SU1713063A1 - Two-way self-exciting inverter - Google Patents

Abstract

The invention relates to electrical engineering and can be used in secondary power supply systems. The purpose of the invention is to increase reliability by reducing the dynamic power loss in power transistors. In a half-bridge self-exciting inverter, the power transistors 11, 12 switch when saturating the driver throttle 10. When the power transistor is turned off, the front voltage rise of the voltage applied to it increases due to the charging of the switching capacitors 15, 26 using switching resistors transistors 21, 22 provide sim_metrirovanie half-periods of the output voltage of the inverter and protection against current surges collector power transistors 11, 12. Auxiliary transistors 31-34 and compensating di Odes 43. 44 provide automatic control of the saturation depth of the power transistors 11, 12. 1 Cp f-ly, 1 il.sls

Description

The invention relates to electrical engineering and can be used in secondary power supply systems.

Half bridge inverters are known in which RCD circuits form a safe switching mode for power transistors.

The disadvantage of this device is the presence of reliability-reducing resistors in the forming RCD circuits.

The closest in technical essence to the present is a self-propelled one; a bobbing inverter containing an output transformer with a primary winding, a secondary winding, positive and negative feedback windings, two transistor switches, each

which consists of a power transistor, shunted by a reverse diode, an additional transistor, the first and second auxiliary transistors, the first and second measuring resistors, the switching transistor, the base of which is connected to the master throttle through the first limiting resistor and the compensating diode whose anode is connected to, base of the additional transistor, and the cathode with the collector of the power transistor, and a parallel resonant circuit consisting of a capacitor and droplets, shunted a resistor. The presence of additional and auxiliary transistors with measuring resistors and a compensating diode increases the reliability of the inverter by reducing the dynamic power losses in the power transistors by reducing their turn-off time, achieved by reducing the saturation factor by adjusting the power transistor base by the additional and auxiliary transistors as a function of the current of its collector. However, in this inverter circuit, a double supply voltage is applied to the power transistors, which is additionally superimposed by switching surges arising in the dispersion inductances of the power transformer, which leads to an increase in the dynamic power dissipated by the power transistors and, accordingly, to a decrease in reliability .

The aim of the invention is to increase the reliability of the inverter by reducing the dynamic power loss in the power transistors.

The goal is achieved in that the transistor switch of a self-exciting push-pull voltage inverter contains an output transformer with a primary winding, a secondary winding and two negative feedback windings, a time setting choke and two transistor switches, each of which consists of a power transistor shunted by a reverse one diode, auxiliary transistor, the first and second auxiliary transistors, the first and second measuring resistors, the switching transistor, the base of which wired through the first limiting resistor connected to the first terminal of the winding time of the master throttle, and the compensating diode connected by the base of the additional transistor and the collector of the power transistor, a rectifying diode, filter capacitor, positive feedback diode, first and second feedback resistors are introduced , a resistive current sensor, a second limiting resistor and a switching capacitor, and the transistor switches and the primary winding of the output transformer are connected in ph lumostar with Birmingham, time specifying choke configured two-winding, each winding its second terminal through a corresponding winding of the negative feedback output transfrrmatora connected to the common point of the transistor switch, a capacitor connected in parallel with the switching power transistor in the emitter circuit of the power transistor included resistive current sensor coupled via

the second limiting resistor with the base of the switching mutant transistor, the rectifying diode of the first output is connected to the second output of the winding

5 throttles, and the second output with a common point of the transistor switch through the filter capacitor and with the emitter of the second auxiliary transistor, the collector and the base of which are connected by the corresponding base

0 and the emitter of the first auxiliary transistor, connected in series between the base and the emitter of the second auxiliary transistor, are connected in series the first and second measuring resistors,

5, the connection point between which is connected to the collector of the additional transistor connected by the emitter to the base of the power transistor and the base to the collector of the switching transistor and to

0 to the collector of the first auxiliary transistor, the first feedback resistor is connected in parallel with the second auxiliary transistor, the collector of which is connected via series to the second feedback resistor and the positive feedback diode to the collector of the power transistor. In addition, the base of the additional transistor and the base of the power transistor are connected through 0, by inserting the first and second locking resistors, respectively, with a common point of the transistor switch.

