CN111211705A - Bidirectional transformation structure suitable for split-phase power grid and output control method - Google Patents

Abstract

The invention relates to a bidirectional transformation structure suitable for a split-phase power grid, which comprises: two DC bus filter capacitors; one end of the three output power lines is respectively connected with a first live wire, a second live wire and a zero line of the split-phase power grid; the inverter circuit is formed by two bridge arms formed by connecting an output power wire with a switching tube and a filter inductor respectively; when the transformation structure works, when the transformation structure is in an off-grid operation mode, the switching-on and the switching-off of the switching tube are controlled, so that the transformation structure controls the output current and the phase difference of each phase when the transformation structure is connected to a grid, and controls the voltage and the phase difference of an output power line when the transformation structure is disconnected from the grid, the single-phase inverter in the prior art can be simultaneously suitable for a single-phase power grid and the off-grid power grid, and when the transformation structure is connected with the off-grid power grid and is in the off-grid operation mode, the requirements of different voltage outputs can be met without additionally arranging extra transformer.

Description

Bidirectional transformation structure suitable for split-phase power grid and output control method

Technical Field

The invention belongs to the technical field of power electronic converters, and particularly relates to a bidirectional conversion structure and an output control method suitable for a split-phase power grid.

Background

An inverter is a system for inverting dc power into ac power, and generally, an inverter includes a grid-connected operation mode and an off-grid operation mode. The grid-connected operation mode is that direct current generated by photovoltaic modules such as solar energy is converted into alternating current, and after the local load consumption is met, redundant electric energy is transmitted to a power grid, namely the grid-connected mode; the off-grid operation mode is a mode in which the inverter operates off-grid and outputs a fixed voltage and supplies power to a load connected to the off-grid output end of the inverter when the power grid is abnormal or stops transmitting power to the power grid, that is, the off-grid mode.

The worldwide household power supply system mainly comprises a single-Phase power grid system and a Split-Phase (Split Phase) power grid system. The household single-phase power grid system is composed of a live wire and a zero wire in a three-phase power grid system, and the voltage of the live wire to the zero wire is 220V or 230V under the system, so that household electrical equipment adapted to a single-phase power grid system area is only 230V in voltage level. Correspondingly, the split-phase power grid system is composed of two live wires and two neutral wires in a three-phase power grid system, in the system, the voltage of the live wire to the neutral wire is 101V or 120V (hereinafter, 120V is taken as an example), and the voltage of the live wire to the live wire is 202V or 240V (hereinafter, 240V is taken as an example), so that the household electrical appliances under the split-phase power grid system also have two grades of 120V and 240V, generally, the electrical appliances of 120V grade are low-power electrical appliances, and the electrical appliances of 240V grade are high-power electrical appliances.

However, most of the existing single-phase inverters are configured according to a single-phase power grid system, and when the existing single-phase inverters are connected to the single-phase power grid system and in a grid-connected operation mode, the ac ports of the inverters are connected to the live line and the neutral line of the single-phase power grid system, and at this time, the currents flowing through the live line and the neutral line are equal.

If the single-phase inverter arranged according to the single-phase power grid system in the prior art needs to be applied to the split-phase power grid system, the ac output port of the single-phase inverter is connected to two live wires in the split-phase power grid system, and the neutral wire (i.e., N wire) of the split-phase power grid system is left unconnected, or the neutral wire is simply connected to a grid voltage sampling circuit inside the device. In practical use, for example, when a photovoltaic inverter or an energy storage inverter is connected to a power grid and is in a grid-connected operation mode, an output current of the inverter flows through two live wires (L1 and L2) of an isolated phase power grid, and the currents flowing through the two live wires should be equal to each other, while a neutral wire N of the isolated phase power grid connected to the inverter does not flow a current, so that, in this mode, the inverter cannot output different powers to two phases of the power grid. It is conceivable that when the photovoltaic energy is sufficient, in order to meet the requirement of backflow prevention, the inverter of the above type outputs a single-phase current value of a small current, which would result in energy waste.

On the other hand, when the power grid is abnormal, the inverter (photovoltaic inverter or energy storage inverter) configured according to the single-phase power grid system is disconnected from the current power grid, operates in an off-grid operation mode, and supplies power to a load connected to the inverter, as described above, the inverter configured according to the single-phase power grid system can only output one voltage level of 120V or 240V, but cannot output two voltage levels at the same time, that is, cannot supply power to a plurality of household electrical devices of different voltage levels at the same time.

In order to solve the technical problem, that is, in a conventional off-grid operating mode of the inverter, two voltage levels of 120V and 240V can be simultaneously output, a common mode in the prior art is to connect a power frequency isolation transformer or an autotransformer to an off-grid output port of the inverter for phase splitting, in this mode, the inverter only outputs one voltage level of 240V in the off-grid operating mode, and the power frequency isolation transformer or the autotransformer phase-splits the output voltage so as to obtain two voltages of 120V and 240V. However, in the common method, due to the adoption of the power frequency isolation transformer or the autotransformer, the size of the inverter is increased, the overall weight of the equipment is heavier, and the energy consumption of the additional transformer is added, so that the overall efficiency of the system is correspondingly reduced. On the other hand, when the inverter in the off-grid operation mode is switched to the power frequency isolation transformer or the autotransformer, the transformer excitation requires the inverter to output a large inrush current (peak current), and the inrush current is inhibited by lacking an effective means, so that semiconductor devices, relays or fuses in the inverter are easily damaged.

Certainly, in the prior art, a mode of connecting an electronic phase splitter can be adopted to replace a power frequency isolation transformer or an autotransformer, however, the connection of the electronic phase splitter is a loop formed by a switching tube, an inductor, a capacitor and other energy storage devices, and in order to achieve the phase splitting effect, the connection of the electronic phase splitter can be regarded as adding a primary power conversion loop on an original system, and as more components are added, extra energy loss is naturally generated in the conversion process, and the equipment cost is further increased, so that the system configuration process is more complicated.

In view of the above, the prior art should be improved to solve the aforementioned technical problems in the prior art.

