JPH069029U - Gas disconnector - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a gas disconnector capable of improving the breaking performance without increasing the driving force and enlarging the driving means. [Structure] A fixed contact 1 and a movable contact 2 slidably provided on a movable shield 5 via an energizing contact 4 and provided so as to come in contact with and separate from the fixed contact 1 and interlockingly connected to a drive means. In the configured gas disconnecting switch, a portion of the movable contact 2 that contacts the current-carrying contact 4 when the arc is extinguished is formed by the Teflon tube 10.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a gas disconnector, which improves arc extinguishing performance without increasing the driving force.

[0002]

[Prior art]

 A gas disconnector that extinguishes the arc using insulating gas as the extinguishing medium is installed in the substation and switchyard. FIG. 5 (a) shows the structure of the conventional example 1 of the gas disconnecting switches, which is called parallel cutting. The figure shows the state in the middle of disconnection, but when connecting, the movable contact 2 is fitted into the fixed contact 1 which is biased by the ring-shaped coil spring 3, so that the current is fixed contact 1 → movable contact 2 → energized contact. 4 → Flows to the movable shield 5. The movable shield 5 is provided for the purpose of relaxing the electric field of the movable contact 2. A fixed shield 6 is provided for the purpose of relaxing the electric field of the fixed contact 1.

When the movable contact 2 is moved to the right from the connected state by the action of the driving means (not shown), an arc 7 is generated between the fixed contact 1 and the movable contact 2, and the contact between the two contacts is performed in the insulating gas. The arc 7 extinguishes due to the increase in the distance.

However, in the gas disconnecting switch having such a structure, the arc cannot be extinguished as the current capacity increases. Therefore, the gas disconnector of Conventional Example 2 shown in FIG. 5B is used. This forms a puffer chamber 8 between the partition wall 5a provided inside the movable shield 5 and the piston 2a formed on the movable contact 2 and connects the puffer chamber 8 and the outside of the movable shield 5 with a flow path 9 Are formed inside the movable contact 2.

In such a gas disconnecting switch, when the movable contact 2 moves to the right at the time of interruption, a negative pressure is generated in the buffer chamber 8 and a pressure difference is generated. Insulating gas flows through 9 into the puffer chamber 8 as indicated by an arrow, and the arc 7 is extinguished by being cooled by the insulating gas. Therefore, the breaking capacity is larger than that of the gas disconnector shown in Conventional Example 1.

[0006]

[Problems to be solved by the device]

 However, since the puffer chamber 8 has a negative pressure, a resistance force is generated against the driving of the movable contact 2, and a driving means having a force that overcomes the resistance force is required. Therefore, it is difficult to reduce the size of the driving means and the cost of the driving means also increases. In addition, since the breaking performance is determined by the volume of the puffer chamber 8, there is a limit to improving the breaking performance.

Therefore, an object of the present invention is to provide a gas disconnector which solves such problems.

[0008]

[Means for Solving the Problems]

 The structure of the present invention for achieving such an object is a fixed contact provided in a space filled with an insulating gas, and a movable side shield slidably provided through an energizing contact and In a gas disconnecting switch composed of a movable contact which is provided so as to be able to come into contact with and separate from the movable means and which is operatively connected to the drive means, a portion of the movable contact which comes into contact with the current-carrying contact when the arc is extinguished is formed of an insulating member. Or in addition to this, a magnet for generating a magnetic field in a direction perpendicular to the arc generated between the fixed contact and the movable contact and between the movable contact and the current-carrying contact is provided, or In addition to these, by providing a ring-shaped nozzle on the non-fixed contact side of the current contact, the nozzle and the current contact can be connected. It is obtained by forming a hot gas chamber between.

[0009]

[Action]

 According to the first aspect of the present invention, during the breaking operation, an arc is generated not only between the movable contact and the fixed contact but also between the movable contact and the energized contact, and the added arc length is about twice that of the conventional one. The cutoff distance can be reduced to about half of the conventional one.

According to the second aspect of the invention, in addition to the function of the first aspect of the invention, the magnetic field generated by the magnet diffuses and drives the two arcs to cool them, thereby further improving the breaking performance.

