CN101951154B - Isolation type active clamping interleaving paralleled bidirectional DC-DC converter - Google Patents

Abstract

The invention discloses an isolation type active clamping interleaving paralleled bidirectional DC-DC converter which comprises four power switch tubes with anti-parallel diodes and parallel capacitors, two auxiliary switch tubes with anti-parallel diodes, two clamping capacitors, two high voltage side capacitors and two winding coupled inductors. The invention utilizes a low voltage side parallel structure to reduce ripples of a low voltage side current, utilizes the parallel capacitors of the power switch tubes to realize zero voltage turn-off of the power switch tubes, utilizes the leakage inductance of the coupled inductors to realize zero voltage switching of the power switch tubes, utilizes the auxiliary switch tubes and an active clamping circuit consisting of the anti-parallel diodes and the clamping capacitors of the auxiliary switch tubes to realize lossless transfer of the leakage inductance energy and utilizes serial structures of high voltage side windings of the two coupled inductors to realize high voltage rising/reduction of the converter. In the invention, a circuit structure is simple, all power switches work in a soft switching state, and an energy loss element does not exist in the circuit, therefore the converter efficiency is enhanced, and voltage overshoot does not occur on a switch device in a current commutating process.

Description

The isolation type active clamping alternation parallel two-way DC-DC converter

Technical field

The present invention relates to a kind of two-way DC-DC converter, especially the isolation type active clamping alternation parallel two-way DC-DC converter.

Background technology

In recent years, along with a large amount of consumption of traditional energies such as oil, coal, the pollution of shortage of energy sources and environment has become the focus in the world, and the development of regenerative resource and application receive the extensive concern of countries in the world.In renewable energy system, there is the fluctuation problem in the short time like electric energy that regenerative resource produced such as wind energy, solar energy, need to use energy storage system that the electricity generation system energy is steadily exported.Wherein, the core of energy storage system is exactly two-way DC-DC converter, can when electricity generation system is exported excessive power, store excess energy in energy storage devices such as storage batterys, and when electricity generation system output energy shortage power output, satisfy the demand of load.Meanwhile, from the personal safety aspect being considered all there is the requirement of electrical isolation many application scenarios,, need to reduce A-battery side ripple for prolonging energy storage device such as storage battery useful life.So low input ripple, high step-up/down, high efficiency isolation type bidirectional transducer have important effect in the renewable energy power generation field.

Conventional Buck-Boost type two-way DC-DC converter is simple in structure, be widely used, but the power switch of this converter works in the hard switching state, and switching loss is bigger, and the voltage stress of power switch pipe is bigger, and the low-pressure side current ripples is big.Conventional Buck-Boost type crisscross parallel DC-to-dc reversible transducer has only reduced the ripple of low-pressure side electric current to a certain extent, but other problem still exists.Occurred some high step-up/down isolated DC-direct current reversible transducers in recent years in succession, had on the basis that builds on the full-bridge topology, and increased the soft switch that active clamping circuir is realized power switch pipe, used switching tube quantity is more, and complex structure; Have in addition to have proposed a kind of reversible transducer, solve the voltage imbalance question between electric capacity but need to increase additional control circuit based on half-bridge structure.

A kind of positive and negative sharp bidirectional DC-DC converter that relates to is disclosed among the Chinese patent CN1545195, by transformer, elementary winding N _S1With N _P1Intercouple and constitute normal shock transformer T ₁By another transformer, elementary winding N _S2With N _P2Intercouple and constitute anti-violent change depressor T ₂, two secondary winding N _S1With N _S2Tandem tap pipe S separately ₁With S ₂After be parallel to input DC power simultaneously.Two elementary winding N _P1With N _P2The series connection back is through rectification/inverter circuit and DC power supply V ₂Parallel connection.Utilize technology such as active-clamp, RCD clamp, LCD clamp, ZVT reset to form gang's reversible transducer topology.

But this technology still has following deficiency:

1, two power grade differences that transformer is handled cause the loss of transformer to distribute inequality, and the voltage and current stress of power switch pipe is asymmetric, has increased the difficulty of heat management, has influenced the life-span of converter;

2, in this scheme, the normal shock transformer does not need air gap, and anti-violent change depressor need increase than air gaps, has increased the Design for Magnetic Elements complexity, is unfavorable for large-scale industrialization production;

3, in this scheme; The normal shock transformer only transmits energy to the high-pressure side when its corresponding switching tube conducting, and anti-violent change depressor only transmits energy to the high-pressure side when its corresponding switching tube turn-offs, cause the utilance of transformer not high; Increase the volume of transformer, reduced system power density;

4, because the asymmetry of normal shock transformer and anti-violent change depressor is difficult to realize the crisscross parallel work of circuit, influenced the raising of system power grade.

Summary of the invention

The purpose of this invention is to provide a kind of simple in structure, isolation type active clamping alternation parallel two-way DC-DC converter that the low-pressure side current ripples is little.

