JP4975319B2 - Vacuum circuit breaker - Google Patents

Description

  The present invention relates to a vacuum circuit breaker using an electromagnetic actuator as an operation mechanism that can improve opening and closing characteristics.

  As shown in FIG. 5, this type of conventional vacuum circuit breaker includes a breaking part 1a for cutting off current from the upper part of the figure, a wipe spring part 1b for applying a contact load when the breaking part 1a is closed, and a breaking part 1a at the lowermost part of the figure. An operation mechanism portion 1c for opening / closing is arranged and configured. In FIG. 5, a closed state is shown on the right side of the figure, and an open state is shown on the left side of the figure.

  The blocking part 1 a is provided with a vacuum valve 5 having a pair of contacts 3 and 4 that can be contacted and separated within the vacuum insulating container 2. An upper conductor 6 is fixed to the fixed side of the vacuum valve 5. Further, a lower conductor 7 is provided on the movable side of the vacuum valve 5 and is connected to an insulating operation rod 8 that is movable in the axial direction.

  The wipe spring portion 1 b is provided with a wipe spring folder 10 that houses a wipe spring 9 connected to the insulating operation rod 8. The wipe spring 9 applies a contact load when the pair of contacts 3 and 4 are in contact with each other. The wipe spring folder 10 is connected to a non-magnetic operating rod 11 described later.

  The operation mechanism unit 1c is provided with an electromagnetic actuator 12 that generates an operation force during an opening / closing operation. The electromagnetic actuator 12 includes a yoke 13 for forming a magnetic path, a magnetic armature 14 provided so as to move in the yoke 13, a permanent magnet 15 for moving or holding the closed circuit of the armature 14, and an outer periphery of the permanent magnet 15 The closed coil 16 and the open coil 17 are disposed on the armature 14, the operation rod 11 is fixed to the armature 14 and penetrates the yoke 13, and the non-magnetic stopper plate 18 that closes the opening in the lower portion of the yoke 13 is illustrated. The electromagnetic actuator 12 is fixed to a lower fixing member 19, and an open spring 20 that is biased so that the operating rod 11 moves in the opening direction is provided in the lower fixing member 19 (for example, (See Patent Document 1).

  Next, the opening / closing operation of such a vacuum circuit breaker will be described.

  When the closing coil 16 is excited in the open circuit state, the attractive force increases between the armature 14 and the yoke 13, and the armature 14 is shown against the spring force biased in the opening direction of the open spring 20 and the wipe spring 9. Move in the upper closed direction. At the same time, the operating rod 11 moves in the closing direction in the upper part of the figure, and the contact points 3 and 4 come into contact with each other to enter a closing state. Thereafter, the closed coil 16 is de-energized, and the closed state is maintained by the magnetic force of the permanent magnet 15.

  On the other hand, when the open coil 17 is energized in the closed state, the attractive force between the armature 14 and the yoke 13 is reduced, and the armature 14 is opened below the figure by the spring force biased in the open direction of the open spring 20 and the wipe spring 9. Move in the direction. At the same time, the operating rod 11 moves in the opening direction in the lower part of the figure, and the contacts 3 and 4 are separated to be in an open state. Thereafter, the open coil 17 is de-energized and the open circuit state is maintained.

  The operating force during such an opening / closing operation will be described with reference to FIG.

  When the circuit is closed, the load characteristics of the vacuum circuit breaker are indicated by a one-dot chain line due to the weight of the armature 14, the operating rod 11, the movable contact 4, and the spring force of the open spring 20 and the wipe spring 9. A point-B point-C point-D point. That is, since the armature 14, the operating rod 11, the movable contact 4 and the like are moved in the closing direction from the point A in the open circuit state to the point B as the closing point where the contacts 3 and 4 come into contact, the ascending point gradually rises. From the point B to the point C, the open spring 20 and the wipe spring 9 are compressed, and the point rises rapidly. From the point C to the point D, the contact points 3 and 4 are gently raised in order to reliably hold the contact. Then, at the point D, the closed circuit state is completed.

  On the other hand, the attractive force (operation force) of the electromagnetic actuator 12 has a characteristic as indicated by a solid line that increases at an accelerated speed from the point A in the open state to the point D1 in the closed state. This is because when the armature 14 moves in the closing direction, the gap length with the yoke 13 is shortened, and the operating force is accelerated. For this reason, at the closing point, the operating force at point B1 is larger than point B. In addition, an operating force is provided to reliably hold the contacts 3 and 4 at the point C1, and the closed state is completed at the point D1 larger than the point D. Note that the movement of the armature 14 is decelerated from the point C to the point C1.

