CN102769377B - Non-isolated variable flow topological structure based on phase shift control and application thereof - Google Patents

Abstract

The invention provides a non-isolated variable flow topological structure based on phase shift control, comprising a switch capacitor circuit and a transformer circuit, wherein the switch capacitor circuit consists of two switching tubes, one high voltage capacitor, one resonant capacitor and one resonant inductor in a connection way; and the transformer circuit consists of two switching tubes, one high voltage capacitor and one filter inductor in a connection way. The invention also discloses a converter which adopts the topological structure. Through the control on the phase shift angles and the duty ratios of the various switching tubes, the control on the voltage balance of all the capacitors in the energy flowing direction and at the high voltage side is realized, and the adjustment of output voltage in a wide range, and the connection and disconnection of each switching tube with zero voltage are realized. With the adoption of a structure that multiple groups of switch capacitor circuits are connected in cascade, the converter disclosed by the invention realizes the output at a higher step-down ratio, so that the voltage stresses of all the components are reduced; and additionally, since the step-down ratio of the converter is further improved by the transformer circuit, not only is the voltage stress reduced, but also the adjustable output voltage is implemented.

Description

A kind of non-isolation type unsteady flow topological structure and application thereof based on phase shifting control

Technical field

The invention belongs to electric power Semiconductor Converting Technology field, be specifically related to a kind of non-isolation type unsteady flow topological structure and application thereof based on phase shifting control.

Background technology

In recent years, the shortage of the energy and the pollution of environment have become the focus in the world, and the development of regenerative resource and application are 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-DC converter that low voltage and direct current is converted to and is applicable to grid-connected high-voltage direct-current electricity, so low input ripple, high-gain, high efficiency converter have important effect in regenerative resource is generated electricity by way of merging two or more grid systems field; Some is lower by the operating voltage of electric loading simultaneously, also needs DC-DC converter high-voltage direct-current electricity to be converted to the low voltage and direct current being applicable to by electric loading.

Traditional BUCK current transformer as shown in Figure 1, it is simple in structure, be widely used, but the power switch pipe of this current transformer works in hard switching state, the voltage stress of switching loss and power switch pipe is all larger, and under the application scenario of high step-down ratio, input side current fluctuation is larger, outlet side uses larger series inductance further to increase cost and volume and reduced efficiency.

As shown in Figure 2, its topological structure can be realized high step-down ratio by transformer voltage ratio to traditional circuit of reversed excitation, but the transmission of all power all needs through magnetic core, has increased to a certain extent current transformer volume and has brought certain electromagnetic interference problem.

In succession occurred in recent years some switching capacity type current transformers, this quasi-converter, on the basis of equal die mould switching capacity code converter topology, increases and has resonance phase-shift circuit to realize the soft switch of power switch pipe; Its typical resonant switch capacitance convertor topological structure as shown in Figure 3, this topological structure has advantages of Zero Current Switch, but the output voltage of resonant switch capacitance convertor is determined by the concrete topological structure of circuit, cannot recently control output voltage by duty, limited to the adjustable extent of current transformer output voltage, and energy cannot two-way flow.

Summary of the invention

For the existing above-mentioned technological deficiency of prior art, the invention provides a kind of non-isolation type unsteady flow topological structure and application thereof based on phase shifting control, pressure drop ratio is high, simple in structure, and efficiency is high, and output voltage is adjustable.

A non-isolation type unsteady flow topological structure based on phase shifting control, comprises a switched-capacitor circuit and a transforming circuit;

Described switched-capacitor circuit is by two switching tube S ₁～S ₂, a high-voltage capacitance C ₁, a resonant capacitance C _rwith a resonant inductance L _rcomposition; Wherein, switching tube S ₁input and high-voltage capacitance C ₁one end be connected, switching tube S ₁output and switching tube S ₂input and resonance inductance L _rone end be connected, switching tube S ₂output and high-voltage capacitance C ₁the other end be connected, resonant inductance L _rthe other end and resonant capacitance C _rone end be connected, resonant capacitance C _rthe other end be connected with transforming circuit;

Described transforming circuit is by two switching tube S ₃～S ₄, a high-voltage capacitance C ₂with a filter inductance L _fcomposition; Wherein, switching tube S ₃input and high-voltage capacitance C ₂one end and switched-capacitor circuit mesohigh capacitor C ₁the other end be connected, switching tube S ₃output and switching tube S ₄input, filter inductance L _fone end and switched-capacitor circuit in resonant capacitance C _rthe other end be connected, switching tube S ₄output and high-voltage capacitance C ₂the other end be connected;

The control end of described switching tube receives the control signal that external equipment provides.

