SU1109857A1 - Harmonic oscillator - Google Patents

Abstract

HARMONIC VIBRATION GENERATOR, containing a middle power point connected in a ring, a first choke, a first cell made in series according to the connected two main thyristors, and a second choke, a second cell made in series in accordance with the connected two main thyristors, the third connected in series the choke, the third cell, filled from sequentially according to the connected two reverse thyristors, and the fourth choke, the fourth 5to cell, made of Consequently, according to the connected two reverse thyristors, two switching capacitors, each of which is connected by one output to the midpoint of the first power source with a midpoint, and the transformer, the first and second primary windings of which are connected respectively between the connection points of the main thyristors of the first cell and the reverse thyristors of the third cell between the main thyristors of the second cell and the reverse thyristors of the fourth cell, and the secondary winding of the transformer is connected to In order to increase the efficiency and frequency of the oscillations, as well as reliability, a second power supply with a midpoint was inserted into it, (the power lines of which are connected to the other terminals of the third and fourth throttles, pefva and second the primary windings of the transformer are made with a medium outlet, the second cell is connected in parallel to the first cell, the fourth cell is connected in parallel, the third cell, the secondary branch of the first and second personal windings of the transformer n sootvetstvuyuscheel to the other terminal of the capacitor kommutirukntsego than the midpoint of the first and second power source to a midpoint, and the other terminals of the switching capacitors are connected to a common bus.

