JPH0517883U - Gas circuit breaker - Google Patents

Abstract

(57) [Abstract] [Purpose] To improve the arc extinguishing performance of a self-extinguishing type gas circuit breaker in the small current range. [Structure] A fixed arc contactor 106 is arranged in a pressure increasing chamber 103, and a piston 104 is fixed around a nozzle 101n provided in the pressure increasing chamber. A movable arc contact 111 that comes into contact with the fixed arc contact through the nozzle 101n is provided, and a cylinder 112 having an opening at one end facing the pressure chamber is attached to the movable arc contact. The position of the cylinder is determined so that the piston 104 fits into the cylinder 112 at a position before the position where the movable arc contactor enters the boost chamber. A check valve 117 that allows only the outflow of gas from the movable cylinder is provided on the other end side of the cylinder 112.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a self-extinguishing type gas circuit breaker.

[0002]

[Prior Art]

 The self-extinguishing type gas circuit breaker is a type of circuit breaker in which a pressure increasing chamber whose pressure is increased by arc energy is provided and the gas ejected from the pressure increasing chamber is blown to the arc to extinguish the arc. This type of circuit breaker provides excellent arc extinguishing performance when shutting off a large current, but when the breaking current is small, the pressure in the booster chamber becomes insufficient, so the arc extinguishing performance deteriorates.

Therefore, various types of gas circuit breakers have been proposed in which a self-extinguishing arc extinguishing mechanism and an arc extinguishing mechanism of another method are used together. Fig. 2 shows a self-extinguishing type gas circuit breaker that also uses an arc rotation type extinguishing mechanism. In the figure, 1 is a booster chamber structure made of a conductive material or an insulating material in a cylindrical shape. Reference numeral 2 denotes a main circuit conductive plate on the fixed contact side which is provided so as to hermetically close the opening of the booster chamber constituent member 1. The booster chamber constituent member 1 and the conductive plate 2 constitute a booster chamber 3. ing. A hole 1a is provided at the center of the pressurizing chamber constituent member 1, and a tapered portion 1b having a diameter gradually increasing toward the outside is provided around the hole 1a. The hole 1a and the taper portion 1b constitute a nozzle portion 1n for ejecting gas.

A fixed side element 5 including a fixed arc contactor and an arc drive coil is housed in the booster chamber 3. This fixed element includes a support base 6 fixed to the inner surface of the conductive plate 2, a tulip-shaped fixed arc contactor 7 supported by the support base 6, a support base 6 and a coil support cylinder 8 at one end. Is connected to the arc drive coil 9, and an annular arc traveling plate 10 connected to the other end of the arc driving coil 9. The arc traveling plate 10 includes the tip position of the fixed arc contactor 7 and the nozzle portion. Is arranged between the hole 1a and the position of the hole 1a.

A movable arc contact 11 is provided on the same axis as the fixed arc contact 7. The movable arc contactor is supported by a means (not shown) so as to be linearly movable, and is connected to the main circuit conductor on the movable contactor side through a collector contact. The movable arc contactor 11 is operated by an operating device (not shown), penetrates the nozzle portion 1n to enter the booster chamber 3 and contacts the fixed arc contactor 7 as shown, and the nozzle portion 1n. After that, the fixed arc contact 7 and the pressure boosting chamber 3 are displaced between the fixed arc contact 7 and the cut-off position where a predetermined insulation distance is maintained.

Each of the above parts is housed in a predetermined shutoff container, and SF ₆ gas is sealed in the shutoff container at a predetermined pressure.

In the above gas circuit breaker, when the movable arc contact 11 is separated from the fixed arc contact 7 and an arc is generated between both arc contacts and the arc contacts the arc traveling plate 10, the arc drive coil An arc current flows through the magnetic flux 9, and the magnetic flux generated from the arc drive coil is linked to the arc at right angles. As a result, the arc is driven to rotate at high speed along the arc traveling plate 10, and gas is relatively blown to the arc. Further, the energy of the arc causes the pressure of the gas in the pressurizing chamber 3 to rise rapidly. The movable arc contactor 11 is operated so as to be removed from the hole 1a of the nozzle portion immediately before reaching the zero point of the current. When the movable arc contactor 11 is disengaged from the hole of the nozzle portion 1n, the gas in the pressurizing chamber 3 is ejected and blown onto the arc. The arc is rapidly cooled and extinguished at the current zero point by the relative spraying of gas generated by rotation and the spraying of gas ejected from the booster chamber.

