RU2137240C1 - High-voltage vacuum switch - Google Patents

Abstract

FIELD: electrical engineering, switching of A C power circuits. SUBSTANCE: high-voltage vacuum switch has three arc chutes with mobile contacts connected to driving device with the aid of kinematic circuit that includes dielectric tie-rods and flat parallel link mechanism made of rotary bell-cranks which rotation axles are linked to case via spring mechanisms f contact pressing. Symmetry axis of dielectric tie-rods and spring mechanisms of contact pressing are placed in one plane with link mechanism. First levers of rotary bell-cranks are interconnected with the use of two strips and second levers are hinged to dielectric tie- rods. Each rotary bell-crank has rest of second lever located between dielectric tie-rod and spring mechanism of contact pressing and two additional rests, one being positioned in symmetry with main rest and second one being arranged on axis of dielectric tie-rod. Driving device registers ON and OFF positions of switch and spring mechanism of contact pressing works in compression and extension. EFFECT: increased speed of response and decreased power of drive. 2 cl, 11 dwg

Description

 The invention relates to electrical engineering, in particular, to the creation of vacuum circuit breakers designed for switching power AC power circuits.

 Existing designs of vacuum circuit breaker drives, as a rule, have a drive device and a transmission mechanism in the form of a rotary shaft with three rotary levers fixed to it, to which insulating rods are connected, connected via compression units with movable contacts of the vacuum chambers [1]. When the switch is turned on, the drive device acts on the additional lever fixed on the shaft. In this case, the shaft is rotated in bearings mounted on the housing and by pivoting levers through insulating rods and contact preloading units, which moves the movable contacts of the vacuum chambers. Thus, the shaft serves as an intermediate link transmitting movement from the drive device to the movable contacts of the three vacuum chambers.

 With the simplicity of the kinematic scheme of the known device, a significant drawback is that a long shaft loaded with twice the compression force of the contacts works for bending and torsion, therefore it must have high rigidity and, therefore, be massive enough, which increases the response time of the circuit breaker and requires a drive device high power. Since the drive device is mounted on the housing and, when exposed to the shaft, transmits a reaction to the housing, the switch housing must also be strong and rigid, which increases its weight and cost.

 Closest to the proposed device is a high-voltage vacuum circuit breaker containing three arcing chambers, the movable contacts of which are connected to the drive device through dielectric rods and spring contact clamping mechanisms using a flat articulated lever parallelogram mechanism, consisting of two two-arm rotary levers and one three-armed axis the rotations of which are connected to the housing, the first shoulders are interconnected by a strap, and the second are pivotally connected to the spring mechanism contact preload. The axis of symmetry of the dielectric rods and spring preload mechanisms are located in the same plane as the articulated lever mechanism. The drive device is connected through the main spring mechanism of preloading the contacts to the third shoulder of the three-arm lever [2].

 In this design of the transmission mechanism, the links working in bending (shaft, circuit breaker housing) are replaced by the links working in compression - tension, which reduces the mass of the transmission mechanism. However, spring contact clamping mechanisms located between the pivoting levers and dielectric rods, as a whole, participate in the movement of the contacts, increasing the mass of moving links brought to the drive device, thereby increasing the response time of the circuit breaker.

 The problem to which the invention is directed, is to increase the speed of the circuit breaker and reduce the power of the drive device.

 The task is achieved in that in a high-voltage vacuum circuit breaker containing 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, rotation axes which are connected to the housing, and the first shoulders are interconnected by a bar, and the axis of symmetry of the dielectric rods and spring mechanisms contact preloads 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 arm levers are pivotally connected to dielectric rods, and the bar consists of two parts.

 Each pivot arm has a second shoulder stop located between the dielectric rod and the spring contact pinch mechanism.

 In addition, each pivot arm has two additional stops, one of which is located symmetrically to the main one, and the second is located on the axis of the dielectric traction. At the same time, the drive device has the ability to fix the on and off position of the switch, and the spring contact preload mechanism has the ability to work in compression and tension.

 In the proposed device, spring contact preloading mechanisms are excluded from the contact movement circuit of the contacts and participate only in contact preloading. Reducing the mass of moving links leads to a decrease in the required power of the drive device and increase the speed of the apparatus.

 The need to use two strips to connect the first shoulders of the pivoting arms is explained by the fact that during the arc wear of the end contacts during operation, the intercontact gaps of different phases become unequal. In the design of the switch described in the prototype, the static indeterminacy of the system when the contacts are closed disappears due to the deformation of the contact tightening mechanisms, the two shoulders and the common bar connecting them do not participate in this process, so the bar can be monolithic. In the proposed switch, the deformation of the preload mechanisms is carried out together with the vertical movement of the two-arm levers. Therefore, to ensure the required contact preload of the contacts of different phases, it is necessary to have unequal vertical movement of the two-arm levers, which is achieved by using a bar consisting of two parts.

