JP2019102706A - On-load tap changeover device - Google Patents

Abstract

To provide an on-load tap changeover device capable of realizing compaction of current-limit resistor and high-speed consecutive changeover, by shortening the electrification time of the current-limit resistor while restraining cost increase.SOLUTION: An on-load tap changeover device is provided with tap terminals 2, 3, thyristors SR1, SR2 connected between respective tap terminals 2, 3 and the neutral point terminal 8 of a stationary induction appliance, a thyristor SR3 connected in parallel with the thyristors SR1, SR2 and connected with the neutral point terminal 8 via a current-limit resistor 7, and a connection switch mechanism part 4. The connection switch mechanism part 4 connects the thyristor SR3, in the ON state, with the tap terminal of changeover destination, and connects the thyristor SR3, in the OFF state, with the tap terminal of changeover source.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to an on-load tap changer.

  Among the on-load tap switching devices for switching the taps of the stationary induction appliance to uninterruption, there is a type in which two main circuits and one current limiting resistance circuit are provided as switching circuits. Each circuit is provided with a switch such as a vacuum valve which is a mechanical contact and a semiconductor switch which is an electric trigger type. Examples of the semiconductor switch include self-excited switching elements such as thyristors, GTOs and IGBTs.

  Among them, the thyristor which is a semiconductor switch can be switched without setting restrictions on the number of times of switching or switching speed. Therefore, deterioration due to switch switching does not occur, and mechanical adjustment is unnecessary. Therefore, it is suitable for the on-load tap changer. For example, in the on-load tap switching device shown in FIG. 15, the main circuit having the thyristors SR1 and SR2 and the energizing switches 9 and 10 is disposed at the T1 tap terminal 2 and the T2 tap terminal 3.

  Hereinafter, the T1 tap terminal 2 is referred to as the T1 terminal 2 or the tap terminal 2, and the T2 tap terminal 3 is referred to as the T2 terminal 3 or the tap terminal 3. Also, a current limiting resistance circuit is connected to one of the two tap terminals 2 and 3. In the circuit configuration shown in FIG. 15, the current limiting resistance circuit is connected to the T2 terminal 3 side. A current limiting resistor 7 and a thyristor SR3 are connected in series to the current limiting resistance circuit.

  Switching sequence in the case of performing tap switching operation from the T1 terminal 2 side to which the current limiting resistance circuit is not connected to the T2 terminal 3 side to which the current limiting resistance circuit is connected using such a load time tap switching device Will be described with reference to FIG. In FIG. 16, the closing of the contacts is shown as ON, and the opening of the contacts is shown as OFF. The switching from the T1 terminal 2 side to the T2 terminal 3 side is abbreviated as T1 → T2 switching, and the switching from the T2 terminal 3 side to the T1 terminal 2 side is abbreviated as T2 → T1 switching.

  At the time of T1 → T2 switching, first, the thyristor SR3 is closed, the current limiting resistor 7 starts to be energized, and a circulating current flows. Subsequently, the thyristor SR1 of the switching source is opened, and immediately after the current extinction, the thyristor SR2 of the switching destination is closed. Thereafter, the thyristor SR3 is opened, and the current limiting resistor 7 is deenergized. Thereby, the T1 → T2 switching operation is completed.

  In general, in the tap switching operation using a thyristor, the thyristor is opened immediately before the current zero point in synchronization with the current phase, and is extinguished at the zero point immediately thereafter. Therefore, as described above, in the case where T1 → T2 switching is performed with the current limiting resistance not connected as the switching side as the switching source, thyristor SR3 closing of the current limiting resistance circuit → main circuit thyristor SR1 opening of the switching source The switching sequence is as follows: current (zero point) extinguishing → switching destination main circuit thyristor SR2 closing.

  In the above switching sequence, the current limiting resistor 7 starts to be energized when the thyristor SR3 of the current limiting resistor circuit is closed, and the current limiting resistor 7 is turned on when the main circuit thyristor SR2 to be switched is closed. Is commutated to the main circuit thyristor SR2 side (see the waveform diagram of FIG. 16). As described above, the time from the start of energization of the current limiting resistor 7 to the commutation to the side of the thyristor SR2 is the time of energization of the current limiting resistor 7. In a switching sequence employing a thyristor, it is possible to configure an interval of each operation in a very short time of several tens μs to several hundreds μs level. Therefore, theoretically, the energization time of the current limiting resistor 7 can be reduced to about 1 ms.

JP, 2016-225334, A

  However, it is possible to make the current conduction time of the current limiting resistor 7 about 1 ms when switching to the tap side to which the current limiting resistance circuit is connected, and the current limiting resistance circuit is not connected. When switching to the tap side, the conduction time of the current limiting resistor 7 is significantly extended. This point will be described with reference to FIG. FIG. 17 shows a switching sequence when tap switching operation is performed from the T2 terminal 3 side to which the current limiting resistance circuit is connected to the T1 terminal 2 side to which the current limiting resistance circuit is not connected.

  At the time of T2 → T2 switching, first, the thyristor SR3 is closed, the current limiting resistor 7 starts to be energized, and a circulating current flows. Subsequently, the switching source thyristor SR2 is opened, and immediately after the current extinction, the switching destination thyristor SR1 is closed. Thereafter, the thyristor SR3 is opened to extinguish the current (zero point), and the current limiting resistor 7 is deenergized. Thus, the T2-> T1 switching operation is completed.

