JPH02111264A - Controller for semiconductor rectifier - Google Patents

Abstract

PURPOSE:To eliminate the need for the regulation of a thyristor rectifier when actual currents are made to flow by uniformly sharing output currents in the parallel operation of a diode rectifier and the thyristor rectifier. CONSTITUTION:When a diode rectifier is shut down, a signal from a voltage setter 43C is changed into the input signal of a voltage controller 42, and output characteristics are shown in A-A'' of Fig. 7. When the state in which load is supplied with currents from the diode rectifier is brought, output voltage changes on a straight line B-B'. Since the output voltage of the diode rectifier is increased on currents shown in I' of Fig. 7, load currents begin to be fed from the diode rectifier, an output from a comparison amplifier 43A is added to a signal to the voltage setter 43C, the input signal of the voltage controller 42 is increased, and the output voltage of a thyristor rectifier 22 is elevated from the point of A-A'' to the point of B'' and equalized to the output voltage of the diode rectifier. Accordingly, load currents are shunted uniformly to the diode rectifier and the thyristor rectifier.

Description

Detailed Description of the Invention [Objective of the Invention] (Industrial Application Field) The present invention provides a Nyristor with an output voltage function when operating multiple rectifiers in parallel in a DC power supply device for electric railways. etc., regarding a semiconductor rectifier control device used.

(Conventional technology) As a rectifier for a DC energizing system such as an electric railway,
Diode rectifiers have generally been used, but because they do not have a control function, the DC output voltage cannot be freely controlled. On the other hand, semiconductor rectifiers using thyristors, etc., can freely change the DC output voltage by controlling their control angle, so they are increasingly being installed in place of diode rectifiers.

A case where a thyristor rectifier is used as a semiconductor rectifier using a thyristor or the like will be described below.

FIG. 2 is a block diagram of parallel operation of a diode rectifier and a thyristor rectifier.

In Fig. 2, 11 is a diode rectifier transformer;
2 is a diode rectifier, 21 is a thyristor rectifier transformer, 22 is a thyristor rectifier, 25 is a load, 31
indicates a thyristor regulator control device.

Figure 3 shows the output characteristics of both the diode rectifier and the thyristor rectifier. In FIG. 3, A shows the regulation characteristics of the diode rectifier, and B shows the output characteristics when the thyristor rectifier is controlled at constant voltage.

In Figure 3, the output current is 100% when the diode rectifier and thyristor rectifier share the same output current.
Only when.

Therefore, when it is less than 100%, it is not preferable because the load will increase on the diode rectifier.

In order to avoid this, it is necessary to control the output characteristics of the thyristor rectifier to be the same as the regulation characteristics of the diode rectifier installed in parallel. Figure 4 shows a conventional control block diagram that takes the above-mentioned measures. .

In FIG. 4, 22 indicates a thyristor rectifier, and 23 indicates a DC current detector of the thyristor rectifier. 1 The regulation of the Neunostar rectifier is adjusted to match the regulation of a diode rectifier (not shown) using the regulation adjuster 41, and the voltage reference is controlled according to the signal detected by the DC current detector 23 in accordance with the set rectification. It is used as an input to the device 42. By matching the regulation of the thyristor rectifier to the regulation of the diode rectifier, the output current distribution can be made uniform. The output characteristics at this time are shown in FIG.

(Problems to be Solved by the Invention) As stated above, when operating a diode rectifier and a thyrisk rectifier in parallel, it is necessary to match the regulation of both in order to equalize the sharing of the output current. In order to confirm that the output current is uniform, it is extremely difficult to adjust and set the regulation characteristics of the thyristor rectifier unless current is applied to the load during actual operation in an actual system. Furthermore, even with regulation, if the voltages B-b generated by the diode rectifier during no-load do not have the same value, as shown in FIG. 6, it is not possible to distribute the current evenly.

SUMMARY OF THE INVENTION An object of the present invention is to provide a semiconductor rectifier control device that can equalize the output current distribution regardless of the regulation characteristics of the diode rectifier when a diode rectifier and a silice rectifier are operated in parallel.

(Structure of the Invention) (Means for Solving the Problem) In order to achieve the above-mentioned object, the present invention detects the output currents of a diode rectifier and a sirisk rectifier, and adjusts the sirisk rectifier so that the difference between the output currents of the two rectifiers is eliminated. The output voltage of the rectifier is controlled.