FIG. 3 shows a self-extinguishing type gas circuit breaker that also uses a suction puffer mechanism. In this example, a cylinder 13 is fixed to one surface of the main circuit conductive plate 12 to form a boosting chamber 14 between the cylinder and the conductive plate 12, and a support stand 15 is provided on the other surface of the conductive plate 12 via a supporting base 15. A fixed arc contact 16 is attached. An insulating cylinder 17 is attached so as to cover the fixed arc contactor 16, and a buffer cylinder 18 made of an insulating material is attached so as to surround the insulating cylinder 17 from the outside. The puffer cylinder 18 has a small-diameter portion 18a having a smaller inner diameter than the other portions, at a position separated from the cylindrical body 17 by a predetermined distance. A nozzle portion 17n having a hole 17a and a tapered portion 17b is formed on the end surface of the cylindrical body 17, and the movable arc contact 19 comes into contact with the fixed arc contact 16 through the hole 17a of the nozzle portion. A puffer piston 20 is fixed to the movable arc contactor 19, and the piston 20 is fitted into the small diameter portion 18a of the puffer cylinder without a gap before the movable arc contactor 19 comes out of the hole of the nozzle portion 17n. ..

In the gas circuit breaker of FIG. 2, when the movable arc contact 19 is separated from the fixed arc contact 16, an arc is generated between both arc contacts, and the energy of this arc raises the pressure in the boost chamber 14. To do. Further, since the puffer piston 20 is fitted into the small diameter portion 18a of the cylinder, the pressure inside the cylinder 18 is lowered, and the difference between the pressure inside the pressure increasing chamber 14 and the pressure inside the cylinder 18 becomes large. When the movable arc contactor comes out of the hole 17a of the nozzle portion 17n, the gas in the booster chamber 14 is ejected through the hole 17a and is blown onto the arc, so that the arc is extinguished at the zero point of the current.

In this gas circuit breaker, the puffer piston 20 is fitted in the small diameter portion 18 a of the puffer cylinder 18 to reduce the pressure in the cylinder 18, and the difference between the pressure in the pressure raising chamber 14 and the pressure in the cylinder 18 is reduced. Therefore, even if the breaking current is relatively small, a large amount of gas can be blown to the arc when the movable arc contactor comes off the nozzle hole, and arc extinguishing performance can be improved. ..

[0011]

[Problems to be solved by the device]

 In the gas circuit breaker shown in Fig. 2, when the breaking current becomes smaller, the excitation of the arc drive coil becomes weaker, so it is not possible to sufficiently compensate for the decrease in boosting effect, and it is possible to improve the arc extinguishing performance when breaking a small current. I couldn't do enough.

In the circuit breaker shown in FIG. 3, immediately after gas is ejected from the booster chamber 14 into the cylinder 13, the difference between the pressure in the booster chamber 14 and the pressure in the cylinder 18 is rapidly reduced, so that an arc is generated. There was a problem that the blown gas flow was weakened and arc extinguishing performance was not improved.

An object of the present invention is to provide a self-extinguishing type gas circuit breaker with improved arc extinguishing performance in a small current region.

[0014]

[Means for Solving the Problems]

 The present invention comprises a booster chamber having a nozzle part for ejecting gas, a fixed arc contactor arranged in the booster chamber, and a movable contactor for contacting the fixed arc contactor in the booster chamber through the nozzle part. It relates to a gas circuit breaker.

In the present invention, the fixed piston is provided on the boost chamber side and the movable cylinder is provided on the movable arc contact side. The movable cylinder is installed so as to concentrically surround the movable arc contact with the opening at one end facing the boost chamber, and the movable arc contact is displaced toward the fixed arc contact in the boost chamber. Position the fixed piston so that it fits when it reaches the set position, which is set to the position before the position to enter. The movable cylinder and the movable arc contactor are connected via a connecting portion. Also, a check valve that allows only the outflow of gas from the inside of the movable cylinder is attached to the other end of the movable cylinder.

In the boost chamber, an arc drive coil concentrically arranged with the fixed arc contact and excited by an arc current, and an arc traveling plate provided at an end of the arc drive coil are further provided. You can

The fixed piston can be integrally provided on the outer peripheral portion of the nozzle portion. The connecting portion for connecting the movable cylinder and the movable arc contactor is preferably a rib provided at intervals in the circumferential direction.