  In the above switching sequence, after closing the main circuit thyristor SR1 of the switching destination, the thyristor SR3 of the current limiting resistance circuit is opened immediately before the current zero point, and it is not necessary to extinguish after waiting for the subsequent zero point. (See the waveform diagram of FIG. 17). That is, when switching to the tap side where the current limiting resistance circuit is not connected, it is necessary to pass the current zero point twice. Therefore, the conduction time of the current limiting resistor 7, which is the total time of this sequence, must be 0.5 cycle time or more.

  The 0.5 cycle time is 10 ms in the case of 50 Hz. That is, when switching to the tap side to which the current limiting resistance circuit was connected, it was possible to complete the conduction time to around 1 ms, but when switching to the tap side to which the current limiting resistance circuit was not connected The conduction time of the current limiting resistor 7 is about 10 times longer. Since the heat generation amount of the current limiting resistor 7 is increased by an amount corresponding to the increase in the current application time, the current limiting resistor 7 is enlarged. In addition, if the current application time of the current limiting resistor 7 becomes long, it becomes difficult to perform the tap switching operation continuously at high speed.

  As a measure to shorten the energizing time of the current limiting resistor, it is conceivable to increase the current limiting resistor and the thyristor one by one and provide the current limiting resistor and the thyristor on both the taps. However, this measure necessitates an increase in component cost and addition of a channel for the thyristor drive circuit. As a result, the cost increases, so it is not a good idea. Therefore, the problem of the embodiment of the present invention is to reduce the on-load tap switching enabling realization of downsizing and high-speed continuous switching of the current limiting resistor by shortening the current application time of the current limiting resistor while suppressing cost increase. It is in providing an apparatus.

The on-load tap switching device of the present embodiment has the following components (1) to (6).
(1) A plurality of tap terminals connected to the tap winding of the stationary induction appliance.
(2) A main circuit switch connected between each of the tap terminals and a neutral point terminal of the stationary induction device.
(3) A current limiting resistance switch connected in parallel with the main circuit switch and connected via a current limiting resistor to the neutral point terminal.
(4) A connection switch mechanism unit for connecting the current limiting resistance switch to the tap terminal.
The connection switch mechanism unit is
(5) A connection switch on the switching destination side to which the current limiting resistance switch is connected when the tap terminal to be switched is in the on state;
(6) The tap terminal serving as the switching source is provided with a connection switch on the switching source side for connecting the current limiting resistance switch when in the off state.

Circuit diagram of the first embodiment Table showing T1 → T2 switching sequence in the first embodiment A table showing a T2-> T1 switching sequence in the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment An exploded perspective view of the connection switch mechanism according to the first embodiment The top view for demonstrating T1-> T2 switching operation of the connection switch mechanism part of 1st Embodiment The top view for demonstrating T2-> T1 switching operation of the connection switch mechanism part of 1st Embodiment A circuit diagram for explaining current movement in the switching sequence of the first embodiment Circuit diagram of the second embodiment Circuit diagram of a typical on-load tap changer A table showing a switching sequence of T1 → T2 in the on-load tap changer of FIG. A table showing a switching sequence of T2 → T1 in the on-load tap changer of FIG.

First Embodiment
[Constitution]
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a circuit diagram of the on-load tap changer using a thyristor. The same components as those of the switching circuit of the on-load tap switching device shown in FIG.

[Circuit configuration]
As shown in FIG. 1, T1 terminal 2 and T2 terminal 3 are drawn out from each end of the tap winding 1 of the stationary induction battery, respectively. A main circuit corresponding to the tap terminals 2 and 3 and a current limiting resistance circuit are connected to the tap terminals 2 and 3 as switching circuits of the on-load tap switching device. Each circuit is connected to the neutral point terminal 8 of the stationary induction machine. A thyristor SR1 and a conduction switch 9 are provided in the main circuit on the T1 terminal 2 side, and a thyristor SR2 and a conduction switch 10 are provided in the main circuit on the T2 terminal 3 side. Thyristor SR3 and current limiting resistor 7 are provided in the current limiting resistance circuit.

  The thyristor SR1 is a main circuit switch connected between the T1 terminal 2 and the neutral point terminal 8, and the thyristor SR2 is a main circuit switch connected between the T2 terminal 3 and the neutral point terminal 8 . The thyristor SR3 is a current limiting resistance switch connected in parallel with the thyristors SR1 and SR2 and connected between the neutral point terminal 8 and the current limiting resistor 7. Although the number of thyristors connected in the thyristors SR1 to SR3 can be appropriately selected, in the example shown in FIG. 1, a bi-directional thyristor which can connect two thyristors in antiparallel to allow a bidirectional current to flow is used. ing.

  The energizing switches 9 and 10 are switches that cause the entire current to flow during steady operation. When switching the T1 terminal 2 and the T2 terminal 3, the thyristors SR <b> 1 to SR <b> 3 shut off the voltage current during energization. Therefore, the interrupting performance of the energizing switches 9 and 10 is sufficient to interrupt the voltage of the internal resistances of the thyristors SR1 to SR3, and does not require the ability to interrupt the large voltage current during energization.

[Connection switch in connection switch mechanism]
In the thyristor SR3, a connection switch mechanism 4 having connection switches 11 and 12 is provided at the end opposite to the current limiting resistor 7 side. The connection switch 11 connects the T1 terminal 2 to the thyristor SR3, and the connection switch 12 connects the T2 terminal 3 to the thyristor SR3.

