PARTIAL DISCHARGE SENSOR

With regard to a top loaded monopole antenna consisting of a disk 5 and a metal post 6, a partial discharge sensor includes a short-circuit conductor 10 joining the metal post 6 to a covering 7 and a coaxial line composed of a hole 8 and a metal terminal 9. This makes it possible to implement a partial discharge sensor that can suppress the induction of high voltage in the disk 5 and can achieve high sensitivity in a frequency band of a partial discharge to be detected.

TECHNICAL FIELD

The present invention relates to a partial discharge sensor for detecting a partial discharge phenomenon that occurs in a metallic casing of an electric power device such as a gas insulated switching device and a vacuum breaker.

BACKGROUND ART

For example, a gas insulated switching device is an electric power device that supports a high voltage conductor (electric wire) in an insulated state in the metallic casing that hermetically seals an insulating gas.

Although the electric field distribution in the metallic casing is designed so as to form a uniform electric field, if a defect (such as a foreign substance and a needle-like projection) forming a nonuniform electric field is mixed, a partial discharge may occur from a part of the defect as its origin.

If the partial discharge is left as it is, it may bring about dielectric breakdown that can lead to an accident. Accordingly, it is important to detect an early state of the partial discharge to prevent the dielectric breakdown.

In addition, as for a vacuum breaker utilizing the high insulation in a vacuum state, if the degree of vacuum lowers, a partial discharge may occur because of the degradation of the insulation performance. In this case also, if the partial discharge is left as it is, since the dielectric breakdown may occur, it is important to detect the partial discharge early.

Thus, a partial discharge sensor is required which detects the partial discharge to ensure the safety of an electric power device.

As a partial discharge sensor, there is one that detects the partial discharge by receiving high-frequency waves generated by the partial discharge with the antenna provided in its metallic casing.

For example, the following Patent Document 1 discloses a partial discharge sensor that can adjust the spacing between the disk of a top loaded monopole antenna installed in a cylindrical branch pipe and the inside diameter of the branch pipe, thereby being able to be set up even when the inside diameter of the branch pipe is small.

Incidentally, since a high voltage conductor is disposed in the metallic casing, stray capacitance is formed across the high voltage conductor and the disk of the top loaded antenna. Accordingly, if the disk of the top loaded antenna is insulated from the metallic casing, a high voltage is induced in the disk of the top loaded antenna.

Since the induced high voltage can have an adverse effect on a measuring instrument of the partial discharge sensor, it is desirable for the partial discharge sensor installed in the metallic casing that the disk and the metallic casing are conductive at the low frequency used for the high voltage conductor.

In the foregoing Patent Document 1, the round column of the top loaded antenna and the covering of the branch pipe are joined through a short stub with an electrical length of one quarter of the wavelength corresponding to the specific frequency of the frequency band of the partial discharge to be detected.

PRIOR ART DOCUMENT

Patent Document

DISCLOSURE OF THE INVENTION

Problems to be Solved by the Invention

Since the conventional partial discharge sensor is arranged as described above, the frequency of the high-frequency wave signal emitted from the partial discharge because of the reduction in the degree of vacuum in a vacuum breaker, for example, is 200-300 MHz, and the short stub with the electrical length of one quarter of the wavelength corresponding to the frequency has a length of 375 mm at most. Accordingly, when the inside diameter of the branch pipe is small, it cannot contain the short stub, which offers a problem of making it difficult to eliminate the adverse effect of the high voltage induced in the disk of the top loaded antenna.

The present invention is implemented to solve the foregoing problems. Therefore it is an object of the present invention to provide a partial discharge sensor capable of eliminating the adverse effect of the high voltage induced in the disk of the top loaded antenna even if the frequency band of the partial discharge to be detected is low.