High-voltage capacitance C ₁one end and high-voltage capacitance C ₂the other end form high-pressure side, filter inductance L _fthe other end and high-voltage capacitance C ₂the other end form low-pressure side;

When high-pressure side as input low-pressure side as when output, described filter inductance L _fthe other end and high-voltage capacitance C ₂the other end between be connected with output capacitance C _out.

Described switching tube S ₁the control signal and the switching tube S that receive ₂the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₃the control signal and the switching tube S that receive ₄the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₁the control signal and the switching tube S that receive ₃the control signal duty ratio that receives is identical and have a phase shifting angle.

Preferably, described switching tube is metal-oxide-semiconductor; Metal-oxide-semiconductor switching frequency is high, and device carries anti-and diode, and the topological structure volume that uses metal-oxide-semiconductor to build is less, and power density is high.

The principle of unsteady flow topological structure of the present invention is: by control switch pipe S ₁control signal and switching tube S ₃the phase shifting angle of control signal realize the balanced and power flow direction control of high-voltage capacitance; In the time that phase shifting angle is 0, high-voltage capacitance C ₁with high-voltage capacitance C ₂between transmitting energy not, electric voltage equalization; (S in the time that phase shifting angle is greater than 0 ₁have precedence over S ₃conducting), C ₁to C ₂transmitting energy, system is from high side to low side transmitting energy; (S in the time that phase shifting angle is less than 0 ₁lag behind S ₃conducting), C ₂to C ₁transmitting energy, system is from low-pressure side to high-pressure side transmitting energy.In the time of high side to low side through-put power, by capacitor C ₂, switching tube S ₃and S ₄, filter inductance L _fwith output capacitance C _outform a BUCK circuit, adjust phase shifting angle, can make C ₂upper voltage is the half of high-pressure side input voltage, and low-pressure side output voltage is C ₂upper voltage and S ₁the product of the duty ratio D of control signal.When low-pressure side is during to high-pressure side through-put power, capacitor C ₂, switching tube S ₃and S ₄with filter inductance L _fform a BOOST circuit, C ₂upper voltage be low-pressure side input voltage divided by duty ratio D, adjust phase shifting angle, can make on high-tension side output voltage is capacitor C ₂the twice of voltage.

A non-isolation type current transformer based on phase shifting control, comprises n switched-capacitor circuit and a transforming circuit, and n switched-capacitor circuit successively cascade forms, and n is greater than 1 natural number;

Described switched-capacitor circuit is by two switching tube S ₁～S ₂, a high-voltage capacitance C ₁, a resonant capacitance C _rwith a resonant inductance L _rcomposition; Wherein, switching tube S ₁input and high-voltage capacitance C ₁one end be connected and be the first input end of switched-capacitor circuit, switching tube S ₁output and switching tube S ₂input and resonance inductance L _rone end be connected and be the second input of switched-capacitor circuit, switching tube S ₂output and high-voltage capacitance C ₁the other end be connected and be the first output of switched-capacitor circuit, resonant inductance L _rthe other end and resonant capacitance C _rone end be connected, resonant capacitance C _rthe other end second output that is switched-capacitor circuit;

The first output of i-1 switched-capacitor circuit is connected with the first input end of i switched-capacitor circuit, and the second output of i-1 switched-capacitor circuit is connected with the second input of i switched-capacitor circuit, and i is natural number and 2≤i≤n;

Described transforming circuit is by two switching tube S ₃～S ₄, a high-voltage capacitance C ₂with a filter inductance L _fcomposition; Wherein, switching tube S ₃input and high-voltage capacitance C ₂one end and the first output of n switched-capacitor circuit be connected, switching tube S ₃output and switching tube S ₄input, filter inductance L _fone end and the second output of n switched-capacitor circuit be connected, switching tube S ₄output and high-voltage capacitance C ₂the other end be connected;

The control end of described switching tube receives the control signal that external equipment provides.

