RU2079164C1 - Resonant power supply - Google Patents

Abstract

FIELD: electric engineering, in particular, high-frequency pulse power supplies. SUBSTANCE: device has gate transistor voltage rectifier 1, which is designed as half-bridge circuit of transistors 4 and 5 and capacitors 6 and 7. In addition device has frequency control unit 25 which is designed as serial circuit of unit 26 which converts voltage to resistance and unit 27 which converts resistance to frequency. Output circuit of rectifier 1 has resonant circuit which is designed as choke 8 and capacitors 9, 10. Output voltage of power supply is stabilized by variation of operation frequency of rectifier 1 depending on variation of output voltage. Specific shape of base current of transistors 4 and 5 is achieved by unit 25 and circuits of elements 15-22. This results in decreased losses when rectifier transistors 4 and 5 are either enabled or disabled. EFFECT: increased stability of output voltage, decreased power losses. 4 cl, 3 dwg

Description

 The invention relates to electrical engineering and can be used in the development of high-quality switching power supplies.

 Known pulse voltage regulator containing a push-pull half-bridge voltage converter, connected to the input terminals by the input and output through a rectifier and filter with output terminals, a pulse-width modulator, the outputs of which are connected to the control inputs of a push-pull half-bridge voltage converter, a square wave generator, sawtooth generator , a voltage reference source and two transistors (1). In the known device, the technical problem is solved to increase the efficiency due to the use of alternating voltages: rectangular reference and sawtooth, proportional to the input voltage, for comparison in a pulse-width modulator. Obtaining such stresses and comparing them requires less energy. And the use of the current of the reference voltage source at the same time to control the transistors of the push-pull half-bridge voltage converter, along with the use of passive PWM, further increases the efficiency.

 PWM power supplies are currently prevailing. However, they are characterized by too high losses, since they relate to schemes with the so-called hard switching. With hard switching, the on transistor switch turns off at the moment when current flows through it, and the off transistor switch turns on when there is voltage on it and therefore, the more often this switch turns on and off, the greater the loss. In this case, the switching time of the transistor (the duration of turning on or off) should be as short as possible.

 Thus, the disadvantage of the known device is the high loss, i.e. low efficiency.

 Ideally, in order to minimize losses, the transistor switch should be turned off at the moment when the current through it is zero (switching at zero current) and turned on when the voltage across it is zero (switching at zero voltage).

 Currently, the best solution for high-frequency switching power supplies is the use of resonant circuits. Unlike PWM power supplies, resonant circuits “soften” the switching mode and thus contribute to the reduction of switching losses. As a result, resonant power supplies at the same operating frequency provide higher efficiency.

 Known resonant power source containing a key transistor voltage converter, input connections with input pins and made in the form of a half-bridge circuit, the output circuit of which includes a resonant circuit consisting of parallel connected series circuit on the inductor and the first capacitor and the second capacitor, and parallel to the first capacitor the primary winding of the output transformer is turned on, the secondary winding of which is connected to the output terminals through a rectifier and a filter, and frequency control, the outputs of which are connected to the control inputs of the key transistor voltage converter, the power terminals of the transistors which are shunted by blocking diodes (2).

 A known power source is the analogue closest to the proposed invention in terms of the essential features.

 However, the known power source also has significant switching losses due to the fact that the frequency control unit generates rectangular oscillations and, therefore, the control current of the transistor of the converter also has a rectangular shape. The technical task of the present invention is to reduce losses when switching transistors of the key transistor voltage converter and reducing the power consumed by the frequency control unit.

 The technical result that can be obtained using the invention is to increase the efficiency of the resonant power source.

