CN112311245A - High-frequency intermittent control system and method of bidirectional series resonant converter - Google Patents

Abstract

The invention discloses a high-frequency intermittent control system and a method suitable for a bidirectional series resonant converter, which comprise a first filter circuit, a first inversion/rectification circuit, a resonant circuit, a high-frequency transformer, a second inversion/rectification circuit, a second filter circuit, a voltage and current acquisition circuit, a controller and a drive circuit, wherein the first filter circuit is connected with the first inversion/rectification circuit; the bidirectional series resonant converter can realize the functions of voltage reduction and voltage increase at the same time, a wider working range is realized, all switches realize wide-range zero-current switching, and the switching loss is reduced. Pulse control is added in the switching period and the pulses can be up to half the resonant frequency, thereby reducing the voltage ripple. The control strategy can enable the system to have a linear power transmission characteristic, and the system characteristic is simple and easy to operate.

Description

High-frequency intermittent control system and method of bidirectional series resonant converter

Technical Field

The invention relates to the technical field of power electronics and power automation equipment, in particular to a high-frequency intermittent control system and method of a bidirectional series resonant converter.

Background

The bidirectional resonant converter is a device capable of enabling direct current electric energy to flow bidirectionally, and can be a bridge between power systems with different connection voltage grades. However, since the voltage variation of the lithium ion battery on the charging side and the discharging side during charging and discharging is generally large, the bidirectional DC-DC converter must have a wide gain range. In addition, the DC-DC converter needs to achieve high efficiency not only under heavy load, but also under light load, high transmission efficiency is required to ensure the charging process of the battery. The main solutions currently in use are the following two types:

(1) a hybrid modulation scheme of frequency-variable modulation and phase-shift modulation (VFM + PSM), where frequency-variable modulation is used for implementation and phase-shift modulation is used to increase the gain range of the converter.

The method can reduce energy loss in the transmission process, but when the load is light, the operating frequency requirement of the method is high, and the method cannot be easily realized in practical application.

(2) And pulse control is carried out, and the converter realizes high-performance transmission power under the condition of light load through controlling the switch.

However, in the mainstream pulse control at present, the pulse frequency is very low, which causes large voltage ripple and affects the normal operation of the circuit. Therefore, a control method of the bidirectional resonant converter is needed, which has the advantages of convenient control, good light-load working condition, small voltage ripple, and better dynamic response performance and stability.

Disclosure of Invention

In view of the above, the present invention provides a system and a method for controlling a bidirectional series resonant converter intermittently at a high frequency.

A high-frequency intermittent control system of a bidirectional series resonant converter comprises a first input power supply, a first filter circuit, a first inversion/rectification circuit, a resonant circuit, a high-frequency transformer, a second inversion/rectification circuit, a second filter circuit, a second input power supply, a first voltage and current acquisition circuit, a second voltage and current acquisition circuit, a first controller, a second controller, a first drive circuit and a second drive circuit;

the output end of the first input power supply is connected with the input end of the first filter circuit, and the feedback end of the first filter circuit is connected with the input end of the first voltage and current acquisition circuit; the output end of the first voltage and current acquisition circuit is connected with the input end of the first controller, the output end of the first controller is connected with the driving circuit, and the output end of the first driving circuit is connected with the first input end of the second inversion/rectification circuit;

the output end of the first filter circuit is connected with the first input end of the first inversion/rectification circuit, the input end of the resonance circuit is connected with the output end of the first inversion/rectification circuit, and the output end of the resonance circuit is connected with the input end of the high-frequency transformer; the output end of the high-frequency transformer is connected with the second input end of the second inversion/rectification circuit; the output end of the second inversion/rectification circuit is connected with the input end of the second filter circuit; the output end of the second filter circuit is used for being connected with a second input power supply, and the feedback end of the second filter circuit is connected with the input end of the voltage and current acquisition circuit; the output end of the second voltage and current acquisition circuit is connected to the input end of the second controller, the output end of the second controller is connected to the input end of the second driving circuit, and the output end of the second driving circuit is connected with the second input end of the first inversion/rectification circuit.

Further, the high-frequency intermittent control system of the bidirectional series resonant converter enables direct current to flow bidirectionally, wherein the working mode of energy transmission from the first input power supply to the second input power supply is a forward transmission mode, and the working mode of energy transmission from the second input power supply to the first input power supply is a reverse transmission mode.

Furthermore, the first filter circuit is a direct current filter capacitor C₁First inverter/rectifier circuit switching tube S₃Pin 2 and switch tube S₄Pin 1 of the resonant converter is connected with the first filter circuit of the resonant converter, wherein the switching tube S₁And S₃Pin 1 for connecting filter capacitor C₁Positive electrode of (2), switching tube S₁And S₃Pin 2 for connecting filter capacitor C₁The first filter circuit is used for filtering harmonic waves in current output by the rectifying circuit in a reverse transmission mode and providing stable direct current energy for the first input power supply.

Furthermore, the first inversion/rectification circuit comprises four identical switching tubes S₁～S₄Each switching tube S₁-S₄A group of diodes and buffer capacitors connected in parallel are respectively connected between the pin 1 and the pin 2, wherein the anode of the diode is connected with the pin 2 corresponding to the switch tube, the cathode is connected with the pin 1 corresponding to the switch tube, and the switch tube S₁Pin 2 and switch tube S₂Pin 1 is connected between two output ends of a first input power supply, and a switching tube S₃Pin 2 and switch tube S₄The pin 1 is connected and then used for connecting between two output ends of a first input power supply; wherein, the switch tube S₁And S₃Pin 1 for connecting a first input power supply and a reverse filter capacitor C₁Positive electrode of (2), switching tube S₂And S₄Pin 2 for connecting a first input power supply and a reverse filter capacitor C₁Negative electrode of (2), switching tube S₁-S₄Selected types include MOSFETs, BJTs and IGBTs.

