RU2138092C1 - Vacuum switch and its operating process (design versions) - Google Patents

Abstract

FIELD: electrical engineering; remote control of low-, medium-, and high-voltage circuits. SUBSTANCE: switch has case, vacuum arc chute accommodating fixed and movable contacts, contact pressure and movable-contact opening springs mounted on arc chute shaft; opening spring is supported on one end by case and on other end, by parts rigidly coupled with movable contact; both springs are held at movable-contact potential. One more design version of switch is proposed as an alternative. Opening spring is held compressed only up to moment when contact members are brought in touch and as soon as switch is closed, operating mechanism components are locked by means of lower pawl; switch opening command is sent at any moment of ON- or OFF- operation. In second version, upper pawl is unlocked by force and movement of reset control spring. EFFECT: reduced power requirement of operating mechanism, improved speed of response and serviceability. 4 cl, 4 dwg

Description

 The invention relates to electrical engineering, namely, electrical switching apparatus engineering, in particular to vacuum circuit breakers, and can find application in electrical circuits of low, medium and high voltage AC for their remote control.

 Known vacuum switch (A. S. of the USSR N 1683087, M. Cl H 01 H 33/66, 1989), a vacuum switch (patent of the Russian Federation N 2040814, M. Cl H 01 H 33/66, 1993), a vacuum switch ( RF patent N 2040815, M. Cl H 01 H 33/66, 1993), a vacuum circuit breaker (RF patent N 2040816, M. Cl H 01 H 33/66, 1993). Their design is distinguished by the location of the vacuum interrupter chamber next to the drive mechanism, which has a large mass, large dimensions, several movable joints of parts with each other, with inevitable backlashes between them. All this reduces the speed of the circuit breaker, increases the bounce of contacts when turned on, increases their burning and wear, reduces the life and reliability of the circuit breaker.

 Known pneumatic actuator for high-voltage switching devices, containing a piston with a rod mounted in a cylinder with radial holes located around a circle in which balls are installed with a gap, and a cam, in the form of a sleeve with two internal cones, mounted with axial movement on the outer surface, and is spring-loaded by a preload spring to the cylinder, an additional driven bush with a bevel of the outer surface from the end face facing the piston is fixed to the rod and spring-loaded inside. At one end, the spring rests on the base plate, and the other on the protruding inner surface of the sleeve.

 To return the piston with the rod to the off position, both of the above springs act as disconnecting springs (A.S. USSR N 907615, M. Cl H 01 H 33/32, 1980).

 A disadvantage of the known pneumatic actuator is that the drive mechanism and the locking of the movable contact operate in a sealed cylinder on compressed gas. In order to maintain sealing, this mechanism must not be lubricated, since lubricant vapors break the tightness.

 As a result, increased friction appears in the mechanism, as a result of which its operation will be unreliable. This will ultimately lead to a decrease in the service life of the circuit breaker and a decrease in the speed of tripping.

 At the same time, both disconnecting springs are made behind the insulator and are not under the potential of movable contact, this leads to an increase in the mass of insulators, especially moving masses, as a result of which one latch with spherical movable elements does not provide accelerated disconnection with an increase in the moving mass.

 Known high-voltage vacuum three-pole switch with simultaneous opening of the contacts of the poles, containing control levers of the movable contacts of the poles of the poles connected to the shaft of the switch by a traction system and additional levers, a fixing unit holding the switch in the on position, and the fixing unit is made in the form of two coaxially arranged and identical to each other to each other of clamps that are not mechanically connected to the drive containing the free trip mechanism, each clamp is made in the form of a sleeve with dimensions the spring-loaded element inside it, having the shape of a body of revolution (cylinder), the end surface of which is in contact with the axis of the pole rod is made spherical with a recess in the form of a truncated cone, in which an additionally inserted ball is mounted for rotation around its axis, the ends of the axis of the pole rod are installed in the groove of the control lever of the movable contact of the corresponding pole with the possibility of reciprocating movement and contact with the spring-loaded clamp element during movement olyusnoy thrust output providing a spring-loaded latch member from a state included rigid fixation position when disconnected and its entry to the state when the rigid fixing (the Russian Federation patent N 2079918, M.Kl H 01 H 33/66, 1995).

 A disadvantage of the known high-voltage vacuum three-pole circuit breaker is that the design and arrangement of the trip spring does not provide the necessary trip speed and reduce the bounce-wear of the contacts due to the hinge assemblies in which backlash occurs.