For realizing above-mentioned purpose, the present invention has following two kinds of technical solutions:

Scheme 1

Isolation type active clamping alternation parallel two-way DC-DC converter of the present invention comprises lower-voltage circuit and high-pressure side circuit;

Described lower-voltage circuit comprises: two active clamping circuirs and two branch roads parallelly connected with the low-pressure side power supply; Article one, parallel branch first power switch pipe anti-with band by the first low-pressure side winding and diode is connected and is constituted; Parallel connection first shunt capacitance at the first power switch pipe two ends; Second parallel branch second power switch pipe anti-with band by the second low-pressure side winding and diode is connected and is constituted, parallel connection second shunt capacitance at the second power switch pipe two ends; First active clamping circuir is connected in parallel on the first low-pressure side winding two ends or is connected in parallel on the source electrode and drain electrode of first power switch pipe, and it is connected by first auxiliary switch of being with anti-and diode and first clamping capacitance and constitutes; Second active clamping circuir is connected in parallel on the second low-pressure side winding two ends or is connected in parallel on the source electrode and drain electrode of second power switch pipe, and it is connected by second auxiliary switch of being with anti-and diode and second clamping capacitance and constitutes;

Described high-pressure side circuit comprises: the first high-pressure side winding, the second high-pressure side winding, the 3rd power switch pipe of being with anti-and diode, band anti-also the 4th power switch pipe, the first high-pressure side electric capacity and the second high-pressure side electric capacity of diode.Wherein the first high-pressure side winding and the first low-pressure side winding are all two windings in the coupling inductance; The second high-pressure side winding and the second low-pressure side winding are all two windings in another coupling inductance; Serving as with reference to end all in the first low-pressure side winding and the second low-pressure side winding with same that end that extremely links to each other of low-pressure side power supply; The end of the same name that the first high-pressure side winding is corresponding with the first low-pressure side winding links to each other with the corresponding end of the same name of the second low-pressure side winding with the second high-pressure side winding; The other end of the first high-pressure side winding links to each other with the source electrode of the 4th power switch pipe and the drain electrode of the 3rd power switch pipe; The other end of the second high-pressure side winding links to each other with the end of the first high-pressure side electric capacity with the second high-pressure side electric capacity; The other end of the first high-pressure side electric capacity links to each other with the source electrode of the 3rd power switch pipe and an end of high-pressure side power supply, and the other end of the second high-pressure side electric capacity links to each other with the drain electrode of the 4th power switch pipe and the other end of high-pressure side power supply.Parallel connection the 3rd shunt capacitance at the 3rd power switch pipe two ends, parallel connection the 4th shunt capacitance at the 4th power switch pipe two ends.

Scheme 2

Isolation type active clamping alternation parallel two-way DC-DC converter of the present invention comprises lower-voltage circuit and high-pressure side circuit;

Described lower-voltage circuit comprises: active clamping circuir and two branch roads parallelly connected with the low-pressure side power supply; Article one, parallel branch first power switch pipe anti-with band by the first low-pressure side winding and diode is connected and is constituted; Parallel connection first shunt capacitance at the first power switch pipe two ends; Second parallel branch second power switch pipe anti-with band by the second low-pressure side winding and diode is connected and is constituted, parallel connection second shunt capacitance at the second power switch pipe two ends; Active clamping circuir first auxiliary switch, band anti-by band and diode second auxiliary switch and clamping capacitance anti-and diode constitute; Wherein the source electrode of first auxiliary switch links to each other with the drain electrode of first power switch pipe; The source electrode of second auxiliary switch links to each other with the drain electrode of second power switch pipe; The drain electrode of the drain electrode of first auxiliary switch and second auxiliary switch links to each other with an end of clamping capacitance, and the other end of clamping capacitance links to each other with the source electrode of second power switch pipe or links to each other with that end that the low-pressure side power supply links to each other with the first low-pressure side winding.

Described high-pressure side circuit comprises: the first high-pressure side winding, the second high-pressure side winding, the 3rd power switch pipe of being with anti-and diode, band anti-also the 4th power switch pipe, the first high-pressure side electric capacity and the second high-pressure side electric capacity of diode.Wherein the first high-pressure side winding and the first low-pressure side winding are all two windings in the coupling inductance; The second high-pressure side winding and the second low-pressure side winding are all two windings in another coupling inductance; Serving as with reference to end all in the first low-pressure side winding and the second low-pressure side winding with same that end that extremely links to each other of low-pressure side power supply; The end of the same name that the first high-pressure side winding is corresponding with the first low-pressure side winding links to each other with the corresponding end of the same name of the second low-pressure side winding with the second high-pressure side winding; The other end of the first high-pressure side winding links to each other with the source electrode of the 4th power switch pipe and the drain electrode of the 3rd power switch pipe; The other end of the second high-pressure side winding links to each other with the end of the first high-pressure side electric capacity with the second high-pressure side electric capacity; The other end of the first high-pressure side electric capacity links to each other with the source electrode of the 3rd power switch pipe and an end of high-pressure side power supply, and the other end of the second high-pressure side electric capacity links to each other with the drain electrode of the 4th power switch pipe and the other end of high-pressure side power supply.Parallel connection the 3rd shunt capacitance at the 3rd power switch pipe two ends, parallel connection the 4th shunt capacitance at the 4th power switch pipe two ends.