 The stated technical problem is achieved in that in a resonant power source containing a key transistor voltage converter, input connections with outputs pins and made in the form of a half-bridge circuit, the output circuit of which includes a resonant circuit, consisting of parallel connected series circuit on the inductor and the first capacitor and the second capacitor, and in parallel with the first capacitor, the primary winding of the output transformer is turned on, the secondary winding of which is through the rectifier and the liter is connected to the output terminals, and the frequency control unit, the outputs of which are connected to the control inputs of the key transistor voltage converter, the power terminals of the transistors which are bridged by blocking diodes, the frequency control unit is made in the form of two series resistors and a diode connected in series and on an additional capacitor connected between common point of the resistors and the free output of the diode, while the control inputs of the transistors through the corresponding chain of formation of the base t they are connected to the corresponding control inputs of the key transistor voltage converter, and the resistance-to-frequency conversion unit is made in the form of a paraphase multivibrator on four logical inverters, third and fourth capacitors, on an additional transistor and three resistors, and the logical inverters are connected in series-series, respectively, the first with the second and third with the fourth, the third capacitor is connected between the output of the first and the input of the third logical inverters, and the fourth a capacitor is connected between the output of the third and the output of the first logical inverters, the first resistor is connected parallel to the output of the voltage-to-voltage converter assembly, through the second and third resistors connected to the outputs of the first and third logical inverters, the outputs of the second and fourth logical inverters are connected to the primary winding of the additional a transformer, the two secondary windings of which are used as the outputs of the resistance to frequency conversion unit and the outputs of the control unit Ia frequency input which is used as an input voltage conversion unit to the resistance connected to the output terminals.

 In addition, the voltage-to-resistance conversion unit is made on an additional transistor, the output of which is used as the output of the voltage-to-resistance conversion unit, a variable resistor used as the input of the voltage-to-resistance conversion unit, and a fourth resistor connected between the input and output of the voltage-conversion unit in resistance, moreover, the control terminal of the variable resistor is connected to the base of the additional transistor.

 Logic inverters can be performed on elements 2I-NOT.

 To ensure the starting of the voltage converter, the additional transformer is equipped with a starting winding included in the output circuit of the key transistor voltage converter in series with the resonant circuit.

 The invention is illustrated by drawings, where in FIG. 1 is a diagram of a resonant power source; FIG. 2 is a base current transistor form of a key transistor voltage converter, FIG. 3 its adjusting characteristic.

 The resonant power source (Fig. 1) contains a key transistor voltage converter 1, connected to the output terminals 2, 3 by an input and made in the form of a half-bridge circuit on transistors 4, 5 and capacitors 6, 7, in the output circuit of which there is a resonant circuit consisting of connected in parallel to the serial circuit on the inductor 8 and the first capacitor 9 and the second capacitor 10, the output transformer 11, the primary winding which is connected parallel to the capacitor 9, and the secondary through the rectifier 12 and the filter 13 is connected to the output of the key transistor voltage converter connected to the output terminals to which the load 14 is connected, the base current generation circuits made in the form of series-connected base resistors 15 and 16, 17, 18 and diodes 19 and 20, and on additional capacitors 21 and 22, connected between the common point of the resistors 15, 16 and 17, 18 and the free terminals of the diodes 19 and 20, respectively, blocking diodes 23 and 24, shunting the power terminals of the transistors 4 and 5, the frequency control unit 25, made in the form of series-connected nodes converting voltage into resistance 26 and node converting resistance to frequency 27.

 The resistance-to-frequency converting unit 27 contains a paraphase multivibrator on four logical inverters 28, 29, 30, 31, a third capacitor 32, a fourth capacitor 33, an additional transformer 34 and three resistors 35, 36, 37, and the logical inverters are connected in series, 28 from 29 and 30 with 31, the third capacitor 32 is connected between the output of the logical inverter 28 and the input of the logical inverter 30, the fourth capacitor 33 is connected between the output of the logical inverter 30 and the input of the logical inverter 28, the first resistor 35 is turned on parallel to the output of the node 26 converting voltage into resistance, through the second resistor 36 and the third resistor 37, connected to the inputs, respectively, of the logical inverter 28 and the logical inverter 30, the outputs of the logical inverter 29 and the logical inverter 31 are connected to the primary winding 38 of the additional transformer 34, secondary windings 39 and 40 of which are used as the outputs of the node 27 for converting the resistance into frequency and the outputs of the frequency control unit 25. Logic inverters 28, 29, 30, 31 can be performed, for example, on the elements 2I-NOT.

