JP7117493B2 - Grid-connected system - Google Patents

Description

TECHNICAL FIELD This disclosure relates generally to grid-connected systems, and more particularly to grid-connected systems that connect distributed power sources to a power grid.

2. Description of the Related Art Conventionally, a photovoltaic power generation system (grid interconnection system) that supplies electric power to electric appliances using a direct current output of a photovoltaic power generation device is known. In the photovoltaic power generation system described in Patent Document 1, a solar cell array (distributed power source) and a battery (storage battery) are connected in parallel to an inverter. 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

In the grid interconnection system described in Patent Document 1, when the DC power from the storage battery is converted to AC power by the inverter while the distributed power supply is not generating power, the ground voltage is applied to the electrodes of the distributed power supply. There was a possibility that the problem of

This indication is made in view of the above-mentioned point, and an object of this indication is to provide the grid interconnection system which is hard to apply ground voltage to the electrode of distributed power supply.

A grid interconnection system according to one aspect of the present disclosure includes an inverter , a storage battery, a backflow blocking diode, and a switch . The inverter is connected between the distributed power source and the power system. The storage battery is connected in parallel with the distributed power source. A current path on the distributed power supply side when viewed from the inverter includes a first path and a second path. The first path includes a positive electrode of the distributed power supply. The second path includes a negative terminal of a local power supply. The storage battery is connected in the current path to a first connection point of the first path and a second connection point of the second path. The inverter is configured to convert DC power from the distributed power source and the storage battery into AC power. The backflow blocking diode is provided closer to the distributed power source than the second connection point in the second path of the current path . The backflow blocking diode blocks leakage current from flowing to the distributed power supply through the second path . The switch is connected in parallel with the backflow blocking diode. The switch is controlled to be always on when the distributed power supply is interconnected with the electric power system, and to be off at other times.
A grid interconnection system according to one aspect of the present disclosure includes an inverter , a storage battery, a backflow blocking diode, a detection circuit, and a switch . The inverter is connected between the distributed power source and the power system. The storage battery is connected in parallel with the distributed power source. The detection circuit is connected in parallel with the distributed power supply and detects an output voltage of the distributed power supply. A current path on the distributed power supply side when viewed from the inverter includes a first path and a second path. The first path includes a positive electrode of the distributed power supply. The second path includes a negative pole of the distributed power supply. The storage battery is connected in the current path to a first connection point of the first path and a second connection point of the second path. The inverter is configured to convert DC power from the distributed power source and the storage battery into AC power. The backflow blocking diode is housed in a second housing different from the first housing housing the inverter. The backflow blocking diode is provided closer to the distributed power supply than the second connection point in the second path of the current path, and blocks leakage current flowing to the distributed power supply through the second path . The detection circuit is connected to a third connection point and a fourth connection point. The third connection point is closer to the distributed power source than the first connection point in the first path of the current path. The fourth connection point is between the second connection point and the reverse current blocking diode on the second path of the current path. The switch is provided closer to the distributed power source than the third connection point on the first path. The switch is controlled to be turned on when the distributed power supply is interconnected with the power system, and turned off when the distributed power supply is not interconnected with the power system.

The present disclosure has the advantage that it is difficult for a voltage to ground to be applied to the electrodes of the distributed power supply.

FIG. 1 is a schematic circuit diagram showing a grid interconnection system according to one embodiment of the present disclosure. FIG. 2 is an explanatory diagram of the operation of the grid interconnection system of the comparative example. FIG. 3 is an explanatory diagram of the operation of the grid interconnection system according to one embodiment of the present disclosure. 4A and 4B are schematic circuit diagrams each showing a grid interconnection system according to a first modified example of an embodiment of the present disclosure. FIG. 5 is a schematic circuit diagram showing a grid interconnection system according to a second modification of one embodiment of the present disclosure. FIG. 6 is a schematic circuit diagram showing a grid interconnection system according to a third modified example of one embodiment of the present disclosure. 7A and 7B are schematic circuit diagrams each showing a grid interconnection system according to a fourth modification of the embodiment of the present disclosure. FIG. 8 is a schematic circuit diagram showing a grid interconnection system according to a fifth modified example of one embodiment of the present disclosure.

