KR830001729Y1 - Switchgear - Google Patents

Abstract

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Description

Switchgear

1 is a cross-sectional view showing the opening and closing state of a conventional switchgear.

Figure 2 is a cross-sectional view showing an embodiment of a state of opening of the opening and closing device according to the present invention.

The present invention relates to a switchgear, and in particular, self-protection to extinguish the arc by arranging the fluid in the switchgear by the arc generated at the time of opening and closing the contactor, and by spraying the high-pressure fluid on the arc. It relates to a type opening and closing device.

1 is a cross-sectional view showing an open state of a conventional switchgear. In FIG. 1, when the movable contactor 9 is in contact with the inside of the fixed contactor 3 as shown by the dotted line, and the switchgear is closed, the electric current flows from the conducting wire 2 to the terminal plate. 1) → fixed contactor 3 → movable contactor 9 → finger contactor 14 → terminal plate 11 → lead 13 are supplied to a load (not shown). When an overcurrent such as a short circuit current flows through the load, the movable contactor 9 is driven downward in FIG. 1 by an opening / closing mechanism (not shown), and the movable contactor 9 opens to the fixed contactor. At this time, arc A is generated between the movable contact 9 and the fixed contact 3. As a result of the arc A, the fluid in the heat-resistant insulating container 4 becomes high temperature and high pressure, and instantaneously opens the hollow portion of the ordinary fixed contactor 3 and the normal movable contactor 9. The pressure of the extinguishing fluid in the pressure type 15 is increased through the nozzle hole 8 at the same time. Since there is a natural zero in the alternating current, the arc current decreases as the current to be blocked approaches zero, and the hollow portion of the fixed contact 3 and the movable contact 9 is released. For this reason, the fluid in the heat resistant insulating container 4 becomes low temperature and low pressure. Therefore, the high-pressure extinguishing fluid in the pressure chamber 15 is blown into the arc A through the nozzle hole 8. Arc A on which the arc extinguishing fluid is pumped is cooled and extinguished at the zero point of the arc current. During the arc generation period and after arc arc extinguishing, a fluid which is not effective for arc arc extinguishing, such as high temperature fluid around arc A or conductive particles evaporated from the fixed contactor 3 and movable contactor 9, etc. Is discharged to the outside in the heat-resistant insulating container 4 through the hollow portions of the fixed contactor 3 and the movable contactor 9, and facilitates arc extinguishing.

However, in the conventional switching device, when the breaking current is small, the pressure of the extinguishing fluid in the pressure chamber 15 does not sufficiently increase. For this reason, the fresh extinguishing fluid necessary for arc arc arcing was not able to be fully sprayed on arc arc arc. In addition, in order to secure the arc extinguishing fluid required to arc arc A when the breaking current is large, the volume of the pressure chamber 15 is increased to increase the volume of the arc extinguishing fluid in the pressure chamber 15 when the breaking current is small. There was a drawback that the pressure did not rise, and both of them were incompatible with the case where the breaking current was small.

In order to improve such a conventional fault, the case where a puffer device which consists of a piston and a cylinder is used together with the conventional switchgear shown in FIG. 1 can be considered. In this case, a large volume cylinder is required when the breaking current is large, and a small volume cylinder is required when the breaking current is small. Therefore, cylinders and pistons with different shapes are required as the number of rated breaking currents of the switchgear, and if the problem is large in inventory control, quality control, and manufacturing cost, and the cutoff current is large, the cylinder becomes larger. There was also a flaw in the shape.

The present invention has been made to ameliorate the drawbacks of the prior art. Next, an embodiment of the present invention will be described based on the drawings.

2 is a cross-sectional view showing an embodiment of a state of opening of the opening and closing device according to the present invention. Corresponding reference numerals are attached to parts corresponding to FIG. 1 in the drawing. In FIG. 2, the conductor 2 is connected to the terminal plate 1, and supports one end of the normal fixed contactor 3. As shown in FIG. The outer circumference of the other end of the fixed contact 3 is slidably attached to the inner circumference of the opening of one end of the heat resistant insulating container 4. The inner partition 6 is attached to the cylinder 5, and constitutes an exhaust passage 7 which communicates the inside of the heat resistant insulating container 4 with the outside of the opening and closing device. The nozzle hole 8 communicates the interior of the cylinder 5 with the interior of the heat resistant insulating container 4. The movable contact 9 is in contact with the outer circumferential surface formed in the tubular state by being fitted into the inner circumferential surface of the fixed contact 3, and is attached to the cylinder 5 so that the hollow portion communicates with the exhaust passage 7. The piston 10 is provided in the interior of the cylinder 5, and is slidably attached to the side wall of the interior of the cylinder 5 and the outer peripheral surface of the inner partition 6. The terminal plate 11 is attached to the piston 10 and is slidably attached to the inner partition 6 via the sliding contact 12. The conductive wire 13 is connected to the terminal plate 11. The communication hole 14 communicates the exhaust path 7 with the outside air.

