SU917282A1 - Three-phase ac-to-dc voltage converter - Google Patents

Description

(5) THREE-PHASE AC VOLTAGE CONVERTER TO PERMANENT

one

The invention relates to a conversion technique and can be used in a multi-pulse rectification of a three-phase alternating voltage. . .

Three-phase AC to DC converters are known that contain a three-phase transformer whose transformer windings, which are connected in parallel with successively connected pairs of oppositely connected controlled valves, form a star connected to the phase input terminals, and the secondary windings are connected in a star and connected to rectification mate or form a six-phase rectification circuit with a 1P equalization reactor:

The disadvantage of these converters is that they do not provide a twelve-pulse regulation of the rectified voltage.

. A three-phase alternating voltage transformer into a constant voltage converter containing a three-phase transformer with secondary windings connected together with valves according to a twelve-pulse rectifier circuit with primary windings connected by one outputs to phase input terminals, and the other to control valves, is known. forming two separate groups, and additional controlled valves, connected by a common point of opposite electrodes to the zero input terminal C21.

15

The disadvantage of this converter is the impossibility of twelve-pulse straightening with regulation on the primary side and switching on the compensation reactor on

20 secondary side.

The purpose of the invention is to provide a twelve-pulse straightening with regulation on the primary side. 3 9 The goal is achieved by the fact that each common point of the electrodes of opposite valve rpyrin is connected to the free electrode of the corresponding additional controlled valve through the series-connected windings of two double-cooling equalizing reactors, the common points of each pair of windings are interconnected. FIG. 1 is a schematic diagram of the proposed converter with two secondary windings forming a six-beam star and connected to a six-phase valve bridge with two equalizing reactors; in fig. 2 - the same, with two secondary windings connected one to a star, and the other triangle B to a triangle and connected to valve bridges connected in parallel through a balancing reactor. The converter (Fig. 1) contains three-phase transformers 1 and 2. The primary windings 3-5 of transformer 1 are connected to the same output terminals A, B, C, and others to thyristors 6-8 and 9-P, forming respectively the cathode and the anode group, the common points of the electrodes of which are connected to the thyristors 12 and 13 through the half windings 1, 15 and 16, respectively, 17 current dividers with combined average leads. The secondary windings 18–20 and 21–23 of transformer 1 are connected in two counter-connected stars, i.e. form a six-pointed star and are connected respectively with the beginnings a, b, |, c, to the AC clips of the valve bridge assembled on vents x 24-29, and the ends, a, b, c to the AC clips of the valve bridge assembled on gates x 3035. The cathodes of the valves 24-2b are connected to the cathodes of the valves 33-35, and the anodes of the valves 27-29 are connected to the anodes of the valves 30-32 through the half windings of 36, 37 and 38, 39 of the balancing reactors, respectively, to the middle terminals of which the load 40 is connected. and the thyristor 13 cathode is connected to the zero input terminal O, formed by the neutral connected in a star and connected to the phase input terminals A, B, C o6i of the coil 41-43 of the transformer 2, the secondary windings kk-k6 of which are connected to a triangle. The number of turns of the secondary windings of transformer 1 is selected in the ratio equal to: I: (1), as a result of which the symmetrical 12-pulse rectified voltage at load 0 when unlocking thyristors 6-13 and load current J is less than critical JK., I.e. before the equalization reactors enter normal operation, the linear voltages of the windings 18-20 and the sum of the voltages of the same-phase phase windings are 18 and 21, 19 and 22, 20 and 23, respectively. At the same time, the thyristors 6-13 and the valves are unlocked in the sequence, corresponding to the natural alternation of linear and phase network voltages: thyristors 6-10, 6-13, 6-11, 12-11, 7-11, 7-13, 7-9, 12-9, 8-9, 8-13 , 8-10, 12-10; valves 2k-28, 2k-3G, 24-29, 3529, 25-29, 25-31, 25-27, 33-27, 2627, 26-32, 26-28,. When the thyristors are open, 6, 10, i.e. when the magnetizing current of the transformer 1 closes, through its windings 3, the thyristors 6, 10 and half-winding 14, 16 of the current dividers conduct the load current of the valves 24, 28 and it flows through the circuit beginning and the windings 18 - valve 24 the half-wind Zb of the equalization reactor - load 40 - half winding 38 of another equalizing reactor; valve 28 - beginning b; winding 19 end winding 1B. The load