CN115133777A - Isolated DC converter and control method - Google Patents

Abstract

The invention discloses an isolated DC converter and a control method, wherein the isolated DC converter comprises: the three-level Boost circuit comprises a plurality of three-level Boost circuits, a first resonance soft switching module, a second resonance soft switching module, a first contactor, a second contactor, an output EMI filter and a central control unit. The control method comprises the following steps: acquiring output current and output voltage of each Boost circuit to control the power or the output voltage of the Boost circuit; the primary side current and secondary side output voltage values of the first resonant soft switching module and the second resonant soft switching module are obtained and used for controlling output voltage or output power, and zero voltage switching-on of the first resonant soft switching module and the second resonant soft switching module can be achieved by selecting proper resonant frequency. The isolated DC converter can be used for DC power transmission in a photovoltaic power generation system and hydrogen production by electrolyzing water in photovoltaic power generation.

Description

Isolated DC converter and control method

Technical Field

The invention belongs to the field of photovoltaic power generation and transmission, and particularly relates to an isolated direct current converter and a control method.

Background

Photovoltaic power generation is an important power generation form in a renewable energy power generation system, at present, photovoltaic power generation is mainly converted by an inverter and is merged into an alternating current power grid, the photovoltaic voltage level is low and is generally below 1500V, so that the cable cost of a photovoltaic power station is high, and the cable loss is also high. The cost of the cable can be reduced by improving the transmission voltage grade, but the cable is limited by the problem of voltage resistance of a photovoltaic module, and few photovoltaic direct-current transmission systems with voltage exceeding 1500V exist at present.

Most of the mainstream DC-DC converters in the field of photovoltaic power generation are non-isolated equipment, and if the voltage of an output end exceeds the withstand voltage value of a photovoltaic module, the photovoltaic module can be damaged under the condition of short circuit to the ground, and even a fire disaster is caused.

Patent CN110838794A discloses a topological circuit of a series-connection type photovoltaic high-voltage direct-current grid-connected converter and a modulation method, wherein an isolated DC-DC conversion topology is adopted, but the output voltage is adjusted by changing the duty ratio, the duty ratio is not fixed 50%, the utilization rate of an isolation transformer is limited, and the efficiency is low in a voltage reduction mode; the input side does not adopt a multi-path MPPT circuit, but integrates the MPPT function into a main circuit, so that the power generation efficiency of the photovoltaic module is limited; in addition, the voltage borne by the topological switch tube is bus voltage and is limited by the withstand voltage of a switch device, and the topological structure is only suitable for photovoltaic power generation systems of 1000V or below.

Disclosure of Invention

The present invention is directed to an isolated dc converter and a control method thereof, so as to solve the above problems of the prior art.

To achieve the above object, the present invention provides an isolated dc converter, including: the three-level Boost circuit comprises a three-level Boost circuit, a first resonance soft switching module, a second resonance soft switching module, a first contactor, a second contactor, an output EMI filter and a central control unit;

the first resonant soft switch module comprises a first H-bridge circuit, a first series resonant cavity and a first rectifying circuit; the first H-bridge circuit is connected with the first series resonant cavity;

the second resonant soft switch module comprises a second H-bridge circuit, a second series resonant cavity and a second rectifying circuit; the second H-bridge circuit is connected with the second series resonant cavity;

the three-level Boost circuit is connected with the first H bridge circuit and the second H bridge circuit;

the first contactor is connected with the first rectifying circuit, and the second contactor is connected with the second rectifying circuit;

the output EMI filter is respectively connected with the three-level Boost circuit;

the central control unit is connected with the three-level Boost circuit, the first resonance soft switch module and the second resonance soft switch module.