  Therefore, a necessary condition for completing the closed circuit state is that the area (energy E1) surrounded by the points A, B, B1 is larger than the area (energy E2) surrounded by the points B1, C1, and C. It becomes. As the energy E1 is larger than the energy E2, the speed of the contact 4 on the movable side (feeding point speed) increases, and welding between the contacts 3 and 4 at the time of closing can be suppressed.

The operating force at the time of opening the circuit has a characteristic as shown by a two-dot chain line, and the movable contact 4 is separated from the fixed contact 3 by the energy of the area surrounded by the points D1−C0−B0. As this energy increases, the speed at which the movable contact 4 separates from the fixed contact 3 (initial separation speed) increases, and the breaking characteristics can be improved.
JP 2002-270423 A (4th page, FIG. 1)

  The above-described conventional vacuum circuit breaker has the following problems.

  The breaking characteristics of the vacuum circuit breaker depend greatly on the initial breaking speed that improves the insulation recovery characteristic. In addition, the charging characteristics such as the pre-arc characteristic and the current carrying capacity characteristic greatly depend on the charging point speed. The vacuum circuit breaker is required to have various specification performances, and it is necessary to develop the electromagnetic actuator 12 in accordance with the load characteristics each time. All of these require a fast turn-on speed and a high initial opening speed, which makes it difficult to develop an electromagnetic actuator 12 that can handle various load characteristics.

  For this reason, there has been a demand for a vacuum circuit breaker using the electromagnetic actuator 12 that can increase the closing point speed and the initial opening speed with an easy configuration and, as a result, can improve the switching characteristics such as the breaking characteristics and the closing characteristics.

  The present invention has been made to solve the above problems, and an object thereof is to provide a vacuum circuit breaker using an electromagnetic actuator capable of improving the switching characteristics.

In order to achieve the above object, a vacuum circuit breaker according to the present invention includes an operating rod that is movably held in a direction to open and close a pair of contactable and separable contacts, an armature fixed to the operating rod, and the armature a permanent magnet closed holding the movement or path by sucking, the yoke for forming a magnetic path which is provided to surround the armature, to increase or decrease the flux in the yoke, closing coil for moving said armature And an open coil, an open spring biased to move the armature in the open direction, and the armature moved.
When make movement allowed by path is from the open circuit condition to a closed state, and a latch mechanism for temporarily blocking the movement start of the armature, the latch mechanism is less certain than the permanent magnet
A latching permanent magnet that attracts the armature with the attraction force, and a latching yoke that is provided on the latching permanent magnet and contacts and separates from the armature.

  According to the present invention, the armature that attempts to move in the closing direction is provided with the latch mechanism that temporarily prevents the movement. Therefore, the operating force of the latch mechanism is added to the attractive force of the electromagnetic actuator to move the armature. Thus, it is possible to provide a vacuum circuit breaker with improved switching characteristics such as a closing point speed between contacts and an initial opening speed.

  Embodiments of the present invention will be described below with reference to the drawings.

  First, a vacuum circuit breaker according to Embodiment 1 of the present invention will be described with reference to FIGS. FIG. 1 is a cross-sectional view showing a configuration of an electromagnetic actuator according to Embodiment 1 of the present invention, and FIG. FIG. 3 is a diagram illustrating the attractive force characteristics of the electromagnetic actuator and the load characteristics of the vacuum circuit breaker when the vacuum circuit breaker according to the first embodiment of the present invention is opened. In addition, in each figure, the same code | symbol was attached | subjected about the component similar to the past. Moreover, since the structure of a vacuum circuit breaker is the same structure as the past, the description is abbreviate | omitted.

  As shown in FIG. 1, the vacuum circuit breaker is provided with an electromagnetic actuator 12 that generates an operation force during an opening / closing operation. The electromagnetic actuator 12 includes a yoke 13 for forming a magnetic path, a magnetic armature 14 provided so as to move in the yoke 13, a permanent magnet 15 for moving or holding the closed circuit of the armature 14, and an outer periphery of the permanent magnet 15 The closed coil 16 and the open coil 17 that increase or decrease the magnetic flux in the yoke 13, the non-magnetic operating rod 11 that is fixed to the armature 14 and penetrates the yoke 13, and the non-magnetic that blocks the opening in the lower portion of the yoke 13 are illustrated. It is composed of a body stopper plate 18.