Means for Solving the Problem

A partial discharge sensor in accordance with the present invention comprises: a cylindrical metallic casing; a cylindrical branch pipe having its first end joined to an opening of the metallic casing; a covering metallic conductor covering a second end of the branch pipe; a flat metallic conductor disposed in the opening of the metallic casing in a manner that the flat metallic conductor is on the same level with an internal surface of the metallic casing without making contact with the metallic casing; a metal post disposed inside the branch pipe in a manner that the metal post has its first end joined to the flat metallic conductor; a metal terminal having its first end joined to a second end of the metal post, and having its second end exposed to the outside through a hole provided at the center of the covering metallic conductor; and a short-circuit conductor having its first end joined to the metal post, and its second end joined to the covering metallic conductor, wherein the length of the short-circuit conductor is less than one quarter of the wavelength corresponding to the frequency of a partial discharge to be detected.

Advantages of the Invention

According to the present invention, even if the frequency band of the partial discharge to be detected is low, it offers an advantage of being able to eliminate the adverse effect of the high voltage induced in the disk of the top loaded antenna.

BEST MODE FOR CARRYING OUT THE INVENTION

The best mode for carrying out the invention will now be described with reference to the accompanying drawings.

FIG. 1is a cross-sectional view showing a partial discharge sensor of an embodiment 1 in accordance with the present invention; andFIG. 2is a top view seen from the arrow A ofFIG. 1.

InFIG. 1andFIG. 2, a metallic casing1is a metallic structure constructed in such a manner as to form a cylindrical closed space2in its inside, which corresponds to a main tank of a gas insulated switching device.

The closed space2is filled with an insulating gas, and a high voltage electric wire (not shown) is disposed. In addition, the surface of the metallic casing1is placed at the ground potential.

An opening3is a hole formed in the metallic casing1. AlthoughFIG. 2shows an example in which the hole is circular, the shape of the opening3is not limited to a circle, but can be selected freely such as a rectangle. However, to prevent the sensitivity of the partial discharge sensor from having angular characteristics, it is desirable to select an axially symmetric shape.

A branch pipe4is made of a metallic cylinder, and its inner wall section has the same shape as the opening3of the metallic casing1. The branch pipe4has its first end joined to the opening3of the metallic casing1.

A disk5is a flat metallic conductor disposed in the opening3of the metallic casing1without making contact with the metallic casing1. A surface of the disk5(the upper surface inFIG. 1) is approximately aligned with the plane of the opening3.

A metal post6is a conductor which is disposed inside the branch pipe4and is joined to a second surface of the disk5. It supports the disk5in such a manner that the disk5does not make direct contact with the metallic casing1or a covering7. AlthoughFIG. 2shows an example in which the metal post6is a round column, it is not limited to the round column, but can be a square column.

Incidentally, the disk5and the metal post6constitute the top loaded monopole antenna.

The covering7, which is a covering metallic conductor that covers the second end of the branch pipe4, is electrically connected to the metallic casing1via the branch pipe4. Accordingly, the surface of the branch pipe4and covering7are also placed at the ground potential.

A hole8is provided approximately at the center of the covering7.

The shape of a section perpendicular to the axis of the hole8is a circle, for example. However, as will be described later, as for the coaxial line comprised of the hole8and a metal terminal9, it is enough that the coaxial line is built so as to become a prescribed low impedance line (constructed so that the characteristic impedance of the coaxial line is lower than the characteristic impedance of a transmission line to be connected to a second end of the metal terminal9), and any shape can be selected as its form.

The metal terminal9, which is a rod-like conductor, is disposed in such a manner that the central axis of the metal terminal9is approximately aligned with the central axis of the hole8, and is passed through the hole8of the covering7.

The metal terminal9has its first end joined to the metal post6, and has its second end exposed to the outside.

A short-circuit conductor10is a conductor that has its first end joined to the metal post6, and its second end joined to the covering7.

Next, the operation will be described.

The gas insulated switching device is a switchgear that switches on or off a high-voltage power line (not shown) mounted in the metallic casing1. At this time, a partial discharge can sometimes occur in the metallic casing1owing to some reasons.

As the reasons, the following cases are conceived.

(1) A partial discharge occurs owing to a local high electric field because of an alien substances mixed into the metallic casing1.

