RU2237309C1 - Inner-mounted vacuum switch - Google Patents

Abstract

FIELD: electrical engineering, concerns vacuum switches designed for use in cubicls of switchgear and control gear.

SUBSTANCE: the vacuum switch has an insulating body rigidly coupled to the supporting frame of the switch, vacuum arc chute with contacts, whose movable contact is connected to an electromagnetic drive partially arranged in the cavity of the insulating body. The rod of the drive engaging electromagnet is installed for engagement with one of the movable levers of the operating mechanism. The operating mechanism has minimum three successively connected movable levers. The outlet lever of the operating mechanism is simultaneously coupled to the insulating tie-rod and the disengagement spring of the electromagnetic drive. The movable levers of the operating mechanism in the on-position of the switch are installed in a position close to the "dead" one.

EFFECT: enhanced reliability of operation and speed of response, reduced mass and dimensional characteristics of the switch.

3 cl, 2 dwg

Description

The invention relates to electrical engineering and for the design of vacuum circuit breakers intended for use in switchgear cubicles.

A switch with an electromagnetic drive is known (RF patent No. 2145746, H 01 H 33/66, H 01 H 33/38), containing a switching electromagnet fed by a rectified current, a rod mounted on an anchor of the switching electromagnet, a two-arm lever with a roller at one end and a hinge on the other, a shaft rigidly connected to the lever, a rod connected through a preload spring to the movable contact of the arcing chamber. Two latches with corresponding springs are installed with the possibility of fixing in the on position, while one of the latches is made in the form of a two-shouldered lever, one shoulder of which is connected with an electromagnet, and the other with the other latch. The disconnect spring is connected to the two-arm lever. The switch also contains a spring connected to the armature of the switching electromagnet.

When the switch is turned on, the rod through the roller acts on one end of the two shoulders lever, which acts on the rod through the hinge at the other end and transmits the movement to the movable contact of the arcing chamber through the preload spring. the camera contacts are closed, the roller is seated on the corresponding latch and the on position of the switch is locked with another latch.

The circuit breaker trips when a command is given to the tripping electromagnet, which acts on the rod of one of the latches, under the action of the tripping spring and the preload spring, another latch bounces. The drive is ready to start up again.

The spring of the latches are used to ensure their return to the working position, the spring associated with the armature of the electromagnet inclusion, is used to return the armature after the power supply to the coil of the electromagnet.

A disadvantage of the known switch is the complexity of its articulated-lever operating mechanism, containing a significant number of levers, springs and latches, reducing the reliability and stability of its operation, as well as reducing the speed of the circuit breaker drive.

Moreover. the articulated-lever operating mechanism of the known switch has a developed spatial structure, as a result of which the use of the switch in the switchgear cells is irrational, since the dimensions of such installations will be significant.

The technical problem solved by the claimed invention is to increase the reliability and speed of the vacuum circuit breaker; as well as reducing the overall dimensions of the circuit breaker.

The problem is solved in that in a vacuum circuit breaker containing an insulating casing, rigidly connected to the support frame of the circuit breaker, a vacuum arcing chamber, an insulating rod. connecting the movable contact of the vacuum interrupter chamber with the electromagnetic actuator of the circuit breaker through the spring contact preload device, the electromagnetic actuator includes on and off electromagnets, a disconnect spring and an articulated lever operating mechanism, the actuator electromagnet rod is installed to interact with one of the movable levers of the operating mechanism, an electromagnetic actuator partially placed in the cavity of the insulating body, the body of the operating mechanism is rigidly connected n with the support frame of the switch, the operating mechanism contains at least three series-connected movable levers, while the output lever of the operating mechanism is connected simultaneously with the insulating rod and with the spring off the electromagnetic drive, the movable levers of the operating mechanism in the on position of the switch are installed in a position close to the "dead."

In the inventive switch, the switching electromagnet can be placed on the side of the housing of the operating mechanism facing outward of the insulating case of the switch, while the angle formed by the axis of the switch and the axis of the switching electromagnet is from 30 to 90 degrees.

In the inventive switch, the trip electromagnet and the trip spring can be rigidly connected to the side of the housing of the operating mechanism facing the outside of the insulator housing of the switch.

The problem of the electric strength of the external insulation of the vacuum interrupter chamber is solved with the help of an additional insulating cover - an insulating casing. Inside the housing are all the main functional units of the vacuum circuit breaker - a vacuum arcing chamber, an insulating rod. connecting the movable contact of the vacuum interrupter chamber with an electromagnetic drive, spring contact preload device. The insulating casing is rigidly fixed to the support frame of the switch.

Since the vacuum circuit breaker, according to the proposed technical solution, is intended for use in switchgear cubicles (complete switchgears), i.e. It is intended for use in rooms that are closed from external atmospheric influences. It is possible to make an insulating casing in such a way that a part of the electromagnetic drive is placed in the cavity of the insulating casing, for example, by making a break in the insulating casing. In this case, of course, air from the interior of the switchgear cell will enter the internal cavity of the insulating casing. Inside the switchgear compartment, the necessary and safe humidity and temperature conditions are maintained for the circuit breaker, therefore, this embodiment of the insulating casing is safe when the circuit breaker operates at medium voltages (for example, 27, 5 kV).

