymer material. Since the withstand voltage is improved, the withstand voltage can be improved remarkably as compared with the conventional case.

Further, in the air insulation type thyristor valve of the invention according to claim 3, the lightning arrester for protecting the anode-cathode electrode of the thyristor valve body is provided in the pleated insulating cylinder made of a polymer material. By providing the lightning arrester between the anode and the cathode, which is housed together with the insulating gas, the inner surface of the insulating cylinder is filled with the insulating gas to improve the pressure resistance, and the outer surface of the insulating cylinder is provided with a fold formed of a polymer material. As a result, the breakdown voltage can be improved, and the breakdown voltage can be remarkably improved as compared with the conventional case.

Further, in the air insulation type thyristor valve of the invention according to claim 5, a water cooling device formed by flowing cooling water for cooling the thyristor element through an inside of a pleated insulating cylinder made of a polymer material. By providing the inside of the insulating cylinder, the insulating cylinder is filled with an insulating gas to improve the withstand pressure, and the outer surface of the insulating cylinder is provided with a fold formed of a polymer material to improve the withstand pressure, and thus the withstand pressure is remarkably improved as compared with the conventional case. be able to.

Further, in the air insulation type thyristor valve of the invention according to claim 7, a plurality of water pipes for flowing the cooling water for cooling the thyristor element are made of a polymer material and have a pleated insulating tube. By installing a water cooling device that was housed together with the insulating gas inside, the inner surface of the insulating cylinder was filled with insulating gas to improve the pressure resistance, and the outer surface of the insulating cylinder was fitted with pleats made of a polymeric material. With this, the withstand voltage is improved, and the withstand voltage can be remarkably improved as compared with the conventional case.

As described above, the creeping dielectric strength of the light guide device, the water cooling device, and the lightning arrester between the anode and the cathode is improved, and the height of the thyristor valve is significantly reduced.
It will be possible to cope with high voltage and large capacity.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention is a pleated insulating cylinder (for example, FRP) in which a water cooling device body, a light guide device body, and an anode-cathode lightning arrester body in an air insulation type thyristor valve are formed of a polymer material. The inner surface of the insulating cylinder is insulated by providing a water cooling device, a light guide device, and a lightning arrester between the anode and the cathode, which are formed by housing together with an insulating gas (for example, SF ₆ gas) in the insulating cylinder. The pressure resistance is improved by filling the inner surface of the insulating cylinder, and the outer surface of the insulating cylinder is provided with a fold formed of a polymer material to improve the pressure resistance so that the pressure resistance can be remarkably improved as compared with the conventional case.

An embodiment of the present invention based on the above concept will be described below in detail with reference to the drawings.
FIG. 1A is a schematic diagram showing a configuration example of an air insulation type thyristor valve provided with a light guide device according to the present invention, and the same elements as those in FIG. 5 are denoted by the same reference numerals.

In FIG. 1A, the structure in which the modules 4 each containing a thyristor element, a resistor and the like as a unit are stacked and stacked is the same as the conventional case shown in FIG. That is, in the air insulation type thyristor valve of the present embodiment, a light guide for transmitting an optical signal for controlling the thyristor elements in the modules 4 stacked in multiple stages is provided.
In the FRP insulation cylinder 3 which is a light guide storage cylinder having a fold formed of a polymer material, SF ₆ which is an insulating gas is filled.
A light guide device that is housed together with gas is installed.

FIG. 1B shows an FR for storing the light guide.
It is a schematic diagram showing an example of detailed composition inside P insulation cylinder 3.
FIG. 1 (b) shows the connecting portion of the FRP insulating cylinder.
A fold (insulation fold) 11 made of a polymer material is attached to the outer peripheral portion of the RP insulating cylinder 12, and the light guide 6 is housed therein together with SF ₆ gas 8 which is an insulating gas. Further, the joint portion of the FRP insulating cylinder 12 is joined by the flange 7 and the light guide lead-out flange 10. This coupling is located in the module 4 described above. Then, each module 4 is fed through the light guide outlet flange 10.

Here, the mounting positions of the pleats 11 made of a polymer material are as follows.
There are three places at the bottom, and one piece each, or multiple pieces are concentrated. Further, it is preferable that the method of attaching the pleats 11 is an efficient method in terms of improving the pressure resistance.