  In the connection switch mechanism unit 4, one of the connection switches 11 and 12 is the connection switch on the switching destination side, and the other is the connection switch on the switching source side. The connection switch on the switching destination side is a switch for connecting the thyristor SR3 when the tap terminal 2 or 3 which is the switching destination is in the on state. On the other hand, the connection switch on the switching source side is a switch for connecting the thyristor SR3 when the tap terminal 3 or 2 serving as the switching source is in the OFF state.

  Referring to the switching sequence shown in FIGS. 2 and 3, either the on / off state of the thyristor SR3 or the connection switch 11 or 12 of the connection switch mechanism 4 becomes the connection switch on the switching destination side, and the other switches It will be described whether the connection switch on the original side is to be used. In FIG. 2 and FIG. 3, the closing of the switch is indicated as ON, and the opening of the switch is indicated as OFF.

  As shown in FIG. 2, when T1 terminal 2 is the switching source and T2 terminal 3 is the switching destination T1 → T2 switching, connection switch 11 is the connection switch on the switching source side and connection switch 12 is the switching destination side. It becomes a connection switch. At the time of T1 → T2 switching, the connection switch 11 on the switching source side is turned on after the thyristor SR3 shifts from on to off, and connects the thyristor SR3 in the off state to the T1 terminal 2 of the switching source. Therefore, at the time when the T1 → T2 switching is completed, the thyristor SR3 is in a state of being connected to the switching source T1 terminal 2 by the connection switch 11 on the switching source side.

  Further, at the time of T1 → T2 switching, the connection switch 12 on the switching destination side continues to connect the thyristor SR3 in the on state to the T2 terminal 3 on the switching destination. That is, the connection switch 12 maintains the on state when the thyristor SR3 is in the on state. Therefore, in the middle of T1 → T2 switching, the thyristor SR3 is connected to the T2 terminal 3 of the switching destination by the connection switch 12 on the switching destination side.

  As shown in FIG. 3, when T2 terminal 3 is the switching source and T1 terminal 2 is the switching destination T2 → T1 switching, connection switch 11 is the connection switch on the switching destination side and connection switch 12 is the switching source side. It becomes a connection switch. At the time of T2-> T1 switching, the connection switch 11 on the switching destination side continues to connect the thyristor SR3 in the on state to the T1 terminal 2 at the switching destination. That is, the connection switch 11 maintains the on state when the thyristor SR3 is in the on state. Therefore, the thyristor SR3 is in a state of being connected to the T1 terminal 2 of the switching destination by the connection switch 11 on the switching destination side in the middle of the T2 → T1 switching.

  Further, at the time of T2 → T1 switching, the connection switch 12 on the switching source side is turned on after the thyristor SR3 shifts from on to off, and the thyristor SR3 in the off state is connected to the T2 terminal 3 of the switching source Do. Therefore, at the point in time when the T2-> T1 switching is completed, the thyristor SR3 is in a state of being connected to the switching source T2 terminal 3 by the connection switch 12.

  As described above, the connection switch mechanism unit 4 connects the tap terminals 2 or 3 as the switching destination to the thyristor SR3 in the on state by switching the connection switches 11 and 12 on and off. Further, the connection switch mechanism unit 4 switches the on / off state of the connection switches 11 and 12 so that the thyristor SR3 in the off state is always deenergized when the tap terminal 3 or 2 of the switching source is completed, ie tap switching is completed. Is connected to the tap side.

[Component of connection switch mechanism]
The components of the connection switch mechanism 4 will be described with reference to FIGS. In the connection switch mechanism unit 4, the moved component performs a reversible operation at the time of T 1 → T 2 switching and at the time of T 2 → T 1 switching.

  As shown in FIG. 4, the connection switch 12 is composed of a conductor 19 and a contact 20, and the connection switch 11 is composed of a conductor 21 and a contact 22. The conductors 19 and 21 are vertically elongated bar-like members. The contact members 20 and 22 have stacked plate-like members, and are divided into upper and lower parts every five sheets. The contact 20 is provided to face the conductor 19, and the contact 22 is provided to face the conductor 21. The conductor 19 is located on the back side of FIG. 4, and the conductor 21 is located on the front side of FIG.

  The connection switch mechanism 4 is provided with a switching shaft 13 connected to a drive source (not shown). With the switching shaft 13 at the center side of the connection switch mechanism 4, the conductors 19 and 21 are disposed closer to the center than the contacts 20 and 22, that is, on the inner side. The conductors 19 and 21 are configured to perform an in-out operation linearly in the radial direction by the forward and reverse rotation of the switching shaft 13.

  That is, the conductors 19 and 21 are movable in the vertical direction of the current-carrying surface by performing the in-out operation. Such movement of the conductors 19 and 21 causes the upper and lower contacts of the contacts 20 and 22 to respectively contact and separate with the conductors 19 and 21 so that the connection switches 12 and 11 open and close. In addition, since the conductors 19 and 21 are arranged inside the contacts 20 and 22, regarding the movement of the conductors 19 and 21, the operation in which the conductors 19 and 21 retract inside and separate from the contacts 20 and 22 The retracting operation, and the operation in which the conductors 19 and 21 move outward and contact the contacts 20 and 22 will be referred to as an advancing operation.