Isolation type active clamping alternation of the present invention and two-way DC-DC converter; Utilize the low-pressure side parallel-connection structure to reduce the ripple of low-pressure side electric current, utilize the no-voltage of the shunt capacitance realization power switch pipe on the power switch pipe to turn-off, utilize the leakage inductance of coupling inductance to realize that the no-voltage of power switch pipe is open-minded; Utilize auxiliary switch and active clamping circuir anti-and diode and clamping capacitance composition thereof to realize the harmless transfer of leakage inductance energy; Utilize the cascaded structure of the high-pressure side winding of two coupling inductances to realize the high step-up/down of converter, circuit structure is simple, and all power switchs work in soft on off state; Noenergy losser in the circuit; Improved the efficient of converter, in the commutation course, the overshoot of switching device no-voltage.The present invention is wound on two coupling inductances on the magnetic cell through the mode of shared magnetic circuit, has reduced volume.

Description of drawings

Fig. 1 is the circuit diagram of scheme 1 isolation type active clamping alternation parallel two-way DC-DC converter;

Fig. 2 is the another kind of execution mode circuit diagram of scheme 1 lower-voltage circuit;

Fig. 3 is the circuit diagram of scheme 2 isolation type active clamping alternation parallel two-way DC-DC converters;

Fig. 4 is the another kind of execution mode circuit diagram of scheme 2 lower-voltage circuits;

Fig. 5 is the two-way DC-DC converter of the present invention course of work oscillogram under the operation mode of boosting;

Fig. 6 is a course of work oscillogram under the two-way DC-DC converter step-down operation mode of the present invention.

Embodiment

Referring to Fig. 1, isolation type active clamping alternation parallel two-way DC-DC converter of the present invention comprises lower-voltage circuit and high-pressure side circuit;

Described lower-voltage circuit comprises: two active clamping circuirs and two and low-pressure side power supply V _LThe branch road of parallel connection, article one parallel branch is by the first low-pressure side winding L _1aAnti-and the diode D with band ₁First power switch tube S ₁Series connection constitutes, in first power switch tube S ₁The two ends parallel connection first shunt capacitance C _S1, the second parallel branch is by the second low-pressure side winding L _2aAnti-and the diode D with band ₂Second power switch tube S ₂Series connection constitutes, in second power switch tube S ₂The two ends parallel connection second shunt capacitance C _S2In the instance shown in Figure 1, the first active clamping circuir parallel connection is connected in parallel on first power switch tube S ₁Source electrode with the drain electrode on, perhaps also can be as shown in Figure 2, be connected in parallel on the first low-pressure side winding L _1aTwo ends.It is anti-and diode D by band _C1The first auxiliary switch S _C1With the first clamping capacitance C _C1Series connection constitutes; In the instance shown in Figure 1, second active clamping circuir is connected in parallel on second power switch tube S ₂Source electrode with the drain electrode on, perhaps also can be as shown in Figure 2, be connected in parallel on the second low-pressure side winding L _2aTwo ends.It is anti-and diode D by band _C2The second auxiliary switch S _C2With the second clamping capacitance C _C2Series connection constitutes;

Described high-pressure side circuit comprises: the first high-pressure side winding L _1b, the second high-pressure side winding L _2b, the anti-and diode D of band ₃The 3rd power switch tube S ₃, the anti-and diode D of band ₄The 4th power switch tube S ₄, the first high-pressure side capacitor C _O1With the second high-pressure side capacitor C _O2The first high-pressure side winding L wherein _1bWith the first low-pressure side winding L _1aBe all two windings in the coupling inductance, the second high-pressure side winding L _2bWith the second low-pressure side winding L _2aBe all two windings in another coupling inductance, with the first low-pressure side winding L _1aWith the second low-pressure side winding L _2aIn all with low-pressure side power supply V _LSame that end that extremely links to each other is with reference to end, the first high-pressure side winding L _1bWith the first low-pressure side winding L _1aThe corresponding end of the same name and the second high-pressure side winding L _2bWith the second low-pressure side winding L _2aCorresponding end of the same name links to each other, the first high-pressure side winding L _1bThe other end and the 4th power switch tube S ₄Source electrode and the 3rd power switch tube S ₃Drain electrode link to each other the second high-pressure side winding L _2bThe other end and the first high-pressure side capacitor C _O1With the second high-pressure side capacitor C _O2An end link to each other the first high-pressure side capacitor C _O1The other end and the 3rd power switch tube S ₃Source electrode and high-pressure side power supply V _HAn end link to each other the second high-pressure side capacitor C _O2The other end and the 4th power switch tube S ₄Drain electrode and high-pressure side power supply V _HThe other end link to each other.In the 3rd power switch tube S ₃Two ends parallel connection the 3rd shunt capacitance C _S3, in the 4th power switch tube S ₄Two ends parallel connection the 4th shunt capacitance C _S4

