RU2148290C1 - Device for controlling two converters - Google Patents

Abstract

FIELD: heavy power converters, in particular, for controlling thyristor converters of alternating current train engines. SUBSTANCE: device has two regulation channels, pulse generator, pulse former, voltage transformer and filter. Each regulation channel is designed as serial circuit of rectifying transformer, thyristor bridge, amplifier and pulse distributor. Input of pulse distributor of second channel is connected to pulse former. Input of voltage transformer is connected to mains terminals. Its output is connected to filter. Goal of invention is achieved by introduced device for calculation of root-mean-square deviation. Also pulse former is designed as adaptive regulator. Filter as frequency selection filter. First input of root-mean-square deviation calculation unit is connected to output of voltage transformer. Its second input is connected to output of frequency selection filter. Output of root-mean-square deviation calculation unit is connected to second input of pulse former, which first input is connected to output of pulse generator. EFFECT: improved quality of power supply voltage, increased reliability of device operations, decreased power consumption (by 4-5%) due to compensation of high-frequency after-commutation voltage deviations. 1 dwg

Description

 The invention relates to control systems for powerful converting installations and can be used, in particular, for controlling two thyristor converters on electromotive composition of alternating current.

 During the operation of AC electric locomotives in some sections of the railway, unstable operation of electronic control equipment is observed with severe distortions in the shape of the supply voltage curve. The essence of these distortions lies in the switching of electric locomotive converters. At the beginning of switching, part of the windings of the traction transformer of each section of the electric locomotive begins to work in short circuit mode. The simultaneous start of switching of all converters causes a sharp decrease in voltage at the current collector. However, an instantaneous decrease in voltage does not occur, since due to the presence of distributed inductances and capacitance in the traction network, free voltage fluctuations occur. Similar processes occur at the end of switching, when the short circuit of a part of the windings of the traction transformer ceases, as a result of which free post-switching voltage fluctuations occur. The research results presented in [1] indicate that the frequencies of free oscillations that occur at the beginning and at the end of switching are different. The amplitudes of voltage fluctuations at the end of switching significantly exceed the amplitude of free voltage fluctuations at the time of its beginning.

 Thus, the distortion of the shape of the supply voltage curve at the current collector of the electric locomotive is made up of the voltage dip during current switching in the converters and free oscillations that occur at the start and end of the switching.

 One of the ways to reduce these distortions is the use of different-phase control of two thyristor converters of an electric locomotive. The essence of different-phase control is the diversity in time of the beginnings, as well as the ends of the switching of various converters. The delayed opening of the thyristors of one of the converters allows to reduce the jump in the forced voltage when turning on and off each converter and the amplitude of the free voltage fluctuations on the current collector of the electric locomotive. Moreover, the multi-phase control device can be implemented with a constant and adjustable value of the delay angle.

 A device for multi-phase control with a constant value of the delay installed on the electric locomotive VL85 001 [1]. The device contains two channels, each of which consists of a converter transformer, a controlled rectifier, an amplifier and a pulse distributor, as well as a source of control pulses and a delay unit.

 Controlled rectifiers are connected to the network through converter transformers, and their inputs are connected to series-connected amplifiers and distributors. The source of control pulses is connected to the input of the distributor of the first channel and to the input of the delay unit, the output of which is connected to the input of the distributor of the second channel.

 The control pulses go directly to the controlled rectifier of the first channel, and to the second channel rectifier through a fixed delay unit.

 The device provides a shift in time of the beginning and, accordingly, the end of the switching of converters of various sections of an electric locomotive. This shift is achieved by delaying the control pulses arriving at one of the sections using a delay unit. In the ideal case, the value of the pulse delay should be equal to the half-period of free voltage fluctuations in the contact network, in this case, complete damping of the switching voltage fluctuations is achieved.

 Thus, the introduction of a delay unit significantly reduces the amplitude of post-switching voltage fluctuations at the current collector of an electric locomotive. This allowed, at a certain location of the electric locomotive, to approximate the shape factor of the supply voltage curve to the shape factor of the sinusoid, which increases the stability of the control equipment.

 However, the constant pulse delay value adopted in the device does not fully compensate for switching voltage fluctuations. This is due to the fact that the frequency of voltage fluctuations after the beginning and end of switching is determined by the changing distance of the electric locomotive from the tires of the traction substation and the parameters of the traction network. Therefore, the optimal value of the delay, adopted in some conditions, is not such in other conditions. The delay in the device is 8 degrees. It is optimal only when the locomotive is located at a distance of about 50 km from the traction substation in the 70-km cantilever feeder zone. At a different distance from the busbar of the electric locomotive traction substation in the supply voltage curve there are vibrations caused by uncompensated switching voltage.