 One fixing unit in the form of a ball latch in the pole does not provide the necessary shut-off speed even with a decrease in its moving mass.

 A high-voltage vacuum circuit breaker is known, in which circuit breaker contacts, a drive mechanism and a movable contact fixation are located in the same vacuum chamber. This mechanism has one spring, which is used as a switching spring and at the same time as a spring of contact preload of the movable contact to the stationary one. In the off position, it is compressed and together with the movable contact, its position is fixed by a latch with spherical movable elements. The lock is removed from the locked position by one electromagnet covering the vacuum chamber, and the circuit breaker is opened, the contacts are opened and the spring is cocked by the second electromagnet also covering the vacuum chamber (A.S. USSR N 645219, M. Cl H 01 H 33/66, 1976 )

 The disadvantages of the known high-voltage vacuum circuit breaker is that the mechanism for driving and fixing the movable contact operates in a deep vacuum, in the one in which the contacts operate. To preserve the vacuum, this mechanism cannot be lubricated, since the lubricants break the deep vacuum. As a result, increased friction appears in the mechanism, as a result of which its operation will be unreliable, and its performance will decrease. The force of the pressure spring is overcome throughout the entire course of the movable contact, with a useless increase in force to the end of the return stroke of the contact, therefore the required work performed by the power drive is unreasonably overestimated. Since this work is performed in the process of turning off the circuit breaker, its quick response to shutdown is great. The advantages of the circuit breaker in the form of small dimensions do not compensate for the listed disadvantages.

 The main task to be solved by the claimed vacuum circuit breaker, the method of its operation and their options is to increase efficiency, i.e., increase the reliability of the circuit breaker, increase its service life by reducing the wear of mechanical parts, increasing the time to develop the contact surface and working without contact bounce , increase the speed of shutdown while maintaining small dimensions.

 The only technical results achieved in the implementation of the claimed group of inventions are a reduction in the power of the actuators for turning the power of the latter from the current transformer on and off, an increase in the breaker switching speed with a decrease in the moving mass, eliminating contact bounce when turned on, and reliable control logic.

 These technical results are achieved by the fact that in the known vacuum circuit breaker containing a vacuum interrupter chamber in which a stationary, movable contact is located in the evacuated shell, the movable contact fixation unit in the “On” position is made in the form of a latch with spherical movable elements in the form of balls, a spring preload for pressing the movable contact to the fixed in the "On" position. According to the invention, the vacuum circuit breaker comprises a vacuum arcing chamber with movable and fixed contacts, disconnection and contact pressing springs, an insulator and a power drive. The disconnecting spring of the movable contact is located on the axis of the vacuum interrupter chamber, with one end resting on the housing, the other on parts rigidly connected to the movable contact and located under its potential, which reduces the mass of the insulator, especially moving masses. In this design of the switch, hinge assemblies are excluded, in which when switching on and off, the backlashes are selected in opposite directions and contribute to an increase in contact bounce when turned on. The structural arrangement of the trip spring eliminates the alternating force on the insulator, resulting in reduced wear and tear, the likelihood of contact bounce, increases the speed of the circuit breaker, i.e. its speed.

 In the mechanism for fixing the movable contact, a second (lower) latch has been introduced mainly also using spherical movable elements. In this design of the switch, the second (lower) latch allows you to increase the shutdown speed while reducing the mass of the insulator, especially the moving mass of the structural elements of the switch.

 In the first embodiment, the design of the vacuum circuit breaker for unlocking the upper latch used in the control mechanism lever mechanism. It consists of two direct levers in the middle part, pivotally connected to each other and located perpendicular to the axis of symmetry of the upper latch, while the first lever is pivotally supported at one end of the switch housing, and the second end is movably connected to the upper latch housing, the second lever interacts with one end with the actuator tripping the circuit breaker, and the second end is movably connected to the upper latch lock. To the first lever of the lever mechanism is also connected a damper for the return stroke of the movable contact.

 This allows you to include it in the work with a minimum increase in the mass of moving parts. The lever disconnect mechanism itself provides a reduction in stroke to reduce the power of the actuator shutdown mechanism with the possibility of its power supply from a current transformer.