The first input end of the 1st switched-capacitor circuit and high-voltage capacitance C ₂the other end form high-pressure side, filter inductance L _fthe other end and high-voltage capacitance C ₂the other end form low-pressure side;

When high-pressure side as input low-pressure side as when output, described filter inductance L _fthe other end and high-voltage capacitance C ₂the other end between be connected with output capacitance C _out.

Described switching tube S ₁the control signal and the switching tube S that receive ₂the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₃the control signal and the switching tube S that receive ₄the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₁the control signal and the switching tube S that receive ₃the control signal duty ratio that receives is identical and have a phase shifting angle.

The principle of current transformer of the present invention is: by control switch pipe S ₁control signal and switching tube S ₃the phase shifting angle of control signal realize the balanced and power flow direction control of high-voltage capacitance; In the time that phase shifting angle is 0, transmitting energy not between each high-voltage capacitance, also transmitting energy not of system;

(S in i-1 switched-capacitor circuit in the time that phase shifting angle is greater than 0 ₁have precedence over S in i switched-capacitor circuit ₁conducting, S in the 5th switched-capacitor circuit ₁have precedence over S ₃conducting), C in i-1 switched-capacitor circuit ₁to C in i switched-capacitor circuit ₁transmitting energy, C in the 5th switched-capacitor circuit ₁to C ₂transmitting energy, system is from high side to low side transmitting energy;

(S in i-1 switched-capacitor circuit in the time that phase shifting angle is less than 0 ₁lag behind S in i switched-capacitor circuit ₁conducting, S in the 5th switched-capacitor circuit ₁lag behind S ₃conducting), C in i switched-capacitor circuit ₁to C in i-1 switched-capacitor circuit ₁transmitting energy, C ₂to C in the 5th switched-capacitor circuit ₁transmitting energy, system is from low-pressure side to high-pressure side transmitting energy.

In the time of high side to low side through-put power, by capacitor C ₂, switching tube S ₃and S ₄, filter inductance L _fwith output capacitance C _outform a BUCK circuit, adjust phase shifting angle, can make each high-voltage capacitance all press and be the 1/n+1 of high-pressure side input voltage, low-pressure side output voltage is C ₂upper voltage and S ₁the product of the duty ratio D of control signal, system no-load voltage ratio is D/n+1.When low-pressure side is during to high-pressure side through-put power, capacitor C ₂, switching tube _s3 and S ₄with filter inductance L _fform a BOOST circuit, C ₂upper voltage be low-pressure side input voltage divided by duty ratio D, adjust phase shifting angle, can make each high-voltage capacitance all press, and on high-tension side output voltage is capacitor C ₂doubly, system no-load voltage ratio is n+1/D to the n+1 of voltage.

Unsteady flow structure of the present invention, by the control to phase shifting angle between transforming circuit and switched-capacitor circuit, has realized the control of the each capacitance voltage balance of energy flow direction and high-pressure side; By the control to upper switching tube duty ratio in circuit, realize the adjusting of output voltage wide region; Utilize the parasitic capacitance of switching tube can realize the no-voltage shutoff of each switching tube simultaneously; Utilize the method for resonant circuit phase shifting control, the no-voltage that can realize each switching tube is open-minded.The higher step-down ratio output of converter is organized switched-capacitor circuit cascade structure more and has been realized in current transformer utilization of the present invention, reduces each device voltage stress, utilizes transforming circuit further to improve the step-down ratio of converter, reduce voltage stress, and it is adjustable to realize output voltage.

Brief description of the drawings

Fig. 1 is the structural representation of traditional B UCK convertor circuit.

Fig. 2 is the structural representation of traditional inverse-excitation type convertor circuit.