Referring to Fig. 3, isolation type active clamping alternation parallel two-way DC-DC converter of the present invention comprises lower-voltage circuit and high-pressure side circuit;

Described lower-voltage circuit comprises: active clamping circuir and two and low-pressure side power supply V _LThe branch road of parallel connection, article one parallel branch is by the first low-pressure side winding L _1aAnti-and the diode D with band ₁First power switch tube S ₁Series connection constitutes, in first power switch tube S ₁The two ends parallel connection first shunt capacitance C _S1, the second parallel branch is by the second low-pressure side winding L _2aAnti-and the diode D with band ₂Second power switch tube S ₂Series connection constitutes, in second power switch tube S ₂The two ends parallel connection second shunt capacitance C _S2Active clamping circuir is anti-and diode D by band _C1The first auxiliary switch S _C1, the anti-and diode D of band _C2The second auxiliary switch S _C2With clamping capacitance C _cConstitute, wherein the first auxiliary switch S _C1The source electrode and first power switch tube S ₁Drain electrode link to each other the second auxiliary switch S _C2The source electrode and second power switch tube S ₂Drain electrode link to each other the first auxiliary switch S _C1The drain electrode and the second auxiliary switch S _C2Drain electrode and clamping capacitance C _cAn end link to each other, in the instance shown in Figure 3, clamping capacitance C _cThe other end and second power switch tube S ₂Source electrode link to each other, perhaps also can be as shown in Figure 4, clamping capacitance C _cThe other end and the first low-pressure side winding L _1aWith low-pressure side power supply V _LThat end that links to each other links to each other.

Described high-pressure side circuit comprises: the first high-pressure side winding L _1b, the second high-pressure side winding L _2b, the anti-and diode D of band ₃The 3rd power switch tube S ₃, the anti-and diode D of band ₄The 4th power switch tube S ₄, the first high-pressure side capacitor C _O1With the second high-pressure side capacitor C _O2The first high-pressure side winding L wherein _1bWith the first low-pressure side winding L _1aBe all two windings in the coupling inductance, the second high-pressure side winding L _2bWith the second low-pressure side winding L _2aBe all two windings in another coupling inductance, with the first low-pressure side winding L _1aWith the second low-pressure side winding L _2aIn all with low-pressure side power supply V _LSame that end that extremely links to each other is with reference to end, the first high-pressure side winding L _1bWith the first low-pressure side winding L _1aThe corresponding end of the same name and the second high-pressure side winding L _2bWith the second low-pressure side winding L _2aCorresponding end of the same name links to each other, the first high-pressure side winding L _1bThe other end and the 4th power switch tube S ₄Source electrode and the 3rd power switch tube S ₃Drain electrode link to each other the second high-pressure side winding L _2bThe other end and the first high-pressure side capacitor C _O1With the second high-pressure side capacitor C _O2An end link to each other the first high-pressure side capacitor C _O1The other end and the 3rd power switch tube S ₃Source electrode and high-pressure side power supply V _HAn end link to each other the second high-pressure side capacitor C _O2The other end and the 4th power switch tube S ₄Drain electrode and high-pressure side power supply V _HThe other end link to each other.In the 3rd power switch tube S ₃Two ends parallel connection the 3rd shunt capacitance C _S3, in the 4th power switch tube S ₄Two ends parallel connection the 4th shunt capacitance C _S4

When two-way DC-DC converter of the present invention is worked; Initial high-low pressure DC power supply is inserted converter; Signals such as low-pressure side electric current, low-pressure side supply voltage, low-pressure side clamping capacitance voltage and high-pressure side supply voltage according to the sampling gained; Use phase shift to add the control method of PWM, leading or lag behind the control signal of the 4th power switch pipe through the control signal that draws second power switch pipe after the DSP routine processes, thus realize the control of through-put power size and Orientation.According to the high-low voltage power source voltage magnitude, calculate the duty ratio of first power switch pipe, second power switch pipe, first auxiliary switch and second auxiliary switch, make the voltage matches on high-pressure side equivalence leakage inductance both sides.According to each switching tube duty ratio size and phase relation of calculating, control turning on and off of first power switch pipe, second power switch pipe, first auxiliary switch, second auxiliary switch, the 3rd power switch pipe and the 4th power switch pipe.

Wherein, The ON time of first power switch pipe and second power switch pipe equates; Phase phasic difference 180 degree, the control signal of first auxiliary switch and first power switch pipe is complementary, and a bit of time that common shutoff arranged is as Dead Time; The control signal of second auxiliary switch and second power switch pipe is complementary, and a bit of time that common shutoff arranged is as Dead Time.The control signal of the 3rd power switch pipe and the 4th power switch pipe is complementary, respectively is 0.5 fixed duty cycle, and the Dead Time of common shutoff is arranged.The control signal of second power switch pipe is leading or lag behind the control signal with the 4th power switch pipe, and the control signal of first power switch pipe is leading or lag behind the control signal of the 3rd power switch pipe.

