CN114759803A - Asymmetric multi-mode variable-bandwidth output LLC converter and design method - Google Patents

Abstract

The invention discloses an asymmetric multi-mode variable frequency wide output LLC converter, which comprises a primary side inverter circuit, a double LLC resonant tank, a double isolation transformer, a secondary side cascade voltage doubling rectifying circuit, an output filter capacitor and an output resistor load, and also discloses a design method of the asymmetric multi-mode variable frequency wide output LLC converter; the primary side inverter circuit has three different switch combinations to make the double LLC resonant tanks work in different modes so as to obtain three gains of low, medium and high, and adopts the asymmetric parameter n of the double isolation transformer₁=2n₂And the maximum normalized gain adjusting range is not more than 1.5, namely, a wide output voltage range of 1-3 times can be realized in a narrow frequency adjusting range. Soft switching can be realized in the full output gain range, the current circulation is small, and the working efficiency is high; secondary side adopts cascade connectionThe voltage-multiplying rectification cascade structure has a simple structure and few components. And the voltage stress of the secondary side device is small, and the method has important significance in high-voltage application occasions.

Description

Asymmetric multi-mode variable-bandwidth output LLC converter and design method

Technical Field

The invention belongs to the technical field of isolated DC-DC power converters, and particularly relates to an asymmetric multi-mode variable-bandwidth output LLC converter and a design method of the asymmetric multi-mode variable-bandwidth output LLC converter.

Background

The LLC resonant converter has the advantages of realizing zero-voltage switching-on of a primary side switching tube and zero-current switching-off of a secondary side diode in a full load range and the like. When the conventional LLC converter is applied in a wide output voltage field such as an LED driver, a battery charger, and a renewable power system, based on the characteristics of the resonant element, the normalized gain of most of the current resonant converters adjusted by frequency conversion control is within 1.5, otherwise the switching frequency of the resonant converter must swing in a wide range and deviate from the resonant frequency, which results in the overall efficiency of the system being reduced. Therefore, since the gain range of the conventional LLC converter is limited by the characteristics of the resonant tank, it is difficult to achieve both wide output and high efficiency through frequency modulation.

Disclosure of Invention

Aiming at the problems in the background art, the invention provides an asymmetric multi-mode variable bandwidth output LLC converter and a design method of the asymmetric multi-mode variable bandwidth output LLC converter. The working mode of the double LLC resonant tank II is changed by changing the working combination of the switching tubes of the primary side inverter circuit I, so that a wide output voltage range is obtained; at the same time, the first isolation transformer T₁And a second isolation transformer T₂Asymmetric relationship of turns ratio (n)₁=2n₂) The gain adjusting range of the converter under the frequency conversion control is within 1.5, and the phenomenon that the integral efficiency is reduced due to the fact that the switching frequency is far away from the resonant frequency due to the fact that the adjusting range is too wide is avoided.

In order to solve the technical problems, the invention adopts the following technical scheme:

an asymmetric multi-mode variable-frequency wide-output LLC converter comprises a first switch tube, a second switch tube, a third switch tube and a fourth switch tube, wherein a drain electrode of the first switch tube is connected with a drain electrode of the second switch tube and is connected with an anode of an input direct current source, a source electrode of the first switch tube, a drain electrode of the third switch tube and a first output interface are connected, a source electrode of the second switch tube, a drain electrode of the fourth switch tube and a second output interface are connected, and a source electrode of the third switch tube, a source electrode of the fourth switch tube, a cathode of the input direct current source and a third output interface are connected; the first output interface is connected with one end of a first resonant capacitor, the other end of the first resonant capacitor is connected with one end of a first resonant inductor, the other end of the first resonant inductor is connected with one end of a first excitation inductor and a primary side homonymy end of a first isolation transformer, a primary side synonym end of the first isolation transformer, the other end of the first excitation inductor, one end of a second excitation inductor, a primary side homonymy end of the second isolation transformer and a second output interface are connected, a primary side synonym end of the second isolation transformer, the other end of the second excitation inductor and one end of the second resonant inductor are connected, the other end of the second resonant inductor is connected with one end of a second resonant capacitor, and the other end of the second resonant capacitor is connected with a third output interface; the homonymous terminal of the secondary side of the first isolation transformer is connected with the cathode of the first rectifier diode and the anode of the third diode, one end of a first energy storage capacitor is connected with the synonym terminal of the secondary side of the first isolation transformer, the other end of the first energy storage capacitor is respectively connected with the anode of the first rectifier diode, the cathode of the second rectifier diode and the synonym terminal of the secondary side of the second isolation transformer, one end of a second energy storage capacitor is connected with the homonymous terminal of the secondary side of the second isolation transformer, and the other end of the second energy storage capacitor is connected with the anode of the second rectifier diode; and the two ends of the output capacitor connected with the load in parallel are respectively connected with the cathode of the third diode and the anode of the second rectifier diode.

