CS275921B6 - Resonant converter - Google Patents

Abstract

The circuit includes a power supply (1), a transformer (2) with a primary winding (21) and a secondary winding (22), a switch (3), a resonant inductance (4), a rectifier diode (5), a resonant capacitor (6), a recirculation diode (7), a filter inductance (8), a filter capacitor (9), a load (10), a charging diode (11) and a discharging diode (12).

Description

The invention relates to a specific implementation of a resonant type converter from an input DC voltage to a desired DC output voltage.

The use of resonant converters minimizes impulse losses on the switching elements that switch on and off at zero current or voltage. This allows inverters with a high operating frequency while maintaining high efficiency. The advantage of these converters is small volume and low weight. The disadvantage of the known connections of resonant converters operating with high frequency is the large influence of parasitic circuit elements on the operation and parameters of the converter. Parasitic elements significantly reduce the maximum value of the output load current of the inverter.

The adverse effect of these parasitic elements is eliminated by a resonant transducer according to the invention, in which the first power supply terminal is connected to the beginning of the transformer primary winding, where the end of the transformer primary winding is connected to a first switch terminal the secondary winding of the transformer is connected to a first resonant inductance terminal, the cathode of the recuperation diode being connected to a first filter inductance terminal, the second terminal of which is connected to the first filter capacitor terminal and a first load terminal, the second terminal of which is connected to the second filter capacitor terminal; the anode of the recuperation diode, with the second terminal of the resonant capacitor and the end of the secondary winding of the transformer, the essence of which is that the second terminal of the resonant inductance is connected to the anode of the rectifier diode and the anode of the charging diode, the cathode of which dy, the cathode of which is connected to the cathode of the rectifier diode and to the cathode of the recuperation diode.

The resonant transducer of the present invention eliminates the adverse effect of certain parasitic circuit elements on the operation and parameters of the transducer. It allows to reach a higher value of the maximum output load current of the inverter. The connection suppresses unwanted oscillations of some current and voltage waveforms in the inverter circuit, which also reduces power losses on some elements. Furthermore, the positive demands on the design and technological design of the entire inverter and on the quality of the components used are reduced.

The resonant converter according to the invention will be described with the aid of Figures 1 and 2. Figure 1 shows the connection of one type of resonant converter, Figure 2 shows an example of the connection of a resonant converter according to the invention.

In Figure 1, the first terminal 10 of the power supply £ is connected to the beginning of the primary winding 21 of the transformer £. The end of the primary winding 21 of the transformer 2 is connected to the first terminal of the switch £, the second terminal of which is connected to the second terminal 102 of the power supply £. The beginning of the secondary winding 26 of the transformer 1 is connected to the first terminal of the resonant inductor 4. Its second terminal is connected to the anode of the rectifier diode 5. Its cathode is connected to the first terminal of the resonant capacitor 6, the cathode of the recuperation diode 7 and the first terminal of the filter inductor 8. Its second terminal is connected to the first terminal of the filter capacitor 9 and to the first terminal of the load 10. Its second terminal is connected to the second terminal of the filter capacitor 9, the anode of the recuperation diode 7, the second terminal of the resonant capacitor 6 and the end of the secondary winding 22 of the transformer 2.

The function of the circuit according to Figure 1 is as follows. It is a single-acting open-loop type resonant converter with a discontinuous function, i.e. a quasi-resonant converter with parallel resonance with switching on and off of switch 3 at zero current with isolating transformer 2. The resonant circuit consists of a resonant inductor 4 and a resonant capacitor 6 connected on the secondary side of the converter. In the function switch 2 ^e j used, for example the power transistor MBS.

The operation of the circuit takes place in four stages. Before the start of the first stage, switch 3 is open. Load current 10 flows from the filter inductor 2 ^and closes the open through freewheeling diode 2 · The voltage on the resonant capacitor 2 ^e J practically zero. The first stage is started by closing the switch 2. This ^{creates a positive pulse on the} secondary winding 22 of the transformer 2, which causes a gradual linear increase of the current by the resonant inductance 4. Switch 2 closed at virtually zero current. When the current through the resonant inductance 2 reaches the value of the output current to the load 10, the recuperation diode 2 closes.

The second stage of the operation of the resonant converter occurs, when the sinusoidal circuit shapes the sinusoidal current with the resonant inductance 2 ^and at the same time charges the resonant capacitor 6. opening occurs at practically zero current value, i.e. lossless.

The third stage of the inverter operation follows, when the resonant capacitor 2 is discharged by the current of the output load 10 through the filter inductance 2. This stage is terminated by a decrease in the voltage of the resonant capacitor 2 to zero.

At that moment, the recuperation diode 2 opens ^and the recuperation step follows. The moment of closing the switch 2 ^and thus the start of the next cycle of operation is set by the feedback circuit of the converter suitably so that the mean value of pulse waveforms at the input of the output filter, which is formed by filter inductance 2 ^and filter capacitor 2; was equal to the required inverter output voltage. Output voltage regulation is performed by changing the repetition frequency of the switching circuit switches 2Funkce will not change if the resonant inductance 4 J ^e are connected in series with the primary winding 22 of the transformer 2. In the case of high working frequencies may be the resonance inductor 2 ^is preferably implemented by the transformer leakage inductance 2_.

A necessary condition for the switch-off of switch 2 to occur at zero current is that the output load current of converter I ₂ is less than or at most equal to the value ^ 2MAX ⁼ ^^^ 0 'U is the amplitude of the positive pulse on the secondary winding 22 of transformer 2 ^and Zq = Vlg / Cg is the characteristic impedance of the resonant circuit. Lg is the inductance by the resonant inductance 2 ³ Cg is the capacitance of the resonant capacitor 6.

