JP7236639B2 - Power conversion system, power supply method, and program - Google Patents

Description

TECHNICAL FIELD The present disclosure generally relates to power conversion systems, power supply methods, and programs. More specifically, the present disclosure relates to a power conversion system, a power supply method, and a program that supply operating power to at least part of the power conversion system.

Patent Literature 1 discloses a photovoltaic power generation system (power conversion system) that supplies electric power to electric appliances using the DC output of a photovoltaic power generation device. In this photovoltaic power generation system, a solar cell array and a battery are connected in parallel to an inverter (power converter). The inverter converts DC power from the solar cell array or battery into AC power, and outputs the AC power to the power grid via the interconnection switch.

JP-A-9-91049

An object of the present disclosure is to provide a power conversion system, a power supply method, and a program capable of stabilizing the supply of operating power to at least part of the power conversion system.

A power conversion system according to an aspect of the present disclosure includes a power conversion section, a first power supply section, a second power supply section, a supply section, and a variable section. The power converter converts power input from the primary side into predetermined power and outputs the power from the secondary side. The first power supply unit generates and outputs a first voltage based on power input to the primary side of the power conversion unit. The second power supply unit generates and outputs a second voltage based on the power output from the secondary side of the power conversion unit. The supply unit supplies the larger one of the first voltage and the second voltage to at least part of the power conversion system as an operating voltage. The variable section changes the magnitude of at least one of the first voltage and the second voltage. The variable section changes the magnitude of at least one of the first voltage and the second voltage according to a determination condition. The secondary side of the power converter is connected to a power system. The determination condition is a condition that interconnected operation is performed with the power system. The variable section is configured such that the supply section supplies the first voltage when the determination condition is satisfied, and the supply section supplies the second voltage otherwise. The magnitude of at least one of the two voltages is changed.

A power supply method according to an aspect of the present disclosure is a power supply method for at least part of a power conversion system. The power conversion system includes a power conversion section, a first power supply section, and a second power supply section. The power converter converts power input from the primary side into predetermined power and outputs the power from the secondary side. The first power supply unit generates and outputs a first voltage based on power input to the primary side of the power conversion unit. The second power supply unit generates and outputs a second voltage based on the power output from the secondary side of the power conversion unit. The power supply method has a supply step and a variable step. The supplying step is a step of supplying the larger one of the first voltage and the second voltage to at least part of the power conversion system as an operating voltage. The varying step is a step of varying the magnitude of at least one of the first voltage and the second voltage. In the variable step, the magnitude of at least one of the first voltage and the second voltage is changed according to a determination condition. The secondary side of the power converter is connected to a power system. The determination condition is a condition that interconnected operation is performed with the power system. In the variable step, the first voltage is supplied in the supply step when the determination condition is satisfied, and the second voltage is supplied in the supply step otherwise. The magnitude of at least one of the two voltages is changed.

A program according to an aspect of the present disclosure causes one or more processors to execute the power supply method described above.

The present disclosure has the advantage of stabilizing the supply of power for operation to at least part of the power conversion system.

FIG. 1 is a schematic circuit diagram showing main parts of a power conversion system according to an embodiment of the present disclosure. FIG. 2 is a schematic circuit diagram showing the same power conversion system. FIG. 3 is an explanatory diagram of the operation of the power conversion system same as above. FIG. 4 is a schematic circuit diagram showing another configuration of the supply unit in the power conversion system;

(1) Outline As shown in FIGS. 1 and 2, the power conversion system 100 of the present embodiment is a system that interconnects a distributed power source 1 with a single-phase three-wire power system SY1. The “power system” referred to in the present disclosure means the entire system for an electric power company such as an electric power company to supply electric power to power receiving facilities of consumers. In this embodiment, as an example, a case where such a power conversion system 100 is introduced into non-residential facilities such as office buildings, hospitals, commercial facilities, and schools will be described.

As shown in FIGS. 1 and 2, the power conversion system 100 includes a power conversion section 3, a first power supply section 21, a second power supply section 22, a supply section 23, and a variable section 24. . In FIG. 2, illustration of the first power supply section 21, the second power supply section 22, the supply section 23, and the variable section 24 is omitted.

The power converter 3 converts the power input from the primary side A1 into predetermined power and outputs the power from the secondary side A2. The “primary side” referred to in the present disclosure is a portion connected to the power converter 3 and is the side to which power from the distributed power source 1 is input as viewed from the power converter 3 . Further, the “secondary side” referred to in the present disclosure is a portion connected to the power conversion unit 3 and is a side that outputs power to the power system SY1 as seen from the power conversion unit 3 . In the following description, even when power is input from the power system SY1 to the power converter 3, the definitions of the "primary side" and the "secondary side" are applied. "Connecting" as used in the present disclosure includes mechanically connecting elements such as terminals, electronic components, or electric wires, as well as electrically connecting elements to each other.

The first power supply section 21 generates and outputs a first voltage V1 based on the power input to the primary side A1 of the power conversion section 3 . In this embodiment, the first power supply unit 21 converts the input voltage from the distributed power supply 1 to the power conversion unit 3 into a predetermined voltage to generate the first voltage V1.

The second power supply section 22 generates and outputs the second voltage V2 based on the power output from the secondary side A2 of the power conversion section 3 . In this embodiment, the second power supply unit 22 generates the second voltage V2 by converting the output voltage from the power conversion unit 3 to the power system SY1 or the isolated system SY2 into a predetermined voltage.