Next, this operation will be described. If the movable contactor 9 is inserted into the fixed contactor 3 as shown by the dotted line, and the switchgear is closed, the current is conducted from the conducting wire 2 → the terminal plate 1 → the fixed contactor 3 → the movable contactor. (9) is supplied to the load (not shown) via the inner partition 6, the sliding contact 12, the terminal plate 11, and the lead 13. When an overcurrent such as a short circuit current flows through the load, the movable contactor 9 is driven downward through the inner partition 6 by the opening / closing mechanism (not shown), and the movable contactor 9 is a fixed contactor ( In 3). Arc A occurs when the movable contactor 9 opens from the fixed contactor 3, but in this case, the cylinder 5 and the heat-resistant insulating container 4 also move downward together with the movable contactor 9. For this reason, the arc extinguishing fluid in the cylinder 5 is compressed by the piston 10, and the pressure rises, it is blown into the arc A through the nozzle hole 8, and when the arc current is a small current, it is blown out by the atmosphere. Acquire Arc A sufficiently. Next, when the arc current is a large current, the pressure of the fluid in the heat-resistant insulating container 4 increases due to the arc energy, thereby temporarily closing the hollow portions of the fixed contactor 3 and the movable contactor 9, and at the same time, the nozzle hole. Through 8, the arc extinguishing fluid of the cylinder 5 is boosted. Therefore, the arc extinguishing fluid in the room of the cylinder 5 becomes high pressure by the action of arc energy and the piston 10. In this state, as the current to be cut off approaches zero, the arc current decreases, and the blockage of the hollow portions of the fixed contact 3 and the movable contact 9 is released. For this reason, the fluid in the heat resistant insulating container 4 becomes low temperature and low pressure. Therefore, the high pressure arc extinguishing fluid in the interior of the cylinder 5 is blown into the arc A through the nozzle hole 8. Arc A on which the arc extinguishing fluid is pumped is cooled and extinguished at the zero point of the arc current. During the arc generation period and after arc arcing, fluids that are not effective for arc arc arcing, such as high temperature fluids around arc A, conductive particles evaporated from the stationary contactor 3 and movable contactor 9, are fixed contactors ( 3) and a part of the switchgear in the heat-resistant insulating container 4 through the hollow part of the movable contactor 9, and effectively extinguish arc A. In addition, in response to the magnitude of the target breaking current, the bottom portion of the piston 10 is changed from the solid line position to the position indicated by L ₁ , L ₂ L ₃ . I) and changing the depth by the specification object, thereby changing the volume of the interior of the cylinder 5 without changing the shape of the cylinder 5, and increasing the pressure in the interior of the cylinder 5; You can effectively extinguish arc A by adjusting. Moreover, since the piston 10 is used as a recess, the cylinder 5 can be made small. In addition, the arc A is formed by the arc-extinguishing fluid from the nozzle holes 8 shown by arrows a and b in FIG. 2, that is, the hollow portion of the fixed contact 3 and the movable contact 9 by the directions shown by arrows c and d. Since it is divided into two directions with a hollow part, it can extinguish more effectively.

As the anti-corrosive fluid, an insulating gas such as SF ₆ and a fluid such as insulating oil are used.

As described above, according to the present invention, only by changing the shape of the piston without changing the shape of the cylinder, it is possible to effectively cut off in response to the change of the breaking current, and also has an excellent effect in inventory control, quality control and production cost.

Claims (1)

A normal fixed contactor 3 connected to the conductor 2, a heat-resistant insulating container 4 in which an opening at one end is slidably attached to an outer circumference of one end of the fixed contactor 3, and the heat-resistant insulating container A cylinder (5) attached to the heat resistant insulating container (4) so as to seal the opening of the other end of (4), an exhaust passage attached to the cylinder (5) to communicate the inside and the outside of the heat resistant insulating container (4); (7) the inner partition wall (6), the nozzle hole (8) which communicates with the interior of the cylinder (5) and the heat-resistant insulating container (4), and is installed in the interior of the cylinder (5) and the side wall of the room And a piston-shaped piston 10 slidably attached to an outer circumferential surface of the inner partition 6, a conductor 2 connected to the piston 10 and the cylinder 5, and the exhaust passage It has a hollow part communicating with (7), and it is provided with the normal movable contactor 9 which contacts the said fixed contactor 3, The opening-closing characterized by the above-mentioned. Device.