Isolation type bidirectional DC-DC converter existence of the present invention is boosted, two kinds of operation modes of step-down.Every kind of operation mode can be divided into six kinds of courses of work, and its course of work is under boost mode: the second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening; First power switch tube S ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening; The 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening; The first auxiliary switch S _C1Turn-off and first power switch tube S ₁Commutation course between opening; Second power switch tube S ₂Turn-off and the second auxiliary switch S _C2Commutation course between opening; The 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening.The course of work of Fig. 1～converter shown in Figure 4 is basic identical, is the course of work that example is explained converter with Fig. 1:

The second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening:

Before the change of current, circuit is in the second auxiliary switch S _C2Conducting, the anti-and diode D of second auxiliary switch _C2Turn-off first power switch tube S ₁Conducting, the anti-and diode D of first power switch pipe ₁Turn-off the 3rd power switch tube S ₃Conducting, the anti-and diode D of the 3rd power switch pipe ₃Turn-off the first auxiliary switch S _C1And anti-and diode D _C1Turn-off second power switch tube S ₂Its anti-and diode D ₂Turn-off the 4th power switch tube S ₄Its anti-and diode D ₄Turn-off.As the second auxiliary switch S _C2During shutoff, in the low-pressure side of converter, the shunt capacitance C of the leakage inductance of coupling inductance and switching tube _S2Beginning resonance is along with shunt capacitance C _S2The decline of voltage, the second auxiliary switch S _C2Voltage start from scratch rising, the i.e. second auxiliary switch S _C2Realized the no-voltage shutoff, as shunt capacitance C _S2On voltage linear when dropping to zero, second power switch tube S ₂Anti-and diode D ₂Conducting provides second power switch tube S this moment ₂Open signal, just realized second power switch tube S ₂No-voltage is open-minded.In this process, in the high-pressure side of converter, the 3rd power switch tube S ₃Be in conducting state, energy is transferred to the first high-pressure side capacitor C from first, second coupling inductance _O1In.

First power switch tube S ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening:

Before the change of current, circuit is in first power switch tube S ₁Conducting, the anti-and diode D of first power switch pipe ₁Turn-off second power switch tube S ₂Conducting, the anti-and diode D of second power switch pipe ₂Turn-off the first auxiliary switch S _C1And anti-and diode D _C1Turn-off the second auxiliary switch S _C2And anti-and diode D _C2Turn-off the 3rd power switch tube S ₃Conducting, the anti-and diode D of the 3rd power switch pipe ₃Turn-off the 4th power switch tube S ₄Its anti-and diode D ₄Turn-off.When first power switch tube S ₁During shutoff, in the low-pressure side of converter, because switching tube shunt capacitance C _S1Effect, first power switch tube S ₁Voltage start from scratch and rise, therefore first power switch tube S so that certain slope is linear ₁Realized the no-voltage shutoff.When first power switch tube S ₁Voltage surpass the first clamping capacitance C _C1Voltage the time, the anti-and diode D of first auxiliary switch _C1The first clamping capacitance C is transferred in conducting, the energy in the leakage inductance of first coupling inductance _C1In, at the anti-and diode D of first auxiliary switch _C1Provide the first auxiliary switch S after the conducting _C1Open signal, and realized the first auxiliary switch S _C1No-voltage open-minded, the anti-and diode D of first auxiliary switch _C1Deactivate.In this process, in the high-pressure side of converter, the 3rd power switch tube S ₃Be in and still be in conducting state, energy continues to transfer to the first high-pressure side capacitor C from first, second coupling inductance _O1In.

The 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening:

Before the change of current, circuit is in second power switch tube S ₂Conducting, the anti-and diode D of second power switch pipe ₂Turn-off the 3rd power switch tube S ₃Conducting, the anti-and diode D of the 3rd power switch pipe ₃Turn-off the first auxiliary switch S _C1Conducting, its anti-and diode D _C1Turn-off the second auxiliary switch S _C2And anti-and diode D _C2Turn-off first power switch tube S ₁Its anti-and diode D ₁Turn-off the 4th power switch tube S ₄Its anti-and diode D ₄Turn-off.The 3rd power switch tube S ₃During shutoff, in the high-pressure side of converter, because switching tube shunt capacitance C _S3Effect, the 3rd power switch tube S ₃Voltage start from scratch and rise, therefore the 3rd power switch tube S so that certain slope is linear ₃Realized the no-voltage shutoff.When the 3rd power switch tube S ₃Voltage surpass the high-pressure side capacitor C _oVoltage the time, the 4th power switch tube S ₄Anti-and diode D ₄Conducting, the energy of first and second coupling inductance is transferred to the high-pressure side capacitor C _O2In, in the 4th power switch tube S ₄Anti-and diode D ₄After the conducting, provide the 4th power switch tube S ₄Open signal, thereby realized the 4th power switch tube S ₄No-voltage open-minded, the 4th power switch tube S ₄Anti-and diode D ₄Deactivate.