Disclosure of Invention

The inverter applying the structure can be simultaneously suitable for a single-phase power grid and a split-phase power grid, and when the inverter is connected with the split-phase power grid, the output current and the phase difference of each phase are controlled, and when the inverter is in an off-grid operation mode, the requirements of different voltage outputs can be met without additionally arranging a transformer or an electronic phase splitter for splitting phases, the system cost when the inverter needs split-phase voltage for splitting phases is obviously reduced, and the energy loss in the conversion process can be reduced.

In order to solve the technical problem, the invention adopts a bidirectional transformation structure suitable for a split-phase power grid, which comprises: the two direct current bus filter capacitors are defined as a first filter capacitor and a second filter capacitor; one end of each of the three output power lines is connected between the first filter capacitor and the second filter capacitor, and the other end of each of the three output power lines is respectively connected with the first live wire, the second live wire and the zero line of the split-phase power grid, so that the three output power lines are respectively defined as a first live wire output power line, a second live wire output power line and a zero line output power line; the inverter circuit is formed by two bridge arms formed by connecting the first live wire output power wire and the second live wire output power wire with a switching tube and a filter inductor respectively; the auxiliary switch element enables the conversion structure to be switched between a single-phase power grid operation mode and a split-phase power grid operation mode, when the conversion structure works, the on-off of the auxiliary switch element is controlled through the control unit, so that the conversion structure is in the single-phase power grid operation mode or the split-phase power grid operation mode, when the conversion structure is in the split-phase power grid operation mode, the on-off of the switch tube is controlled, so that the output current and the phase difference of each phase of the conversion structure are controlled when the conversion structure is connected to the power grid, and the voltage and the phase difference of the output power line are controlled when the conversion structure is disconnected from the power grid.

Further preferably, a bridge arm formed by a first live wire output power line is defined as a first bridge arm, and a bridge arm formed by a second live wire output power line is defined as a second bridge arm, wherein the first bridge arm comprises a first switch tube, a second switch tube, a third switch tube, a fourth switch tube and a first filter inductor; the second bridge arm comprises a fifth switching tube, a sixth switching tube, a seventh switching tube, an eighth switching tube and a second filter inductor.

Still further preferably, in the first bridge arm, a drain of a first switching tube is connected to the first filter capacitor, a source of the first switching tube is connected to a source of a third switching tube, a drain of the third switching tube is connected to a drain of the second switching tube, in the second bridge arm, a drain of a sixth switching tube is connected to a drain of a seventh switching tube, a source of the seventh switching tube is connected to a drain of the eighth switching tube, and a source of the eighth switching tube is connected to the second filter capacitor, wherein a source of the second switching tube and a source of the sixth switching tube are both connected to a midpoint between the first filter capacitor and the second filter capacitor, and a drain of the fourth switching tube is connected to a source of the first switching tube, and a source thereof is connected between a source of the eighth switching tube and the second filter capacitor, the drain electrode of the fifth switching tube is connected with the drain electrode of the first switching tube, and the source electrode of the fifth switching tube is connected with the drain electrode of the eighth switching tube.

Still further preferably, the auxiliary switch element comprises a first switch element and a second switch element, wherein one end of the first switch element is connected between the second switch tube and the third switch tube, and the other end of the first switch element is connected between the sixth switch tube and the seventh switch tube, and the second switch element is arranged on the zero line output power line, so that when the conversion structure is in the single-phase grid operation mode, the first switch element is closed, and the second switch element is opened; when the transformation structure is in the split-phase power grid operation mode, the first switch part is opened, and the second switch part is closed.

Still further preferably, the control unit is at least one independent digital controller, and when the conversion structure is in a split-phase power grid operation mode, the control unit independently controls energy flow on the first bridge arm and the second bridge arm, wherein the control unit sends a driving signal to each switching tube to control the switching tubes to be turned on and off.

Still further preferably, when the conversion structure is in the split-phase grid operation mode, the control unit controls the first switching tube and the second switching tube, the third switching tube and the fourth switching tube, the fifth switching tube and the sixth switching tube, and the seventh switching tube and the eighth switching tube to be selectively conducted.

Correspondingly, the invention also provides a split-phase power grid output control method based on the split-phase power grid bidirectional control device, and the output control method comprises the following steps: step A1 of configuring three output power lines to be respectively connected with a first live wire, a second live wire and a zero wire of the split-phase power grid; step A2 of configuring an auxiliary switch element for switching the operation mode of the conversion structure and configuring a switch tube and a filter inductor; a step A3 of controlling the switching sequence of the switching tube by the configuration control unit; and A4, configuring phase differences among the first live wire, the second live wire and the zero line and voltages among the first live wire, the second live wire and the zero line, and respectively configuring current values of the first live wire and the second live wire when the two live wires are in a grid-connected operation mode.

Further preferably, the auxiliary switch device includes a first switch device and a second switch device, wherein in step a2, two ends of the first switch device are respectively connected to the first live output power line and the second live output power line, and the second switch device is further disposed on the output power line connected to the neutral line, so that when the auxiliary switch device is connected to the single-phase power grid, the first switch device is controlled to be closed, and the second switch device is controlled to be opened; when the control circuit is connected with the split-phase power grid, the first switch part is controlled to be opened, and the second switch part is controlled to be closed.

Still further preferably, the bridge arm formed by the first live wire output power line is defined as a first bridge arm, and the bridge arm formed by the second live wire output power line is defined as a second bridge arm, wherein in step a4, when the transformation structure works, it is determined through sampling that the switched-in is a single-phase power grid or a split-phase power grid, and the control unit controls the on-off of the auxiliary switch element, so that the transformation structure is in a single-phase power grid operation mode or a split-phase power grid operation mode

When the conversion structure is in a split-phase power grid operation mode, the on-off of the switch tube is controlled, so that the conversion structure controls the output current and the phase difference of each phase when the conversion structure is connected to the grid, and the conversion structure controls the voltage and the phase difference of the output power line when the conversion structure is disconnected from the grid.

