JPH05342957A - Insulating nozzle for circuit breaker - Google Patents

Abstract

PURPOSE:To easily measure the spread degree of the aperture of an insulated nozzle throat section by forming at least part of the insulated nozzle throat section with a different material from the main constituting material of an insulated nozzle. CONSTITUTION:An insulated nozzle 1 is fixed on a moving side main contact 4 having a moving arc contact 4a at the center section. The arc 5 generated when a current is cut off between a fixed side contact 3a provided at the center section of a fixed side contact 3 brought into contact with the contact 4 and the moving side arc contact 4a penetrates an insulated nozzle throat section 2 containing a different material from the main constituting material of the nozzle 1. The arc-extinguishing gas extinguishing the arc 5 is filled in the space of a tank 7. A piston 9 is slidably coupled in a cylinder 8 kept in contact with the lower section of the contact 4, the piston 9 and the cylinder 8 are relatively moved when the current of a circuit breaker is cut off, and the arc-extinguishing gas in the cylinder 8 is sprayed to the throat section 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insulating nozzle arranged in the vicinity of an arc generating part for spraying an arc extinguishing gas against an arc generated between a movable arc contact and a fixed arc contact when a current is cut off. Is.

[0002]

2. Description of the Related Art FIG. 5 is a sectional view of a conventional gas circuit breaker arc extinguishing chamber using an insulating nozzle. In FIG. 5, the movable-side main contact 4 has a movable arc contactor 4a at the center thereof. The insulating nozzle 1 is mechanically fixed to the upper part of the movable-side main contact 4. The insulating nozzle 1 has, for example, boron nitride 0.3% to 1.% in order to improve the insulating performance.
It is made of fluororesin mixed with 0% inorganic material. The fixed side contact 3 which comes into contact with the movable side main contact 4 has a fixed side arc contactor 3a at the center thereof. Fixed side arc contactor 3a and movable side arc contactor 4a
The arc 5 generated at the time of interruption of the current passes through the insulating nozzle throat portion 2. 6 is SF for extinguishing arc 5.
₆ gas, and 7 is a tank for sealing SF ₆ gas. A cylinder 8 is integrally connected to a lower portion of the movable side main contact contact 4. Reference numeral 9 denotes a fixed piston that engages with the cylinder 8. The SF ₆ gas in the cylinder 8 is blown to the insulating nozzle throat portion 2 of the insulating nozzle 1 when the current of the circuit breaker is cut off. A valve 10 used for filling and collecting SF ₆ gas is provided on the side surface of the tank 7.

The operation of the gas breaker arc extinguishing chamber provided with the conventional insulating nozzle 1 will be described below. When the current is cut off in the circuit breaker, a high temperature plasma-like arc 5 is generated between the fixed arc contactor 3a and the movable arc contactor 4a. In order to extinguish the arc 5, SF ₆ gas in the cylinder 8 is blown from the insulating nozzle 1. Arc 5
In order to prevent the occurrence of voids (internal defects) or carbon inside the insulating nozzle 1 and thereby lowering the insulating performance of the insulating nozzle 1, as is well known, for example, in Japanese Examined Patent Publication No. 63-11921, 0.3% to 1.0% A fluororesin mixed with an inorganic substance such as boron nitride is used for the insulating nozzle 1. By mixing an inorganic substance such as boron nitride, the inner surface of the insulating nozzle 1 has good arc resistance, and the electric resistance performance after being cut off many times is improved. However, since the insulating nozzle 1 made of a fluororesin mixed with such an inorganic substance has a high arc energy ray absorption density on the surface of the insulating nozzle, the amount of wear of the insulating nozzle throat portion 2 which comes into direct contact with the arc becomes large. The expansion of the diameter of the insulating nozzle throat portion 2 lowers the pressure inside the cylinder 8 and lowers the blocking performance. Therefore, the service limit of the insulating nozzle made of a fluororesin mixed with an inorganic substance is mainly determined by the degree of expansion of the diameter of the insulating nozzle throat portion 2.