Fig. 3 is the structural representation of resonant switch electric capacity convertor circuit.

Fig. 4 is the schematic diagram of unsteady flow topological structure of the present invention.

Working waveform figure when Fig. 5 is unsteady flow topological structure decompression mode of the present invention.

Working waveform figure when Fig. 6 is unsteady flow topological structure boost mode of the present invention.

Fig. 7 is the structural representation of current transformer of the present invention.

Embodiment

In order more specifically to describe the present invention, below in conjunction with the drawings and the specific embodiments, technical scheme of the present invention is elaborated.

As shown in Figure 4, a kind of non-isolation type unsteady flow topological structure based on phase shifting control, comprises a switched-capacitor circuit and a transforming circuit;

Switched-capacitor circuit is by two switching tube S ₁～S ₂, a high-voltage capacitance C ₁, a resonant capacitance C _rwith a resonant inductance L _rcomposition; Wherein, switching tube S ₁input and high-voltage capacitance C ₁one end be connected, switching tube S ₁output and switching tube S ₂input and resonance inductance L _rone end be connected, switching tube S ₂output and high-voltage capacitance C ₁the other end be connected, resonant inductance L _rthe other end and resonant capacitance C _rone end be connected, resonant capacitance C _rthe other end be connected with transforming circuit;

Transforming circuit is by two switching tube S ₃～S ₄, a high-voltage capacitance C ₂, an output capacitance C _outwith a filter inductance L _fcomposition; Wherein, switching tube S ₃input and high-voltage capacitance C ₂one end and switched-capacitor circuit mesohigh capacitor C ₁the other end be connected, switching tube S ₃output and switching tube S ₄input, filter inductance L _fone end and switched-capacitor circuit in resonant capacitance C _rthe other end be connected, switching tube S ₄output and high-voltage capacitance C ₂the other end be connected; Filter inductance L _fthe other end and high-voltage capacitance C ₂the other end between be connected with output capacitance C _out.

High-voltage capacitance C ₁one end and high-voltage capacitance C ₂the other end form high-pressure side external high voltage power supply or high-voltage load, filter inductance L _fthe other end and high-voltage capacitance C ₂the other end form low-pressure side external low-tension supply or low-voltage load.

The control end of switching tube receives the control signal that external equipment provides; In present embodiment, switching tube S ₁the control signal and the switching tube S that receive ₂the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₃the control signal and the switching tube S that receive ₄the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₁the control signal and the switching tube S that receive ₃the control signal duty ratio that receives is identical and have a phase shifting angle.

Present embodiment is because the needs nature that powers on is all pressed, therefore C ₁=C ₂, switching tube employing N-type metal-oxide-semiconductor and each switching tube parameter are basic identical.

In the time that phase shifting angle is 0, resonant inductance L _relectric current is 0, C ₁, C ₂between transmitting energy not, electric voltage equalization;

(S in the time that phase shifting angle is greater than 0 ₁have precedence over S ₃), as shown in Figure 5, C ₁to C ₂transmitting energy, system is from high side to low side transmitting energy, capacitor C ₂, switching tube S ₃and S ₄, filter inductance L _fwith output capacitance C _outform a BUCK circuit, adjust phase shifting angle, can make C ₂upper voltage is the half of high-pressure side input voltage, and low-pressure side output voltage is C ₂the product of upper voltage and duty ratio D; Working state of system is as follows:

Stage 1 (t ₀-t ₁) S ₁, S ₂dead band, S ₁parasitic capacitance discharge, S ₂parasitic capacitance charging; S ₄conducting, L _frelease energy to low-pressure side.S ₂have no progeny in pass, resonant inductance L _rto S ₁, S ₂contact is filled with electric current, due to S ₂parasitic capacitance exist, therefore the S that flows through ₂electric current be zero, voltage rising is to V _c1, realize soft shutoff.

Stages 2 (t ₁-t ₂) S ₁, S ₄conducting, high-pressure side starts to C _rcharging.S ₂parasitic capacitance voltage rise to V _c1after, S ₁the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₁, realize no-voltage open-minded.