As the movable cylinder, it is possible to use a tubular body having both ends in the axial direction opened. In this case, the check valve is provided so as to be movable in the axial direction of the movable arc contactor and comes into contact with the opening on the other end side of the movable cylinder from the outside, and the valve plate is provided with the movable cylinder. It can be configured by a spring biasing toward.

[0019]

[Action]

 With the above structure, the movable cylinder causes the piston to fit from the beginning during the shutoff operation to reduce the internal pressure of the piston, so that the flow velocity of the gas ejected from the boost chamber into the cylinder can be increased. If a check valve is attached to the movable cylinder as described above, the check valve will be released when the pressure in the cylinder rises after the movable arc contactor comes out of the nozzle hole and gas is ejected from the boost chamber into the cylinder. Since the gas is opened and the gas in the cylinder is discharged to the outside, the gas can be smoothly discharged from the pressurizing chamber. Therefore, not only high arc extinguishing performance can be obtained at the time of breaking the large current, but also arc extinguishing performance can be improved by blowing a large amount of gas to the arc at the time of breaking the small current.

In addition, when the arc drive coil is provided, the arc is cooled by the relative gas blowing caused by the rotation of the arc, and the inside of the boost chamber is agitated by the rotation of the arc and Since the arc energy is efficiently supplied to the gas, the arc extinguishing performance can be further improved.

Further, as described above, when the movable cylinder is opened at both ends and the end opposite to the pressurizing chamber is opened and closed by the valve plate of the check valve, the check valve is passed through from inside the cylinder. Since a large amount of gas can be made to flow out, the gas can be smoothly made to flow out of the pressurizing chamber, and arc extinguishing performance can be improved.

[0022]

【Example】

 FIG. 1 shows an embodiment of the present invention. In FIG. 1, 101 is a cylindrical pressure chamber forming member made of an insulating material, and 102 is mounted so that the upper end opening of the pressure chamber forming member 101 is airtightly closed. This is a fixed contactor side main circuit conductive plate, and the booster chamber constituent member 101 and the conductive plate 102 constitute a booster chamber 103. A hole 101a is provided at the center of the bottom of the booster chamber constituent member 101 made of an insulating material, and a taper portion 101b is provided at the periphery of the hole 101a. The outer peripheral portion of the tapered portion 101b is extended to form an umbrella-shaped extended portion 10b1, and the hole 101a, the tapered portion 101b, and the extended portion 101b1 constitute a nozzle portion 101n. The extended portion 101b1 of the tapered portion constitutes the fixed piston 104.

A support 105 is attached to the inner surface of the conductive plate 102, and a tulip type fixed arc contact 106 is supported on the support 105. Also, one end of an annular coil support cylinder 107 is connected to the support base 105, and one end of an arc drive coil 108 is connected to the other end of the coil support cylinder 107. An annular arc traveling plate 109 is attached to the other end of the arc driving coil 108, and the stationary side element 110 is fixed by the support base 105, the fixed arc contactor 106, the coil support cylinder 107, the arc driving coil 108, and the arc traveling plate 109. Is configured.

A tubular or rod-shaped movable arc contact 111 is provided so as to be linearly displaced along the central axis of the fixed arc contact 106. This movable arc contactor 111 has a diameter dimension that penetrates the hole 101a of the nozzle portion 101n without any gap, and is operated by an operating device (not shown) to move to the fixed arc contactor 106 through the hole 101a of the nozzle portion as shown. It is displaced between the contacting position where it comes into contact and the cut-off position where it is separated from the hole of the nozzle portion and is separated from the pressure-increasing chamber 103 by a predetermined insulation distance.

A movable cylinder 112 is arranged around the movable arc contact 111. This movable cylinder is composed of a cylinder whose both ends are open. The movable cylinder is arranged concentrically with the movable arc contact with the opening at one end facing the booster chamber 103 side, and is radially arranged with a gap in the circumferential direction. The movable arc contactor 111 is connected to the movable arc contactor 111 by a connecting portion 113 including at least three ribs. The inner diameter of the movable cylinder 112 is set to a size that allows the fixed piston 104 to be fitted without a gap. The position of the movable cylinder 112 such that the fixed piston 104 fits inside the movable cylinder 112 when the set position set at the position (position of the movable arc contact position at a certain later stage of the breaking operation) is reached. Has been defined. Therefore, at the time of interruption, curling is applied to both ends of the movable cylinder 112 in the axial direction so as not to form edge portions where electric fields are concentrated.

