CN203691234U - Dual output bus type high-gain converter based on coupling inductor voltage multiplying structure - Google Patents

Abstract

The utility model discloses a dual output bus type high-gain converter based on a coupling inductor voltage multiplying structure, which comprises a main switching tube device S, a clamping switching tube Sc, two free-wheel diodes Dr1, Dr2, two output diodes Do1, Do2, a clamping capacitor Cc, two switching tube capacitors C1, C2, two energy storage capacitors Co1, Co2, and a coupling inductor with two windings. High gain under a normal duty ratio is realized by using the coupling inductor voltage multiplying structure, and the voltage stress of the main switching tube device S is reduced; voltage overshoot generated when a main switching tube is turned off is effectively suppressed by using an active clamping circuit structure, and energy stored in an leakage inductor is recycled and stored; zero-voltage conduction of the main switching tube device and the clamping switching tube is realized by using the leakage inductor Lk of the coupling inductor; and the voltage stress of the first output diode Do1 and the voltage stress of the second output diode Do2 are enabled to be smaller than output voltage by using the switching tube capacitor C1, the switching tube capacitor C2, the first energy storage capacitor Co1 and the second energy storage capacitor Co2.

Description

Dual output bus type high-gain converter based on coupling inductance times laminated structure

Technical field

The utility model relates to DC-DC converter, is a kind of dual output bus type high-gain converter of realizing based on coupling inductance times laminated structure specifically.

Background technology

In the last few years, along with the further aggravation of energy crisis, the development of regenerative resource and application were more and more subject to the extensive concern of countries in the world.In renewable energy system, the electric energy that many regenerative resources are sent is all the direct current that voltage is lower, and need to grid transmission the direct current that voltage is higher, therefore need DC-to-DC converter that low voltage and direct current is converted to and is applicable to grid-connected high-voltage direct-current electricity, meanwhile, for personal safety aspect is considered, there is the requirement of electrical isolation many application scenarios.So low input ripple, high-gain, high efficiency isolated converter have important effect in regenerative resource is generated electricity by way of merging two or more grid systems field.

In practice, traditional Boost circuit cannot complete high step-up ratio and high efficiency conversion requirement.First, high step-up ratio needs high duty ratio, can cause so larger output diode current spike, causes larger reverse recovery current, has increased switching tube conduction loss.The second, the voltage stress of switching tube equates with output voltage, therefore can only select high withstand voltage power device, has further increased conduction loss.Finally, switching tube and diode are all operated in hard switching environment, and switching loss is larger.

High-gain converter topologies based on coupling inductance is day by day ripe.The topology of this type, by utilizing coupling inductance, for step-up ratio provides new control freedom degree, has reduced the voltage stress of power device simultaneously.But the voltage stress that these topological major defects are output diode is bigger than normal.

Summary of the invention

The purpose of this utility model is to provide a kind of dual output bus type high-gain converter based on coupling inductance times laminated structure, switch tube voltage stress is little and be soft open-minded, the simple in structure active-clamp dual output bus type high-gain converter of realizing based on coupling inductance times laminated structure.

The technical solution that realizes the utility model object is: a kind of dual output bus type high-gain converter based on coupling inductance times laminated structure, comprising: one provides the power supply V of electric energy _in; Coupling inductance, can regard as under ideal transformer by magnetizing inductance L in equivalence _mwith former limit leakage inductance L _kcomposition, is mainly used in storing electric charge, realizes LC resonant circuit and to the discharging and recharging of other circuit structure, one end of coupling inductance and power supply V _inforward end be connected, the other end of coupling inductance and former limit leakage inductance L _kbe connected.

Main switch circuit, is mainly used in the control to contactor state, coordinates other circuit structure to realize the output of high-gain DC voltage, and wherein main switching device is enhancement mode N-type metal-oxide-semiconductor, the former limit leakage inductance L of the drain electrode of main switching device S and coupling inductance _kone end is connected, and source electrode is connected with zero reference potential GND, and grid connects external control unit.