component of the primary current is closed along the same circuit as the magnetizing one. When the valve 24 is unlocked, the previously opened valve 34 is locked, winding 22 is de-energized, de-energized and thus the thyristor 12 is locked (hereinafter, the magnetizing component of the primary current is less than the thyristor holding current). Through 15 el. hail, after unlocking the thyristor 6 (the unlocking angle of the thyristors ot is equal to the natural one), the potential of phase A with respect to the common zero becomes greater. than the potential of phase B and the triristor 12 is locked, not only because of the de-energization, but also because of the reverse voltage applied to it. 5 Through 30 el.grad. after unlocking the thyristor 6, the thyristor 13 is unlocked, the valve 30 and the load current flows through the circuit beginning a;) winding 18 - valve 2 - half winding BW of the balancing reactor - load 40 - half winding 39 of the other balancing reactor - valve 30 - end and winding 21 - winding end 18 When unlocking the valve 30, the valve 28 is locked, the windings 19 and L are de-energized, the current is de-energized and thus the thyristor 10 is locked. The load component of the primary current is closed along the same circuit as the magnetizing: rmm 3 of transformer 1 - thyristors 6, 13 - n luobmotki 1, 17 divisors current windings 2, 3 of the transformer 2 - uc Tocnik mains. Through 30 el.grad. after unlocking the thyristor 13, the thyristor 11 is unlocked, the valve 29 and the load current flows through the circuit and winding 18 starts - valve 2 - half winding B 3 of the balancing reactor - loading kO - half winding 38 of the other balancing reactor - valve 29 - beginning from, winding 20 - end of the winding 19 When the valve 29 is unlocked, the valve 30 is de-energized, the winding 21 is de-energized, and the thyristor 13 is de-energized and thus the primary current is closed along the circuit of the transformer 1 of the transformers 6, 11, half-winding rt, 1 & current dividers. Through 15 el.grad. after unlocking the thyristor I (rb-O), the potential of phase C with respect to the common zero becomes greater than the potential of phase A and the thyristor 13 is locked not only because of the obestation, but also because of the reverse voltage applied to the voltage. Similarly, it is possible to trace the load current circuit through the rest of the yents when unlocking the corresponding thyristors in the whole range of variation of the angle оС. When the load current LV is slightly more critical, i.e. when the leveling reactors enter normal operation, the duration of the conduction state of the thyristors and veytiles in the above switching sequence increases, which leads to simultaneous conduction of the number of thyristors and gates. 2 Suppose THAT thyristor 6 and valve 2 are opened at the moment of time when with a phase shift of 30 degrees EL. towards the front, the thyristors 12, 10 and the valves 3, 28 from the rectifying voltage applied to the last, adjacent to the rectifying voltage unlocking the valve 2, are already in a conducting state. The load current flows through the circuit. start by end of winding 19 | then it splits into two equal parts, one of which flows through the winding 18, valve 2, the half-winding Zb of the balancing reactor, and the other through the winding 22, valve 3, the half-winding 37 of the balancing reactor then the load current again flows through the common branch through the load "O , semi-winding- 38 of the surge reactor - valve 28, the beginning of winding 19. The function of the half windings 3 and 37 of the surge reactor, as in the known circuits, is to equalize the instantaneous values of adjacent output-: direct voltages, which ensures the division of the load current into two equal parts flowing through valve 2k and winding 18, valve 3 and winding 22. The semi-winding 39 of another surge reactor is de-energized at this time point, and the half-winding 33 conducts a full load current, as a result of which the magnetic system of this reactor is saturated, i.e. The inductive resistance of the half winding 38 becomes zero and falling. The voltage in this half winding also becomes almost zero. The load component of the primary current of the transformer 1 at the time in question flows through the circuit from the end to the beginning of the winding, k, the source of supply voltage, then splits into two equal parts, one of which flows through the winding 3, the thyristor 6, the half-winding 14 of the divider, and the other through the windings 1 and Ji3 of the transformer 2, the thyristor 12, the half-winding 15 of the current divider, then the primary current of the transformer 1 again flows through the common branch through the floor ;;; winding 16 current divider, valve 10, the end of the winding. Through 30 el.grad. after unlocking the thyristor 6 (((.0) the potential, the phase A relative to the common zero becomes