The supply unit 23 supplies the larger one of the first voltage V1 and the second voltage V2 to at least part of the power conversion system 100 as an operating voltage. A “part of the power conversion system” as used in the present disclosure refers to a part of a plurality of components (including circuits) that configure the power conversion system 100 . Below, the control unit 10 will be described as part of the power conversion system 100 . That is, the control unit 10 is supplied with either the first voltage V1 or the second voltage V2 from the supply unit 23 to generate power for operation and operate.

The variable section 24 changes the magnitude of at least one of the first voltage V1 and the second voltage V2. In this embodiment, the variable section 24 is configured to change the magnitude of the second voltage V2 by controlling the second power supply section 22 .

As described above, in the present embodiment, the variable section 24 can change the magnitude of at least one of the first voltage V1 and the second voltage V2. Therefore, in the present embodiment, it is controlled whether power for operation is supplied from either the first power supply unit 21 or the second power supply unit 22 according to the situation in which the power conversion system 100 is placed. can do. Therefore, in this embodiment, there is an advantage that it is possible to stabilize the supply of power for operation to at least part of the power conversion system 100 (here, the control unit 10).

(2) Details The power conversion system 100 according to the present embodiment, as shown in FIG. (Variable section 24). The power conversion system 100 further includes an input capacitor C0, a rectifying element D1, a DC/DC converter 2, a parallel-off relay 5, and an isolation relay 6, as shown in FIG. The power conversion unit 3 , first power supply unit 21 , second power supply unit 22 , supply unit 23 , and control unit 10 are all housed in one housing 101 . The input capacitor C0, the rectifying element D1, the DC/DC converter 2, the parallel-off relay 5, and the isolation relay 6 are also housed in the housing 101. As shown in FIG.

A distributed power source 1 is connected to the power conversion system 100 as shown in FIG. In this embodiment, the distributed power source 1 is a photovoltaic power generation device including solar cells. Furthermore, as shown in FIG. 2, a storage battery B1 is connected to the power conversion system 100 via a charging/discharging circuit B2. Storage battery B<b>1 and charging/discharging circuit B<b>2 are connected in parallel with distributed power source 1 to power conversion system 100 . In the following description, the distributed power supply 1, the storage battery B1, and the charge/discharge circuit B2 are all not included in the components of the power conversion system 100, but some or all of them are included in the components of the power conversion system 100. may be included.

The input capacitor C0 is connected between the distributed power source 1 and the DC/DC converter 2, as shown in FIG. A first electrode 13 of the input capacitor C0 is connected to the positive electrode 11 of the distributed power supply 1 and the high-potential input terminal of the DC/DC converter 2 . A second electrode 14 of the input capacitor C0 is connected to the negative electrode 12 of the distributed power supply 1 and the low potential input end of the DC/DC converter 2 . The input capacitor C0 has a function of stabilizing the DC voltage output from the distributed power supply 1. FIG.

The DC/DC converter 2 is a non-insulated step-up DC/DC converter, and includes an inductor L0, a diode D0, and a switching element Q0, as shown in FIG. A first end of the inductor L0 is connected to the high-potential input end of the DC/DC converter 2 and to the first electrode 13 of the input capacitor C0. A second end of inductor L0 is connected to the anode of diode D0. The cathode of the diode D0 is connected to the high-potential output end of the DC/DC converter 2 and to the first electrode 15 of the output capacitor C1.

The switching element Q0 consists of an enhancement-type n-channel MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor). The source of the switching element Q0 is connected to the low potential input terminal and output terminal of the DC/DC converter 2, and is connected to the second electrode 14 of the input capacitor C0. A drain of the switching element Q0 is connected to a connection point between the second end of the inductor L0 and the anode of the diode D0. The switching element Q0 is turned on/off by a control signal S0 provided from the control section 10. FIG. The switching element Q0 is not limited to a MOSFET, and may be, for example, an IGBT (Insulated Gate Bipolar Transistor) or another semiconductor switching element such as a bipolar transistor.

The DC/DC converter 2 can boost the voltage across the input capacitor C0 by PWM (Pulse Width Modulation) control of the switching element Q0 by the control unit 10 . Specifically, the control unit 10 boosts the voltage across the input capacitor C0 by controlling the switching of the switching element Q0, and outputs the boosted DC voltage to the output capacitor C1 and the inverter 31.

The anode of the rectifying element D1 is connected to the second electrode 16 of the output capacitor C1 and the low potential input terminal of the inverter 31, as shown in FIG. The cathode of the rectifying element D1 is connected to the low-potential input terminal of the DC/DC converter 2, and is connected to the source of the switching element Q0. The rectifying element D1 prevents current from flowing from the negative electrode 12 of the distributed power supply 1 toward the output capacitor C1.

The power converter 3 has a function of converting power (DC power) input from the primary side A1 into predetermined power (AC power) and outputting it from the secondary side A2. In this embodiment, the power converter 3 includes an output capacitor C1, an inverter 31, and a noise filter 4, as shown in FIGS. Therefore, the primary side A1 of the power conversion unit 3 includes circuits closer to the distributed power source 1 and the storage battery B1 than the output capacitor C1. In other words, the primary side A1 of the power converter 3 is connected to the storage battery B1. Further, the secondary side A2 of the power converter 3 includes circuits on the side of the power system SY1 and the isolated system SY2 rather than the noise filter 4 . In other words, the secondary side A2 of the power converter 3 is connected to the power system SY1.