(2) In the case of a vacuum breaker, although the switchgear is mounted in the vacuum container to insulate between the terminals of the switchgear, when the degree of vacuum in the vacuum container lowers, the insulation performance reduces, thereby bringing about a partial discharge.

If a partial discharge occurs, a discharge source of the partial discharge emits high-frequency waves.

In the present embodiment 1, the top loaded monopole antenna comprised of the disk5and the metal post6receives the high-frequency waves emitted from the discharge source, and transmits the signal of the high-frequency waves (referred to as a “high-frequency wave signal” from now on) to the outside through the metal terminal9.

Detecting the high-frequency wave signal with an external measuring instrument makes it possible to detect that a partial discharge occurs inside the metallic casing1from the intensity and/or frequency of the high-frequency wave signal.

Although the frequency of the high-frequency waves emitted from the partial discharge varies depending on a location where the discharge occurs or the like, the high-frequency waves from a VHF band to a UHF band are mainly observed.

To obtain a high-frequency wave signal with a high signal level at the external measuring instrument, it is necessary to improve the sensitivity of the partial discharge sensor at a prescribed frequency.

The top loaded monopole antenna comprised of the disk5and the metal post6has high performance when the impedance makes series resonance at the prescribed frequency. Accordingly, the diameter of the disk5and the length of the metal post6should be designed in accordance with the inside diameter of the branch pipe4so that the impedance forms the series resonance at the prescribed frequency.

Here, to transmit the high-frequency wave signal to the external measuring instrument, the disk5, metal post6and metal terminal9must be insulated from the metallic casing1, branch pipe4and covering7which are placed at the ground potential.

On the other hand, since the high-voltage power line is disposed inside the metallic casing1, a high voltage is induced in the high-voltage power line and the disk5.

When the high voltage induced in the high-voltage power line and disk5is supplied to the external measuring instrument via the metal terminal9, there is a risk of causing damage of the measuring instrument.

Thus, in the present embodiment 1, the short-circuit conductor10connects the metal post6to the covering7so as to discharge the high voltage induced in the high-voltage power line and the disk5to the ground potential.

In addition, in the present embodiment 1, since the length of the short-circuit conductor10is set at a length shorter than one quarter of the wavelength corresponding to the specific frequency in the frequency band of the partial discharge to be detected, it operates as a parallel inductance for the high-frequency wave signal.

On the other hand, as for the current flowing through the high-voltage power line, since it has the commercial frequency of 50 Hz or 60 Hz, which is much lower than the frequency of the high-frequency waves emitted from the discharge source, the short-circuit conductor10can prevent the high voltage from occurring without short-circuiting the high-frequency wave signal.

The impedance characteristic of the top loaded monopole antenna comprised of the disk5and the metal post6will now be described in more detail.

FIG. 3is a cross-sectional view showing an enlargement of the hole8and its surroundings of the covering7.

Since the central axis of the metal terminal9is approximately aligned with the central axis of the hole8provided in the covering7, a coaxial line is formed which is comprised of the metal terminal9functioning as its internal conductor and of the hole8of the covering7functioning as its external conductor.

At this time, the characteristic impedance of the coaxial line is determined by a cross-sectional shape of the hole8and that of the metal terminal9of the covering7.

When the cross-sectional shape of the hole8and that of the metal terminal9of the covering7are circular, the characteristic impedance Z0of the coaxial line is proportional to log(D/d), where D is the diameter of the hole8and d is the diameter of the metal terminal9(where, D/d>1).

Here, when designing D/d at approximately one, the characteristic impedance Z0of the coaxial line has a low value. At this time, the coaxial line formed by the hole8and metal terminal9operates as a parallel capacitance.

Thus, inFIG. 3, the impedance seen looking into the top loaded monopole antenna comprised of the disk5and the metal post6from the position designated by the symbol B is equivalent to a circuit shown inFIG. 4.

InFIG. 4, Za is a series resonant circuit denoting the impedance characteristic of the top loaded monopole antenna itself comprised of the disk5and the metal post6, L is the inductance formed by the short-circuit conductor10, C is the capacitance of the coaxial line comprised of the hole8and the metal terminal9.