greater than the potential of phase B and the reverse voltage applied to the thyristor 12 tends to reduce the flow. through it, however, the EMF of the mutual induction of the current divider prevents this by introducing an additional positive voltage across the thyristor circuit 12. In general, the role of the current divider at any time is to equalize the instantaneous values of the currents flowing through its half winding due to the EMF mutual induction of the latter.

Through 30 el.grad. after unlocking the thyristor b, a triggering pulse is applied to the thyristor 13, valve 30 is opened and the load current flows through the circuit, the beginning of the winding 18 - valve 24 - half-winding of the balancing stage, the reactor - load 40, then splits into two equal parts, one of which flows through the half-winding 38 surge reactor, valve 28, winding 19, and the other through the semi-winding 39 of the surge reactor, valve 30, winding 21, then the load current again flows along the common branch from the end to the winding section 18. When unlocked, valve 30 is locked ostomy The winding 22 is de-energized, and thus the thyristor 12 is locked. The leveling function, the instantaneous values of the adjacent rectifying lines, are now performed by the semi-windings 38 and 39 of the equalization reactor. The semi-winding 37 of the other equalizing reactor is de-energized at this point in time, and the half-winding 36 conducts the full load current and its inductive resistance is zero.

The load component of the primary current of the transformer 1 at this time flows through the circuit from the beginning to the end of the winding 3 thyristor b - half winding 1 current divider, then splits into two wounded parts, one of which flows through the half winding 17 current divider thyristor 13, winding k2 and AZ of the transformer 2, the source of the supply voltage, and the other through the semi-winding 16 of the current divider, the thyristor 10, the winding, the source of the supply voltage, then the primary current of the transformer 1 again flows through the common branch through the winding 3.

Further, the processes in the entire range of angle changes are cyclically repeated, i.e. thyristor 11 is turned on, valve 29 is unlocked, valve 28 is locked, and when, for example, the potential of phase C with respect to a common zero becomes greater than the potential of phase A, then the EMF of the mutual induction of the current divider with half windings 1b and 17 prevents it from closing the thyristor 13, i.e. equalizes the instantaneous values of the currents flowing through the half windings 16 and 17. The primary current is conducted by the thyristors 6, 11 and 13,; and the secondary valves 2k, 23 .and 30.

Then after 30 el.grad. the thyristor 12 is turned on, the valve 13 is closed, the valve 35 is opened, the valve 30 is locked and the primary current is conducted by the thyristors 6, 11 and 12, and the secondary valve 2, 29 and 35.

Thus, thyristors 6–13 and .Ventils conduct current in the following sequence:

thyristors 6-10-12, 6-10-13, 6-1113, 6-11-12, 7-11-12, 7-11-13, 7-9-1 7-9-12, - 8-9 -12, 8-9-13, 8-10-13, 8-10-12 ;,

valves 2 -28-34, 2i-28-30, 2 29-30, 24-29-35, 25-29-35, 25-29-31, 25-27-31, 25-27-33, 26- 27-33, 26-2732, 26-28-32, 26-28-34.

Claims (2)

1. Sitnik N.Kh. Power semiconductor technology. M., Energie, 2. USSR author's certificate No. 752681, cl. H 02 M 7/06, 1976. And with “Y ig. one 95 9 A 917282 9