Clamp circuit, be mainly used in the voltage overshoot producing while suppressing main switching device S shutoff, and the recyclable energy being stored in leakage inductance, comprise a clamp switch pipe Sc and a clamping capacitance Cc, wherein the source electrode of clamp switch pipe Sc is connected with the drain electrode of main switching device S, the drain electrode of clamp switch pipe Sc is connected with one end of clamping capacitance Cc, the other end of clamping capacitance Cc is connected with zero reference potential GND, and the grid of clamp switch pipe Sc connects the external control unit for controlling its turn-on and turn-off.

Coupling inductance times laminated structure, the main high-gain with realizing under conventional duty ratio, thereby reduce the voltage stress of main switching device Sc, and can select low withstand voltage and power device low on-resistance further to reduce conduction loss, comprise coupling inductance secondary side winding L ₂, the first switching tube capacitor C ₁, second switch pipe capacitor C ₂, the first sustained diode _r1with the second sustained diode _r2, wherein coupling inductance secondary side winding L ₂one end be connected with the source electrode of clamp switch pipe Sc, coupling inductance secondary side winding L ₂the other end and the first switching tube capacitor C ₁one end be connected, simultaneously and second switch pipe capacitor C ₂one end be connected, the first switching tube capacitor C ₁the other end and the first sustained diode _r1negative electrode be connected, second switch pipe capacitor C ₂the other end and the second sustained diode _r2anode be connected, the first sustained diode _r1anode second and sustained diode _r2negative electrode be connected, simultaneously the first sustained diode _r1anode and the second sustained diode _r2the connected common node of negative electrode be connected with zero reference potential GND.

Dual output circuit structure, there is mid point zero potential in sort circuit structure, provides advantage for rear one-level realizes multi-level inverse conversion, comprises the first output diode D _o1, the second output diode D _o2, the first storage capacitor C _o1, the second storage capacitor C _o2, the first equivalent load R _o1with the second equivalent load R _o2, wherein the first output diode D _o1anode and sustained diode _r1negative electrode be connected, simultaneously and the first switching tube capacitor C ₁one end be connected, the first output diode D _o1negative electrode and the first storage capacitor C _o1positive pole be connected, the second output diode D _o2negative electrode and sustained diode _r2anode be connected, simultaneously and second switch pipe capacitor C ₂one end be connected, the second output diode D _o2anode and the second storage capacitor C _o2negative pole be connected, the first storage capacitor C _o1negative pole and the second storage capacitor C _o2positive pole be connected, the first equivalent load R _o1one end and the first storage capacitor C _o1positive pole be connected, the second equivalent load R _o2one end and the second storage capacitor C _o2negative pole be connected, the first equivalent load R _o1the other end and the second equivalent load R _o2the other end be connected, the first equivalent load R _o1with the second equivalent load R _o2connected common point and the first storage capacitor C _o1with the second storage capacitor C _o2connected common point is connected, and this common point is connected with zero reference potential GND.

Main switch circuit is by main switching device S, parasitic capacitance C _swith anti-paralleled diode composition, the drain electrode of master control device S and parasitic capacitance C _sone end be connected, be connected with the negative electrode of anti-paralleled diode simultaneously, source electrode and parasitic capacitance C _sthe other end be connected, be connected with the anode of anti-paralleled diode simultaneously, the grid of main switching device S connects the external control unit that is used for controlling its turn-on and turn-off, wherein anti-paralleled diode can be parasitic anti-paralleled diode or independent anti-paralleled diode.

Clamp switch pipe Sc in clamp circuit comprises an enhancement mode N-type MOSFET and an anti-paralleled diode, the source electrode of clamp switch pipe Sc is connected with the drain electrode of master control device S, be connected with the anode of anti-paralleled diode simultaneously, the drain electrode of clamp switch pipe Sc is connected with the negative electrode of anti-paralleled diode, be connected to zero reference potential GND through clamping capacitance Cc simultaneously, the grid of clamp switch pipe Sc connects the external control unit for controlling its turn-on and turn-off, and wherein anti-paralleled diode is parasitic anti-paralleled diode or independent anti-paralleled diode.