 It is also known a device of different-phase control with an adjustable value of the delay angle [2], which controls with adjustable delay one of the rectifier bridges of the two-bridge converter.

 A device for controlling a two-bridge converter contains two channels, each of which consists of a converter transformer, a controlled rectifier, an amplifier and a pulse distributor, as well as a voltage transformer, a pulse shaper, a filter, an RS-trigger, a source of control pulses, an amplifier-limiter, a rectifier, an element And the reset driver.

 Controlled rectifiers are connected to the network through converter transformers, and their inputs are connected to series-connected amplifiers and distributors. The source of control pulses is connected to the input of the distributor of the first channel and input S of the RS-flip-flop, the output of which is connected to the first input of element I. A circuit of series-connected voltage transformer, filter, limiter amplifier, and rectifier is connected to the second input of this element. The output of the element And is connected to the input of the shaper of the reset signals and the input of the shaper of pulses, the output of which is connected to the input of the distributor of the second channel. The output of the reset signal conditioner is connected to the input R of the RS trigger.

 The control pulses generated by the source of control pulses arrive without delay to the controlled rectifier of the first channel. To the rectifier of the second channel, these pulses are applied with a delay created in the pulse shaper in the second channel. The value of the delay angle is determined by the half-period after the switching voltage fluctuations, extracted from the mains voltage using a voltage transformer and a filter. Thus, the creation of an artificial shift in the sequence of control pulses between the channels provides the opposite phasing of free oscillations after the switching voltage when switching two bridges. This control device allows to reduce high-frequency switching oscillations and thereby significantly improve the quality of the supply voltage, the reliability of the converter device.

 However, when the delay angle is formed in the device in the form of post-switching voltage fluctuations, the second component of free voltage fluctuations associated with the beginning of switching is not taken into account. The voltage fluctuations that occur during switching at the moments of its beginning and end have different amplitudes and frequencies. Free oscillations in the general case are non-sinusoidal and can be obtained by summing an infinite number of harmonics [3, 4]. The device filter identifies both components of the switching voltage fluctuations. In this case, the high-frequency component, due to the beginning of switching, is added to the curve of post-switching voltage fluctuations, distorting its shape. These distortions lead to a shift in the moments of the natural transition of this voltage through zero and, accordingly, to an error in the formation of the delay angle, which is determined by the half-period after the switching voltage fluctuations. Therefore, the formation of the delay angle in a distorted form after switching voltage fluctuations leads to incomplete compensation of the free components of the mains voltage and its shape deterioration, which leads to a deterioration in the operation of the converter device.

 The basis of the invention is the creation of a device with an adjustable delay angle for controlling two converters with full compensation of free post-switching voltage fluctuations by maximally approximating the distorted voltage form to the sinusoidal one. At the same time, due to the optimal control of the delay angle, the device constantly maintains the minimum value of the standard deviation, providing the best approximation of the voltage curve to the sinusoidal shape.

 To solve this problem, in a known device for controlling two converters, containing two control channels, each of which is made of series-connected converter transformer, thyristor bridge, an amplifier and a pulse distributor, a pulse source, a pulse shaper, a voltage transformer and a filter, while the input of the distributor the first channel is connected to the output of the pulse source, the input of the distributor of the second cocoa - with a pulse shaper, the input of the transformer voltage is connected to the network, and its output is connected to the filter, an additional standard deviation calculation device is introduced, the pulse shaper is made in the form of an adaptive regulator, the filter is in the form of a frequency-isolating filter, while the first input of the standard deviation calculation device is connected to the output of the voltage transformer, the second input - with the output of the frequency-isolating filter, and the output of the device for calculating the standard deviation is connected to the second input of the pulse shaper Having a first input connected to the output of the pulse source.

где U_с(t) - функция сетевого напряжения,
U_i(t) - первая гармоника этого напряжения;
T - период сетевого напряжения.The introduction of a device for calculating the standard deviation makes it possible to form an angle of control delay for one of the thyristor bridges according to the value of the standard deviation of the mains voltage from its first harmonic. The standard deviation of these values is determined by the formula

where U _с (t) is the function of the mains voltage,
U _i (t) is the first harmonic of this voltage;
T is the period of the mains voltage.

This value characterizes the overall form of the mains voltage by the degree of its approximation to the first harmonic. The decrease in the value of δ ² by adjusting the angle of delay corresponds to the approximation of the shape of the mains voltage to a sinusoid. This, in turn, means a decrease in the line voltage curve of higher harmonic components caused by current switching in the converter. Thus, improving the shape of the mains voltage due to the adjustable delay helps to increase the stability of the electric locomotive converter.

 The drawing shows a block diagram of a device for controlling two converters.