 The specified technical result is achieved by the fact that in the known method of operation of the vacuum circuit breaker at the moment the circuit breaker is turned on after the locking ring of the spherical movable elements of the latch, the movable contact is moved by the power drive until it closes with the fixed contact, and the contact pressing and disconnecting springs are compressed (A.S. USSR 645219 M. Cl H 01 H 33/66, 1976).

 According to the invention, the method of operation of the first embodiment of the vacuum circuit breaker provides that the release spring is compressed only until the contacts come into contact, and upon completion of the activation, the position of the elements of the lower latch control mechanism is fixed. The command to open the circuit breaker is given at any time during the on or on position of the circuit breaker, for which the control mechanism to open the circuit breaker releases the fixed position of the upper latch through the second lever of the lever mechanism and the movable contact returns the movable contact to the open position, and the lower latch is released from the fixed position to the end of the return stroke of the movable contact by touching the lower latch lock with one of the parts rigidly connected to the movable contact the act and the subsequent course of this part.

 Due to the limitation of compression of the disconnection spring, the drive power is reduced, contact bounce is eliminated when the circuit breaker is turned on, the wear of mechanical parts is reduced, since there is no alternating force, and removing the lower latch from the locked position by the reverse stroke of the contact provides reliable logic of the control mechanism, as a result which increases the efficiency of the switch.

 This allows you to turn on the switch with a minimum increase in the mass of moving parts.

 These technical results are achieved by the fact that in the known vacuum circuit breaker containing a vacuum arcing chamber in which a stationary, movable contact is located in the evacuated shell, the movable contact fixation unit in the “Disconnected” position is made in the form of a latch with spherical movable elements of four balls, a spring preload for preloading the movable contact to the stationary in the "On" position (A.S. USSR N 645219, M. Cl H 01 H 33/66, 1976).

 According to the invention, in a second embodiment, the vacuum circuit breaker comprises a vacuum arrester with movable and fixed contacts, a trip and contact spring, an insulator and a power drive. The disconnecting spring of the movable contact is located on the axis of the vacuum interrupter chamber with one end resting on the housing, the other on the parts rigidly connected to the movable contact and located under its potential, which allows to reduce the mass of the insulator, especially moving masses. In this design of the switch, hinge assemblies are excluded, in which, when switching on and off, the backlashes are selected in opposite directions, contribute to an increase in contact bounce when turned on. The structural arrangement of the tripping spring eliminates the alternating force on the insulator, resulting in reduced wear, the likelihood of contact bounce, and an increased tripping speed, i.e. its speed.

 In the mechanism for fixing the movable contact, a second (lower) latch has been introduced mainly also using spherical movable elements. In this design of the switch, the second (lower) latch allows you to increase the shutdown speed while reducing the mass of the insulator, especially the moving mass of the structural elements of the switch.

 In the second embodiment of the design of the vacuum circuit breaker for unlocking the upper latch, at least one control spring, an emphasis, a return spring and a third latch are introduced as part of the control mechanism, the locking element of which interacts with the right end of the second direct lever and with the actuator of the switch, and the left the end is movably connected to the upper latch lock, while the first lever is pivotally supported at one end by the switch housing, and the second end is movably connected to the latch housing top, to the first lever of the lever mechanism is also connected a damper for the return stroke of the movable contact.

 The specified technical result is achieved by the fact that in the known method of operation of the vacuum circuit breaker at the moment of turning on the circuit breaker after closing the spherical movable elements of the latch with the locking ring, the movable contact is moved by the power actuator until it closes with the fixed contact, and the contact pressing and disconnecting springs are compressed (A.S. USSR N 645219 M. Cl H 01 H 33/66, 1976).

 According to the invention, the method of operation of the second version of the vacuum circuit breaker also provides that the disconnection spring is compressed only until the contacts come into contact, and upon completion of switching on, the position of the elements of the lower latch control mechanism is fixed, a command to open the circuit breaker is given at any time during the switching process or on position of the switch, the control mechanism for opening the circuit breaker through the second lever of the lever mechanism, the upper latch is released from the fixed position Nia cocked force and motion control spring, which is pre-cocked in contact breaker trip phase focusing and fixed in this position, the third latch, the latter on command to the circuit breaker free feed control action to the actuator, the trip spring returns the movable contact to the open position; the lower latch is released from the fixed position at the end of the return stroke of the movable contact by touching the lock of the lower latch with one of the parts rigidly connected with the movable contact and the subsequent stroke of this part.