Stages 3 (t ₂-t ₃) S ₁, S ₄conducting, high-pressure side is to C _rcharging, C _relectric current just becomes, S ₁forward conduction.

Stages 4 (t ₃-t ₄) S ₃, S ₄dead band, S ₃parasitic capacitance discharge, S ₄parasitic capacitance charging.S ₄have no progeny in pass, resonant inductance L _rto S ₃, S ₄contact is filled with electric current, due to S ₄parasitic capacitance exist, therefore the S that flows through ₄electric current be zero, voltage rising is to V _c2, realize soft shutoff.

Stages 5 (t ₄-t ₅) S ₁, S ₃conducting, C _rstart to absorb C ₁energy, its electric current is larger, C ₁, C ₂between isolated island absorb electric charge.S ₄parasitic capacitance voltage rise to V _c2after, S ₃the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₃, realize no-voltage open-minded.

Stages 6 (t ₅-t ₆) S ₁, S ₃conducting, C _rcontinue to absorb C ₁energy, its electric current reduces, C ₁, C ₂between isolated island emit electric charge, S ₃forward conduction.

Stages 7 (t ₆-t ₇) S ₁, S ₂dead band, S ₂parasitic capacitance discharge, S ₁parasitic capacitance charging.S ₁have no progeny in pass, resonant inductance L _rfrom S ₁, S ₂contact absorbing current, due to S ₁parasitic capacitance exist, therefore the S that flows through ₁electric current be zero, voltage rising is to V _c2, realize soft shutoff.

Stages 8 (t ₇-t ₈) S ₂, S ₃conducting, C _rstart to release energy.S ₁parasitic capacitance voltage rise to V _c1after, S ₂the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₂, realize no-voltage open-minded.

Stages 9 (t ₈-t ₉) S ₂, S ₃conducting, C _rcontinue to release energy, C _relectric current becomes negative, S ₂forward conduction.

Stages 10 (t ₉-t ₁₀) S ₃, S ₄dead band, S ₄parasitic capacitance discharge, S ₃parasitic capacitance charging.S ₃have no progeny in pass, resonant inductance L _rfrom S ₃, S ₄contact absorbing current, due to S ₃parasitic capacitance exist, therefore the S that flows through ₃electric current be zero, voltage rising is to V _c2, realize soft shutoff.

Stages 11 (t ₁₀-t ₁₁) S ₂, S ₄conducting, C _rgive C ₂release energy.S ₃parasitic capacitance voltage rise to V _c2after, S ₄the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₄, realize no-voltage open-minded;

(S in the time that phase shifting angle is less than 0 ₁lag behind S ₃), as shown in Figure 6, C ₂to C ₁transmitting energy, system is from low-pressure side to high-pressure side transmitting energy, capacitor C ₂, switching tube S ₃and S ₄with filter inductance L _fform a BOOST circuit and (remove output capacitance C _out), C ₂upper voltage be low-pressure side input voltage divided by duty ratio D, adjust phase shifting angle, can make on high-tension side output voltage is capacitor C ₂the twice of voltage; Working state of system is as follows:

Stage 1 (t ₀-t ₁) S ₃, S ₄dead band, S ₃parasitic capacitance discharge, S ₄parasitic capacitance charging.S ₄have no progeny in pass, resonant inductance L _rto S ₃, S ₄contact is filled with electric current, due to S ₄parasitic capacitance exist, therefore the S that flows through ₄electric current be zero, voltage rising is to V _c2, realize soft shutoff.

Stages 2 (t ₁-t ₂) S ₂, S ₃conducting, C _rstart to release energy to L _r.S ₄parasitic capacitance voltage rise to V _c2after, S ₃the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₃, realize no-voltage open-minded.

Stages 3 (t ₂-t ₃) S ₂, S ₃conducting, C _rcontinue to release energy, C _relectric current becomes negative, S ₃forward conduction.