Furthermore, the resonance circuit adopts a series LC resonance circuit comprising an inductor and a capacitor, and the series LC resonance circuit comprises a resonance inductor L_rAnd a resonant capacitor C_rResonant capacitor C_rOne end of the first inverter/rectifier circuit is connected with a switching tube S₁Pin 2, the other end is connected in series with a resonance inductor L_r，L_rThe other end of the switch tube S is connected with the switch tube S₃Pin 2 of the transformer is connected with one end of the primary side of the high-frequency transformer.

Furthermore, the high-frequency transformer is a high-frequency isolation transformer, and one end of the primary side of the high-frequency isolation transformer is connected with a resonant inductor L_rAnd a switching tube S₃Pin 2, the other end of the primary side is connected to a third switch tube S₃And a fourth switching tube S₄At the connecting end ofUnder the excitation of the square wave voltage output by the first inversion/rectification circuit, the resonance inductance L of the resonance circuit_rResonant capacitor C_rThe equivalent excitation inductance of the primary side of the high-frequency isolation transformer generates a high-frequency resonant current which is approximate to sine and is transmitted to the secondary side of the high-frequency isolation transformer through the primary side of the high-frequency isolation transformer.

Furthermore, the second inversion/rectification circuit has four same switching tubes S₅～S₈Each switching tube S₅-S₈A group of diodes and buffer capacitors connected in parallel are respectively connected between the pin 1 and the pin 2, wherein the anode of the diode is connected with the pin 2 corresponding to the switch tube, the cathode is connected with the pin 1 corresponding to the switch tube, and the switch tube S₅Pin 2 and switch tube S₆Pin 1 is connected to be connected between two output ends of a second input power supply, and a switching tube S₇Pin 2 and switch tube S₈The pin 1 is connected and then used for connecting between two output ends of a second input power supply; wherein, the switch tube S₅And S₇Pin 1 and pin 2 of (2) are used for connecting the output end of the high-frequency transformer, S₅And S₇Pin 1 of the filter is used for connecting a second input power supply and a filter capacitor C₂Positive electrode of (2), S₆And S₈Pin 2 for connecting a second input power supply and a filter capacitor C₂Negative electrode of (2), switching tube S₅-S₈Types of (d) include MOSFETs, BJTs and IGBTs.

Furthermore, the second filter circuit is a DC filter capacitor C₂Second inverter/rectifier circuit switching tube S₇Pin 2 and switch tube S₈Pin 1 is connected for connection to both ends of a second filter circuit, wherein a switching tube S₅And S₇Pin 1 for connecting filter capacitor C₂Positive electrode of (2), switching tube S₆And S₈Pin 2 for connecting filter capacitor C₂And the second filter circuit is used for filtering harmonic waves in the current output by the rectifying circuit in the forward transmission mode and providing stable direct current energy for the second input power supply.

A high-frequency intermittent control method of a bidirectional series resonant converter is used for any one of the high-frequency intermittent control systems of the bidirectional series resonant converter, and comprises the following steps:

s101: collecting voltage value V of first input power supply₁A current value I output by the first inversion/rectification circuit₁And a voltage value V of the second input power supply₂A current value I output by the second inverter/rectifier circuit₂The power P output by the first inversion/rectification circuit is calculated by the controller₁And power P output by the second inverter/rectifier circuit₂；

S102: determining reference power P_refIf P is positive or negative_refIf > 0, the converter works in the forward direction, and the step S103 is carried out, P_ref< 0, the inverter operates in reverse, step S104, where P_refIs the set value of the output power;

s103: judgment V₁And nV₂If V is a magnitude relation of₁≤nV₂Step S105 is executed to step S105 if the converter is boosted in the forward direction₁＞nV₂Step S107 is executed after the converter forward voltage reduction;

s104: judgment V₁And nV₂If V is a magnitude relation of₁≤nV₂Step S108 is performed, if V is reached, the converter is reversely reduced₁＞nV₂Step S106 is executed;

s105: according to the formula f_s＝K_p1e₁+K_i1×(∫e₁dt+C₁) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁、S₂，S₅-S₈According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₃And S₄Wherein S is₁And S₅Same phase, S₂And S₆Same phase, S₈Relative to S₂Hysteresis T_rTime; s₁、S₂Complementary phase, S₅、S₆Complementary phase, S₇、S₈Complementary in phase, during a working cycleT_sIn the first half period, S₄Relative to S₂Lead T_rTime, S₃And S₂In phase; in the second half period, S₃Relative to S₁Lead T_rTime, S₄And S₁Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₁As power error, e₁＝P_ref－P₂，K_p1And K_i1Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₁C in the current beat calculation as an integral constant₁Integral e with last beat calculation₁dt+C₁Value of (C) at the time of the first calculation₁＝0，P_refTo output power set point, P₂The output power value of the second inversion/rectification circuit;

s106: according to the formula f_s＝K_p1e₁+K_i1×(∫e₁dt+C₁) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁-S₄，S₅、S₆According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₇And S₈(ii) a Wherein S is₅And S₁Same phase, S₆And S₂Same phase, S₄Relative to S₆Hysteresis T_rTime; s₅、S₆Complementary phase, S₁、S₂Complementary phase, S₃、S₄Complementary in phase, during a working period T_sIn the first half period, S₈Relative to S₆Lead T_rTime, S₇And S₆In phase; in the second half period, S₇Relative to S₅Lead T_rTime, S₈And S₅Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₁As power error, e₁＝P_ref－P₁，K_p1And K_i1Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₁C in the current beat calculation as an integral constant₁Integral e with last beat calculation₁dt+C₁Value of (C) at the time of the first calculation₁＝0，P_refTo output power set point, P₁The output power value of the first inversion/rectification circuit;