[0004]

Since the service limit of the insulating nozzle 1 mixed with an inorganic substance is determined by the degree of spread of the diameter of the insulating nozzle throat, the diameter of the insulating nozzle throat is regularly measured for the purpose of maintaining good blocking performance. There is a need to. However, in order to measure the caliber of the insulating nozzle throat, after performing a series of disassembly work such as blackout work, SF ₆ gas recovery, manhole cover opening and fixed contact contact removal, the insulating nozzle is taken out and the insulating nozzle throat is removed. I had to measure the diameter of the part, and it took a great deal of effort and time. For this reason, the circuit breaker cannot be inspected in a timely manner, such as when inspection is not possible when the power demand is high.Therefore, there is a problem that an accident may occur due to the use of a worn insulating nozzle. It was The present invention relates to an insulating nozzle capable of easily measuring the degree of spread of the diameter of an insulating nozzle throat portion without performing a series of disassembling operations by interrupting the breaker and a measuring method thereof.

[0005]

According to another aspect of the present invention, there is provided an insulating nozzle for a circuit breaker characterized in that a different substance different from a main constituent material of the insulating nozzle is present in at least a part of an insulating nozzle throat portion. To do. The circuit breaker insulating nozzle according to claim 2 is characterized in that the different substance is present in a portion deeper than a portion having a constant depth in a radial direction from a surface of the insulating nozzle throat portion. According to another aspect of the insulating nozzle for circuit breaker of the present invention, the different substance is made of an oxide, a nitride, or a mixture of both. The method for measuring the degree of wear of the diameter of the insulating nozzle throat in the insulating nozzle for circuit breaker according to claim 4, wherein at least a part of the insulating nozzle throat is configured such that a different substance different from the main constituent material of the insulating nozzle is present. The arc extinguishing gas is collected and the components of the different substance melted by the arc are analyzed, and the degree of wear of the insulating nozzle throat part is detected by the content of the different substance.

[0006]

Operation: The arc-extinguishing gas is recovered and the components of the different substances in the insulating nozzle throat that are melted by the arc are analyzed, and the degree of wear of the insulating nozzle throat is detected by the content of the different substances.

[0007]

1 is a sectional view of an arc extinguishing chamber of a gas circuit breaker using an insulating nozzle according to the present invention, and FIG. 2 is an AA of the insulating nozzle of FIG.
FIG. In FIG. 1, the movable-side main contact 4 is provided with a movable arc contactor 4a at the center thereof. The insulating nozzle 1 is mechanically fixed to the upper part of the movable-side main contact 4. The insulating nozzle 1 is made of a fluororesin mixed with an inorganic substance such as boron nitride 0.3% to 1.0% in order to improve the insulating performance. Movable side main contact 4
The fixed side contact 3 which comes into contact with the fixed side contact 3 has a fixed side arc contactor 3a at the center thereof. The arc 5 generated when the current is interrupted between the fixed side arc contactor 3a and the movable side arc contactor 4a penetrates the insulating nozzle throat portion 2. The space in the tank 7 to seal the SF ₆ gas SF ₆ gas for extinguishing the arc 5 is filled. A cylinder 8 is integrally connected to a lower portion of the movable side main contact contact 4.
A fixed piston 9 is slidably engaged in the cylinder 8, and SF ₆ gas in the cylinder 8 is insulated by the relative movement of the piston 9 and the cylinder 8 when the breaker current is cut off. It is sprayed onto the insulating nozzle throat portion 2 of the nozzle 1. A valve 10 used for filling and collecting SF ₆ gas is provided on the side surface of the tank 7.

At a part of the throat portion 2 of the insulating nozzle 1,
Oxide in the shape of a buried screw from the outside, eg
An oxide piece made of SiO ₂ is attached, and the insulating nozzle 1 having a thickness h is left between the oxide nozzle throat portion 2 and the inner surface of the insulating nozzle throat portion 2 as shown in the AA sectional view of FIG. A container containing a deoxidizer 13 for removing oxygen in the tank 7 before filling the SF ₆ gas is attached to the outside of the valve 10. SF outside the valve 10 and inside the tank 7
There is provided through the SF ₆ gas cylinder 15 each switching valve 16, 16 'for supplying the vacuum pump 14 and the SF ₆ gas 6 in the tank for evacuating the interior of the tank prior to filling the ₆ gas 6 .. The oxygen scavenger 13, the vacuum pump 14, the SF ₆ gas cylinder 15, and the switching valve 16 are necessary during SF ₆ gas charging work, and are disconnected from the tank by the valve 10 in a normal operating state.

