SU1141540A1 - Versions of d.c.voltage-to-a.c.voltage converter - Google Patents

Abstract

1. A DC / DC converter containing at least one converter cell on the thyristors and a transformer, the transformer primary winding being connected to the cell input through the main thyristors, at least one of the transformer windings is bridged by additional thyristors, the inputs of individual cells are connected with common input pins, output circuits of cells are connected in series and connected to output pins, as well as an emergency switching node formed by Connected to a voltage source and a fully controllable key connected to the cell thyristors with distribution thyristors, the distribution thyristors switching the main thyristors: are connected by one of the power cables to a common point, and the switching node of the distribution thyristors, which are connected in series with an additional source of commirings a voltage and an additional fully controllable key and associated with a common point of distribution thyristors, characterized by in order to simplify it, reduce the cost and increase reliability, sequentially with each distribution thyristor switching an additional thyristor, the primary winding of the input pulse transformer is switched on and this circuit from the winding and distribution thyristor is connected between the connection point of the main and additional thyristors and a common point of distribution thyristors, commuting the main thyristors ,. a The secondary winding of the pulse transformer is connected to the source of supply voltage through the introduced rectifier. 2. DC / AC converter containing at least one converter 1 cell on the thyristors and transformer, with the primary winding of the transformer and the formatter connected to the input of the cell through the main thyristors, at least one of the transformer windings is shunted by additional thyristors, the inputs of the individual cells are connected to the common input terminals, the output circuits of the cells are connected in series and connected to the output terminals, as well as the forced switching node formed by connected by a source of commuting to

Description

connected to the cell thyristors with distribution thyristors, the distribution thyristors switching the main thyristors are connected by one of the power terminals to a common point, characterized in that, in order to simplify it, reduce the cost and increase reliability, with each. distribution thyristor, switching additional thyristor, the primary winding of the inserted pulse transformer and this circuit from the winding and distribution thyristor are turned on between the connection point of the main and additional thyristors and the common point of the distribution thyristors, commuting the main thyristors, the secondary winding of the pulse transformer is connected to the source of supply voltage via the input rectifier, and between the source of the primary winding of the transformer, and the common point of the distribution thyristors, commuting the main thyristors, includes the input choke, parallel to which are connected in series The entered diode and zener diode, are 3. A DC / DC converter containing at least one converter cell on the thyristors and a transformer, with the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings shunted by additional thyristors, the inputs of individual cells are connected to common input pins, OUTPUT

The cell circuits are connected in series and connected to the output pins, as well as a forced switching node formed by switching voltage connected in series and a fully controllable key and connected to the thyristors of the cell by distribution thyristors, the distribution type of the resistors switching the main thyristors are connected by one of the power leads to a common point, characterized in that, in order to simplify it, reduce the cost and: increase reliability, consistently with each additional thyristor, commuting additional

thyristor, the primary winding of the inserted pulse transformer is turned on and this circuit from the winding and distribution thyristor is connected between the point of the main and additional thyristors and the common point of the distribution thyristors switching the main thyristors, the secondary winding of the pulse transformer is connected to the source of supply voltage through the input rectifier, between the pole of the power source connected to the midpoint of the primary winding of the transformer cell, and the common point of the distribution thyri tori, commuting the main. thyristors, is connected through an injected diode, an injected choke, in parallel with which are connected in series the second injected diode and injected zener diode, and the impulse transformer contains an additional injected winding, which through the third injected diode, commuting the main thyristors, and the secondary terminal of this transformer, which is the same with the primary terminals, connected to the common point,

4, DC / AC converter containing

at least one converter cell on the thyristors and a transformer, with the transformer primary winding connected to the cell input through the main thyristors at least one of the transformer windings is shunted with additional thyristors, the inputs of individual cells are connected to common input terminals, the output circuits of the cells are connected in series and connected with output pins, as well as a forced switching node, formed by series-connected switching voltage sources and fully controllable The key is connected to the thyristor cell tori by distributing thyristors, and the distributive circuits that commute the main thyristors are connected by one of the power outputs to a common point, characterized in that, in order to simplify it, reduce the cost and increase reliability, in series with each distribution thyristor switching an additional thyristor, the primary winding of the input pulse transformer is switched on and this circuit from the winding and distribution thyristor is connected between the junction point Ineni main and auxiliary thyristor and the common point of distribution thyristors main switching thyristors, Auto) ichna winding of the pulse transformer inputted through the rectifier is connected to the source voltage pitakscheg, the pulse transformer has two. additionally introduced windings, one of which is connected via an inserted diode between the terminal of the power source connected to the midpoint of the primary winding of the cell transformer and the common point of the distribution thyristors commuting the main thyristors, the second winding is connected through the second inserted diode between this point and the output of the secondary winding of this transformer, of the same name with the primary windings connected to the common point. I

5, Permanent converter

voltage to AC containing at least one converter cell on the thyristors and a transformer, the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings is shunted by additional thyristors, the inputs of individual cells are connected to common input terminals , the k4eeK output circuits are connected in series and connected to the output pins, as well as a forced switching node, which is connected in series by voltage and a fully controllable key connected to the thyristors of the cell by distribution thyristors, and the distribution thyristors switching the main thyristors are connected by one of the power terminals to a common point, characterized in that, in order to simplify it, reduce the cost and increase reliability, in series with each distribution thyristor, commutating additional thyristor, the primary winding of the inserted pulse transformer and this circuit from the winding and distribution tee are switched on the resistor is connected between the connection point of the main and additional thyristors and about (the common point of the distribution thyristors commuting the main thyristors, the secondary winding of the pulse transformer is connected to the source of supply voltage through the input rectifier, the primary winding of the input pulse transformer is connected to the fully controllable switch current, one part of the secondary winding of which is connected through the second input current to the power supply terminals, and the other part of the secondary winding connected through. The introduced diode to the common point of the distribution thyristors commuting the main thyristors.