Preferably, when the off-grid operating mode is performed, the step of configuring the phase difference between the first live wire, the second live wire and the zero wire is to adjust the phase difference between the first live wire and the zero wire and the phase difference between the second live wire and the zero wire within a preset range so as to control the output voltage between the first live wire and the second live wire.

Compared with the prior art, the invention has the following beneficial technical effects due to the adoption of the technical scheme:

1. three output power lines are configured, one ends of the three output power lines are connected between the first filter capacitor and the second filter capacitor, and the other ends of the three output power lines are respectively connected with a first live wire, a second live wire and a zero line of the split-phase power grid, so that in the conversion structure, the output power lines are connected with the zero line of the split-phase power grid, and a current loop is provided for the zero line inside the conversion structure, so that the zero line of the split-phase power grid can be used for sampling by a sampling circuit, and current passes through the conversion structure at the same time, thereby solving the technical problems that when an inverter is connected with the split-phase power grid in the prior art, different currents cannot be output to two phases of the split-phase power grid, and when the inverter is connected with the split-phase power grid, the voltages and phases of the first live wire to the zero line and;

2. based on the reasons, as the three output power lines are respectively connected with the first live wire, the second live wire and the zero line of the split-phase power grid, the power loop is provided for the zero line of the split-phase power grid due to the conversion structure, so that the inverter can output different powers for two phases of the split-phase power grid during grid connection, namely, each phase of output can be controlled, and independent reverse flow prevention for each phase can be realized;

3. when the inverter is in an off-grid running state, the voltage between a first live wire, a second live wire and a zero wire of the split-phase power grid is controlled to be 120V, and the phase difference between the first live wire and the zero wire and the phase difference between the second live wire and the zero wire are controlled to be 180 degrees, so that the voltage between the first live wire and the second live wire can be 240V, two voltage levels of 120V and 240V are output simultaneously, and the technical problem that different levels of voltage cannot be output simultaneously when the inverter designed based on a single-phase power grid is connected with the split-phase power grid in the prior art is solved;

4. the method of realizing different levels of voltage output by additionally arranging a transformer split phase or externally connecting an electronic sharer under the prior art is replaced, so that the overall complexity of the system is reduced, the use of system components is reduced, and the workload of system configuration and installation and the system operation cost are obviously reduced;

5. based on the advantages, the inverter designed based on the single-phase power grid in the prior art can be suitable for the single-phase power grid and the split-phase power grid, and the switching of the operation mode of the inverter conversion structure is completed by controlling the on and off of the switch element by introducing the auxiliary first switch element and the auxiliary second switch element, so that the loss of system energy in the conversion process is reduced;

6. the independent controllers are used for respectively controlling the plurality of switching tubes in the two bridge arms, or the independent controllers are used for configuring a switching time sequence for each switching tube, so that the energy flow of each bridge arm in the whole conversion process of the inverter can be controlled, and a foundation is provided for controlling the output current of each phase during grid connection and controlling the voltage and the phase of each phase during grid disconnection.

Drawings

FIG. 1 is a schematic diagram illustrating a bidirectional transformation architecture for a split-phase power grid according to a preferred embodiment of the present invention;

FIG. 2 is a schematic diagram illustrating the connection of the bi-directional transformation architecture for an isolated phase grid to a single phase grid as described in the preferred embodiment of FIG. 1;

FIG. 3 is a schematic diagram illustrating the connection of a bi-directional transformation architecture for an isolated phase grid to the isolated phase grid as described in the preferred embodiment shown in FIG. 1;

FIG. 4 is a schematic diagram showing driving signals of a first switch tube to a fourth switch tube in the bidirectional conversion structure suitable for the split-phase power grid in the preferred embodiment shown in FIG. 3;

FIG. 5 is a schematic diagram showing driving signals of a fifth switching tube to an eighth switching tube in the bidirectional conversion structure suitable for the split-phase power grid in the preferred embodiment shown in FIG. 3;

FIG. 6 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the split-phase power grid voltage is in positive half cycle during grid connection or the output voltage L1-L2 is in negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in state 1;

FIG. 7 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the split-phase power grid voltage is in positive half cycle during grid connection or the output voltage L1-L2 is in negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in state 2;

FIG. 8 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the split-phase power grid voltage is in positive half cycle during grid connection or the output voltage L1-L2 is in negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in state 3;

FIG. 9 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the split-phase power grid voltage is in positive half cycle during grid connection or the output voltage L1-L2 is in negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in state 4;

FIG. 10 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the voltage of the split-phase power grid is in a negative half cycle during grid connection or the voltage of the output L1-L2 is in a negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in a state 5;

FIG. 11 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the voltage of the split-phase power grid is in a negative half cycle during grid connection or the voltage of the output L1-L2 is in a negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in a state 6;

FIG. 12 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure suitable for the split-phase power grid in the preferred embodiment shown in FIG. 3, when the split-phase power grid voltage is in the negative half cycle during grid connection or the output voltage L1-L2 is in the negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in the state 7;

FIG. 13 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the voltage of the split-phase power grid is in a negative half cycle during grid connection or the voltage of the output L1-L2 is in a negative half cycle during off-grid, the control unit controls the bidirectional transformation structure to be in a state 8;

FIG. 14 is a flow chart showing the flow of the split-phase power grid output control method according to another preferred embodiment of the invention.

Detailed Description

An embodiment of a bidirectional conversion structure and an output control method suitable for a split-phase power grid according to the present invention will be described below with reference to the accompanying drawings. Those of ordinary skill in the art will recognize that the described embodiments can be modified in various different ways, without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and not intended to limit the scope of the claims. Furthermore, in the present description, the drawings are not to scale and like reference numerals refer to like parts.

It should be noted that, in the embodiments of the present invention, the expressions "first" and "second" are used to distinguish two entities with the same name but different names or different parameters, and it is understood that "first" and "second" are merely for convenience of description and should not be construed as limitations of the embodiments of the present invention, and the descriptions thereof in the following embodiments are omitted.