Preferably, the first H-bridge circuit includes a first switch tube, a second switch tube, a third switch tube, and a fourth switch tube; the first switching tube and the second switching tube are connected to form a first bridge arm, and the third switching tube and the fourth switching tube are connected to form a second bridge arm; the first bridge arm and the second bridge arm are respectively connected with two ends of the first series resonant cavity;

the second H-bridge circuit comprises a fifth switching tube, a sixth switching tube, a seventh switching tube and an eighth switching tube; the fifth switching tube and the sixth switching tube are connected to form a third bridge arm, and the seventh switching tube and the eighth switching tube are connected to form a fourth bridge arm; and the third bridge arm and the fourth bridge arm are respectively connected with two ends of the second resonant cavity.

Preferably, the first series resonant cavity comprises a first resonant inductor, a first resonant capacitor and a first isolation transformer which are connected in sequence;

the second series resonant cavity comprises a second resonant inductor, a second resonant capacitor and a second isolation transformer which are sequentially connected.

Preferably, the central control unit is configured to control on and off of switching tubes corresponding to the three-level Boost circuit, the first H-bridge circuit, and the second H-bridge circuit, and obtain a current and a voltage of the three-level Boost circuit, a current of the first series resonant cavity and the second series resonant cavity, and a voltage of the first rectifying circuit and the second rectifying circuit.

The invention also provides a control method of the isolated DC converter, which comprises the following steps:

adjusting the output voltage or the output power of the three-level Boost circuit based on the control mode of the three-level Boost circuit;

on the basis of voltage stabilization and frequency limitation control, presetting an oscillation frequency lower limit at the same time, and acquiring a switching frequency corresponding to a switching tube;

and controlling the switching tubes corresponding to the first H-bridge circuit and the second H-bridge circuit to work and controlling the zero-voltage switching-on soft switch to operate based on the switching frequency corresponding to the switching tubes.

Preferably, the process of adjusting the output voltage or the output power of the three-level Boost circuit based on the control mode of the three-level Boost circuit includes:

based on a maximum power tracking control mode, all three-level Boost circuits change output voltage at regular time to obtain different output powers; obtaining a maximum power point based on the different output powers;

based on the voltage stabilization control mode, all three-level Boost circuits control output voltage by adjusting duty ratio based on a preset voltage droop curve.

Preferably, the process of acquiring the switching frequency corresponding to the switching tube includes:

based on the first PI regulator, performing difference processing on a first target output voltage and a first actual output voltage of the first rectifying circuit to obtain a first target oscillation frequency value; the first target oscillation frequency value is not less than a preset oscillation frequency lower limit value; controlling the first series resonant cavity to work based on the first target oscillation frequency value; the first target oscillation frequency value is the switching frequency of the first H-bridge switching tube;

based on a second PI regulator, performing difference processing on a second target output voltage and a second actual output voltage of a second rectifying circuit to obtain a second target oscillation frequency value; the first target oscillation frequency value is not less than a preset oscillation frequency lower limit value; controlling a second series resonant cavity to work based on the second target oscillation frequency value; and the second target oscillation frequency value is the switching frequency of the second H-bridge switching tube.

Preferably, the process of controlling the operation of the switching tubes corresponding to the first H-bridge circuit and the second H-bridge circuit further includes:

a first switching tube and a fourth switching tube of a first H-bridge circuit, a second switching tube and a third switching tube are synchronously switched on, wherein the switching-on moments of the first switching tube and the second switching tube of the first H-bridge circuit are complementary; and controlling a fifth switching tube and an eighth switching tube of a second H-bridge circuit, and controlling a sixth switching tube and a seventh switching tube to be synchronously switched on, wherein the switching-on moments of the fifth switching tube and the sixth switching tube of the second H-bridge circuit are complementary.

The invention has the technical effects that:

according to the invention, the high-efficiency voltage grade conversion is realized by constructing the first resonant soft switching module and the second resonant soft switching module and simultaneously adopting a voltage-stabilizing frequency-limiting soft switching control method.