s107: according to the formula f_s＝K_p2e₂+K_i2×(∫e₂dt+C₂) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁-S₄，S₅、S₆According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₇And S₈Wherein S is₁And S₅Same phase, S₂And S₆Same phase, S₄Relative to S₂Tr time ahead; s₁、S₂Complementary phase, S₃、S₄Complementary phase, S₅、S₆Complementary in phase, during a working period T_sIn the first half period, S₈And S₄Same phase, S₇And S₆In phase; in the second half period, S₇And S₃Same phase, S₈And S₁Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₂As power error, e₂＝P_ref－P₂，K_p2And K_i2Respectively an output power proportional coefficient and an output power integral coefficient, t is timeM, C₂C in the current beat calculation as an integral constant₂Integral e with last beat calculation₂dt+C₂Value of (C) at the time of the first calculation₂＝0，P_refTo output power set point, P₂The output power value of the second inversion/rectification circuit;

s108: according to the formula f_s＝K_p2e₂+K_i2×(∫e₂dt+C₂) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁、S₂，S₅-S₈According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₃And S₄Wherein S is₅And S₁Same phase, S₆And S₂Same phase, S₈Relative to S₆Lead T_rTime; s₅、S₆Complementary phase, S₇、S₈Complementary phase, S₁、S₂Complementary in phase, during a working period T_sIn the first half period, S₄And S₈Same phase, S₃And S₂In phase; in the second half period, S₃And S₇Same phase, S₄And S₅Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₂As power error, e₂＝P_ref－P₁，K_p2And K_i2Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₂C in the current beat calculation as an integral constant₂Integral e with last beat calculation₂dt+C₂Value of (C) at the time of the first calculation₂＝0，P_refTo output power set point, P₁The output power value of the first inversion/rectification circuit;

s109: and (4) transmitting the PWM signals to corresponding switching tubes, and finishing the work after the transmission process is finished.

Further, the output power proportionality coefficient K_p1And the output power integral coefficient K_i1The determination process of (2) is:

s201: will K_i1The initial value is 0;

s202: debugging K first_p1Checking whether the output power waveform of the high-frequency intermittent control system of the bidirectional series resonant converter oscillates or not, if so, reducing K_p1Until the waveform oscillation is eliminated, the process is switched to S203; otherwise, the process S202 continues debugging K_p1Until the waveform oscillation is eliminated;

s203: fixed K_p1Value, debug K_i1Checking whether the output power waveform fluctuates at the moment, if so, reducing K_i1Until the waveform oscillation is eliminated; otherwise, continue debugging K_i1Until the waveform oscillation is eliminated;

s204: will K_p1And K_i1The final value of (a) is used as the output power proportionality coefficient K_p1And the output power integral coefficient K_i1。

Further, the output power proportionality coefficient K_p2And the output power integral coefficient K_i2The determination process of (2) is:

s301: will K_i2The initial value is 0;

s302: debugging K first_p2Checking whether the output power waveform of the high-frequency intermittent control system of the bidirectional series resonant converter oscillates or not, if so, reducing K_p2Until the waveform oscillation is eliminated, the process is switched to S303; otherwise, continue debugging K_p2Until the waveform oscillation is eliminated;

s303: fixed K_p2Value, debug K_i2Checking whether the output power waveform fluctuates at the moment, if so, reducing K_i2Until the waveform oscillation is eliminated; otherwise, continue debugging K₂Until the waveform oscillation is eliminated;

s304: finally obtaining the output power proportionality coefficient K_p2And the output power integral coefficient K_i2。

The technical scheme provided by the invention has the beneficial effects that: the bidirectional DC-DC series resonant converter simultaneously realizes the functions of boosting and reducing voltage and realizes a wide gain range; the operation of the converter in a half switching period is divided into a working state and a silent state, in the working state, the high pulse frequency can effectively reduce voltage ripple, and in the silent state, energy stored in the working state of the resonant network generates pulse control oscillation to release the energy to a load, so that the oscillation is inhibited. All switches are switched on or off when the resonant current is zero, so that the equipment realizes wide-range zero-current switching, and the switching loss is reduced.

Drawings

FIG. 1 is a schematic diagram of a high frequency intermittent control system and method of a bi-directional series resonant converter of the present invention;

FIG. 2 is a circuit diagram of an embodiment of a system and method for high frequency intermittent control of a bi-directional series resonant converter of the present invention;

FIG. 3 is a control flow chart of the high frequency intermittent control system and method of the bidirectional series resonant converter of the present invention;

FIG. 4 is a schematic diagram of the switching tube driving signals of the high-frequency intermittent control system and method of the bidirectional series resonant converter in the boost mode according to the present invention;

fig. 5 is a schematic diagram of the switching tube driving signals of the high-frequency intermittent control system and method of the bidirectional series resonant converter in the buck mode according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be further described with reference to the accompanying drawings.

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings. Referring to fig. 1 and fig. 2, fig. 1 and fig. 2 show a schematic diagram of a high-frequency intermittent control system of a bidirectional series resonant converter according to the present invention and a circuit diagram of an embodiment of the high-frequency intermittent control system.

