RU2157041C2 - Control method for voltage deviation and reactive power compensators - Google Patents

Abstract

FIELD: power engineering; input power factor and output voltage correction. SUBSTANCE: method involves controlling inverter of transformer-thyristor reactive-power compensator with stepless amplitude-phase control of booster voltage. At low peak values of booster voltage when device functions to regulate load voltage only, inverter is controlled according to 180 deg. algorithm and at high voltages requiring also compensation for load voltage deviations and for supply mains reactive power, use is made of 150 deg. control algorithm. Desired inverter control algorithm is selected either steplessly or in steps under subcritical conditions of continuous currents through voltage inverter using one of variables associated directly or indirectly with inverter current phase. Such control is proposed to be made using inverter input voltage. EFFECT: reduced percentage of higher-harmonic components in output voltage. 3 dwg

Description

 The invention can be used in reactive power compensators having a high-speed channel for smooth correction of input power factor and output voltage, made on the basis of a boost booster transformer and a thyristor converter of amplitude and phase with an intermediate DC voltage link. The inventive voltage booster generated by a rectifier with a filter, voltage inverter and booster transformer, is regulated in amplitude and phase so that the load voltage vector is the radius of a given circle. Moreover, in the region of small voltage amplitudes of the voltage boost, when compensation of the reactive power of the network is practically not required and the device provides only stabilization of the load voltage, the voltage inverter is controlled by a 180-degree algorithm, and in the region of large values, when compensation is also required for deviations of the load voltage and reactive network power, a 150-degree control algorithm is applied. The transfer of voltage inverter control from one algorithm to another is performed smoothly or discretely in the boundary mode of continuous voltage inverter currents according to one of the parameters that are directly or indirectly related to the phase between the current and the inverter voltage or to the voltage boost amplitude.

 The technical effect of the application of the method consists in a twofold reduction in the percentage of higher harmonic components in the output voltage curve.

 The invention relates to power electronics and can be used in reactive power compensators to improve the quality of the output voltage.

 A known method of controlling the voltage and reactive power deviation compensator (Patent N 2056692 RF, 6 H 02 J 3/18, Bull. N 8, 1996), comprising a three-phase boost transformer with a primary winding connected between the network and the load and the secondary winding connected to the star and through a three-phase voltage inverter, a filter and a reversible rectifier connected to the network or the load, which consists in measuring the voltage deviations on the load and from it form the first control signal, which, acting on the three-phase invert p voltage, change the phase of the voltage at the output of this inverter within 0 - π rad in the advance direction relative to the mains voltage, while ensuring the duration θ of the conducting state of the thyristors of the three-phase voltage inverter, equal to π rad (180-degree control), and also measure the reactive power network and from it form the second control signal, which, acting on the reversing rectifier, change the amplitude of the output voltage of a three-phase inverter, with the limitation of its minimum value proportional to nnomu range of voltage stabilization.

 The disadvantage of the prototype method should include a large percentage of higher harmonic components in the output voltage curve at θ = π in the region of large voltage amplitudes of the voltage boost, when voltage deviations and reactive power compensation are also implemented. At the same time, the use of control algorithms for a three-phase voltage inverter with θ <π rad creates large overvoltages due to the occurrence of current-free intervals in the secondary phase winding circuit of the boost transformer when the device is operating under active load.

 The objective of the invention is to improve the shape of the output voltage of the device without violating the continuous current mode of the inverter and maintaining low switching losses.

 The effect of solving this problem is to halve the percentage of higher harmonic components in the output voltage curve.

 The solution to this problem is achieved by measuring the voltage at the input of a three-phase voltage inverter, comparing it with the voltage of a given level and, when this level is exceeded, adjusting the first control signal, reduce the conductive state of the thyristors of a three-phase voltage inverter to 5 π / 6 rad, while the specified the voltage level at the input of a three-phase voltage inverter is chosen so that the continuity of currents in the secondary phase windings of the three-phase boost voltage transformer is maintained rmatora.

The compensator control method includes the operation of measuring the voltage deviation at the load, the first control signal is formed from it, and the reactive power of the network is measured and the second control signal is formed from it. The first control signal changes the phase within 0 - π rad, and the second - the amplitude of the first voltage harmonic at the output of the three-phase voltage inverter with the limitation of its minimum value, in proportion to the specified stabilization range. A three-phase voltage inverter converts the rectified input or output voltage of the compensator into an alternating voltage of the same frequency, but with amplitude-phase regulation depending on the first and second control signals. The voltage from the output of the three-phase inverter is supplied to the secondary windings of the three-phase boost transformer and, decreasing by a factor of k _t , it is added to the mains voltage. The method also includes measuring the voltage at the input of a three-phase voltage inverter, which changes the duration of the conductive state of the thyristors of a three-phase voltage inverter from π to 5 π / 6 rad, when this voltage exceeds a predetermined level that preserves the continuity of currents in the secondary phase windings of a three-phase boost transformer.

