JP2680511B2 - Gas insulated bushing - 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 insulating bushing in which an insulating tube is arranged near the inner surface of the insulating tube to prevent the scattering of the insulating tube. The present invention relates to a technology for diagnosing discharge.

[0002]

2. Description of the Related Art A gas-insulated bushing is a bushing in which a high-voltage conductor is coaxially arranged in a porcelain tube filled with a gaseous insulating medium. In such a gas-insulated bushing, the sealing pressure of the gaseous insulating medium filled inside the porcelain insulator is high, for example, 4 kgf / cm ² , so if the porcelain insulator is damaged, the damaged porcelain is scattered. there's a possibility that. In order to prevent such scattering of the porcelain bushing, conventionally, there has been proposed a gas insulating bushing in which an insulating cylinder is coaxially arranged near the inner surface of the porcelain bushing. FIG.
An example of a gas-insulated bushing having such a porcelain stone scattering prevention structure is shown in FIG.

That is, as shown in FIG. 4, an insulating medium 2 such as SF ₆ gas is enclosed in the porcelain tube 1, and
A high voltage conductor 3 is arranged coaxially with the porcelain insulator 1. The high-voltage conductor 3 is supported by an insulating support 4 in the lower part of the porcelain insulator 1 and by a metal support (not shown) in the upper part thereof. The high voltage conductor 3 is provided on the outer peripheral portion of the high voltage conductor 3 inside the lower end portion of the porcelain insulator 1.
A ground shield electrode (ground shield) 5 is arranged coaxially with the high-voltage conductor 3 with a constant space.

Further, in a bushing of a class in which the system circuit voltage is high, a space between the high voltage conductor 3 and the ground shield 5 is coaxial with the high voltage conductor 3 and has a constant spacing between the high voltage conductor 3 and the ground shield 5. Shield electrode for electric field control (shield for electric field control) 6
Is arranged. The electric field control shield 6 is supported and fixed to the ground shield 5 by an insulator 7.

Then, these shields 5 and 6 and the porcelain insulator 1
A ground side air shield electrode (ground side air shield) 8 is provided on the outer side of the lower end of the, and a high voltage side air shield electrode (high voltage on the high voltage side together with the cooler 12 is provided on the outer side of the upper end of the insulator tube 1. A side air shield) 9 is provided. By the shields 5, 6, 8 and 9 arranged in this way, the creeping electric field strength of the insulator tube flange portion 10 and the ground side air shield 8 and the insulator tube 1 is relaxed, and the withstand voltage is improved. ing.

On the other hand, the porcelain insulator 1 has a
Insulating cylinder 11 is arranged inside of, in such a manner as to be coaxial with porcelain bushing 1 and to maintain a slight gap with the inner surface of porcelain bushing 1. When the insulating cylinder 11 is arranged in this manner, the volume occupied by the insulating medium 2 between the insulating cylinder 11 and the porcelain bushing 1 is extremely small with respect to the entire volume of the insulating medium 2 filled in the porcelain bushing 1. is there. Therefore, the filling pressure of the insulating medium 2 is, for example, 4 kgf / cm ² as described above.
Even if the porcelain insulator 1 is damaged in this state, the damaged porcelain pipe will not scatter. As described above, in the gas-insulated bushing of FIG. 4, the simple structure of disposing the insulating cylinder 11 near the inner surface of the porcelain bushing 1 can reliably prevent the porcelain bushes from scattering.

[0007]

By the way, the insulating cylinder 11 used for the gas insulating bushing having the above-mentioned porcelain bush scattering prevention structure has the above-mentioned function.
In essence, the porcelain insulator 1 and the length of the degree of identification are required. In this case, the length of the insulating cylinder 11 is, for example, when the system circuit voltage is 50.
The bushing for 0 kV has a length of 5.4 m or more, and the bushing for 1100 kV, which is expected to be put to practical use in the future, has a length of 10 m or more. Since such a long insulating cylinder is required to have high mechanical strength, an epoxy impregnated material (GFRP) reinforced with glass fiber is generally used as the material thereof.

However, this type of long GFRP
Since it cannot be impregnated in a vacuum, there is a concern that voids may be generated. If a void is formed inside the insulating cylinder 11, a partial discharge may occur at the void portion during operation, resulting in insulation deterioration and a decrease in withstand voltage performance of the gas insulating bushing. In particular, for an organic insulating material such as GFRP, even a very small amount of partial discharge of several pC causes discharge deterioration over a long period of time, deterioration progresses, and the insulation cylinder 11 eventually causes dielectric breakdown. There is a fear.

Therefore, conventionally, the withstand voltage test and partial discharge measurement of the gas-insulated bushing have been conducted in the factory.
The apparent discharge charge due to the void discharge inside the insulating cylinder 11 is small, and it is difficult to measure from a coupling capacitor connected in parallel with the gas insulating bushing in terms of measurement accuracy. Further, in the partial discharge diagnosis of the gas insulation bushing during operation in the system circuit, the detection shield electrode (not shown) of the insulation support 4 shown in FIG. 1 is generally used. However, this method also applies to the insulating cylinder 1.
It is difficult to diagnose the void discharge inside No. 1 in terms of measurement accuracy.