As described above, the turn ratio of the primary winding to the secondary winding of the first isolation transformer and the turn ratio of the primary winding to the secondary winding of the second isolation transformer are n₁And n₂，n₁=2n₂。

As described above, the capacitance values of the first resonant capacitor and the second resonant capacitor are the same, the inductance values of the first resonant inductor and the second resonant inductor are the same, and the inductance values of the first excitation inductor and the second excitation inductor are the same.

Under a first mode V1, the first switch tube and the second switch tube are normally open, and the third switch tube and the fourth switch tube are conducted in a complementary mode;

in a second mode V2, the first switching tube is normally closed, the second switching tube is normally open, and the third switching tube and the fourth switching tube are conducted in a complementary manner;

in a third mode V3, the first switching tube and the third switching tube are conducted complementarily, the second switching tube and the fourth switching tube are conducted complementarily, and the second switching tube and the third switching tube are conducted synchronously.

A design method of an asymmetric multi-mode variable bandwidth output (LLC) converter comprises the following steps:

step 1, the output voltage at the resonant point of the first mode V1 can be obtained

，V _inIs the dc input voltage of the dc source,V _ofor outputting the voltage of the load R according to n₂Determining n based on the following two inequalities₁，

Wherein n is₁Is a first isolating transformer T₁The turn ratio of the primary side winding to the secondary side winding, n₂Is a second isolating transformer T₂The turn ratio of the primary side winding to the secondary side winding;

step 2, selectingkAnd a quality factorQ ₂，kIs a second excitation inductance L_m2And a second resonant inductor L_r2The ratio of (a) to (b),

step 3, calculating the characteristic impedance Z_r，

Equivalent impedance of alternating current

，

，

Wherein the content of the first and second substances,Ris an output load;

step 4, calculating the resonance parameters,

，

，

，

wherein L is_r1And L_r2Respectively, the inductance value of the first resonant inductor and the inductance value of the second resonant inductor, L_m1And L_m2Inductance values of the first and second exciting inductances, C, respectively_r1And C_r2Respectively the capacitance values of the first resonance capacitor and the second resonance capacitor,f _r is the resonant frequency;

step 5, if

If so, the parameters meet the requirements;

otherwise, reselectingkAndQ ₂returning to the step 3;

wherein, t_dIs the dead time; c_ossIs the parasitic capacitance of the switching tube.

Compared with the prior art, the invention has the beneficial effects that:

by adopting asymmetric parameters of the two isolation transformers, under the control of frequency conversion, the maximum normalized gain adjustment range is not more than 1.5, namely, the wide output voltage range of 1-3 times can be realized in the narrow frequency adjustment range, soft switching can be realized in the full output gain range, the current circulation is small, and the working efficiency is high; the secondary side adopts a voltage-doubling rectifying cascade structure, the structure is simple, and the number of components is small. And the voltage stress of the secondary side device is small, and the method has important significance in high-voltage application occasions.