As shown inFIG. 4, connecting the parallel resonant circuit to the series resonant circuit makes it possible to broaden the band of the impedance. Utilizing the effect enables the partial discharge sensor of the present embodiment 1 to reduce a mismatch loss in the frequency band of the partial discharge to be detected, thereby being able to improve the sensitivity in average.

FIG. 5is a diagram showing a result of a simulation that calculates the received voltage characteristics of the top loaded monopole antenna comprised of the disk5and the metal post6.

InFIG. 5, a solid line shows the received voltage characteristics of the top loaded monopole antenna in the present embodiment 1. In addition, a broken line shows the received voltage characteristics of the top loaded monopole antenna without the short-circuit conductor10and the metal terminal9to make the effect of the present invention clearer.

It is found fromFIG. 5that the received voltage increases in the frequency band of the partial discharge to be detected in the present embodiment 1, thereby being able to implement a partial discharge sensor with a higher sensitivity.

As is clear from the above, according to the present embodiment 1, it is configured in such a manner that as for the top loaded monopole antenna comprised of the disk5and the metal post6, it comprises the short-circuit conductor10joining the metal post6and the covering7, and the coaxial line comprised of the hole8and the metal terminal9. Accordingly, it offers an advantage of being able to suppress the induction of the high voltage in the disk5, and thus to prevent an adverse effect on the measuring instrument, and to implement a partial discharge sensor with a higher sensitivity in the frequency band of the partial discharge to be detected.

In addition, according to the present embodiment 1, since the length of the short-circuit conductor10is made shorter than one quarter of the wavelength corresponding to the specific frequency in the frequency band of the partial discharge to be detected, even if the inside diameter of the branch pipe4is small compared with the wavelength, the short-circuit conductor10can be disposed, which enables constructing a small-sized partial discharge sensor.

FIG. 6is a cross-sectional view showing a partial discharge sensor of an embodiment 2 in accordance with the present invention. InFIG. 6, since the same reference numerals as those ofFIG. 1designate the same or like components, their description will be omitted.

A resin material11is a dielectric which is comprised of a hardening resin like an epoxy resin, for example, and is fixed to the covering7in a manner as to cover the hole at the center of the covering7through which the metal terminal9passes. For example, the resin material11is fixed to the covering7using screws or the like.

In the present embodiment 2, since the resin material11is fixed to the covering7in a manner as to cover the hole8of the covering7, it can maintain the closed space2in the metallic casing1, thereby being able to prevent the insulating gas in the closed space2from leaking to the outside. In addition, the resin material11can fix the metal terminal9in such a manner that the metal terminal9is isolated from the covering7.

Incidentally, although it is configured that the resin material11does not enter the hole8inFIG. 6, the resin material11can plug up the hole8as shown inFIG. 7.

In this case, it is enough to design the cross-sectional shape of the metal terminal9and the hole8by considering the relative dielectric constant of the resin material11.

When using the epoxy resin as the resin material11, the relative dielectric constant is about four. Accordingly, the characteristic impedance of the coaxial line comprised of the hole8and the metal terminal9reduces as compared with the case where the resin material11is not filled.

Since the impedance Z0of the coaxial line is set at a low value as described above in the embodiment 1, filling the resin material11does not cause any trouble.

FIG. 8is a cross-sectional view showing a partial discharge sensor of an embodiment 3 in accordance with the present invention. InFIG. 8, since the same reference numerals as those ofFIG. 1designate the same or like components, their description will be omitted.

A cylindrical metal component12has approximately at its center a hole13through which the metal terminal9is passed, and is disposed inside the branch pipe4in a manner that its bottom is electrically joined to the covering7.

In the present embodiment 3, the short-circuit conductor10is joined to the top of the metal component12so that the short-circuit conductor10is electrically connected to the covering7via the metal component12.

The present embodiment 3 differs from the foregoing embodiment 1 in that the metal component12is disposed inside the branch pipe4.

As described in the embodiment 1, the resonance frequency of the monopole antenna comprised of the disk5and the metal post6is adjustable by designing the diameter of the disk5and the length of the metal post6in accordance with the diameter of the branch pipe4.