The present invention has been proposed to solve the above-mentioned problems of the prior art.
It is an object of the present invention to provide a gas-insulated bushing having high insulation reliability, which can accurately measure partial discharge of defects such as voids inside the insulating cylinder with a simple configuration.

[0011]

A gas-insulated bushing of the present invention has a high-voltage conductor and a ground shield electrode arranged coaxially in a porcelain tube filled with a gaseous insulating medium, and In a gas-insulated bushing in which an insulating cylinder is coaxially arranged in the vicinity of the inner surface, a detection shield electrode is provided on the insulating cylinder, and it is configured so that partial discharge measurement of the insulating cylinder can be performed through the detection shield electrode. There is.

As a concrete structure of the detection shield electrode of the insulating cylinder, for example, a metal flange is provided on the insulating cylinder, and this metal flange is used as the detection shield electrode. Then, prepare an insulating support board in which the electrode with screw is embedded and the detection terminal is attached, and the metal flange is supported and fixed to this insulating support board, and the lead wire connects the metal flange and the voltage detection via the electrode with screw. It is possible to electrically connect the terminals so that the terminals have the same potential.

Alternatively, an insulating flange is provided on the insulating cylinder, and a metal electrode foil is arranged on the lower end surface of the insulating flange,
This metal electrode foil is used as a voltage detection shield electrode. Then, in the same manner as in the above case, prepare an insulating support board in which the threaded electrode is embedded and the detection terminal is attached, and the insulating flange is supported and fixed to this insulating support board, and the lead wire is used to attach the threaded electrode. It is possible to electrically connect the metal electrode foil and the detection terminal via the metal foil so as to have the same potential.

[0014]

In the gas-insulated bushing of the present invention constructed as described above, the partial discharge caused by the defect inside the insulating cylinder can be directly detected by the detection shield electrode provided on the insulating cylinder. Compared to indirect detection, such as when measuring from a coupling capacitor that is connected in parallel with an insulating bushing or when using the voltage detection shield electrode of an insulating support that supports high-voltage conductors. Therefore, the detection accuracy of the partial discharge can be significantly improved.

Therefore, even if a defective portion such as a minute void exists inside the insulating cylinder, it can be diagnosed in advance by a factory test before the operation of the gas insulating bushing is started. In addition, even if a partial discharge occurs in the insulating cylinder during operation in the system circuit, connecting the partial discharge monitoring device to the voltage detection terminal will prevent the insulating cylinder from being damaged before the insulation deterioration and insulation breakdown. It is possible to detect the internal partial discharge with high accuracy and diagnose the existence of a defect inside the insulating cylinder.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A typical embodiment of the gas insulating bushing according to the present invention will be specifically described below with reference to FIGS. In this case, FIG. 1 is a cross-sectional view showing the gas insulating bushing, and FIG. 2 is a cross-sectional view showing details of the metal flange corresponding to the detection shield electrode and the insulating support board.
Incidentally, the same parts as those of the conventional example shown in FIG.

In this embodiment, as shown in FIG.
A metal flange 11a is attached to the insulating cylinder 11 as a detection shield electrode of the present invention, and the metal flange 11a is supported and fixed to the insulating support board 13.
That is, as shown in FIG. 2, an insulating cylinder supporting screw electrode 13a and a metal container supporting screw electrode 13b are arranged on the circumference inside and outside the insulating support plate 13 at equal intervals. . The metal flange 11a is fastened to the insulating cylinder supporting screw electrode 13a with a bolt 21 to support and fix the insulating cylinder 11. On the other hand, the insulating support board 13 has a bolt 2 attached to the electrode 13b with a screw for supporting the metal container.
By fastening 2 and 23, the porcelain bushing flange portion 10 is supported and fixed, and is also supported and fixed to the metal container 14. Further, outside the insulating support board 13, a voltage detection terminal 13c is provided.
Is provided, and the detection terminal 13c is electrically connected to the insulating cylinder supporting screw electrode 13a by the detection lead wire 13d.

In the gas insulating bushing of this embodiment having the above-mentioned structure, the following operational effects can be obtained. That is, in this embodiment, the metal flange 11a provided on the insulating cylinder 11 is electrically connected to the detection terminal 13c via the bolt 21, the insulating cylinder supporting screw electrode 13a, and the detection lead wire 13d. They are connected and have the same potential. Therefore, by connecting the partial discharge detection device to the voltage detection terminal 13c, the discharge pulse current flowing by the void discharge inside the insulating cylinder 11 must be the metal flange 11a.
Flow through the detection lead wire 13d to the partial discharge detection device connected to the detection terminal 13c, and the partial discharge detection device detects the partial discharge.