The inverter 31, as shown in FIGS. 1 and 2, has four switching elements Q1 to Q4 connected in a full bridge. The switching elements Q1 to Q4 are all depletion-type n-channel MOSFETs. The switching elements Q1 to Q4 are not limited to MOSFETs, and may be other semiconductor switching elements such as IGBTs or bipolar transistors.

In the inverter 31, a series circuit of the switching elements Q1 and Q3 and a series circuit of the switching elements Q2 and Q4 are connected in parallel across the output capacitor C1. The drains of the switching elements Q1 and Q2 are connected to the high-potential output end of the DC/DC converter 2 and the first electrode 15 of the output capacitor C1. The sources of the switching elements Q3 and Q4 are both connected to the low-potential output end of the DC/DC converter 2 and the second electrode 16 of the output capacitor C1.

A connection point (first connection point) between the source of the switching element Q1 and the drain of the switching element Q3 is connected to the electric power system SY1 via the inductor L11 of the noise filter 4 and the first contact portion 51 of the parallel-off relay 5. ing. The first connection point is also connected to the isolated system SY2 via the inductor L11 of the noise filter 4 and the first contact portion 61 of the isolated relay 6 . A connection point (second connection point) between the source of the switching element Q2 and the drain of the switching element Q4 is connected to the electric power system SY1 via the inductor L12 of the noise filter 4 and the second contact portion 52 of the parallel-off relay 5. ing. The second connection point is also connected to the isolated system SY2 via the inductor L12 of the noise filter 4 and the second contact portion 62 of the isolated relay 6 .

Inverter 31 is a bidirectional DC/AC converter. The inverter 31 performs PWM control of the switching elements Q1 to Q4 by the control unit 10 to convert the DC voltage to the AC voltage or the AC voltage to the DC voltage. That is, the inverter 31 has a function of converting the DC power from the output capacitor C1 into AC power and outputting it to the power system SY1, and a function of converting the AC power from the power system SY1 into DC power and outputting it to the output capacitor C1. and have Further, the inverter 31 has a function of converting the DC power from the output capacitor C1 into AC power and outputting it to the isolated system SY2 when the parallel-off relay 5 is opened and the isolated relay 6 is closed.

The noise filter 4 has two inductors L11 and L12 and a capacitor C2, as shown in FIGS. A first end of the inductor L11 is connected to a connection point (first connection point) between the source of the switching element Q1 and the drain of the switching element Q3. A second end of the inductor L11 is connected to the first contact portion 51 of the parallel-off relay 5 and the first contact portion 61 of the isolation relay 6 . A first end of the inductor L12 is connected to a connection point (second connection point) between the source of the switching element Q2 and the drain of the switching element Q4. A second end of the inductor L12 is connected to the second contact portion 52 of the parallel-off relay 5 and the second contact portion 62 of the isolation relay 6 . A capacitor C2 is connected between the second end of the inductor L11 and the second end of the inductor L12. The noise filter 4 has a function of removing high-frequency components from the AC voltage output from the inverter 31 and generating a sinusoidal voltage.

The parallel-off relay 5 includes a first contact portion 51 and a second contact portion 52, as shown in FIGS. The first contact portion 51 and the second contact portion 52 are turned on or off at the same time by a control signal S10 given from the control portion 10 . The parallel-off relay 5 parallels the inverter 31 to the power system SY1 when the first contact portion 51 and the second contact portion 52 are turned on at the same time, and disconnects the inverter 31 from the power system SY1 when they are turned off at the same time.

The self-sustaining relay 6 includes a first contact portion 61 and a second contact portion 62, as shown in FIGS. The first contact portion 61 and the second contact portion 62 are turned on or off at the same time by a control signal S20 given from the control portion 10 . The isolation relay 6 parallels the inverter 31 to the isolation system SY2 when the first contact portion 61 and the second contact portion 62 are turned on at the same time, and disconnects the inverter 31 from the isolation system SY2 when they are turned off at the same time.

The control unit 10 is composed of, for example, a microcontroller having one or more processors and memory. In other words, the control unit 10 is realized by a computer system having one or more processors and memory, and the computer system functions as the control unit 10 by executing a program stored in the memory by the one or more processors. Function. Although the program is pre-recorded in the memory of the control unit 10 here, it may be provided through an electric communication line such as the Internet or recorded in a non-temporary recording medium such as a memory card. The control unit 10 may be configured by, for example, an FPGA (Field-Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit).

The control unit 10 outputs control signals S0-S4 for controlling the five switching elements Q0-Q4. The control signals S0-S4 are applied to the gates of the switching elements Q0-Q4 either directly or through a drive circuit to individually turn on/off the switching elements Q0-Q4. The control unit 10 controls the switching elements Q0 to Q4 by a PWM method with an adjustable duty ratio.