The utility model compared with prior art, its remarkable advantage: (1) the utility model utilizes coupling inductance times laminated structure to realize the high-gain under conventional duty ratio, reduce the voltage stress of main switching device S simultaneously, can select like this power device of low withstand voltage low on-resistance further to reduce conduction loss; (2) utilize active clamping circuir structure can effectively suppress the voltage overshoot producing when main switch turn-offs, and the recyclable energy being stored in leakage inductance; (3) utilize the leakage inductance L of coupling inductance _krealize the no-voltage conducting of main switch and clamp switch pipe, the reverse-recovery problems of diode has also obtained alleviation to a certain degree simultaneously; (4) utilize the switching tube capacitor C in times laminated structure ₁, switching tube capacitor C ₂with the first storage capacitor C in dual output circuit structure _o1with the second storage capacitor C _o2make the first output diode D _o1, the second output diode D _o2voltage stress be less than output voltage.

Brief description of the drawings

Fig. 1 is the circuit diagram of the dual output bus type high-gain converter of the utility model based on coupling inductance times laminated structure, and wherein n1 represents former limit inductance L ₁turn ratio, n2 represents secondary inductance L ₂turn ratio.

Fig. 2 is the equivalent circuit diagram of Fig. 1 circuit.

Fig. 3 is converter course of work oscillogram.

Fig. 4 a-Fig. 4 h is the circuit diagram in circuit each stage in a course of work in Fig. 2, and wherein arrow represents current direction, and dotted line represents to disconnect, and represents that no current flows through, and solid line represents to connect, and indicates that electric current flows through.

Embodiment

Below in conjunction with accompanying drawing, the utility model is described in further detail.

In order to realize the high-gain of DC converter, introduce a coupling inductance times laminated structure, by controlling high speed conducting and the shutoff of main switching device S, can be at the secondary inductance L that flows through ₂electric current in produce very high di/dt, after dual output circuit structure, producing high gain voltage output, and making output diode (D _o1and D _o2) voltage stress be less than its output voltage; The utility model, by introducing one-level active clamping circuir structure, can effectively suppress the instantaneous surge over voltage of generation in main switching device S drain electrode, utilizes leakage inductance L simultaneously _kdevice for power switching in circuit (main switching device S and clamp switch pipe S are realized _c) no-voltage conducting.

In conjunction with Fig. 1 and Fig. 2, a kind of dual output bus type high-gain converter based on coupling inductance times laminated structure, comprises a power supply V that electric energy is provided _in, coupling inductance, main switch circuit, clamp circuit, coupling inductance times laminated structure and dual output circuit structure.

Coupling inductance, can regard as under ideal transformer by magnetizing inductance L in equivalence _mwith former limit leakage inductance L _kcomposition, is mainly used in storing electric charge, realizes LC resonant circuit and to the discharging and recharging of other circuit structure, one end of coupling inductance is connected with the forward end of power supply Vin, the other end of coupling inductance and former limit leakage inductance L _kbe connected.

Main switch circuit, is mainly used in the control to contactor state, coordinates other circuit structure to realize the output of high-gain DC voltage, and wherein main switching device is enhancement mode N-type metal-oxide-semiconductor, the former limit leakage inductance L of the drain electrode of main switching device S and coupling inductance _kone end is connected, and source electrode is connected with zero reference potential GND, and grid connects external control unit.

Clamp circuit, be mainly used in the voltage overshoot producing while suppressing main switching device S shutoff, and the recyclable energy being stored in leakage inductance, comprise a clamp switch pipe Sc and a clamping capacitance Cc, wherein the source electrode of clamp switch pipe Sc is connected with the drain electrode of main switching device S, the drain electrode of clamp switch pipe Sc is connected with one end of clamping capacitance Cc, the other end of clamping capacitance Cc is connected with zero reference potential GND, and the grid of clamp switch pipe Sc connects the external control unit for controlling its turn-on and turn-off.

Coupling inductance times laminated structure, the main high-gain with realizing under conventional duty ratio, thereby reduce the voltage stress of main switching device Sc, and can select low withstand voltage and power device low on-resistance further to reduce conduction loss, comprise coupling inductance secondary side winding L ₂, the first switching tube capacitor C ₁, second switch pipe capacitor C ₂, the first sustained diode _r1with the second sustained diode _r2, wherein coupling inductance secondary side winding L ₂one end be connected with the source electrode of clamp switch pipe Sc, coupling inductance secondary side winding L ₂the other end and the first switching tube capacitor C ₁one end be connected, simultaneously and second switch pipe capacitor C ₂one end be connected, the first switching tube capacitor C ₁the other end and the first sustained diode _r1negative electrode be connected, second switch pipe capacitor C ₂the other end and the second sustained diode _r2anode be connected, the first sustained diode _r1anode second and sustained diode _r2negative electrode be connected, simultaneously the first sustained diode _r1anode and the second sustained diode _r2the connected common node of negative electrode be connected with zero reference potential GND.