 Due to the limitation of compression of the trip spring, the forces are reduced, the drive power is reduced, contact bounce is eliminated when the circuit breaker is turned on, and the wear of mechanical parts is reduced, there is no alternating force, and the removal of the lower latch from the fixed position by the reverse stroke of the contact provides reliable logic for the operation of the control mechanism, which increases the efficiency of the switch. At the same time, the mechanical work spent on removing the locking element of the third latch from a fixed position is much less than the mechanical work spent shifting the upper latch lock to release the spherical movable elements. Therefore, the required power of the actuator in the second embodiment is much less than the power of the actuator in the first embodiment and, accordingly, its speed is much higher, and therefore operability.

 The analysis of the level carried out by the applicant technically made it possible to establish that there are no analogues that are characterized by sets of features identical to all the features of the claimed vacuum circuit breaker and its operation method and their variants. Therefore, each of the claimed inventions meets the condition of patentability "novelty."

 Search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the prototypes of each claimed invention have shown that they do not follow explicitly from the prior art.

 From the prior art determined by the applicant, the influence of the transformations provided for by the essential features of each of the claimed inventions on the achievement of the indicated technical result has not been revealed. Therefore, each of the claimed inventions meets the condition of patentability "inventive step".

 In the present application for the grant of a patent, the requirement of unity of invention is met, since the method is designed to operate a vacuum circuit breaker.

 The claimed inventions and their variants solve the same problem - improving the circuit breaker by increasing the reliability of the circuit breaker, increasing its life due to the reduction of wear of mechanical parts, increasing the time to develop the contact surface and working with minimal contact bounce when the circuit breaker is turned on, increasing the shutdown speed while maintaining small dimensions due to the achievement of the same technical results in the implementation of the claimed group of inventions, reduction oschnosti trip actuator mechanism, with its power from the current transformer, the switch off velocity increasing with decreasing movable mass, reduced contact bounce when switched on, the logic reliable mechanism.

 In FIG. 1 shows the relative position of the nodes and elements of the vacuum circuit breaker. In FIG. 2 shows the control mechanism of a vacuum circuit breaker with a contact pressing unit and a latch unit in the “Disconnected” switch position and in the “On” switch position.

 In FIG. 3 shows a diagram of a first embodiment of a link mechanism for removing the upper latch from a locked position. In FIG. 4 shows a diagram of a second embodiment of a link mechanism for removing the upper latch from a locked position.

 The switch contains a vacuum arcing chamber 4 mounted on the insulator of the housing 3, a control mechanism with a contact pressing unit 14, a fixing unit 17, with a stem 30, an insulator 15 and a power drive 32.

 A disengaging spring is mounted on the movable contact 5 of the vacuum interrupter chamber 4, the upper end of which is supported by the middle bracket of the housing 7, and the lower end is flanged by the nut 10 of the contact contact pressing unit 14. The contact pressing spring 11, in turn, is mounted on the sleeve 12 of the contact pressing unit 14 , the upper end rests on the flange nut 10, and the lower end on the protruding part of the same sleeve 12. The screw 9 of the contact pressing unit 14 is rigidly fixed at one end to the movable contact 5 of the vacuum arcing chamber 4, and nother projecting portion abuts on the inner surface of the sleeve 12.

 The contact pressing unit (see Fig. 2) consists of a screw 9, a flange nut 10, a contact pressing spring 11, and a sleeve 12.

 The control mechanism includes a fixing unit 17 (Fig. 1), consisting of two latches of the upper - 21 and lower - 25 with spherical movable elements 23 and 27 (Fig. 2), a spring return rod 13 and a rod 30.

 The contact pressing unit 14 is separated from the fixing unit 17 by the insulator 15.

 The upper latch with spherical movable elements consists of a housing 18 with several radial holes.

 Spherical movable elements, for example balls 23, are placed in the holes. Outside they are surrounded by a lock 22 with an internal conical bevel and face down (according to the drawing), which can axially move along the latch housing 18. Between the protruding outer cylindrical part of the housing 18, the washer 19, the glass of the upper lock 20, a return spring of the upper lock 19 is installed on the outer surface of the upper latch 22 of the latch. The upper latch includes a corresponding part of the stem 30 with a groove.