Next, in the air-insulation type thyristor valve having the light guide device of the present embodiment configured as described above, the inside of the FRP insulating cylinder 12 is about 3 to 10 times higher than air.
The creeping dielectric strength is improved by SF ₆ gas, which has about 10 times the dielectric strength. Further, by providing the pleats 11 on the outer peripheral portion of the FRP insulating cylinder 12, the creeping dielectric strength outside the FRP insulating cylinder 12 is improved. Especially in the fouling wet condition,
The breakdown voltage is improved by about 1.3 to 5 times. And overall,
It is possible to obtain a light guide device whose creeping breakdown voltage is improved several times. As a result, the height of the light guide device can be significantly reduced.

As described above, in the air-insulated thyristor valve of this embodiment, the light guide 6 for transmitting an optical signal for controlling the thyristor elements in the multi-layered modules 4 is made of a polymer material. F with folds 11
The light guide device formed by accommodating the SF ₆ gas, which is an insulating gas, in the RP insulating cylinder 12 is provided.

Therefore, the creeping dielectric strength of the light guide device can be improved, and the height of the light guide device can be reduced. This makes it possible to reduce the height of the air insulation type thyristor valve.

Therefore, DC 500 kV to be realized in the near future
The height of the thyristor valve can be significantly reduced, and high voltage and large capacity can be supported. Next, another embodiment of the present invention will be described.

FIG. 2 is a schematic view (side view) showing an example of the structure of an air-insulated thyristor valve equipped with the light guide device according to the present invention. The same elements as those in FIG. 5 are designated by the same reference numerals. There is.

In FIG. 1A, the structure in which the modules 4 each containing a thyristor element, a resistor and the like in a unit are stacked and stacked is the same as the conventional case shown in FIG. That is, in the air insulation type thyristor valve of the present embodiment, the lightning arrester for protecting the thyristor valve poles (between AK) is provided in the FRP insulating cylinder with the folds (insulation folds) 15 formed of a polymer material. Insulating gas SF ₆
An AK lightning arrester 14 formed by housing together with gas is installed.

Here, the mounting positions of the pleats 15 made of a polymer material are as follows.
There are three places at the bottom, and one piece each, or multiple pieces are concentrated. Further, it is preferable that the method of attaching the pleats 11 is an efficient method in terms of improving the pressure resistance.

Next, the A of the present embodiment configured as described above.
In the air insulation type thyristor valve equipped with the -K lightning arrester 14, the inside of the FRP insulation cylinder is about 3 to 1 from the air.
SF ₆ gas, which has about 0 times the dielectric strength, improves the creeping dielectric strength. Further, by providing the pleats 15 on the outer peripheral portion of the FRP insulating cylinder, the creeping dielectric strength outside the FRP insulating cylinder is improved. In particular, the pressure resistance is improved by about 1.3 to 5 times in the dirty and wet state. Then, as a whole, it is possible to obtain the AK lightning arrester 14 having a creeping breakdown voltage improved by several times.
As a result, the height of the AK lightning arrester 14 can be significantly reduced.

As described above, in the air insulation type thyristor valve of this embodiment, the lightning arrester for protecting the A-K pole of the thyristor valve body is formed in the FRP insulating cylinder with the pleats 15 made of the polymer material. In addition, an AK inter-pole arrester 14 formed by being housed together with SF ₆ gas which is an insulating gas is provided.

Therefore, the creeping dielectric strength of the AK pole arrester 14 can be improved, and the height of the AK pole arrester 14 can be reduced. This makes it possible to reduce the height of the air insulation type thyristor valve.

Therefore, DC 500 kV to be realized in the near future
The height of the thyristor valve can be significantly reduced, and high voltage and large capacity can be supported. Next, FIG.
FIG. 5A is a schematic view showing a configuration example of an air insulation type thyristor valve provided with the water cooling device according to the present invention, and FIG.
The same elements as those in are denoted by the same reference numerals.

In FIG. 3A, the structure in which the modules 4 each containing a thyristor element, a resistor and the like as a unit are stacked and stacked is the same as the conventional case shown in FIG. That is, in the air-insulation type thyristor valve of the present embodiment, by flowing the cooling water for cooling the thyristor element through the FRP water pipe 16 which is the FRP insulating cylinder with the pleats (insulation folds) formed of the polymer material, Forming a water cooling device.