Further, the control unit 10 outputs a control signal S10 for controlling on/off of the first contact portion 51 and the second contact portion 52 of the parallel-off relay 5, the first contact portion 61 and the second contact portion 61 of the self-sustaining relay 6. A control signal S20 for controlling the on/off of the unit 62 is output. The control unit 10 causes the parallel-off relay 5 to be paralleled off from the power system SY1 and parallels the isolation relay 6 to the isolation system SY2 in the event of an abnormality such as a power failure in the power system SY1. Then, the control unit 10 controls the DC/DC converter 2 and the inverter 31 so as to perform self-sustained operation in which AC power is output from the inverter 31 to the self-sustained system SY2 when there is an abnormality in the power system SY1.

The first power supply unit 21 generates and outputs a first voltage V1 based on the power input to the primary side A1 of the power conversion unit 3, as shown in FIG. The first voltage V1 is, for example, twenty-odd [V]. In the present embodiment, the first power supply unit 21 is, for example, an insulated DC/DC converter, and steps down the input voltage input to the output capacitor C1 (that is, the input voltage from the distributed power supply 1 or the storage battery B1). Then, the stepped-down voltage is output to the supply unit 23 as the first voltage V1.

The second power supply section 22 generates and outputs a second voltage V2 based on the power input to the secondary side A2 of the power conversion section 3 . The second voltage V2 is, for example, twenty-odd [V]. In the present embodiment, the second power supply unit 22 is, for example, an insulated AC/DC converter, and converts the voltage input to the power system SY1 side of the parallel-off relay 5 (that is, the phase voltage of the power system SY1) into a DC voltage. The voltage is converted into a voltage, and the converted DC voltage is output to the supply unit 23 as the second voltage V2.

The supply unit 23 supplies operating power (operating voltage) to the control unit 10 . In this embodiment, the supply section 23 has a first diode 231 and a second diode 232, as shown in FIG. The anode of the first diode 231 is connected to the high-potential output end of the first power supply section 21 . The anode of the second diode 232 is connected to the high-potential output end of the second power supply section 22 . Both the cathode of the first diode 231 and the cathode of the second diode 232 are connected to the connection point 233 . The connection point 233 is connected to a high-potential power terminal of the control unit 10 .

In the supply section 23, when the first voltage V1 is greater than the second voltage V2, the first diode 231 becomes conductive and the second diode 232 becomes non-conductive. In this case, the control unit 10 is supplied with the first voltage V1 from the first power supply unit 21 through the first diode 231 . On the other hand, when the second voltage V2 is greater than the first voltage V1, the second diode 232 conducts and the first diode 231 does not conduct. In this case, the control unit 10 is supplied with the second voltage V2 from the second power supply unit 22 via the second diode 232 . That is, the supply unit 23 supplies the larger one of the first voltage V1 and the second voltage V2 to the control unit 10 (that is, at least part of the power conversion system 100) as the operating voltage.

Due to the design of the first power supply section 21 and the second power supply section 22, the designed voltage value of the first voltage V1 and the designed voltage value of the second voltage V2 may be the same. However, even in this case, since a difference occurs between the first voltage V1 and the second voltage V2 in actual operation, either the first voltage V1 or the second voltage V2 is supplied to the control section 10. will be

The variable section 24 is configured to change the magnitude of at least one of the first voltage V1 and the second voltage V2. In this embodiment, the variable section 24 can change the magnitude of the second voltage V2 by controlling the second power supply section 22 . For example, assume that the second power supply section 22 generates the second voltage V2 by PWM-controlling the switching element. In this case, the variable section 24 changes the magnitude of the second voltage V2 by giving the control signal S30 to the switching element of the second power supply section 22 to change the duty ratio. In this embodiment, the variable section 24 is implemented as one of the functions of the control section 10 .

Here, the supply unit 23 is configured to supply the larger one of the first voltage V1 and the second voltage V2 to the control unit 10 . For this reason, it is preferable to prevent the first voltage V1 and the second voltage V2 from having the same voltage value so that the supply source of the operating power supplied from the supply unit 23 does not become unstable. Therefore, in the present embodiment, the variable section 24 adjusts at least one of the first voltage V1 and the second voltage V2 (here, , the magnitude of the second voltage V2). Accordingly, in this embodiment, the first voltage V1 and the second voltage V2 are prevented from having the same voltage value.

In this embodiment, the variable section 24 changes the magnitude of at least one of the first voltage V1 and the second voltage V2 (here, the second voltage V2) according to the determination condition. As an example, the determination condition is a condition that interconnected operation with power system SY1 is performed. The grid-connected operation refers to operation in which the first contact portion 51 and the second contact portion 52 of the parallel-off relay 5 are turned on at the same time, and the inverter 31 is connected in parallel with the power system SY1. Grid-connected operation may include reverse power flow. Then, the variable unit 24 sets the first voltage V1 and the second voltage V1 so that the supply unit 23 supplies the first voltage V1 when the determination condition is satisfied, and the supply unit 23 supplies the second voltage V2 otherwise. The magnitude of at least one of the two voltages V2 (here, the second voltage V2) is changed.

That is, the variable unit 24 reduces the second voltage V2 by controlling the second power supply unit 22 during the grid-connected operation so that the second voltage V2 becomes lower than the first voltage V1. On the other hand, the variable unit 24 adjusts the second voltage V2 so that the second voltage V2 is higher than the first voltage V1 by controlling the second power supply unit 22 during the period in which the grid-connected operation is not performed. raise the pressure.