The isolated DC converter provided by the invention can be used for DC power transmission in a photovoltaic power generation system and hydrogen production by electrolyzing water in photovoltaic power generation.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application. In the drawings:

fig. 1 is a schematic circuit diagram of an isolated dc converter according to an embodiment of the present invention;

101-a first path of three-level Boost circuit, 102-a second path of three-level Boost circuit, 103-an Nth path of three-level Boost circuit, 104-a first resonant soft switching module, 105-a second resonant soft switching module, K21-a first contactor, K22-a second contactor, 106-an output EMI filter, 107-a central control unit, 108-a first photovoltaic component, 109-a second photovoltaic component, 110-a third photovoltaic component and 111-an EMI filter;

fig. 2 is a control flowchart of the isolated dc converter in the embodiment of the present invention;

fig. 3 is an exemplary schematic diagram of an isolated dc converter used for high-voltage power transmission of a photovoltaic system according to an embodiment of the present invention;

301-a photovoltaic component, 302-a multi-path Boost circuit of a first isolated direct current converter, 303-a first resonant soft switching module of the first isolated direct current converter, 304-a second resonant soft switching module of the first isolated direct current converter, 305-a multi-path Boost circuit of an Nth isolated direct current converter, 306-a first resonant soft switching module of the Nth isolated direct current converter, 307-a second resonant soft switching module of the Nth isolated direct current converter, 308-an inverter and 309-a transformer;

FIG. 4 is a schematic diagram illustrating an exemplary principle of an isolated DC converter for hydrogen production by photovoltaic electrolysis of water according to an embodiment of the present invention;

the photovoltaic module is 401-a photovoltaic module, 402-a multi-path Boost circuit of a first isolation type direct current converter, 403-a first resonance soft switching module of the first isolation type direct current converter, 404-a second resonance soft switching module of the first isolation type direct current converter, 405-a multi-path Boost circuit of an Nth isolation type direct current converter, 406-a first resonance soft switching module of the Nth isolation type direct current converter, 407-a first resonance soft switching module of the Nth isolation type direct current converter and 408-an electrolytic cell load.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

It should be noted that the steps shown in the flow chart of the figure may be performed in a computer system such as a Digital Signal Processor (DSP), a single chip, etc. that can execute instructions, and that while a logical order is shown in the flow chart, in some cases the steps shown or described may be performed in an order different than here.

Example one

As shown in fig. 1 to 4, the present embodiment provides an isolated dc converter, including: the three-level Boost circuit comprises a plurality of three-level Boost circuits, a first resonance soft switching module, a second resonance soft switching module, a first contactor, a second contactor, an output EMI filter and a central control unit;

the first resonant soft switch module comprises a first H-bridge circuit, a first series resonant cavity and a first rectifying circuit; the first H-bridge circuit is connected with the first series resonant cavity;

the second resonant soft switch module comprises a second H-bridge circuit, a second series resonant cavity and a second rectifying circuit; the second H-bridge circuit is connected with the second series resonant cavity;

the input end of each three-level Boost circuit is provided with a direct-current isolating switch, an EMI filter and a group of bypass diodes, the outputs of all the Boost circuits are connected in parallel, the output anode is connected with the anode of the first H-bridge circuit, and the output cathode is connected with the cathode of the second H-bridge circuit; the first H-bridge circuit is connected with the second H-bridge circuit in series; each circuit of the three-level Boost circuit is provided with 4 switching tubes and 2 bypass diodes, and the 2 bypass diodes are respectively placed on the anode and the cathode and are connected in parallel with a circuit formed by the inductor and the follow current switching tubes.

The first contactor is connected with the first rectifying circuit, and the second contactor is connected with the second rectifying circuit; the first rectifying circuit is composed of a rectifying bridge and a filter capacitor which are composed of 4 diodes, and the second rectifying circuit is composed of a rectifying bridge and a filter capacitor which are composed of 4 diodes; alternatively, the diode may be replaced by a controllable switching tube, such as a MOSFET.

And the central control unit is connected with the three-level Boost circuit, the first resonance soft switch module and the second resonance soft switch module.