The bidirectional conversion structure can be used for being connected with a solar panel of a photovoltaic array or a direct current source such as a storage battery, and can also be connected with another stage of DCDC converter, so that the direct current voltage generated by the solar panel or output by the DCDC converter is controlled by the control unit to switch the operation modes (including a single-phase power grid operation mode and a split-phase power grid operation mode) of an auxiliary switch element related to the conversion structure, when the conversion structure is in the split-phase power grid operation mode, the conversion structure controls the output current and the phase difference of each phase of the conversion structure during grid connection by controlling the on-off of a switch tube, and controls the voltage and the phase difference of an output power line during grid disconnection so that the conversion structure can output different powers on a first live wire and a second live wire during grid connection; when the power grid is off-grid, different voltage levels are output, and the power grid is usually distinguished from the split-phase power grid in the united states, namely, two voltages of 120V and 240V are output.

Specifically, fig. 1 is a schematic diagram illustrating a bidirectional transformation structure suitable for an isolated phase power grid according to a preferred embodiment of the present invention. As shown in fig. 1, the dc side is connected to two dc bus filter capacitors, which are defined as a first filter capacitor C1 and a second filter capacitor C2, and the theoretical voltage values of the first filter capacitor C1 and the second filter capacitor C2 should be equal to one-half of the dc bus voltage.

Three output power lines are configured, the three output power lines respectively correspond to a first live wire L1, a second live wire L2 and a zero line N (N line) of a power grid, the three output power lines are defined as a first live wire output power line 10, a second live wire output power line 20 and a zero line output power line 30 according to the connection relation, and one ends of the first live wire output power line 10, the second live wire output power line 20 and the zero line output power line 30 are all connected to the midpoint position between a first filter capacitor C1 and a second filter capacitor C2.

The bridge arm formed by the first live wire output power line 10 is a first bridge arm, and the first bridge arm includes a first switching tube S1, a second switching tube S2, a third switching tube S3, and a first filter inductor La. Referring to fig. 1, the drain of the first switch tube S1 is connected to the first filter capacitor C1, the source thereof is connected to the source of the third switch tube S3, the drain of the third switch tube S3 is connected to the drain of the second switch tube S2, so that the first switch tube S1, the second switch tube S2, the third switch tube S3 and the first filter capacitor C1 are connected to form a loop, and the second switch tube S2, the third switch tube S3 and the first filter inductor La form the first live wire output power line 10, and the first live wire output power line 10 is connected to the first live wire L1 from the midpoint between the first filter capacitor C1 and the second filter capacitor C2. The bridge arm formed by the second live wire output power line 20 is a second bridge arm, and the second bridge arm includes a sixth switching tube S6, a seventh switching tube S7, an eighth switching tube S8, and a second filter inductor Lb. Referring to fig. 1, a drain of the sixth switching tube S6 is connected to a drain of the seventh switching tube S7, a source of the seventh switching tube S7 is connected to a drain of the eighth switching tube S8, and a source of the eighth switching tube S8 is connected to the second filter capacitor C2, so that the sixth switching tube S6, the seventh switching tube S7, the eighth switching tube S8, and the second filter capacitor C2 are connected to form a loop, and the sixth switching tube S6, the seventh switching tube S7, and the second filter inductor Lb form the second live wire output power line 20, and so that the second live wire output power line 20 is connected to the second live wire L2 from a midpoint between the first filter capacitor C1 and the second filter capacitor C2. Meanwhile, the first bridge arm further comprises a fourth switching tube S4, the second bridge arm further comprises a fifth switching tube S5, the drain electrode of the fourth switching tube S4 is connected to the source electrode of the first switching tube S1, and the source electrode of the fourth switching tube S4 is connected between the source electrode of the eighth switching tube S8 and the second filter capacitor C2; the drain of the fifth switch tube S5 is connected to the drain of the first switch tube S1, and the source of the fifth switch tube S5 is connected to the drain of the eighth switch tube S8. In this way, the fourth switching tube S4 and the fifth switching tube S5 are the switching tubes respectively connected to the first arm and the second arm, so that the flow direction of energy can be controlled by controlling the timing sequence of the switching tubes, and the purpose of controlling the output voltage is achieved. In another preferred embodiment, the second switch tube S2 and the third switch tube S3, the sixth switch tube S6 and the seventh switch tube S7 in the modified structure can also exchange drain sources at the same time, that is, the connection manner in the foregoing embodiment is adjusted such that the drain of the first switch tube S1 is connected to the first filter capacitor C1, the source thereof is connected to the drain of the third switch tube S3, and the source of the third switch tube S3 is connected to the source of the second switch tube S2, so that the first switch tube S1, the second switch tube S2, the third switch tube S3 and the first filter capacitor C1 are connected to form a loop; meanwhile, the connection mode of the sixth switch tube S6 and the seventh switch tube S7 is adjusted such that the source of the sixth switch tube S6 is connected to the source of the seventh switch tube S7, the drain of the seventh switch tube S7 is connected to the drain of the eighth switch tube S8, and the source of the eighth switch tube S8 is connected to the second filter capacitor C2, so that the sixth switch tube S6, the seventh switch tube S7, the eighth switch tube S8, and the second filter capacitor C2 are connected to form a loop, which is equivalent to the connection mode in the foregoing embodiment.

It should be noted that, in different embodiments of the present invention, the switch tube may be selected from gate turn-off thyristors (GTOs), power transistors (GTRs), power field efficiency transistors (VMOSFETs), Insulated Gate Bipolar Transistors (IGBTs), Integrated Gate Commutated Thyristors (IGCTs), Symmetric Gate Commutated Thyristors (SGCTs), and the like, for example, and the embodiments of the present invention are not limited thereto.

In the configuration of the auxiliary switch member, the auxiliary switch member includes a first switch member T1 and a second switch tube member T2, one end of the first switch member T1 is connected between the second switch tube S2 and the third switch tube S3, the other end thereof is connected between the sixth switch tube S6 and the seventh switch tube S7, and the second switch member T2 is disposed on the neutral output power line 30. Fig. 2 is a schematic diagram showing the configuration of the bidirectional conversion architecture for an isolated phase grid according to the preferred embodiment of fig. 1 in a grid-connected operation mode when connected to a single-phase grid, and referring to fig. 2, in practical use, when connected to a normal single-phase grid, the first switching device T1 is kept closed, and the second switching device T2 is opened, in which mode, since the second switching device T2 is opened, so that the zero line is opened, no current flows through the zero line; due to the closing of the first switching device T1, the second switching device S2 and the sixth switching device S6 are bypassed as shown, that is, the conversion structure is switched to the single-phase grid operation mode, at this time, the first live wire output power line of the conversion structure is connected to L of the single-phase grid, and the second live wire output power line is connected to N of the single-phase grid.