 As the input of the frequency control unit 25, the input of the voltage-to-resistance conversion unit 26 made on an additional transistor 41, the output of which is used as the output of the voltage to resistance conversion unit 26, is used on the variable resistor 42 used as the input of the voltage-to-resistance conversion unit 26 and a fourth resistor 43 connected between the input and output of the voltage-to-resistance converting unit 26, the adjustment terminal of the variable resistor 42 being connected to the base th additional transistor 41. The input of the frequency control unit 25 is connected to the load 14. To ensure the start of the key transistor voltage converter 1, the additional transformer 34 is equipped with a start winding 44 connected to the output circuit of the key transistor converter 1 in series with the resonant circuit. The paraphase multivibrator is powered from a separate power source and from a reference voltage source (elements 45, 46) by applying voltage to it from the output of the rectifier 12 of the key transistor voltage converter 1 through a capacitive filter 47. Resistors 48, 49, 50, 51 specify the necessary operating mode transistors 4 and 5.

 The resonant power source operates as follows. When the power source is turned on, the key transistor voltage converter 1 is excited due to the positive feedback of the starting winding 44 of the additional transformer 34 and starts to generate low-frequency pulses. A voltage appears on the secondary winding of the output transformer 11, which feeds the microcircuit on the inverters 28.31 of the paraphase multivibrator through the rectifier 12. The multivibrator begins to generate high-frequency pulses that enter through a transformer 34 on the base current generation circuit of transistors 4 and 5.

 Due to the formation of the base current of the transistors 4 and 5 of the converter 1 using the frequency control unit 25 and the base current generation chains (elements 15.22), losses are reduced in the transistors 4 and 5 when they are switched.

At time t ₁ (Fig. 2), the transistor 4 is turned on (turning on at zero voltage). With such a sharp jump in the base current, losses are reduced when the transistor is turned on. The transistor is turned on and saturated for a time t ₁ t ₂ . In this case, the base current decreases linearly to i _b min. at which the transistor is still saturated. With a value of i _b , the resorption time t _{races of the} transistor when it is turned off will be minimal, which leads to a decrease in losses when the transistor is turned off. During the time t ₂ t ₃ , when the base current takes negative values, the turn-off time of the transistor due to an additional decrease in t _races. decreases, due to which thermal losses are reduced when the transistor is turned off.

 Thus, due to the formation of the base current of transistors 4 and 5 of a special form (Fig. 2), losses are reduced both when turning on and off the transistors of converter 1.

 When the transistor 4 is turned on, the current in the inductor 8 begins to gradually increase. This current is equal to the sum of the current in the primary winding of the transformer 11 and the charging current of the capacitor 9. When the voltage across the capacitor 9 and the primary winding of the transformer 11 is equal to the input voltage, the voltage drop across the inductor 8 will become zero, after which the energy stored in the inductor 8 starts charge the capacitor 9. After a time interval, which is set by the natural resonant frequency of the circuit, the current in the inductor 8 and, therefore, in the transistor 4 will become equal to zero. Then the current through the inductor 8 changes direction and the capacitor 9 begins to discharge, maintaining the flow of current through the diode 23. In this case, the transistor 4 turns off (switching at zero current). The resonant charging half-cycle of the capacitor 10 begins after the transistor 4 is turned off and ends before the transistor 5 is turned on. When both transistors are turned off, energy is transferred from the inductor 8 to the capacitor 10. As the capacitor 10 is charged, the voltage on the transistor 4 increases, and on the transistor 5 decreases. When the voltage at the transistor 5 drops to zero, it turns on without loss, while the diode 24 provides the return of energy remaining in the inductor 8, back to the input of the resonant power source. The next half-cycle is identical to the first and begins when the transistor 5 turns off. Now the voltage on the transistor 5 will increase, and the voltage on the transistor 4 will decrease, and when it drops to zero, the transistor 4 is turned on without loss.