6. A DC / DC converter containing at least one converter cell on the thyristors and a transformer, the transformer primary winding being connected to the input of the cell through the main thyristors, at least one of the transformer windings is bridged by additional thyristors, the inputs of individual cells connected to the common input terminals, the output circuit of the cells is connected in series and connected to the output pins, as well as the node of the forced switching, formed in series connected by the primary winding of a pulse transformer and a fully controllable key, the secondary winding of this transformer is connected to the thyristors of the cell by distribution thyristors, and the distribution thyristors switching the main thyristors are connected from one of the power outputs to a common one, characterized by the fact that in order to simplify it , reducing the cost and increasing reliability, consistently with each distributor thyristor commuting an additional thyristor, the primary winding is inserted pulse transformer and this circuit from the winding and the distribution thyristor is connected between the connection point of the main and additional thyristors and the common point of the distribution thyristors commuting the main thyristor, and the secondary winding of the switching transformer through the input

The rectifier is connected to the power supply.

7. The converter according to claim 6, characterized in that a separate pulse transformer is included for each additional thyristor.

8. The converter according to claim 6, characterized in that for a group of additional thyristors, a common pulse transformer is included.

9. The converter according to claim 6, wherein the additional thyristors are connected in parallel to each of the halves of the transformer primary winding cell.

go A converter as claimed in claim 6, wherein the additional thyristors are connected in parallel with the primary winding of the transformer of the cell.

11. The converter according to claim 6, characterized in that the additional thyristors are connected in parallel with the secondary winding of the transformer of the cell.

12. The converter according to claim 6, of which is reverse, with reverse diodes included in parallel with the main thyristors.

13. A converter as claimed in claim 6, characterized in that reverse thyristors are connected in parallel with the main thyristors.

The invention relates to converter technology and can be used in power supply and electric drive systems for converting DC voltage to AC.

A known DC / AC converter (inverter) contains a series of thyristor converter cells, the inputs of which are connected to common input terminals, and the outputs are connected in series, and forced switching circuits having a source of constant voltage connected to the main thyristors of the converter cells. through distribution thyristors and switching elements common to the thyristor group P.

The disadvantage of this converter is that the inverter, made according to the scheme with the output of the midpoint of the primary windings of the transformers of the cells, has an increased weight and size. In addition, it contains twice the number of cells to obtain the same shape of the output voltage curve. The inverter, made according to the bridge circuit, has a lower efficiency at low input voltages.

DC-to-AC converters are known, in which a supply voltage source connected through a pulse transformer 21 is used as a source of switching voltage.

These converters have a simpler circuit, but they have the same drawbacks as indicated above.

DC-to-AC converters are known that contain at least one converter cell in transistor output thyristors, the inputs of individual cells are connected to common input leads, and the output circuits are connected in series and connected to output terminals, and a common forced switching node, formed by a series-connected auxiliary source of switching voltage and a fully controllable key, Svnny with Ti; the valve-sided Christors distribute thyristors, the converter cells are made according to the zero scheme, and half of the primary windings of the transformers of the cells are shunted each with additional thyristors, which through additional distribution thyristors and an additional fully controllable key

associated with an additional source of switching voltage 1з1.

A disadvantage of known transducers is the need for two fully controllable keys for the entire impulse cell power, two auxiliary switches and B two sources of switching voltage. Since at large powers the fully control key can contain up to several hundreds of parallel-connected transistors, as well as preliminary cascades, the need for twice the number of elements to turn off the power thyristors complicates the converter, increases its cost and reduces its reliability.

The purpose of the invention is to simplify the converter, reduce its cost and increase reliability.

The goal is achieved by the fact that the DC / DC converter contains at least one converter cell on the thyristors and a transformer, with the transformer primary winding connected to the input of the cell through the main thyristors, at least one of the transformer windings is shunted by additional thyristors , the inputs of the individual cells are connected to the common input terminals, the output circuits of the cells are connected in series and connected to the output outputs, as well as the node forcing switching, formed by a series-connected switching voltage source and a fully controllable key and connected to the thyristors of the cell by distribution thyristors, the distribution thyristors switching the main thyristors connected by one of the power terminals to the common point, and the switching node of the distribution thyristors containing an additional source of commutation voltage and an additional fully controllable switch connected to a common distribution point The thyristors, in series with each distribution thyristor switching an additional thyristor, are connected the primary winding of the inserted pulse transformer and this circuit from the winding and the distribution thyristor is connected between the main and additional thyristors connecting point and the common point of the distribution thyristors switching the main thyristors, and the secondary pulse of the thyristors The transformer is connected to the source of supply voltage through the introduced rectifier.

In the following embodiments of the converter, there is no switching node of the distribution thyristors containing an additional source of switching voltage connected in series, an additional fully controllable key and connected to a common point of the distribution thyristors.

