JPH053729B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a load tap switching device using a thyristor as a current switching element.

[Conventional technology]

FIG. 3 is a circuit diagram of a conventional on-load tap switching device. In the figure, 1 and 2 are transformer input terminals,
3 is the primary winding of the transformer, 4 is the secondary winding of the transformer, 5 is voltage tap A on one side of the secondary winding 4 of the transformer, and 6 is voltage tap B on the other side of the secondary winding 4 of the transformer. ,7
10 are thyristors Th ₁ to _{Th 4} , 11 is a thyristor switch A consisting of thyristors 7 and 8 connected in anti-parallel, and 12 is a thyristor switch A consisting of thyristors 9 and 10 connected in anti-parallel. B, 13 is thyristor switch A
11 movable contacts, 14 thyristor switch B1
2 movable contact, 15 is thyristor switch A11
and a current-carrying contact that bypasses the thyristor switch B12; 16 is an auxiliary contact that operates in conjunction with the current-carrying contact 15 and generates a signal when the current-carrying contact 15 is not in contact with the voltage tap of the transformer secondary winding 4; 17 is an auxiliary contact for the thyristors 7 and 8; , 9 and 10, and 18 and 19 are transformer output terminals. In addition, when the current-carrying contact 15 is not in contact with any voltage tap, the movable contact 13 and the movable contact 14 are always mechanically interlocked so that they are in contact with different voltage taps.

Next, the operation will be explained. 4a to 4h explain the operating sequence of FIG. 3.

FIG. 4a shows a case in which a current is constantly taken out from the voltage tap A5, and the current is supplied from the voltage tap A5 through the current carrying contact 15 to a load (not shown). At this time, the movable contacts 13 and 14 are in the open state in FIG. 4a, but they may be in contact with the voltage tap A5, and the thyristor switch A11 and the thyristor switch B12 may be in a conducting or non-conducting state. Good too.

Further, FIG. 4h shows a case where current is constantly taken out from the voltage tap B6, and the current is supplied from the voltage tap B6 through the current-carrying contact 15 to a load (not shown). At this time, the movable contact 13
and 14 are in the open state in FIG. 2h, but they may be in contact with voltage tap B6, and thyristor switch A11 and thyristor switch B12 may be conductive or non-conductive.

In this way, from voltage tap A5 to voltage tap B
When switching the tap to 6, first, the thyristor switch B12 is brought into a non-conducting state by the ignition control device 17, and as shown in FIG. 1
3 is brought into contact with voltage tap A5. At this time,
Since the current carrying contact 15 is in contact with the voltage tap A5, current is supplied from the voltage tap A5 through the current carrying contact 15 to a load (not shown). The thyristor switch A11 may be conductive or non-conductive at this time. Next, as shown in FIG. 4c, the movable contact 13 and the current-carrying contact 15 contact the voltage tap A5, and the movable contact 14 contacts the voltage tap B6. At this time, the ignition control device 17 controls the thyristor switch B12 to remain non-conducting, but the thyristor switch A11 to become conductive. At this time, the current supplied to the load (not shown) is supplied through the current carrying contact 15 from the voltage tap A5. Next, as shown in FIG. 4d, the current-carrying contact 15 separates from the voltage tap A5 and comes into contact with no tap, but since the thyristor switch A11 is already in a conductive state, no firing occurs. The current-carrying contact 15 can now disconnect from the voltage tap A5. At this time, the current supplied to the load (not shown) is supplied from voltage tap A5 to movable contact 13 to thyristor switch A.
11. In this state, the auxiliary contact 16 sends a signal to the ignition control device 17, and the ignition control device 17 receives this signal and controls the thyristor switch A11 and thyristor switch B12. Move to B6. This state is shown in FIG. 4e. In FIG. 4e, thyristor switch A1
The thyristor switch B12 is controlled by the ignition control device 17 so that the thyristor switch B1 is turned off and the thyristor switch B12 is turned on. The current is supplied by voltage tap B6, movable contact 14,
It is supplied to a load (not shown) through a thyristor switch B12.

