JPS6122463Y2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to high-voltage switches that are installed in large numbers in the middle of high-voltage distribution lines, especially high-voltage underground distribution lines. The purpose is to enable detection.

High-voltage power distribution lines in urban centers are almost always installed underground due to geographical and various external conditions.

In this way, when high-voltage distribution lines are installed underground, various inspections on the distribution lines, such as inspections of the voltage of each phase, can be carried out because the wires of each phase are completely shielded and because they are buried underground. Therefore, detection tests were extremely difficult.

The present invention was devised to solve the above-mentioned inconvenience of high-voltage underground distribution lines, and utilizes high-voltage switches installed at approximately equal intervals along the high-voltage underground distribution lines. This allows for easy inspection of each phase voltage.

It should be noted that the present invention is applicable to high-voltage overhead power distribution lines as well, as the electric wires of each phase are being coated recently.

An embodiment of the present invention will be described below with reference to the drawings.

In the figure, 1 is a case serving as a frame of a high voltage switch, and this case 1 is made of a steel plate and is grounded.

Bushings 2 made of an electrically insulating material, each having an internal conductor 3 connected to a power distribution line fixed thereto, are fixed to opposing side wall portions of the case 1 in a state that the bushings 2 penetrate through the side walls of the case 1, respectively.

The ends of the internal conductor 3 fixed to the case 1 via this bushing 2 are electrically connected by a rotating conductor 4 rotatably assembled inside the case 1. Alternatively, by automatic operation, the rotating conductor 4 can be rotated using the elasticity of a spring or the like to interrupt the connection between the opposing internal conductors 3, 3, thereby placing the distribution line in a disconnected state. It's becoming like that.

The outer peripheral surface of the part of the bushing 2 (in the illustrated embodiment, the left side in FIG. 1), which securely holds the internal conductor 3 connected to the distribution line of the power transmission system on one side, is located inside the case 1. A metal electrode 5 is arranged and fixed in a position facing the internal conductor 3 fixedly held by the bushing 2, and forms a capacitor structure between the metal electrode 5 and the internal conductor 3.

Each metal electrode 5 forming a capacitor structure with the internal conductor 3 is connected to a matching impedance 6 (capacitor,
(It can be either a reactor or a resistor).

Both terminals 7 of each matching impedance 6
are led out from inside the case 1 and fixed to terminal boxes 8 provided individually outside the case 1.

In the illustrated embodiment, this matching impedance 6
The ground side terminals of both terminals are at the same potential, so they are connected together and serve as a common terminal.

By the way, the metal electrode 5 forming the capacitor structure with the internal conductor 3 may be a ring metal tube surrounding the bushing 2 as in the embodiment shown in FIGS. As in the embodiment, a metal layer may be formed directly on the outer peripheral surface of the bushing 2 by metallization or vapor deposition.

In any case, the metal electrode 5 disposed on the outer periphery of the bushing 2 is located inside the case 1 so that no discharge occurs between it and the internal conductor 3 that protrudes from the bushing 2 and is exposed inside the case 1. It is preferable to place the case 1 sufficiently away from the tip of the bushing 2, or to make the side wall of the case 1 have a double structure and to position it between both wall plates of the side wall of the case 1, which has a double structure.

Since the present invention has the above structure, the capacitor capacity of the capacitor structure formed by the internal conductor 3 and the metal electrode 5 is set as [C ₁ ] (commercial frequency impedance is Z ₁ ), If the commercial frequency impedance of matching impedance 6 is Z ₀ , the impedance of this capacitor capacitance C ₁ is
The ground voltage of the high-voltage distribution line is divided by Z ₁ and Z ₀ of the matching impedance 6, and a voltage proportional to the voltage on the high voltage side is obtained between both terminals 7 of the matching impedance 6.

Therefore, by connecting a voltmeter between the terminals 7, 7 fixed to the terminal box 8, it is possible to detect and measure the voltage proportional to the ground voltage of each distribution line.

In this way, the present invention can easily detect the ground voltage of the distribution line using a large number of high-voltage switches installed in the middle of the high-voltage underground distribution line. The detection work becomes extremely easy, which makes maintenance management of high-voltage underground distribution lines easier.

In addition, the high voltage switch according to the present invention has a simple structure since it only uses the bushings 2 to add a capacitor structure, and is therefore easy to manufacture and can be easily attached to an existing high voltage switch. can be implemented.

Furthermore, matching impedance 6 is made of iron case 1
Since the metal electrode 5 is installed in the case 1, the voltage between the metal electrode 5 and the ground is stabilized, and since the metal electrode 5 is grounded through the low impedance matching impedance 6, the influence of noise is small. Because the matching impedance 6 is installed inside the case, there is no oscillation device at the installation location, and less noise is picked up.Furthermore, since the metal electrode 5 is grounded through a low resistance that is the matching impedance 6, the case Even if noise enters the conductor other than 1, this noise is attenuated at the low resistance point, which is the matching impedance 6, and its influence can be significantly suppressed.

As is clear from the above explanation, the high voltage switch according to the present invention can easily and accurately detect the ground voltage of each phase in the middle of a high voltage underground distribution line, and has an extremely simple structure. Therefore, it is easy to manufacture and has many excellent effects such as being able to easily improve existing switches.

[Brief explanation of the drawing]

FIG. 1 is a partially cutaway view showing the basic structure of a high voltage switch according to the present invention. FIG. 2 is a sectional view of a main part taken along the line A--A in FIG. 1. FIG. 3 is an enlarged sectional view of a main part showing another example of configuring a metal electrode. Explanation of symbols, 1... Case, 2... Bushing, 3... Internal conductor, 4... Rotating conductor, 5... Metal electrode, 6... Matching impedance, 7... Terminal, 8... Terminal box.

Claims (1)

[Scope of utility model registration request] Among the bushings 2 fixed to the iron case 1 with the internal conductor 3 fixed therethrough, a peripheral surface of each bushing 2 facing the power transmission system side faces the internal conductor 3 via the bushing 2. The metal electrodes 5 are respectively arranged in a posture, each of the metal electrodes 5 is grounded via a matching impedance 6 installed inside the case 1, and both terminals 7 of each of the matching impedances 6 are connected to a ground outside the case 1. A high voltage switch that is led out and fixed to the terminal box 8.