RU2168200C2 - Gear for control and protection of converter - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: invention is related to voltage and current converters of electric technological installations. It can find use in contactless control over voltage and current in primary windings of transformers supplying power to rectifiers, resistance furnaces, welding, arc and electrolysis plants, charging devices, capacitive energy storages and so on. Gear has protection unit made of load current transmitter to which adjustment resistor with threshold unit is connected and control unit composed of power supply source, pulse-width modulator synchronized with supplying network and incorporating integrating RC circuit and adjusting resistor connected in series and output device to control regulating element of converter. Resistor of integrating RC circuit is shunted by transistor with collector resistor which is connected with control input to adjustment resistor. Receivers of optrons are connected in parallel and in series with adjustment resistor and their radiators are linked via current-limiting resistor to load current transmitter. One optron is connected with radiator via threshold element and with receiver in parallel to adjustment resistor. EFFECT: enhanced reliability and expanded functional capabilities of gear for control and protection of converter. 2 dwg

Description

 The device relates to the field of electrical engineering, in particular to voltage and current converters of electrical installations, and can be used for contactless voltage and current regulation in power transformers of rectifiers, resistance furnaces, welding, arc and electrolysis plants, chargers, capacitive energy storage devices and other consumers .

 A device for controlling a thyristor regulating body of a converter (see, for example, a research report, N State registration B119150, 1974, Fig. 2.8, p. 56), containing a phase-feedback control system with current feedback, including a current sensor loads, threshold element, power and control voltage sources and thyristor control output device.

 The disadvantage of this device is the lack of protection against inrush currents of magnetization and overload.

 A device is known for protecting the converter from overloads (see, for example, Prince Ivanov V.I. et al. Semiconductor optoelectronic devices. Handbook. - M .: EAI, 1989, Fig. 12.2, p. 404) containing a control system a half-wave transformer key, which includes a power source, a phase-pulse modulator based on a relaxation generator with an output device, a load current sensor with an RC filter, a threshold element with a modulator control element is connected in parallel with its output.

 The disadvantage of this device is the lack of protection against inrush currents of the magnetization of the transformer, the inability to turn on the converter without replacing the fuse.

 A device for current protection of a converter (see, for example, Prince Glukha E. M., Zelenova V.E. Protection of semiconductor converters. - M .: Energy, 1970, Fig. 5-3, p. 115), containing a current sensor the load to which the threshold element is connected, a control circuit on transistors, an output control device for the converter keys and a power source.

 This device does not protect the regulatory body from inrush currents of magnetization when it is connected to the mains, which can cause a false shutdown of the converter.

 The closest in technical essence to the claimed object is a control and protection device of the converter (see, for example, Prince M. Fotieva. Electrical equipment of ferrous metallurgy enterprises. -M.: Metallurgy, 1980, Fig. 49, p. 78), containing a phase-pulse modulator synchronized with the supply network with an output device for controlling the keys of the regulatory body at the output and a shunt transistor at the input of the control voltage, a power source and a load current sensor with an RC filter, which is connected in parallel with the capacitor n threshold element with trimmer.

 The disadvantage of this device is limited functionality and lack of reliability. This is due to the fact that this control device does not protect the converter from inrush currents of magnetization without turning it off, and without changing the voltage level of the control resistor, it is impossible to reduce the open circuit voltage. However, for many converters — welding transformers, power supplies for capacitive energy storage devices — according to electrical safety conditions or technology, the open circuit voltage must be minimum or equal to zero. In addition, even with a smooth increase in the angle of regulation of the regulatory body of the converter due to a smooth increase in the control voltage at the input of the phase-pulse modulator, which is feasible when the control resistor is supplied from the capacitor of the integrating circuit, it is not always possible to avoid the inrush of the magnetizing current of the transformer, many times higher than its nominal value . Based on the fact that the power to the control and protection device must be supplied earlier than to the power part of the converter, or, at least at the same time, it can be tuned by an integrating circuit so as to avoid surges in the magnetization current of the transformer when the converter is initially turned on. However, during operation, it is possible to disconnect the power circuit of the converter, for example, by a circuit breaker without disconnecting the power source of the control circuits, i.e. the regulatory angle of the regulatory body remains unchanged. Now, when resuming the supply of voltage to the power part of the converter, the voltage arrives at the transformer, determined by the angle of regulation, which can be maximum. At this moment, depending on the location of the operating point on the hysteresis loop, two cases are possible: 1. successful, in which the transformer quietly, without inrush currents of magnetization, comes into operation, transforming the open circuit voltage determined by the transformation coefficient and the angle of regulation of the regulatory body ; 2. unsuccessful, when the inrush of the magnetization current leads to the operation of the electromagnetic (current) protection or the failure of the regulatory body. Unauthorized shutdown of the converter reduces the reliability of the converter.