According to the third aspect of the invention, in addition to the effect of the first or second aspect of the invention, hot gas or the like generated by the arc is stored in the hot gas chamber and is blown to the arc when the arc current is near zero. To extinguish the arc. Therefore, the breaking performance is further improved.

[0012]

【Example】

 Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the drawings. Since the present embodiment is an improvement of a part of the conventional gas disconnector, the same parts as those of the prior art are designated by the same reference numerals, and the description thereof will be omitted. Only different parts will be described.

(A) First Embodiment FIG. 1 shows the configuration of a first embodiment of a gas disconnector according to the present invention. As shown in the figure, the small diameter portion 2a is formed by setting the outer diameter of the movable contact 2 small over a certain range, and the Teflon tube 10 as an insulating member is attached to the small diameter portion 2a so that the Teflon tube is attached. The outer diameter dimension of 10 and the outer diameter dimension of the movable contact 2 are set to the same value. The Teflon tube 10 is attached by, for example, a two-part structure.

The certain range in which the small diameter portion 2a is formed means the following range. In FIG. 1, it is desirable that the right end of the small diameter portion 2a is located at a position where the energizing contact 4 and the movable contact 2 start not to slide when the movable contact 2 starts to separate from the fixed contact 1. On the other hand, the left end of the small diameter portion 2a is set at a position where the distance between the energizing contact 4 and the outer peripheral surface of the movable contact 2 can be sufficiently maintained even when the arc is extinguished.

In such a gas disconnecting switch, the Teflon tube 10 does not come into contact with either the fixed contact 1 or the current-carrying contact 4 at the time of connection, and electric conduction between the fixed contact 1 and the current-carrying contact 4 is secured. When the movable contact 2 moves to the right, an arc 7 is generated between the fixed contact 1 and the movable contact 2 (distance L ₁ ) and between the movable contact 2 and the current-carrying contact 4 (distance L ₂ ). Therefore, when the distance between the fixed contact 1 and the movable contact 2 is separated by L ₁ , the length of the arc 7 becomes (L ₁ + L ₂ ). That is, by securing a small breaking distance L ₁ , it is possible to break a large capacity current having a breaking distance of (L ₁ + L ₂ ). Therefore, the blocking performance can be significantly improved by only providing the Teflon tube 10 without changing the stroke or drive speed of the movable contact 2. In addition, when the arc 7 generated between the energizing contact 4 and the movable contact 2 contacts the Teflon tube 10, a part of the surface of the Teflon tube 10 is melted to generate Teflon vapor, and the Teflon vapor cools the arc 7. Therefore, the blocking performance is improved also from this point.

(B) Embodiment 2 The configuration of Embodiment 2 of the gas disconnector is shown in FIG. Since this embodiment is a further improvement of the first embodiment, only parts different from the first embodiment will be described.

As shown in FIG. 2A, in this embodiment, a ring-shaped permanent member is sandwiched between the projecting portion 5 a protruding inward from the left end of the movable shield 5 and the energizing contact 4. The magnet 11 is fitted inside the shield 5. The permanent magnet 11 is arranged at this position because when the magnet is positioned substantially in the middle of the two arcs 7, the magnetic flux directly intersects with the arc current and both arcs 7 are easily diffused.

In such a gas disconnecting switch, since the magnetic field φ is generated due to the presence of the permanent magnet 11 as shown in FIG. 2A, the two arcs 7 generated during the interruption operation have Is magnetically driven and diffused. Therefore, the cooling effect of the arc 7 is enhanced and the breaking performance is improved.

In FIG. 2B, one permanent magnet 11 is added inside the movable shield 5 and is also provided inside the fixed shield 6 to provide a total of three permanent magnets 11. This is because the magnetic field in which the magnetic flux is orthogonal to each arc 7 is made stronger to improve the breaking capacity. Such a gas disconnecting switch has a larger blocking performance than the case where only one permanent magnet is used.

(C) Example 3 FIG. 3 shows the configuration of Example 3 of the gas disconnecting switch. Since this embodiment is also an improvement of the first embodiment, only parts different from the first embodiment will be described.

As shown in FIG. 3A, a nozzle 12 is fitted inside the movable shield 5 and on the right side of the energization contact 4. The nozzle 12 is formed of an insulating member in a substantially ring shape, and has a taper surface 12a whose inner diameter gradually increases from left to right in the drawing. With this nozzle 12, a hot gas chamber 13 is formed between the nozzle 12 and the energizing contact 4.