 The lower latch with spherical movable elements has a similar housing 29 with several radial holes. Spherical movable elements, balls 27 are placed in the holes. Outside they are covered by a lower lock 25 with an internal conical bevel and facing upwards (according to the drawing), which can axially move along the latch body 29. A return spring of the lower lock 26 is installed between the protruding part of the lower lock 25 and the cup 28. A plate 24 is installed between the lower part of the latch housing 18 of the upper and upper parts of the lower latch housing 29. The lower latch includes the corresponding part of the stem 30 with a groove.

 The housing of the lower latch 29 with its lower protruding part and the cup 28 rest on the lower bracket of the housing 31.

 The control mechanism also includes a linkage assembly.

 A first embodiment of the link mechanism is shown in FIG. 3 It includes the first lever 33 and the second lever 34 located perpendicular to the axis of the rod 30.

 In the middle part, these levers 33 and 34 are pivotally connected to each other by an axis 35. The first lever 33 at one end pivotally rests on the insulator of the switch housing 3, and at the other end interacts with the rod 36 of the damper 37 and is movably connected to the latch housing of the upper 18. The second lever 34 at one end interacts with the rod 41 of the actuator 42, and the second end is movably connected to lock top 22 latches 21.

 The second version of the design of the lever mechanism (Fig. 4) also includes straight levers 33 and 34 located perpendicular to the axis of the rod 30. In the middle part, these levers 33 and 34 are also pivotally connected to each other by an axis 35. The first lever 33 at one end pivotally rests on the insulator of the housing 3, and at the other end interacts with the rod 36 of the damper 37.

 The second lever 34 at one end interacts with the locking element 43 of the third latch, is connected to the control spring 39, interacts with the stop 38, and the other end is movably connected to the lock by the upper 22 of the latch.

 The third latch additionally introduced into the design of the control mechanism has a locking element 43, a return spring 40 is attached to the locking element at one end, and the other is attached to the insulator of the switch housing 3 at the other end. The perpendicular end of the locking element 43 of the third latch interacts with the rod 41 of the actuator 42.

 In turn, the actuator 42, the spring 39 is controlled and the emphasis 38 is rigidly attached to the insulator of the switch housing 3.

 The method of operation of the switch according to the first embodiment is as follows: in the off position of the switch, i.e. with open contacts in the vacuum interrupter chamber 4, the movable contact 5 with the screw 9, the trip spring 8 is pressed to the lower (according to the drawing) position (Fig. 2). The rod 30 spring return 13, is also pressed into the lower position. The spherical movable elements 23 by means of a spring 21 and a tapered bevel on the lock 22 of the upper latch are moved into the groove of the rod 30. By further moving the lock 22 downward, the spherical movable elements 23 are brought into contact with the cylindrical surface of the lock 22 of the upper latch and are thus fixed in the groove. The insulator 15 through the return spring 13 of the rod 30 is also pressed into the lower position. The lower latch with spherical movable elements in this state of the switch is in the unlocked position. It corresponds to the end stop of the latch housing of the upper 18 in the plate 24, its movement of the lower lock 25 to the lower position, compression of the return spring of the lower lock 26 and the exit of the spherical movable elements 27 outward relative to the axis of the rod 30.

 When a command is issued to “Turn on” the circuit breaker, the circuit breaker circuitry (not shown in the drawings) supplies electric current from the external source to the power drive 32.

 As a result of this, the rod 30 of the actuator 32 moves upward and through the spherical movable elements 23 of the upper latch moves the upper latch, the insulator 15, the washers 16 and 19.

 The pre-compression force of the spring 8 of the contact pressure 11 is higher than the compression force of the trip spring 8. Therefore, in the initial phase of the movement of the rod 30, the screw 9 with the movable contact 5, the insulator 15 are moved, the shut-off spring 8 and the contact pressure spring 11 are compressed.

 After the movable contact 5 touches the fixed contact located inside the vacuum interrupter chamber 4, the further movement of the movable contact 5 with the screw 9 and the compression of the disconnection spring 8 stops. The actuator 32 continues to move the upper latch, as a result, the screw 9 moves away from the stop in the sleeve 12 and the pressure of the contact pressing spring 11 through the flange nut 10, the sleeves 12, the screw 9 on the movable contact 5. At the end of the stroke of the rod 30 of the actuator 32, the control mechanism comes into the state shown in FIG. 2 (on position).