(3) Operation First, the basic operation of the power conversion system 100 of this embodiment will be described with reference to FIG. When the distributed power supply 1 receives sufficient sunlight and generates power, such as during the daytime, the distributed power supply 1 outputs DC power to the inverter 31 via the DC/DC converter 2 . Inverter 31 converts the input DC power into AC power, and outputs the converted AC power to power system SY1. As a result, the power generated by the distributed power supply 1 is supplied to the load connected to the power system SY1. In addition, when there is surplus power in the power generated by the distributed power source 1, the distributed power source 1 charges the storage battery B1 by outputting the surplus power to the storage battery B1 via the DC/DC converter 2 and the charging/discharging circuit B2. do. Alternatively, the storage battery B1 may be charged by the power system SY1 outputting DC power to the storage battery B1 via the inverter 31 and the charging/discharging circuit B2.

On the other hand, when the distributed power supply 1 cannot receive sufficient sunlight and does not generate power, such as when the weather is cloudy, rainy, or at night, the storage battery B1 supplies DC power to the inverter 31 via the charging/discharging circuit B2. to output Inverter 31 converts the input DC power into AC power, and outputs the converted AC power to power system SY1. As a result, the power discharged by storage battery B1 is supplied to the load connected to power system SY1.

Further, when an abnormality such as a power outage in the power system SY1 occurs in the power system SY1, the control unit 10 disconnects the parallel-off relay 5 from the power system SY1 and parallels the isolation relay 6 to the isolation system SY2. Self-sustaining operation is performed by

Next, an example of the operation of supplying operating power to the control unit 10 in the power conversion system 100 of this embodiment will be described with reference to FIG. In the example shown in FIG. 3, it is assumed that the first voltage V1 output by the first power supply section 21 is constant regardless of the passage of time. The first period T1 is a period during which the first voltage V1 is higher than the second voltage V2 and the first voltage V1 is supplied from the supply section 23 to the control section 10 . Also, the second period T2 is a period during which the second voltage V2 is higher than the first voltage V1 and the second voltage V2 is supplied from the supply section 23 to the control section 10 .

Between time 0 and time t1, the power conversion system 100 is in interconnected operation. Therefore, since the determination condition is satisfied, the variable section 24 steps down the second voltage V2 so that the second voltage V2 becomes lower than the first voltage V1. Therefore, between time 0 and time t1, the supply unit 23 supplies the control unit 10 with the first voltage V1 as the operating voltage. Note that if the second voltage V2 is always lower than the first voltage V1 between time 0 and time t1, the variable section 24 does not need to step down the second voltage V2.

Between time t1 and time t2, the power conversion system 100 does not perform grid-connected operation. Therefore, since the determination condition is not satisfied, the variable section 24 boosts the second voltage V2 so that the second voltage V2 becomes higher than the first voltage V1. Therefore, between time t1 and time t2, the second voltage V2 is supplied from the supply unit 23 to the control unit 10 as an operating voltage.

After time t2, the power system SY1 is out of power, so the phase voltage of the power system SY1 is not input to the second power supply unit 22, and the second voltage V2 becomes zero. Therefore, since the first voltage V1 becomes higher than the second voltage V2 after time t2, the first voltage V1 is supplied from the supply unit 23 to the control unit 10 as a voltage for operation.

Advantages of the power conversion system 100 of the present embodiment will be described below in comparison with the power conversion system of the comparative example. The power conversion system of the comparative example differs from the power conversion system 100 of the present embodiment in that the variable section 24 is not provided. In the power conversion system of the comparative example, it is not possible to control which power supply unit among the first power supply unit 21 and the second power supply unit 22 supplies power for operation to the control unit 10, There is a problem that it is difficult to stabilize the supply of power for operation.

For example, in the power conversion system of the comparative example, the first power supply unit 21 is designed so that the first voltage V1 is constant at α [V], and the second voltage V2 is in the range of α±β [V]. Assume that the second power supply section 22 is designed to accommodate. In this case, the second voltage V2 fluctuates depending on the situation in which the power conversion system of the comparative example is placed. and the second voltage V2. Therefore, for example, the second voltage V2 (that is, the phase voltage of the power system SY1) can be supplied to the control unit 10 even during the period when the power conversion system of the comparative example is performing grid-connected operation. In this case, distortion may occur in the current waveform output from power system SY1.

To solve the above problem, the first power supply section 21 must be designed so that the first voltage V1 is always higher than the second voltage V2. Power for operation is supplied from the power supply unit 21 . Therefore, in this case, for example, if the power conversion system of the comparative example includes the storage battery B1, the energy accumulated in the storage battery B1 is used for the operation of the control unit 10 even during periods such as nighttime when grid-connected operation is not performed. A problem may occur that the power is unnecessarily consumed.

On the other hand, in the power conversion system 100 of the present embodiment, the magnitude of at least one of the first voltage V1 and the second voltage V2 can be changed by the variable section 24 . Therefore, in the present embodiment, it is controlled whether power for operation is supplied from either the first power supply unit 21 or the second power supply unit 22 according to the situation in which the power conversion system 100 is placed. can do.

For example, as described above, during the period when the power conversion system 100 is performing grid-connected operation, if the second voltage V2 is changed by the variable unit 24 so as to be lower than the first voltage V1, this period , the first voltage V1 is always supplied to the control unit 10. In this case, since the phase voltage of power system SY1 is not supplied to control unit 10, it is possible to reduce the possibility that the current waveform output from power system SY1 is distorted.