Next, as shown in FIG. 4f, the current-carrying contact 15
contacts voltage tap B6, but since thyristor switch B12 is already in a conductive state, current-carrying contact 15 can contact voltage tap B6 without firing. Next, as shown in FIG. 4g, the movable contact 13 separates from the voltage tap A5.
At this time, the current flows from voltage tap B6 to current-carrying contact 15.
is supplied to a load (not shown) through. Further, the thyristor switch B12 may be in either a conductive state or a non-conductive state, but next
As shown in the figure, a state is reached in which current is constantly taken out from the voltage tap B6, and the switching is completed.

As described above, in the conventional device, as shown in FIGS. 4d to 4e, the timing condition for switching the current from tap A5 to tap B6 uses the auxiliary contact 16 that interlocks the current-carrying contact 15. At the same time, it becomes complicated, and even if you try to time high-speed switching to minimize the amount of time the current flows through the thyristor switches in order to minimize heat generation in thyristor switch A11 and thyristor switch B12, it is difficult to obtain accurate timing.
Therefore, despite using a thyristor switch that is capable of high-speed switching,
Not only could this advantage not be achieved, but there was also the problem that the heat dissipation device had to be large due to the large amount of heat generated.

[Summary of the invention]

This invention was made to solve the above-mentioned problems, and uses a current detection device to detect the presence or absence of current in the current-carrying contact. To provide an on-load tap switching device capable of high-speed switching by switching current to a thyristor switch.

[Embodiments of the invention]

In FIGS. 3 and 4 showing the conventional one,
As is clear from FIG. 4, the contact state in which the current can be switched from voltage tap A5 to voltage tap B6 is as follows.
This is the case where the movable contact 13 is in contact with the voltage tap A5, the movable contact 14 is in contact with the voltage tap B6, and the current-carrying contact is not in contact with any voltage tap. Now, in conventional system FIG. Since the forward voltage drop of the switch is about 1 to 2 V, most of the current flows through the current carrying contact 15. Therefore, between FIGS. 4a to 4h, no current flows through the current-carrying contacts 15 only at points d and e. The presence or absence of current in the current-carrying contact 15 is already detected, and if no current is detected, it may be considered to be in state d or e.
This indicates that the switching timing can be determined by the presence or absence of current in the current-carrying contact instead of the auxiliary contact 16 mechanically interlocking with the current-carrying contact 15.

FIG. 1 shows an embodiment of the present invention. In the figure, 1 to 15 and 17 to 19 are the same as the conventional ones, so explanations thereof will be omitted. Reference numeral 20 denotes a current detection device that detects the current flowing through the current-carrying contact 15, and is, for example, a current transformer. The tap switching operation in Fig. 1 is shown in Fig. 2a~
This will be explained in Fig. 2h. In Figure 2, 4 to 6,
11 to 15, 17, and 20 are the same as in FIG.

FIG. 2a shows a case in which current is constantly taken out from the voltage tap A5, and the current is supplied from the voltage tap A5 through the current carrying contact 15 to a load (not shown). At this time, the movable contacts 13 and 14 are in the open state in FIG. 2a, but they may be in contact with the voltage tap A5, and the thyristor switch A11 and the thyristor switch B12 may be in a conductive state or a non-conductive state. good.

Further, FIG. 2h shows a case where current is constantly taken out from the voltage tap B6, and the current is supplied from the voltage tap B6 through the current-carrying contact 15 to a load (not shown). At this time, the movable contact 13
and 14 are in an open state in FIG. 2h, but they may be in contact with voltage tap B6, and thyristor switch A11 and thyristor switch B12 may be conductive or non-conductive.