FIG. 3 is a schematic diagram showing the connection of the bidirectional transformation structure for the isolated phase power grid to the isolated phase power grid described in the preferred embodiment shown in FIG. 1. As described above, when the inverter is applied to the inverter sampling to the split-phase grid, the first switching element T1 is kept open, and the second switching element T2 is kept closed, so as to operate in the split-phase grid mode, and provide a power loop for the zero line, and each phase current (power) can be controlled independently by grid connection, and the voltage and phase of each phase can be controlled by off-grid. In the preferred embodiment, two independent SPWM controllers respectively send driving signals to the first to eighth switching tubes, that is, one SPWM controller controls the on and off of the first to fourth switching tubes (S1 to S4), and the other SPWM controller controls the on and off of the fifth to eighth switching tubes (S5 to S8), so that each controller corresponds to one phase bridge arm to control the energy flow direction on the bridge arm.

Fig. 4 is a schematic diagram showing driving signals of the first to fourth switching tubes in the bidirectional conversion structure suitable for the split-phase power grid in the preferred embodiment shown in fig. 3. FIG. 5 is a schematic diagram showing driving signals of a fifth switching tube to an eighth switching tube in the bidirectional conversion structure suitable for the split-phase power grid in the preferred embodiment shown in FIG. 3; referring to fig. 4 and 5, in the driving signals sent by the SPWM controller, corresponding to the first to eighth switching tubes (S1 to S8), which are PWM1 to PWM8, respectively, PWM1 and PWM2 are complementarily turned on, PWM3 and PWM4 are complementarily turned on, PWM5 and PWM6 are complementarily turned on, and PWM7 and PWM8 are complementarily turned on. That is, the SPWM controller controls the first switching tube and the second switching tube, the third switching tube and the fourth switching tube, the fifth switching tube and the sixth switching tube, and the seventh switching tube and the eighth switching tube to be selectively turned on.

Based on the above transformation structure, in practical application, no matter the transformation structure works in a grid-connected operation state or an off-grid operation state, the alternating current output by the output side of the transformation structure is a sine wave including positive and negative half cycles, and as one switch between complementary switch tubes is controlled to be switched on, 8 possible working states exist, and the following explains 8 inversion working process states when the output voltage of the transformation structure is in the positive half cycle and the negative half cycle with reference to the attached drawings.

Fig. 6 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the split-phase power grid voltage is on grid connection or the output voltage L1-L2 is in positive half cycle when the output voltage is off grid, the control unit controls the bidirectional transformation structure to be in state 1. In the state 1, the driving signal of the SPWM controller is PWM1 high, PWM2 low, PWM3 high, PWM4 low, PWM5 low, PWM6 high, PWM7 low, PWM8 high, and corresponding to the corresponding switch tube, the first switch tube S1 is turned on, the second switch tube S2 is turned off, the third switch tube S3 is turned on, the fourth switch tube S4 is turned off, the fifth switch tube S5 is turned off, the sixth switch tube S6 is turned on, the seventh switch tube S7 is turned off, and the eighth switch tube S8 is turned on. Referring to fig. 6, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, so that when the conversion structure is in this state, the energy of the first bridge arm flows from the positive pole of the first filter capacitor C1, through S1 → La → L1 → N → T2, and returns to the negative pole of the first filter capacitor C1; meanwhile, the energy of the second arm flows from the positive electrode of the second filter capacitor C2, through N → L2 → Lb → S8, and returns to the negative electrode of the second filter capacitor C2.

Fig. 7 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the split-phase power grid voltage is on grid connection or the output voltage L1-L2 is in positive half cycle when the output voltage is off grid, the control unit controls the bidirectional transformation structure to be in state 2. In the state 2, the driving signal of the SPWM controller is PWM1 high, PWM2 low, PWM3 high, PWM4 low, PWM5 low, PWM6 high, PWM7 high, PWM8 low, and corresponding to the corresponding switch tube, the first switch tube S1 is turned on, the second switch tube S2 is turned off, the third switch tube S3 is turned on, the fourth switch tube S4 is turned off, the fifth switch tube S5 is turned off, the sixth switch tube S6 is turned on, the seventh switch tube S7 is turned on, and the eighth switch tube S8 is turned off. Referring to fig. 7, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, so that when the conversion structure is in this state, the energy of the first bridge arm flows from the positive pole of the first filter capacitor C1, through S1 → La → L1 → N → T2, and returns to the negative pole of the first filter capacitor C1; meanwhile, the energy of the second leg flows from the left end of the second filter inductance Lb, through S7 → S6 → the second filter capacitance → T2 → N → L2, and returns to the right end of the second filter inductance Lb.

FIG. 8 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in FIG. 3, when the split-phase power grid voltage is connected to the grid or the output voltage L1-L2 is in the positive half cycle when the output voltage is off the grid, the control unit controls the bidirectional transformation structure to be in the state 3; in the state 3, the driving signal of the SPWM controller is PWM1 low, PWM2 high, PWM3 high, PWM4 low, PWM5 low, PWM6 high, PWM7 low, PWM8 high, and corresponding to the corresponding switch tube, the first switch tube S1 is turned off, the second switch tube S2 is turned on, the third switch tube S3 is turned on, the fourth switch tube S4 is turned off, the fifth switch tube S5 is turned off, the sixth switch tube S6 is turned on, the seventh switch tube S7 is turned off, and the eighth switch tube S8 is turned on. Referring to fig. 8, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, then as shown in the drawing, when the conversion structure is in this state, the energy of the first bridge arm flows from the right end of the first filter inductor La, through L1 → N → T2 → S2 → S3, and returns to the left end of the first filter inductor La; meanwhile, the energy of the second leg flows from the left end of the second filter inductance Lb, through S7 → S6 → C2 → T2 → N → L2, and returns to the right end of the second filter inductance Lb.