The high-frequency intermittent control system of the bidirectional series resonant converter of the present embodiment can enable direct current electric energy to flow bidirectionally, and includes a first input power supply 1, a first filter circuit 2, a first inverter/rectifier circuit 3, a resonant circuit 4, a high-frequency transformer 5, a second inverter/rectifier circuit 6, a second filter circuit 7, a second input power supply 8 voltage and current acquisition circuit 91, a voltage and current acquisition circuit 92, a first controller 101, a second controller 102, a first driving circuit 111, and a second driving circuit 112;

the output end of the first input power supply 1 is connected with the input end of the first filter circuit 2, and the feedback end of the first filter circuit 2 is connected with the input end of the first voltage and current acquisition circuit 91; the output end of the first voltage and current acquisition circuit 91 is connected with the input end of the first controller 101, the output end of the first controller 101 is connected with the first driving circuit 111, and the output end of the first driving circuit 111 is connected with the first input end of the second inversion/rectification circuit 6;

the output end of the first filter circuit 2 is connected with the first input end of the first inversion/rectification circuit 3, the input end of the resonance circuit 4 is connected with the output end of the first inversion/rectification circuit 3, and the output end of the resonance circuit 4 is connected with the input end of the high-frequency transformer 5; the output end of the high-frequency transformer 5 is connected with the second input end of the second inversion/rectification circuit 6; the output end of the second inversion/rectification circuit is connected with the input end of the second filter circuit 7; the output end of the second filter circuit 7 is used for connecting with the second input power supply 8, and the feedback end of the second filter circuit 7 is connected with the input end of the second voltage and current acquisition circuit 92; the output end of the second voltage and current collecting circuit 92 is connected to the input end of the second controller 102, the output end of the second controller 102 is connected to the input end of the second driving circuit 112, and the output end of the second driving circuit 112 is connected to the second input end of the first inverter/rectifier circuit 3.

The high-frequency intermittent control system of the bidirectional series resonant converter enables direct current to flow bidirectionally, wherein the working mode of energy transmission from the first input power supply 1 to the second input power supply 8 is a forward transmission mode, and the working mode of energy transmission from the second input power supply 8 to the first input power supply 1 is a reverse transmission mode.

The first filter circuit 2 and the second filter circuit 7 include: an LC filter circuit, a CL filter circuit, and an LCL filter circuit.

The resonant circuit 4 adopts a resonant circuit containing an inductor and a capacitor, and comprises: a series resonant circuit, a parallel resonant circuit, a series-parallel resonant circuit, an LLC resonant circuit, a CLC resonant circuit, and an LCL resonant circuit.

The high-frequency transformer 5 comprises a high-frequency isolation transformer, a high-frequency autotransformer and a high-frequency transformer with a center tap.

The first filter circuit 2 is a DC filter capacitor C₁First inverter/rectifier circuit 3 switching tube S₃Pin 2 and switch tube S₄Pin 1 is connected for connection to both ends of a first filter circuit 2, wherein a switching tube S₁And S₃Pin 1 for connecting filter capacitor C₁Positive electrode of (2), switching tube S₁And S₃Pin 2 for connecting filter capacitor C₁The first filter circuit 2 is used for filtering out harmonic waves in the current output by the rectifying circuit in a reverse transmission mode, and providing stable direct current energy for the first input power supply.

The first inverter/rectifier circuit 3 adopts a full-bridge voltage type converter for converting the DC voltage of the input power supply into periodically-changing square wave voltage with symmetrical positive and negative half periods according to the driving signal output by the driving circuit 11, and the voltage V of the first input power supply 1₁Has a range of 240V-480V, a rated voltage of 400V and a current I₁In the range of 0-2.5A.

The first inversion/rectification circuit 3 comprises four same switching tubes S₁～S₄Each switching tube S₁-S₄A group of diodes and buffer capacitors connected in parallel are respectively connected between the pin 1 and the pin 2, wherein the anode of the diode is connected with the pin 2 corresponding to the switch tube, the cathode is connected with the pin 1 corresponding to the switch tube, and the switch tube S₁Pin 2 and switch tube S₂Pin 1 is connected for connection to a first input powerBetween the two outputs of the source 1, a switching tube S₃Pin 2 and switch tube S₄The pins 1 are connected and then used for being connected between two output ends of a first input power supply 1; wherein, the switch tube S₁And S₃Pin 1 for connecting a first input power supply 1 and a reverse filter capacitor C₁Positive electrode of (2), switching tube S₂And S₄Pin 2 for connecting a first input power supply 1 and a reverse filter capacitor C₁Negative electrode of (2), switching tube S₁-S₄Selected types include MOSFETs, BJTs and IGBTs.

The resonance circuit 4 adopts a series LC resonance circuit comprising an inductor and a capacitor and is used for generating high-frequency resonance current under the excitation of square wave voltage, and a resonance inductor L_r50 muH, resonant capacitance C_r12nF, resonant frequency 200 kHz; the series LC resonant circuit comprises a resonant inductor L_rAnd a resonant capacitor C_rResonant capacitor C_rOne end of the first inverter/rectifier circuit 3 is connected with a switching tube S₁Pin 2, the other end is connected in series with a resonance inductor L_r，L_rThe other end of the switch tube S is connected with the switch tube S₃Pin 2 of the transformer is connected with one end of the primary side of the high-frequency transformer 5.

The high-frequency transformer 5 is a high-frequency isolation transformer and is used for amplifying or reducing high-frequency resonance voltage and current, and the transformation ratio is 8: 1; one end of the primary side of the high-frequency isolation transformer is connected with a resonant inductor L_rAnd a switching tube S₃Pin 2, the other end of the primary side is connected to a third switch tube S₃And a fourth switching tube S₄Under the excitation of the square wave voltage output by the first inverter/rectifier circuit 3, the resonant inductor L of the resonant circuit 4_rResonant capacitor C_rThe equivalent excitation inductance of the primary side of the high-frequency isolation transformer generates a high-frequency resonant current which is approximate to sine and is transmitted to the secondary side of the high-frequency isolation transformer through the primary side of the high-frequency isolation transformer.