Drawings

FIG. 1 is a schematic block diagram of the present invention;

FIG. 2 is a diagram illustrating a state of a primary side inverter circuit I according to the present invention in different modes;

FIG. 3 is a graph of the output gain of the present invention;

FIG. 4 is a steady state simulation waveform diagram with an output of 100-150V in the first mode V1 according to the present invention;

FIG. 5 is a steady state simulation waveform diagram with an output of 150-200V in the second mode V2 according to the present invention;

FIG. 6 is a steady state simulation waveform diagram with an output of 200-300V in the third mode V3 according to the present invention;

FIG. 7 shows the second switch tube S of the present invention at the 150V output of the first mode V1₂The fourth switch tube S₄ZVS simulation waveforms of (a);

FIG. 8 shows the second rectifying diode D of the present invention at the 150V output of the first mode V1₂A third diode D₃ZCS simulation waveform of (a);

FIG. 9 shows the second switch tube S of the present invention at the 200V output of the second mode V2₂And a fourth switching tube S₄ZVS simulation waveforms of (a);

FIG. 10 shows the 200V output first rectifying diode D of the present invention in the second mode V2₁A second rectifier diode D₂A third diode D₃ZCS simulation waveform of (a);

FIG. 11 shows the second switch tube S with 300V output in the third mode V3 according to the present invention₂And a fourth switching tube S₄ZVS simulation waveforms of (a);

FIG. 12 is a schematic diagram of the 300V output first rectifier diode D of the present invention in the third mode V3₁A second rectifier diode D₂A third diode D₃ZCS simulation waveform of (1).

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the following embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other cases, which can be obtained by a person skilled in the art without making creative efforts based on the embodiments of the present invention, belong to the protection scope of the present invention.

As shown in fig. 1, an asymmetric multi-mode variable bandwidth output LLC converter structure includes a primary side inverter circuit i, a dual LLC resonant tank ii, an isolation transformer iii, and a secondary side cascaded voltage-doubler rectifier circuit iv.

The primary side inverter circuit I comprises a first switch tube S₁A second switch tube S₂A third switch tube S₃And a fourth switching tube S₄；

The double LLC resonant tank II comprises a first resonant tank and a second resonant tank. The first resonant tank includes a first resonant capacitor C_r1A first resonant inductor L_r1And a first excitation inductance L_m1. The second resonant tank includes a second resonant capacitor C_r2A second resonant inductor L_r2And a second excitation inductance L_m2The two resonant cavities share one branch and are connected to the midpoint of the second bridge arm (a second output interface b);

the isolation transformer III comprises a first isolation transformer T₁And a second isolation transformer T₂First isolation transformer T₁And a second isolation transformer T₂Using a double-winding high-frequency transformer, a first isolating transformer T₁And a second isolation transformer T₂The turn ratio of the primary side winding to the secondary side winding is N_p1:N_s1=n ₁1 and N_p2：N_s2=n₂：1；

The secondary side cascade voltage-multiplying rectification circuit IV comprises a first voltage-multiplying rectification unit, a second voltage-multiplying rectification unit and a third diode D₃. The first voltage-multiplying rectifying unit comprises a first energy-storage capacitor C₁And a first rectifying diode D₁The second voltage-multiplying rectification unit comprises a second energy-storage capacitor C₂And a second rectifying diode D₂。

A first switch tube S on the primary side₁And a second switching tube S₂Is connected with the anode of the input DC source, a first switch tube S₁Source electrode and third switch tube S₃Is connected with the first output interface a, and a second switch tube S₂Source electrode and fourth switching tube S₄Is connected with the second output interface b, and a third switching tube D₃Source electrode and fourth switch tube D₄The source electrode of the first output interface, the cathode of the input direct current source and the third output interface c are connected; a first output interface a and a first resonance capacitor C_r1One end connected to a resonant capacitor C_r1The other end and the first resonant inductor L_r1One end connected to the first resonant inductor L_r1The other end and the first excitation inductor L_m1One end of the first isolation transformer T is connected with the primary side dotted terminal of the first isolation transformer T₁Primary side unlike terminal, first excitation inductance L_m1The other end of (2), a second excitation inductance L_m2One end, second isolation transformer T₂The primary side homonymous terminal of the first isolation transformer T is connected with the second output interface b₂Primary side unlike terminal, second excitation inductance L_m2And the other end of the second resonant inductor L_r2One end connected to the second resonant inductor L_r2The other end of the capacitor is connected with a second resonant capacitor C_r2One end connected to the second resonant capacitor C_r2The other end of the first output interface is connected with a third output interface c; first isolation transformer T₁Homonymous terminal of secondary side and first rectifier diode D₁And a third diode D₃Is connected with the anode of a first energy storage capacitor C₁One end of the first isolating transformer T is connected with₁A synonym terminal of the secondary side and a first energy storage capacitor C₁The other end is respectively connected with a first rectifying diode D₁Anode of (2), second rectifying diode D₂And a second isolation transformer T₂The synonym terminals of the secondary side are connected, and a second energy storage capacitor C₂One end of the first isolating transformer is connected with the first isolating transformer T₂The dotted terminal of the secondary side, the second energy storage capacitor C₂One end of the second rectifying diode is connected with the first rectifying diode₂The anode of (1); output capacitor C_oThe two ends of the load R are connected with a third diode D in parallel₃And a second rectifying diode D₂The anodes of the two electrodes are connected to form an output loop.