The first H-bridge circuit comprises 4 switching tubes, wherein the switching tubes are respectively Q1, Q2, Q3 and Q4, the Q1 and the Q2 are connected in series to form one bridge arm, and the Q3 and the Q4 are connected in series to form the other bridge arm; the second H-bridge circuit comprises 4 switching tubes which are respectively Q5, Q6, Q7 and Q8, wherein Q5 and Q6 are connected in series to form a bridge arm, and Q7 and Q8 form the other bridge arm; the middle points of 2 bridge arms of the first H-bridge circuit are respectively connected with two ends of the first series resonant cavity, and the middle points of 2 bridge arms of the second H-bridge circuit are respectively connected with two ends of the second resonant cavity.

The first series resonant cavity comprises a first resonant inductor, a first resonant capacitor and a first isolation transformer which are sequentially connected; the second series resonant cavity comprises a second resonant inductor, a second resonant capacitor and a second isolation transformer which are connected in sequence.

The central control unit is used for controlling the on-off of the switching tubes in the Boost circuit, controlling the on-off of the switching tubes in the first H-bridge circuit and the second H-bridge circuit, obtaining the output current, the input voltage and the output voltage of the Boost circuit, and collecting the currents of the first series resonant cavity and the second series resonant cavity; and collecting output voltages of the first rectifying circuit and the second rectifying circuit.

In order to achieve the above object, this embodiment further provides a method for controlling an isolated dc converter, including the following steps:

adjusting the output voltage or the output power of the three-level Boost circuit based on the control mode of the three-level Boost circuit;

on the basis of voltage stabilization and frequency limitation control, presetting duty ratios at the same time, and controlling corresponding switching tubes of the first H-bridge circuit and the second H-bridge circuit to work;

and acquiring the switching frequency corresponding to the switching tube, and controlling the zero voltage switching-on soft switch to operate based on the switching frequency.

The control method of the three-level Boost circuit comprises a Maximum Power Point Tracking (MPPT) control mode and a voltage stabilization control mode 2, wherein in the MPPT control mode, all three-level Boost circuits automatically change output voltage at regular time to further influence input side voltage, the change of input voltage and output current can cause the change of output power, and a maximum power point is sought through the change of the output power; in the voltage stabilization control mode, all three-level Boost circuits take a preset voltage droop curve as a control target, and output voltage is controlled by adjusting duty ratio; in any mode, the switching timing in all three-level Boost circuits is phase-shift interleaved.

When the input voltage reaches the voltage value that the first resonance soft switch module and the second resonance soft switch module can normally operate, the control method of the three-level Boost circuit is that the Boost inductor in the control circuit is bypassed to improve the efficiency, the bypass of the Boost inductor is realized by controlling 2 switch tubes in 4 switch tubes in charge of energy storage to be switched off, and 2 switch tubes in charge of follow current are switched on at the same time, and the Boost control is not performed at the moment.

The process of controlling the operation of the switching tubes corresponding to the first H-bridge circuit and the second H-bridge circuit may include:

voltage-stabilizing frequency-limiting control, and meanwhile, controlling the first H-bridge circuit Q1 and Q4 to be synchronously switched on, controlling the first H-bridge circuit Q2 and the first H-bridge circuit Q3 to be synchronously switched on, and controlling the first H-bridge circuit Q1 and the first H-bridge circuit Q2 to be complementary in switching-on time; the second H-bridge circuit Q5 and Q8 are synchronously switched on, Q6 and Q7 are synchronously switched on, and Q5 is complementary with Q6 at the switching-on time; the duty ratio of all the switching tubes of the first H-bridge circuit and the second H-bridge circuit is 50%, and the zero-voltage switching-on soft switching operation is realized by selecting a proper switching frequency section of the switching tubes.

The process of voltage-stabilizing frequency-limiting control comprises the following steps: acquiring corresponding control targets based on output voltages corresponding to the first rectifying circuit and the second rectifying circuit; and adjusting the output voltage by changing the oscillation frequency of the first series resonant cavity and the second series resonant cavity based on the control target.