Further, for example, during a period in which the power conversion system 100 is not performing grid-connected operation, if the second voltage V2 is changed by the variable unit 24 so as to be higher than the first voltage V1, the second voltage V2 The voltage V2 is supplied to the control section 10. FIG. Therefore, in this case, the energy accumulated in the storage battery B1 is not unnecessarily consumed as electric power for the operation of the control unit 10 during periods such as nighttime when grid-connected operation is not performed.

As described above, the present embodiment has the advantage of stabilizing the supply of operating power to at least part of the power conversion system 100 (here, the control unit 10).

In this embodiment, the supply unit 23 is configured to supply the higher voltage of the first voltage V1 and the second voltage V2 as the operating voltage. Therefore, in the present embodiment, even if one of the first power supply unit 21 and the second power supply unit 22 stops, the voltage from the other power supply unit is automatically supplied as the operating voltage. Therefore, it is possible to stably continue to supply power for operation.

(4) Modifications The embodiment described above is just one of various embodiments of the present disclosure. The above-described embodiments can be modified in various ways according to design and the like as long as the object of the present disclosure can be achieved. Also, functions similar to those of the power conversion system 100 may be embodied by a test method, a (computer) program, or a non-temporary recording medium recording the program.

A power supply method according to one aspect is a power supply method for at least part of the power conversion system 100 . The power conversion system 100 includes a power conversion section 3 , a first power supply section 21 and a second power supply section 22 . The power converter 3 converts the power input from the primary side A1 into predetermined power and outputs the power from the secondary side A2. The first power supply section 21 generates and outputs a first voltage V1 based on the power input to the primary side A1 of the power conversion section 3 . The second power supply section 22 generates and outputs the second voltage V2 based on the power output from the secondary side A2 of the power conversion section 3 . The power supply method has a supply step and a variable step. The supply step is a step of supplying the larger one of the first voltage V1 and the second voltage V2 to at least part of the power conversion system 100 (for example, the control unit 10) as an operating voltage. A variable step is a step of changing the magnitude of at least one of the first voltage V1 and the second voltage V2. A program according to one aspect causes one or more processors to execute the power supply method described above.

Modifications of the above-described embodiment are listed below. Modifications described below can be applied in combination as appropriate.

The power conversion system 100 in the present disclosure includes a computer system in the control unit 10, for example. A computer system is mainly composed of a processor and a memory as hardware. The function of the control unit 10 in the present disclosure is realized by the processor executing a program recorded in the memory of the computer system. The program may be recorded in advance in the memory of the computer system, may be provided through an electric communication line, or may be recorded in a non-temporary recording medium such as a computer system-readable memory card, optical disk, or hard disk drive. may be provided. A processor in a computer system consists of one or more electronic circuits, including semiconductor integrated circuits (ICs) or large scale integrated circuits (LSIs). The integrated circuit such as IC or LSI referred to here is called differently depending on the degree of integration, and includes integrated circuits called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). In addition, a field-programmable gate array (FPGA) that is programmed after the LSI is manufactured, or a logic device capable of reconfiguring the bonding relationship inside the LSI or reconfiguring the circuit partitions inside the LSI may also be adopted as the processor. can be done. A plurality of electronic circuits may be integrated into one chip, or may be distributed over a plurality of chips. A plurality of chips may be integrated in one device, or may be distributed in a plurality of devices. A computer system, as used herein, includes a microcontroller having one or more processors and one or more memories. Accordingly, the microcontroller also consists of one or more electronic circuits including semiconductor integrated circuits or large scale integrated circuits.

Further, it is not an essential configuration of the control unit 10 that a plurality of functions of the control unit 10 are integrated into one housing. The constituent elements of the control unit 10 may be distributed over a plurality of housings. Furthermore, at least part of the functions of the control unit 10 may be implemented by, for example, a server device and a cloud (cloud computing). Conversely, all functions of the control unit 10 may be integrated into one housing as in the above-described embodiment.

In the above-described embodiment, the variable section 24 may be configured to vary the magnitude of the first voltage V1 instead of the second voltage V2. Also, the variable section 24 may be configured to vary the magnitude of both the first voltage V1 and the second voltage V2.

In the above-described embodiment, the magnitudes of the first voltage V1 and the second voltage V2 that are changed by the variable section 24 may be set by inputting to an operation section provided in the housing 101, or may be set via a server. may be set by remote input. That is, the magnitude of the voltage that is changed by the variable section 24 between the first voltage V1 and the second voltage V2 may be settable from the outside of the power conversion system 100 .

In the above-described embodiment, the supply unit 23 may be configured as shown in FIG. 4, for example. In the example shown in FIG. 4, the supply unit 23 includes a series circuit of resistors R1 and R2, a series circuit of resistors R3 and R4, a comparator 234, a buffer 235, a NOT circuit 236, and a first switch 237. , and a second switch 238 . The first switch 237 and the second switch 238 are semiconductor switches, for example.

A series circuit of resistors R1 and R2 is configured to divide the first voltage V1 and input the divided voltage to the non-inverting input terminal (“+” terminal) of the comparator 234 . A series circuit of resistors R3 and R4 is configured to divide the second voltage V2 and input the divided voltage to the inverting input terminal (“−” terminal) of the comparator 234 . Here, the voltage division ratio of the series circuit of the resistors R1 and R2 is the same as the voltage division ratio of the series circuit of the resistors R3 and R4. Therefore, the comparator 234 essentially compares the first voltage V1 and the second voltage V2.