As described above, in the present embodiment, when a partial discharge is generated inside the insulating cylinder 11, the partial discharge inside the insulating cylinder 11 is caused by the discharge current flowing from the metal flange 11a of the insulating cylinder 11 to the detection terminal 13c. It can be detected directly. Therefore, the partial discharge of the insulating cylinder 11 can be detected with extremely high accuracy as compared with the conventional case. For example,
It is possible to accurately measure even an apparent partial discharge charge amount of a few pC which is generated due to a minute void defect inside the insulating cylinder 11. Since such partial discharge can be detected with high accuracy, the presence or absence of an internal defect in the insulating cylinder 11 can be detected promptly, and appropriate countermeasures can be taken at an early stage to improve the insulation reliability.

Next, another embodiment of the gas insulating bushing according to the present invention will be specifically described with reference to FIG. In this case, it is a cross-sectional view showing a detection shield electrode (detection shield) and an insulating support board in the gas insulating bushing. In the embodiment of FIG. 3, an insulating flange 11b is attached to the insulating cylinder 11, and a metal electrode foil-shaped detection shield electrode (detection shield) 15 is arranged on the annular lower end surface of the insulating flange 11b. ing. The insulating flange 11b is fastened to the insulating cylinder supporting screw electrode 13a with a bolt 21 to support and fix the insulating cylinder 11. The other parts are configured in the same manner as in the above embodiment.

Also in the gas insulating bushing of this embodiment having the above-mentioned structure, the same effect as that of the above embodiment can be obtained. That is, in the present embodiment, the detection shield 15 is electrically connected to the detection terminal 13c through the bolt 21, the insulating cylinder supporting screw electrode 13a, and the detection lead wire 13d, and has the same potential. Has been done. Therefore, by connecting the partial discharge detection device to the detection terminal 13c, the discharge pulse current flowing by the void discharge inside the insulating cylinder 11 must be surely from the detection shield 15 to the detection lead wire 1.
It flows through 3d to the partial discharge detection device connected to the detection terminal 13c, and is detected by this partial discharge detection device.

As described above, in this embodiment, when a partial discharge occurs inside the insulating cylinder 11, the partial discharge inside the insulating cylinder 11 is caused by the discharge current flowing from the detection shield 15 of the insulating cylinder 11 to the detection terminal 13c. Can be detected directly. Therefore, the partial discharge of the insulating cylinder 11 can be detected with extremely high accuracy as compared with the conventional one, so that the presence or absence of an internal defect in the insulating cylinder 11 can be detected promptly and appropriate in an early stage, as in the above embodiment. Therefore, the insulation reliability can be improved.

The present invention is not limited to the above-mentioned embodiments, and the specific construction of the detection shield electrode provided in the insulating cylinder and the peripheral portion thereof can be appropriately selected. Further, the present invention is not limited to the gas-insulated bushing shown in each of the embodiments, but is widely applicable to a gas-insulated bushing in which an insulating tube is arranged in the vicinity of the inner surface of the porcelain tube to prevent scattering of the porcelain tube. The action and effect can be obtained.

[0024]

As described above, in the present invention,
With a simple configuration in which the detection shield electrode is arranged in the insulating cylinder, it is possible to provide a gas insulating bushing with high insulation reliability that can accurately measure partial discharge of defects such as voids inside the insulating cylinder.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a typical embodiment of a gas insulating bushing according to the present invention.

FIG. 2 is a cross-sectional view showing details of a metal flange and an insulating support board corresponding to a voltage detection shield electrode in the gas insulating bushing of FIG.

FIG. 3 is a sectional view showing a detection shield electrode (detection shield) and an insulating support board in another embodiment of the gas insulating bushing according to the present invention.

FIG. 4 is a cross-sectional view showing an example of a conventional gas insulation bushing.

[Explanation of symbols] 1 ... Insulator 2 ... Insulating medium 3 ... High-voltage conductor 4 ... Insulating support 5 ... Ground shield 6 ... Electric field control shield 7 ... Insulator 8 ... Ground side air shield 9 ... High voltage side air Shield 10 ... Insulator pipe flange 11 ... Insulation cylinder 11a ... Metal flange (electrodetection shield electrode) 11b ... Insulation flange 12 ... Cooler 13 ... Insulation support plate 13a ... Insulation cylinder supporting screw electrode 13b ... Metal container supporting screw Electrode 13c ... Detection terminal 13d ... Detection lead wire 14 ... Metal container 15 ... Detection shield 21-23 ... Bolt

Claims (1)

(57) [Claims] 1. A gas in which a high-voltage conductor and a ground shield electrode are coaxially arranged in a porcelain tube filled with a gaseous insulating medium, and an insulating cylinder is coaxially arranged in the vicinity of an inner surface of the porcelain tube. In the insulating bushing, the gas insulation bushing is characterized in that a detection shield electrode is provided on the insulation cylinder so that partial discharge measurement of the insulation cylinder can be performed through the detection shield electrode.