  The switching pressing cam 14 is attached to the switching shaft 13 as a member for transmitting the rotational force to the conductors 19 and 21. A switching lever 17 is provided adjacent to the switching pressing cam 14. A biasing spring 18 is attached to the switching lever 17. The drive cam 15 is installed so as to sandwich the switching pressing cam 14 and the switching lever 17 from above and below. The drive cam 15 is rotatably supported on the switching shaft 13.

  A spring holder 16 is installed so as to sandwich the drive cam 15 from above and below. A lower support plate 23 is disposed adjacent to the lower spring holder 16 and an upper support plate 24 is disposed adjacent to the upper spring holder 16. The support plates 23 and 24 are respectively fixed to a housing (not shown) which is a fixing portion of the switching mechanism main body of the connection switches 11 and 12.

  As shown in FIG. 5, the upper sides of the contacts 20, 22 are both connected to the thyristor SR3. The lower side of the contact 22 is connected to the T1 terminal 2, and the lower side of the contact 20 is connected to the T2 terminal 3, respectively. Accordingly, the thyristor SR3 is connected to the T1 terminal 2 side or the T2 terminal 3 side by the closing operation of the connection switches 11 and 12 of the connection switch mechanism unit 4 (in terms of the conductors 19 and 21).

  As shown in FIG. 6, the conductors 19 and 21 are disposed so as to be vertically sandwiched between the lower support plate 23 and the upper support plate 24. In FIG. 6, the conductor 19 is located on the left side, and the conductor 21 is located on the right side. The conductors 19 and 21 are provided with support shafts 19a and 21a, arm shafts 19b and 21b, and arms 19c and 21c, respectively.

  The arm 19c and the arm 21c are rotatably supported by the arm shafts 19b and 21b on a casing (not shown) which is a fixing portion of the switching mechanism main body of the connection switches 11 and 12. Reference numeral 17 a in FIG. 6 denotes an engagement portion of the switching lever 17. The engagement portion 17 a is slidably installed in the engagement groove 15 a of the drive cam 15.

  As shown in FIGS. 7 and 8, the drive cam 15 is provided with an engagement groove 15a and a guide groove 15b, and is supported by a bearing 25 (shown in FIG. 8). At the ends of the conductors 19 and 21 opposite to the contacts 20 and 22, drive rollers 19 d and 21 d are rotatably supported. The drive rollers 19 d and 21 d are inserted into the guide groove 15 b of the drive cam 15.

  As shown in FIG. 9, on the switching pressing cam 14, a protrusion 14b for switching to the T1 terminal 2 side and a protrusion 14a for switching to the T2 terminal 3 side are formed to face each other. Reference numeral 27 in FIG. 9 is a fulcrum shaft of the switching lever 17. The fulcrum shaft 27 is supported between the upper support plate 24 and the lower support plate 23.

  The spring holder 16 is rotatably supported by the drive shaft 13 via a spring holder bearing 26. A spring hooking protrusion 16 a is formed on the spring holder 16. A biasing spring 18 is hooked between the spring hooking projection 16a of the spring holder 16 and the spring hooking projection 17b of the switching lever 17 (shown in FIGS. 9 and 10).

  As shown in FIG. 10, the switching lever 17 is provided with engaging portions 17a (also shown in FIG. 6) facing up and down, and spring hooking protrusions 17b are provided in the vicinity of each engaging portion 17a. . The biasing spring 18 is attached to the spring hooking protrusion 17b. The biasing spring 18 is configured to exert a biasing force in the left-right switching direction centering on the switching neutral point.

  At the end of the switching lever 17 on the switching shaft 13 side, an interference projection 17 c is formed which protrudes toward the switching shaft 13. The interference projection 17c is disposed between the two projections 14a and 14b (shown in FIG. 9) of the switching pressing cam 14. When the protrusions 14a and 14b press the interference protrusion 17c by the forward and reverse rotation of the drive shaft 13, the switching lever 17 rotates. When the switching lever 17 rotates, the engaging portion 17a of the switching lever 17 slides on the engaging groove 15a of the drive cam 15, and the drive cam 15 rotates.

  The rotation of the drive cam 15 causes the conductors 19 and 21 to move in and out in the radial direction. That is, when the switching lever 17 is rotated by the forward and reverse rotation of the drive shaft 13, the drive cam 15 receives a biasing force in the switching direction by the biasing spring 18. As described above, since the biasing force acts in the left-right switching direction centering on the switching neutral point by the biasing spring 18, the direction in which the driving cam 15 receives the biasing force is reversed at the switching neutral point of the switching lever 17. ing.

[Operation of connection switch mechanism section]
Hereinafter, the operation of the connection switch mechanism unit 4 at the time of T1 → T2 switching ([1] to [6]) will be described using FIG.

  In the T1 energized state shown in [1] of FIG. 11, the projection 14b of the switching pressing cam 14 pushes the interference projection 17c of the switching lever 17 completely. At this time, the conductor 19 shorts the contact 20 by the drive roller 19 d of the conductor 19 guided by the guide groove 15 b of the drive cam 15 and the drive roller 21 a of the conductor 21, and the conductor 21 separates from the contact 22 ing. The drive cam 15 is biased to the switching end via the switching lever 17 by the biasing spring 18. This biasing force brings about a contact force between the contact or conductor 19 and the contactor 2 in the T1 conductive state.

