JP3480038B2 - Gas insulated stationary induction device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas-insulated static induction electric device, and in particular, a plurality of units are divided and installed, and these are three-phase connected and an insulating gas such as SF ₆ gas is enclosed. The present invention relates to a gas-insulated static induction electric appliance suitable for use in the above.

[0002]

2. Description of the Related Art As a tank of a static induction electric device, for example, a tank shown in Japanese Patent Laid-Open No. 56-4218 is adopted. A stationary induction machine using such a tank usually has the following features:
Various lead wires (primary, secondary, and tertiary lead wires, secondary neutral point lead wires, tap lead wires, etc.) are drawn from the top surface of the tank to connect the units.

[0003]

By the way, when the above-mentioned conventional method is adopted for the static induction machine installed in an underground substation or the like, since the lead wire is pulled out from the upper surface of the tank, the lead wire is stored. The height of the lead wire duct is increased, and when it is used in an underground substation, the underground excavation depth becomes large, and the construction cost of the underground substation greatly increases. It was

The present invention has been made in view of the above points,
It is an object of the present invention to provide a gas-insulated static induction generator capable of significantly reducing the construction cost even when the entire apparatus is simple and downsized to be used in an underground substation.

[0005]

To achieve the above objectives in the present invention SUMMARY OF THE INVENTION, one unit is a single-phase structure, is insulated gas per unit sealed, then placed the contents of at least the winding and the iron core It is characterized in that the three cylindrical tanks are arranged vertically and are arranged substantially linearly, and the longitudinal direction of the iron core is substantially the same as the arrangement direction of the cylindrical tank. .

Further, in the present invention, three cylindrical tanks are provided.
The load tap changers are arranged in the same direction, the tap lead wire is drawn out from the side surface of the cylindrical tank, and the drawn tap lead wire is a duct between the cylindrical tanks. that the inner and the tank side is as connected to the load <br/> tap changer, three cylindrical tank <br/> click is substantially linearly arranged, and each of the primary lead But
Withdrawn from the side middle portion of the cylindrical tank, these drawn primary lead is housed in the three cylindrical installation direction substantially parallel-arranged common primary lead wire duct of the tank That, three cylindrical tanks and a load
When a tap changer is arranged at a predetermined interval in the same direction, and the phase between adjacent cylindrical tanks, and the tap lead between the cylindrical tank <br/> click-load tap changer is arranged between the Are connected by ducts for pipes, and adjacent cylindrical tanks on the opposite side to the side where the ducts for tap lead wires are arranged are connected by ducts for lead wires arranged between the cylindrical tanks. are possible, placing three cylindrical tank in a substantially linear shape, and provided with a condenser for each said cylindrical tank, to the arrangement of the cooling device and the cable head alternately, three cylindrical with installing the tank every vertical, placing them in a substantially linear shape, and the cylindrical
The load tap changer in a part of the form the tank between the side are arranged, together with placing the three cylindrical tanks every vertical, placing them in a substantially linear shape, and the cylindrical tank <br /> A part of the side of the cylindrical tank where the duct for tap lead wires that accommodates the tap lead wires is connected
Each is characterized in that an on- load tap changer is arranged.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the gas-insulated static induction generator of the present invention will be described in detail with reference to the illustrated embodiments. still,
In this embodiment, a gas insulation transformer will be described as an example.

1 and 2 show an embodiment of the gas insulation transformer of the present invention. As shown in the figure, in the gas-insulated transformer of this embodiment, the content of the iron core 1 and the winding 2 has a single-phase unit, and is a cylinder in which SF ₆ gas is enclosed in each unit. It is configured by being stored in the shape tank 3,
Three of these are installed. Each of the cylindrical tanks 3 is installed vertically and is arranged in a straight line in a row together with the load tap changer 4, and the longitudinal direction of the iron core 1 is substantially the same as the arrangement direction of the cylindrical tank 3. It is in the same direction. Further, each adjacent cylindrical tank 3 has a lead in which a tertiary lead wire 9, a secondary lead wire 10, and a secondary neutral point lead wire 11 which will be described later and which are arranged laterally of the cylindrical tank 3 are housed. On the other hand, the taps described later are arranged between the adjacent cylindrical tanks 3 on the opposite side to each other, and between the cylindrical tank 3 and the tap changer 4 under load, which are connected to each other by a wire duct 5. The lead wires 13 are connected by a tap lead wire duct 15 which is housed therein. Further, a cooler 14 for cooling the above SF ₆ gas for each cylindrical tank 3
Is provided.

A primary lead wire 12 is connected to each winding. Each of the primary lead wires 12 is drawn out from the center of the side surface of each cylindrical tank 3, and the drawn primary lead wires 12 are They are housed in a common primary lead wire duct 16 which is arranged substantially parallel to the installation direction of the above three substantially cylindrical tanks 3. Furthermore, from each winding 2 to the tertiary lead wire 9, the secondary lead wire 10,
A tertiary cable head 6, a secondary cable head 7, and a secondary neutral point cable head 8 for drawing out the secondary neutral point lead wire 11 as an external terminal are provided, and these tertiary cable head 6 and secondary cable head 7 are provided. , The cooler 14 is arranged alternately with the secondary neutral point cable head 8. Tertiary lead wire 9, secondary lead wire 1 from each winding 2
0, the secondary neutral point lead wire 11 is passed through the inside of the lead wire duct 5 arranged laterally between the adjacent cylindrical tanks 3 described above, and is crossed over the inside of the cylindrical tank 3 to form each cable. Connected to the heads 6, 7, 8 and the primary side busbar.

