RU2584551C1 - High-voltage vacuum circuit breaker - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: high-voltage vacuum circuit breaker comprises two independent coaxially fixed vacuum arc-quenching chambers, ends of which are closed by flanges. Contact unit of first vacuum arc-quenching chamber consists of fixed and movable contacts. Contact unit of second vacuum arc-quenching chamber consists of two movable contacts. Fixed contact of first vacuum arc-quenching chamber is rigidly connected with flange by means of current lead, and movable contact is connected to other flange by bellows. Movable contacts of second vacuum arc-quenching chamber are connected to its flanges by bellows. Movable contact of first vacuum arc-quenching chamber and closest to movable contact of second vacuum arc-quenching chamber are connected to common current lead with possibility of back-and-forth movement along axis of vacuum arc-quenching chambers. Common current lead is made in form of rod with locking bulge arranged between vacuum arc-quenching chambers. On common current conductor between flange of first vacuum arc-quenching chamber and locking bulge compression spring is installed. Other movable contact of second vacuum arc-quenching chamber is connected to drive its current conductor.

EFFECT: high operating voltage and functionality of high-voltage vacuum circuit breaker with simple design.

1 cl, 3 dwg

Description

The invention relates to electrical engineering, in particular to high-voltage apparatus engineering, for the design of high-voltage circuit breakers with vacuum interrupter chambers, and can be used for switching AC power energy circuits.

Known high-voltage vacuum circuit breaker [RU 2137240 C1, IPC6 H01H 33/66, publ. 09/10/1999], which contains three arcing chambers, the movable contacts of which are connected to the drive device by means of a kinematic circuit including dielectric rods, spring contact clamping mechanisms and a flat articulated lever parallelogram mechanism, containing two-arm rotary levers, the rotation axes of which are connected to the housing, and the first shoulders are interconnected by a bar consisting of two parts. The axis of symmetry of the dielectric rods and spring contact preload mechanisms are located in the same plane as the articulated lever mechanism. The axis of rotation of the pivoting levers are connected to the housing through spring contact preload mechanisms. The second arms of the levers are pivotally connected to dielectric rods.

The connection of the movable contacts with the drive device through the complex construction of the kinematic circuit, including dielectric traction and a linkage mechanism, reduces the reliability of this high-voltage vacuum circuit breaker.

Known high-voltage vacuum circuit breaker [RU 2224318 C1, IPC7 H01H 33/666, publ. 02/20/2004], containing a common shaft and vacuum arcing chambers installed on the base, each of which has a fixed contact and a movable contact connected to the insulating rod. Each chamber is equipped with a drive and a node for compressing contacts with the spring, coaxial to the rod. The drive of each vacuum interrupter chamber, which provides contact closure, has an electromagnet with a pusher acting on the rod by means of a movable stop at its lower end, mounted to allow it to move along the rod and pivotally connected to the shaft. The spring of the contact preload unit is installed between the movable stop and the fixed stop fixed on the rod. The switch is equipped with a contact disconnection drive common to all the interrupter chambers, containing a common shaft, in the cavity of which there is a torsion spring, one end of which is rigidly fixed to the base, the other end to the shaft.

The closing and opening of the contacts of this high-voltage vacuum circuit breaker is ensured by a complex design, which leads to a decrease in the reliability of its operation.

Known high-voltage vacuum circuit breaker [RU 2282266 C1, IPC H01H 33/666 (2006.01), publ. 08/20/2006], containing three poles with vacuum interrupter chambers mounted on the base, an electromagnetic drive device mounted on the same base on the reverse side, the movable part thereof being connected to the insulating rods of the vacuum interrupter chambers by a common traction located in a plane perpendicular to the axes insulating rods and electromagnetic drive device. The electromagnetic drive device contains two electromagnetic drives mounted in a row with the poles between the middle and extreme insulation rods.

The disadvantage of such a high-voltage vacuum circuit breaker is the complexity of the design of the electromagnetic drive device, which provides the closing and opening of the contacts of the vacuum circuit breaker, which leads to an increase in cost and a decrease in the reliability of the circuit breaker.

Known high-voltage vacuum circuit breaker [RU 2402832 C1, IPC H01H 33/66 (2006.01), publ. 10.27.2010] containing a common shaft and vacuum arcing chambers installed on the housing, each of which has a fixed contact and a movable contact connected to the insulating rod. Each chamber is equipped with an insulating rod drive. A common for all interrupter chambers, the lock of the closed position of the contacts contains a “breaking” lever from two shoulders. One of the ends of the shoulder is pivotally connected to the body. The other end of the other shoulder is pivotally connected to a common shaft. The opposite ends of the shoulders are interconnected by a central hinge. The latch of the “breaking” lever is made in the form of stops located at the ends of the shoulders adjacent to the central hinge.