  When shifting to the state of [2] in FIG. 11, the switching shaft 13 rotates counterclockwise to reach the neutral point. Although the switching pressure cam 14 rotates with the rotation of the switching shaft 13, the projection 14 a does not reach the pressure angle of the switching lever 17 against the interference projection 17 c. Therefore, the switching lever 17 does not operate, there is no change in the short-circuited state between the conductor 19 and the contact 20 and the separated state between the conductor 21 and the contact 22, and the connection switches 11 and 12 do not operate.

  In the state shown in [3] of FIG. 11, the switching shaft 13 further rotates in the counterclockwise direction. Therefore, the projection 14 a of the switching pressing cam starts contacting the interference projection 17 c of the switching lever 17 and pushes this. Accordingly, the drive cam 15 starts to rotate clockwise. When the drive cam 15 rotates, the drive roller 19d of the conductor 19 starts moving along the guide groove 15b, and the conductor 19 starts the withdrawal operation from the contact 20.

  When the switching shaft 13 rotates in the counterclockwise direction until the state of [4] in FIG. 11, the projection 14 a of the switching pressing cam 14 further pushes the interference projection 17 c of the switching lever 17. As a result, the rotation of the drive cam 15 advances, and the drive roller 19d of the conductor 19 further moves along the guide groove 15b, and the conductor 19 to be retracted starts to separate from the contact 20.

  In the state shown in [5] of FIG. 11, the switching shaft 13 further rotates in the counterclockwise direction, whereby the projection 14a of the switching pressing cam further pushes the interference projection 17c of the switching lever 17, and the rotation of the driving cam 15 Continues. Therefore, the drive roller 21d of the conductor 21 moves along the guide groove 15b to advance the conductor 21 to the outside, and the conductor 21 contacts the contact 22 to short circuit.

  As shown in [6] of FIG. 11, when the T2 current-carrying state is reached, the projection 14a of the switching pressing cam pushes the interference projection 17c of the switching lever 17 completely. Therefore, the conductor 21 shorts the contacts 22 up and down, and the conductor 19 completely separates from the contacts 20. In this state, the drive cam 15 is biased at the switching end via the switching lever 17 by the biasing spring 18. The biasing force brings about a contact force between the contacts on the T2 current conduction side, that is, a contact force between the conductor 21 and the contact 22.

  Subsequently, the switching operation of the connection switch mechanism unit 4 at the time of T2 → T1 switching ([6] to [10], [1]) will be described using FIG. The T2 energized state shown in [6] of FIG. 12 is the same as that of the previous stage.

  When shifting to the state of [7] in FIG. 12, the switching shaft 13 rotates clockwise and reaches the neutral point. Although the switching pressure cam 14 rotates with the rotation of the switching shaft 13, the projection 14 b does not reach the pressure angle with respect to the interference projection 17 c of the switching lever 17. Therefore, the switching lever 17 does not operate, there is no change in the separated state of the conductor 19 and the contact 20 and the short state between the conductor 21 and the contact 22, and the connection switches 11 and 12 do not operate.

  In the state shown in [8] of FIG. 12, the switching shaft 13 further rotates in the clockwise direction. Therefore, the projection 14b of the switching pressing cam starts contact with the interference projection 17c of the switching lever 17, and pushes this. Accordingly, the drive cam 15 starts to rotate in the counterclockwise direction. When the drive cam 15 rotates, the drive roller 21d of the conductor 21 starts moving along the guide groove 15b, and the conductor 21 starts the retraction operation from the contact 22.

  When the switching shaft 13 rotates in the clockwise direction until the state of [9] in FIG. 12, the projection 14 b of the switching pressing cam 14 further pushes the interference projection 17 c of the switching lever 17. Thereby, the rotation of the drive cam 15 advances, and the drive roller 21d of the conductor 21 further moves along the guide groove 15b, and the conductor 21 to be retracted starts to separate from the contact 22.

  In the state shown in [10] of FIG. 12, when the switching shaft 13 further rotates in the clockwise direction, the projection 14 b of the switching pressing cam further pushes the interference projection 17 c of the switching lever 17 and the rotation of the driving cam 15 Continue. Therefore, the drive roller 19d of the conductor 19 moves along the guide groove 15b, the conductor 19 advances, and the conductor 19 contacts the contact 20 to short circuit.

  When the T1 energization state shown in [1] of FIG. 12 is reached, the projection 14b of the switching pressing cam pushes the interference projection 17c of the switching lever 17 completely. Therefore, the conductor 19 shorts the contact 20 up and down, and the conductor 21 completely separates from the contact 22. In this state, the drive cam 15 is biased at the switching end via the switching lever 17 by the biasing spring 18. This biasing force brings about a contact force between the contacts on the T1 current conduction side, that is, a contact force between the conductor 19 and the contact 20.

[Current transfer]
The current movement (shown by thick lines) in the switching sequence shown in FIGS. 2 and 3 will be described with reference to FIG. [1] to [10] in FIG. 13 correspond to [1] to [10] in the diagram showing the operation of the connection switch mechanism shown in FIGS. 11 and 12.

  The current movement in the switching sequence of T1 → T2 switching will be described. In the case of T1 → T2 switching, the connection switch 12 on the T2 terminal 3 side is the connection switch 12 of the switching destination, and the connection switch 11 on the T1 terminal 2 side is the connection switch 11 of the switching source.

[1] In the T1 energized state, all current flows in the energizing switch 9 on the T1 terminal 2 side.
[2] The thyristors SR1 and SR2 are both open, the thyristor SR3 is closed, the connection switch 12 of the switching destination is on, and the connection switch 11 of the switching source is off. Therefore, all current flows to the T2 terminal 3 side via the current limiting resistor 7.