Description

The invention relates to radio engineering and can be used in various DC / AC converters, as well as in radio transmitters. Harmonic oscillators are known that contain a ring-connected power source, a choke and a parallel-connected load and three cells, each of which contains a series-connected main thyristor, a choke with a tap connected to one capacitor and a reverse thyristor, and the other capacitor leads are combined between each other flj. However, this harmonic oscillator does not provide energy recovery to the power source, which does not allow to increase its efficiency ratio (EFF.). The closest to the invention in its technical essence is a harmonic oscillator containing a first power source with a ring in a ring, the first choke, the first cell made of in series according to the connected two main types of tori, and the second choke, the second cell made of consecutively according to united two main thyristors, the third choke connected in series, the third cell made of successively according to the connected two reverse thyristors, and the fourth choke the fourth cell made of successively according to the connected two reverse thyristors, two switching capacitors, each of which is connected by one output the middle point of the first power source with the middle point, and the transformer, the first and second primary windings of which are connected respectively between the points tim main thyristors first cell and reverse thyristors third cell and between the connection points of the thyristors of the second basic cell and inverse moat tiristo fourth cell and the secondary winding of the transformer is connected to the load 2. A disadvantage of the known harmonic oscillator is that there is a current pulse in it until the discharge of the commutator capacitors does not flow through the load. In this case, the CPL of the harmonic vibration generator is not high enough, and overvoltages occur on its elements, which reduces reliability. The frequency of the oscillations generated is not high enough. The aim of the invention is to increase the efficiency and frequency of the oscillations generated, as well as to increase the reliability. The goal is achieved by the fact that in a harmonic oscillator, which contains a ringed first power source with a midpoint, a first choke, a first cell made in series according to the connected two main thyristors, and a second choke, a second cell, filled in series in accordance with the connected two the main thyristors, serially connected third choke, the third cell, made of sequentially according to the connected two reverse thyristors, and the fourth Rossel, h an fourth cell made of serially connected two reverse thyristors, two switching capacitors, each of which is connected by one step to the middle point of the first power source and the middle point, and the transformer, the first and second primary windings of which are connected respectively between the points of connection of the main thyristors of the first cell and the reverse thyristors of the third cell and between the junction points of the main thyristors of the second cell and the reverse thyristors of the fourth cell, and the secondary winding the transformer is connected to the load, the second power source with a midpoint is inserted, the output busbars of which are connected to the other conclusions of the third and fourth chokes, the first and second primary windings of the transformer are made with an average tap, the second cell is connected in parallel to the first cell, the fourth cell is connected in parallel to the third cell , the average tap of the first and second primary windings of the transformer. is connected to another view of the corresponding switching capacitor, and the middle point of the first and a second mid-point power supply, as well as other terminals of the switching capacitors, are connected to a common bus. The drawing shows the circuit diagram of the proposed harmonic oscillator. The harmonic oscillator contains the first 1 and second 2 power sources with mid-points each, the first 3, the second 4, the third 5 and the fourth 6 throttles, the first 7 and the second 8 cells made of consistently according to connected two main thyristors, the third 9 and the fourth 10 cells, made of in series according to the connected two reverse thyristors, transformer 11, first 12 and second 13 primary windings of the transforms Ator 11, secondary winding l4 of transformer 11, load 15, switching capacitors 16 and 17. The harmonic generator works as follows. When the top thyristor of the first cell 7 (according to the drawing) is switched on, the oscillating charge of the switching capacitor 16 occurs through the first choke 3 and the right half winding of the first primary winding 12 of the transformer 11. Through the load 15 a half-wave of current flows, having a shape close to sinusoidal in the direction for my pr. In this case, the switching capacitor is charged to a voltage greater than, where E is the voltage between the grousers of the first power source 1 with a midpoint. Upon completion of the formation of the first (positive) half-wave voltage at the load 15, the reverse voltage is applied to the upper main thyristor of the first cell 7, locking it. At this point in time, when the lower primary thyristor of the second cell 8 is turned on, the oscillating charge of the switching capacitor 17 occurs through the second choke and the first half winding of the second primary winding 13 of the transformer 11. The second half-wave of the current in the direction opposite to the previous one flows through the load 15 a negative half-voltage is formed in the load, and the lower main thyristor of the second cell B is under reverse voltage due to the oscillatory charge of the switching capacitor 17 to the voltage no, more. Then, the upper reverse thyristor of the third cell 9 is turned on and the oscillating discharge of the switching capacitor 16 occurs, the discharge current of which flows through the new half-winding of the first primary winding 12 of the transformer 1 1, the third douq-sel 5 and the second power source 2 with a midpoint. In this case, a positive half-wave voltage is formed in the nugrue-ke 15, and the residual energy of the switching capacitor 16 enters the second power source 2 with a midpoint, the voltage of which is .j. The next (negative) voltage wave in load 15 is formed when the lower reverse thyristor of the fourth cell 10 is turned on and the switch capacitor 17 discharges through the left half winding of the second primary winding 13 of the transformer 11, the fourth choke 6 and the second power source 2 with a midpoint. The full cycle of oscillation formation is waggled with the subsequent alternate switching on of the upper and lower main thyristors of the second 8 and first 7 cells respectively, as well as the upper and lower reverse thyristors of the fourth 10 and third 9 cells. Further cycles are repeated. As the current flows through the load both during charging and when discharging the switching capacitors, the efficiency of the harmonic oscillator increases. The time given to the thyristors to restore their electrical strength increases and becomes more than 3/4 of the frequency period of the generated oscillations, which as a result may be higher than in the known, and with a smaller number of cells. It also increases the reliability of the harmonic oscillator, since the discharge of the switching capacitors to zero eliminates overvoltages on its elements caused by transients.

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Claims (1)

HARMONIC OSCILLATION GENERATOR comprising a first power supply connected to a ring with a midpoint, a first choke, a first cell made of two main thyristors connected in series, and a second choke, a second cell made of two main thyristors connected in series, a third choke connected in series , a third cell made of in series according to the connected two reverse thyristors, and a fourth choke, a fourth cell made of according to the connected two reverse thyristors, two switching capacitors, each of which is connected by one output to the midpoint of the first power supply with the midpoint, and a transformer, the first and second primary windings of which are connected * respectively between the connection points of the main thyristors of the first cell and the reverse thyristors of the third cell and between the connection points of the main thyristors of the second cell and the reverse thyristors of the fourth cell, and the secondary winding of the transformer is connected to the load, I distinguish In order to increase the efficiency and frequency of the generated oscillations, as well as increase the reliability, a second power supply with a midpoint is introduced into it, to the power supply lines of which are connected | Г the other terminals of the third and fourth chokes, respectively, the first and the second primary windings of the transformer are made with a middle tap, the second cell is connected in parallel to the first cell, the fourth cell is connected in parallel to the third cell, the outer tap of the first and second primary windings of the transformer is connected to another terminal with Resp commutating capacitor, the midpoint of the first and second power source to a midpoint, and the other terminals of the switching capacitors are connected to a common bus. 1 1109857 2