According to the second variant, in the DC / AC converter, between the power supply pole connected to the midpoint of the primary winding T {cell transformer) and the common point of the distribution thyristors commuting the main thyristors, an input choke is inserted, in parallel to which: a series-connected input diode and stabilitron. ; According to the third variant, in the DC / DC converter the voltage between the power supply pole connected to the middle point of the primary winding of the transformer cell and the common point of the distribution thyristors commuting the main thyristors is connected through the injected diode injected choke in parallel with the coaxle connected in series the second injected the diode and the Zener diode inserted, and the pulse transformer contains an additional entered winding, the torus through the third inserted diode is connected between common point of thyristor distribution, commuting the main thyristors, and secondary transformer winding of the same transformer, with the same name as the primary windings connected to said common point.

In the fourth embodiment, in a DC / DC converter, a pulse transformer contains two additional windings, one of which is connected via an input diode between the pole of the power supply connected to the midpoint, the primary winding of the transformer cell, and the common point of the distribution thyristors switching the main thyristors , the second winding is connected through the second inserted diode between this point and the secondary winding of this transformer, which is the same with the terminals ne) a coil connected to said common point. By the fifth variant, the primary winding of the input pulsed current transformer, one part of the secondary winding of which is connected to the power supply terminals, and the other part of the secondary winding is connected in the DC / DC converter to the AC circuit of the fully controllable key. through the introduced diode to a common point of distribution thyristors, commuting the main thyristors. The sixth variant of the DC / DC converter for the forced switching of the main and additional thyristors contains, instead of the source of the switching voltage, the secondary winding of the inserted pulse transformer, the primary winding of which is connected in series with the fully controlled key. Moreover, it can be used as a separate impulse transformer for each additional thyristor, as well as a common impulse transformer for a group of additional thyristors. Additional thyristors can be connected both in parallel to each of the halves of the primary winding of the cell transformer and in parallel with the entire primary (or secondary) winding of the cell transformer. In parallel, the main thyristors can include both reverse diodes and reverse thyristors. FIG. 1-7 show circuit diagrams of the converter options of FIG. 8 — voltage plots illustrating its operation; Fig. 9 is a block diagram of the control system; Fig. 10 is a pulse diagram of the driving oscillator. One cell converter (Fig. 1) contains a transformer 1 with a primary winding consisting of two halves 2 and 3, and a secondary winding 4, main thyristors 5 and 6 through which the primary winding halves are connected to the converter input, additional thyristors 7 and 8 , connected in parallel to the half of the primary winding, reverse diodes 9 and 10 for passing a reactive load current, distribution thyristors 11-14, fully controlled switch-transistor 15, switching voltage source 16 and pulse transformer 17c primary and the windings 18 and 19 and the secondary winding 20. The primary windings 18 and 19 of the pulse transformer 17 are connected in series with the distribution thyristors 13 and 14, and these successive chains are connected between the common connection points of the main and additional thyristors and the common connection point ,. The thyristors 11 and 12 commuting the main thyristors 5 and 6. The secondary winding 20 is connected to the converter input via a diode 21 and is bounded by a reverse diode 22. An additional source 23 and a transistor 24 are turned on to lock the distribution thyristors. The voltage of the source 23 must exceed the input voltage (almost 2-2.5 times), the power of source 23 and transistor 24 is substantially less than the power of source 16 and transistor 15. As sources 16 and 23, for example, rectifiers with filters, can be used. pitak ties from a low-power transistor inverter. In low-power converters, transistor 24 may be replaced by a resistor, however, this is due to the loss of power on it. A resistor 25 can be connected in series with the transistor 15, which limits the switching off current of the power thyristors, a. parallel to the transistor 15 a high-ohm resistor 26 may be connected, reducing the voltage across the transistor 15. in the locked state. To the input of the converter, a source of supply voltage is connected with the polarity shown in Fig. 1, and a load is connected to the output. Fig. 8 shows the output voltage of the Ugyx converter and the control voltages of the thyristors 5-8 and transistors 15; and 24, Uij (S, respectively., W 17 (voltages between the control electrode and the cathode of the thyristors or between the BASE and the emitter of the transistors). The thyristors of the converter are switched as follows. After removing the control voltage from the thyristor 5, which is supplied it is in the interval t (Fig. 8 is supplied with control voltages to the thyristor 11 and the transistor 15 during the time interval required for guaranteed locking of the thyristor 5 at a low reverse voltage (0.9-1.5 V). this time interval from the source As current 16 goes