FIG. 3 (b) is a schematic view showing a detailed structural example of the inside of the FRP water pipe 16. In FIG. 3B, a fold (insulation fold) 19 made of a polymer material is attached to the outer peripheral portion of the FRP insulating cylinder 20, and SF, which is cooling water, is provided inside.
₆ Gas 21 is passing. Further, the FRP insulating cylinder 20 is
The flange 18 and the water dividing flange 17 are connected to each other. This coupling is located in the module 4 described above. Then, by connecting the water pipe 22 and the valve 23 to the water dividing flange 17, cooling water is fed into the module 4.

Here, the mounting positions of the pleats 19 made of a polymer material are as follows.
There are three places at the bottom, and one piece each, or multiple pieces are concentrated. Further, it is preferable that the method of attaching the pleats 19 is an efficient method in terms of improving the pressure resistance.

Next, in the air insulation type thyristor valve equipped with the water cooling device of the present embodiment configured as described above, the inside of the FRP insulation cylinder 20 is SF having about 3 to 10 times the dielectric strength of air. ₆ Gas 21 improves the surface dielectric strength. In addition, a fold 1 is provided on the outer peripheral portion of the FRP insulating cylinder 20
By attaching 9, the creeping dielectric strength of the outside of the FRP insulating cylinder 20 is improved. Particularly in the fouling wet state, 1.
The breakdown voltage is improved about 3 to 5 times. Then, as a whole, it is possible to obtain a water cooling device having a creeping pressure resistance improved by several times.
As a result, the length of the water pipe can be significantly reduced.

As described above, the air-insulated thyristor valve of the present embodiment is a water formed by flowing cooling water for cooling the thyristor element through the FRP insulating cylinder 20 with the pleats 19 made of a polymer material. A cooling device is provided.

Therefore, the creeping dielectric strength of the water cooling device can be improved, and the length of the water pipe can be reduced. This makes it possible to reduce the height of the air insulation type thyristor valve.

Therefore, DC 500 kV to be realized in the near future
The height of the thyristor valve can be significantly reduced, and high voltage and large capacity can be supported. The present invention is not limited to the above embodiments, but can be implemented in the same manner as described below.

(A) As another embodiment corresponding to the embodiment of FIG. 3, although not shown, a plurality of Teflon pipes, which are water pipes for flowing cooling water for cooling the thyristor element, FRP with pleats made of polymer material
A water cooling device formed by housing together with SF ₆ gas which is an insulating gas may be provided in the insulating cylinder. The pleated mounting position in this case is also the same as in the above case.

With this structure, the creeping surface dielectric strength of the FRP insulating tubular portion can be significantly improved, and the length of the water pipe can be greatly reduced. (B) In each of the above-described embodiments, the case where SF ₆ gas is used as the insulating gas has been described, but the present invention is not limited to this, and it is also possible to use other insulating gases such as high pressure air and nitrogen. is there.

(C) In each of the above-mentioned embodiments, the insulating gas pressure inside the FRP insulating cylinder 12 is not particularly limited and explained, but it is assumed to be positive pressure and there is no other limitation. (D) In each of the above-mentioned embodiments, the polymer material forming the pleats attached to the FRP insulating cylinder 12 is not particularly limited.

(E) In each of the above embodiments, the FRP insulating cylinder 1
The case where the pleats are attached to the two folds has been described in the case of three places, but the pleats are not limited to this and may be increased in number as necessary. The place of attachment and the number of folds are not particularly limited.

(F) In each of the above embodiments, the case where FRP is used as the insulating cylinder material has been described, but the present invention is not limited to this, and other insulating materials such as Teflon, acrylic, and epoxy may be used. It is not particularly limited. In addition, the present invention can be variously modified and implemented within the scope of the invention.

[0052]

As described above, according to the present invention, in the air-insulated thyristor valve used in the AC / DC converter, the light transmitting the optical signal for controlling the thyristor elements in the multi-tiered modules. Guide
A light guide device formed by accommodating an insulating gas together with a pleated insulating cylinder made of a polymer material was provided, or a lightning arrester for protecting the anode-cathode electrode of the thyristor valve body was made of a polymer material. It is formed by accommodating an anode-cathode lightning arrester formed by accommodating insulating gas in a pleated insulating cylinder, or by flowing cooling water for cooling the thyristor element through a pleated insulating cylinder formed of a polymer material. It is equipped with a water cooling device or a water cooling device formed by accommodating a plurality of water pipes for flowing cooling water for cooling the thyristor element together with insulating gas in a pleated insulating cylinder made of a polymer material. As a result, the creeping dielectric strength of the light guide device, the water cooling device, and the lightning arrester between the anode and the cathode is improved, and It is achieving reduction, high voltage, high air insulating system thyristor valve extremely reliable which can correspond to the large capacity can be provided.