The disadvantage of such a high-voltage vacuum circuit breaker is the complexity of the design of the kinematic circuit on-off of the vacuum circuit breaker, which leads to an increase in the inertia of the mechanism and reduce the reliability of the circuit breaker.

Known high-voltage vacuum circuit breaker [RU 2428761 C2, IPC H01H 33/66 (2006.01), publ. 09/10/2011. Bull. No. 25], adopted as a prototype containing a vacuum interrupter chamber in which at least one movable contact element is located. Inside the vacuum interrupter chamber there are two series-connected contact devices with two, in total, openable contact planes. The contact element, which is made moving together with or after the first contact element, is surrounded by a bowl-shaped device that is integral with the contact element or is at least firmly connected to it or provided with an opening through which the contact element passes, having active contact surfaces on both sides. Both contacts are made with the possibility of driving a single common drive. One of the contact elements is arranged to be actuated by means of a drive directly with forced movement, while the other contact element is configured to be actuated by means of a spring force indirectly and in at least one direction of actuation and is made to move together with the first contact element or after him.

The disadvantage of such a high-voltage vacuum circuit breaker is the presence of a spring located inside the vacuum chamber between the movable bowl-shaped element and the edge of the side on the inner side of the vacuum chamber. The presence of such a spring is technologically difficult to implement, since with the obligatory annealing of the vacuum chamber during the production process, the spring almost completely loses its elastic properties and cannot provide the mobility of the inner cup-shaped element. As a result, the vacuum circuit breaker loses the ability to perform its functions.

The objective of the invention is to simplify the design, increase the operating voltage and functionality of the high-voltage vacuum circuit breaker.

The solution to this problem is achieved in that the high-voltage vacuum circuit breaker, as in the prototype, contains a vacuum arcing chamber in which one movable contact is configured to be actuated by the drive, while the other movable contact is configured to be actuated by means of a spring force and made moving together with or after the first contact.

According to the invention, the high-voltage vacuum circuit breaker contains two self-contained coaxially fixed vacuum arcing chambers, the ends of which are closed by flanges. The contact node of the first vacuum interrupter chamber consists of fixed and movable contacts. The contact node of the second vacuum interrupter chamber consists of two movable contacts. The fixed contact of the first vacuum interrupter chamber is rigidly connected to the flange by means of a current supply, and the movable contact is connected to the other flange by a bellows. The movable contacts of the second vacuum interrupter chamber are connected to its flanges by bellows. The movable contact of the first vacuum arcing chamber and the closest movable contact of the second vacuum arcing chamber are connected by a common current supply with the possibility of reciprocating movement along the axis of the vacuum arcing chambers. The common current supply is made in the form of a rod with a locking thickening located between the vacuum interrupter chambers in such a way that a compression spring is installed on the common current supply between the flange of the first vacuum arcing chamber and the locking thickening. Another movable contact of the second vacuum arcing chamber is connected to the drive by its current supply.

The proposed solution allows you to mount the spring in the design of the high-voltage vacuum circuit breaker after annealing autonomous vacuum arcing chambers, which simplifies the design of the high-voltage vacuum circuit breaker. In this case, annealing of autonomous vacuum interrupter chambers does not change the elastic characteristics of the spring, which increases the functionality of the high voltage vacuum circuit breaker. This solution also allows you to increase the number of autonomous arcing vacuum chambers in the design and, thus, increase the operating voltage of the high-voltage vacuum circuit breaker.

In FIG. 1 shows the design of a high voltage vacuum circuit breaker in the off state.

In FIG. 2 shows the design of a high voltage vacuum circuit breaker in an intermediate state.

In FIG. 3 shows the design of the high voltage vacuum circuit breaker in the on state.