Dual output circuit structure, there is mid point zero potential in sort circuit structure, provides advantage for rear one-level realizes multi-level inverse conversion, comprises the first output diode D _o1, the second output diode D _o2, the first storage capacitor C _o1, the second storage capacitor C _o2, the first equivalent load R _o1with the second equivalent load R _o2, wherein the first output diode D _o1anode and sustained diode _r1negative electrode be connected, simultaneously and the first switching tube capacitor C ₁one end be connected, the first output diode D _o1negative electrode and the first storage capacitor C _o1positive pole be connected, the second output diode D _o2negative electrode and sustained diode _r2anode be connected, simultaneously and second switch pipe capacitor C ₂one end be connected, the second output diode D _o2anode and the second storage capacitor C _o2negative pole be connected, the first storage capacitor C _o1negative pole and the second storage capacitor C _o2positive pole be connected, the first equivalent load R _o1one end and the first storage capacitor C _o1positive pole be connected, the second equivalent load R _o2one end and the second storage capacitor C _o2negative pole be connected, the first equivalent load R _o1the other end and the second equivalent load R _o2the other end be connected, the first equivalent load R _o1with the second equivalent load R _o2connected common point and the first storage capacitor C _o1with the second storage capacitor C _o2connected common point is connected, and this common point is connected with zero reference potential GND.In this example, the output voltage of circuit is ± 380V.

Main switch circuit is by main switching device S, parasitic capacitance C _swith anti-paralleled diode composition, the drain electrode of master control device S and parasitic capacitance C _sone end be connected, be connected with the negative electrode of anti-paralleled diode simultaneously, source electrode and parasitic capacitance C _sthe other end be connected, be connected with the anode of anti-paralleled diode simultaneously, the grid of main switching device S connects the external control unit that is used for controlling its turn-on and turn-off, wherein anti-paralleled diode can be parasitic anti-paralleled diode or independent anti-paralleled diode.

Clamp switch pipe Sc in clamp circuit comprises an enhancement mode N-type MOSFET and an anti-paralleled diode, the source electrode of clamp switch pipe Sc is connected with the drain electrode of master control device S, be connected with the anode of anti-paralleled diode simultaneously, the drain electrode of clamp switch pipe Sc is connected with the negative electrode of anti-paralleled diode, be connected to zero reference potential GND through clamping capacitance Cc simultaneously, the grid of clamp switch pipe Sc connects the external control unit for controlling its turn-on and turn-off, and wherein anti-paralleled diode is parasitic anti-paralleled diode or independent anti-paralleled diode.

In conjunction with Fig. 3 converter course of work oscillogram and the circuit diagram in Fig. 4 a-Fig. 4 h circuit each stage in a course of work, the course of work of the dual output bus type high-gain converter of the utility model based on coupling inductance times laminated structure in one-period:

At the t of Fig. 3 ₀-t ₁in the stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4a, at t ₁before moment, main switch device S conducting, clamp switch pipe S _cturn-off.Sustained diode _r1with the second output diode D _o2conducting, sustained diode _r2with the second output diode D _o1oppositely cut-off.Power supply V _into magnetizing inductance L _mwith leakage inductance L _kcharging, magnetizing inductance electric current and leakage inductance electric current all approximately linear rise.For just half part of output, coupling inductance secondary is to switching tube capacitor C ₁charging; To with negative half part of output, be stored in and close pipe capacitor C ₂pass to the second equivalent load R with the energy in coupling inductance secondary _o2.

At the t of Fig. 3 ₁-t ₂stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4b, main switching device S is at t ₁moment turn-offs, parasitic capacitance C _sstart and leakage inductance L _kresonance.Consider L _kcompared with large and C _sless, the drain-source voltage V of main switch device S _dsthe near linear of starting from scratch rises, and turn-off power loss is because the existence of parasitic capacitance Cs decreases.This time zone is extended to V _dsrise to clamping capacitance voltage V _cc.