 A device for controlling two converters comprises converter transformers 1, 2, thyristor bridges 3, 4, amplifiers 5, 6 and pulse distributors 7, 8, comprising two control channels, a pulse source 9, a pulse shaper 10, a voltage transformer 11, a filter 12, and a device standard deviation calculations 13.

 In each of the control channels, converter transformers 1, 2, thyristor bridges 3, 4, amplifiers 5, 6, and pulse distributors 7, 8 are connected in series.

 The voltage transformer 11 is connected to the input of the filter 12 and the first input of the standard deviation calculation device 13, the second input of which is connected to the output of the filter 12. The pulse source 9 is connected to the input of the pulse distributor of the first channel 7 and the first input of the pulse shaper 10, the output of which is connected with the input of the pulse distributor of the second channel 8. The pulse shaper 10 is connected by its second input to the output of the device for calculating the standard deviation 13. The inputs are converter x transformers 1, 2 and voltage transformer 11 are connected to the network.

 Transformers 1, 2 are traction transformers ОНДЦЭ-10000 / 25-82 УХЛ 2 of an electric locomotive VL85 [5]. Thyristor bridges 3, 4 are a fully controllable eight-arm thyristor converter. The frequency-isolating filter 12 is made as described in [6].

 The device for calculating the standard deviation 13 is implemented on operational amplifiers and transistors [7].

 A device for controlling two converters operates as follows.

The pulse source 9 generates control pulses U _control , which through the distributor 7 and amplifier 5 are fed to the control electrodes of the thyristors of the bridge 3 of the first converter, and, thus, set its operation. At the same time, the pulses U _control arrive at the first input of the pulse shaper 10, which delays the control pulses. Using a voltage transformer 11 and a filter 12, a signal U ₁ is proportional to the first harmonic of the mains voltage. In this case, the phase of this voltage coincides with the points of the natural transition through zero of the mains voltage. In this case, the standard deviation calculation device 13 determines the degree of deviation of the mains voltage from its first harmonic. The signal from the output of the device for calculating the standard deviation 13 is supplied to the second input of the pulse shaper 10, setting the angle of delay of the control pulses U _{control2 by the} second converter. The pulse shaper adjusts the angle of delay, providing a minimum value of the standard deviation of the voltage.

 Thus, the formation of the delay angle of the thyristor opening by the standard deviation provides the maximum possible approximation of the voltage curve to its first harmonic and, accordingly, the most effective compensation after switching voltage fluctuations. An improved form of mains voltage makes it possible to increase the stability and reliability of the operation of electric locomotive equipment.

 The device for controlling two converters was tested on an AC electric locomotive VL65. Reducing the distortion of the mains voltage curve made it possible to reduce the minimum opening angle of the thyristors of the converter, which in turn affected the decrease in power consumption by (4-5)%.

Sources of information taken into account:
1. Yu.M. Kulinich et al. Tests of an electric locomotive VL85 with different-phase control of rectifier-inverter converters. - Vestnik VNIIZHT, 1986, N 4.

 2. A. c. N 1099376. Device for controlling a two-bridge converter. Yu.B. Philip and others publ. in B.I. 1984 N 23, MKI N 02 P 13/18.

 3. Kuchumov V.A. and others. Electromagnetic processes in a burdened network with a distributed capacity during current switching in an electric rolling stock converter. - Vestnik VNIIZHT, 1984, N 1.

 4. Kuchumov V.A. and others. Electromagnetic processes in a traction network with a distributed capacity when rectifying the current in the converter of electric rolling stock. - Vestnik VNIIZHT, 1984, N 8.

 5. Electric locomotive VL85: Operation manual / Pushkarev N.G. et al. - M.: Transport, 1992.

 6. Application for a patent N 97105625 from 04/09/97, the decision to grant a patent from 02/11/98.

 7. E.A. Colombet. Microelectronic analog signal processing tools. - M .: Radio and communications, 1991.

Claims (1)

 A device for controlling two converters from a series-connected converter transformer and a thyristor bridge each containing two control channels, through a series-connected pulse distributor and amplifier of each of which control pulses are fed to the control electrodes of the thyristors of the bridge of the corresponding converter, in addition, a voltage transformer and a filter, this input of the pulse distributor of the first channel is connected to the output of the pulse source, the input distribution second channel - with a pulse shaper that delays control pulses, the input of the voltage transformer is connected to the network, and its output is connected to the filter, characterized in that it additionally includes a device for calculating the standard deviation, which determines the degree of deviation of the mains voltage from its first harmonic, the filter is made in the form of a frequency-generating filter, while the first input of the device for calculating the standard deviation is connected to the output of the voltage transformer Ia, the second input - to the output chastotnovydelyayuschego filter, and the output of the standard deviation calculation unit is connected to the second input of the pulse shaper, by setting the delay angle of the corresponding inverter control pulses and the first input of the pulse shaper connected to the output pulses of the source.