Next, a method of measuring the degree of wear of the diameter of the insulating nozzle throat portion of the embodiment will be described with reference to FIG.
When the diameter of the insulating nozzle throat part 2 is consumed by the depth h or more due to the arc generated between the fixed side arc contactor 3a and the movable side arc contactor 4a when the current is cut off, a part of the insulating nozzle throat part 2 is formed. SiO ₂ is also irradiated with thermal energy by the arc. As a result, SiO ₂ is decomposed and oxygen gas O ₂ is generated inside the tank 7. Next, as shown in FIG. 4, a recovery container 17 is attached to the outside of the valve 10, the inside of the recovery container 17 is evacuated by a vacuum pump 14, and then a valve 16 between the vacuum pump 14 and the recovery container 17 is provided.
Close. After that, the valve 10 is opened and the arc extinguishing gas 6 inside the tank 7 is partially contained in the recovery container 17, and the valve 10 is closed.
The arc-extinguishing gas 6 contained in the recovery container 17 is analyzed by, for example, gas chromatography. Thereby the collection container 17
By knowing the amount of oxygen gas O ₂ inside, the degree of wear of the diameter of the insulating nozzle throat portion 2 can be grasped.

In the embodiment of the present invention, since boron nitride was mixed as the inorganic filler of the insulating nozzle, the example in which the oxide SiO ₂ was used as the different substance was shown, but another substance not containing nitrogen is used as the inorganic filler. When using Nitride as a heterogeneous substance, the nitrogen concentration is detected by gas analysis, and as the different substance, a nitrogen oxide (Nox) concentration is detected by a gas analysis. Good.

FIG. 3 shows the insulating nozzle throat portion of the second embodiment. In the embodiment of FIG. 1, when a certain depth h is consumed from a part of the surface of the insulating nozzle throat portion, a different material piece (eg oxide, nitriding) is used. However, in the embodiment shown in FIG. 3, foreign substance pieces are present on the entire surface of the insulating nozzle throat. In the case of this embodiment, since the oxygen concentration in the tank increases in proportion to the consumption of the surface of the nozzle throat after the start of operation, the consumption of the nozzle is measured by measuring this oxygen concentration.

[0012]

As described above, according to the present invention, at least a part of the throat portion of the insulating nozzle is provided with a different substance (for example, oxide, nitride, and a mixture of both) different from the main constituent material of the insulating nozzle. Configured to do. As a result, the degree of wear of the diameter of the insulating nozzle throat portion can be determined by gas analysis. Therefore, the degree of spread of the diameter of the insulating nozzle throat portion can be easily measured without performing a series of disassembling work for the circuit breaker.

[Brief description of drawings]

FIG. 1 is a gas circuit breaker using an insulating nozzle according to the present invention.

2 is a cross-sectional view taken along the line AA of the insulating nozzle of FIG.

FIG. 3 is another embodiment of the insulating nozzle according to the present invention.

FIG. 4 is a view of recovering arc extinguishing gas of the gas circuit breaker according to the present invention.

FIG. 5 is a gas circuit breaker using a conventional insulating nozzle.

[Explanation of symbols]

 1. Insulation nozzle 2. Insulated nozzle throat section 3a. Fixed arc contactor 4a. Movable arc contact 5. Ark 6. Arc extinguishing gas 11. Foreign substances h. depth

Claims (4)

[Claims] 1. An insulating nozzle for a circuit breaker for blowing an arc-extinguishing gas to extinguish an arc generated between a pair of arc contacts, wherein at least a part of an insulating nozzle throat is a main constituent material of the insulating nozzle. An insulating nozzle for a circuit breaker, characterized in that different different substances are present. 2. The insulating nozzle for a circuit breaker according to claim 1, wherein the different substance is present in a portion deeper than a portion having a constant depth in a radial direction from a surface of the insulating nozzle throat portion. .. 3. The insulated nozzle for a circuit breaker according to claim 1, wherein the different substance is an oxide, a nitride, or a mixture of both. 4. A component of the foreign substance, wherein at least a part of the insulating nozzle throat part is constituted so that a different substance different from the main constituent material of the insulating nozzle exists, and the arc extinguishing gas is recovered and melted by an arc. And a method for measuring the degree of wear of the insulating nozzle throat part in the insulating nozzle for a circuit breaker, which detects the degree of wear of the insulating nozzle throat part by analyzing the contents of the different substances.