 In this case, the lower groove of the rod 30 approaches the spherical movable elements 27. The pressure of the return spring of the lower 26 on the lower lock 25, and the conical surface made on it, the spherical movable elements 27 are moved into the groove and the axial movement of the lower 25 lock is fixed in it. This ensures that the force is transmitted from the spring 11 through the sleeve 12, the flange nut 10, the insulator 15, the spherical movable elements 23 and 27, the conical surfaces on the stem 30, the screw 9, to the movable contact 5. Thus, the necessary contact pressing of the contact is carried out.

 After that, the power is removed from the power drive 32, and the switch remains in the on position.

 Upon receipt of a command to turn off the switch, the automation unit (not shown in the drawings) supplies power to the actuator 42. Its rod 41 through the lever 34 moves the upper lock 22 with the glass 20 relative to the latch housing of the upper 18 up.

 The conical surface of the rod 30 under the action of the spring force of the contact pressing 11 pushes the spherical movable elements 23 out. After that, the latch housing of the upper 18, the washers 16 and 19, the insulator 15, the sleeve 12 under the action of the spring 11 move down.

 When the spring 11 extends to the size of the initial compression, and the screw 9 rests against the sleeve 12 with the head, the disconnection spring 8 tears the movable contact 5 from the stationary one and moves it down. At the end of the stroke of the movable contact 5, the lower end of the upper latch housing abuts against the plate 24 and moves the lower latch lock 25 down through it. Released spherical movable elements 27 are mixed outward, and the rod 30 under the action of the return spring 13 is returned to the lower position. In this position of the rod 30, the upper latch again enters the closed position between the rod 30 and the latch housing of the upper 18. This process proceeds as described above.

 If, in the process of turning on the circuit breaker, the control unit detects the need to turn off the circuit breaker before the end of the on-cycle, it gives a command to turn off the circuit breaker immediately. When this is done, the lever 34 removes the upper latch from the locked position and further processes occur as described above. The difference lies in the fact that the stem 30 of the actuator 32 remains in its highest position. After the transients in the power drive 32 pass, it will be disconnected and return to the off state. After that, the rod 30 will return to the lower position and will engage with the housing of the upper latch 18 as described above.

 The method of operation of the vacuum circuit breaker according to the second embodiment is as follows.

 In the off position of the switch, i.e. when the contacts are open in the vacuum interrupter chamber 4, the movable electrode 5 with screw 9, the trip spring 8 is pressed to the lower (according to the drawing) position (Fig. 2). The stem 30 spring return 13 is also pressed into the lower position. Spherical movable elements 23 with the help of the return spring of the upper lock 21 and the conical bevel on the lock 22 of the upper latch are moved to the groove of the rod 30.

 By further moving the lock 22 down, the spherical movable elements 23 are brought into contact with the cylindrical surface of the upper lock 22 and are thus fixed in the groove of the rod 30. The insulator 15 is also pressed into the lower position through the spring return of the rod 13. The lower latch 25 with spherical movable elements in this state of the switch is in the unlocked position. It corresponds to the stop of the end face of the latch housing of the upper 18 in the plate 24, its movement of the lower lock 25 to the lower position, compression of the return spring of the lower lock 26 and the exit of the spherical movable elements 27 to the outside relative to the rod 30.

 When a command is issued to “Turn on” the circuit breaker, the circuit breaker circuitry (not shown in the drawings) supplies electric current from the external source to the power drive 32.

 As a result of this, the rod 30 of the actuator 32 moves upward and moves the upper latch 25, the insulator 15, the washers 16 and 19 through the spherical movable elements 23 of the upper latch. The pre-compression force of the contact pressing spring 11 is higher than the compression force of the disconnecting spring 8. Therefore in the initial phase of the movement of the rod 30, a screw 9 with a movable contact 5, an insulator 15 are moved, a trip spring 8 and a contact pressing spring 11 are compressed.

 After the movable contact 5 touches the fixed contact located inside the vacuum interrupter chamber 4, the further movement of the movable contact 5 with the screw 9 and the compression of the disconnection spring 8 is stopped. The actuator 32 continues to move the upper latch, as a result, the screw 9 moves away from the stop in the sleeve 12 and the pressure of the contact pressing spring 11 through the flange nut 10, the sleeve 12, the screw 9 on the movable contact 5.

 At the end of the stroke of the stem 30 of the actuator 32, the control mechanism comes into the state shown in FIG. 2 (on position).