off, the diode 9, thyristor 11, resistor 25 and transistor 15 flow. This current is chosen to exceed the maximum operating current of the thyristor 5. The thyristor 5 in the interval is blocked by the voltage applied to it from the open diode 9. If in the interval r the output diode the converter current has a reverse direction, i.e. the current conducts diode 9, then the turn-off current is added to the current of diode 9. Thus, the thyristor 5 is locked at any direction of the output current of the converter. I When applying the control voltage to thyristors 7 and 8 in the interval Tj, the primary winding of the transformer 1 is short-circuited at any direction of the output current of the converter. Neither the voltage of the output of the transformer (on the winding 4) at eSVm is practically zero. At the end of the zero-pause interval t, the control voltages from thyristors 7 and 8. are removed and, in interval C, control voltages are applied to the thyristor 13 and the transistor 15. If at the end of the interval the output current of the converter had the same direction as that of the thyristor 7 rather than the thyristor 8, the current that passed through the winding 2 and the thyristor 7, in the interval C passes through the winding 2, the thyristor 13, the winding 18, the resistor 25, the transistor 15, the source 16 and the converter power supply. In the winding 20, a countercurrent equal in ampere-turns occurs, a passage of diy through this winding, a diode 21, and a converter power supply (the directions of the currents are shown in Fig. 1 by arrows). In this case, the voltage of the 08 winding on the winding 20 closed through the diode 21 to the input voltage source is almost equal to the voltage of this source. If the numbers of turns of the windings 18 (19) and 20 are equal, then the voltage on the winding 18 (19) is in the interval ((also practically equal to the input voltage of the converter. The thyristor 7 is locked in the interval T along the circuit: the input voltage source, the thyristor 7, thyristor 13, winding 18, resistor 25, transistor 15 and source 16. The voltage of the input voltage source and the TV winding are mutually compensated, and if the thyristor 8 is locked in the interval, the blocking voltage of the source is applied 16 minus the drop voltages on elements 13, 25, and 15. If The side of 8 V is open, there is a large positive voltage (1.2-1.8 V) on the non-interval, it shunts both winding 3 and winding 2, the voltage on these windings is equal, and the same negative voltage is applied to the thyristor 7 In this case, the source 16 is closed to series-connected resistances of open thyristors j 8 and 13, transistor l5, diode 21, resistor 25, windings 2, 3, 18 and 20. By selecting the voltage of source 16 and the ratio of the number of turns of the windings 18 (19) and 20 is set in the first case, the negative voltage on the 7th resistor in the interval T is equal to 1-1.5 In, in the second - the current from. source 16, the greater the operating current of the winding 2 in this interval. Since in both cases the voltage on the thyristors 7 and 8 and the windings 2 and 3 are no more than 1-2 V, i.e., about the same as in the interval, in the interval the output voltage is " "The converter is practically such an interval. closer, as in the interval to oh to zero. After the interval 4 ends, the transistor 15 is closed, in the interval fg the control voltage ha is applied to the thyristor 6, it is unlocked and the supply voltage is applied to the winding 3. If in the interval. the thyristor 8 is open, it is locked by the reverse voltage of the winding 3. Thus, the formation of a negative stage of the output voltage curve begins. The thyristor 11 is locked after the interval i, and the thyristor 13 after the interval. Although after these intervals the operating current of the thyristors is overloaded by closing the transistor 15, however, if the holding current of these thyristors is less than the sum of the leakage current of the transistor 15 (especially if the transistor 15 consists of a large number of parallel-connected transistors) and the leakage currents of the distribution thyristors of other cells, forced closure of distribution thyristors is required. To do this, after the transistor 15 is closed, the transistor 24 is opened during the interval 50–200 µs (depending on the type of distribution thyristor) transistor 24 (intervals tg, fig 2) and the supply voltage 23 is applied to the distribution thyristor, which must exceed the input voltage of the converter. The current delivered by the source 23 and flowing through the transistor 24 must exceed the sum of the leakage currents locked by the transistor 15 and the distribution thyristors. Similarly, the thyristors 6 and 8 are locked in the intervals tg and € g. The no-load current, caused by the flux accumulated in the transformer 17 magnetic circuit, at intervals f and fg-, after the termination of these intervals, closes diode 22, to accelerate the absorption of this flux with a large number of cells in series with the diode a zener diode can be switched or the winding 20 may be shorted to an output voltage source not only for direct countercurrent, but also for reverse idle current, for example,. through a rectifying bridge or through a two-half-rectifier with a middle point in this winding. Since the locked transistor 15 and the distribution thyristors in the intervals are connected in series, when a large input voltage is applied to the converter to reduce the voltage on the locked transistor 15, a high-resistance resistor 26 can be connected in parallel with it is substantially less than the input voltage, and only