The second inverter/rectifier circuit 6 adopts a full-bridge circuit, is used as a full-wave rectifier circuit in a forward transmission mode, and is used for converting high-frequency resonance current into direct current and secondary side voltage; in reverse transmission mode, as a full-bridge voltage-type converter for outputting according to the driving circuitThe drive signal converts the DC voltage of the input power into periodically-changed square-wave voltage with positive and negative half-period symmetry and secondary side voltage V₂In the range of 24-56V, rated voltage of 48V, current I₂In the range of 0-20A.

The second inversion/rectification circuit 6 has four same switching tubes S₅～S₈Each switching tube S₅-S₈A group of diodes and buffer capacitors connected in parallel are respectively connected between the pin 1 and the pin 2, wherein the anode of the diode is connected with the pin 2 corresponding to the switch tube, the cathode is connected with the pin 1 corresponding to the switch tube, and the switch tube S₅Pin 2 and switch tube S₆Pin 1 is connected for connection between two output terminals of a second input power supply 2, a switching tube S₇Pin 2 and switch tube S₈The pin 1 is connected and then used for connecting between two output ends of a second input power supply 2; wherein, the switch tube S₅And S₇Pin 1 and pin 2 of (2) are used for connecting the output end of a high-frequency transformer 5, S₅And S₇Pin 1 for connecting a second input power supply 8 and a filter capacitor C₂Positive electrode of (2), S₆And S₈Pin 2 for connecting a second input power supply 8 and a filter capacitor C₂Negative electrode of (2), switching tube S₅-S₈Types of (d) include MOSFETs, BJTs and IGBTs.

The second filter circuit 7 is a DC filter capacitor C₂Second inverter/rectifier circuit 6 switch tube S₇Pin 2 and switch tube S₈Pin 1 of the first filter circuit is connected for connection to two ends of a second filter circuit 7, wherein a switch tube S₅And S₇Pin 1 for connecting filter capacitor C₂Positive electrode of (2), switching tube S₆And S₈Pin 2 for connecting filter capacitor C₂And the second filter circuit 7 is used for filtering out harmonic waves in the current output by the rectifying circuit in the forward transmission mode and providing stable direct current energy for the second input power supply 8.

Referring to fig. 3, a high-frequency intermittent control method for a bidirectional series resonant converter is used in any one of the high-frequency intermittent control systems for a bidirectional series resonant converter, and includes the following steps:

(1) collecting a voltage value V of a first input power supply 1₁A current value I output by the first inverter/rectifier circuit 3₁And the voltage value V of the second input power supply 8₂A current value I output by the second inverter/rectifier circuit 6₂The power P output by the first inversion/rectification circuit 3 is calculated by the controller₁And the power P output by the second inverter/rectifier circuit 6₂；

(2) Determining reference power P_refIf P is positive or negative_refIf more than 0, the converter works in the forward direction, step (3) is carried out, P_ref< 0, the inverter operates in reverse, step (4) is carried out, wherein P_refIs the set value of the output power;

(3) judgment V₁And nV₂If V is a magnitude relation of₁≤nV₂Step (5), if V is₁＞nV₂The converter forward steps down, and then step (7) is carried out;

(4) judgment V₁And nV₂If V is a magnitude relation of₁≤nV₂Step (8) is carried out, if V is₁＞nV₂The converter boosts the voltage in the reverse direction, and then the step (6) is performed;

(5) according to the formula f_s＝K_p1e₁+K_i1×(∫e₁dt+C₁) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁、S₂，S₅-S₈According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₃And S₄Wherein S is₁And S₅Same phase, S₂And S₆Same phase, S₈Relative to S₂Hysteresis T_rTime; s₁、S₂Complementary phase, S₅、S₆Complementary phase, S₇、S₈Complementary in phase, during a working period T_sIn the first half period, S₄Relative to S₂Lead T_rTime, S₃And S₂In phase; in the second half period, S₃Relative to S₁Lead T_rTime, S₄And S₁In phase, turning to step (9);

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₁As power error, e₁＝P_ref－P₂，K_p1And K_i1Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₁C in the current beat calculation as an integral constant₁Integral e with last beat calculation₁dt+C₁Value of (C) at the time of the first calculation₁＝0，P_refTo output power set point, P₂The output power value of the second inversion/rectification circuit;

(6) according to the formula f_s＝K_p1e₁+K_i1×(∫e₁dt+C₁) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁-S₄，S₅、S₆According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₇And S₈(ii) a Wherein S is₅And S₁Same phase, S₆And S₂Same phase, S₄Relative to S₆Hysteresis T_rTime; s₅、S₆Complementary phase, S₁、S₂Complementary phase, S₃、S₄Complementary in phase, during a working period T_sIn the first half period, S₈Relative to S₆Lead T_rTime, S₇And S₆In phase; in the second half period, S₇Relative to S₅Lead T_rTime, S₈And S₅In phase, turning to step (9);

wherein f is_rTo the resonant frequency, T_rIs at resonancePeriod, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₁As power error, e₁＝P_ref－P₁，K_p1And K_i1Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₁C in the current beat calculation as an integral constant₁Integral e with last beat calculation₁dt+C₁Value of (C) at the time of the first calculation₁＝0，P_refTo output power set point, P₁The output power value of the first inversion/rectification circuit;

(7) according to the formula f_s＝K_p2e₂+K_i2×(∫e₂dt+C₂) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁-S₄，S₅、S₆According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₇And S₈Wherein S is₁And S₅Same phase, S₂And S₆Same phase, S₄Relative to S₂Tr time ahead; s₁、S₂Complementary phase, S₃、S₄Complementary phase, S₅、S₆Complementary in phase, during a working period T_sIn the first half period, S₈And S₄Same phase, S₇And S₆In phase; in the second half period, S₇And S₃Same phase, S₈And S₁In phase, turning to step (9);