Fig. 9 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the split-phase power grid voltage is on grid connection or the output voltage L1-L2 is in positive half cycle when the output voltage is off grid, the control unit controls the bidirectional transformation structure to be in state 4. In state 4, the driving signal of the SPWM controller is PWM1 low, PWM2 high, PWM3 high, PWM4 low, PWM5 low, PWM6 high, PWM7 high, PWM8 low, and corresponding to the corresponding switch tube, the first switch tube S1 is turned off, the second switch tube S2 is turned on, the third switch tube S3 is turned on, the fourth switch tube S4 is turned off, the fifth switch tube S5 is turned off, the sixth switch tube S6 is turned on, the seventh switch tube S7 is turned on, and the eighth switch tube S8 is turned off. Referring to fig. 9, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, then as shown in the drawing, when the conversion structure is in this state, the energy of the first bridge arm flows from the right end of the first filter inductor La, through L1 → N → T2 → S2 → S3, and returns to the left end of the first filter inductor La; meanwhile, the energy of the second leg flows through S7 → S6 → C2 → T2 → N → L2 right end of the second filter inductance Lb starting from the left end of the second filter inductance Lb.

Fig. 10 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the voltage of the split-phase power grid is in negative half cycle during grid connection or the voltage of the output L1-L2 during off-grid, and the control unit controls the bidirectional transformation structure to be in state 5. In the state 5, the driving signal of the SPWM controller is PWM1 low, PWM2 high, PWM3 low, PWM4 high, PWM5 high, PWM6 low, PWM7 high, PWM8 low, and corresponding to the corresponding switch tube, the first switch tube S1 is turned off, the second switch tube S2 is turned on, the third switch tube S3 is turned off, the fourth switch tube S4 is turned on, the fifth switch tube S5 is turned on, the sixth switch tube S6 is turned off, the seventh switch tube S7 is turned on, and the eighth switch tube S8 is turned off. Referring to fig. 10, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, so that when the conversion structure is in this state, the energy of the first bridge arm flows from the positive pole of the second filter capacitor C2, through T2 → N → L1 → La → S4 and returns to the negative pole of the second filter capacitor C2; meanwhile, the energy of the second leg flows from the positive electrode of the first filter capacitor C1, through S5 → Lb → L2 → N → T2, and returns to the negative electrode of the first filter capacitor C1.

Fig. 11 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the voltage of the split-phase power grid is in negative half cycle during grid connection or the voltage of the output L1-L2 during off-grid, and the control unit controls the bidirectional transformation structure to be in state 6. In the state 6, the driving signal of the SPWM controller is PWM1 low, PWM2 high, PWM3 low, PWM4 high, PWM5 low, PWM6 high, PWM7 high, PWM8 low, and corresponding to the corresponding switch tube, the first switch tube S1 is turned off, the second switch tube S2 is turned on, the third switch tube S3 is turned off, the fourth switch tube S4 is turned on, the fifth switch tube S5 is turned off, the sixth switch tube S6 is turned on, the seventh switch tube S7 is turned on, and the eighth switch tube S8 is turned off. Referring to fig. 11, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, so that when the conversion structure is in this state, the energy of the first bridge arm flows from the positive pole of the second filter capacitor C2, through T2 → N → L1 → La → S4 and returns to the negative pole of the second filter capacitor C2; meanwhile, the energy of the second leg flows from the right end of the second filter inductance Lb, through L2 → N → T2 → S6 → S7, and returns to the left end of the second filter inductance Lb.

Fig. 12 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the voltage of the split-phase power grid is in negative half cycle during grid connection or the voltage of the output L1-L2 during off-grid, and the control unit controls the bidirectional transformation structure to be in state 7. In the state 7, the driving signal of the SPWM controller is PWM1 low, PWM2 high, PWM3 high, PWM4 low, PWM5 high, PWM6 low, PWM7 high, PWM8 low, and corresponding to the corresponding switch tube, the first switch tube S1 is turned off, the second switch tube S2 is turned on, the third switch tube S3 is turned on, the fourth switch tube S4 is turned off, the fifth switch tube S5 is turned on, the sixth switch tube S6 is turned off, the seventh switch tube S7 is turned on, and the eighth switch tube S8 is turned off. Referring to fig. 12, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, then as shown in the drawing, when the conversion structure is in this state, the energy of the first bridge arm flows from the left end of the first filter inductor La, through S3 → S2 → T2 → N → L1, and returns to the right end of the first filter inductor La; meanwhile, the energy of the second leg flows from the positive electrode of the first filter capacitor C1, through S5 → Lb → L2 → N → T2, and returns to the negative electrode of the first filter capacitor C1.

Fig. 13 is a schematic diagram showing an equivalent circuit structure of the bidirectional transformation structure applied to the split-phase power grid in the preferred embodiment shown in fig. 3, when the voltage of the split-phase power grid is in negative half cycle during grid connection or the voltage of the output L1-L2 during off-grid, and the control unit controls the bidirectional transformation structure to be in state 8. In the state 8, the driving signal of the SPWM controller is PWM1 low, PWM2 high, PWM3 high, PWM4 low, PWM5 low, PWM6 high, PWM7 high, PWM8 low, and corresponding to the corresponding switch tube, the first switch tube S1 is turned off, the second switch tube S2 is turned on, the third switch tube S3 is turned on, the fourth switch tube S4 is turned off, the fifth switch tube S5 is turned off, the sixth switch tube S6 is turned on, the seventh switch tube S7 is turned on, and the eighth switch tube S8 is turned off. Referring to fig. 13, the solid arrows in the drawing show the flowing direction of the energy flowing through the first inductor La, and the hollow arrows show the flowing direction of the energy flowing through the second inductor Lb, then as shown in the drawing, when the conversion structure is in this state, the energy of the first bridge arm flows from the left end of the first filter inductor La, through S2 → S2 → T2 → N → L1, and returns to the right end of the first filter inductor La; meanwhile, the energy of the second leg flows from the right end of the second filter inductance Lb, through L2 → N → T2 → S6 → S7, and returns to the left end of the second filter inductance Lb.