Reference numeral 13 denotes a tap lead wire for connecting each winding 2 and the tap changer 4 under load.
3 is drawn out from each winding 2 from the side surface of each cylindrical tank 3, passes through the duct 15 for tap lead wires from this side surface, and crosses the inside of the adjacent cylindrical tank 3. It passes through the inside of the shaped tank 3 and is connected to the tap changer 4 under load.

According to the structure of this embodiment, since the three cylindrical tanks are installed vertically and are arranged substantially linearly, the entire apparatus is simple and compact. Of course, since the longitudinal direction of the iron core is the same as the arrangement direction of the three cylindrical tanks, each lead wire can be pulled out from the side surface of the cylindrical tank. Since the length of the lead wire duct accommodating each lead wire can be shortened by extending each lead wire inside the cylindrical tank, the overall planar dimension is As the gas-insulated transformer is simple and miniaturized for use in an underground substation, the construction cost will be greatly reduced because it hardly increases.

3 and 4 show another embodiment of the present invention. The schematic configuration of the embodiment shown in the figure is substantially the same as that of the above-described embodiment, and thus detailed description thereof is omitted.

In this embodiment, a load tap changer 4 is arranged on a side of a part between the cylindrical tanks 3 in parallel with the arrangement direction of the cylindrical tanks 3. Between this load tap changer 4 and the cylindrical tank 3, and the adjacent cylindrical tank 3
A tap lead wire 13, which will be described later, is housed in the space.

A primary lead wire 12 is connected to each winding 2, and each of the primary lead wires 12 is drawn out from the central portion of the side surface of each cylindrical tank 3. Each winding 2 and the tap changer 4 under load are connected by a tap lead wire 13. The tap lead wire 13 is drawn from each winding 2 from the side surface of each cylindrical tank 3, while the tap changer under load is connected. The tap lead wire 13 drawn out from the side surface of the cylindrical tank 3 adjacent to the nozzle 4 is the tap lead wire duct 1
A tap lead wire 1 connected directly to the tap changer 4 under load and drawn out from the other side, that is, from the side surface of the cylindrical tank 3 separated from the tap changer 4 during load.
3 passes through the duct 15 for tap lead wires, crosses the inside of the adjacent cylindrical tanks 3, and is connected to the tap changer 4 under load.

Even with the structure of this embodiment, the same effect as that of the above-described embodiment can be obtained.

[0016]

According to the gas-insulated static induction machine of the present invention described above, the construction cost can be greatly reduced even when the entire apparatus is simple and miniaturized for use in an underground substation. There is an effect that there is.

[Brief description of drawings]

FIG. 1 is a plan view showing a gas-insulated transformer that is an embodiment of the gas-insulated static induction generator of the present invention.

FIG. 2 is a front view of FIG.

FIG. 3 is a plan view showing another embodiment of the gas-insulated static induction generator of the present invention.

FIG. 4 is a front view of FIG.

[Explanation of symbols]

1 ... Iron core, 2 ... Winding, 3 ... Cylindrical tank, 4 ... Load tap changer, 5 ... Lead wire duct, 6 ... Tertiary cable head, 7 ... Secondary cable head, 8 ... Secondary neutral point Cable head, 9 ... tertiary lead wire, 10 ... secondary lead wire,
11 ... Secondary neutral point lead wire, 12 ... Primary lead wire, 13
... Tap lead wire, 14 ... Cooler, 15 ... Tap lead wire duct, 16 ... Primary lead wire duct.

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shuzo Sakaguchi 1-1-1, Kokubun-cho, Hitachi City, Ibaraki Hitachi Ltd., Kokubun Plant, Hitachi, Ltd. (56) References: 60-66018 (JP, U) ) (58) Fields surveyed (Int.Cl. ⁷ , DB name) H01F 36/00-38/42

Claims (9)