Stages 4 (t ₃-t ₄) S ₁, S ₂dead band, S ₁parasitic capacitance discharge, S ₂parasitic capacitance charging.S ₂have no progeny in pass, resonant inductance L _rto S ₁, S ₂contact is filled with electric current, due to S ₂parasitic capacitance exist, therefore the S that flows through ₂electric current be zero, voltage rising is to V _c1, realize soft shutoff.

Stages 5 (t ₄-t ₅) S ₁, S ₃conducting, C _rgive C ₁release energy, L _felectric current is larger, C ₁, C ₂between isolated island absorb electric charge.S ₂parasitic capacitance voltage rise to V _c1after, S ₁the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₁, realize no-voltage open-minded.

Stages 6 (t ₅-t ₆) S ₁, S ₃conducting, C _rcontinue to C ₁release energy, L _felectric current reduces, C ₁, C ₂between isolated island emit electric charge.

Stages 7 (t ₆-t ₇) S ₃, S ₄dead band, S ₄parasitic capacitance discharge, S ₃parasitic capacitance charging.S ₃have no progeny in pass, resonant inductance L _rfrom S ₃, S ₄contact absorbing current, due to S ₃parasitic capacitance exist, therefore the S that flows through ₃electric current be zero, voltage rising is to V _c2, realize soft shutoff.

Stages 8 (t ₇-t ₈) S ₁, S ₄conducting, high-pressure side will be to C _rcharging.S ₃parasitic capacitance voltage rise to V _c2after, S ₄the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₄, realize no-voltage open-minded.

Stages 9 (t ₈-t ₉) S ₁, S ₄conducting, high-pressure side is to C _rcharging, C _relectric current just becomes, S ₄forward conduction.

Stages 10 (t ₉-t ₁₀) S ₁, S ₂dead band, S ₂parasitic capacitance discharge, S ₁parasitic capacitance charging.S ₁have no progeny in pass, resonant inductance L _rfrom S ₁, S ₂contact absorbing current, due to S ₁parasitic capacitance exist, therefore the S that flows through ₁electric current be zero, voltage rising is to V _c2, realize soft shutoff.

Stages 11 (t ₁₀-t ₁₁) S ₂, S ₄conducting, C _rabsorb C ₂energy.S ₁parasitic capacitance voltage rise to V _c1after, S ₂the anti-and diode current flow of parasitism, its drain-source voltage is 0, now opens switching tube S ₂, realize no-voltage open-minded.

In order to improve pressure drop ratio, according to the unsteady flow topological structure in above-mentioned example, expand the progression of switched-capacitor circuit; As shown in Figure 7, a kind of non-isolation type current transformer based on phase shifting control, comprises n switched-capacitor circuit and a transforming circuit, and n switched-capacitor circuit successively cascade forms, n=5 in present embodiment;

Switched-capacitor circuit is by two switching tube S ₁～S ₂, a high-voltage capacitance C ₁, a resonant capacitance C _rwith a resonant inductance L _rcomposition; Wherein, switching tube S ₁input and high-voltage capacitance C ₁one end be connected and be the first input end of switched-capacitor circuit, switching tube S ₁output and switching tube S ₂input and resonance inductance L _rone end be connected and be the second input of switched-capacitor circuit, switching tube S ₂output and high-voltage capacitance C ₁the other end be connected and be the first output of switched-capacitor circuit, resonant inductance L _rthe other end and resonant capacitance C _rone end be connected, resonant capacitance C _rthe other end second output that is switched-capacitor circuit;

The first output of i-1 switched-capacitor circuit is connected with the first input end of i switched-capacitor circuit, and the second output of i-1 switched-capacitor circuit is connected with the second input of i switched-capacitor circuit, and i is natural number and 2≤i≤5;

Transforming circuit is by two switching tube S ₃～S ₄, an output capacitance C _outa high-voltage capacitance C ₂with a filter inductance L _fcomposition; Wherein, switching tube S ₃input and high-voltage capacitance C ₂one end be connected with the first output of the 5th switched-capacitor circuit, switching tube S ₃output and switching tube S ₄input, filter inductance L _fone end be connected with the second output of the 5th switched-capacitor circuit, switching tube S ₄output and high-voltage capacitance C ₂the other end be connected; Filter inductance L _fthe other end and high-voltage capacitance C ₂the other end between be connected with output capacitance C _out.