 In this case, the lower groove of the rod 30 approaches the spherical movable elements 27. By the pressure of the return spring of the lock 26 on the lower lock 25 and the conical surface made on it, the spherical movable elements 27 move into the groove, and are fixed in it by further axial movement of the lower 25 lock. This ensures the transfer of force from the spring 11 through the sleeve 12, the flange nut 10, the insulator 15, the spherical movable elements 23 and 27, the conical surface on the rod 30, the screw 9 on the movable contact 5.

 Thus, the necessary contact clicking on the contact is carried out.

 When giving the command to turn on (Fig. 4) the left end of the lever lever 33 of the lever mechanism is mixed upward, through the axis 35 the left end of the second lever 34 also moves upward, cocking the spring 39. The rotation of the second lever around the axis under the action of the spring is prevented by the locking element 43 of the third latch, on which the second lever 34 rests.

 After the above operations, the power is removed from the power drive 32, and the switch remains in the on position.

 Upon receipt of a command to turn off the switch, the unit automatically (not shown in the drawings) supplies power to the actuator 42, which acts on the third latch, causing the latter to rotate around its axis. Turning, the third latch releases the second lever 34, which rotates around the axis 35 under the influence of the spring 39. In this case, the lever 34 moves the lock of the upper latch 22 with its left end and thereby releases the spherically movable elements of the upper latch 23.

 The conical surface of the rod 30 under the action of the force of the spring 11 pushes the spherical movable elements 23 out. After that, the latch housing of the upper 18, the washers 16 and 19, the insulator 15, the sleeve 12 under the action of the contact pressing spring 11 move down. When the spring 11 extends to the size of the initial compression, the screw 9 rests its head against the sleeve 12, the disconnection spring 8 tears the movable contact 5 from the stationary and moves it down.

 At the end of the stroke of the movable contact 5, the lower end of the upper latch body 18 rests on the plate 24 and moves the lower latch lock 25 down through it. Released spherical movable elements 27 are moved outward, and the rod 30 under the action of the return spring 13 is returned to the lower position. In this position of the rod 30, the upper latch again enters the closed position between the rod 30 and the latch housing of the upper 18. This process proceeds as described above. The left end of the lever 33 and the axis 35 under the influence of the trip spring are moved down. The lever 34, bumping on the stop 38, rotates around the axis 35. In this case, the right end of the lever 34 moves upward and engages with the locking element 43 of the third latch, which returns to its initial state under the influence of the return spring 40, at the same time, a partial spring cocking 39.

 If, in the process of turning on the circuit breaker, the control unit detects the need to turn off the circuit breaker before the end of the on-cycle, it gives a command to turn off the circuit breaker immediately. When this is done, the lever 34 of the upper latch is removed from the fixed position and further processes occur as described above.

 The difference lies in the fact that the stem 30 of the actuator 32 remains in its highest position. After the transients in the power drive 32 pass, it will be disconnected and return to the off state. After that, the rod 30 will return to the lower position and will engage with the housing of the upper latch 18 as described above. In addition to the indicated technical result achieved and the advantages of the claimed objects, their additional advantages should also be noted - such as the compactness of the poles and the ability to independently control each pole both on and off, which opens the possibility of turning the poles on and off according to a given algorithm, as well as the possibility of manufacturing one, two, three or more pole switches (as needed).

Thus, the above information shows that when implementing the claimed group of inventions, the following conditions are met:
- means embodying the invention in their implementation are intended for use in industry, namely: in the energy industry, for switching electrical circuits of low, medium and high AC voltage;
- for the claimed inventions in the form as described in the independent claims, the possibility of their implementation is confirmed.

 Drawings were developed, a prototype of a vacuum circuit breaker was manufactured at the Ufa State Production Enterprise Elektroapparat in 1997. Tests have yielded positive results. UGPP "Elektroapparat" began in 1998 to manufacture serial production of this product. Therefore, the claimed invention meets the condition of patentability "industrial applicability".

Literature
1. RU, patent, 1683087, cl. H 01 H 33/66, 1989.