 The use of rotary levers of the second shoulder stops in the switch makes it possible to extinguish the speed of movement of the movable contacts immediately before the moment the contacts of the switch touch. This, in turn, makes it possible to increase the average velocity of the contacts, i.e. increase the speed of the circuit breaker.

 The introduction of additional stops of the second arms of the pivoting levers makes it possible to transfer the energy of the compressed spring of the preload mechanism to the energy of motion of the dielectric traction and vice versa, which leads to lower energy costs for turning the switch on and off, i.e. reduces the power of the drive device.

 In FIG. 1 shows a high voltage vacuum circuit breaker with a vertical arrangement of the gear mechanism; in FIG. 2 - with a horizontal layout of the transmission mechanism; in FIG. 3 shows the action of the pivot arm in the presence of a stop of the second shoulder; in FIG. 4 - action of the pivot arm in the presence of three stops of the second shoulder.

 The high-voltage vacuum circuit breaker contains three arcing chambers 1 with movable contacts 2 connected through a transmission device to a drive device 3. The transmission device includes dielectric rods 4 and a flat articulated lever mechanism consisting of two-arm rotary levers 5, the axis of rotation 6 of which are connected to the housing 7 of the transmission mechanism through the spring mechanisms 8 preload contacts. The axis of symmetry of the dielectric rods 4 and spring mechanisms 8 of the preload contacts are located in the same plane with the articulated lever mechanism. The first shoulders of the pivoting levers 5 are interconnected by two strips 9, coaxially to one of which a trip spring 10 is supported against the housing 7. The second shoulders of the pivoting levers 5 are connected to the dielectric rods 4 by hinges 11. To exclude the mobility of the levers 5 in the direction perpendicular the plane of the articulated lever mechanism, additional levers 12 are used, pivotally connected to the housing 7 and to the axes of rotation of the rotary levers 5. The drive device 3 is connected to the first shoulder of one of the rotary levers 5 p thrust means 13 with two universal joints 14 at the ends. The use of universal joints is necessary because the drive mechanism is located in a plane perpendicular to the plane of the transmission mechanism.

 The high-voltage vacuum circuit breaker with a horizontal arrangement of the transmission mechanism further comprises intermediate two-arm rotary levers 15 (Fig. 2), the first shoulders of which are connected to dielectric rods 4, and the second to the movable contacts 2 of the vacuum chambers 1.

 Each pivot arm 5 has a stop 16 of the second shoulder (Fig. 3), located between the dielectric rod 4 and the spring mechanism for compressing the contacts 8.

 In addition, each pivot arm 5 has two additional stops 17 and 18 of the second shoulder (Fig. 4). The additional emphasis 17 is located symmetrically to the main emphasis 16, and the additional emphasis 18 is located on the axis of the dielectric rod 4 and abuts against the hinge 11 when the switch is off. The spring mechanism 8 of preloading contacts contains a rod 19, on which between the plates 20 there is a spring 21, upper and lower stops 22, mounted on the mechanism body. The mechanism also contains two nuts 23, mounted on the rod 19 from the outer sides of the plates 20.

 The vacuum switch operates as follows. When you turn on the drive device 3 through the rod 13 with universal joints 14 rotates one of the two-arm levers 5. In this case, thanks to the straps 9, the other two two-arm levers 5 also rotate around the axes 6. Thus, the dielectric rods 4 and the movable contacts 2 are driven. After closing of the contacts, the continued impact of the drive device 3 leads to the rotation of the two-arm levers 5 around the hinges 11, while the compression of the springs of the spring mechanisms 8 of the contacts is compressed, which ensures the required contact e pressing the contacts of the vacuum chambers 1. Upon completion of switching on, the drive device 3 locks the switch mechanism in the “on” position.

 When the circuit breaker is turned off, the drive device 3 knocks the latch, and under the action of the compression springs 8 and the trip spring 10 compressed when turning on, the circuit breaker mechanism returns to its initial disconnected state.

 The on and off switch with a horizontal arrangement of the transmission mechanism (Fig. 2) also occurs, except that the dielectric rods 4 do not move the movable contacts 2 of the vacuum chambers 1 directly, but through the intermediate two-arm levers 15.