An output terminal of the comparator 234 is connected to the first switch 237 via the buffer 235 . Also, the output terminal of the comparator 234 is connected to the second switch 238 via the NOT circuit 236 . The first switch 237 opens and closes the electric circuit between the first power supply section 21 and the power terminal of the control section 10 . The second switch 238 opens and closes the electric circuit between the second power supply section 22 and the power terminal of the control section 10 .

In the supply section 23 shown in FIG. 4, when the first voltage V1 is higher than the second voltage V2, the first switch 237 is turned on and the second switch 238 is turned off. Therefore, in this case, the electric path between the first power supply section 21 and the power supply terminal of the control section 10 is closed, and the first voltage V1 is supplied to the control section 10 as a voltage for operation. On the other hand, when the second voltage V2 is higher than the first voltage V1, the first switch 237 is turned off and the second switch 238 is turned on. Therefore, in this case, the electric path between the second power supply section 22 and the power supply terminal of the control section 10 is closed, and the second voltage V2 is supplied to the control section 10 as an operating voltage.

In the above-described embodiment, the determination condition is not limited to the condition that grid-connected operation with power system SY1 is performed. For example, the determination condition may be that the charging voltage of storage battery B1 is higher than the threshold voltage. In this case, the variable unit 24 changes the second voltage V2 to be lower than the first voltage V1 if the charging voltage of the storage battery B1 is higher than the threshold voltage, and changes the first voltage V1 if lower than the threshold voltage. The second voltage V2 should be changed so that it becomes greater than . Further, for example, the determination condition may be a condition that surplus power is generated in the dispersed power source 1 .

In the above-described embodiment, the power conversion system 100 may not be connected to the storage battery B1 and the charging/discharging circuit B2.

Although the power conversion system 100 includes the input capacitor C0, the DC/DC converter 2, the output capacitor C1, and the noise filter 4 in the above-described embodiment, some or all of these may be omitted. For example, in the power conversion system 100 , the DC/DC converter 2 does not have to be connected between the distributed power source 1 and the inverter 31 . That is, the power conversion unit 3 may be configured with only the inverter 31 .

In the above-described embodiment, the distributed power source 1 is a photovoltaic power generation device, but it is not intended to be limited to this. For example, the distributed power source 1 may be a storage battery (including a storage battery for electric vehicles) or a power generation device such as a fuel cell. Also, the distributed power source 1 may be a power generator that uses renewable energy other than sunlight, such as wind power, water power, geothermal power, and biomass.

In the above-described embodiments, the power conversion system 100 is not limited to being installed in non-residential facilities, but may be installed in houses, and may be installed in places other than facilities such as electric vehicles.

(summary)
As described above, the power conversion system (100) according to the first aspect includes a power conversion section (3), a first power supply section (21), a second power supply section (22), a supply section (23 ) and a variable part (24). The power converter (3) converts the power input from the primary side (A1) into predetermined power and outputs the power from the secondary side (A2). A first power supply unit (21) generates and outputs a first voltage (V1) based on power input to a primary side (A1) of the power conversion unit (3). A second power supply section (22) generates and outputs a second voltage (V2) based on the power output from the secondary side (A2) of the power conversion section (3). The supply unit (23) applies the larger one of the first voltage (V1) and the second voltage (V2) to at least part of the power conversion system (100) (for example, the control unit (10)). supply voltage for A variable section (24) changes the magnitude of at least one of the first voltage (V1) and the second voltage (V2).

According to this aspect, there is an advantage that the supply of power for operation to at least part of the power conversion system (100) can be stabilized.

In the power conversion system (100) according to the second aspect, in the first aspect, the secondary side (A2) of the power converter (3) is connected to the power system (SY1).

According to this aspect, since the second voltage (V2) can be generated based on the power supplied from the power system (SY1), there is an advantage that the supply of power for operation can be easily stabilized.

In the power conversion system (100) according to the third aspect, in the first or second aspect, the variable section selects at least one of the first voltage (V1) and the second voltage (V2) according to the determination condition. Vary the magnitude of the voltage.

According to this aspect, there is an advantage that it is easy to stabilize the supply of power for operation according to the situation in which the power conversion system (100) is placed.

In the power conversion system (100) according to the fourth aspect, in the third aspect, the secondary side (A2) of the power converter (3) is connected to the power system (SY1). The determination condition is a condition that interconnected operation with the power system (SY1) is performed. The variable section (24) is configured so that the supply section (23) supplies the first voltage (V1) when the determination condition is satisfied, and the supply section (23) supplies the second voltage (V2) otherwise. Also, the magnitude of at least one of the first voltage (V1) and the second voltage (V2) is changed.

According to this aspect, since the power for operation is not supplied from the power system (SY1) during the grid-connected operation, there is an advantage that the distortion of the waveform of the output current of the power converter (3) can be easily suppressed.

In the power conversion system (100) according to the fifth aspect, in any one of the first to fourth aspects, the primary side (A1) of the power converter (3) is connected to the storage battery (B1).