The drawing shows the electrical circuit of the inverter.,

5 The voltage inverter contains an output transformer 1 with a primary winding 2, negative feedback windings 3, 4 and a secondary winding 5, a capacitive voltage divider consisting of capacitors 6, 7, the extreme points of which are connected to the power supply terminals 8, 9 , double-winding time setting choke 10 and two transistor switches, power transistors 11,12 of which are bridged by reverse diodes 13, 14 and switching capacitors 15, 16. The primary winding 2 of the output transformer 1 is connected between the midpoint of the capacitive divide Voltage across the capacitors 6, 7 and the connection point of the common point of the first transistor switch on the power transistor 11, the collector of which is connected to the output 8 of the power source, and collector of the power transistor 12 of the second transistor switch, the common point of which is connected to the output 9 of the power source. The windings of the negative feedback connection 3, 4 are connected by one opposite terminals to the common point of one of the transistor switches, and the second to the anodes

rectifying diodes 17, 18 and one of the windings of a two-winding time, the master drossel 10, connected in opposite direction, are connected through the first limiting resistors 19,20 to the bases of switching transistors 21, 22, to which resistive current sensors are also connected via second limiting resistors 23,24 25,26, entered into the emitter circuit of the power transistors 11, 12. The emitters of the switching transistors 21, 22 are connected to common points of the transistor switches, and the collectors to the bases of the additional transistors 27, 28. The cathodes of the rectifying diodes 17.18 are connected to the first terminals of the filter capacitors 29.30, the second terminals of which are connected to common points of transistor switches and emitters of the second auxiliary transistors 31, 32, whose collectors are connected to the bases, and the bases to the emitters of the first auxiliary transistors 33, 34. Between the emitters the first auxiliary transistors 33, 34 and the cathodes of the rectifying diodes 17, 18 successively include the first 35, 36 and second 37, 38 measuring resistors, to the junction point of which the collectors of the additional transistor are connected 27, 28, the bases of which are connected to the collectors of the first auxiliary transistors 33, 34 and through the first locking resistors 39.40 with common points of the transistor switches, and the emitters - with the bases of the power transistors 11,12 connected through the second locking resistors 41, 42 s common points of transistor switches. The collectors of the power transistors 11, 12 are connected to the cathodes of the compensating diodes 43, 44, the anodes of which are connected to the bases of the additional transistors 27.28, and the cathodes of the diodes 45, 46 of the positive feedback. (The lepBbie feedback resistors 47, 48 are connected in parallel to the second auxiliary transistors 31, 32, between whose collectors and anodes of the diodes 45, 46 feedback resistors 49.50 are connected. The output voltage is removed from the winding 5 of the output transformer 1.

The inverter works as follows.

Suppose that an open-power transistor 12. A voltage equal to half the supply voltage is applied to the primary winding 2 of transformer 1. Under the action of the voltage from the negative feedback winding 4 on the capacitor 30, a constant positive voltage is maintained through the diode 18. Since the voltage on the collector of the open transistor 12 is less than the voltage on the positive feedback capacitor 46 is open and therefore transistors 32, 34, 28 are open, which

together with resistors 36 and 38 and diode 44 form a negative feedback circuit that maintains the input current of transistor 12 such that, regardless of the collector current, keep it on the border

.0 saturation, which makes it possible to minimize its turn-off time. Under the influence of tension with. winding 4 time, the driving choke 10 is re-magnetized and, when it is saturated, the voltage with

5 winding 4 through the first limiting resistor, 20 is applied to the base of the switching resistor 22. Since the voltage after the saturating time, the driving throttle has a linearly increasing

0 front, the time of switching on the switching transistor 22 will, in addition, be determined by the voltage from the resistive current sensor 26 supplied through the second limiting resistor 24 and playing

5, the role of the initial bias for the transistor 22. Through the opened transistor 22, the base of the additional transistor 28 is connected to the common point of the transistor switch, the transistor 28 starts to close and

0 reduces the base current of the power transistor

12, which also begins to close. The voltage on the collector of the closing transistor 12 grows and when it exceeds the voltage on the filter capacitor 29, the diode 46 closes, and hence the transistors 32,34, which will cause the closing of the transistors 28, 12. The presence of locking resistors 40, 42 in the circuit forces the process turning off the transistors 28, 12.