The connecting portion 113 is provided on the other end side of the movable cylinder 113, and a small diameter portion 111 a is formed on a part of the movable arc contact 111 adjacent to the connecting portion 113. A sleeve-shaped boss member 114 is slidably fitted to the small-diameter portion 111a, and the boss member 114 is fixed to the central portion of the dish-shaped valve plate 115. The valve plate 115 has a diameter dimension such that its outer peripheral portion comes into contact with the peripheral wall portion at the other end of the movable cylinder 112 from the outside, and is movable with the valve plate 115 being in contact with the peripheral wall portion of the movable cylinder 112 as shown. The opening at the other end of the cylinder 112 is closed. Further, a spring 116 is arranged between the step formed at the end of the small-diameter portion 111a of the movable arc contact 111 and the end of the boss member 114, and by this spring, the valve plate 115 is constantly movable in the cylinder 112. Biased to the side. The strength of the spring 116 is set so that when the pressure in the cylinder 112 becomes higher than the pressure in the outside, the valve plate 115 is displaced to the side away from the cylinder 112 and the gas in the cylinder 112 is discharged to the outside. Has been done. The check member 117 is constituted by the boss member 114, the valve plate 115, and the spring 116. Each of the above parts is housed in a shutoff container, and SF ₆ gas is sealed in the container.

In the above gas circuit breaker, when the movable arc contact 111 is moved to the fixed arc contact side at the time of closing, the movable cylinder 112 is moved before the movable arc contact enters the hole 101a of the nozzle portion 101n. The piston 104 fits into the piston 104, but at this time, the valve plate 115 that constitutes the check valve opens to let out the gas in the cylinder 112, so that the operating force required to move the movable arc contact becomes excessive. It is possible to easily perform the closing operation of the movable arc contactor. At the time of turning on, the main circuit current flows through the path of the main circuit conductor (not shown) connected to the main circuit conductive plate 102, the support 105, the fixed arc contact 106, the movable arc contact 111, and the movable arc contact.

When the movable arc contact 111 is displaced in the direction of separating from the fixed arc contact 106 in order to cut off the electric current, the movable arc contact is separated from the fixed arc contact and at the same time an arc is generated between both arc contacts. To do. When this arc contacts the arc traveling plate 109, an arc current flows through the arc drive coil 108, and a magnetic flux is generated from the coil. Since this magnetic flux intersects the arc at a right angle, the arc is driven and rotates at high speed along the arc traveling plate 109. The rotation of the arc blows a gas relatively to the arc, thereby cooling the arc. At the same time when the arc is generated, a large amount of arc energy is applied to the gas inside the boost chamber 103, so that the gas expands and the pressure inside the boost chamber rapidly rises. In this embodiment, the gas in the boosting chamber is agitated by the rotation of the arc, so that the arc energy is efficiently supplied to the gas. Further, since the movable cylinder 112 is displaced along with the displacement of the movable arc contactor to reduce the internal pressure thereof, the difference between the pressure inside the boost chamber and the pressure inside the cylinder is enlarged. When the movable arc contactor 111 is disengaged from the hole 101a of the nozzle portion, the gas in the pressurizing chamber 103 is ejected into the cylinder 112 through the nozzle portion. Since the high-speed gas flow generated at this time is blown onto the arc, the arc is extinguished at the zero point of the current. When the pressure in the cylinder 112 becomes higher than the external pressure due to the gas in the pressurizing chamber 103 ejecting into the cylinder, the valve plate 115 immediately separates from the cylinder 112 and causes the gas in the cylinder to flow out. The outflow of gas will occur unimpeded. Further, in the latter stage of the shutoff operation, the movable cylinder 112 is disengaged from the piston 104, so that the gas flow is made smoother.

In the present invention, since the piston 104 is fitted into the movable cylinder 112 from the beginning during the shutoff operation to lower the pressure in the cylinder and increase the flow velocity of the gas flowing out of the pressurizing chamber. High arc extinguishing performance can be obtained when shutting off a large current, and high arc extinguishing performance is also achieved by generating a high-speed gas flow even in the region where the breaking current is small and the maximum pressure in the booster chamber is relatively low. be able to.

In the above-described embodiment, in order to facilitate the outflow of gas through the check valve, the connecting portion 113 that connects the movable cylinder 112 and the movable arc contact 111 may be formed by a rib having a thickness as thin as possible. desirable.

When the arc driving coil is provided to rotate the arc as in the above embodiment, the arc extinguishing performance can be improved. However, in the present invention, it is not always necessary to provide the arc driving coil. The present invention can also be applied to the case where the arc drive coil is not provided.