short intervals - g applied voltage to it.  The polarity of the voltage is the sum of the input voltage and the voltage of the sources 16 and 23. At intervals, the sum of the leakage currents and the current of the resistor 26 flows through the open transistor 24 and the source 23, to simplify the converter (exclude the additional source 23 and the transistor 24) To lock the switching thyristors, choke 27 can be used, in parallel with which are connected series-connected Zener diode 28 and diode 29 (FIG. 2). At intervals ,, Cg and d, the sum is applied to the choke 27 through the open transistor 15. of the voltage and voltage source 16, willows magnitnm these intervals and current flow throttle increase linearly from zero.  After the end of these intervals, the transistor 15 is closed and in the intervals Td the magnetic flux and the droplet current decrease linearly to zero.  The decreasing throttle current flows through the stabilizer Ron 28 and the diode 29, the voltage across the pull in the C intervals, has the form of a rectangular pulse with an amplitude equal to the stabilization voltage of the Zener diode 28 and the polarity shown in FIG. 3, the stabilization voltage of the zener diode 28 is chosen to be greater than twice the input voltage.  In this case, the thyristors 11 and 13 are locked in the IQ intervals as follows.  The thyristor 11 is locked after the interval L on the circuit: the thyristor 11, the choke 27, the winding 2 of the transformer 1, After the interval C, the windings of the transformer 1 are shorted by thyristors 7 and 8 and the thyristor 11 is locked in the interval With the aforementioned throttle pulse 27, The thyristor 13 is locked - after the interval G ,)     contour: thyristor 13, winding 18 of transformer 17, choke 27, winding 2, After the interval, the voltage on winding 2 is equal to the input voltage.  pr.  Idling current trance. . .  formatter 17 after the intervals and flows through the winding 30 or 31 and the diode 32 or 33.  It is advisable to simultaneously wind two wires of winding 18 and 30 (19 and 31) simultaneously.  With equal number of turns. The windings 18 and 30 (19 and 31), the voltage on the winding 18 after the interval is also equal to the input on the windings 2 and 18 after the interval G are shown in FIG. 2  The thyristor 13 is locked in the interval tg by the difference of said pulse of throttle 27 and the sum of the voltages of windings 2 and 18.  In order to discharge current thyristors that short-circuit the transformer windings of the cell, they can be connected in parallel with the entire primary or secondary winding of the transformer.  FIG. 2 thyristors 7 and 8 are connected in parallel with the entire primary winding of transformer 1.  This provides a decrease in current through the thyristors 7 and 8 in.  two times compared with the converter in FIG. 1 when the voltage across them is doubled in the locked state (equal to the voltage on the main thyristors 5 and 6).  . With small inductances, the dissipation of the transformer windings can short-circuit the thyristors can be connected in parallel to the secondary winding, and if the transformer is increasing, the current through these thyristors decreases in the transformation ratio, respectively, the voltage on the thyristors is negative, however the design of the transformer with small the inductance of the scattering windings is somewhat more complicated.   WITH.  in order to increase the 1-SPD converter instead of the reverse diodes 9 and 10 (FIG. 1) thyristors 34 and 35 can be switched on (FIG. 2).  At the same time, thyristor 34 (35) needs to be supplied with the same control voltage as thyristor 5 (6), however, control voltage should be removed from thyristors 34 (3 should be 20-30 µs before the end of the interval. With inductive load a converter with cosV less than 0.7-0.8, which in practice usually takes place, at the end of the intervals and the switchable current flows through the thyristors 5 and 6, and not through the thyristors 34 and 35.  Therefore, in intervals Jg and Tg in steady state operation, the thyristors 34 and 35 are locked and do not short the source 16 through these distribution thyristors 11 (12) and the transistor 15.  The current consumed in these intervals from the source 16 is equal to the current of the primary winding of the transformer 1, and does not exceed this current with a large margin, as in the converter in FIG. one.  With pain. The maximum number of cells may be 114 12.  reach a few percent.  Since the voltage of source 16 is no more than a few volts, a voltage of about 1-2 V is applied to lockable thyristors 5 and 6 at intervals of t and the form of the output voltage of the converter is almost not distorted.  Some drawback of the converter in FIG. H is a 2.2-2.5 times shorter time duration for locking distribution thyristors 11-14 as compared to locking time for power thyristors 5-8.  This is due to the fact that the current and flow of the throttles 27 increase in the intervals AND T / g with a voltage across the 6 throttle, approximately equal to the input, and decrease with a reverse voltage on the throttle 2.2-2.5 times greater than the input, and the duration of the intervals of La, respectively, 2.2-2.5 times less. the duration of the intervals r T, g; If faster thyristors are taken as distribution thyristors than power j, then this is insignificant, and if they are analogous to power, then this one. the disadvantage is eliminated by using the converter in FIG. H.  In the converter (FIG. 3) the transformer 17 contains an additional winding 36, which is connected at one end to the secondary; winding 30, the second through diode 37 is connected to the common connection point of distribution thyristors 11 and 12.  The number of turns of the winding 36 is 2.2-3 times the number of turns of the winding 30, the winding 36 can be wound with a very thin wire, calculated ka leakage currents of the locked transistor and distribution thyristors.  The stabilization voltage of the zener 28 is approximately equal to the input voltage, and after each turn off of the transistor 15 on the inductor 27, a rectangular voltage pulse is formed polarity polarity the same as in FIG. 2, with an amplitude approximately equal to the input voltage, and a duration approximately equal to the open state duration of the transistor 15.  