The high-voltage vacuum circuit breaker contains two self-contained vacuum interrupter chambers 1 and 2. The casings of the vacuum interrupter chambers are cylindrical in shape and coaxially mounted on a dielectric base (not shown in FIG. 1). The ends of the vacuum arcing chamber 1 are closed by flanges 3 and 4. Inside the first vacuum arcing chamber 1, there is a contact group consisting of a fixed contact 5, which is rigidly connected by a current lead 6 to flange 3, and a movable contact 7, connected by a bellows 8 to another flange 4. Inside the second vacuum interrupter chamber 2, the ends of which are closed by flanges 9 and 10, is a contact group consisting of two movable contacts 11 and 12, which are connected by bellows 13 and 14 with flanges 9 and 10, respectively. The movable contact 7 of the first vacuum arcing chamber 1 and the movable contact 11 of the second vacuum arcing chamber 2 are connected by a common current lead 15 with the possibility of reciprocating motion along the axis of the vacuum arcing chambers 1 and 2 through the bellows 8, flanges 4 and 9 and the bellows 13. The current lead 15 is made in the form of a rod with a locking thickening 16 located between the vacuum interrupter chambers 1 and 2. A compression spring is installed on the current lead 15 between the flange 4 of the first vacuum arc extinguishing chamber 1 and the locking thickening 16 ment 17. The movable contact 12 of the second vacuum interrupter chamber 2 is connected to a bellows 14 disposed inside the current feeder 18, which is connected to the actuator.

Shutdown of a high-voltage vacuum switch. When the high-voltage vacuum circuit breaker is turned off, the drive moves the current supply 18 together with the movable contact 12 of the second vacuum interrupter chamber 2 in the direction from the stationary contact 5 of the first vacuum arrester chamber 1. The compression spring 17 expands and pushes the common current lead 15 together with the movable contact 11 second the vacuum interrupter chamber 2 and the movable contact 7 of the first vacuum interrupter chamber 1 in the direction of the movable contact 12 of the second vacuum interrupter chamber 2. E о leads to the fact that between the movable contact 7 and the stationary contact 5 of the first vacuum arcing chamber 1, a gap is formed, which increases until the stopper thickening 16 of the common current supply 15 abuts against the flange 9 of the second vacuum arcing chamber 2. After that, the movement of the common the current supply 15 is stopped, and in the first vacuum arcing chamber 1 between the movable contact 7 and the stationary contact 5, a gap is maintained, which corresponds to the disconnected state of the first vacuum arcing chamber s 1 (Fig. 2). A further movement of the current supply 18 occurs until a gap is formed between the movable contacts 12 and 11 of the second vacuum arcing chamber 2, which corresponds to the disconnected state of the second vacuum arrester chamber 2. When the movable contacts 12 and 11 of the second vacuum arrester chamber 2, as well as the movable contact 7 and the fixed contact 5 of the first vacuum interrupter chamber 1 are open, the high-voltage vacuum circuit breaker is in the off state (Fig. 1).

Turning on the high voltage vacuum circuit breaker. From the drive of the high-voltage vacuum circuit breaker, the current lead 18, together with the movable contact 12, moves towards the movable contact 11 of the second vacuum arcing chamber 2. After the movable contacts 12 and 11 of the second vacuum arcing chamber 2 are closed, the current lead 18 is moved together with the common current lead 15, which connects the movable contact 11 of the first vacuum interrupter chamber 1 and the movable contact 7 of the second vacuum arrester chamber 2. The movement of the current lead 15 together with the movable contact 7 in The defense of the stationary contact 5 of the first vacuum interrupter chamber 1 is caused by the compression of the spring 17, which, on the one hand, abuts against the locking collar 16 of the current supply 15, and, on the other hand, abuts the flange 4 of the first vacuum arrester chamber 1. When contacts 7 and 5 come into contact, the high-voltage vacuum switch included, and the spring 17 is compressed as much as possible (Fig. 3).

Claims (1)

A high voltage vacuum circuit breaker comprising a vacuum arcing chamber in which one movable contact is arranged to be actuated by a drive, while the other movable contact is configured to be actuated by a spring force and is made to move in conjunction with or after the first contact, characterized in that contains two autonomous coaxially fixed vacuum interrupter chambers, the ends of which are closed by flanges, the contact node of the first vacuum arrester chamber with consists of fixed and movable contacts, and the contact node of the second vacuum arcing chamber consists of two movable contacts, the stationary contact of the first vacuum arcing chamber is rigidly connected to the flange by means of a current supply, and the movable contact is connected to the other flange by a bellows, and the movable contacts of the second vacuum arcing chamber connected to its flanges by bellows, the movable contact of the first vacuum arcing chamber and the closest movable contact of the second vacuum arc the quenching chamber is connected by a common current supply with the possibility of reciprocating movement along the axis of the vacuum interrupter chambers, while the general current supply is made in the form of a rod with a stopper thickening located between the vacuum arrester chambers in such a way that the common current lead between the flange of the first vacuum extinguishing chamber and the stopper thickening a compression spring is installed, and another movable contact of the second vacuum arcing chamber is connected to the drive by its current supply.

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