In the above-described embodiment, the entire pressurizing chamber constituent member 101 is formed of the insulating material, but only the vicinity of the bottom of the boosting chamber constituent member 101 and the nozzle portion 101n are formed of the insulating material, and the other parts are formed. It may be formed of a conductive material.

In the above embodiment, only the fixed arc contactor and the movable arc contactor are provided. However, in addition to the fixed and movable arc contactors, the fixed main contactor and the movable main contactor are provided, and at the time of charging. The movable main contact comes into contact with the fixed main contact after the movable arc contact comes into contact with the fixed arc contact, and when the movable main contact comes off from the fixed main contact, the movable arc contact comes into contact with the fixed main contact. Of course, the present invention can be applied to the case where each contactor is positioned so as to be separated from the contactor.

[0034]

[Effect of the device]

 As described above, according to the present invention, since the movable cylinder fits the piston from the beginning during the shutoff operation to reduce the internal pressure of the piston, the flow velocity of the gas ejected from the boost chamber into the cylinder can be increased. Moreover, by attaching a check valve to the movable cylinder, gas can be smoothly discharged from the pressurizing chamber. Therefore, not only high arc extinguishing performance can be obtained when a large current is cut off, but also a large amount of gas can be blown to the arc to improve arc extinguishing performance even when a small current is cut off.

According to the second aspect of the invention, since the arc driving coil is provided to rotate the arc, the arc can be cooled by the relative gas spray generated as the arc rotates. In addition, the arc rotation can stir the interior of the pressure boosting chamber to efficiently supply the arc energy to the gas, so that the arc extinguishing performance can be improved.

Further, according to the invention described in claim 3, since both ends of the movable cylinder are opened and the end portion on the side opposite to the pressure increasing chamber is opened and closed by the valve plate of the check valve, A large amount of gas can be discharged from the inside of the heater through the check valve. Therefore, the gas can be smoothly discharged from the booster chamber, and the arc extinguishing performance can be enhanced.

[Brief description of drawings]

FIG. 1 is a sectional view showing an essential part of an embodiment of the present invention.

FIG. 2 is a sectional view showing a main part of a conventional gas circuit breaker.

FIG. 3 is a cross-sectional view showing a main part of another conventional gas circuit breaker.

[Explanation of symbols]

Reference numeral 101 ... Pressure raising chamber constituent member, 101a ... Nozzle hole, 1
01n ... Nozzle part, 102 ... Main circuit conductive plate, 103 ... Boosting chamber, 104 ... Fixed piston, 106 ... Fixed arc contactor, 108 ... Arc drive coil, 109 ... Arc traveling plate, 111 ... Movable arc contactor, 112 ... Movable cylinder, 113 ... Connection part (rib), 115 ... Valve plate, 116 ...
Spring 117 ... Check valve.

Claims (3)

[Scope of utility model registration request] 1. A booster chamber having a nozzle portion for jetting gas, and a fixed arc contactor disposed in the booster chamber,
In a gas circuit breaker including a movable contactor that contacts a fixed arc contactor in the booster chamber through the nozzle portion, a fixed piston provided in a fixed state with respect to the booster chamber and an opening at one end are provided. The movable arc contactor is provided so as to concentrically surround the movable arc contactor toward the booster chamber side, and is connected to the movable arc contactor through a connecting portion so as to be displaced together with the movable arc contactor. The fixed piston is fitted when the movable arc contactor reaches a set position set before the position where the movable arc contactor enters the boost chamber in the process of displacement of the arc contactor toward the fixed arc contactor side. And a check valve attached to the other end side of the movable cylinder and allowing only the outflow of gas from inside the movable cylinder. Gas circuit breaker according to claim. 2. An arc drive coil which is arranged concentrically with the fixed arc contact and is excited by an arc current,
The gas circuit breaker according to claim 1, further comprising an arc traveling plate provided at an end portion of the arc drive coil, the arc traveling plate being provided in the boost chamber. 3. The fixed piston is integrally provided on an outer peripheral portion of the nozzle portion, and a connecting portion connecting the movable cylinder and the movable arc contact is formed from a rib provided at a circumferential interval. The movable cylinder is composed of a tubular body with both ends in the axial direction opened, and the check valve is provided movably in the axial direction of the movable arc contactor and is provided at an opening on the other end side of the movable cylinder. The gas circuit breaker according to claim 1 or 2, comprising a valve plate abutted from the outside and a spring for urging the valve plate toward the movable cylinder.