Now, when switching the tap from voltage tap A5 to voltage tap B6, first switch thyristor switch B.
6 is brought into a non-conducting state by the ignition control device 17 and moved to the movable contact 14 and the voltage tap B6, as shown in FIG. 2b, and the movable contact 13 is brought into contact with the voltage tap A5. At this time, the current-carrying contact 15
is in contact with voltage tap A5, so the current is
The voltage is supplied from voltage tap A5 through current carrying contact 15 to a load (not shown). The thyristor switch A11 may be conductive or non-conductive at this time. Next, as shown in FIG. 2c, the movable contact 1
3 and current-carrying contact 15 are voltage taps A5
At the same time, the movable contact 14 contacts the voltage tap B6.
At this time, the ignition control device 17 controls the thyristor switch A11 to be conductive. At this time, the current supplied to the load (not shown) is supplied through the current carrying contact 15 from the voltage tap A5. Next, as shown in Fig. 2d, the movable contact 15 separates from the voltage tap A5 and comes into contact with no tap, but since the thyristor switch A11 is already in a conductive state, no firing occurs. The current-carrying contact 15 can be disconnected from the voltage tap A5. At this time, the current supplied to the load (not shown) is supplied from the voltage tap A5 through the movable contact 13 and the thyristor switch A11. In this state, the current detection device 20 sends a message to the ignition control device 17 that no current is flowing through the current-carrying contact 15, and sends a message to the ignition control device 17.
7 receives this signal and switches the thyristor switch A1.
1 and thyristor switch B12 to transfer the current from voltage tap A5 to voltage tap B6. This state is shown in FIG. 2e. In FIG. 2e, the ignition control device 17 controls the thyristor switch A11 to be non-conducting and the thyristor switch B12 to be conductive. Current is supplied to a load (not shown) through voltage tap B6, movable contact 14, and thyristor switch B12.

Next, as shown in FIG. 2f, the current-carrying contact 15
contacts voltage tap B6, but since thyristor switch B12 is already in a conductive state, current-carrying contact 15 can contact voltage tap B6 without firing. Next, as shown in FIG. 2g, the movable contact 13 leaves the voltage tap A5. At this time, current is supplied to a load (not shown) through voltage tap B6 and current-carrying contact 15. Further, the thyristor switch B12 may be in either a conductive state or a non-conductive state. Next, as shown in FIG. 4h, a state is reached in which current is steadily drawn from the voltage tap B6, and the switching is completed.

〔Effect of the invention〕

As described above, according to the present invention, the switching timing of the thyristor switch is obtained based on the presence or absence of current in the current-carrying contact, so even if a series of switching and operations are performed at high speed, the timing is stable. Reliable switching timing can be obtained.

That is, since it is possible to minimize the period of current flowing through the thyristor switch, the amount of heat generated by the thyristor switch is also reduced, and the device can be made smaller accordingly.

[Brief explanation of drawings]

Fig. 1 is a circuit diagram showing the on-load tap switching device according to the present invention, Fig. 2 is an operation sequence diagram of Fig. 1, Fig. 3 is a circuit diagram showing the conventional one, and Fig. 4 is the operation of Fig. 3. It is a diagram. In the figure, 5 is the first voltage tap and 6 is the second voltage tap.
11 is a first thyristor switch, 12 is a second thyristor switch, 15 is an energizing contact, 17 is an ignition control device, and 20 is a current detection device. Note that the same reference numerals in each figure indicate the same or corresponding parts.

Claims (1)

[Claims] 1 supplying current to the load through current-carrying contacts in contact with the first voltage tap of a transformer having a plurality of voltage taps, consisting of thyristors connected in antiparallel and each connected in parallel with the above-mentioned current-carrying contacts; The current-carrying contact is switched from the first voltage tap to the second voltage tap by controlling first and second thyristor switches, which are connected to the current-carrying contact and whose current is energized, by controlling first and second thyristor switches, which A current detection device for detecting current is provided, and when the current detection device detects no current in the current-carrying contact, the current supplied to the load is switched from the first thyristor switch to the second thyristor switch. An on-load tap switching device characterized in that both thyristor switches are controlled by the above-mentioned ignition control device.