The first auxiliary switch S _C1Turn-off and first power switch tube S ₁Commutation course between opening:

Since the symmetry of circuit, the commutation course of converter low-pressure side and the second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening is similar.

Second power switch tube S ₂Turn-off and the second auxiliary switch S _C2Commutation course between opening:

Because symmetry, the commutation course of converter low-pressure side and first power switch tube S of circuit ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening is similar.

The 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening:

Since the symmetry of circuit, on high-tension side commutation course of converter and the 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening is similar.

Fig. 5 is the two-way DC-DC converter course of work oscillogram under the operation mode of boosting, and Φ representes phase shifting angle among Fig. 5, and D representes duty ratio, and the drive waveforms duty that the top of figure is divided into each switching tube is the phase relation sketch map when, the i among the figure _LbBe the current waveform of high-pressure side coupling inductance, the θ among the figure ₀To θ ₁₁Represent the time point in the switch periods, θ ₀～θ ₁In time the second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening, θ ₁～θ ₃It in time first power switch tube S ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening, θ ₃～θ ₅It in time the 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening, θ ₅～θ ₇In time the first auxiliary switch S _C1Turn-off and first power switch tube S ₁Commutation course between opening, θ ₇～θ ₉Second power switch tube S in time ₂Turn-off and the second auxiliary switch S _C2Commutation course between opening, θ ₉～θ ₁₁It in time the 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening.

Fig. 6 is a course of work oscillogram under the two-way DC-DC converter step-down operation mode.Its course of work is following six processes under decompression mode: the second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening; First power switch tube S ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening; The 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening; The first auxiliary switch S _C1Turn-off and first power switch tube S ₁Commutation course between opening; Second power switch tube S ₂Turn-off and the second auxiliary switch S _C2Commutation course between opening; The 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening.

The second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening:

Before the change of current, circuit is in the second auxiliary switch S _C2Conducting, the anti-and diode D of second auxiliary switch _C2Turn-off first power switch tube S ₁Conducting, the anti-and diode D of first power switch pipe ₁Turn-off the 4th power switch tube S ₄Conducting, the anti-and diode D of the 4th power switch pipe ₄Turn-off the first auxiliary switch S _C1And anti-and diode D _C1Turn-off second power switch tube S ₂Its anti-and diode D ₂Turn-off the 3rd power switch tube S ₃Its anti-and diode D ₃Turn-off.As the second auxiliary switch S _C2During shutoff, in the low-pressure side of converter, the shunt capacitance C of the leakage inductance of coupling inductance and switching tube _S2Beginning resonance is along with shunt capacitance C _S2The decline of voltage, the second auxiliary switch S _C2Voltage start from scratch rising, the i.e. second auxiliary switch S _C2Realized the no-voltage shutoff, as shunt capacitance C _S2On voltage linear when dropping to zero, second power switch tube S ₂Anti-and diode D ₂Conducting provides second power switch tube S this moment ₂Open signal, just realized second power switch tube S ₂No-voltage is open-minded.In this process, in the high-pressure side of converter, the 4th power switch tube S ₄Be in conducting state, energy is capacitor C from the high-pressure side _O2Transfer to low-pressure side through first, second coupling inductance.

First power switch tube S ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening:

Before the change of current, circuit is in first power switch tube S ₁Conducting, the anti-and diode D of first power switch pipe ₁Turn-off second power switch tube S ₂Conducting, the anti-and diode D of second power switch pipe ₂Turn-off the first auxiliary switch S _C1And anti-and diode D _C1Turn-off the second auxiliary switch S _C2And anti-and diode D _C2Turn-off the 4th power switch tube S ₄Conducting, the anti-and diode D of the 4th power switch pipe ₄Turn-off the 3rd power switch tube S ₃Its anti-and diode D ₃Turn-off.When first power switch tube S ₁During shutoff, in the low-pressure side of converter, because switching tube shunt capacitance C _S1Effect, first power switch tube S ₁Voltage start from scratch and rise, therefore first power switch tube S so that certain slope is linear ₁Realized the no-voltage shutoff.When first power switch tube S ₁Voltage surpass the first clamping capacitance C _C1Voltage the time, the anti-and diode D of first auxiliary switch _C1The first clamping capacitance C is transferred in conducting, the energy in the leakage inductance of first coupling inductance _C1In, at the anti-and diode D of first auxiliary switch _C1Provide the first auxiliary switch S after the conducting _C1Open signal, and realized the first auxiliary switch S _C1No-voltage open-minded, the anti-and diode D of first auxiliary switch _C1Deactivate.In this process, in the high-pressure side of converter, the 4th power switch tube S ₄Be in and still be in conducting state, energy continues from the high-pressure side capacitor C _O2Transfer to low-pressure side through first, second coupling inductance.