The process of acquiring the switching frequency corresponding to the switching tube may include:

the difference between the target voltage and the actual voltage of the first rectifying circuit enters a first PI regulator to obtain a target oscillation frequency value, and the frequency value is used as the switching frequency of a first H-bridge switching tube to control the first series resonant cavity to work; and the difference between the target voltage and the actual voltage of the second rectifying circuit enters a second PI regulator to obtain a target oscillation frequency value, and the frequency value is used as the switching frequency of a second H-bridge switching tube to control the second series resonant cavity to work.

The control link using the voltage as the control target also adds the limitation of the oscillation frequency, and a minimum oscillation frequency is given, so that the frequency cannot be lower than the set minimum oscillation frequency even if the output voltage does not reach the target voltage value.

Example two

As shown in fig. 1, the isolated dc converter proposed in this embodiment includes a multi-path three-level Boost circuit: the circuit comprises a first three-level Boost circuit 101, a second three-level Boost circuit 102 …, an Nth three-level Boost circuit 103, a first resonant soft switch module 104, a second resonant soft switch module 105, a first contactor K21, a second contactor K22, an output EMI filter 106, a central control unit 107, a first photovoltaic module 108, a second photovoltaic module 109, a third photovoltaic 110 module and an EMI filter 111.

The input ends of the three-level Boost circuits are respectively connected with the photovoltaic cell components, and the outputs are connected in parallel. The internal circuits of each Boost circuit are the same and comprise a direct current switch K11, K11 is connected with an external photovoltaic cell module 107, the other end of K11 is connected with the input end of an EMI filter 111, an input filter capacitor Ci1 is connected in parallel with the output end of the EMI filter 111, the positive electrode of a filter capacitor Ci1 is connected with a positive Boost inductor L11, the negative electrode of a filter capacitor Ci1 is connected with a negative Boost inductor L12, the other end of the positive Boost inductor L11 is connected with the connection point of a positive freewheeling switch tube Q11 and a switch tube Q12, and a negative Boost inductor L12 is connected with the connection point of the negative freewheeling switch tube Q14 and a switch tube Q13. An output anode filter capacitor C11 and a cathode filter capacitor C12 are connected in series and then connected to the output end of the three-level Boost circuit in parallel, the anode of a first bypass diode D11 is connected with the anode of an input filter capacitor Ci1, and the cathode of D11 is connected with the anode of an output anode filter capacitor C11; the cathode of the second bypass diode D12 is connected with the cathode of the input filter capacitor Ci1, and the anode of D11 is connected with the cathode of the output cathode filter capacitor C11.

The first resonant soft switch module 104 is composed of a first H-bridge circuit, a first series resonant cavity, and a first rectifying circuit; the second resonant soft switching module 105 is composed of a second H-bridge circuit, a second series resonant cavity, and a second rectifying circuit.

The first H-bridge circuit comprises 4 switching tubes, wherein the switching tubes are respectively Q1, Q2, Q3 and Q4, the Q1 and the Q2 are connected in series to form a bridge arm, and the Q3 and the Q4 are connected in series to form the other bridge arm; the second H-bridge circuit comprises 4 switching tubes which are respectively Q5, Q6, Q7 and Q8, wherein Q5 and Q6 are connected in series to form one bridge arm, and Q7 and Q8 form the other bridge arm.

The first resonant cavity is formed by connecting a first resonant inductor L1, a first resonant capacitor C3 and the primary side of a first isolation transformer T1 in series, and the second resonant cavity is formed by connecting a second resonant inductor L2, a second resonant capacitor C4 and the primary side of a second isolation transformer T2 in series.

The middle points of 2 bridge arms of the first H-bridge circuit are respectively connected with two ends of the first series resonant cavity, and the middle points of 2 bridge arms of the second H-bridge circuit are respectively connected with two ends of the second resonant cavity.