The first input end of the 1st switched-capacitor circuit and high-voltage capacitance C ₂the other end form high-pressure side external high voltage power supply or high-voltage load, filter inductance L _fthe other end and high-voltage capacitance C ₂the other end form low-pressure side external low-tension supply or low-voltage load;

The control end of switching tube receives the control signal that external equipment provides; Switching tube S ₁the control signal and the switching tube S that receive ₂the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₃the control signal and the switching tube S that receive ₄the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₁the control signal and the switching tube S that receive ₃the control signal duty ratio that receives is identical and have a phase shifting angle.

Present embodiment is because the needs nature that powers on is all pressed, therefore C ₁=C ₂, switching tube employing N-type metal-oxide-semiconductor and each switching tube parameter are basic identical.

Be similar to the operation principle of foregoing employing one-level switched-capacitor circuit in conjunction with the unsteady flow topological structure of transforming circuit: in the time that phase shifting angle is 0, resonant inductance L _relectric current is zero, transmitting energy not between each high-voltage capacitance, and system is transmitting energy not;

(S in i-1 switched-capacitor circuit in the time that phase shifting angle is greater than 0 ₁have precedence over S in i switched-capacitor circuit ₁conducting, S in the 5th switched-capacitor circuit ₁have precedence over S ₃conducting), C in i-1 switched-capacitor circuit ₁to C in i switched-capacitor circuit ₁transmitting energy, C in the 5th switched-capacitor circuit ₁to C ₂transmitting energy, system is from high side to low side transmitting energy; By capacitor C ₂, switching tube S ₃and S ₄, filter inductance L _fwith output capacitance C _outform a BUCK circuit, adjust phase shifting angle, can make each high-voltage capacitance all press and for high-pressure side input voltage 1/6, low-pressure side output voltage is C ₂upper voltage and S ₁the product of the duty ratio D of control signal, now low-pressure side load is from C ₂with level V resonant capacitance C _ron absorb energy, and C ₂with level V resonant capacitance C _rfrom level V high-voltage capacitance C ₁with fourth stage resonant capacitance C _ron absorb energy, by that analogy, system no-load voltage ratio is D/6;

(S in i-1 switched-capacitor circuit in the time that phase shifting angle is less than 0 ₁lag behind S in i switched-capacitor circuit ₁conducting, S in the 5th switched-capacitor circuit ₁lag behind S ₃conducting), C in i switched-capacitor circuit ₁to C in i-1 switched-capacitor circuit ₁transmitting energy, C ₂to C in the 5th switched-capacitor circuit ₁transmitting energy, system is from low-pressure side to high-pressure side transmitting energy; By capacitor C ₂, switching tube S ₃and S ₄with filter inductance L _fform a BOOST circuit and (remove output capacitance C _out), C ₂upper voltage be low-pressure side input voltage divided by duty ratio D, adjust phase shifting angle, can make each high-voltage capacitance all press, and on high-tension side output voltage is capacitor C ₂6 times of voltage, now high-pressure side load is from first order high-voltage capacitance C ₁on absorb energy, low-pressure side power supply is to C ₂with level V resonant capacitance C _renergy storage, level V high-voltage capacitance C ₁with fourth stage resonant capacitance C _rdraw C ₂with level V resonant capacitance C _ron energy, by that analogy, system no-load voltage ratio is 6/D.