The 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening:

Before the change of current, circuit is in second power switch tube S ₂Conducting, the anti-and diode D of second power switch pipe ₂Turn-off the 4th power switch tube S ₄Conducting, the anti-and diode D of the 4th power switch pipe ₄Turn-off the first auxiliary switch S _C1Conducting, its anti-and diode D _C1Turn-off the second auxiliary switch S _C2And anti-and diode D _C2Turn-off first power switch tube S ₁Its anti-and diode D ₁Turn-off the 3rd power switch tube S ₃Its anti-and diode D ₃Turn-off.The 4th power switch tube S ₄During shutoff, in the high-pressure side of converter, because switching tube shunt capacitance C _S4Effect, the 4th power switch tube S ₄Voltage start from scratch and rise, therefore the 4th power switch tube S so that certain slope is linear ₄Realized the no-voltage shutoff.When the 3rd power switch tube S ₃Voltage linear when dropping to zero, the 3rd power switch tube S ₃Anti-and diode D ₃Conducting provides the 3rd power switch tube S this moment ₃Open signal, thereby realized the 3rd power switch tube S ₃No-voltage open-minded, the 3rd power switch tube S ₃Anti-and diode D ₃Deactivate the first high-pressure side capacitor C _O1Energy begin to shift in first and second coupling inductance.

The first auxiliary switch S _C1Turn-off and first power switch tube S ₁Commutation course between opening:

Since the symmetry of circuit, the commutation course of converter low-pressure side and the second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening is similar.

Second power switch tube S ₂Turn-off and the second auxiliary switch S _C2Commutation course between opening:

Because symmetry, the commutation course of converter low-pressure side and first power switch tube S of circuit ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening is similar.

The 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening:

Since the symmetry of circuit, on high-tension side commutation course of converter and the 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening is similar.

The drive waveforms duty that the top of Fig. 6 is divided into each switching tube is the phase relation sketch map when, and Φ representes phase shifting angle, and D representes duty ratio, the i among the figure _LbBe the current waveform of high-pressure side coupling inductance, the θ among the figure ₀To θ ₁₁Represent the time point in the switch periods, θ ₀～θ ₁In time the second auxiliary switch S _C2Turn-off and second power switch tube S ₂Commutation course between opening, θ ₁～θ ₃It in time first power switch tube S ₁Turn-off and the first auxiliary switch S _C1Commutation course between opening, θ ₃～θ ₅It in time the 4th power switch tube S ₄Turn-off and the 3rd power switch tube S ₃Commutation course between opening, θ ₅～θ ₇In time the first auxiliary switch S _C1Turn-off and first power switch tube S ₁Commutation course between opening, θ ₇～θ ₉Second power switch tube S in time ₂Turn-off and the second auxiliary switch S _C2Commutation course between opening, θ ₉～θ ₁₁It in time the 3rd power switch tube S ₃Turn-off and the 4th power switch tube S ₄Commutation course between opening.

Claims (2)

1. isolation type active clamping alternation parallel bidirectional, dc-DC converter is characterized in that, comprises lower-voltage circuit and high-pressure side circuit;

Described lower-voltage circuit comprises: two active clamping circuirs and two and low-pressure side power supply (V _L) parallelly connected branch road, article one parallel branch is by the first low-pressure side winding (L _1a) the anti-and diode (D with band ₁) the first power switch pipe (S ₁) the series connection formation, at the first power switch pipe (S ₁) the two ends parallel connection first shunt capacitance (C _S1), the second parallel branch is by the second low-pressure side winding (L _2a) the anti-and diode (D with band ₂) the second power switch pipe (S ₂) the series connection formation, at the second power switch pipe (S ₂) the two ends parallel connection second shunt capacitance (C _S2); First active clamping circuir is connected in parallel on the first low-pressure side winding (L _1a) two ends or be connected in parallel on the first power switch pipe (S ₁) source electrode and drain electrode on, it is anti-and diode (D by band _C1) the first auxiliary switch (S _C1) and the first clamping capacitance (C _C1) the series connection formation; Second active clamping circuir is connected in parallel on the second low-pressure side winding (L _2a) two ends or be connected in parallel on the second power switch pipe (S ₂) source electrode and drain electrode on, it is anti-and diode (D by band _C2) the second auxiliary switch (S _C2) and the second clamping capacitance (C _C2) the series connection formation;

