KR830001777Y1 - Tank Type Zinc Oxide Lightning Arrester - Google Patents

Abstract

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Description

Tank Type Zinc Oxide Lightning Arrester

1 is a partial cross-sectional view of a tank-type zinc oxide arrester according to an embodiment of the present invention.

2 is a characteristic diagram showing the potential distribution of FIG.

3 is a longitudinal sectional front view of a tank type zinc oxide lightning arrester according to another embodiment of the present invention.

4 is a perspective view of a tank zinc oxide lightning arrester according to another embodiment of the present invention.

5 is a characteristic diagram showing the potential distribution of FIG.

6 to 10 are longitudinal sectional front views showing the outline of a tank type zinc oxide lightning arrester according to another embodiment of the present invention, which is different from each other.

The present invention relates to a tank-type zinc oxide lightning arrester having no direct gap, in which a non-linear resistor composed mainly of zinc oxide is superposed in the tank.

The general arrester used SiC as an afferester element. However, these days, zinc oxide has a main component, and a small amount of Bi ₂ O ₃ , CoO, MnO, Sb ₂ O _3, etc. is added thereto, mixed, and formed into a predetermined shape to be regenerated at a high temperature of 1000 ° C. or higher. In addition, a lightning arrestor element excellent in nonlinearity has been developed. This has led to the development of so-called gap less surge arresters that do not require direct thermal gaps.

The gapless lightning arrester stacks a plurality of arrester elements in a tank with a ground potential filled with SF ₆ gas, connects one of the arrester elements to the main circuit conductor, and connects the other end to the ground potential. have. Although the dielectric constant of the nonlinear resistor is less than 1000 to 2000, it is influenced by the tank, so the voltage sharing on each of the arrester elements is not equalized, and a higher voltage is applied to the arrester elements on the main circuit conductor side.

In other words, this is because of the influence of stray capacity between each arrester element and the tank. In this way, if the potential distribution is uneven, the devices with a large voltage share are deteriorated.

An object of the present invention is to provide a ground tank type zinc oxide lightning arrester in order to more uniformly share the constant voltage applied to each of the arrester elements.

Another object of the present invention is to provide a ground tank type zinc oxide arrester having a control device capable of simply controlling the potential distribution.

The present invention provides two or more annular shielding means, for example, a shield ring, spaced at a predetermined distance from the main circuit diagram of the arrester elements, and by this means, the voltage sharing of each of the arrester elements is made more uniform. It is.

The distance between the two annular shield means allows at least one equipotential surface to reach the arrester elements through the bicyclic shield. The annular shielding means can be configured in various ways such as shape, number and diameter.

FIG. 1 shows a partial cross-sectional view of the tank type arrester, and the ground tank 2 encapsulating a medium excellent in insulation such as gas is closed by the insulating spacer 3 to block the opening on the connection side. Inside the grounding tank 2, it is arrange | positioned as the nonlinear resistance group 1 which is a characteristic element which fixed one end to the grounding tank 2, and the other end of this nonlinear resistance group 1 is connected to the high voltage conductor 4. As shown in FIG. . At both ends of the non-linear resistance group 1 in the axial direction, the connecting portions are surrounded by the electric field relaxation shield cylinders 27 and 28, respectively.

An umbrella type shielding device 26 is fixed to the high pressure side end of the non-linear resistance group 1, and a shield ring 20 as an annular member is integrally attached to the free end of the umbrella type shielding device 26. have. Umbrella-type shield device 26 is a container type having a side wall over its entire circumference, but may be composed of a plurality of shield rings arranged in close proximity as another example.

However, as shown in the same figure, it is made not to form a continuous equipotential surface in the equipotential surface of the nonlinear resistance group 1 through such a seal ring.

Between the axial ends of the nonlinear resistance group 1, two annular shields, for example, shield rings 21 and 22, which surround another outer circumference, are arranged so that the high-voltage conductor 4 is connected by the connecting conductors 30 and 31. At the same time, the door is held at the same potential as that of the high-pressure conductor 4 while being fixed to the side.

The characteristic points here are the opposing distance between the shield rings 20, 21 and 22 and the arrangement and shape of the connecting conductors 30 and 31. That is, as shown by the dotted line in the same diagram as the dotted line, the relationship between the above is selected so that the equipotential lines passing through the shield rings are continuous with the equipotential surfaces of the nonlinear resistance group 1. Therefore, it is arranged discretely at a predetermined distance between at least two shield rings provided between the axial ends of the nonlinear resistance group 1.

