RU2703984C2 - Double-channel straightening method - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering, namely to the field of conversion equipment, and can be used for supply of industrial consumers and DC power transmission lines with rectified voltage with twelve pulsations. Frequency of voltage pulsations at rectifier output makes 12 during period of supply circuit and is achieved at absence of phase shift between supply secondary windings of three-phase transformer at proportion of number of turns of feeding secondary windings of main and additional channels in proportion 4 to 1 respectively. At that, it is not necessary to use windings in triangle or zigzag pattern with larger number of turns compared to that of star, thus reducing consumption of active materials of transformer. In the method of double-channel voltage rectification, half of the power valves can be uncontrolled diodes (three-phase bridge of the main channel), the other half must be controlled keys. In case it is not required to control output voltage, it is possible to use common thyristors in additional channel by supplying signal for their opening with some advance. Since the number of turns in the supply winding of the additional channel is four times less, and the main channel can be made on diodes with natural switching of currents, the method ensures good electromagnetic compatibility of the device with the supply network and low level of distortions. Principal difference of method is compensation of variable component in pulsations of main channel by pulsations of additional channel of negative polarity, which do not have constant component of voltage.

EFFECT: formation of rectified voltage at the output with low ripple coefficient with reduction of number of turns of supply three-phase winding relative to the main prototype and reduction of level of switching emissions.

1 cl, 5 dwg, 1 tbl

Description

The technical field to which the invention relates. The invention relates to power electrical engineering, in particular to the field of semiconductor converting technology, and can be used to obtain rectified voltage to power an industrial load and direct current power lines.

The prior art. The prior art method of voltage rectification [Dmitriev B.F., Ryabenky V.M., Cherevko A.I., Music M.M. Marine semiconductor converters: a textbook. - Arkhangelsk: NArFU Publishing House, 2015. - 556 pp.] With 6 ripples of the output voltage, based on the power supply from a three-phase voltage source, then switching the supply voltage, and the duration of the switching periods is 60 electrical degrees with a phase shift of 60 electrical degrees relative to the beginning half waves in phases.

The disadvantages of this solution include a high level of voltage ripple at the output, which makes it unsuitable for powering some DC consumers. Also a disadvantage is the high level of distortion of the currents consumed from the supply network.

The prior art also known a method of voltage rectification [Koptyaev E.N., Balashevich V.M., Abramov S.S. Rectifier with "side" ripple for DC inserts // Electricity. - 2017. - No. 7. - from. 55-59], based on the supply of each of the two channels from three-phase voltage sources, further switching of the supply voltages, the duration of the switching periods in the main channel being 60 electrical degrees at a phase shift relative to the half-waves in phases of 60 electrical degrees, and the duration of the switching periods in additional a channel of 30 electrical degrees with a phase shift of 30 electrical degrees relative to the moments of zero half-waves in phases, then summing the output voltages of the same polar the main and additional channels, and the ratio of the supply voltage of the channels is 2.8 to 1, respectively.

The disadvantages of this solution include the complicated ratio of the turns of the three-phase winding of the main and additional channels by 2.8 times, which leads to the difficulty of its implementation in the manufacture of the transformer. Also, the alternating component of the ripple of the auxiliary channel has the same polarity with the ripple of the main channel, and is added to them, thereby reducing the efficiency of reducing the ripple coefficient and improving the quality of the output voltage.

This technical solution is the closest prototype in essence.

Disclosure of the invention. In modern industrial installations and technological processes, semiconductor rectifiers are used, which have advantages over obsolete electric machine rectifiers. The main advantage of semiconductor converters is the long duration of periods of continuous operation without maintenance, less weight and noise.

Rectifiers are used to power a DC load, and are the most developed and widespread type among all converting equipment. The basics of operation and control algorithms of classical three-phase rectifiers are widely covered in various literature, both educational and scientific [1, 2, 3].

In the last decade, the semiconductor industry has mastered the production of powerful fully controllable switches with high parameters - for almost the entire range of voltages and currents that are in demand in the construction of semiconductor rectifiers, which gave a new impetus to their development.