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₂As power error, e₂＝P_ref－P₂，K_p2And K_i2Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₂C in the current beat calculation as an integral constant₂Integral e with last beat calculation₂dt+C₂Value of (C) at the time of the first calculation₂＝0，P_refTo output power set point, P₂The output power value of the second inversion/rectification circuit;

(8) according to the formula f_s＝K_p2e₂+K_i2×(∫e₂dt+C₂) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁、S₂，S₅-S₈According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₃And S₄Wherein S is₅And S₁Same phase, S₆And S₂Same phase, S₈Relative to S₆Lead T_rTime; s₅、S₆Complementary phase, S₇、S₈Complementary phase, S₁、S₂Complementary in phase, during a working period T_sIn the first half period, S₄And S₈Same phase, S₃And S₂In phase; in the second half period, S₃And S₇Same phase, S₄And S₅And (5) rotating to the step (9) in the same phase.

Wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₂As power error, e₂＝P_ref－P₁，K_p2And K_i2Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₂C in the current beat calculation as an integral constant₂Integral e with last beat calculation₂dt+C₂Value of (C) at the time of the first calculation₂＝0，P_refTo output power set point, P₁The output power value of the first inversion/rectification circuit;

(9) and (4) transmitting the PWM signals to corresponding switching tubes, and finishing the work after the transmission process is finished.

The output power proportional coefficient K_p1And the output power integral coefficient K_i1The determination process of (2) is:

(1) will K_i1The initial value is 0;

(2) debugging K first_p1Checking whether the output power waveform of the high-frequency intermittent control system of the bidirectional series resonant converter oscillates or not, if so, reducing K_p1Turning to the process (3) until the waveform oscillation is eliminated; otherwise, the process (2) is switched to continue debugging K_p1；

(3) Fixed K_p1Value, debug K_i1Checking whether the output power waveform fluctuates at the moment, if so, reducing K_i1Until the waveform oscillation is eliminated; otherwise, go to procedure (3) to continue debugging K_i1；

(4) Will K_p1And K_i1The final value of (a) is used as the output power proportionality coefficient K_p1And the output power integral coefficient K_i1。

The output power proportional coefficient K_p2And the output power integral coefficient K_i2The determination process of (2) is:

(1) will K_i2The initial value is 0;

(2) debugging K first_p2Checking whether the output power waveform of the high-frequency intermittent control system of the bidirectional series resonant converter oscillates or not, if so, reducing K_p2Turning to the process (3) until the waveform oscillation is eliminated; otherwise, the process (2) is switched to continue debugging K_p2；

(3) Fixed K_p2Value, debug K_i2Checking whether the output power waveform fluctuates at the moment, if so, reducing K_i2Until the waveform oscillation is eliminated; otherwise, go to procedure (3) to continue debugging K₂；

(4) Finally obtaining the output power proportionality coefficient K_p2And the output power integral coefficient K_i2。

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (11)

1. A high-frequency intermittent control system of a bidirectional series resonant converter is characterized by comprising a first input power supply (1), a first filter circuit (2), a first inversion/rectification circuit (3), a resonance circuit (4), a high-frequency transformer (5), a second inversion/rectification circuit (6), a second filter circuit (7), a second input power supply (8), a first voltage and current acquisition circuit (91), a second voltage and current acquisition circuit (92), a first controller (101), a second controller (102), a first drive circuit (111) and a second drive circuit (112);

the output end of the first input power supply (1) is connected with the input end of the first filter circuit (2), and the feedback end of the first filter circuit (2) is connected with the input end of the first voltage and current acquisition circuit (91); the output end of the first voltage and current acquisition circuit (91) is connected with the input end of a first controller (101), the output end of the first controller (101) is connected with a driving circuit (111), and the output end of the first driving circuit (111) is connected with the first input end of a second inversion/rectification circuit (6);

the output end of the first filter circuit (2) is connected with the first input end of the first inversion/rectification circuit (3), the input end of the resonance circuit (4) is connected with the output end of the first inversion/rectification circuit (3), and the output end of the resonance circuit (4) is connected with the input end of the high-frequency transformer (5); the output end of the high-frequency transformer (5) is connected with the second input end of the second inversion/rectification circuit (6); the output end of the second inversion/rectification circuit (6) is connected with the input end of the second filter circuit (7); the output end of the second filter circuit (7) is connected with a second input power supply (8), and the feedback end of the second filter circuit (7) is connected with the input end of the second voltage and current acquisition circuit (92); the output end of the second voltage and current acquisition circuit (92) is connected to the input end of the second controller (102), the output end of the second controller (102) is connected to the input end of the second driving circuit (112), and the output end of the second driving circuit (112) is connected with the second input end of the first inversion/rectification circuit (3).

2. A high frequency intermittent control system of a bidirectional series resonant converter as recited in claim 1, wherein the high frequency intermittent control system of the bidirectional series resonant converter makes a bidirectional flow of direct current, wherein an operation mode of energy transmission from the first input power source (1) to the second input power source (8) is a forward transmission mode, and an operation mode of energy transmission from the second input power source (8) to the first input power source (1) is a reverse transmission mode.

3. A high frequency intermittent control system of a bidirectional series resonant converter as recited in claim 1, characterized in that said first filter circuit (2) is a dc filter capacitor C₁A first inversion/rectification circuit (3) switch tube S₃Pin 2 and switch tube S₄Pin 1 is connected for connection to both ends of a first filter circuit (2) of the resonant converter, wherein a switching tube S₁And S₃Pin 1 for connecting filter capacitor C₁Positive electrode of (2), switching tube S₁And S₃Pin 2 for connecting filter capacitor C₁The first filter circuit (2) is used for filtering harmonic waves in current output by the rectifying circuit in a reverse transmission mode and providing stable direct current energy for the first input power supply (1).

