SU1676034A1 - Single-cycle d c-to-d c voltage converter - Google Patents

Abstract

The invention relates to the field of electrical engineering and can be used in secondary power supply sources. The goal is to increase efficiency. The device contains a transistor 1. a transformer 2. a secondary winding 3 of which is connected via a rectifying diode 4 and a filter choke 5 with output terminals 6 and 7 to which the filter capacitor 8 is connected. When transistor 1 is turned on, the voltage across the winding 3 increases and through the unlocking diode 4 a current flows through the inductor 5 and through the diode 9 and the winding 10 of the throttles 11. The reverse current of the locking diode 9 is limited. After the diode 9 is locked, the energy stored in the double-choke choke 11, through the diode 13, charges the capacitor 14 and then is discharged through the diode 15 to the load. 1 hp ff, 2 ill. 3

Description

The invention relates to electrical engineering and can be used in sources of secondary power supply systems of radio engineering, automation and computer technology.

The aim of the invention is to increase efficiency.

In FIG. 1 shows the electrical circuit of a single-cycle converter; in FIG. 2 - diagrams of currents and voltages on its elements.

A single-ended DC-DC converter contains a transistor 1, a transformer 2, the secondary winding of which is connected via a rectifier diode 4 and a filter choke 5 to the output terminals 6 and 7, to which a filter capacitor 8 is connected. The closing diode 9 is connected through the first winding 10 of the two-winding inductor 11, the second winding of which 12 is connected to the auxiliary diode 13, the storage capacitor 14, the discharge diode 15 and the control unit 16.

The converter operates as follows.

When the transistor 1 is on, the load current is flowing! through a rectifying diode 4 and a smoothing filter made on the inductor 5 and capacitor 8, from the secondary winding 3 of the transformer 2, the primary winding of which 17 is connected to the transistor T. The diodes 9 and 15 are turned on, the capacitor 14 is charged (the potential is indicated in brackets). When the transistor is turned on, the diode 15 is unlocked and the capacitor 14 is discharged, and the discharge time of the capacitor 14 is selected 1.2-1.5 times the turn-off time of the transistor 1.

The direct diode 4 is turned off, the capacitor 14 starts to charge (the polarity is indicated without brackets), the current through the closing diode 9 increases and reaches the value of the output current. Before turning on the transistor 1, the output current flows completely through the closing diode, the diode 15 is turned off. When the transistor 1 is turned off, all voltage of the winding 3 is applied to the winding 10 of the inductor 11, almost double the voltage of the winding 3 is induced on the secondary winding 12, which excludes the flow of current in the circuit: winding 3 - diode 13 capacitor 14, since the voltage of the winding 12 of the inductor 11 is greater than the sum voltage of the winding 3 and the capacitor 14 in the recovery interval of the closing diode 9. After the diode 9 is restored, the polarity of the voltage of the inductor winding 12 changes and the capacitor 14 starts charging in the circuit: winding 3 of the transformer 2 - winding 12 of the inductor 11 - diode 13, capacitor 14. At the same time, the output current from the rectifier diode 4 switches to diode 15. After resetting the energy of the inductor 11, the rectifier diode 4 is turned on again, etc.

The reverse current of the diode 9 flows in the interval shown in FIG. 2, and its duration is determined by the properties of the diode 9 and the inductance of the inductor 11. Therefore, the direct current of the diode 4 (figure 2, diagram 20) in the interval to - tt is equal to the sum of the output current and the current of the diode 9. When the diode 9 is restored, a current flows in the diode 13 (Fig. 2, diagram 23,) and this current in the time interval ti - t2 is equal to the sum of the output current and the overdischarge current of the capacitor 14, since the blocking voltage of the winding 12 of the inductor 11 is applied to the diode 4, as evidenced by the failure of the diode current (Fig. .2, diagram 20). In this case, the winding current 3 in the time interval and to - t2 has two pulse currents caused by the diodes 9 and 13 (Figure 2, graphs 22 and 23.). The voltage across the capacitor 14 (Fig. 2, diagram 19) begins to change its polarity after turning on the diode 13. At time x _2, all dynamic processes in the circuit elements end. At time xs, the transistor 1 turns off, the polarity of the voltage of winding 5 (Fig. 2, diagram 18) changes its polarity, reverse current pulses flow through diode 4 and winding 3 (Fig. 2, diagrams '20 and 21). due to the restoration of diode 4, and the capacitor 14 starts to recharge while maintaining the output current, the current through the diode 9 increases (Fig. 2, diagram 22), and when the output current is completely switched to diode 9, the capacitor 14 is charged to a voltage of 0.1-0.3 from voltage across winding 3 and is maintained at this level until the next duty cycle.

In the invention, the instantaneous power loss in the transistor 1 is reduced when it is turned off due to the introduction of a capacitor 14, which increases the efficiency. In addition, the first winding 10 of the two-winding inductor 11 is included in the circuit of the closing diode 9.

Claims (1)

Claim 1. A single-ended DC-DC to DC converter, containing a transistor, the base of which is connected through the control unit to the output terminals, and the power terminals are connected to the input terminals through the primary winding of the transformer, the first terminal of the secondary winding of which is connected to the first output terminal and to the first output of the filter capacitor , the second terminal of which is connected to the second output terminal and connected to the second terminal of the secondary winding of the transformer through a filter inductor and a rectifying diode, point the compounds of which are connected to the first output terminal through a series circuit of a closing diode and a first winding of a two-winding inductor, the second winding of which and the auxiliary diode form a first series circuit, characterized in that. that, in order to increase the efficiency, a second series circuit from a storage capacitor and a discharge diode is introduced, connected between the first output terminal and the connection point of the filter inductor and the rectifier diode, while the first series circuit is connected between the second terminal of the secondary winding of the transformer and the connection point of the storage capacitor and a discharge diode. 10 2. The converter according to claim 1, with the fact that the number of turns of the second winding of the double-winding inductor is two times greater than the number of turns of the first winding.