(57) [Claims] The method according to claim 1 One unit is the single-phase configuration, the cylindrical tank insulating gas is sealed in each unit, is constructed by housing the contents consisting of an iron core and at least winding, they are installed three And each winding and tap of each unit
Equipped with a load tap changer connected via a pleated wire
The three circles in the gas insulated static induction
With installing a cylindrical tank every vertical, they were placed in a substantially straight line, and, Ri substantially the same direction der the arrangement direction of the longitudinal direction cylindrical tank of the iron core, the three cylindrical Tan
And the tap changer under load are arranged in the same direction.
From the side of the cylindrical tank,
As it is pulled out, the drawn tap lead wire is
In a duct between the cylindrical tanks and the cylindrical tank
A gas-insulated static induction machine, characterized in that the gas-insulated static induction machine passes through the inside and is connected to the load tap changer . 2. A cylindrical tank in which one unit has a single-phase structure and in which an insulating gas is filled for each unit, and at least the contents consisting of a winding wire and an iron core are housed therein, and three of these are installed. In addition, in the gas-insulated static induction machine in which a primary lead wire is connected to each of the windings, the three cylindrical tanks are installed vertically, and these are arranged substantially linearly, and The longitudinal direction of the iron core is substantially the same as the arranging direction of the cylindrical tank, each of the primary lead wires is drawn out from the center of the side surface of the cylindrical tank, and these drawn primary lead wires are the three pieces. A gas-insulated static induction machine, characterized in that the gas-insulated static induction machine is housed in a common primary lead wire duct arranged substantially parallel to the installation direction of the cylindrical tank. 3. A cylindrical tank in which one unit has a single-phase structure and an insulating gas is enclosed in each unit, and at least the winding and an iron core are contained in the cylindrical tank, and three units are installed. In addition, in the gas-insulated static induction machine equipped with a load tap changer connected to each winding of each unit via a tap lead wire, the three cylindrical tanks are installed vertically. In addition, these are arranged in a substantially straight line, and the longitudinal direction of the iron core is substantially in the same direction as the arrangement direction of the cylindrical tanks, and the three cylindrical tanks and the tap changer during load are predetermined in the same direction. Gas insulation characterized in that it is connected with a gap between the cylindrical tanks adjacent to each other and between the cylindrical tanks and the tap changer under load, and is connected by ducts for tap lead wires. Stationary invitation Electric Appliances. 4. A tap lead wire connecting each winding of each unit and a tap changer under load is drawn from a side surface of the cylindrical tank, and the drawn tap lead wire is the tap. The gas-insulated static induction machine according to claim 3, wherein the gas-insulated static induction machine passes through the lead wire duct and the inside of the cylindrical tank and is connected to the load tap changer. 5. A cylindrical tank in which one unit has a single-phase structure and in which an insulating gas is sealed in each unit, at least the contents of a winding and an iron core are housed, and three of these are installed. In addition, in the gas-insulated static induction machine equipped with a load tap changer connected to each winding of each unit via a tap lead wire, the three cylindrical tanks are installed vertically. In addition, these are arranged in a substantially straight line, and the longitudinal direction of the iron core is substantially in the same direction as the arrangement direction of the cylindrical tanks, and the three cylindrical tanks and the tap changer during load are predetermined in the same direction. Connected by ducts for tap lead wires arranged at intervals and between adjacent cylindrical tanks and between the cylindrical tank and the tap changer under load, and for the tap lead wires. Duck There the gas insulated stationary induction apparatus, characterized in that the cylindrical tank adjacent opposite phases are connected in a deployed leads duct between the cylindrical tank to the side are disposed. 6. A unit comprising a single-phase unit, a unit having a single-phase structure, and a unit having a cylindrical tank in which an insulating gas is filled, in which at least a winding and an iron core are contained, and three units are installed. In addition, in a gas-insulated static induction generator equipped with a load tap changer connected to each winding of each unit via a tap lead wire, a cooler for cooling the insulating gas and each winding And a plurality of cable heads for pulling out the lead wire of
The individual cylindrical tanks are installed vertically and are arranged substantially linearly, and the longitudinal direction of the iron core is substantially the same direction as the arrangement direction of the cylindrical tanks. A gas-insulated static induction machine characterized in that a cooler is provided, and the cooler and the cable head are arranged alternately. 7. A unit comprising a single-phase unit, and a cylindrical tank in which an insulating gas is filled in each unit contains at least a winding and an iron core, and three units are installed. In addition, in the gas-insulated static induction machine equipped with a load tap changer connected to each winding of each unit via a tap lead wire, the three cylindrical tanks are installed vertically. Together, these are arranged in a substantially straight line, and the longitudinal direction of the iron core is substantially the same direction as the arrangement direction of the cylindrical tank, and the tap tap changer at the time of loading on a part of the side between the cylindrical tanks. A gas-insulated static induction generator characterized in that it is arranged. 8. A unit comprising a single-phase unit, a unit having a single-phase structure, and a unit having a cylindrical tank in which an insulating gas is filled, in which at least a winding and an iron core are contained, and three units are installed. In addition, in the gas-insulated static induction machine equipped with a load tap changer connected to each winding of each unit via a tap lead wire, the three cylindrical tanks are installed vertically. Together, these are arranged substantially linearly, and the longitudinal direction of the iron core is substantially the same direction as the arrangement direction of the cylindrical tanks, the cylindrical tanks are connected to each other, and the tap lead wires for accommodating the tap lead wires are accommodated. A gas-insulated static induction machine in which the load tap changer is arranged on a part of a side of the cylindrical tank in which a duct for use is arranged. 9. The tap lead wire is drawn out from the side surface of the cylindrical tank, and the tap lead wire drawn out from the cylindrical tank adjacent to the load tap changer is directly connected to the tap changer. A tap lead wire that is connected and drawn from a cylindrical tank that is separate from the tap changer passes through the inside of the tap lead wire duct and the inside of the cylindrical tank, and is connected to the tap switch during load. The gas-insulated static induction machine according to claim 8, wherein