This pulse locks the distribution thyristors 11 and 12 after the intervals Cd and f. The distribution thyristor 13 is locked after the interval fjf along the circuit: thyristor 13, winding 18, diode 37, winding 36, winding 30, input voltage source, winding 2 of transformer 1.  . The polarities of the stresses on the windings after interval G are shown in FIG. H.  The voltages on the windings 2, 18 and 30 are almost equal to the input, on the winding 36 - to 2, for more input, and the difference of the sum of voltages on the windings 36 and 30 n of the sum of the input voltages and on the winding as 2 and J8 thyristor 13 through the diode 37 is closed in the interval d (with a trace after the interval and approximately equal to it).  Diode 38 responds to choke 27 from the thyristor connection point. 11 and 12 at intervals and g.  In order to simplify the converter in FIG. H can be excluded droselle, while in the transformer 17 (Fig. 4) an additional winding 39 is introduced, the number of turns of which is slightly more (by 5-15%) the number of turns of winding 18 (19).  In intervals of G; and Sg winding 39 is connected to an input voltage source and a source 16 through a diode 38 and an open transistor 15.  In this interval, a flux accumulates in the magnetic conductor of the transformer 17, which in the interval Gd following the intervals or C and practically equal to these intervals creates a no-load current flowing through the winding 30, diode 32 to the input voltage source.  The thyristor 11 is locked along the circuit: the thyristor 11, diode 37, winding 36, winding 30, input voltage source, winding 2 of the transformer 1.  The polarity of the voltage on the windings 36 and 30 in the interval fg after the interval T is shown, the voltage on the short-circuited winding 2 is close to zero.  Thyristor 11 is locked by the difference of the sum of the voltage on the windings 36 and 30 and the input voltage.  In the interval or Vg, the sum of the input voltage and the voltage of source 16 is applied to the winding 18 or 19.  Since the number of turns of the winding 39 is greater than the number of turns of the winding 18 or 19, the voltage across the winding 39 is greater than that of the winding 18 or 19.  In the interval 2Г or tg, the ends of the windings 39, 18 and 19, indicated in FIG. 4 points connected to the positive input voltage bus (end of the winding 39.  - directly, the ends of the winding 18 or 19 - through the opening thyristor 13 or 14 and the primary winding of the transformer 1, shorted in these intervals by open thyristors 7 and 8).  Therefore, in the INTER in al and the potential of the opposite end of the winding 39 is more minus than the potentials of the opposite ends of the windings 18 and 19, the diode 38 is locked and the winding 39 is at intervals and t is disconnected.  The thyristors 13 and 14 are locked in the intervals Y following the intervals and are the same as in the converter in FIG. H.  x In the converters in FIG. 2-4 in the intervals of the first transistor, the sum of the input voltage and the voltage of the additional source of the switching voltage is applied.  If the input voltage is large, then in order to reduce the voltage across the locked transistor at these intervals, use the converter in FIG. 5, in which a high voltage is applied to the locked transistor only in short The inverter co-intervals hold the transistor 15, the pulse transformer 17 and the current transformer 40, the primary winding 41 of which is connected in series with the transistor 15, a portion of the secondary winding 42 is connected through a diode bridge 43 to the input source the voltage, and the entire secondary winding 42, 44 is connected through a diode 45 to a common connection point of distribution thyristors, the main thyristors commuting (the winding 41 contains. several turns, windings 42 and 44 are up to several hundred and wound with a thin wire, while the number of windings 44 is 2.2-2.5 times the number of turns of the winding 42).  In the intervals r t −4 5 -g - in, a current of the transistor 15 passes through the winding 41, the signs of the voltages on the windings in these intervals are shown in FIG. 5, in the magnetic core of the transformer 40.  at the same time linearly increases flow.  After locking the transistor 15, this flow decreases linearly in the intervals of d.  At the same time, a linearly falling current flows through the winding 42 and the bridge 43, the voltage on the winding 42 is almost equal to the input.  The voltage signs on the windings and the intervals 2d are inverse to those shown in FIG. five.  The voltage of the winding 44 in the intervals 2 locks the distribution thyristors 11-14.  The number of turns of the winding 44.  the dimensions of transformer 40 can be significantly reduced. if an additional winding 36 is connected to the common transistor 17, connected via diode 37 to a common connection point of distribution thyristors that commute the main thyristors.  The thyristors 11 and 12 are then locked from the winding 44 through the diode 45, the thyristors 13 and 14 from the winding 36 through the diode 37.  FIG. Figure 6 shows a converter circuit containing, for example, two converter cells, which makes it possible to obtain an output voltage closer to a sinusoid, and thereby reduce the mass and dimensions of the output filter if it is necessary to obtain a sinusoidal output voltage.  This converter does not have a separate switching voltage source, for which the input voltage source and the pulse transformer 46 with the primary 47 and the secondary 48 windings are used.  Primary winding 47 through the key transistor 15 is connected to the input voltage source.  In the intervals S and tg, the transistor 15 is open, the voltage on the primary winding is almost equal to the input, on the secondary it is the voltage required from the switching voltage source, which is achieved by choosing the transformer ratio 46.  The polarity of the voltage on the windings at these intervals is shown in FIG. 6  Thus, winding 48 at these intervals is a source of switching voltage.  Accumulated in these intervals, the current in the magnetic circuit of the transformer 46, after the termination of these intervals, creates a current x; a cavity course, flowing through the primary winding 47, a hundred bilitron 49 and a diode 50.  This current decreases linearly to zero in the intervals of i-d.  