In the embodiment, the double LLC resonant tank II works in different modes by mainly changing different combinations of the switching tubes on the primary side inversion side I of the converter, so that three gains, namely low gain, medium gain and high gain, are obtained. Fig. 2 is a schematic diagram showing the state of the primary-side inverter circuit i in different modes.

When the first switch tube S₁And a second switching tube S₂Normally open, third switch tube S₃And a fourth switching tube S₄During complementary conduction, the invention works in a first mode V1, wherein the first resonant tank I does not work, the second resonant tank II works in a half-bridge mode, and the third switching tube S is controlled by frequency conversion₃And a fourth switching tube S₄The complementary conducting switching frequency enables the output voltage range to cover 0.5-0.75 time of the direct current input voltage Vin;

when the first switch tube S₁Normally closed, second switching tube S₂Normally open, third switch tube S₃And a fourth switching tube S₄When the resonant tank is in complementary conduction, the resonant tank works in a second mode V2, the first resonant tank I and the second resonant tank II work in a half-bridge mode, and the third switching tube S is controlled by frequency conversion₃And a fourth switching tube S₄The complementary conducting switching frequency enables the output voltage range to cover 0.75-1 time of the direct current input voltage Vin;

when the first switch tube S₁And a fourth switching tube S₄And a second switch tube S₂And a third switching tube S₃When complementary conduction is performed, i.e. the first switch tube S₁And a third switch tube S₃Complementary conduction, second switch tube S₂And a fourth switching tube S₄Complementary conduction, second switch tube S₂And a third switch tube S₃Synchronously conducting, the converter works in a third mode V3, the first resonant tank I works in a full-bridge mode, the second resonant tank II works in a half-bridge mode, and the first switching tube S is controlled by frequency conversion₁And a fourth switching tube S₄And a second switch tube S₂And a third switching tube S₃The complementary conducting switching frequency makes the output voltage range cover 1-1.5 times of the DC input voltage Vin.

Table 1 shows the operating modes of the two resonant tanks of the converter and the circuit gains in the 3 modes:

wherein n is₁And n₂Are respectively a first isolation transformer T₁Primary side winding to secondary side winding turns ratio and second isolation transformer T₂The turn ratio of the primary winding to the secondary winding.

In a wide range of applications, considering the design of the magnetic element and the narrow frequency modulation range, the normalized gain suitable for the operation of the LLC resonant converter is within 1.5. To ensure that the gain between the 3 modes is continuous, we can:

（1）

thus taking n₁=2n₂。

Output gain of the circuit in the first mode V1G ₁The expression is as follows:

（2）

wherein:kis a second excitation inductance L_m2And a second resonant inductor L_r2The inductance ratio of (a); quality factor

(ii) a AC equivalent impedance

；f _n In order to normalize the frequency of the signal,

，f _sin order to be able to switch the frequency,f _ris the resonant frequency;Ris the output load.

Output gain of the circuit in the second mode V2G ₂The expression is as follows:

（3）

wherein:kis a second excitation inductance L_m2And a second resonant inductor L_r2The inductance ratio of (a); quality factor

(ii) a Quality factor

(ii) a AC equivalent impedance

(ii) a Equivalent impedance of alternating current

；f _n In order to normalize the frequency of the signal,

，f _sin order to be able to switch the frequency,f _ris the resonant frequency;Ris the output load.

Output gain of the circuit in the third mode V3G ₃The expression is as follows:

（4）

wherein:kis a second excitation inductance L_m2And a second resonant inductor L_r2The ratio of (A) to (B); quality factor

(ii) a Quality factor

(ii) a Equivalent impedance of alternating current

(ii) a AC equivalent impedance

；f _n In order to normalize the frequency of the signal,

，f _sin order to be able to switch the frequency,f _ris the resonant frequency;Ris the output load.