However, at high operating frequencies of the converters in the range of hundreds of kolihertz to megahertz, it turns out that the value of the maximum load current is greatly reduced by the action of some parasitic elements of the converter circuit. It has a particularly adverse effect on the series parasitic inductance of the resonant capacitor 2 ^{and the} parasitic inductance of the recuperation diode 2 · These elements together with the resonant capacitor 2 form a parasitic resonant circuit which adversely affects the operation of the whole converter. In addition to a significant reduction in the value of ^ HAX ^from P $ ^s ° bi parasitic elements, a strong oscillation of current and voltage waveforms in the inverter, which in addition to increasing interference also increases power losses on power elements of the inverter, did not increase the effective value of currents through these elements. The oscillation of the waveform also has an adverse effect on the feedback stability of the inverter. The need to reduce these parasitic elements to a minimum value places high demands on the technological and structural design of the entire inverter as well as on the quality of the elements used. The necessary technologies and elements are expensive and difficult to access.

At turn 2 there is an example of an arrangement of a resonant converter according to the invention, where the first terminal 101 of the power supply 6 is connected to the beginning of the primary winding 25 of the transformer 2. The end of the primary winding 21 of the transformer 2 is connected to the first terminal of the switch 3 terminal 102 of the power supply £. The beginning of the secondary winding 22 of the transformer 2 is connected to the first terminal of the resonant inductance e. Its second terminal is connected to the anode of the charging diode 11 and to the anode of the rectifier diode 5. Its cathode is connected to the cathode of the discharge diode £ 2, to the cathode of the recuperation diode £ and to the first terminal of the filter inductance 8. Its second terminal is connected to the first terminal of the filter capacitor 9 and to the first. load terminal £ 0. Its second terminal is connected to the second terminal of the filter capacitor 9, and an anode-wheeling diodes 7 to the second terminal of the resonance, the ⁿ capacitors £ ° and the end of the secondary winding of the transformer 22 £. The cathode of the charging diode ££ is connected to the first terminal of the resonant capacitor £ and to the anode of the discharging diode 12.

The operation of the resonant transducer according to Figure 2 again takes place in four stages. In the first stage, after the switch £ is closed, the current of the resonant inductance £ increases through the open rectifier diode £. At the same time, the charging of the resonant capacitor 6 via the open charging diode ££ is started. In this first stage, the recuperation diode £ is still open. As soon as the current through the rectifier diode £ reaches the value of the output current of the converter, the recuperation diode £ is closed and the resonant phase of the operation of the converter follows.

At this time, a sinusoidal current is generated via the charging diode ££ into the resonant capacitor £. At the moment when the current passes through the resonant inductance £, the switch £ is opened and at the same time the rectifier diode £ and the charging diode ££ are closed.

In the third stage of operation, the resonant capacitor 6 is discharged through the open discharge diode 12 with a constant current which corresponds to the output load current of the converter. At the moment when the resonant capacitor £ is discharged, the recuperation diode £ opens and the recuperation step follows.

By the action of the parasitic inductance of the resonant capacitor £ and the parasitic inductance in the circuit of the recuperation diode £, the resonant capacitor £ is charged to a negative voltage value. The magnitude of the voltage depends on the magnitude of both parasitic inductors, on the value of the capacitance of the resonant capacitor 6 and on the magnitude of the output current of the converter. The negative voltage generated on the resonant capacitor £ closes the discharge diode £ 2. Thus, at the time of recuperation, the circuit of the resonant capacitor 6 is disconnected from the circuit of the recuperation diode 7, and thus no parasitic resonant circuit is formed. The charging diode 11 and the discharging diode 12 separate the resonant capacitor circuit á from the converter output circuit. This prevents oscillation of current and voltage waveforms in the inverter circuit. The negative voltage on the resonant capacitor 6, which is maintained until the start of the next cycle of operation, represents a non-zero initial condition, ensuring a higher value of the maximum load current I ₂ MAX ^{than with the converter} P ° according to Figure 1. the total current flowing through the resonant inductance £ is defined divided into a part flowing through the rectifier diode £ and through the charging diode ££. This, together with unbalanced waveforms, also contributes to higher inverter efficiency.

CS 275921 06

In resonant converters with a higher output voltage, where the voltage drop across the charging diode 11 and the discharging diode 12 in the forward direction is negligible from the value of the output voltage, the rectifier diode £ can be omitted.

The circuit solution according to Figure 2 can be used for all types of permeable resonant converters with single-acting or with double-acting converter with or without transformer. The resonant inductance 4 can be connected in the secondary part of the converter or in the primary part of the converter, or it can be replaced by the stray inductance of the transformer 6.

The resonant converter according to the invention is suitable for realizing converters with a high operating frequency. It reduces the requirements for the design of the inverter and the quality of the components used.

Claims (1)

PATENT CLAIMS A resonant converter in which the first terminal of the power supply is connected to the beginning of the primary winding of the transformer, wherein the end of the primary winding of the transformer is connected to the first terminal of the switch, the second terminal of which is connected to the second terminal of the power supply, resonant. inductance, the cathode of the recuperation diode being connected to the first terminal by a filter inductance, the second terminal of which is connected to the first terminal of the filter capacitor and, to the first terminal of the load, the second terminal of which is connected to the second terminal of the filter capacitor, to the anode of the recuperation diode. resonant capacitor and the end of the secondary winding of the transformer, characterized in that the second resonant inductance terminal (4) is connected to the anode of the rectifier diode (5) and the anode of the charging diode (11), the cathode of which is connected to the first terminal of the resonant capacitor (6) and a discharge diode (12), the cathode of which is connected to the cathode of the rectifier diode (5) and to the cathode of the recuperation diode (7). .