 2. RU, patent, 2040814, cl. H 01 H 33/66, 1993.

 3. RU, patent, 2040815, cl. H 01 H 33/66, 1993.

 4. RU, patent, 2040816, cl. H 01 H 33/66, 1993.

 5. SU, copyright certificate, 907615, cl. H 01 H 33/32, 1980.

 6. RU, patent, 2079918, cl. H 01 H 33/66, 1995.

 7. SU, copyright certificate, 645219, cl. H 01 H 33/66, 1976.

Claims (4)

 1. A vacuum circuit breaker comprising a housing, a vacuum arrester with fixed and movable contacts, a power drive, contact pressing and disconnecting springs, a control mechanism and a movable contact fixing mechanism made in the form of a latch using spherical movable elements, characterized in that in a vacuum only the fixed and movable contacts are located in the arcing chamber, the spring of disconnecting the movable contact is located on the axis of the vacuum arcing chamber, with one end being supported is mounted on the housing, another on parts rigidly connected to the movable contact, and is under its potential, a lower (second) latch is inserted into the mechanism of fixation of the movable contact, mainly also using spherical movable elements, a lever is inserted into the control mechanism of the upper (first) latch a mechanism consisting of two direct levers in the middle part articulated to each other and located perpendicular to the axis of symmetry of the upper latch, while the first lever is pivotally supported at one end on the housing of Tell, and a second end movably connected to the housing upper latch, a second arm one end interacts with the actuating mechanism of the circuit breaker, and a second end movably connected with the upper lock latch to the first arm link mechanism also connected the damper return stroke of the movable electrode.  2. The method of operation of the vacuum circuit breaker, which provides that at the moment of turning on the circuit breaker after closing the spherical movable elements of the upper latch with a power actuator, the movable contact is moved until it closes with the fixed contact, and the contact pressing and disconnecting springs are compressed, characterized in that the disconnection spring is only compressed until the contacts come into contact, and upon completion of switching on, fix the position of the elements of the lower latch control mechanism, the command to open the circuit breaker is given at any time during the on or off position of the circuit breaker, for which the control mechanism for opening the circuit breaker through the second lever of the lever mechanism releases the fixed position of the upper latch and releases the movable contact to the open position with the disconnection spring, and release the lower latch from the locked position at the end of the return contact of the movable contact lock the bottom latch with one of the parts rigidly connected with the movable contact and the subsequent stroke of this part.  3. A vacuum circuit breaker comprising a housing, a vacuum interrupter chamber, fixed and movable contacts, a power drive, a contact pressing and disconnecting spring, a control mechanism and a movable contact fixing mechanism made in the form of a latch using spherical movable elements, characterized in that in a vacuum only fixed and movable contacts are located in the arcing chamber, the spring of disconnecting the movable contact is located on the axis of the vacuum arcing chamber, at the same time it supports I’m on the housing, the other on the parts rigidly connected with the movable contact, and is under its potential, a lower (second) latch is inserted into the mechanism of fixation of the movable contact, mainly also using spherical movable elements, a lever mechanism is introduced into the control mechanism of the upper (first) latch consisting of two direct levers in the middle part pivotally connected to each other and located perpendicular to the axis of symmetry of the upper latch, at least one control spring, an emphasis, a spring are additionally introduced on return and the third latch, the locking element of which interacts with the right end of the second direct lever and with the actuator of the switch, and the left end is movably connected with the lock of the upper latch, while the first lever is pivotally supported at one end of the switch housing, and the second end is movably connected with the upper latch housing, the movable contact return damper is also connected to the first lever of the linkage mechanism.  4. The method of operation of the vacuum circuit breaker, which provides that at the moment of turning on the circuit breaker after closing the spherical movable elements of the upper latch with a power drive, the movable contact is moved until it closes with the fixed contact, and the contact pressing and disconnecting springs are compressed, characterized in that only the compression spring is compressed until the contacts come into contact, and upon completion of switching on, fix the position of the elements of the lower latch control mechanism, the command to open the circuit breaker is given at any time during the on or off position of the circuit breaker, for which the control mechanism for opening the circuit breaker through the second lever of the lever mechanism releases the upper latch from the locked position by force and movement of the cocked control spring, which is pre-cocked in the phase of the circuit breaker contact with the stop and lock in this position element of the third latch, the last command to open the circuit breaker is released by applying a control action to the actuator The mechanism, the release spring returns the movable contact to the open position, the lower latch is released from the fixed position at the end of the return stroke of the movable contact by touching the lower latch lock with one of the parts rigidly connected to the movable contact and the subsequent stroke of this part.

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