The first rectifying circuit is composed of a rectifying bridge consisting of 4 diodes including D1, D2, D3 and D4 and a filter capacitor C21; the second rectifying circuit is composed of a rectifying bridge composed of 4 diodes including D5, D6, D7 and D8, and a filter capacitor C22.

Alternatively, the diodes D1, D2, D3, D4, D5, D6, D7, D8 may be replaced with MOSFETs.

The first contactor K21 is connected in series to the output terminal of the first rectifying circuit, and the second contactor K22 is connected in series to the output terminal of the second rectifying circuit.

The central control unit 107 is configured to control on and off of switching tubes in the Boost circuit, control on and off of switching tubes in the first H-bridge circuit and the second H-bridge circuit, obtain an output current, an input voltage, and an output voltage of the Boost circuit, and collect currents of the first series resonant cavity and the second series resonant cavity; and acquiring output voltages of the first rectifying circuit and the second rectifying circuit.

The control flow of the isolated dc converter provided in this embodiment is shown in fig. 2, and these controls are executed in the central control unit.

Specifically, in step 201, an output current, an input voltage, and an output voltage value of each three-level Boost circuit are respectively obtained, and a first resonant cavity current value, a second resonant cavity current value, and a first rectifying circuit output voltage, and a second rectifying circuit output voltage are obtained.

In step 202, the control mode is determined, and if the current mode is the Maximum Power Point Tracking (MPPT) mode, the control mode jumps to step 203, otherwise, the control mode jumps to step 204.

In step 203, an MPPT control mode is executed, all three-level Boost circuits automatically and regularly change output voltage to influence input-side voltage, the change of input voltage and output current can cause the change of output power, and the maximum power point is sought through the change of output power.

In step 204, a voltage stabilization control mode is executed, all the three-level Boost circuits take preset voltage droop curves as control targets, and output voltage is controlled by adjusting duty ratios.

In any mode, the switching timing in all three-level Boost circuits is phase-shift interleaved.

In step 205, a first resonant cavity control is executed, the output voltage of the first rectifying circuit is used as a control target, a target oscillation frequency value of the first H-bridge circuit is calculated through the PI regulator, and the oscillation frequency is limited during the control, wherein the resonance frequency is not less than a preset lower limit value of the resonance frequency. The system presets a minimum oscillation frequency, which is not lower than the set minimum oscillation frequency even if the output voltage does not reach the target voltage value.

In step 206, a second resonant cavity control is executed, the output voltage of the second rectifying circuit is used as a control target, a target oscillation frequency value of the second H-bridge circuit is calculated through the PI regulator, and the oscillation frequency is limited during control, wherein the resonance frequency is not less than a preset lower limit value of the resonance frequency. The system presets a minimum oscillation frequency which is not lower than the set minimum oscillation frequency even if the output voltage does not reach the target voltage value.

In step 207, the first H-bridge circuit and the second H-bridge circuit are controlled according to the switching frequency values obtained in steps 205 and 206, respectively. The first H-bridge circuit Q1 and Q4 are synchronously switched on, Q2 and Q3 are synchronously switched on, Q1 and Q2 are complementary to each other in switching-on time, the duty ratios of switching tubes of Q1, Q4, Q2 and Q3 are 50%, and zero-voltage switching-on soft switching operation is realized; the second H-bridge circuit Q5 and Q8 are synchronously switched on, Q6 and Q7 are synchronously switched on, Q5 and Q6 are complementary to each other in switching-on time, the duty ratios of switching tubes of Q5, Q6, Q7 and Q8 are 50%, and zero-voltage switching-on soft switching operation is achieved.