 As in other resonant power sources, a change in the operating frequency of the converter 1 leads to a change in the output voltage, the working frequency of the converter 1 being higher than its resonant frequency, and the working point of the conversion is located on the right slope of the resonant curve of the circuit (Fig. 3) in its straight section. The output voltage is stabilized by supplying negative feedback voltage from the load 14 to the frequency control unit 25 and generating control pulses of the transistors 4 and 5 of the converter 17 in this block. In the frequency control unit 25, the voltage is converted into resistance using the node 26, and then the conversion of resistance to frequency using the node 27. The frequency modulation occurs due to changes in the resistance of the resistor 35, shunted by the transistor 41.

 Resistor 35 and capacitors 32, 33 and resistors 36, 37 perform the function of timing elements of a paraphase multivibrator.

When the output voltage decreases from U ₀ to U ₂ due to an increase in the load current, the frequency of the paraphase multivibrator decreases from f ₁ to f ₃ (Fig. 3), while the output voltage of converter 1 increases to U ₁ and compensates for the decrease in the output voltage source.

 Thus, the output voltage of the resonant power source will remain unchanged.

 Similarly, the output voltage is stabilized by reducing the load current.

On the resonant (adjusting) characteristic (Fig. 3), the conversion working point is shifted along the line f ₁ , f ₂ , f ₃ : the larger the current in the load, the closer the operating point to the frequency and vice versa, the smaller the current in the load, the closer the working point to frequency f ₂ .

At very large load points or short circuits in the load, the conversion operating point shifts to the left beyond the resonant frequency f _p , reducing the voltage to almost zero (point f ₄ , Fig. 3). In this case, protection against short circuits of the power source is carried out without the use of any additional elements.

 The proposed implementation scheme of the frequency control unit, in particular, its node converting the resistance into frequency, is very economical, because It features low power consumption.

 Thus, this invention allows to increase the efficiency of the resonant power source.

Claims (4)

 1. A resonant power source containing a key transistor voltage converter connected in input to the input terminals and made in the form of a half-bridge circuit, the output circuit of which includes a resonant circuit consisting of a parallel connected series circuit on the inductor and the first capacitor and the second capacitor, parallel to the first the primary winding of the output transformer is connected to the capacitor, the secondary winding of which is connected through the rectifier and filter to the output of the key transistor a voltage converter connected to the output terminals, and a frequency control unit, the outputs of which are connected to the control inputs of the key transistor voltage converter, the power terminals of the transistors of which are shunted by blocking diodes, characterized in that the frequency control unit is made in the form of series-connected voltage to resistance conversion units and node of converting resistance to frequency, as transistors of a key transistor voltage converter using These are bipolar transistors, the base circuits of which are equipped with base current generation circuits made in the form of two series resistors and a diode connected in series and with an additional capacitor connected between the common point of the base resistors and the diode’s free terminals, while the control inputs of the transistors through the corresponding base current generation circuits connected to the corresponding control inputs of the key transistor voltage converter, and the resistance to frequency conversion unit made in the form of a paraphase multivibrator on four logical inverters, the third and fourth capacitors, on an additional transformer and three resistors, and the logical inverters are connected in pairs in series, respectively, the first with the second and third with the fourth, the third capacitor is connected between the output of the first and the input of the third logical inverters and the fourth capacitor is connected between the output of the third and the input of the first logical inverters, the first resistor is connected parallel to the output of the voltage conversion unit In the resistance, through the second and third resistors connected to the inputs of the first and third logical inverters, the outputs of the second and fourth logical inverters are connected to the primary winding of an additional transformer, the two secondary windings of which are used as the outputs of the resistance to frequency conversion unit and the outputs of the control unit frequency, input, which is used as the input node of the voltage to resistance conversion, connected to the output terminals.  2. The power source according to claim 1, characterized in that the voltage-to-resistance conversion unit is made on an additional transistor, the output of which is used as the output of the voltage-to-voltage conversion unit, a variable resistor used as the input of the voltage-to-voltage conversion unit, and the fourth a resistor connected between the input and output of the node converting voltage into resistance, and the control output of the variable resistor is connected to the base of the additional transistor.  3. The power supply according to claims 1 and 2, characterized in that the logical inverters are made on elements 2I-NOT.  4. The power supply according to claims 1 to 3, characterized in that the additional transformer is equipped with a starting winding included in the output circuit of the key transistor voltage converter in series with the resonant circuit.

Images