At the t of Fig. 3 ₂-t ₃in the stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4c, at t ₂moment, the drain-source voltage V of main switch device S _dsreach V _cc, clamp switch pipe S _creverse parasitic diode conducting, V _dsbe clamped to V _cc.Due to clamping capacitance C _cmuch larger than parasitic capacitance C _sso nearly all electric current is all from C _cflow through.T ₂after moment, former limit leakage inductance L _kelectric discharge, to clamping capacitance C _ccharge.This stage, leakage inductance current i _lksharply decline, secondary current i _l2also approximately linear declines.

At the t of Fig. 3 ₃-t ₄stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4d, secondary current i _l2at t ₃moment linearity drops to zero, the first sustained diode _r1with the second output diode D _o2oppositely cut-off, the second sustained diode r2 and the first output diode Do1 conducting, now, magnetizing inductance L _mwith former limit leakage inductance L _kelectric discharge simultaneously, former limit leakage inductance electric current is with respect to last stage slow decreasing.For just half part of output, be stored in the first switching tube capacitor C ₁pass to the first equivalent load R with the energy in coupling inductance secondary _o1; For negative half part of output, coupling inductance secondary is to second switch pipe capacitor C ₂start charging.

At the t of Fig. 3 ₄-t ₅in the stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4e, at t ₄moment, clamp switch pipe S _copen signal and arrive, S _cnow open-minded.Due to last time zone S _cthe conducting of parasitic backward diode, S _crealize no-voltage open-minded.

At the t of Fig. 3 ₅-t ₆stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4f, clamp switch pipe is at t ₅moment turn-offs, parasitic capacitance C _sstart and former limit leakage inductance L _kresonance.Consider L _kcompared with large and C _sless, the drain-source voltage V of main switch device S _dsnear linear declines, clamp switch pipe S _cdrain-source voltage V _cdsnear linear rises.S _cturn-off power loss due to C _sexistence decrease.

At the t of Fig. 3 ₆-t ₇in the stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4g, at t ₆moment, parasitic capacitance C _sthe voltage drop to zero at two ends, the reverse parasitic diode conducting of main switch device S.Parasitic capacitance C _sstart and former limit leakage inductance L _kstop resonance.Former limit leakage inductance L flows through _kcurrent-rising-rate determined by output voltage, simultaneously at t ₆moment, the current i of the secondary winding of flowing through _l2start to decline.

At the t of Fig. 3 ₇-t ₈in the stage, the current direction of the utility model implementing circuit and annexation corresponding diagram 4h, at t ₇in the moment, main switch device S is open-minded after parasitic diode conducting, and the no-voltage that realizes main switch device S is open-minded.Secondary current i _l2at t ₈moment linearity drops to zero, the first sustained diode _r1with the second output diode D _o2conducting, the second sustained diode _r2with the first output diode D _o1oppositely cut-off.T ₈after moment, power supply Vin is to magnetizing inductance L _mwith former limit leakage inductance L _kcharging.With respect to stage 7 and stage 8, former limit leakage inductance L now flows through _kelectric current rising.Converter comes back to the stage 1, starts new switch periods.

Claims (3)

1. the dual output bus type high-gain converter based on coupling inductance times laminated structure, is characterized in that: comprising:

One provides the power supply V of electric energy _in;

Coupling inductance, can regard as under ideal transformer by magnetizing inductance L in equivalence _mwith former limit leakage inductance L _kcomposition, is mainly used in storing electric charge, realizes LC resonant circuit and to the discharging and recharging of other circuit structure, one end of coupling inductance and power supply V _inforward end be connected, the other end of coupling inductance and former limit leakage inductance L _kbe connected;

Main switch circuit, is mainly used in the control to contactor state, coordinates other circuit structure to realize the output of high-gain DC voltage, and wherein main switching device is enhancement mode N-type metal-oxide-semiconductor, the former limit leakage inductance L of the drain electrode of main switching device S and coupling inductance _kone end is connected, and source electrode is connected with zero reference potential GND, and grid connects external control unit;