[Brief description of drawings]

FIG. 1 is a schematic view showing an embodiment (light guide portion) of an air insulation type thyristor valve according to the present invention.

FIG. 2 is a schematic view showing another embodiment (AK inter-pole lightning arrester section) of the air-insulated thyristor valve according to the present invention.

FIG. 3 is a schematic view showing another embodiment (water cooling section) of the air-insulated thyristor valve according to the present invention.

FIG. 4 is a single wire connection diagram showing a configuration example of a DC converter station.

FIG. 5 is a schematic diagram showing a configuration example of a conventional air insulation type thyristor valve.

FIG. 6 is a schematic diagram showing a configuration example of a water pipe portion of a conventional air-insulated thyristor valve.

[Explanation of symbols]

1 ... top shield, 2: insulating posts, 3 ... light guide receiving cylinder, 4 ... module, 5 ... frame, 6 ... light guide, 7 ... flange, 8 ... SF ₆ gas, 9 ... light guide, 10 ... light guide yarn end finding Flange, 11 ... Insulation fold, 12 ... FRP insulation tube, 13 ... Shield, 14 ... A-
K pole arrester, 15 ... pleats, 16 ... FRP water pipe, 1
7 ... Water diversion flange, 18 ... Flange, 19 ... Pleat, 20
… FRP insulation cylinder, 21… SF ₆ gas, 22… Water pipe,
23 ... Valve, 24 ... AC busbar, 25 ... Upper stage transformer for transformer, 26 ... Lower stage transformer for transformer, 27 ... Upper stage valve group, 28 ... Lower stage valve group, 29, 30 ... Between AK poles Lightning arrester, 31 ... DC reactor, 32 ... Thyristor valve, 33 ... AK pole arrester, 34 ... Light guide storage cylinder, 35 ... Water pipe (Teflon).

Claims (9)

[Claims] 1. In an air-insulated thyristor valve used in an AC / DC converter, a light guide for transmitting an optical signal for controlling thyristor elements in a multi-layered module is provided with a pleated material made of a polymer material. An air-insulated thyristor valve, characterized by comprising a light guide device formed by accommodating the insulating gas together with an insulating gas. 2. The air-insulated thyristor valve according to claim 1, wherein the pleats to be attached to the insulating cylinder are attached to the upper portion, the middle portion, and the lower portion at one piece respectively, or a plurality of pieces are collectively attached. An air-insulated thyristor valve characterized by the above. 3. In an air-insulated thyristor valve used in an AC / DC converter, a lightning arrester for protecting the anode-cathode electrode of the thyristor valve body is insulated in a pleated insulating cylinder made of a polymer material. Anode formed by housing with gas
An air-insulated thyristor valve comprising a lightning arrester between cathodes. 4. The air-insulated thyristor valve according to claim 3, wherein the pleats to be attached to the insulating cylinder are attached to the upper portion, the middle portion, and the lower portion at one piece respectively or a plurality of pieces are collectively attached. An air-insulated thyristor valve characterized by the above. 5. An air insulation type thyristor valve used in an AC / DC converter, comprising a water cooling device formed by flowing cooling water for cooling the thyristor element through an insulating cylinder with a fold formed of a polymer material. An air-insulated thyristor valve characterized by being provided. 6. The air-insulated thyristor valve according to claim 5, wherein the pleats to be attached to the insulating cylinder are attached to the upper portion, the intermediate portion, and the lower portion in a single piece or in a concentrated manner, respectively. An air-insulated thyristor valve characterized by the above. 7. In an air-insulated thyristor valve used in an AC / DC converter, a plurality of water pipes for flowing cooling water for cooling the thyristor element are provided in a pleated insulating cylinder formed of a polymer material. An air-insulated thyristor valve, characterized by comprising a water cooling device housed together with an insulating gas. 8. The air-insulated thyristor valve according to claim 7, wherein the pleats to be attached to the insulating cylinder are attached one at each of an upper portion, an intermediate portion, and a lower portion, or are collectively attached at a plurality of portions. An air-insulated thyristor valve characterized by the above. 9. An insulating material selected from the group consisting of FRP, Teflon, acrylic, and epoxy is used as the material of the insulating cylinder. Air insulation type thyristor valve described in.