JP2001358024A - Gas-insulated stationary induction apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a gas-insulated stationary induction apparatus which is simplified in structure and reduced in size as a whole and, accordingly, can significantly reduce the construction cost even when the apparatus is adopted to an underground transformer station. SOLUTION: This gas-insulated stationary induction apparatus is constituted by vertically installing a plurality of cylindrical tanks 3 one unit of which is constituted in a single phase, encloses an insulating gas, and houses contents composed at least of a winding and a core along a straight line and arranging on-load tap changers in parallel with the arrangement directions of the tanks 3 in partial lateral spaces between adjacent tanks 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to relates to a gas insulated stationary induction apparatus, in particular, with a plurality of units are installed by dividing, they are three-phase connections, and an insulating gas such as SF ₆ gas is filled The present invention relates to a gas insulated stationary induction device suitable for the above.

[0002]

2. Description of the Related Art For example, a tank as disclosed in Japanese Patent Laid-Open Publication No. Sho 56-4218 is employed as a tank for a stationary induction device. Stationary induction devices using such tanks are usually designed to minimize the site area,
Various lead wires (primary, secondary, and tertiary lead wires, secondary neutral point lead wires, tap lead wires, etc.) are drawn out from the tank upper surface to connect the units.

[0003]

By the way, if the above-mentioned prior art method is adopted for a stationary induction device installed in an underground substation or the like, the lead wire is drawn out from the upper surface of the tank, so that the lead wire is stored. However, when used in an underground substation, there is a drawback that the underground excavation depth increases and the construction cost of the underground substation increases.

[0004] 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 stationary induction device that can greatly reduce the construction cost even when the entire device is simple and small in size and used in an underground substation.

[0005]

According to the present invention, in order to achieve the above object, one unit has a single-phase structure, an insulating gas is sealed in each unit, and at least the contents of a winding and an iron core are stored. A plurality of tanks are arranged vertically, and these are arranged in a substantially L-shape, and taps are formed so as to form a substantially inverted L-shape with tanks located at both ends of the L-shape arrangement. A switching device is provided.

In the present invention, the tap lead wires are respectively drawn out from the side surfaces of the plurality of tanks, and each of the tap lead wires is connected to the tap changer via a stored tap lead wire duct. It is characterized by being connected.

[0007] Further, the tap lead wire drawn out from the side surface of the center tank arranged in the L-shape,
It is characterized in that it is connected to the tap changer through between tanks located at both ends of the L-shaped arrangement.

Further, the tap leads are respectively drawn out from the side faces of the plurality of tanks, and the tap lead wires drawn out from the tank side faces located at both ends of the L-shaped arrangement are housed tap leads. The tap lead wire, which is connected to the tap changer via a wire duct and is drawn out from the side surface of the central tank arranged in an L-shape, is connected to the tap in one of adjacent tanks and the tap lead wire. It is connected to the tap changer through a lead wire duct.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a gas-insulated stationary induction device according to the present invention will be described in detail based on the illustrated embodiment. still,
This embodiment will be described by taking a gas-insulated transformer as an example.

FIG. 1 shows an embodiment of a gas-insulated transformer according to the present invention. As shown in the figure, the gas-insulated transformer of the present embodiment has a cylindrical structure in which one unit has a single-phase configuration and is filled with SF ₆ gas for each unit. It is configured to be housed in a shaped tank 3, and a plurality of these are installed. Each of the cylindrical tanks 3 is installed vertically and is arranged in a substantially straight line in a line, and the longitudinal direction of the iron core 1 is substantially the same as the arrangement direction of the cylindrical tank 3. In addition, each adjacent cylindrical tank 3
Are connected by a lead wire duct 5 in which a tertiary lead wire 9, a secondary lead wire 10, and a secondary neutral lead wire 11, which will be described later, are disposed in a side space of the cylindrical tank 3. , On the other hand, the adjacent cylindrical tank 3 on the opposite side
A load tap changer 4 is disposed in a part of the side space between the load tap changer 4 and the cylindrical tank 3, and is arranged in parallel with the arrangement direction of the cylindrical tank 3. The tanks 3 are connected by a tap lead wire duct 15 in which a tap lead wire 13 described later is stored. Furthermore,
A cooler 14 for cooling the SF ₆ gas is provided for each cylindrical tank 3.

Further, a primary lead wire 12 is connected to each winding 2, and each of the primary lead wires 12 is drawn out from the center of the side surface of each cylindrical tank 3, A tertiary cable head 6, a secondary cable head 7, and a secondary neutral cable head 8, which lead out the lead wire 9, secondary lead wire 10, and secondary neutral lead wire 11 as external terminals, are provided. The cooler 14 is arranged alternately with the tertiary cable head 6, the secondary cable head 7, and the secondary neutral point cable head 8. The tertiary lead 9, the secondary lead 10, and the secondary neutral lead 11 from each winding 2 are connected to the above-described lead wire duct 5 arranged in the side space between the adjacent cylindrical tanks 3. Through the inside, it is connected to each of the cable heads 6, 7, 8 and the primary-side bus through the inside of the cylindrical tank 3.