 The main objective of the invention is to expand the functionality while improving reliability by reducing or eliminating the inrush currents of the magnetization of the transformer at the time of connection to the mains, reducing the open circuit voltage level and limiting the short circuit current at a given level.

 The solution to this problem is achieved by the fact that in the control and protection device of the converter containing the load current sensor, to which a tuning resistor with a threshold element is connected, and a power supply connected in series with a pulse-width modulator synchronized by the network, including an integrating RC circuit and an adjustment a resistor, and an output device for controlling the regulatory body of the Converter, according to the claimed invention introduced a transistor with a collector resistor and two optocouplers, p and in this case, a transistor with a collector resistor is connected in parallel with the integrating resistor, the control input of the transistor is connected to a control resistor, in parallel with which the receiver of one optocoupler is connected, and the receiver of another optocoupler is connected in series with the control resistor, and the emitter of one optocoupler is connected to the load current sensor through a threshold element and a current-limiting resistor, and the emitter of another optocoupler is connected to the load current sensor through a current-limiting resistor.

 In FIG. 1 is a functional diagram of a converter control and protection device, and FIG. 2 - external characteristics formed by him.

 The control device consists of a series-connected power source 1, synchronized with the power supply network of a pulse-width modulator (PWM) 2, and an output device 3 for controlling the regulatory body of the converter 4. The converter 4 is a matching transformer with a regulatory body, for example, on bipolar thyristors, installed on the primary side.

 PWM 2 includes an integrating RC circuit on resistor 5 and capacitor 6, the time constant of which is close to the half-cycle duration of the supply network, an adjustment resistor 7, and a reference voltage source. In parallel with resistor 5, a transistor 8 is connected with a collector resistor 9, the control input of which is connected to the regulating resistor 7 engine. A current sensor 10 is installed in the load circuit 11 connected to the converter 4. A tuning resistor 12, 13 with a threshold element 14 is connected to the current sensor 10 ( dashed line) and emitters of the optocouplers 15, 16 through a current-limiting resistor 17, and the emitter of the optocoupler 15 is connected through the threshold element 14. The receivers of the optocouplers 15, 16 are connected in parallel and sequentially no adjustment to the resistor. The currents of the optocoupler receivers 15, 16 are limited by the resistor 18. The threshold element 14 may be a transistor, a single-junction transistor or a transistor 19 with a zener diode 20, as shown in FIG. 1.

 Pulse-width modulator 2 can be performed on the timer, on a horizontal or vertical principle. The output device 3 may be a blocking generator, a pulse transformer with a transistor, a reed switch or a transistor in key mode.

 The current sensor 10 can be made in the form of a shunt in DC circuits and a current transformer with a rectifier and an RC filter in AC circuits, as shown in FIG. 1 dotted line.

As the optocoupler 16 connected by the receiver in series with the adjustment resistor 7, optocouplers with a diode emitter and a transistor or diode photodetector should be used. The type of optocoupler 15 connected by the emitter through the threshold element 14 depends on the desired shape of the curve of the external characteristic U _n = f (I _n ) - curves 22, 23 in FIG. 2. If characteristic 22 is required with a short-circuit current not exceeding the rated current at point A (Fig. 2), transistor 21 optocoupler 15 is required, and for steeply dropping characteristic 23, a thyristor optocouple with a trip button is needed.

 The essence of the operation of the device of FIG. 1 and the solution of the problem we explain by the example of a voltage converter 4 into current - a welding transformer with a thyristor regulating body in the primary winding.