When the inverter runs off the grid, the voltage and the phase of each live wire to the zero wire can be controlled, so that the voltage of the first live wire L1 and the voltage of the second live wire L2 to the zero wire N are both 120V, and meanwhile, the phase difference between the voltage of the first live wire L1 to the zero wire N and the voltage of the second live wire L2 to the zero wire N is configured, so that the output voltage of the first live wire L1 to the second live wire L2 is controlled. For example, the phase difference between the voltage of the first live line L1 and the voltage of the second live line L2 is set to 180 ° with respect to the zero line N, so that the output voltage of the first live line L1 and the second live line L2 is set to 240V. However, in an actual power grid, since the frequency and phase of the power grid deviate from the theoretical values, the effective voltage values of the first live line L1 to the zero line N and the second live line L2 to the zero line N are both 120V, and the phase difference of the first live line L1 to the zero line N and the phase difference of the second live line L2 to the zero line N may be 179 ° or 181 °, so that the effective voltage value between the first live line L1 and the second live line L2 is less than 240V in this case. Based on the above situation in the actual power grid, the purpose of controlling the output voltage between the first live wire L1 and the second live wire L2 can be further achieved by adjusting the phase difference between the first live wire L1 to the zero wire N and the second live wire L2 to the zero wire, for example, if the phase difference between the first live wire L1 to the zero wire N and the second live wire L2 to the zero wire N is adjusted to be 0 °, then the effective voltage value between the first live wire L1 and the second live wire L2 is 0V at this time. Thus, if the phase difference between the first live wire L1 and the second live wire L2 is dynamically adjusted, the effective voltage value before the first live wire and the second live wire can be adjusted to be varied in the range of 0V to 240V. Therefore, when the inverter including the power architecture according to the preferred embodiment of the present invention is in an off-grid operation state, the output voltage is controlled to simultaneously output the 120V voltage and the 240V voltage, so as to solve the problem that the conventional inverter cannot simultaneously supply power to the 120V load and the 240V load when being off-grid.

Accordingly, the present invention also provides an output control method based on various preferred embodiments of the present invention including the above control state. FIG. 14 is a flow chart showing the flow of the split-phase power grid output control method according to a preferred embodiment of the invention. Referring to FIG. 14, the split-phase power grid output control method in the preferred embodiment of the present invention comprises the following steps: step A1 of configuring three output power lines to be respectively connected with a first live wire, a second live wire and a zero wire of the split-phase power grid; step A2 of configuring an auxiliary switch element for switching the operation mode of the conversion structure and configuring a switch tube and a filter inductor; and a step A3 of controlling the switching time sequence of the switching tube by a configuration control unit, and a step A4 of configuring the phase difference between the first live wire, the second live wire and the zero wire when the switching tube is in an off-grid operation mode.

Compared with the prior art, the invention has the following beneficial technical effects due to the adoption of the technical scheme:

1. three output power lines are configured, one ends of the three output power lines are connected between the first filter capacitor and the second filter capacitor, and the other ends of the three output power lines are respectively connected with a first live wire, a second live wire and a zero line of the split-phase power grid, so that in the conversion structure, the output power lines are connected with the zero line of the split-phase power grid, and a current loop is provided for the zero line inside the conversion structure, so that the zero line of the split-phase power grid can be used for sampling by a sampling circuit, and current passes through the conversion structure at the same time, thereby solving the technical problems that when an inverter is connected with the split-phase power grid in the prior art, different currents cannot be output to two phases of the split-phase power grid, and when the inverter is connected with the split-phase power grid, the voltages and phases of the first live wire to the zero line and;

2. based on the reasons, as the three output power lines are respectively connected with the first live wire, the second live wire and the zero line of the split-phase power grid, the power loop is provided for the zero line of the split-phase power grid due to the conversion structure, so that the inverter can output different powers for two phases of the split-phase power grid during grid connection, namely, each phase of output can be controlled, and independent reverse flow prevention for each phase can be realized;

3. when the inverter is in an off-grid running state, the voltage between a first live wire, a second live wire and a zero wire of the split-phase power grid is controlled to be 120V, and the phase difference between the first live wire and the zero wire and the phase difference between the second live wire and the zero wire are controlled to be 180 degrees, so that the voltage between the first live wire and the second live wire can be 240V, two voltage levels of 120V and 240V are output simultaneously, and the technical problem that different levels of voltage cannot be output simultaneously when the inverter designed based on a single-phase power grid is connected with the split-phase power grid in the prior art is solved;

4. the method of realizing different levels of voltage output by additionally arranging a transformer split phase or externally connecting an electronic sharer under the prior art is replaced, so that the overall complexity of the system is reduced, the use of system components is reduced, and the workload of system configuration and installation and the system operation cost are obviously reduced;

5. based on the advantages, the inverter designed based on the single-phase power grid in the prior art can be suitable for the single-phase power grid and the split-phase power grid, and the switching of the operation mode of the inverter conversion structure is completed by controlling the on and off of the switch element by introducing the auxiliary first switch element and the auxiliary second switch element, so that the loss of system energy in the conversion process is reduced;

6. the independent controllers are used for respectively controlling the plurality of switching tubes in the two bridge arms, or the independent controllers are used for configuring a switching time sequence for each switching tube, so that the energy flow of each bridge arm in the whole conversion process of the inverter can be controlled, and a foundation is provided for controlling the output current of each phase during grid connection and controlling the voltage and the phase of each phase during grid disconnection.