An exemplary principle of the isolated dc converter provided in this embodiment for high-voltage power transmission of a photovoltaic system is shown in fig. 3. In fig. 3, 301 represents a photovoltaic module, 302 represents a multi-path Boost circuit of a first isolated dc converter, 303 represents a first resonant soft switching module of a first isolated dc converter, 304 represents a second resonant soft switching module of the first isolated dc converter, 305 represents a multi-path Boost circuit of an nth isolated dc converter, 306 represents a first resonant soft switching module of an nth isolated dc converter, 307 represents a second resonant soft switching module of the nth isolated dc converter, 308 represents an inverter, and 309 represents a transformer. The photovoltaic module 301 serves as an input of the isolated dc converter provided in this embodiment, and a plurality of output terminals of the dc converter are connected in series. In fig. 3, a first resonant soft switching module 303 and a second resonant soft switching module 304 of a first isolated dc conversion are connected in series; the first resonant soft switch module 306 and the second resonant soft switch module 307 of the N (N is more than or equal to 2) isolation type DC converter are connected in series and then connected in series with other isolation type DC converters, and the output end is connected in series to obtain DC with higher voltage level. The cost of the cable and the loss of the cable can be greatly reduced by transmitting power through high-voltage direct current, the cable is inverted into alternating current through the inverter 308 after being transmitted for a certain distance, and then the alternating current is boosted or reduced in voltage through the transformer 309 and is connected to a power grid.

In the photovoltaic power transmission system, the number of the isolated dc converters may be 1, or may be plural.

An exemplary principle of the isolated dc converter for hydrogen production by photovoltaic electrolyzed water provided by this embodiment is shown in fig. 4, and in fig. 4, 401 — a photovoltaic module, 402 — a multi-way Boost circuit of a first isolated dc converter, 403 — a first resonant soft switch module of the first isolated dc converter, 404 — a second resonant soft switch module of the first isolated dc converter, 405 — a multi-way Boost circuit of an nth isolated dc converter, 406 — a first resonant soft switch module of the nth isolated dc converter, 407 — a first resonant soft switch module of the nth isolated dc converter, and 408-an electrolytic bath load. The input of the multi-path Boost circuit 402 of the first isolated dc converter in fig. 4 is connected to the photovoltaic module, and the output of the first resonant soft switching module 403 is connected in parallel with the output of the second resonant soft switching module. The system comprises one or more isolated direct current converters and an Nth multi-path Boost circuit 405, wherein the output of the Nth path of first resonant soft switch module 403 is connected in parallel with the output of the second resonant soft switch module 404 and is simultaneously merged into the output end of the first isolated direct current converter, the output current is improved through multi-path parallel connection, and the multi-path parallel connection is connected to an electrolytic cell load 408.

In the above photovoltaic power generation hydrogen production system, the multi-path Boost circuit 402 may be separated from the first resonant soft-switching module 403 and the second resonant soft-switching module 404, the multi-path Boost circuit 402 is installed near the photovoltaic module, and the first resonant soft-switching module 403 and the second resonant soft-switching module may be installed near the hydrogen production electrolytic cell.

The above description is only for the preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present application should be covered within the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (8)

1. An isolated dc converter, comprising: the three-level Boost circuit comprises a three-level Boost circuit, a first resonance soft switching module, a second resonance soft switching module, a first contactor, a second contactor, an output EMI filter and a central control unit;

the first resonant soft switch module comprises a first H-bridge circuit, a first series resonant cavity and a first rectifying circuit; the first H-bridge circuit is connected with the first series resonant cavity;

the second resonant soft switch module comprises a second H-bridge circuit, a second series resonant cavity and a second rectifying circuit; the second H-bridge circuit is connected with the second series resonant cavity;

the three-level Boost circuit is connected with the first H bridge circuit and the second H bridge circuit;

the first contactor is connected with the first rectifying circuit, and the second contactor is connected with the second rectifying circuit;

the output EMI filter is respectively connected with the three-level Boost circuit;

the central control unit is connected with the three-level Boost circuit, the first resonant soft switch module and the second resonant soft switch module.