The introduction of pulse voltage converters, including rectifiers, has an increased switching frequency, which is many times higher than the frequency of the mains, and much more compared to classical converters. However, this leads to an increase in the heat dissipation of the keys, and a decrease in the reliability of their operation - since the switching process is the most stressful mode of operation, accompanied by voltage surges when the current curve breaks. The listed reasons determine the expediency of the development of the classical converting technique, based on switching according to piecewise sinusoidal modulation algorithms - in which fragments of the voltage phases of the supply voltages having one or another period (duration) between the moments of switching and phase shift are used.

The figure 1 shows a schematic diagram of a three-phase rectifier based on a three-phase bridge (switch), using thyristors. It is also possible to install uncontrolled diodes in the circuit, if there is no need to adjust the output voltage level. Such a circuit is basic for all multiphase semiconductor rectifiers, and is described in detail in the literature [1, 2], including control algorithms.

The figure 2 shows a graph of the output voltage of the above three-phase rectifier, the duration of the graph is 2π (360 °), that is, the period of the mains. From the graph it is obvious that during the period of the supply network, six ripples of the output voltage of the rectifier are formed. The number of ripples of the rectified voltage determines its quality and is one of the parameters characterizing its quality.

Figure 3 shows a schematic diagram of a rectifier having two three-phase bridge connected in series according to one another. The voltages of three-phase bridges are summed, which in the presence of a phase shift between the supply windings leads to a doubling of the number of ripples of the output voltage. The voltages of the supplying three-phase windings are set equal to each other, to obtain symmetrical ripples in the mode with natural switching. Thus, a hallmark of the prior art is the use of a phase shift of the supply voltage in the rectification channels, and their equal proportion (level). The schematic diagram shown in figure 3 is used in the rectification method selected for the main prototype, however, through a special sequence of actions (i.e., a key switching algorithm), 12 ripples of the rectified voltage are obtained without using a phase shift of the supply windings. The main advantage of the main prototype is the refusal in the device that implements it of the windings of the triangle and zigzag type, which allows to reduce weight and dimensions. However, to obtain symmetrical ripples, and thus the lowest ripple coefficient, a complex proportion of supply voltages is used, which may not be very convenient when implemented on the basis of a transformer.

The figure 4 shows the voltage graphs in the main prototype [3]. Here 1 is the voltage of the main channel with a large number of turns, 2 is the voltage of the additional channel with a smaller number of turns. The output voltages of both channels are combined with each other, and the polarity of the voltages coincides. This ensures the formation of voltage with 12 ripples at the output of the circuit. This rectification method can be implemented on the basis of a classical circuit with a serial connection of channels (bridges), as shown in figure 3, differs from previously known rectifier control algorithms. That is, the technical effect of the main prototype is achieved precisely by the sequence of actions - and not by the device that implements it.

The figure 5 shows the voltage graphs in the proposed solution. Here 1 is the voltage of the main channel with a large number of turns, 2 is the voltage of the additional channel with a smaller number of turns, 3 is the total voltage of two channels. From the graphs you can see the main distinguishing feature of the proposed solution is the formation of a voltage of negative polarity in the additional channel, that is, its subtraction from the output voltage of the main channel. As a result, the voltage of the auxiliary channel does not have a constant component and interacts with the voltage ripples of the main channel, leading not only to a decrease in their amplitude, but also to an increase in the number of ripples in the output voltage of the rectifier.

As can be seen in figure 5, the voltage of the additional channel does not contain a constant component, and coincides in phase with the ripples in the main channel - but has the opposite polarity. Thus, the maximum ripple of the main channel corresponds to the maximum ripple of the additional channel having a different polarity.

Compensation of the amplitude of the ripple of the output voltage of the proposed solution occurs, which is more effective than the addition of ripple. The symmetry (equality) of the ripple of the output voltage is ensured with a certain proportion of two channels, which is 4 to 1. More voltage corresponds to the main channel, less voltage corresponds to the additional channel.

As is known from the literature [2, 3], in the three-phase network, the half-wave transition points of the voltage are repeated after 60 electrical degrees, thus, such points are the moments of the reference phase shifts for the switching periods of any transformation algorithm [2]. This is used in the description of algorithms, as well as in synchronization nodes of devices implementing them. From the literature it is known that all phases have a symmetric shift, therefore, half-waves of stress alternate in the sequence of phases, and the falling front of the half-wave replaces the rising one. This means that it is fundamentally possible to create any three-phase voltage switching algorithm, when switching occurs at the intersection points of the half-waves with each other (i.e., the equalities of their voltages), called the points of natural switching - ascending and falling voltage fragments will alternate [1, 2 ]. As can be seen from figure 5, the period between switching in the additional channel is 30 electrical degrees, with a zero phase shift relative to the points of equal zero voltage half-waves of negative polarity.