Claims (6)

1. the non-isolation type unsteady flow topological structure based on phase shifting control, is characterized in that: comprise a switched-capacitor circuit and a transforming circuit;

Described switched-capacitor circuit is by two switching tube S ₁～S ₂, a high-voltage capacitance C ₁, a resonant capacitance C _rwith a resonant inductance L _rcomposition; Wherein, switching tube S ₁input and high-voltage capacitance C ₁one end be connected, switching tube S ₁output and switching tube S ₂input and resonance inductance L _rone end be connected, switching tube S ₂output and high-voltage capacitance C ₁the other end be connected, resonant inductance L _rthe other end and resonant capacitance C _rone end be connected, resonant capacitance C _rthe other end be connected with transforming circuit;

Described transforming circuit is by two switching tube S ₃～S ₄, a high-voltage capacitance C ₂with a filter inductance L _fcomposition; Wherein, switching tube S ₃input and high-voltage capacitance C ₂one end and switched-capacitor circuit mesohigh capacitor C ₁the other end be connected, switching tube S ₃output and switching tube S ₄input, filter inductance L _fone end and switched-capacitor circuit in resonant capacitance C _rthe other end be connected, switching tube S ₄output and high-voltage capacitance C ₂the other end be connected;

Described switching tube S ₁～S ₄control end all receive the control signal that external equipment provides; Wherein, described switching tube S ₁the control signal and the switching tube S that receive ₂the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₃the control signal and the switching tube S that receive ₄the control signal phase place that receives is complementary and have an interval, dead band; Described switching tube S ₁the control signal and the switching tube S that receive ₃the control signal duty ratio that receives is identical and have a phase shifting angle.

2. the non-isolation type unsteady flow topological structure based on phase shifting control according to claim 1, is characterized in that: when high-pressure side as input low-pressure side as when output, described filter inductance L _fthe other end and high-voltage capacitance C ₂the other end between be connected with output capacitance C _out.

3. the non-isolation type unsteady flow topological structure based on phase shifting control according to claim 1, is characterized in that: described switching tube S ₁～S ₄be metal-oxide-semiconductor.

4. the non-isolation type current transformer based on phase shifting control, is characterized in that: comprise n switched-capacitor circuit and a transforming circuit, n switched-capacitor circuit successively cascade forms, and n is greater than 1 natural number;

Described switched-capacitor circuit is by two switching tube S ₁～S ₂, a high-voltage capacitance C ₁, a resonant capacitance C _rwith a resonant inductance L _rcomposition; Wherein, switching tube S ₁input and high-voltage capacitance C ₁one end be connected and be the first input end of switched-capacitor circuit, switching tube S ₁output and switching tube S ₂input and resonance inductance L _rone end be connected and be the second input of switched-capacitor circuit, switching tube S ₂output and high-voltage capacitance C ₁the other end be connected and be the first output of switched-capacitor circuit, resonant inductance L _rthe other end and resonant capacitance C _rone end be connected, resonant capacitance C _rthe other end second output that is switched-capacitor circuit;

The first output of i-1 switched-capacitor circuit is connected with the first input end of i switched-capacitor circuit, and the second output of i-1 switched-capacitor circuit is connected with the second input of i switched-capacitor circuit, and i is natural number and 2≤i≤n;

Described transforming circuit is by two switching tube S ₃～S ₄, a high-voltage capacitance C ₂with a filter inductance L _fcomposition; Wherein, switching tube S ₃input and high-voltage capacitance C ₂one end and the first output of n switched-capacitor circuit be connected, switching tube S ₃output and switching tube S ₄input, filter inductance L _fone end and the second output of n switched-capacitor circuit be connected, switching tube S ₄output and high-voltage capacitance C ₂the other end be connected;

Described switching tube S ₁～S ₄control end all receive the control signal that external equipment provides; Wherein, described switching tube S ₁the control signal and the switching tube S that receive ₂the control signal phase place that receives is complementary and have an interval, dead band; Switching tube S ₃the control signal and the switching tube S that receive ₄the control signal phase place that receives is complementary and have an interval, dead band; Described switching tube S ₁the control signal and the switching tube S that receive ₃the control signal duty ratio that receives is identical and have a phase shifting angle.

5. the non-isolation type current transformer based on phase shifting control according to claim 4, is characterized in that: when high-pressure side as input low-pressure side as when output, described filter inductance L _fthe other end and high-voltage capacitance C ₂the other end between be connected with output capacitance C _out.

6. the non-isolation type current transformer based on phase shifting control according to claim 4, is characterized in that: described switching tube S ₁～S ₄be metal-oxide-semiconductor.