  Further, a latch mechanism 21 fixed to the stopper plate 18 side is provided between the armature 14 and the stopper plate 18. The latch mechanism 21 includes a latching permanent magnet 22 and latching yokes 23a and 23b for forming magnetic paths provided in the S pole and N pole of the permanent magnet 22. The one side surface of the latching yokes 23a and 23b is adapted to attract the armature 14 when it is in the open circuit state.

  Next, the opening / closing operation of the electromagnetic actuator 12 will be described.

  When the closed coil 16 is excited in the open circuit state, the attractive force increases between the armature 14 and the yoke 13, and the armature 14 moves in the closed circuit direction in the upper part of the figure. At the same time, the operating rod 11 moves in the closing direction in the upper part of the figure, and contacts (not shown) come into contact to enter a closed state. Thereafter, the closed coil 16 is de-energized, and the closed state is maintained by the magnetic force of the permanent magnet 15.

  On the other hand, when the open coil 17 is excited in the closed state, the attractive force between the armature 14 and the yoke 13 is reduced, and the armature 14 moves in the open direction below the figure by the spring force of an open spring (not shown). At the same time, the operating rod 11 moves in the opening direction in the lower part of the drawing, and the contacts (not shown) are separated to be in the opening state. Thereafter, the open coil 17 is de-energized and the open circuit state is maintained.

  The operation force at the time of closing in such an opening / closing operation will be described with reference to FIG.

  The load characteristics of the vacuum circuit breaker are the points A, B, and C as shown by the alternate long and short dash line due to the weight of the armature 14 and the operating rod 11 and the spring force of the open spring and wipe spring, as in the conventional case. -Characteristic passing through point D. Then, at the point D, the closed circuit state is completed.

  On the other hand, since the armature 14 is attracted by the latch mechanism 21 with respect to the attracting force (operation force) of the electromagnetic actuator 12, the operation cannot be started from the conventional point A, and the attracting force of the latch mechanism 21 is overcome. The armature 14 starts moving from the point. That is, the start of movement of the armature 14 is temporarily blocked by the latch mechanism 21.

  And it becomes a characteristic as shown with the continuous line which rises at an accelerated speed to D2 point of a closed circuit state through B2 point and C2 point. This is like adding the suction force of the latch mechanism 21 to the conventional characteristic indicated by the dotted line and moving it in parallel. Moreover, it becomes an operating force for reliably holding the contact at the point C2, and the closed state is completed at the point D2. The movement of the armature 14 is decelerated from the point C to the point C2.

  For this reason, the area (energy E3) enclosed by point A-A2 point-B2 point-B point becomes much larger than the area (energy E4) enclosed by point B2-C2 point-C, and the circuit is closed. The state can be reliably completed. By making the energy E3 larger than the energy E4, the speed of the contact on the movable side (feeding point speed) becomes much faster than before, and welding between the contacts can be suppressed.

  Note that the attractive force of the latch mechanism 21 is smaller than the attractive force of the electromagnetic actuator 12. Further, if the suction force of the latch mechanism 21 is selected according to the performance specifications of the vacuum circuit breaker, a predetermined closing point speed can be easily obtained. Furthermore, in order to increase the energizing current capacity, even if the spring force of the wipe spring is increased and the characteristics from point B to point C are increased, it can be easily handled by selecting the attractive force of the latch mechanism 21.

  Next, the operation force at the time of opening will be described with reference to FIG.

  The operating force at the time of the open circuit has characteristics as indicated by a two-dot chain line that rapidly decreases from the closed point D2 through the B01 point to the open state A0. Then, the movable contact is separated by an area (energy E5) surrounded by D2 point−C01 point−B01 point. The point D2 is larger than the conventional point D1, and as a result, the speed at which the movable contact is separated from the fixed side (initial separation speed) is increased, and the breaking characteristics can be improved.

  According to the vacuum circuit breaker of the first embodiment, the armature 14 that is about to move in the closing direction is provided with the latch mechanism 21 that temporarily prevents the armature 14 from moving by the attractive force of the latching permanent magnet 22. Therefore, the attractive force of the latch mechanism 21 is added to the attractive force of the electromagnetic actuator 12, and the armature 14 starts to move, so that the opening / closing characteristics such as the closing point speed and the initial opening speed can be improved.