In these polarity intervals, the stresses on the windings of the transformer 46 are inverse to those shown in FIG. 6  By choosing the voltage of the stabilization of the Zener diode 49, the sum of the voltages across the windings as 47 and 48 in the intervals tg is set to a greater double the input voltage.  The total voltage ob1 of coil 47 and 48 in the intervals tg is applied between the common connection point of the distribution thyristors, commuting the main thyristors, and the positive pole of the input voltage source and locks the distribution thyristor. ora.  In order to simplify the design of a pulse transformer for switching additional thyristors, for switching each of the additional thyristors, a separate pulse transformer containing two windings wound simultaneously with two wires is used.  In the converter of FIG. 7 are transformers 51-54.  Diodes 55-58 and Zener diode 59 serve to pass the no-load current of transformers 51-54 after the end of the intervals vT, -4 -b & The magnetic link is more complete. between windings and work each. Transformer only once per period also ensures the operation of such a converter at higher frequencies.  To limit the breaking current in series with the winding 48, it can be.  resistor 60 is on.  The block diagram of the converter control system shown in FIG. 1 is shown in FIG. 9.  This control system generates control pulses,; %, - Ujj, and Uyg (FIG. eight) .  The control system contains a master oscillator 61, generating short rectangular pulses, the input of a single vibrator 62 is connected to the output of this generator, the input of a single vibrator 63 is connected to the output of this single vibrator, and the input of a single vibrator 64 is connected to the output of this single vibrator.  To the output of the one-shot 62 is also connected to the input of the counting trigger 65.  The outputs of the one-shot 62-64 and counting, trigger 65 are connected to the telephone inputs O, o, b and 2.  Converter 66 double code to positional number.  The outputs of odnirvibrator 62 and 64 is connected to the input element 2I 67, the output of which is connected to the input of the one-shot 68. - To six outputs (b, & x, 5, U, K) of converter 66, to the outputs of the one-shot 63, element 2I-67 and the one-shot 68 are connected key power amplifiers 6978, amplifying the output signals of the microcircuits to the power levels necessary for controlling thyristors and transistors are transformed.  spinner  If it is necessary to stabilize the output voltage of the converter, a step-down transformer 79 is included in the control system, the primary winding of which (point L) is connected to the output of the converter, the input of the diode output 80 is connected to the second winding, and the output of the filter 81 is connected to the output.  One of the inputs of the operational amplifier 82 is connected to the output of the filter, the source 83 of the reference voltage is connected to the second input of the input, and an input is connected to the output of the operational amplifier. one-shot 63, which is governed by the duration of its output pulse.  The control system works as follows.  The output pulses for the generator 61 (FIG. 10) a one-shot 62 is started with a falling edge, the output pulses of which trigger a one-shot 64 using a falling edge. Front count trigger 65. The output pulses of the one-shot 63 rear edge start the one-shot 64.  The output pulses of the one-shot 62-64 and counting trigger 65 are fed to the inputs d, 8, b and d of the converter 66, creating four bits of the binary code on them (input O is thousands, input d is hundreds, input b is tens, input t - units).  Each binary number at the inputs of converter 66 is associated with a unit at one of its outputs with zero x at all other outputs.  In the interval t, the number 0000 comes to the inputs of the converter 66 (FIG. 10), where 1 is at the output and the control pulse Uijj is at the output of amplifier 69 (FIG. 9 and 10). Accordingly, in the intervals t,) $ gi and tg; the inputs of the converter 66 come in the number 1001; 0011, 0001, 1000 and 0010; the units at the outputs, and, b, and it, alternately take place, and at the outputs of the amplifiers 71, 73, 70, i72 and 74, control pulses appear alternately, and, Uy, U (and (fig. ten).  . . . . . -.  The control pulses Uu and Ut in the intervals are taken separately.  sredstventstso from the output of the single 63 output through the drivers 75.  and 76 (FIG. 9), galvanically isolating inputs of thyristors 7 and 8 (in the transducer & FIG. 1 this separation is not needed and 1G4 18 both impulses of the Ts. and and. "May be removed from the output of one of the amplifiers, the second amplifier may be absent).  The Iktulsa from the outputs of the one-shot 62 and 64 are summed by the element 2I 67 / and fed to the input of the amplifier 77, from which output the control pulses Uy 45 are removed. , from the output of the latter, the control pulses are removed. The feedback (elements 79-83) stabilizes the output voltage of the converter (for example, by the mean value) by adjusting the duration of the pause of the output voltage (the duration of the control impulses cos A control system Uyi transducers according to the schemes of Fig. 2-5 is different from the system in FIG. 9 by the absence of elements 68 and 78.  For converter control systems in FIG.  3-5, the output 66 of the converter 66 of one of the inputs of the input element 2I is necessary; the output of the key power amplifier is connected to the output; a reverse thyristor control signal, for example, UtA, is removed from the output of the latter. 2  The input of the master oscillator 61 is connected to the input of the input element HE, the output of which is connected to the second input of said element 2I.  Thus, the control pulse will repeat the pulse Uyj- (FIG.  10), but con-  chats. before it for the pulse duration Ug (,) t. 6i, which must be set within 20-30 µs.  By connecting a similar node to the output of the transducer 66, the control signal of the second reverse thyristor is generated, for example, the control of the thyristor 35 in the converter in FIG. 3  The converter control system in FIG. 6 and 7.  may contain, for example, two described control systems with a fixed or adjustable phase shift between the pulses of two generators 61, one of which is zadakshimi, and the second is known.  If necessary, stabilize the output voltage