  When switching from T1 terminal 2 to T2 terminal 3, if terminals 2 and 3 are simultaneously turned ON, current does not flow to neutral point terminal 8 and it becomes circulating current flowing from T1 terminal 2 side to T2 terminal 3 side, and temperature rise There is a possibility that the burnout of the winding due to and the winding deformation due to the electromagnetic mechanical force may occur. Therefore, it was stated in the previous stage that “thyristor SR1 and SR2 are both open and thyristor SR3 is closed”, but more precisely, closing of thyristor SR1 is maintained (T1 → T2, so thyristor SR2 First, the thyristor SR3 is closed.

  Then, the current flowing in the switching circuit is the current flowing from the tap winding 1 to the neutral point terminal 8 through the T1 terminal 2 and the thyristor SR1, and the tap winding 1 to the T2 terminal 3, the thyristor SR3 and the current limiting resistor 7 And the current flowing to the neutral point terminal 8 in proportion to the resistance ratio. The presence of the current limiting resistor 7 significantly suppresses the circulating current flowing to the T2 terminal 3 via the T1 terminal 2, the thyristor SR1, and the thyristor SR3.

  After closing the thyristor SR3, the thyristor SR1 is opened. Then, current flows only from the tap winding 1 to the neutral point terminal 8 through the T 2 terminal 3, the thyristor SR 3 and the current limiting resistor 7.

[3] By closing the thyristor SR2, almost all the current is commutated from the thyristor SR3 to the thyristor SR2. That is, when thyristor SR2 is closed, current limiting resistor 7 is connected to thyristor SR3, so most of the current flows from tap winding 1 to neutral point terminal 8 through T2 terminal 3 and thyristor SR2. Flow.

  However, there is also a current flowing from the tap winding 1 to the neutral point terminal 8 via the T 2 terminal 3, the thyristor SR 3 and the current limiting resistor 7. By closing the thyristor SR2 after closing the thyristor SR2, current flows only from the tap winding 1 to the neutral point terminal N through the T2 terminal 3 and the thyristor SR2.

[4] [5] Similar to the above [3], all the current is supplied to the thyristor SR2.
[6] The energizing switch 10 on the T2 terminal 3 side is closed, a total current flows through the energizing switch 10, and the T2 is energized.

  Next, current transfer in the switching sequence of T2 → T1 will be described. In the case of T2 → T1, the connection switch 11 on the T1 terminal 2 side is the connection switch 11 of the switching destination, and the connection switch 12 on the T2 terminal 3 side is the connection switch 12 of the switching source. The following [7] to [10] are the reversible operations of [2] to [5].

[6] In the T2 energized state, the entire current flows in the energizing switch 10 on the T2 terminal 3 side.
[7] The thyristors SR1 and SR2 are both open, the thyristor SR3 is closed, the connection switch 11 of the switching destination is on, and the connection switch 12 of the switching source is off. Therefore, all current flows to the T1 terminal 2 side via the current limiting resistor 7. The operation order of the thyristors SR1 to SR3 is as follows.

  First, the thyristor SR3 is closed while maintaining the closing of the thyristor SR2 (the thyristor SR1 is in an open state since T2 → T1). Then, the current flowing in the switching circuit is the current flowing from the tap winding 1 to the neutral point terminal 8 through the T2 terminal 3 and the thyristor SR2, and the tap winding 1 to the T1 terminal 2, the thyristor SR3 and the current limiting resistor 7 And the current flowing to the neutral point terminal 8 in proportion to the resistance ratio. After closing the thyristor SR3, the thyristor SR1 is opened. Then, current flows only from the tap winding 1 to the neutral point terminal 8 through the T 2 terminal 3, the thyristor SR 3 and the current limiting resistor 7.

[8] When the thyristor SR1 is closed, almost all the current is commutated from the thyristor SR3 to the thyristor SR1. That is, when thyristor SR1 is closed, current limiting resistor 7 is connected to thyristor SR3. Therefore, most of the current is from tap winding 1 to neutral point terminal 8 through T1 terminal 2 and thyristor SR1. Flow.

  However, there is also a current flowing from the tap winding 1 to the neutral point terminal 8 via the T1 terminal 2, the thyristor SR3 and the current limiting resistor 7. By closing the thyristor SR1 after closing the thyristor SR1, current flows only from the tap winding 1 to the neutral point terminal N through the T1 terminal 2 and the thyristor SR1.

[9] [10] Similar to the above [8], all current is supplied to the thyristor SR1.
[1] The energizing switch 9 on the T1 tap end 2 side is closed, a total current flows through the energizing switch 9, and the T1 is energized.

[effect]
In a first embodiment, the tap terminals 2, 3 connected to the tap winding 1 of the stationary induction appliance;
Thyristors SR1 and SR2 connected between the tap terminals 2 and 3 and the neutral point terminal 8;
A thyristor SR3 connected in parallel with the thyristors SR1 and SR2 and connected via a current limiting resistor 7 to the neutral point terminal 8;
A connection switch mechanism 4 for connecting the thyristor SR3 to the tap terminals 2 and 3;
The connection switch mechanism 4
A connection switch 11 or 12 on the switching destination side for connecting the thyristor SR3 in the ON state to the tap terminal 2 or 3 to be the switching destination;
And a connection switch 12 or 11 on the switching source side for connecting the thyristor SR3 in the off state to the tap terminal 3 or 2 serving as the switching source. For this reason, the following effects are exhibited.