Placing a part of the electromagnetic drive in the cavity of the insulating casing will make it possible to bring the electromagnetic drive as close as possible to the switch, i.e. will minimize the overall dimensions of the switch.

The electromagnetic drive includes an articulated lever operating mechanism, the housing of which is rigidly connected to the support frame of the switch.

The operating mechanism is made of at least four-link and contains three movable links - three series-connected movable levers, and one fixed link - the housing of the operating mechanism. The output lever is simultaneously connected with an insulating rod and with a trip spring, for this the output lever is triple-arm. In this case, the first lever, the second intermediate lever and the first shoulder of the output lever are locking links of the operating mechanism. When controlling the operation of the circuit breaker, they act on the locking links of the operating mechanism in order to turn the circuit breaker on or off. The locking links of the operating mechanism when the circuit breaker is turned on are set to close to “dead”, providing a locked state of the operating mechanism (when the circuit breaker is on), from which it exits only when these links are released from the action of the rod of the switching solenoid.

The output lever is made in such a way that its second and third shoulder are connected respectively to the insulating rod and to the trip spring, and the first lever of the output lever, as already noted, is one of the locking links of the operating mechanism that are affected by the operation of the switch.

Thus, the maximum approximation of the zones in which the force arises (insulating traction) and the control zones (exposure) is ensured. Those. control is carried out where a force arises, which, firstly, increases the efficiency of the electromagnetic drive and the speed of the circuit breaker, and secondly, allows to minimize the overall dimensions of the circuit breaker, which is relevant when the circuit breaker is designed for placement in switchgear cubicles.

The presence in the operating mechanism of a minimum number of levers and transmission links can also significantly reduce the weight of the switch.

The circuit breaker is controlled by the rod of the electromagnet inclusion. For this, the switching electromagnet is placed on the side of the housing of the operating mechanism facing the outside of the insulating housing. The rod of the switching electromagnet is installed with the possibility of interaction with one of the movable levers of the operating mechanism (with one of the locking links). In this case, the movable levers of the operating mechanism of the circuit breaker are installed in a position close to “dead”, thus performing kinematic locking of the operating mechanism in the on position. In this position, the movable levers are held by the rod of the electromagnet inclusion. When the rod of the switching solenoid acts on one of the movable levers of the operating mechanism, the output lever begins to move and simultaneously acts on the insulating rod connected to the movable contact of the vacuum interrupter chamber and compresses the disconnection spring. At the end of the movement, the output lever maximally compresses the disconnection spring, and the contacts of the vacuum arcing chamber are closed, held in this position by an insulating rod.

When the switch is turned off, the rod of the electromagnet of inclusion is set in motion to trip, releasing the levers of the operating mechanism. Under the action of a breaking spring, which tends to open, the levers of the operating mechanism come into motion. The dispersed masses of levers strike an insulating rod, breaking the contacts of the vacuum interrupter chamber. The insulation rod moves down, the contacts are parted.

In order to ensure reliable and optimal from the point of view of speed of operation of the electromagnetic drive, the inclusion electromagnet is placed on the side of the housing of the operating mechanism, while the angle formed by the axis of the electromagnet inclusion and the axis of the switch is from 30 to 90 degrees. Such placement of the switching solenoid will optimally accommodate the electromagnetic drive, maximally approximating the zone of occurrence of force (insulating traction) and the zone of influence (control) - movable levers of the operating mechanism.

The placement of the closing electromagnet, the tripping electromagnet and the tripping spring on the side of the operating mechanism housing facing outward of the circuit breaker insulating housing is appropriate from the point of view of ensuring the stability of the circuit breaker during its operation. Such an arrangement of the elements of the electromagnetic drive leads to the fact that the whole system - on the one hand, a vacuum arcing chamber located in the insulating casing, an insulating rod and a contact clamping device, and on the other hand - an electromagnetic drive that includes a pivot-lever operating mechanism, on and off electromagnets and disconnect spring, form a rigid V-shaped structure. When the switch is turned on and off, the forces arising in each arm of this V-shaped structure have opposite directions and, thus, balance each other. Therefore, during the operation of the circuit breaker, a stable equilibrium position of the insulating casing and the vacuum arcing chamber, insulating rod and contact clamping device placed in it is ensured, which increases the reliability of the circuit breaker design. Increases the strength and stability of the entire system.

Thus, the claimed combination of features of a technical solution regarding the design of a vacuum circuit breaker for indoor installation, can significantly reduce the overall dimensions of the circuit breaker by reducing the number of levers and transmission links of the operating mechanism, due to the maximum proximity of the electromagnetic drive to the switch.

In addition, due to the fact that the control action on the levers of the operating mechanism is carried out where there is a force to be controlled (insulation rod), the speed of the circuit breaker is increased. At the same time, the minimum number of levers and transmission links of the operating mechanism significantly increases the efficiency of the electromagnetic drive.