4. A high frequency intermittent control system of a bidirectional series resonant converter as recited in claim 1, wherein said first inverter/rectifier circuit (3) comprises four identical switching tubes S₁～S₄Each switching tube S₁-S₄A group of diodes and buffer capacitors connected in parallel are respectively connected between the pin 1 and the pin 2, wherein the anode of the diode is connected with the pin 2 corresponding to the switch tube, the cathode is connected with the pin 1 corresponding to the switch tube, and the switch tube S₁Pin 2 and switch tube S₂The pin 1 is connected and then used for being connected between two output ends of a first input power supply (1), and a switching tube S₃Pin 2 and switch tubeS₄The pins 1 are connected and then are used for being connected between two output ends of a first input power supply (1); wherein, the switch tube S₁And S₃Pin 1 of the reverse filter is used for connecting a first input power supply (1) and a reverse filter capacitor C₁Positive electrode of (2), switching tube S₂And S₄Pin 2 for connecting a first input power supply (1) to a reverse filter capacitor C₁Negative electrode of (2), switching tube S₁-S₄Selected types include MOSFETs, BJTs and IGBTs.

5. A high frequency intermittent control system of a bidirectional series resonant converter as recited in claim 1, characterized in that said resonant circuit (4) employs a series LC resonant circuit comprising an inductor and a capacitor, the series LC resonant circuit comprising a resonant inductor L_rAnd a resonant capacitor C_rResonant capacitor C_rOne end of the first inverter/rectifier circuit (3) is connected with a switching tube S₁Pin 2, the other end is connected in series with a resonance inductor L_r，L_rThe other end of the switch tube S is connected with the switch tube S₃Pin 2 is connected with one end of the primary side of the high-frequency transformer (5).

6. The high frequency intermittent control system of the bidirectional series resonant converter as recited in claim 1, wherein said high frequency transformer (5) is a high frequency isolation transformer, one end of the primary side of the high frequency isolation transformer is connected to a resonant inductor L_rAnd a switching tube S₃Pin 2, the other end of the primary side is connected to a third switch tube S₃And a fourth switching tube S₄Under the excitation of the square wave voltage output by the first inverter/rectifier circuit (3), the resonant inductor L of the resonant circuit (4)_rResonant capacitor C_rThe equivalent excitation inductance of the primary side of the high-frequency isolation transformer generates a high-frequency resonant current which is approximate to sine and is transmitted to the secondary side of the high-frequency isolation transformer through the primary side of the high-frequency isolation transformer.

7. A high frequency intermittent control system of a bidirectional series resonant converter as recited in claim 1, wherein said second inverter/rectifier circuit (6) has four identical inverter/rectifier circuits in totalSwitch tube S₅～S₈Each switching tube S₅-S₈A group of diodes and buffer capacitors connected in parallel are respectively connected between the pin 1 and the pin 2, wherein the anode of the diode is connected with the pin 2 corresponding to the switch tube, the cathode is connected with the pin 1 corresponding to the switch tube, and the switch tube S₅Pin 2 and switch tube S₆The pin 1 is connected and then is used for being connected between two output ends of a second input power supply (8), and a switching tube S₇Pin 2 and switch tube S₈The pins 1 are connected and then are used for being connected between two output ends of a second input power supply (8); wherein, the switch tube S₅And S₇Pin 1 and pin 2 of (2) are used for connecting the output end of a high-frequency transformer (5), S₅And S₇Pin 1 of the filter is used for connecting a second input power supply (8) and a filter capacitor C₂Positive electrode of (2), S₆And S₈Pin 2 for connecting a second input power supply (8) and a filter capacitor C₂Negative electrode of (2), switching tube S₅-S₈Types of (d) include MOSFETs, BJTs and IGBTs.

8. A high frequency intermittent control system of a bidirectional series resonant converter as recited in claim 1, characterized in that said second filter circuit (7) is a dc filter capacitor C₂A second inverter/rectifier circuit (6) switching tube S₇Pin 2 and switch tube S₈Pin 1 is connected for connection to both ends of a second filter circuit (7), wherein a switching tube S₅And S₇Pin 1 for connecting filter capacitor C₂Positive electrode of (2), switching tube S₆And S₈Pin 2 for connecting filter capacitor C₂And the second filter circuit (7) is used for filtering harmonic waves in the current output by the rectifying circuit in the forward transmission mode and providing stable direct current energy for the second input power supply (8).

9. A high-frequency intermittent control method of a bidirectional series resonant converter, which is used for a high-frequency intermittent control system of a bidirectional series resonant converter according to any one of claims 1 to 8, characterized by comprising the steps of:

s101: collecting a voltage value V of a first input power supply (1)₁A current value I output by the first inversion/rectification circuit (3)₁And the voltage value V of the second input power supply (8)₂A current value I output by the second inversion/rectification circuit (6)₂The power P output by the first inversion/rectification circuit (3) is calculated by the controller₁And the power P output by the second inversion/rectification circuit (6)₂；