  At the time of T1 → T2 switching, the switching sequence is as follows: thyristor SR3 closing of current limiting resistance side → thyristor of SR1 opening of switching source → current (zero point) extinguishment → thyristor SR2 closing of switching destination. In this switching sequence, the current limiting resistor 7 starts to be energized when the thyristor SR3 of the current limiting resistor circuit is closed, and the current limiting resistor 7 is supplied with current when the main circuit thyristor SR2 to be switched is closed. It commutates to the main circuit thyristor SR2 side (see the waveform diagram of FIG. 2).

  At the time of T2 → T1 switching, the switching sequence is as follows: thyristor SR3 closing of current limiting resistance side → opening of thyristor SR2 of switching source → current (zero point) extinguishing → thyristor SR1 closing of switching destination. In this switching sequence, the current limiting resistor 7 starts to be energized when the thyristor SR3 of the current limiting resistor circuit is closed, and the current limiting resistor 7 is supplied with current when the main circuit thyristor SR1 to be switched is closed. It commutates to the main circuit thyristor SR1 side (see the waveform diagram of FIG. 3).

  That is, in the first embodiment, the thyristor SR3 is turned ON immediately before the current of the tap winding 1 becomes 0A, and the connection switch 11 or 12 is turned OFF when the current of the tap winding 1 becomes 0A. It is possible to turn on the thyristor of the other main circuit immediately after that. Just before the current of the tap winding 1 becomes 0 A, it can be obtained from the periodically changing current waveform.

  For example, in the case of drawing a waveform in which the current value rises and then falls after the current has once reached 0 A, the time when the current value becomes 1 A in the current waveform that tends to fall can be made just before 0 A. . Similarly, in the case of drawing a waveform in which the current value drops and then rises after the current has once reached 0 A, the time when the current value becomes -1 A in the current waveform that tends to rise is made just before it becomes 0 A. Can. The current waveform of the tap winding 1 may be measured by a current measuring device.

  In the above first embodiment, the connection switch mechanism unit 4 switches on / off of the connection switch 11 or 12 instead of fixedly connecting the current limiting resistance circuit to one of the two tap terminals 2 and 3. Thus, the tap terminal 2 (or 3) to be switched can always be connected to the thyristor SR3 in the on state. Therefore, it is possible to energize the switching destination tap terminals 2 and 3 from the current limiting resistor circuit in the middle of the switching operation.

  Further, the connection switch mechanism unit 4 is turned off by switching on and off of the connection switches 11 and 12 instead of fixing and connecting the thyristor SR3 in the off state to either one of the tap terminals 2 or 3. The thyristor SR3 in the state can always be connected to the tap terminals 2 and 3 of the switching source. Therefore, the connection state of the current limiting resistor circuit with respect to the terminals 2 and 3 can be switched, and the tap switching operation is always switching operation from the tap side to which the current limiting resistor circuit is not connected.

  Therefore, it is possible to always perform the tap switching operation from the terminal 2 or 3 where the current limiting resistor 7 is not connected to the terminal 3 or 2 where the current limiting resistor 7 is connected. At this time, both switching sequences are reversible, and as described above, in the switching sequence employing a thyristor, the interval between each operation can be configured at a level of several tens of microseconds to several hundreds of microseconds. Therefore, it is possible to make the current supply time of the current limiting resistor 7, which is the total time of the intervals, about 1 ms.

  In the first embodiment described above, the connection switch mechanism unit 4 switches the connection switches 11 and 12 so that switching to the tap side where the current limiting resistor circuit is not connected is not performed. As a result, after closing the main circuit thyristor SR1 or SR2 to be switched, it is not necessary to open the thyristor SR3 just before the current zero point and wait for the subsequent zero point to extinguish the arc. That is, it is not necessary to pass the current zero twice until the current limiting resistor 7 is ended, and the current flowing time of the current limiting resistor 7 does not reach 0.5 cycle time.

  Moreover, in the first embodiment, since the energizing switches 9 and 10 through which all current flows in steady operation are provided corresponding to the tap terminals 2 and 3, the thyristors SR1 and SR2 are not energized in steady operation. Therefore, the heat capacities of the thyristors SR1 and SR2 can be minimized. Therefore, it is possible to shorten the conduction time of the thyristors SR1 and SR2 on the main circuit side. The heat generation amount of the current limiting resistor 7 can be suppressed by shortening the current conduction time, and the current limiting resistor 7 can be miniaturized.

  In the first embodiment, the switching current flows through the energizing switch 9 or 10 during steady operation, and the thyristors SR1 to SR3 are used only when switching operation is performed. Therefore, the energizing switches 9 and 10 may cut off the voltage of the internal resistance of the thyristors SR1 to SR3. Therefore, no blocking device such as a vacuum valve or a switch gear is required as the energizing switches 9 and 10, and it is sufficient to use a simple mechanical switch.

  For the power of such a mechanical switch, for example, a drive source of a tap selector connected to the on-load tap changer can be used. As a result, even when the mechanical switch and its operating mechanism are taken into consideration, it is possible to provide an on-load tap changer which is smaller than the conventional one.

  As described above, in the first embodiment, the thyristor and the drive circuit thereof, and the connection switch mechanism including the addition of relatively simple mechanical components without adding the current limiting resistance, specifically, the connection switches 11 and 12 Only by adding the part 4, the current limiting resistor 7 can be miniaturized. Moreover, since the energization time of the current limiting resistor 7 can be shortened, the tap switching operation can be performed continuously at high speed.