In addition, the connecting conductors 30 and 31 are constituted by the width and the number of the peripheral directions within a range satisfying the above conditions for forming the equipotential lines (part of the equipotential surface) between the shield rings, for example, rod-shaped conductors, It consists of a large plate-shaped conductor, a lead wire, etc. However, when the sealing rings 21 and 22 are not fixed when the sealing rings 21 and 22 are fixed by the connecting conductors 30 and 31, the connecting conductors 30 and 31 are mechanically supported at least as electrical connecting members. It can also be performed with a dielectric. The supporting and fixing of the shield rings 21 and 22 on the high voltage conductor 4 side is for adjusting the potential distribution along the axial direction of the nonlinear resistance group 1. In other words, when the shield rings 21 and 22 are set to substantially the same potential as the high-voltage conductor 4, the shield rings 22 are electrically and insulatedly strict.

However, since the seal ring 22 is fixed to the equipotential portion via the connecting conductor 31, no insulation support is required between the shielding tank 22 and the ground tank 2, which requires electrical insulation. Therefore, the shield ring 22 and the ground tank 2 can be accessed using the excellent dielectric strength of SF ₆ gas. This makes it possible to make the position of the seal ring 22 most desirable for adjusting the potential distribution of the nonlinear resistance group 1.

In order to weaken the surface electric field of the seal ring 22, the diameter, i.e., the width to be matched in the axial direction of the nonlinear resistance group 1 may be increased.

With such a configuration, the distribution of voltages applied to the resistors of the nonlinear resistor group 1 is almost uniform as apparent as the potential distribution shown by the points in FIG. This is also expected in the equipotential lines shown by the dashed lines in FIG.

The straight line 11 in FIG. 2 is a uniform distribution straight line, the potential distribution is expressed in% on the vertical axis, and the horizontal axis H shows the distance H at the ground potential side end of the nonlinear resistance group 1. The embodiment in FIG. 1 has several other features. The first characteristic is that the thickness of the shield rings 21 and 22 is larger than the thickness of the seal ring 20. This is advantageous for insulation in the shield ring 22 adjacent to the ground potential.

In particular, the seal ring 22 is adjacent to the ground potential side as one half of the axial length of the nonlinear resistance group 1, and according to its thickness, the electric field relaxation action and excellent insulation such as SF ₆ gas can be conveniently used. have. The second feature is that the diameter of the shield ring 20 is smaller than that of other shield rings. This is because the high pressure side of the nonlinear resistance group 1 is effective for improving the potential main body, and the large-diameter seal ring 22 is effective for improving the potential distribution of the ground potential axis of the nonlinear resistance group 1.

The third characteristic is that the distance between the first and second shield rings 20, 21 at the high voltage side is 2, 3 when the number of seal rings located between the axial ends of the nonlinear resistance group 1 is three or more. This is shorter than the distance between the three shield rings 21 and 22. It was confirmed by experiment that the potential distribution on the ground potential side of the nonlinear resistance group 1 can be satisfactorily established. The seal rings 20, 21, 22 shown as annular shields are actually shown in the cross section, but may be hollow or cross-section C-shaped, or may be elliptical. Alternatively, instead of the seal ring 20, a skirt-shaped annular seal which reverses the free short axis of the umbrella-type shield device 26 may be used. One such example is shown in FIG.

In the same figure, the normal shield 40 is provided surrounding the high pressure side of the nonlinear resistance group 1, and the lower end of the normal shield 40 is somewhat smaller than the high pressure side end of the nonlinear resistance group 1. It protrudes. The annular shields 41, 42, 43 having an almost C-shaped cross section surround the outer circumference of the nonlinear resistance group 1 at intervals of a predetermined distance. The normal shield 40 and the annular shields 41, 42, 43 are spaced apart from each other by a distance that forms an equipotential surface that reaches the equipotential surface of the nonlinear resistance group 1 therebetween. Each shield 40, 41, 42, 43 is joined by a rod-shaped connecting conductor 44. The normal shield 40 is attached to the high pressure conductor 4 or the connection part 45. The high voltage conductor 4 is electrically connected to the connecting portion 45 via the conductor.

Such a normal shield 40 also serves as an umbrella-shaped shield device 26, a seal ring 20, and a shield cylinder 27 in FIG. The potential distribution in the axial direction of the nonlinear resistance group 1 can be improved almost as in the case of FIG.

When a plurality of seal rings or annular shields are provided between the high voltage side end surface and the ground side end of the nonlinear resistance group 1, the lower ends of the seal ring 20 of FIG. 1 and the normal shield of FIG. It may be located on the high voltage conductor 4 side rather than the high voltage side cross section of the resistance group 1.

4 shows a schematic of a lightning arrester of a tank according to another embodiment. The point of having a non-linear resistance group 1 having one end connected to the high voltage conductor 4 in the ground tank 2 sealed with the insulating medium and the other end at the same ground potential as the ground tank 2 is the same as that in FIG. .