According to the gain formula of the converter in different modes, the parameter design method provided by the invention comprises the following steps:

step 1, the output voltage at the resonant point of the first mode V1 can be obtained

，V _inIs the dc input voltage of the dc source,V _ofor outputting the voltage of the load R according to n₂Determining n based on the following two inequalities₁，

Wherein n is₁Is a first isolating transformer T₁The turn ratio of the primary side winding to the secondary side winding, n₂Is a second isolating transformer T₂The turn ratio of the primary side winding to the secondary side winding;

considering the design of the magnetic element and the narrower frequency modulation range, the normalized gain suitable for the operation of the LLC resonant converter is within 1.5, so in order to maintain the gain continuity of the three modes, the inequality described above can be adopted for the transformation ratio relationship of the two isolation transformers.

Step 2, selecting proper oneskAndQ ₁(orQ ₂) According to the equations (2), (3) and (4), a gain curve can be obtained and the gain curve can satisfy the maximum gain requirement. When the converter has multiple modes, the gain requirement of each mode is ensured to be met during parameter design. Among the multiple circuit modes, one of the modes has the most strict gain requirement, and parameter design can be performed according to the mode. Analyzing and selecting the third modeV3, at this timek=3.5，Q ₂=0.64。

Step 3, calculating the characteristic impedance Z_r。

In the third mode V3, at this time: equivalent impedance of alternating current

，

And 4, calculating resonance parameters.

，

，

. Wherein the content of the first and second substances,f _r is the resonant frequency.

And 5, verifying whether the calculation parameters meet ZVS conditions.

The ZVS condition is satisfied as follows: in dead time, the excitation current I_Lm1And the parasitic capacitance charging and discharging process of the switch tube is completed, so that the drain-source voltage of the switch tube is reduced to zero when a gate-level signal arrives. The exciting electric induction satisfies the following conditions:

wherein, t_dIs the dead time; c_ossIs the parasitic capacitance of the switching tube.

If it is

If so, the parameters meet the requirements;

otherwise, reselectingkAndQ ₂returning to the step 3;

according to the parameter design process, the converter parameters shown in the table 2 are selected, and the converter voltage gain curve shown in fig. 3 can be obtained by combining the formulas (2) to (4), so that the designed parameters not only meet the requirement of continuous gain among the three modes, but also reach the wide output voltage range required by the converter.

As shown in table 3, compared with the voltage stress of the secondary side device of the conventional voltage-doubling LLC converter, it can be seen that the voltage stress of the secondary side device of the present embodiment is reduced, and the present embodiment has great significance in being applied to a wide output voltage field, especially a high voltage field.

FIG. 4 is a diagram of the under-resonant steady-state waveform of the first mode V1 of the present embodiment, wherein the DC input voltage V is_in200V, and the output voltage range can cover 100-150V through frequency conversion control. Wherein V_cbFor the input voltage of the second resonant tank 2, i.e. the voltage between the third output interface c and the second output interface b, it can be seen that the second resonant tank 2 operates in half-bridge mode. V_gs1Is a first switch tube S₁Drive pulse waveform of V_gs3For a third switching tube S₃The waveform of the driving pulse can be seen that the first switch tube S is at the moment₁A third switch tube S₃All are always on. V_gs2Is a second switch tube S₂Drive pulse waveform of (2), V_gs4Is a fourth switching tube S₄The two keep complementary conduction. I.C. A_Lm2Is a second excitation inductance L_m2Excitation current waveform of (I)_Lr2Is a second resonant inductor L_r2The resonant current waveform of (1). I is_D3Is a third diode D₃The current waveform of (1).