 If there are stops 16 of the second shoulders of the pivoting levers (Fig. 3a), the switching process also occurs until the gap between the contacts of the arcing chambers is 2-3 mm. At this moment, the second shoulders of the levers 5 abut against the fixed stops 16 (Fig. 3b). In this case, the second shoulders of the levers act as balancers, the midpoints of which are the stops 16. The kinetic energy of the motion of the moving contacts passes into the potential energy of the springs of the compression mechanisms, compressing them (Fig. 3c). The speed of the moving contacts is effectively extinguished without loss of energy, and when the contacts touch, it has the required permissible value of 1 m / s. This allows you to increase the average speed of movement of the moving contacts and reduce the response time of the switch. The exact location of the stops should be calculated for each particular switch based on the parameters of the switch and the transmission mechanism. After closing the contacts, the drive device 3 compresses the spring of the contact pressing mechanism 8 and locks the switch mechanism in the on position (Fig. 3d).

 In the presence, in addition to the main, additional stops of the second shoulders of the rotary levers, the device operates as follows (Fig. 4). In the initial state of the switch “off” (Fig. 4a), the dielectric rod 4 abuts against an additional stop 18, and the spring 21 is compressed using the upper stops 22. In this case, the second arm of the lever 5 is located between the stops 16 and 17. When the switch is turned on, the spring 21 expands by rotating the two-arm lever 5 around the hinge 11 (point C in Fig. 4a). The reduced masses of the two-arm levers 5 and the straps 9 connected to them acquire kinetic energy, which, when the second arm of the lever 5 is abutted against the stop 17, transforms into the energy of motion of the dielectric rod 4 and movable contact 2 (Fig. 4b). When this occurs, the second shoulder of the lever 5 is rotated around the stop 17 (point C in Fig. 4b), which is the midpoint of the balancer, which transmits the accelerating force of the spring 21 to the movable contact 2.

 After the compression spring 21 is fully unclenched, resting against the lower stops 22, the two-arm lever 5 continues to rotate under the action of inertia forces and the drive device around the hinge 6 (Fig. 4c). At the moment when the gap between the contacts of the interrupter chamber 1 is 2-3 mm, the second shoulder of the lever 5 abuts against the fixed stop 16. In this case, the second shoulder of the lever 5 acts as a balancer, the middle point of which is the stop 16 (Fig. 4d). The kinetic energy of the movable contact 2 and the dielectric rod 4 passes into the potential energy of the spring 21, pressing it to the lower limiters 22. The speed of the movable contact 2 is effectively extinguished.

 After closing the contacts, the continued impact of the drive device 3 leads to a further rotation of the lever 5 around the hinge 11 (point C in Fig. 4e). This compresses the contact spring 21 even more. Turning on is completed by locking the drive unit (fixing the on position of the switch).

 The circuit breaker is turned off in the reverse order and also ends by fixing the disconnected position of the circuit breaker so that the compression spring 21 remains in a compressed state. In this case, the drive device can be made with two mechanical locks (latches) or with a kinematic latch with two dead positions, for example, a crank-articulated mechanism or a pivot-link four-link with dead end positions.

 Thus, the present invention improves the performance of the circuit breaker and reduce the power of the drive device. The invention can be used in vacuum circuit breakers of low mass, with increased speed, which allows them to be used in complexes BAVR (high-speed emergency switching on the reserve) and in switchboards of general purpose, because increased performance reduces the arc wear of contacts and extends the life of the most expensive circuit breaker elements - vacuum interrupter chambers. The invention can be used in circuit breakers with both a vertical arrangement of the transmission mechanism and a horizontal one. Switches with a vertical layout are designed for installation in switchgear cabinets at substations when replacing outdated and obsolete oil and electromagnetic switches. The design fits into any roll-out element of existing switchgear cabinets. The horizontal circuit-breaker design is suitable for two-tier switchgear cubicles.

Sources of information:
1. Vacuum circuit breakers type VVE-M-10-20. Technical description and operating instructions INLA. 674152. 009 Maintenance, p. 8.

 2. Auto 1457010, MKI4 H 01 H 33/66, 11.02.87, (prototype).

Claims (3)

 1. A high-voltage vacuum circuit breaker containing 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 pinching 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, and the axis of symmetry of the dielectric rods and spring contact clamping mechanisms are located in one oskosti articulated-lever mechanism, characterized in that the rotational axis of the swivel arms are connected to the frame via spring mechanisms bias the contacts, the second lever arm pivotally coupled with the dielectric rods and the bracket consists of two parts.  2. The switch according to claim 1, characterized in that each pivot arm has a second shoulder stop located between the dielectric rod and the spring contact clamping mechanism.  3. The switch according to claim 2, characterized in that each pivot arm has two additional stops, one of which is located symmetrically to the main one, the second is located on the axis of the dielectric traction, the drive device has the ability to fix the on and off positions of the switch, and the spring contact pressing mechanism has the ability to work in compression and tension.

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