(Function) According to the present invention, in parallel operation of a diode rectifier and a thyristor rectifier, the output current is equally shared, so there is no need to adjust the regulation of the thyristor rectifier when a real current is passed as in the conventional case. It disappears.

(Example) An embodiment of the present invention will be described below with reference to FIG. 1A.

In FIG. 1A, 13 is a diode rectifier direct current detector, 22 is a thyrisk rectifier, and 23 is a thyrisk rectifier direct current detector. 43 is a current controller, which includes a comparison amplifier 43A for the output current signal of the diode rectifier and the output current signal of the thyristor rectifier, and outputs 43A only when the output current signal of the thyristor rectifier is lower than the output current signal of the diode rectifier. There is also an adder 43B that adds the signal to the signal from the voltage setter 43C.

Now, when the diode rectifier is not operating, the signal from the voltage setter 43C becomes the input signal to the voltage controller 42, and the thyristor rectifier 22 is operated at a constant output voltage. The output characteristics at this time are shown by A-A'' in FIG.

Next, when the diode rectifier supplies current to the load, the output voltage changes on a straight line B-8'' due to the output characteristics of the diode rectifier.

When the current reaches the value indicated by - in FIG. 7, the output voltage of the diode rectifier is high, so the diode rectifier starts supplying the load current. From this, the comparison amplifier 43
The output of A is added to the signal sent to the voltage setter 43C, and the input signal of the voltage controller 42 increases, and the output voltage of the thyristor rectifier 22 increases from the point A-A"' to 8-'
The voltage rises to the point where it becomes the same as the output voltage of the diode rectifier. The same can be said for other currents; when current is flowing through the load, the output voltage of the thyrisk rectifier 22 is increased only in the shaded area in Fig. 7 by the recommendation of the current controller 43, and it is always connected to the diode rectifier. The voltage will be the same. As a result, the load current will be divided equally between the diode rectifier and the thyristor rectifier.

FIG. 1B is a configuration diagram showing another embodiment of the present invention.
The difference from Figure A is that the output current signals of the diode rectifier and Iristor rectifier operating in parallel are compared and amplified at 43A, and when the output of the diode rectifier is large, the output voltage of the thyrisk rectifier is increased.
Further, an adder 43D is provided for the signal from the voltage setter 43C so as to reduce the output voltage of the diode rectifier when the output of the diode rectifier is small. With the above configuration, as shown in FIG. 8, by always making the output voltage of the thyrisk rectifier the same as that of the diode rectifier, the output current can be shared equally between the rectifiers.

[Effect of Rlight] As explained above, according to the present invention, it is possible to follow any regulation characteristics of the diode rectifiers operating in parallel, so that the output current sharing between the diode rectifiers and the thyristor rectifiers operating in parallel can be equalized. can provide a high-performance DC power supply.

[Brief explanation of the drawing]

Figures 1A and 1B are block diagrams showing different embodiments of the present invention, Figure 2 is a configuration diagram of parallel operation of a diode rectifier and a thyristor rectifier, and Figure 3 is a constant voltage control of a diode rectifier and a thyristor rectifier. Output characteristic diagram by
Figure 4 is a control block diagram of a conventional thyrisk rectifier, Figure 5 is a diagram of the output characteristics of diode rectifier, current flow rectifier and thyristor rectifier when the regulation characteristics are matched, and Figure 6 is the generated voltage of the diode rectifier and thyristor rectifier. 7 and 8 are output characteristic diagrams according to the present invention when the values are not equal. 11... Guio 1-rectifier transformer, 12... Diode rectifier, 13... Direct current detector for diode rectifier, 21.
... Cyrisk rectifier transformer, 22... Thyristor rectifier, 23... Direct current detector for Cyrisk rectifier, 25.
...Load, 31...Sirisk rectifier control device, 41...Reculation adjustment, 42...Voltage controller, 43...Current controller, 43A...Comparison amplifier, 43B...7JOF 43C...voltage setting device, 43D...adder. Agent Patent Attorney Nori Chika Ken Futoshi Daishimaru Kano Figure 1 Figure Figure Figure Figure Figure Figure Figure Figure

Claims (1)

[Claims] In a semiconductor rectifier control device that operates a rectifier without an output voltage control function and a semiconductor rectifier with an output control function in parallel, the output current of each is compared and the control function is activated only when the output current of the semiconductor rectifier with a control function is low. 1. A semiconductor rectifier control device that controls to increase the output current of a semiconductor rectifier.