S102: determining reference power P_refIf P is positive or negative_refIf > 0, the converter works in the forward direction, and the step S103 is carried out, P_ref< 0, the inverter operates in reverse, step S104, where P_refIs the set value of the output power;

s103: judgment V₁And nV₂If V is a magnitude relation of₁≤nV₂Step S105 is executed to step S105 if the converter is boosted in the forward direction₁＞nV₂Step S107 is executed after the converter forward voltage reduction;

s104: judgment V₁And nV₂If V is a magnitude relation of₁≤nV₂Step S108 is performed, if V is reached, the converter is reversely reduced₁＞nV₂Step S106 is executed;

s105: according to the formula f_s＝K_p1e₁+K_i1×(∫e₁dt+C₁) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁、S₂，S₅-S₈According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₃And S₄Wherein S is₁And S₅Same phase, S₂And S₆Same phase, S₈Relative to S₂Hysteresis T_rTime; s₁、S₂Complementary phase, S₅、S₆Complementary phase, S₇、S₈Complementary in phase, during a working period T_sIn the first half period, S₄Relative to S₂Lead T_rTime, S₃And S₂In phase; in the second half period, S₃Relative to S₁Lead T_rTime, S₄And S₁Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₁As power error, e₁＝P_ref－P₂，K_p1And K_i1Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₁C in the current beat calculation as an integral constant₁Integral e with last beat calculation₁dt+C₁Value of (C) at the time of the first calculation₁＝0，P_refTo output power set point, P₂The output power value of the second inversion/rectification circuit (6);

s106: according to the formula f_s＝K_p1e₁+K_i1×(∫e₁dt+C₁) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁-S₄，S₅、S₆According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₇And S₈(ii) a Wherein S is₅And S₁Same phase, S₆And S₂Same phase, S₄Relative to S₆Hysteresis T_rTime; s₅、S₆Complementary phase, S₁、S₂Complementary phase, S₃、S₄Complementary in phase, during a working period T_sIn the first half period, S₈Relative to S₆Lead T_rTime, S₇And S₆In phase; in the second half period, S₇Relative to S₅Lead T_rTime, S₈And S₅Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₁As power error, e₁＝P_ref－P₁，K_p1And K_i1Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₁C in the current beat calculation as an integral constant₁Integral e with last beat calculation₁dt+C₁Value of (C) at the time of the first calculation₁＝0，P_refTo output power set point, P₁The output power value of the first inversion/rectification circuit (3);

s107: according to the formula f_s＝K_p2e₂+K_i2×(∫e₂dt+C₂) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁-S₄，S₅、S₆According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₇And S₈Wherein S is₁And S₅Same phase, S₂And S₆Same phase, S₄Relative to S₂Tr time ahead; s₁、S₂Complementary phase, S₃、S₄Complementary phase, S₅、S₆Complementary in phase, during a working period T_sIn the first half period, S₈And S₄Same phase, S₇And S₆In phase; in the second half period, S₇And S₃Same phase, S₈And S₁Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₂As power error, e₂＝P_ref－P₂，K_p2And K_i2Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₂C in the current beat calculation as an integral constant₂The integral value calculated for the last beat∫e₂dt+C₂Value of (C) at the time of the first calculation₂＝0，P_refTo output power set point, P₂The output power value of the second inversion/rectification circuit (6);

s108: according to the formula f_s＝K_p2e₂+K_i2×(∫e₂dt+C₂) Obtaining an operating frequency command f_sGenerating duty ratio of 0.5 and working frequency of f_sPWM signal for controlling the switch S₁、S₂，S₅-S₈According to D ═ f_s/f_rGenerating a duty ratio of D and an operating frequency of f_sPWM signal for controlling the switch S₃And S₄Wherein S is₅And S₁Same phase, S₆And S₂Same phase, S₈Relative to S₆Lead T_rTime; s₅、S₆Complementary phase, S₇、S₈Complementary phase, S₁、S₂Complementary in phase, during a working period T_sIn the first half period, S₄And S₈Same phase, S₃And S₂In phase; in the second half period, S₃And S₇Same phase, S₄And S₅Turning to step S109 in the same phase;

wherein f is_rTo the resonant frequency, T_rFor the resonance period, T_r＝1/f_r；T_sIs a duty cycle, T_s＝1/f_s；e₂As power error, e₂＝P_ref－P₁，K_p2And K_i2Respectively an output power proportional coefficient and an output power integral coefficient, t is time, C₂C in the current beat calculation as an integral constant₂Integral e with last beat calculation₂dt+C₂Value of (C) at the time of the first calculation₂＝0，P_refTo output power set point, P₁The output power value of the first inversion/rectification circuit (3);

s109: and (4) transmitting the PWM signals to corresponding switching tubes, and finishing the work after the transmission process is finished.

10. The method according to claim 9, wherein the output power proportionality coefficient K is_p1And the output power integral coefficient K_i1The determination process of (2) is:

s201: will K_i1The initial value is 0;

s202: debugging K first_p1Checking whether the output power waveform of the high-frequency intermittent control system of the bidirectional series resonant converter oscillates or not, if so, reducing K_p1Until the waveform oscillation is eliminated, the process is switched to S203; otherwise, the process S202 continues debugging K_p1Until the waveform oscillation is eliminated;

s203: fixed K_p1Value, debug K_i1Checking whether the output power waveform fluctuates at the moment, if so, reducing K_i1Until the waveform oscillation is eliminated; otherwise, continue debugging K_i1Until the waveform oscillation is eliminated;

s204: will K_p1And K_i1The final value of (a) is used as the output power proportionality coefficient K_p1And the output power integral coefficient K_i1。

11. The method according to claim 9, wherein the output power proportionality coefficient K is_p2And the output power integral coefficient K_i2The determination process of (2) is:

s301: will K_i2The initial value is 0;

s302: debugging K first_p2Checking whether the output power waveform of the high-frequency intermittent control system of the bidirectional series resonant converter oscillates or not, if so, reducing K_p2Until the waveform oscillation is eliminated, the process is switched to S303; otherwise, continue debugging K_p2Until the waveform oscillation is eliminated;

s303: fixed K_p2Value, debug K_i2Checking whether the output power waveform fluctuates at the moment, if so, reducing K_i2Until the waveform oscillation is eliminated; otherwise, continue debugging K₂Until the waveform oscillation is eliminated;

s304: finally obtaining the output power proportionality coefficient K_p2And the output power integral coefficient K_i2。

Images