The prior art does not reveal solutions regarding the design of the vacuum circuit breakers of the indoor installation, characterized by the claimed combination of features, therefore, the present invention meets the criterion of patentability - “novelty”.

The claimed combination of features of the claimed invention, which allows to significantly reduce the overall dimensions of the vacuum circuit breakers of the indoor unit, to increase their speed in comparison with the known from the prior art, allows us to conclude that the claimed invention meets the patentability criterion of “inventive step”.

The invention is illustrated by drawings.

Figure 1 presents the inventive vacuum circuit breaker of the indoor installation in the context.

Figure 2 shows the articulated lever operating mechanism of the vacuum circuit breaker.

The vacuum circuit breaker of the indoor unit (Fig. 1) comprises an insulating housing 2 and an operating mechanism housing 3 mounted on the support frame 1. In the insulating housing 1 there is a vacuum arcing chamber 4, an insulating rod 5 connecting the movable contact (not shown) of the vacuum arcing chamber 4 through a spring-loaded contact clamping device with an electromagnetic drive. The device spring preload contacts made in the form of a glass 6 and placed inside the spring 7 preload. The electromagnetic drive contains an electromagnet 8 on and an electromagnet 9 trip, spring 10 trip and articulated lever operating mechanism. The activation electromagnet 8 is rigidly mounted on the side surface of the housing 3 of the operating mechanism facing outward of the insulating housing 2, and comprises a rod 11 having the ability to act on the movable levers of the operating mechanism. The output lever 12 of the operating mechanism is connected to the disconnecting spring 10, as well as to the insulating rod 5 through the cup 6 of the spring contact preload device. The rod 11 is connected to the armature 13 of the electromagnet 8 inclusion.

The hinged-lever operating mechanism (figure 2) is a four-link and contains three movable links - levers 12, 14, 15 and one fixed link, which is the housing 3 of the operating mechanism. The housing 3 of the operating mechanism is made in the form of two supporting channels 16, between which are placed the levers 12, 14, 15. The axis of rotation 17 and 18 of the lever 15 and the output lever 12, respectively, are attached to the inner side surfaces of the channels 16. The output lever 12 is made of a three-arm, its first shoulder is connected to the lever 14 and is one of the locking links of the operating mechanism. The locking links are also the levers 14 and 15. The second shoulder of the output lever 12 is connected to the insulating rod 5 through the glass 6. and the third shoulder is connected to the spring 10 disconnect.

The vacuum switch of the indoor unit operates as follows.

When a signal is sent to turn on, the armature 13 of the switching solenoid is retracted. When this rod 11 acts on the lever 15 of the operating mechanism. The lever 15 comes into motion and through the lever 14 transmits the movement to the output lever 12, which simultaneously compresses the disconnect spring 10 and drives the insulation rod 5 through the glass 6, connected to the movable contact of the arcing chamber 4. After closing the contacts of the arcing chamber 4, the continued movement of the output the lever 12 leads to compression of the spring 7 preload contacts. At the end of the movement, the locking levers 12, 14 and 15 become in a position close to “dead”, kinematically locking the operating mechanism in the on position.

When the switch is turned off, the armature 13 sets in motion to trip, releasing the locking levers 12, 14 and 15. The levers 12, 14 and 15 and the cup 6, in which the trip spring 7 is located, are set in motion to trip. Under the action of pre-compressed spring 7 preload contacts and spring 10 disconnect levers are accelerated. Under the influence of the masses of levers 12, 14 and 15 and the glass 6, an impact is made on the insulating rod 5, while the welded contacts of the vacuum interrupter chamber 4 are torn apart. Insulation rod 5 is set in motion, the contacts are parted.

Claims (3)

1. Vacuum circuit breaker for indoor installation, comprising an insulating casing rigidly connected to the support frame of the circuit breaker, a vacuum arrester chamber, an insulating rod connecting the movable contact of the vacuum arrester chamber to the electromagnetic actuator of the circuit breaker via a spring contact preload device, the electromagnetic actuator includes on and off electromagnets, a spring disconnection and articulated lever operating mechanism, the rod of the electromagnet inclusion is installed one of the movable levers of the operating mechanism, characterized in that the electromagnetic drive is partially located in the cavity of the insulating casing, the housing of the operating mechanism is rigidly connected to the support frame of the switch, the operating mechanism contains at least three movable levers in series, the output lever of the operating mechanism being connected simultaneously with the insulating rod and with the electromagnetic actuator release spring, I will turn off the movable levers of the operating mechanism in the on position the receiver are installed in a position close to "dead". 2. The switch according to claim 1, characterized in that the switch-on electromagnet is located on the side of the operating mechanism housing facing outward of the switch insulator body, wherein the angle formed by the switch axis and the axis of the switching electromagnet is 30 to 90 °. 3. The switch according to claim 1 or 2, characterized in that the tripping electromagnet and the tripping spring are rigidly connected to the side of the housing of the operating mechanism facing the outside of the insulating housing of the switch.

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