2. The isolated DC converter according to claim 1,

the first H-bridge circuit comprises a first switching tube, a second switching tube, a third switching tube and a fourth switching tube; the first switching tube and the second switching tube are connected to form a first bridge arm, and the third switching tube and the fourth switching tube are connected to form a second bridge arm; the first bridge arm and the second bridge arm are respectively connected with two ends of the first series resonant cavity;

the second H-bridge circuit comprises a fifth switching tube, a sixth switching tube, a seventh switching tube and an eighth switching tube; the fifth switching tube and the sixth switching tube are connected to form a third bridge arm, and the seventh switching tube and the eighth switching tube are connected to form a fourth bridge arm; and the third bridge arm and the fourth bridge arm are respectively connected with two ends of the second resonant cavity.

3. The isolated DC converter according to claim 1,

the first series resonant cavity comprises a first resonant inductor, a first resonant capacitor and a first isolation transformer which are connected in sequence;

the second series resonant cavity comprises a second resonant inductor, a second resonant capacitor and a second isolation transformer which are sequentially connected.

4. The isolated DC converter according to claim 1,

the central control unit is used for controlling the on-off of the switching tubes corresponding to the three-level Boost circuit, the first H-bridge circuit and the second H-bridge circuit, and obtaining the current and the voltage of the three-level Boost circuit, the current of the first series resonant cavity and the second series resonant cavity and the voltage of the first rectifying circuit and the second rectifying circuit.

5. A control method for an isolated direct current converter is characterized by comprising the following steps:

adjusting the output voltage or the output power of the three-level Boost circuit based on the control mode of the three-level Boost circuit;

based on voltage stabilization and frequency limitation control, presetting an oscillation frequency lower limit at the same time, and acquiring a switching frequency corresponding to a switching tube;

and controlling the switching tubes corresponding to the first H-bridge circuit and the second H-bridge circuit to work and controlling the zero-voltage switching-on soft switch to operate based on the switching frequency corresponding to the switching tubes.

6. The isolated DC converter control method according to claim 5,

based on the control mode of the three-level Boost circuit, the process of adjusting the output voltage or the output power of the three-level Boost circuit includes:

based on a maximum power tracking control mode, all three-level Boost circuits change output voltage at regular time to obtain different output powers; obtaining a maximum power point based on the different output powers;

based on the voltage stabilization control mode, all three-level Boost circuits control output voltage by adjusting duty ratio based on a preset voltage droop curve.

7. The isolated DC converter control method according to claim 5,

the process of acquiring the switching frequency corresponding to the switching tube comprises the following steps:

based on a first PI regulator, performing difference processing on a first target output voltage and a first actual output voltage of a first rectifying circuit to obtain a first target oscillation frequency value; the first target oscillation frequency value is not less than a preset oscillation frequency lower limit value; controlling the first series resonant cavity to work based on the first target oscillation frequency value; the first target oscillation frequency value is the switching frequency of the first H-bridge switching tube;

based on a second PI regulator, performing difference processing on a second target output voltage and a second actual output voltage of a second rectifying circuit to obtain a second target oscillation frequency value; the first target oscillation frequency value is not less than a preset oscillation frequency lower limit value; controlling a second series resonant cavity to work based on the second target oscillation frequency value; and the second target oscillation frequency value is the switching frequency of the second H-bridge switching tube.

8. The isolated DC converter control method according to claim 5,

the process of controlling the work of the switching tubes corresponding to the first H-bridge circuit and the second H-bridge circuit further comprises the following steps:

a first switching tube and a fourth switching tube of a first H-bridge circuit, and a second switching tube and a third switching tube are synchronously switched on, wherein the switching-on moments of the first switching tube and the second switching tube of the first H-bridge circuit are complementary; and controlling a fifth switching tube and an eighth switching tube of a second H-bridge circuit, and controlling a sixth switching tube and a seventh switching tube to be synchronously switched on, wherein the switching-on moments of the fifth switching tube and the sixth switching tube of the second H-bridge circuit are complementary.

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