Clamp circuit, be mainly used in the voltage overshoot producing while suppressing main switching device S shutoff, and the recyclable energy being stored in leakage inductance, comprise a clamp switch pipe Sc and a clamping capacitance Cc, wherein the source electrode of clamp switch pipe Sc is connected with the drain electrode of main switching device S, the drain electrode of clamp switch pipe Sc is connected with one end of clamping capacitance Cc, the other end of clamping capacitance Cc is connected with zero reference potential GND, and the grid of clamp switch pipe Sc connects the external control unit for controlling its turn-on and turn-off;

Coupling inductance times laminated structure, the main high-gain with realizing under conventional duty ratio, thereby reduce the voltage stress of main switching device Sc, and can select low withstand voltage and power device low on-resistance further to reduce conduction loss, comprise coupling inductance secondary side winding L ₂, the first switching tube capacitor C ₁, second switch pipe capacitor C ₂, the first sustained diode _r1with the second sustained diode _r2, wherein coupling inductance secondary side winding L ₂one end be connected with the source electrode of clamp switch pipe Sc, coupling inductance secondary side winding L ₂the other end and the first switching tube capacitor C ₁one end be connected, simultaneously and second switch pipe capacitor C ₂one end be connected, the first switching tube capacitor C ₁the other end and the first sustained diode _r1negative electrode be connected, second switch pipe capacitor C ₂the other end and the second sustained diode _r2anode be connected, the first sustained diode _r1anode second and sustained diode _r2negative electrode be connected, simultaneously the first sustained diode _r1anode and the second sustained diode _r2the connected common node of negative electrode be connected with zero reference potential GND;

Dual output circuit structure, there is mid point zero potential in sort circuit structure, provides advantage for rear one-level realizes multi-level inverse conversion, comprises the first output diode D _o1, the second output diode D _o2, the first storage capacitor C _o1, the second storage capacitor C _o2, the first equivalent load R _o1with the second equivalent load R _o2, wherein the first output diode D _o1anode and sustained diode _r1negative electrode be connected, simultaneously and the first switching tube capacitor C ₁one end be connected, the first output diode D _o1negative electrode and the first storage capacitor C _o1positive pole be connected, the second output diode D _o2negative electrode and sustained diode _r2anode be connected, simultaneously and second switch pipe capacitor C ₂one end be connected, the second output diode D _o2anode and the second storage capacitor C _o2negative pole be connected, the first storage capacitor C _o1negative pole and the second storage capacitor C _o2positive pole be connected, the first equivalent load R _o1one end and the first storage capacitor C _o1positive pole be connected, the second equivalent load R _o2one end and the second storage capacitor C _o2negative pole be connected, the first equivalent load R _o1the other end and the second equivalent load R _o2the other end be connected, the first equivalent load R _o1with the second equivalent load R _o2connected common point and the first storage capacitor C _o1with the second storage capacitor C _o2connected common point is connected, and this common point is connected with zero reference potential GND.

2. the dual output bus type high-gain converter based on coupling inductance times laminated structure according to claim 1, is characterized in that: main switch circuit is by main switching device S, parasitic capacitance C _swith anti-paralleled diode composition, the drain electrode of master control device S and parasitic capacitance C _sone end be connected, be connected with the negative electrode of anti-paralleled diode simultaneously, source electrode and parasitic capacitance C _sthe other end be connected, be connected with the anode of anti-paralleled diode simultaneously, the grid of main switching device S connects the external control unit that is used for controlling its turn-on and turn-off, wherein anti-paralleled diode can be parasitic anti-paralleled diode or independent anti-paralleled diode.

3. the dual output bus type high-gain converter based on coupling inductance times laminated structure according to claim 1, it is characterized in that: the clamp switch pipe Sc in clamp circuit comprises an enhancement mode N-type MOSFET and an anti-paralleled diode, the source electrode of clamp switch pipe Sc is connected with the drain electrode of master control device S, be connected with the anode of anti-paralleled diode simultaneously, the drain electrode of clamp switch pipe Sc is connected with the negative electrode of anti-paralleled diode, be connected to zero reference potential GND through clamping capacitance Cc simultaneously, the grid of clamp switch pipe Sc connects the external control unit for controlling its turn-on and turn-off, wherein anti-paralleled diode is parasitic anti-paralleled diode or independent anti-paralleled diode.

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