19114

The stabilization unit 79-83 in this system is only one, from its output (from the output of element 82) of control, the signal is fed to the control inputs of the pulse duration of both elements 63 and to the input of the phase control element of the two generators. 61.

1540

20

The technical and economic efficiency of the invention consists in simplifying the converter, cheapening it and increasing its reliability due to a halving in comparison with the prototype of the number of transistors of the key for switching the power thyristors.

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Claims (12)

1. A DC-to-AC converter containing at least one converter cell on thyristors and a transformer, the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings shunted by additional thyristors, the inputs of individual cells connected to the common input conclusions, the output circuit of the cells are connected in series and connected with the output conclusions, as well as the node of the forced switching formed in series with a distributed source of switching voltage and a fully controllable key and distribution thyristors connected to the cell thyristors, the distribution thyristors switching main thyristors: connected by one of the power terminals to a common point, and the switching thyristor switching node containing an additional switching voltage source and an additional fully connected controlled key and associated with a common point of distribution thyristors, characterized in that, with the goal In order to simplify it, reduce cost and increase reliability, a follower thyristors switching main thyristors, · a Secondary winding of a pulse transformer through an introduced rectifier is connected to a power supply go on. straining. 2. A DC to AC converter containing at least one converter cell on the thyristors and a transformer, the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings shunted by additional thyristors, the inputs of individual cells connected to the common input conclusions, the output circuit of the cells are connected in series and connected with the output conclusions, as well as the node of the forced switching formed in series with the source of switching voltage 1141540 and a fully controllable key and connected to the thyristors of the cell by distribution thyristors, and the distribution thyristors switching main thyristors connected by one of the power outputs to a common point, characterized in that, in order to simplify it, reduce cost and increase reliability, in series with each distribution thyristor switching an additional thyristor, the primary winding of the introduced pulse transformer is turned on and this circuit from the tap and distribution thyristor is connected between the connection point of the main and additional thyristors and the common point of distribution thyristors switching the main thyristors, the secondary winding of the pulse transformer through the introduced rectifier is connected to the supply voltage, and between the pole of the power supply connected to the middle point of the primary winding of the cell transformer , and the common point of the distribution thyristors switching the main thyristors is the introduced inductor, in parallel, to the diode and the zener diode <- 3. A DC / AC converter containing at least one converter cell on the thyristors and the transformer, the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings shunted by additional thyristors, the inputs of the individual cells connected to the common input conclusions ·, output · cell circuits are connected in series and connected to output terminals, as well as the forced switching unit formed in series a single source of switching voltage and a fully controlled key and distribution thyristors connected to the cell thyristors, the distribution thyristors switching main thyristors connected by one of the power outputs to a common point, characterized in that, in order to simplify it, reduce cost and to increase reliability, in series with each distribution thyristor switching an additional thyristor, the primary winding of the introduced pulse transformer and this circuit from the winding and the distribution thyristor is connected between the point of the main and additional thyristors and the common point of the distribution thyristors switching the main thyristors, the secondary winding of the pulse transformer through the introduced rectifier is connected to the supply voltage, between the pole of the power source connected to the middle point of the primary winding of the cell transformer, and the common point distribution thyristors, switching main. thyristors, connected through the entered diode introduced choke, pair in parallel with which the second inputted, diode and introduced zener diode are connected in series, and the pulse transformer contains an additional input winding, which, through the third input diode, is connected between the common point of the distribution thyristors switching the main thyristors and the output of the secondary winding of this transformer of the same name as the primary terminals windings connected to said common point. 4. A DC-to-AC converter containing at least one converter cell on thyristors and a transformer, the primary winding of the transformer being connected to the cell input through the main thyristors, at least one of the transformer windings is shunted by additional thyristors, the inputs of individual cells are connected to common input terminals , the output circuits of the cells are connected in series and connected to the output terminals, as well as the forced switching unit formed in series with an internal switching source and a fully controllable switch connected to the thyristors of the cell by distribution thyristors, the distribution thyristors switching the main thyristors connected by one of the power outputs to a common point, cast in that, in order to simplify it, reduce the cost and increase reliability , in series with each distribution thyristor switching an additional thyristor, the primary winding of the introduced pulse transformer and this circuit from the windings are turned on and distributive thyristor connected between the connection point of the main and auxiliary thyristor and the common point of distribution thyristors main switching thyristors, a secondary winding of the pulse transformer inputted through the rectifier is connected to a source of supply voltage, wherein the pulse transformer has two. additionally introduced windings, one of which is connected through the introduced diode between the point of the power supply connected to the midpoint of the primary winding of the cell transformer and the common point of the distribution thyristors switching the main thyristors, the second winding is connected through the second introduced diode between this point and the output of the secondary winding of this a transformer of the same name with the terminals of the primary windings connected to said common point. I 5. A DC-to-AC converter containing at least one converter cell on the thyristors and a transformer, the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings shunted by additional thyristors, the inputs of individual cells connected to common input terminals, the output circuits of the cells are connected in series and connected to the output terminals, as well as a forced switching unit formed in series with the source of switching voltage and a fully controllable switch connected to the cell thyristors by distribution thyristors, and distribution thyristors switching main thyristors connected by one of the power outputs to a common point, characterized in that, in order to simplify it, reduce cost and increase reliability, with each distribution thyristor switching an additional thyristor, the primary winding of the introduced pulse transformer and this circuit from the winding are turned on and the distribution thyristor is connected between the connection point of the ochobib and auxiliary thyristors and the common point of the distribution thyristors switching the main thyristors, the secondary winding of the pulse transformer is connected to the supply voltage through the introduced rectifier, the primary winding of the introduced pulse current transformer is included in the circuit of the fully controlled switch , one part of the secondary winding of which is connected through the second introduced rectifier to the terminals of the power source, and the other part the secondary winding is connected through. the introduced diode to the common point of the distribution thyristors commuting the main thyristors. 6. A DC / AC converter containing at least one converter cell on the thyristors and the transformer, the primary winding of the transformer connected to the input of the cell through the main thyristors, at least one of the transformer windings shunted by additional thyristors, the inputs of the individual cells are connected to common input pins, the output circuit of the cells are connected in series and connected to the output pins, as well as the unit for direct switching formed in series with by the primary winding of a pulse transformer and a fully controlled key, the secondary winding of this transformer is connected to the thyristors of the cell by distribution thyristors, and the distribution thyristors, switching main thyristors, are connected by one of the power outputs to a common point, characterized in that, in order to simplify it, reduce cost and to increase reliability, in series with each distribution thyristor switching an additional thyristor, the primary winding of the pulse transformer and this circuit from the winding and distribution thyristor is connected between the connection point of the main and additional thyristors and the common point of distribution thyristors switching the main thyristors, and the secondary winding of the pulse transformer through the introduced rectifier is connected to a supply voltage source. 7. The converter according to claim 6, characterized in that a separate pulse transformer is included for each additional thyristor. 8. The converter according to claim 6, characterized in that for the group of additional thyristors a common pulse transformer is included. 9. The converter according to claim 6, characterized in that the additional thyristors are connected in parallel to each of the halves of the primary winding of the cell transformer. r0. The converter according to claim 6, characterized in that the additional thyristors are connected in parallel with the primary winding of the cell transformer. 11. The Converter according to claim 6, characterized in that the additional thyristors are connected in parallel with the secondary winding of the cell transformer. '' 12. The Converter according to claim 6, about t · l and with the fact that in parallel with the main thyristors reverse diodes are connected. 13. The converter according to claim 6, characterized in that the reverse thyristors are connected in parallel with the main thyristors.