Table 1 presents the control sequence of the main and additional channels in the proposed solution. The table shows that the period between switching of the main channel is 60 electrical degrees (π / 3), the period between switching in the additional channel is 30 electrical degrees (π / 6).

The author believes that the most suitable keys for implementing this method of straightening the device are fully controllable keys, which can be opened and closed independently by signals from the control system. These keys include fully controllable thyristors such as GTO and IGCT. The polarity of the inclusion of the output of the bridges of the two channels is consonant, which is necessary, since the current flows into the load only in the positive polarity - determined by the polarity of the main channel. The negative voltage of the additional channel is then subtracted from the voltage of the main channel, however, the keys in the additional channel will remain open, since the direction of the current flow will coincide with the polarity of their inclusion - and the voltage of the additional channel is much less than basically.

The difference between the proposed method of frequency conversion from the prototype is to use the compensation of the variable component of the ripple voltage of the main channel - voltage of the opposite polarity of the additional channel, in which there is no constant component. Thus, the voltage of the auxiliary channel does not have a constant component level, and interacts only with the variable component of the output voltage of the main channel, reducing it. Such a solution is used for the first time in the converter technology, and fundamentally distinguishes the proposed method of voltage rectification from all others. To ensure the symmetry of the ripple of the output voltage of the two-channel rectifier, a special proportion of the supply voltages of the main and additional channels is used, which is 4 to 1, respectively. All this as a result and provides an output constant voltage with twelve ripples.

The inventive method is a new solution having the following fundamental differences from the prototype:

- set the duration of the switching periods in the additional channel equal to 30 electrical degrees with a phase shift of fragments equal to 0 electrical degrees for ascending fronts, and 30 electrical degrees for descending fronts, counted from the moments of zero half-waves in phases;

- ascending and descending fronts of negative half-waves in the additional channel alternate;

- set the voltage ratio of the primary and secondary channels in a ratio of 4 to 1, respectively.

Thus, the set of essential features of the invention leads to a new technical result - reducing the number of turns of the supply winding and lower levels of switching emissions.

This solution is new, and the entire set of distinctive features is previously unknown from the prior art.

A brief description of the drawings. The figure 1 shows a schematic diagram of a three-phase rectifier. The figure 2 shows a graph of the output voltage of a three-phase rectifier. The figure 3 shows a schematic diagram of a two-channel rectifier. The figure 4 shows the voltage graphs of the main prototype. Here 1 is the voltage of the main channel, 2 is the voltage of the auxiliary channel, 3 is the output voltage of the two-channel rectifier. The figure 5 shows the voltage graphs of the proposed solution. Here 1 is the voltage of the main channel, 2 is the voltage of the auxiliary channel, 3 is the output voltage of the two-channel rectifier.

List of used literature.

1. Kartashov R.P., A.K. Kulish, E.M. Case Thyristor frequency converters with artificial switching. / Kiev: TECHNOLOGY, 1979. - p. 152.

2. Dmitriev B.F., Ryabenky V.M., Cherevko A.I., Music M.M. Marine semiconductor converters: a textbook. - Arkhangelsk: Publishing House of NArFU, 2015 .-- 556 p.

3. Koptyaev E.N., Balashevich V.M., Abramov S.S. Rectifier with "side" ripple for DC inserts. // Electricity. - 2017. - No. 7. - from. 55-59.

Claims (1)

The method of voltage rectification, based on the supply of each of the two channels from three-phase voltage sources, then switching the supply voltages, the duration of the switching periods in the main channel is set to 60 electrical degrees with a phase shift relative to the beginning of half waves in phases equal to 60 electrical degrees, summing the output voltage of the channels characterized in that the duration of the switching periods in the additional channel is set to 30 electrical degrees with a phase shift of 0 electrical x degrees relative to the vanishing points in the negative half-waves of the phases for the uplink half-waves and equal to 30 electrical degrees downward fronts alternation of ascending and descending fronts set voltage ratio of the main and additional channels in a ratio of 4 to 1 at negative polarity supplemental channel.

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