Reference numeral 13 denotes a tap lead wire for connecting each of the windings 2 to the load tap changer 4.
3 is drawn out from each winding 2 from the side surface of each cylindrical tank 3, and the cylindrical tank 3 adjacent to the load tap changer 4.
Is connected directly to the on-load tap changer 4 via the tap lead wire duct 15, and the other, that is, the on-load tap changer 4
The tap lead wire 13 drawn out from the side surface of the cylindrical tank 3 that is separated from the tank tank passes through the tap lead wire duct 15, passes through the inside of the adjacent cylindrical tank 3, and is connected to the on-load tap changer 4. .

According to the structure of this embodiment, a plurality of cylindrical tanks are installed vertically, these are arranged substantially linearly, and a part of the space between adjacent cylindrical tanks is provided. In the side space, the tap changer under load is arranged in parallel with the arrangement direction of the cylindrical tank, so that the entire apparatus is simple and compact, and of course, the longitudinal direction of the iron core is reduced. Since the same direction as the arrangement direction of the plurality of cylindrical tanks, each lead wire can be pulled out from the side surface of the cylindrical tank, so that the installation height of the gas insulated transformer can be reduced, Since the length of the lead wire duct that stores each lead wire inside the cylindrical tank can be shortened, the overall plane size hardly increases, so the gas insulated transformer is simpler and smaller in the end. Used in underground substations Case, so that the construction cost is greatly reduced.

[0014]

According to the gas insulated stationary induction device of the present invention described above, one unit has a single-phase configuration, an insulating gas is sealed in each unit, and at least the contents of the winding and the iron core are accommodated. A plurality of tanks are arranged vertically, and these are arranged substantially linearly, and a tap changer is arranged in parallel with this arrangement direction. In addition to being installed vertically, these are arranged substantially linearly, and a tap changer is arranged in a part of the side space between the tanks, and a plurality of tanks are installed vertically. And a tap changer is arranged in a part of the tank side space where the duct for the tap lead wire which connects the tanks and stores the tap lead wire is arranged. , The tap lead wire is Along with being pulled out from the side of,
The tap lead drawn from the tank adjacent to the tap changer is directly connected to the tap changer, and the tap lead drawn from the tank remote from the tap changer is inserted into the tap lead duct and Because each is characterized by being connected to a tap changer through the tank, the construction cost is greatly reduced even if the entire device is simple and small and used in underground substations A possible gas-insulated static induction appliance can be obtained.

[Brief description of the drawings]

FIG. 1 is a plan view showing a gas-insulated transformer, which is one embodiment of the gas-insulated stationary induction device of the present invention.

FIG. 2 is a front view of FIG.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Iron core, 2 ... Winding, 3 ... Cylindrical tank, 4 ... Tap changer under load, 5 ... Duct for lead wire, 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 lead, 12 ... primary lead, 13
... Tap lead wire, 14 ... Cooler, 15 ... Tap lead wire duct, 16 ... Primary lead wire duct.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Iwao Umene 1-1-1, Kokubuncho, Hitachi City, Ibaraki Prefecture Inside the Kokubu Plant, Hitachi, Ltd. No. 1 in the Kokubu Plant of Hitachi, Ltd.

Claims (4)

[Claims] 1. One unit is constituted as a unit, and at least the contents consisting of a winding and an iron core are housed in a tank filled with an insulating gas for each unit. In a gas-insulated stationary induction device having a tap changer connected to each winding of each unit via a tap lead wire, the plurality of tanks are installed vertically and these are substantially L-shaped. Wherein the tap changers are arranged so as to form a substantially inverted L-shape with tanks located at both ends of the L-shape arrangement. 2. The tap lead wire is drawn out from a side surface of each of the plurality of tanks, and each of the tap lead wires is connected to the tap changer through a stored tap lead wire duct. The gas insulated stationary induction device according to claim 1, wherein: 3. The tap lead wire drawn from the side surface of the central tank arranged in the L-shape passes between tanks located at both ends of the L-shape arrangement and is connected to the tap changer. The gas-insulated stationary induction device according to claim 2, wherein the induction device is provided. 4. A tap lead wire drawn out from each of the plurality of tank side faces, and the tap lead wires drawn out from the tank side faces located at both ends of the L-shaped arrangement are housed tap lead wires. The tap lead wire connected to the tap changer via the duct for use and drawn out from the side surface of the central tank arranged in an L-shape is connected to the tap lead wire in one of adjacent tanks and the tap lead. 2. The gas insulated stationary induction device according to claim 1, wherein the device is connected to the tap changer through a wire duct.