  Next, a vacuum circuit breaker according to Embodiment 2 of the present invention will be described with reference to FIG. FIG. 4 is a cross-sectional view illustrating the configuration of the electromagnetic actuator according to the second embodiment of the present invention. The second embodiment is different from the first embodiment in the configuration of the latch mechanism. In FIG. 4, the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. Moreover, since the structure of a vacuum circuit breaker is the same structure as the past, the description is abbreviate | omitted.

  As shown in FIG. 4, a ball plunger 24 is provided on the yoke 13 that faces the side surface of the armature 14. The ball plunger 24 includes a movable and rotatable ball 25, a spring 26 biased so as to press the ball 25 against the armature 14, and a case 27 that exposes the tip of the ball 25 and stores the spring 26. Has been. Further, a recess 14a is provided on the side surface of the armature 14 with which the ball 25 abuts in the open circuit state.

  Therefore, in order to move the armature 14 in the closing direction, in addition to the attractive force of the electromagnetic actuator 12, the spring 26 must be compressed to remove the ball 25 from the recess 14a. That is, the movement of the armature 14 is temporarily blocked by the spring 26, and the spring force of the spring 26 is added to the attractive force of the electromagnetic actuator 12, so that the armature 14 starts moving. This spring force is smaller than the attractive force of the electromagnetic actuator 12. Further, by changing the spring force according to the performance specifications of the vacuum circuit breaker, a predetermined closing point speed and initial opening speed can be obtained.

  Here, the ball plunger 24 temporarily blocks the start of movement of the armature 14 by the spring force of the spring 26. For this reason, this ball plunger 24 is also defined as the latch mechanism used in the first embodiment for temporarily preventing the armature 14 from starting to move. Further, the suction force of the latch mechanism of the first embodiment and the spring force of the ball plunger 24 of the second embodiment are defined as the operation force of the latch mechanism.

  According to the vacuum circuit breaker of the second embodiment, the same effect as that of the first embodiment can be obtained.

  In addition, this invention is not limited to the said Example, In the range which does not deviate from the summary of invention, it can implement in various deformation | transformation. In the embodiment described above, the armature 14 is provided with the latch mechanism. However, the latch mechanism that temporarily prevents the movable member connected to the operating rod 11 from starting to move from the open state to the closed state. The opening / closing characteristics can be improved even if the is provided.

Sectional drawing which shows the structure of the electromagnetic actuator which concerns on Example 1 of this invention. The figure explaining the attraction force characteristic of the electromagnetic actuator at the time of closing of the vacuum circuit breaker concerning Example 1 of the present invention, and the load characteristic of a vacuum circuit breaker. The figure explaining the attraction force characteristic of the electromagnetic actuator at the time of circuit opening of the vacuum circuit breaker concerning Example 1 of the present invention, and the load characteristic of a vacuum circuit breaker. Sectional drawing which shows the structure of the electromagnetic actuator which concerns on Example 2 of this invention. Sectional drawing which shows the structure of a vacuum circuit breaker. The figure explaining the attraction force characteristic of the electromagnetic actuator at the time of opening and closing of the conventional vacuum circuit breaker, and the load characteristic of a vacuum circuit breaker.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a Blocking part 1b Wipe spring part 1c Operation mechanism part 2 Vacuum insulation container 3, 4 Contact 5 Vacuum valve 6 Upper conductor 7 Lower conductor 8 Insulation operation rod 9 Wipe spring 10 Wipe spring folder 11 Operation rod 12 Electromagnetic actuator 13 Yoke 14 Armature 14a Depression part 15 Permanent magnet 16 Closing coil 17 Opening coil 18 Stopper plate 19 Lower fixing member 20 Opening spring 21 Latching mechanism 22 Permanent magnets 23a and 23b for latching Latching yoke 24 Ball plunger 25 Ball 26 Spring 27 Case

Claims (1)

An operating rod held movably in a direction to open and close a pair of contactable contacts;
An armature fixed to the operating rod;
A permanent magnet that attracts the armature to move or hold the electrical circuit closed;
A yoke for forming a magnetic path provided to surround the armature;
A closed coil and an open coil for increasing and decreasing the magnetic flux in the yoke and moving the armature;
An opening spring biased so that the armature moves the circuit in the opening direction;
When make moving path by moving the armature from an open circuit condition to a closed state, and a latch mechanism for temporarily blocking the movement start of the armature,
The latch mechanism includes a permanent magnet for latch that attracts the armature with a predetermined attractive force smaller than that of the permanent magnet;
A vacuum circuit breaker comprising: a latching yoke provided on the latching permanent magnet and contacting and separating from the armature.

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