However, the present embodiment differs from the example of FIG. 1 in that the potential distribution is controlled by providing three shield rings 20, 21, and 22 of substantially the same diameter on the outer circumference of the nonlinear resistance group 1. The shield rings 20, 21, 22 are held at a predetermined distance in the axial direction of the nonlinear resistance group 1, respectively, and are formed at substantially the same potential as the high-voltage conductor 4 (not shown).

It was confirmed that the dislocation distribution in the above configuration was very close to the uniform distribution line 11 as in the dislocation distribution curve 23 shown in FIG. 5, and the nonuniformity coefficient (uniformity was 1.0) was about 1.1 or less. .

On the other hand, it was confirmed that the potential distribution in the case of forming one cylinder with each shield ring integrally is as shown in the curve 24 of FIG. 5, and the voltage sharing of the nonlinear resistor in the axial middle portion is strict. The connecting conductor 30 of FIG. 4 can be an impedance device such as a capacitor or a resistor. At this time, the shield rings 21 and 22 have a potential different from that of the shield ring 20, and are effective for the delicate adjustment of the equipotential surface. The characteristic when using the impedance device is almost the same as in FIG. In any case, the shield ring 22 located at the highest ground potential side end does not have a connection relationship with the intermediate potential of the nonlinear resistance group 1, and thus the state is mainly used for improving the potential distribution by effectively utilizing the insulation distance of the SF ₆ gas. You can place it in a good location.

6 to 10 show different examples, respectively, and almost the same effects as in FIG. 4 are obtained. In addition, the support apparatus of each shield ring is abbreviate | omitted. 6 shows the metal base 25 extending in the same axial direction at the ground potential side end of the non-linear resistance group 1, and expands the width of the potential distribution adjustment jointly with the shield rings 20, 21, 22 and grounds. The potential distribution at the distal side end portion can be improved. 7 shows two seal rings.

In this example, the effect of dislocation uniformity decreases as compared with the example of FIG. 4, but a more preferable dislocation distribution can be obtained compared to the curve 24 of FIG. 8 shows a vessel-type shield 26 between the uppermost seal ring 20 and the high pressure conductor 4, and the seal rings 20, 21, 22 are formed with substantially the same diameter. This kind of structure can achieve an effect almost equivalent to that of the example of FIG. 1 and can more preferably improve the potential distribution on the high-voltage conductor 4 side of the nonlinear resistance group 1. FIG. 9 sequentially increases the cross-sectional area of the shield ring as it approaches the ground potential side of the nonlinear resistance group 1. As shown in FIG.

According to this embodiment, the electric field at the tip of the shield ring 22 can be more relaxed, thereby arranging the shield ring 22 in the best position for improving the potential distribution on the ground potential side of the nonlinear resistance group 1. It is to be done.

FIG. 10 shows that the diameter of the shield ring is increased as the ground potential side of the nonlinear resistance group 1 is increased, and the nonlinear resistance group 1 is increased in comparison with the shield for improving the potential distribution of the nonlinear resistance group 1. The potential distribution on the high-voltage conductor 4 axis and the ground potential side of the () can be improved more preferably, and the potential distribution curve 24 of FIG. 5 can be brought closer to the uniform main curve 11.

The seal rings 20, 21, 22 in the above embodiments may be annular or may be divided into plural in the circumference if they are equivalent to the annular with respect to the electric field. In addition, the present invention can further improve dislocation distribution by adding an auxiliary shield in the vicinity of the annular shield represented by the seal ring.

As described above, the present invention arranges a plurality of annular shields surrounding the outer periphery between the two axial ends of the nonlinear resistance group 1 at a predetermined distance, and between the annular portions is non-cyclic. Since the annular shields were electrically connected by the connecting conductors, and the annular shields were made almost at the same potential as the high voltage conductors, an equipotential surface continuous with the equipotential surfaces of the nonlinear resistance group could be formed through the adjacent annular shields. The voltage sharing applied to each nonlinear resistor of the resistor group 1 can be made almost uniform. Furthermore, since the shield used for uniformity of the voltage sharing can be configured around the annular body, it is easy to manufacture and its structure is simple.

Claims (1)

A grounding tank (2) encapsulated with an insulating medium, a non-linear resistance group (1) disposed in the grounding tank (2), one end of which is connected to the high voltage conductor (4) and the other end of which is connected to the ground potential; A plurality of annular shielding means provided at both ends of the linear resistance group 1 and enclosing the nonlinear resistance group 1 in the ground tank 2, and the plurality of annular shielding means; A tank-type zinc oxide lightning arrestor having means for supporting and fixing on the high pressure side of 1).