The present invention has been described in detail, and the embodiments are only used for understanding the method and the core idea of the present invention, and the purpose of the present invention is to enable those skilled in the art to understand the content of the present invention and to implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (10)

1. A bidirectional conversion structure suitable for a split-phase power grid is characterized by comprising:

the two direct current bus filter capacitors are defined as a first filter capacitor and a second filter capacitor;

one end of each of the three output power lines is connected between the first filter capacitor and the second filter capacitor, and the other end of each of the three output power lines is respectively connected with the first live wire, the second live wire and the zero line of the split-phase power grid, so that the three output power lines are respectively defined as a first live wire output power line, a second live wire output power line and a zero line output power line;

the inverter circuit is formed by two bridge arms formed by connecting the first live wire output power wire and the second live wire output power wire with a switching tube and a filter inductor respectively;

an auxiliary switching element for switching the conversion structure between a single-phase network operating mode and a split-phase network operating mode, wherein,

when the transformation structure works, the control unit controls the on-off of the auxiliary switch element to enable the transformation structure to be in a single-phase power grid operation mode or a split-phase power grid operation mode, when the transformation structure is in the split-phase power grid operation mode, the on-off of the switch tube is controlled to enable the transformation structure to control the output current and the phase difference of each phase of the transformation structure when the transformation structure is connected to the power grid, and the voltage and the phase difference of the output power line when the transformation structure is disconnected from the power grid.

2. The bi-directional conversion architecture for an isolated phase power grid according to claim 1, wherein the leg formed by the first live output power line is defined as a first leg, and the leg formed by the second live output power line is defined as a second leg, wherein,

the first bridge arm comprises a first switch tube, a second switch tube, a third switch tube, a fourth switch tube and a first filter inductor;

the second bridge arm comprises a fifth switching tube, a sixth switching tube, a seventh switching tube, an eighth switching tube and a second filter inductor, and two ends of the fourth switching tube and two ends of the fifth switching tube are respectively connected with the first bridge arm and the second bridge arm.

3. The bidirectional conversion structure applicable to an isolated phase power grid according to claim 2, wherein in the first bridge arm, the drain of the first switch tube is connected to the first filter capacitor, the source of the first switch tube is connected to the source of the third switch tube, the drain of the third switch tube is connected to the drain of the second switch tube, in the second bridge arm, the drain of the sixth switch tube is connected to the drain of the seventh switch tube, the source of the seventh switch tube is connected to the drain of the eighth switch tube, and the source of the eighth switch tube is connected to the second filter capacitor,

the source electrode of the second switch tube and the source electrode of the sixth switch tube are both connected to the midpoint between the first filter capacitor and the second filter capacitor, the drain electrode of the fourth switch tube is connected to the source electrode of the first switch tube, the source electrode of the fourth switch tube is connected between the source electrode of the eighth switch tube and the second filter capacitor, the drain electrode of the fifth switch tube is connected with the drain electrode of the first switch tube, and the source electrode of the fifth switch tube is connected with the drain electrode of the eighth switch tube.

4. The bidirectional conversion structure applicable to an isolated phase power grid according to claim 3, wherein the auxiliary switching member includes a first switching member and a second switching member, wherein,

one end of the first switch piece is connected between the second switch tube and the third switch tube, the other end of the first switch piece is connected between the sixth switch tube and the seventh switch tube, the second switch piece is arranged on the zero line output power line, and when the conversion structure is in the single-phase power grid operation mode, the first switch piece is closed, and the second switch piece is opened; when the transformation structure is in the split-phase power grid operation mode, the first switch part is opened, and the second switch part is closed.

5. The bidirectional conversion architecture for an isolated phase power grid according to claim 4, wherein said control unit is at least one independent digital controller that independently controls the energy flow on said first leg and said second leg when said conversion architecture is in an isolated phase grid operating mode, wherein,

the control unit sends a driving signal to each switching tube to control the switching tubes to be switched on and switched off.

6. The bidirectional conversion structure suitable for the split-phase power grid according to claim 5, wherein when the conversion structure is in the split-phase power grid operation mode, the control unit controls the first and second switching tubes, the third and fourth switching tubes, the fifth and sixth switching tubes, and the seventh and eighth switching tubes to be alternatively conducted.

7. An energy output method suitable for the split-phase power grid based on the claims 1-6: characterized in that the output control method comprises the following steps:

step A1 of configuring three output power lines to be respectively connected with a first live wire, a second live wire and a zero wire of the split-phase power grid;

step A2 of configuring an auxiliary switch element for switching the operation mode of the conversion structure and configuring a switch tube and a filter inductor;

a step a3 of configuring the control unit to control the switching sequence of the switching tube,

and a step A4 of configuring phase differences among the first live wire, the second live wire and the zero wire and voltages among the first live wire, the second live wire and the zero wire when the grid-connected operation mode is performed, and configuring current values of the first live wire and the second live wire when the grid-connected operation mode is performed.

8. The output control method for an isolated phase power grid according to claim 7, wherein the auxiliary switching element comprises a first switching element and a second switching element, wherein,

in the step a2, two ends of the first switch are respectively connected to the first live wire output power line and the second live wire power output line, and the second switch is disposed on the output power line connected to the zero line, so that when the first switch is connected to the single-phase power grid, the first switch is controlled to be closed, and the second switch is controlled to be opened; when the control circuit is connected with the split-phase power grid, the first switch part is controlled to be opened, and the second switch part is controlled to be closed.

9. The output control method suitable for the split-phase power grid according to claim 8, wherein the bridge arm formed by the first live output power line is defined as a first bridge arm, and the bridge arm formed by the second live output power line is defined as a second bridge arm, wherein,

in the step a4, whether a single-phase power grid or a split-phase power grid is connected is judged by sampling, the control unit controls the on/off of the auxiliary switch element, so that the transformation structure is in a single-phase power grid operation mode or a split-phase power grid operation mode, when the transformation structure is in the split-phase power grid operation mode, the transformation structure controls the output current and the phase difference of each phase of the transformation structure when the transformation structure is connected to the grid, and controls the voltage and the phase difference of the output power line when the transformation structure is disconnected from the grid.

10. The output control method for an isolated phase power grid according to claim 7, wherein the step of configuring the phase difference between the first live wire, the second live wire and the neutral wire is to control the output voltage between the first live wire and the second live wire by adjusting the phase difference between the first live wire and the neutral wire and the phase difference between the second live wire and the neutral wire within a preset range.

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