However, when the length of the branch pipe4is longer than the length of the metal post6, the position of the disk5becomes lower than the opening3of the metallic casing1in the structure of the embodiment 1.

Here, when the inside diameter of the branch pipe4is less than about one half of the wavelength corresponding to the frequency at the lowest limit of the frequency band of the partial discharge to be detected, the inner part of the branch pipe4operates as a cutoff waveguide. Thus, the high-frequency waves generated from the discharge source reduce abruptly in the branch pipe4, thereby lowering the receiving sensitivity of the partial discharge sensor.

Since the present embodiment 3 is provided with the metal component12electrically connected to the covering7, it can elevate the position of the ground potential, and can adjust the position of the disk5to approximately the same level of the opening3even if the branch pipe4is long. Thus, it can prevent the reduction of the receiving sensitivity of the partial discharge sensor.

As for the diameter of the hole13provided at the center of the metal component12, although it can be equal to the diameter of the hole8, they can differ from each other as shown inFIG. 8.

As for the height of the metal component12, since it is determined from the length of the branch pipe4and the length of the metal post6, it cannot be used as a design parameter to optimize the impedance of the top loaded monopole antenna comprised of the disk5and the metal post6.

However, since it allows to select the characteristic impedance of the coaxial line comprised of the hole8and the metal terminal9and the characteristic impedance of the coaxial line comprised of the hole13and the metal terminal9independently, the degree of freedom of the design increases, which enables the design to broaden the band of the impedance of the antenna.

As is clear from the above, according to the present embodiment 3, it is configured in such a manner as to comprise the metal component12which is disposed inside the branch pipe4in a fashion that the metal component12has the hole13provided approximately at its center to pass through the metal terminal9and that its bottom is electrically joined to the covering7. Accordingly, even when the length of the branch pipe4is greater than the length of the metal post6, the present embodiment 3 offers an advantage of being able to provide a partial discharge sensor with high receiving sensitivity.

FIG. 9is a cross-sectional view showing a partial discharge sensor of an embodiment 4 in accordance with the present invention. InFIG. 9, since the same reference numerals as those ofFIG. 8designate the same or like components, their description will be omitted.

A short-circuit conductor14is a connecting conductor that has its first end joined to the metal component12at its top, and has its second end joined to the internal surface of the branch pipe4.

The present embodiment 4 differs from the foregoing embodiment 3 in that it comprises the short-circuit conductor14connecting the metal component12and the branch pipe4.

Since the metal component12has its bottom electrically joined to the covering7, the structure seen looking into the covering7from the top of the metal component12has a choke structure.

Accordingly, at the frequency at which the height of the metal component12becomes equal to (¼+n/2)λ (where λ is the wavelength and n is an integer equal to or greater than zero), the impedance seen looking into the covering7from the top of the metal component12takes a very high value which is infinite theoretically. As a result, the current across the metal component12and the metallic casing1is broken so that the sensitivity of the partial discharge sensor reduces greatly.

The present embodiment 4 is constructed so as to cause the current to low across the metal component12and the metallic casing1even at the above mentioned specific frequency by connecting the top of the metal component12or its neighborhood to the internal surface of the branch pipe4via the short-circuit conductor14. Accordingly, the present embodiment 4 can prevent the reduction of the sensitivity of the partial discharge sensor.

Incidentally, as for the form of the short-circuit conductor14, it is enough that it has a shape to electrically connect the top of the metal component12or its neighborhood to the internal surface of the branch pipe4, and a spring or a conductive gasket is usable.

Incidentally, it is to be understood that a free combination of the individual embodiments, variations of any components of the individual embodiments or removal of any components of the individual embodiments is possible within the scope of the present invention.

INDUSTRIAL APPLICABILITY

The present invention is applicable to a power device (such as a gas insulated switching device and a vacuum breaker) which must detect a partial discharge phenomenon that can occur inside the metallic casing.

DESCRIPTION OF REFERENCE SYMBOLS