FIG. 5 shows an under-resonant steady-state wave of the present embodiment operating in the second mode V2Graph, DC input voltage V_inThe voltage is 200V, and the output voltage range can cover 150-200V through frequency conversion control. Wherein V_abIs the input voltage of the first resonant tank, i.e. the voltage between the first output interface a and the second output interface b; v_cbFor the input voltage of the second resonant tank, i.e. the voltage between the third output interface c and the second output interface b, it can be seen that both the first resonant tank and the second resonant tank operate in half bridge mode. V_gs1Is a first switch tube S₁Drive pulse waveform of V_gs3For a third switching tube S₃The driving pulse waveform of (2), it can be seen that the first switch tube S is at this moment₁Normally closed, third switch tube S₃Is normally open. V_gs2Is a second switch tube S₂Drive pulse waveform of V_gs4Is a fourth switching tube S₄The two keep complementary conduction. I is_Lm1Is a first excitation inductance L_m1Excitation current waveform of (I)_Lr1Is a first excitation inductance L_r1The resonant current waveform of (2). I is_Lm2Is a second excitation inductance L_m2Excitation current waveform of (I)_Lr2Is a second excitation inductance L_r2The resonant current waveform of (1). I is_D3Is a third diode D₃The current waveform of (1).

FIG. 6 is a diagram showing the under-resonant steady-state waveform of the third mode V3 of the present embodiment, wherein the DC input voltage V is_in200V, and the output voltage range can cover 200-300V through frequency conversion control. Wherein V_abThe input voltage of the first resonant tank is the voltage between the first output interface a and the second output interface b; v_cbFor the input voltage of the second resonant tank, i.e. the voltage between the third output interface c and the second output interface b, it can be seen that the first resonant tank operates in full-bridge mode and the second resonant tank operates in half-bridge mode. V_gs1Is a first switch tube S₁Drive pulse waveform of (2), V_gs3For a third switching tube S₃The two keep complementary conduction. V_gs2Is a second switch tube S₂Drive pulse waveform of V_gs4Is a fourth switching tube S₄The two keep complementary conduction.I_Lm1Is a first excitation inductance L_m1Excitation current waveform of (I)_Lr1Is a first excitation inductance L_r1The resonant current waveform of (2). I is_Lm2Is a second excitation inductance L_m2Excitation current waveform of (I)_Lr2Is a second excitation inductance L_r2The resonant current waveform of (1). I is_D3Is a third diode D₃The current waveform of (1).

As shown in fig. 7, 8, 9, 10, 11, and 12, the soft switching performance of the primary-side switching tube and the secondary-side diode in the present embodiment is different in output voltage. As can be seen from fig. 7, 9 and 11, the second switching tube S₂And a fourth switching tube S₄Drain-source voltage of the transistor at its corresponding trigger pulse signal V_gs2、V_gs4The voltage of the switch tube is reduced to zero before arrival, so that zero voltage switching-on of each switch tube is realized, and the switching-on loss of the switch tube is effectively reduced. As can be seen from fig. 8, 10 and 12, the first rectifying diode D₁A second rectifying diode D₂Before the voltage rises, the current is already reduced to zero, zero current turn-off is realized, and the turn-off loss of the diode is effectively reduced.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the spirit and scope of the invention.

Claims (5)

1. An asymmetrical multi-mode variable-frequency wide-output LLC converter comprises a first switch tube (S)₁) A second switch tube (S)₂) And a third switching tube (S)₃) And a fourth switching tube (S)₄) Characterized in that a first switching tube (S)₁) And a second switching tube (S)₂) Is connected with the anode of the input DC source, a first switch tube (S)₁) Source electrode of (S), third switching tube (S)₃) Is connected with the first output interface (a), and a second switch tube (S)₂) Source electrode ofFour-switch tube (S)₄) Is connected with the second output interface (b), and a third switching tube (D)₃) Source electrode, fourth switching tube (D)₄) The source electrode, the cathode of the input direct current source and the third output interface (c) are connected; a first output interface (a) and a first resonant capacitor (C)_r1) One end connected to a first resonant capacitor (C)_r1) The other end and the first resonant inductor (L)_r1) One end connected to the first resonant inductor (L)_r1) The other end is connected with a first excitation inductor (L)_m1) One end of the first isolation transformer (T) is connected with the primary side homonymous end of the first isolation transformer (T)₁) Primary side unlike terminal, first exciting inductance (L)_m1) The other end of (a), a second excitation inductance (L)_m2) One end, second isolation transformer (T)₂) The primary side homonymous terminal of the first isolation transformer (T) is connected with the second output interface (b)₂) Primary side unlike terminal, second exciting inductance (L)_m2) And the other end of the second resonant inductor (L)_r2) One end connected to the second resonant inductor (L)_r2) The other end and a second resonance capacitor (C)_r2) One end connected to a second resonant capacitor (C)_r2) The other end of the first output interface (c) is connected to the third output interface (c); first isolation transformer (T)₁) Second and third rectifying diodes (D)₁) And a third diode (D)₃) Is connected to the anode of a first energy-storing capacitor (C)₁) One end of the first isolating transformer is connected with the first isolating transformer (T)₁) A synonym terminal of the secondary side, a first energy storage capacitor (C)₁) The other end is respectively connected with a first rectifying diode (D)₁) Anode of (2), second rectifying diode (D)₂) And a second isolation transformer (T)₂) The different name ends of the secondary side are connected, and a second energy storage capacitor (C)₂) One end of the first isolating transformer is connected with the first isolating transformer (T)₂) The dotted terminal of the secondary side, the second energy storage capacitor (C)₂) The other end is connected to a second rectifying diode (D)₂) The anode of (1); output capacitance (C)_o) Both ends of the load (R) are connected with a third diode (R)D₃) And a second rectifying diode (D)₂) Are connected with each other.