 A feature of the principle of construction of the compensator is the relationship between the phase of the output current of a three-phase inverter and the voltage value at its input and output. This feature underlies the method of improving the quality of the output voltage of the compensator by switching control algorithms for a three-phase voltage inverter without violating the continuous current mode.

 Figure 1 shows a block diagram of a device that implements a method for controlling a compensator for voltage and reactive power deviation, figure 2 is a timing diagram of the operation modes of the compensator, and figure 3 of the application shows a functional diagram of a switching device for changing the inverter control algorithm.

 The compensator (Fig. 1) contains a three-phase boost transformer 1, a three-phase voltage inverter 2 with a control system 3 synchronized with the network, in which the first control signal is generated, a rectifier 4 with a control system 5 synchronized with the voltage at its input terminals, in which the formation of the second control signal, inductive-capacitive filter 6. In addition, the compensator contains a sensor 7 of the reactive power of the network with a limiter 8 of the minimum level, for example voltage sensor, load deviation sensor 9, voltage sensor 10 at the input of a three-phase voltage inverter, switching device 11 and load 12. The switching device (Fig. 4) includes a comparator 13, a key 14 (transistor) and an additional resistor 15 for a single-shot 16.

 The first control input of the three-phase inverter 2 voltage control system 3 is connected to the output of the voltage deviation sensor 9 at the load 12, by which the phase of the auxiliary voltage is regulated within the range 0 - π rad, in the direction of advancing the mains voltage. The second control input of the three-phase inverter 2 voltage control system 3 through the switching device 11 is connected to the voltage sensor 10 at the input of the three-phase inverter 2, by which the inverter control algorithms are switched. The control input of the control system 5 of the reversing rectifier 4 through the limiter 8 of the minimum voltage level is connected to the output of the sensor 7 of the reactive power of the network, the magnitude of which regulates the amplitude of the auxiliary voltage.

 Compensator deviations of voltage and reactive power (Fig. 1) according to the proposed method works as follows.

 For small values of the angle φ of the load 12, the voltage boost voltage amplitude has a minimum value (Fig. 2, b), determined by the specified voltage stabilization range, and is regulated only in phase as a function of the deviation of the voltage at the load 12 from a given, for example, nominal, level. In this case, the voltage at the input of a three-phase voltage inverter 2 is lower than the switching level of the control algorithms of the voltage inverter 2 and it works as in the prototype with a 180-degree control algorithm. When the angle φ of the load 12 increases, the signal from the output of the sensor 7 of the reactive power of the network increases. This causes an increase in the voltage at the input of a three-phase inverter 2 and when it exceeds a value that causes a change in the load angle of the inverter from π / 12 to 11π / 12 rad, the duration θ of the conducting state of the thyristors of the three-phase voltage inverter is changed from π to 5π / 6 rad ( Fig. 2, a) by means of a switching device 11. As a switching device 11 (Fig. 4), a comparator 13 can be used that turns off the transistor 14, which shunts the additional resistance 15 of a single-shot 16 designed for delaying the intervals of the conducting state of the thyristors for the time of restoration of their blocking properties, and when this additional resistance is introduced, it increases the delay time to π / 6 rad, thereby reducing θ to 5π / 6.

The device (Fig. 1) that implements the proposed control method provides voltage regulation in magnitude and phase by changing the control angles of the rectifier α _in and inverter α _and . In the compensator, a change in α _{in is} performed as a function of the deviation of the reactive power of the network from the zero level, and a change in the angle α _and - as a function of the deviation of the load voltage from a given level. Such automatic regulation provides stabilization of the load voltage and compensation of the reactive power of the network, regardless of the rigidity of the external characteristics of the network, as well as the magnitude and nature of the load.

 Using the compensator control method allows improving the quality of the power supply to consumers and reducing losses in power lines.

Claims (1)

A method for controlling a voltage and reactive power deviation compensator comprising a three-phase boost transformer with a primary winding connected between the network and the load, and with a secondary winding connected to the star and through a three-phase voltage inverter, a filter and a reversing rectifier connected to the network or to the load, which consists in that the voltage deviations at the load are measured and the first control signal is formed from it, which, acting on the three-phase voltage inverter, changes the phase of the voltage ice additives in the range of 0 - π rad in the lead in relation to the mains voltage, while ensuring the duration of the conductive state of the thyristors of the three-phase voltage inverter, equal to π rad, and also measure the reactive power of the network and form a second control signal from it, which, acting on the reversing rectifier, the voltage amplitude of the voltage boost is changed with the limitation of its minimum value determined by the specified voltage stabilization range, characterized in that the input voltage is measured three-phase of the voltage inverter, compare it with the voltage of a given level and, when this level is exceeded, by correcting the first control signal, the duration of the conductive state of the thyristors of the three-phase voltage inverter is reduced to 5π / 6 rad, while the specified voltage level at the input of the three-phase voltage inverter is chosen such that saved
continuity of currents in the secondary phase windings of a three-phase booster transformer.

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