Described high-pressure side circuit comprises: the first high-pressure side winding (L _1b), the second high-pressure side winding (L _2b), the anti-and diode (D of band ₃) the 3rd power switch pipe (S ₃), the anti-and diode (D of band ₄) the 4th power switch pipe (S ₄), the first high-pressure side electric capacity (C _O1) and the second high-pressure side electric capacity (C _O2), the first high-pressure side winding (L wherein _1b) and the first low-pressure side winding (L _1a) be all two windings in the coupling inductance, the second high-pressure side winding (L _2b) and the second low-pressure side winding (L _2a) be all two windings in another coupling inductance, with the first low-pressure side winding (L _1a) and the second low-pressure side winding (L _2a) in all with low-pressure side power supply (V _L) same that end that extremely links to each other be with reference to holding the first high-pressure side winding (L _1b) and the first low-pressure side winding (L _1a) the corresponding end of the same name and the second high-pressure side winding (L _2b) and the second low-pressure side winding (L _2a) corresponding end of the same name links to each other the first high-pressure side winding (L _1b) the other end and the 4th power switch pipe (S ₄) source electrode and the 3rd power switch pipe (S ₃) drain electrode link to each other the second high-pressure side winding (L _2b) the other end and the first high-pressure side electric capacity (C _O1) and the second high-pressure side electric capacity (C _O2) an end link to each other the first high-pressure side electric capacity (C _O1) the other end and the 3rd power switch pipe (S ₃) source electrode and high-pressure side power supply (V _H) an end link to each other the second high-pressure side electric capacity (C _O2) the other end and the 4th power switch pipe (S ₄) drain electrode and high-pressure side power supply (V _H) the other end link to each other, at the 3rd power switch pipe (S ₃) two ends parallel connection the 3rd shunt capacitance (C _S3), at the 4th power switch pipe (S ₄) two ends parallel connection the 4th shunt capacitance (C _S4).

2. isolation type active clamping alternation parallel bidirectional, dc-DC converter is characterized in that, comprises lower-voltage circuit and high-pressure side circuit;

Described lower-voltage circuit comprises: active clamping circuir and two and low-pressure side power supply (V _L) parallelly connected branch road, article one parallel branch is by the first low-pressure side winding (L _1a) the anti-and diode (D with band ₁) the first power switch pipe (S ₁) the series connection formation, at the first power switch pipe (S ₁) the two ends parallel connection first shunt capacitance (C _S1), the second parallel branch is by the second low-pressure side winding (L _2a) the anti-and diode (D with band ₂) the second power switch pipe (S ₂) the series connection formation, at the second power switch pipe (S ₂) the two ends parallel connection second shunt capacitance (C _S2); Active clamping circuir is anti-and diode (D by band _C1) the first auxiliary switch (S _C1), the anti-and diode (D of band _C2) the second auxiliary switch (S _C2) and clamping capacitance (C _c) formation, the wherein first auxiliary switch (S _C1) the source electrode and the first power switch pipe (S ₁) drain electrode link to each other the second auxiliary switch (S _C2) the source electrode and the second power switch pipe (S ₂) drain electrode link to each other the first auxiliary switch (S _C1) the drain electrode and the second auxiliary switch (S _C2) drain electrode and clamping capacitance (C _c) an end link to each other clamping capacitance (C _c) the other end and the second power switch pipe (S ₂) source electrode link to each other or with the first low-pressure side winding (L _1a) with low-pressure side power supply (V _L) that end of linking to each other links to each other;

Described high-pressure side circuit comprises: the first high-pressure side winding (L _1b), the second high-pressure side winding (L _2b), the anti-and diode (D of band ₃) the 3rd power switch pipe (S ₃), the anti-and diode (D of band ₄) the 4th power switch pipe (S ₄), the first high-pressure side electric capacity (C _O1) and the second high-pressure side electric capacity (C _O2), the first high-pressure side winding (L wherein _1b) and the first low-pressure side winding (L _1a) be all two windings in the coupling inductance, the second high-pressure side winding (L _2b) and the second low-pressure side winding (L _2a) be all two windings in another coupling inductance, with the first low-pressure side winding (L _1a) and the second low-pressure side winding (L _2a) in all with low-pressure side power supply (V _L) same that end that extremely links to each other be with reference to holding the first high-pressure side winding (L _1b) and the first low-pressure side winding (L _1a) the corresponding end of the same name and the second high-pressure side winding (L _2b) and the second low-pressure side winding (L _2a) corresponding end of the same name links to each other the first high-pressure side winding (L _1b) the other end and the 4th power switch pipe (S ₄) source electrode and the 3rd power switch pipe (S ₃) drain electrode link to each other the second high-pressure side winding (L _2b) the other end and the first high-pressure side electric capacity (C _O1) and the second high-pressure side electric capacity (C _O2) an end link to each other the first high-pressure side electric capacity (C _O1) the other end and the 3rd power switch pipe (S ₃) source electrode and high-pressure side power supply (V _H) an end link to each other the second high-pressure side electric capacity (C _O2) the other end and the 4th power switch pipe (S ₄) drain electrode and high-pressure side power supply (V _H) the other end link to each other, at the 3rd power switch pipe (S ₃) two ends parallel connection the 3rd shunt capacitance (C _S3), at the 4th power switch pipe (S ₄) two ends parallel connection the 4th shunt capacitance (C _S4).

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