0 The transistor 12 is closed, while the rate of increase of voltage on its collector is limited by the switching capacitor 16, which, under the action of the current accumulated in the magnetizing inductance of the output transformer 1, is charged to the value of the supply voltage. The voltage on the capacitor 15, and hence on the collector of the transistor 11, also drops. When it becomes less than the voltage on the capacitor 29, a positive feedback diode 45 will open, and therefore the transistors 33, 31, 27 will open the transistor 11 and stabilize its input current so as to maintain it at the saturation limit regardless of the collector current . The voltage from the winding 3 of the negative feedback will remagnetize the time I set the choke 10 in the opposite direction and the process is completely repeated. If, due to any asymmetries of the circuit or external influences, one-sided biasing of the output transformer 1 occurs, then the amplitudes of the currents through the transistors 11 and 12 will become different, and hence the magnitudes of the voltages coming from the resistive current sensors 25 and 26, resulting in initial the displacements of the transistors 21, 22 will be unequal, and therefore, the turn-on time of the transistors 11 and 12 will be different, and the duration of the conducting state of the transistor, the current through which the bias increases, will It is smaller and vice versa, due to which the bias will be eliminated.

Thus, in the proposed device, switching capacitors form a voltage front on the collector of the transistor when turned off, positive feedback diodes with resistive dividers allow the key to be turned on only with small voltages on the collector, and switching transistors, double-winding time setting choke and resistive sensors current are eliminated asymmetries in the inverter, which leads to a decrease in dynamic losses emitted by the inverter power transistors and, accordingly, increase adherence The introduction of the locking resistors reduces the turn-off time of the additional and power transistors, thereby reducing their dynamic losses and also increasing their reliability. It should also be noted that, with an appropriate choice of parameters, the switching transistor may operate, i.e. turning off the power transistor by a signal only from a resistive current sensor, which allows protecting the power transistors from overloading of the collector current and, thus, also increases the reliability of the inverter.

Claims (2)

Formula from the acquisition 1. A self-initiating push-pull inverter containing an output transformer with a primary winding, a secondary winding and two negative feedback windings, a time driving inductor and two transistor switches, each of which consists of a power transistor, shunted by a reverse diode, an additional transistor, the first and second auxiliary transistors, the first and second measuring resistors, the switching transistor, the base of which is connected through the first limiting resistor with the first terminal of the winding, the time of the master droplet, and the compensating diode connected between the base of the additional transistor and the collector of the power transistor, differing By the fact that, in order to increase reliability by reducing the dynamic power losses in power transistors, a rectifying diode is inserted into each transistor switch; positive feedback diode, first and second feedback resistors, resistive current sensor, second limiting resistor and switching capacitor, with transistor switches and the primary winding of the output transformer is connected by a half bridge circuit, the time of the choke is made of a double winding, each winding of the second terminal through the corresponding winding the negative feedback of the output transformer is connected to the common point of the transistor switch, the switching capacitor is connected parallel to the power transistor, to the power emitter circuit the transistor is connected to a resistive current sensor connected via the second limiting resistor to the base of the switching transistor, the rectifying diode is connected to the second terminal of the winding by the first terminal of the switching throttle, and the second terminal to the common point of the transistor switch through the filter capacitor and to the emitter of the second auxiliary transistor the collector and base of which are connected respectively to the base and the emitter of the first auxiliary transistor, between the base and the emitter of the second auxiliary transistor and included in series the first and second measuring resistors, the connection point between which is connected to the collector of the additional transistor connected by the emitter to the base of the power transistor and the base to the collector of the switching transistor and to the collector of the first auxiliary transistor, the first feedback resistor is connected in parallel to the second auxiliary transistor, the collector of which is connected through serially connected a second feedback resistor and a positive feedback diode are connected to the collector of the power transistor. 2. The inverter according to claim 1, characterized in that the base of the additional transistor and the base of the power transistor are connected via the first and second locking resistors respectively to the common point of the transistor switch.