According to this aspect, even if a power failure occurs, the first voltage (V1) can be generated based on the power supplied from the storage battery (B1), so it is easy to stabilize the supply of power for operation. There is an advantage.

In the power conversion system (100) according to the sixth aspect, in any one of the first to fifth aspects, the variable section (24) has both the first voltage (V1) and the second voltage (V2) change the size of

According to this aspect, it is possible to improve the degree of freedom in setting which of the first power supply section (21) and the second power supply section (22) is preferentially used as the power supply source for operation. There is an advantage.

In the power conversion system (100) according to the seventh aspect, in any one of the first to sixth aspects, one of the first voltage (V1) and the second voltage (V2) is changed by the variable section (24) The magnitude of the voltage can be set from outside the power conversion system (100).

According to this aspect, the advantage is that the magnitude of at least one of the first voltage (V1) and the second voltage (V2) can be changed without going to the installation location of the power conversion system (100). There is

In the power conversion system (100) according to the eighth aspect, in any one of the first to seventh aspects, the variable section (24) is configured such that the difference between the first voltage (V1) and the second voltage (V2) is The magnitude of at least one of the first voltage (V1) and the second voltage (V2) is changed so as to be equal to or higher than a predetermined value.

According to this aspect, there is an advantage that it is difficult to determine whether the voltage supplied from the supply section (23) is the first voltage (V1) or the second voltage (V2).

A power supply method according to a ninth aspect is a power supply method for at least part of a power conversion system (100). A power conversion system (100) includes a power conversion section (3), a first power supply section (21), and a second power supply section (22). The power converter (3) converts the power input from the primary side (A1) into predetermined power and outputs the power from the secondary side (A2). A first power supply unit (21) generates and outputs a first voltage (V1) based on power input to a primary side (A1) of the power conversion unit (3). A second power supply section (22) generates and outputs a second voltage (V2) based on the power output from the secondary side (A2) of the power conversion section (3). The power supply method has a supply step and a variable step. In the supplying step, the larger one of the first voltage (V1) and the second voltage (V2) is supplied to at least part of the power conversion system (100) (for example, the control unit (10)) as an operating voltage. It is a step of supplying as A variable step is a step of changing the magnitude of at least one of the first voltage (V1) and the second voltage (V2).

According to this aspect, there is an advantage that the supply of power for operation to at least part of the power conversion system (100) can be stabilized.

A program according to a tenth aspect causes one or more processors to execute the power supply method according to the ninth aspect.

According to this aspect, there is an advantage that the supply of power for operation to at least part of the power conversion system (100) can be stabilized.

The configurations according to the second to eighth aspects are not essential configurations for the power conversion system (100), and can be omitted as appropriate.

21 first power supply unit 22 second power supply unit 23 supply unit 24 variable unit 3 power conversion unit 100 power conversion system A1 primary side A2 secondary side B1 storage battery SY1 power system V1 first voltage V2 second voltage

Claims (7)

a power conversion unit that converts power input from the primary side into predetermined power and outputs the power from the secondary side;
a first power supply unit that generates and outputs a first voltage based on the power input to the primary side of the power conversion unit;
a second power supply section that generates and outputs a second voltage based on the power output from the secondary side of the power conversion section;
a supply unit that supplies the larger one of the first voltage and the second voltage to at least part of a power conversion system as an operating voltage;
a variable unit that changes the magnitude of at least one of the first voltage and the second voltage ,
The variable unit changes the magnitude of at least one of the first voltage and the second voltage according to a determination condition,
The secondary side of the power conversion unit is connected to a power system.
The determination condition is a condition that interconnected operation is performed with the power system,
The variable section is configured such that the supply section supplies the first voltage when the determination condition is satisfied, and the supply section supplies the second voltage otherwise. changing the magnitude of at least one of the two voltages,
power conversion system. A storage battery is connected to the primary side of the power conversion unit,
The power conversion system according to claim 1. The variable section changes the magnitude of both the first voltage and the second voltage,
The power conversion system according to claim 1 or 2. The magnitude of the voltage changed by the variable unit of the first voltage and the second voltage can be set from the outside of the power conversion system.
The power conversion system according to any one of claims 1 to 3. The variable section changes the magnitude of at least one of the first voltage and the second voltage such that a difference between the first voltage and the second voltage is equal to or greater than a predetermined value.
The power conversion system according to any one of claims 1-4. a power conversion unit that converts power input from the primary side into predetermined power and outputs the power from the secondary side;
a first power supply unit that generates and outputs a first voltage based on the power input to the primary side of the power conversion unit;
and a second power supply section that generates and outputs a second voltage based on the power output from the secondary side of the power conversion section, wherein the power is supplied to at least a part of the power conversion system. A method of supply,
a supply step of supplying the larger one of the first voltage and the second voltage to at least part of the power conversion system as an operating voltage;
a variable step of changing the magnitude of at least one of the first voltage and the second voltage;
In the variable step, the magnitude of at least one of the first voltage and the second voltage is changed according to a determination condition;
The secondary side of the power conversion unit is connected to a power system.
The determination condition is a condition that interconnected operation is performed with the power system,
In the variable step, the first voltage is supplied in the supply step when the determination condition is satisfied, and the second voltage is supplied in the supply step otherwise. changing the magnitude of at least one of the two voltages,
Power delivery method. to one or more processors;
executing the power supply method according to claim 6,
program.

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