When the voltage U _{c of the} network is supplied to the converter 4 and the power source 1 for almost half a period of voltage U _{c, the} capacitor 6 is charged through the resistor 5 and a sawtooth voltage U _{p is} supplied to the PWM 2, where, in comparison with the fixed reference voltage, in the form of a square pulse short duration arrives at the output device 3. The angle of control of the keys of the regulatory body and the transformed voltage will be minimal, as a result of which the magnetization current of the transformer will also be less than the nominal. From the moment the load 11 is connected, a voltage proportional to the load current 11 appears at the output of the current sensor 10. A current begins to flow through the trimming resistor 12, 13 and the optocoupler emitter 16, the magnitude of which determines the light emission intensity. The photodetector - the optocoupler transistor 16 is opened and the unlocking signal is supplied to the control input of the transistor 8 from the adjustment resistor 7. The transistor 8 and the resistor 9 shunts the resistor 5 of the integrating RC circuit, while the charging time constant of the capacitor 6 decreases and the duration of the PWM signal increases. The angle of regulation of the keys of the regulatory body of the Converter 4, the output voltage and current in the load 11. The voltage at the output of the current sensor 10 and the radiation intensity of the optocoupler 16 will increase, which will lead to saturation of the photodetector. Now the equivalent resistance of the resistors 5 and 9 will be determined by the position of the slider of the adjustment resistor 7, which sets the angle of regulation. Until the specified angle of regulation of the regulatory body is established, the magnetic core is magnetized by the private hysteresis loops. When the load 11 is disconnected by the optocoupler 16, the adjustment resistor 7 is turned off and the transistor 8 is turned off, the duration of the "sawtooth" voltage U _p becomes maximum, and the control angle and the output voltage of the converter 4 are minimal. Therefore, the converter 4 at idle always provides the minimum values of the output voltage and idle current, which increases its power factor.

 The current cutoff operates at a current exceeding the value set by the trimmer resistor 13 and 12. When overloaded, the voltage at the tuning resistor 12, 13 will exceed the voltage of the threshold element 14, consisting of a transistor 19 and a zener diode 20, and it will pass the current through the emitter of the optocoupler 15. The photodetector - transistor 21 of the optocoupler 15 changes its resistance depending on the radiation intensity, as a result the equivalent resistance of the resistors 5 and 9 of the integrating RC circuit changes. An increase in the load current 11 above the set point A on the characteristic 22 (Fig. 2) causes a decrease in the voltage at the control input of the transistor 8 and an increase in the equivalent resistance of the integrating circuit, which leads to a decrease in the control angle and the output voltage of the converter 4. At the time of saturation of the phototransistor 21, the transistor 8 it is locked and the angle of regulation of the regulatory body becomes minimal. When a thyristor optocoupler is used as the optocoupler 15, a steeply dipping external characteristic 23 is formed. After the phototyristor 15 is unlocked, it will bypass the adjustment resistor 7 until the short circuit is removed and the phototyristor is disconnected from the power source 1 by the reset button (stop).

 From the description it follows that the external characteristic can be formed by anyone with the required setting of the short circuit current. Possible with a minimum voltage on the primary winding of the transformer, inrush currents of magnetization are much less than the rated current of the winding, do not cause the converter to trip by current protection and do not lead to failure of the regulatory body.

 Thus, the task is to expand the functionality and increase reliability are successfully solved by simultaneously performing the control and protection functions by changing the time constant of the integrating RC circuit, as a result of which the inverter duty cycle always starts with the minimum open-circuit voltage. This is very important from the point of view of electrical safety in welding transformers.

 The proposed control and protection device of the converter can be used in voltage control systems on the primary side of transformers, including voltage to current converters supplying electrical installations.

Claims (1)

 A converter control and protection device comprising a load current sensor to which a trimming resistor with a threshold element is connected, and a power supply connected in series with a pulse-width modulator synchronized with the network, including an integrating RC circuit and an adjustment resistor, and an output control device a regulator of the converter, characterized in that a transistor with a collector resistor and two optocouplers are introduced, while in parallel with the integrating resistor is connected a transistor with a collector resistor, the control input of the transistor is connected to a control resistor, in parallel with which the receiver of one optocoupler is connected, and a receiver of another optocoupler is connected in series with the control resistor, the emitter of one optocoupler connected to the load current sensor through a threshold element and current-limiting resistor, and the emitter of another optocoupler connected to a load current sensor through a current limiting resistor.

Images