When an arc 7 is generated between the movable contact 2 and the fixed contact 1 and the current-carrying contact 4 as shown in FIG. 3A during the breaking operation, the insulating gas is heated by the arc 7 to generate hot gas. And the Teflon vapor generated when the arc 7 comes into contact with the Teflon tube 10 are stored in the hot gas chamber 13, and then a strong gas flow is generated near the zero point of the current as shown by the arrow in FIG. 3 (b). And extinguish arc 7. Fig. 4 shows the relationship between the arc current and the pressure in the hot gas chamber during interruption. It can be seen that the arc current causes the pressure in the thermal gas chamber to rise significantly. Thus, by providing the nozzle and forming the hot gas chamber, it is possible to greatly improve the breaking performance without changing the driving force of the movable contact.

Note that the third embodiment has the nozzle added to the first embodiment, but if the nozzle is added to the second embodiment, it has the effects of the second embodiment and the effects of the third embodiment. . The insulating member is not limited to Teflon.

[0024]

[Effect of device]

 As can be seen from the above description, according to the gas disconnecting switch of the first aspect, since the part of the movable contact that contacts the current-carrying contact when the arc is extinguished is formed of an insulating member, arcs are generated at two locations. Therefore, the current interruption performance can be improved without increasing the stroke of the movable contact. In addition, since the stroke of the movable contact may be small, the insulation performance between phases when the three phases are integrated is improved. Furthermore, the increase of the blocking capacity allows the blocking range to be expanded without providing the puffer chamber, and the increase of the driving force due to the provision of the puffer chamber is not required, and the driving means can be downsized and the cost can be reduced.

According to the gas disconnecting switch of the second aspect, since the magnet for generating the magnetic field whose magnetic flux is orthogonal to the arc is provided, in addition to the effect of the first aspect, the magnetic field drives the arc at the time of interruption. The arc cooling effect can be enhanced, and the breaking capacity can be further increased.

According to the gas disconnecting switch of the third aspect, since the hot gas chamber is formed by providing the nozzle, in addition to the effects of the first and second aspects, hot gas or the like is blown from the hot gas chamber to the arc. It is possible to further increase the breaking capacity by cooling.

[Brief description of drawings]

FIG. 1 is a sectional view showing a first embodiment of a gas disconnector according to the present invention.

2 relates to a second embodiment of the gas disconnecting switch according to the present invention, FIG. 2 (a) is a sectional view in the case of one permanent magnet, FIG. 2 (b)
Is a cross-sectional view in the case of three permanent magnets.

3A and 3B relate to Embodiment 3 of a gas disconnecting switch according to the present invention, FIG. 3A is a sectional view when an arc is generated, and FIG. 3B is a sectional view when an arc is extinguished.

FIG. 4 is a graph showing the relationship between the arc current and the pressure of the hot gas chamber according to the third embodiment of the gas disconnector according to the present invention.

FIG. 5 relates to a conventional gas disconnector, FIG. 5 (a) is a sectional view of Conventional Example 1, and FIG. 5 (b) is a sectional view of Conventional Example 2.

[Explanation of symbols]

 1 ... Fixed contact 2 ... Movable contact 4 ... Conductive contact 5 ... Movable side shield 7 ... Arc 10 ... Teflon tube 11 ... Permanent magnet 12 ... Nozzle 13 ... Hot gas chamber

Claims (3)

[Scope of utility model registration request] 1. A driving means, which is slidably provided on a movable shield via an energizing contact and is provided so as to be contactable with and separable from the fixed contact, and a fixed contact provided in a space filled with an insulating gas. A gas disconnector comprising a movable contact connected in an interlocking manner, wherein a portion of the movable contact that comes into contact with the current-carrying contact when the arc is extinguished is formed of an insulating member. 2. The gas disconnector according to claim 1, further comprising a magnet for generating a magnetic field in a direction perpendicular to an arc generated between the fixed contact and the movable contact and between the movable contact and the current-carrying contact. 3. The gas disconnector according to claim 1, wherein a hot gas chamber is formed between the nozzle and the current contact by providing a ring-shaped nozzle on the side opposite to the fixed contact of the current contact.