  The connection switch mechanism 4 further includes conductors 19 and 21 movable in the vertical direction with respect to the current-carrying surface, and contacts 20 and 21 capable of coming into contact with and separating from the conductors 19 and 20 by movement of the conductors 19 and 20. ing. Therefore, it is optimal as a load tap changer for gas without oil lubrication. Furthermore, the connection switch mechanism unit 4 can stably carry out a reversible switching sequence by providing the biasing spring 18 that exerts biasing force in the left-right switching direction centering on the switching neutral point. .

[Other embodiments]
(1) In the above embodiment, the contact switching of the thyristors SR1 to SR3 and the connection switches 11 and 12 includes a CPU and a memory, and a control device (not shown) configured by a computer or a dedicated electronic circuit operated by a predetermined program. It takes place in The control device is configured to automatically open and close the contacts by detecting the state of the tap changer or the tap selector, but may be manually operated by the operator via the control device. The above-described embodiment can also be understood as a method of controlling the on-load tap switching device according to the above switching sequence.

(2) As a specific embodiment, for example, multiple bidirectional thyristors may be connected in series to improve breakdown voltage. In addition, self-excitation semiconductor switching such as GTO or IGBT may be used as a semiconductor switch other than a thyristor. Even in the case where a self-excitation element such as GTO or IGBT is used, the switching operation is performed in the shortest time in the vicinity where the current value obtained from the current value flowing through the tap winding 1 becomes OA. The same effect as that of the embodiment can be obtained.

(3) In another embodiment shown in FIG. 14, vacuum valves Vm1, Vm2 and Vr3 are used instead of the thyristors SR1 to SR3. In all the blocking circuits, the energizing switches 9 and 10, the thyristors SR1 and SR2 on the main circuit side, the vacuum valves Vm1 and Vm2, and the other end of the current limiting resistor 7 are connected to the neutral point terminal 8.

  In such an embodiment, even in the on-load tap changer using a vacuum valve, the current conduction time of the current limiting resistor 7 can be suppressed, which can contribute to the miniaturization of the current limiting resistor 7. . In addition, by shortening the energization time of the current limiting resistor 7, it is possible to realize high-speed continuous switching.

(4) In the connection switch mechanism unit 4, although the connection switches 11 and 12 are provided independently, only one connection switch is provided, and the thyristor SR3 in the on state is connected to the tap terminal to be switched with this connection switch. And the off-state thyristor SR3 may be connected to the tap terminal which is the switching source.

(5) While certain embodiments of the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These embodiments can be implemented in other various forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the invention described in the claims and the equivalents thereof as well as included in the scope and the gist of the invention.

DESCRIPTION OF SYMBOLS 1 ... Tap winding 2 ... T1 tap terminal 3 ... T2 tap terminal 4 ... Connection switch mechanism part 7 ... Current limiting resistor 8 ... Neutral point terminal 9, 10 ... Energizing switch 11, 12 ... Connection switch 13 ... Switching shaft 14 ... Switching pressing cams 14a, 14b ... Pressing projections 15 ... Driving cams 15a ... Engagement grooves 15b ... Guide grooves 16 ... Spring holders 16a, 17a ... Spring hooking projections 17 ... Switching levers 18 ... Energizing springs 19, 21 ... Conductors 19a, 21a ... Support shafts 19b, 21b ... Arm shafts 19c, 21c ... Arms 19d, 21d ... Drive rollers 20, 22 ... Contacts 23 ... Lower support plates 24 ... Upper support plates 25 ... Drive cam bearings 26 ... Spring holder bearings SR1, SR2, SR3 ... Thyristor Vm1, Vm2, Vr3 ... Vacuum valve

Claims (7)

A plurality of tap terminals connected to the tap winding of the stationary induction appliance,
A main circuit switch connected between each of the tap terminals and a neutral point terminal of the stationary induction appliance;
A current limiting resistance switch connected in parallel with the main circuit switch and connected via a current limiting resistor to the neutral point terminal;
A connection switch mechanism unit for connecting the current limiting resistance switch to the tap terminal;
The connection switch mechanism unit is
A connection switch on the switching destination side which connects the current limiting resistance switch when the switch terminal is in the on state to the tap terminal to be switched to;
An on-load tap switching device comprising: a connection source on a switching source side for connecting the current limiting resistance switch in an off state to the tap terminal as a switching source;   The on-load tap switching device according to claim 1, wherein the connection switch on the switching destination side is switched on after the connection switch on the switching source side is switched off.   The on-load tap changer according to claim 1 or 2, wherein the main circuit is provided with an energizing switch through which all current flows in steady operation.   The on-load tap changer according to any one of claims 1 to 3, wherein the main circuit switch and the current limiting resistance switch are semiconductor switches.   The on-load tap changer according to any one of claims 1 to 3, wherein the main circuit switch and the current limiting resistance switch are vacuum valves. The connection switch mechanism unit is
A conductor movable in the vertical direction with respect to the current-carrying surface,
A contactor capable of coming into contact with or separating from the conductor by movement of the conductor;
The on-load tap changer according to any one of claims 1 to 5, comprising:   The on-load tap changer according to any one of claims 1 to 6, wherein the connection switch mechanism section includes an urging spring which exerts an urging force in a left / right switching direction centering on a switching neutral point.

Images