2. An asymmetric multi-mode variable frequency wide output LLC converter according to claim 1, characterized in that said first isolation transformer (T ™)₁) Primary side winding to secondary side winding turns ratio and a second isolation transformer (T)₂) The turn ratio of the primary side winding to the secondary side winding is n₁And n₂，n₁=2n₂。

3. An asymmetric multi-mode variable frequency wide output LLC converter as claimed in claim 2, characterized in that said first resonant capacitor (C)_r1) And a second resonance capacitor (C)_r2) Has the same capacitance value as the first resonant inductor (L)_r1) And a second resonant inductance (L)_r2) Has the same inductance value as the first exciting inductance (L)_m1) And a second excitation inductance (L)_m2) The inductance values of (a) and (b) are the same.

4. An asymmetrical multi-mode variable frequency wide output LLC converter according to claim 3, wherein in the first mode V1, the first switch tube (S)₁) And a second switching tube (S)₂) Normally open, third switch tube (S)₃) And a fourth switching tube (S)₄) Conducting complementarily;

in the second mode V2, the first switch tube (S)₁) Normally closed, second switching tube (S)₂) Normally open, third switch tube (S)₃) And a fourth switching tube (S)₄) Conducting complementarily;

in the third mode V3, the first switch tube (S)₁) And a third switching tube (S)₃) Complementary conduction, second switch tube (S)₂) And a fourth switching tube (S)₄) Complementary conduction, second switch tube (S)₂) And a third switching tube (S)₃) And synchronously conducting.

5. A method of designing an asymmetric multi-mode variable bandwidth output (LLC) converter as claimed in claim 4, comprising the steps of:

step 1, the output voltage at the resonance point of the first mode V1 can be obtained

，V _inIs the dc input voltage of the dc source,V _ofor outputting the voltage of the load R according to n₂Determining n based on the following two inequalities₁，

Wherein n is₁Is a first isolating transformer T₁The turn ratio of the primary side winding to the secondary side winding, n₂Is a second isolating transformer T₂The turn ratio of the primary side winding to the secondary side winding;

step 2, selectingkAnd a quality factorQ ₂，kIs a second excitation inductance L_m2And a second resonant inductor L_r2The ratio of (a) to (b),

step 3, calculating the characteristic impedance Z_r，

AC equivalent impedance

，

，

Wherein the content of the first and second substances,Ris an output load;

step 4, calculating the resonance parameters,

，

，

，

wherein L is_r1And L_r2Respectively, the inductance value of the first resonant inductor and the inductance value of the second resonant inductor, L_m1And L_m2Inductance values of the first and second exciting inductances, C, respectively_r1And C_r2Respectively the capacitance values of the first resonance capacitor and the second resonance capacitor,f _r is the resonant frequency;

step 5, if

If so, the parameters meet the requirements;

otherwise, reselectkAndQ ₂returning to the step 3;

wherein, t_dIs the dead time; c_ossIs the parasitic capacitance of the switching tube.

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