(1) Outline As shown in FIG. 1 , a grid interconnection system 100 of the present embodiment is a system that interconnects a distributed power source 1 with a single-phase three-wire power system 6 . 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 description will be given on the assumption that such a grid interconnection system 100 is introduced into non-residential facilities such as office buildings, hospitals, commercial facilities, and schools.

The grid interconnection system 100 includes an inverter 3 as shown in FIG. The inverter 3 is connected between the distributed power source 1 and the power system 6 and converts DC power from the distributed power source 1 into AC power. "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 grid interconnection system 100 converts the DC power output from the distributed power supply 1 into AC power by the inverter 3 and outputs the converted AC power to the power system 6 . In addition, the grid interconnection system 100 is configured to open the disconnector and perform a self-sustained operation in which AC power is output in a state of being disconnected from the power system 6 when there is an abnormality such as a power outage in the power system 6 . there is

The grid interconnection system 100 further includes a backflow blocking diode D1. The backflow blocking diode D1 is provided in a current path (a first path P1 and a second path P2, which will be described later) including at least part of the circuit on the distributed power supply 1 side when viewed from the inverter 3 . The backflow blocking diode D1 is oriented to block leakage current flowing through the current path to the reference potential Vb1. The “reference potential Vb1” referred to in the present disclosure refers to the potential of the ground when the neutral line of the electric power system 6 is connected to the ground.

As described above, in this embodiment, the leakage current flowing through the current path to the reference potential Vb1 is blocked by the reverse current blocking diode D1. Therefore, in the present embodiment, the ground capacitance (first ground capacitance Ce1 or second ground capacitance Ce2 described later) existing between the electrode (positive electrode 11 or negative electrode 12) of the distributed power supply 1 and the reference potential Vb1 leaks. It is difficult to be charged by electric current. Therefore, in this embodiment, there is an advantage that the charging voltage of the ground capacitance (in other words, ground voltage) is less likely to be applied to the electrodes of the distributed power supply 1 .

(2) Details As shown in FIG. 1, the grid interconnection system 100 according to the present embodiment includes an input capacitor C0 and an output capacitor C1, a DC/DC converter 2, an inverter 3, a filter circuit 4, and a control circuit. 10 and. The input capacitor C0, the output capacitor C1, the DC/DC converter 2, the inverter 3, the filter circuit 4, and the control circuit 10 are housed in one housing (hereinafter also referred to as "first housing") 7.

A distributed power source 1 is connected to the grid interconnection system 100 . In this embodiment, the distributed power source 1 is a photovoltaic power generation device including solar cells. Furthermore, the grid connection system 100 is connected with the storage battery 5 via the charging/discharging circuit 50 . The storage battery 5 and the charging/discharging circuit 50 are connected in parallel with the distributed power supply 1 to the grid interconnection system 100 . In the following description, the distributed power supply 1, the storage battery 5, and the charging/discharging circuit 50 are all not included in the grid interconnection system 100, but some or all of them constitute the grid interconnection system 100. element may be included.

Input capacitor C0 is connected between distributed power source 1 and DC/DC converter 2 . 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 terminal 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.

Output capacitor C1 is connected between DC/DC converter 2 and inverter 3 . A first electrode 15 of the output capacitor C1 is connected to the high potential output end of the DC/DC converter 2 and the high potential input end of the inverter 3 . A second electrode 16 of the output capacitor C1 is connected to the low potential output end of the DC/DC converter 2 and the low potential input end of the inverter 3 . The output capacitor C1 has a function of stabilizing the DC voltage output from the DC/DC converter 2. FIG.

The DC/DC converter 2 is a non-insulated step-up DC/DC converter, and includes an inductor L0, a diode D0, a switching element Q0, and a reverse current blocking diode D1. 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 given from a control circuit 10 (described later). 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 cathode of the reverse blocking diode D1 is connected to the low potential input terminal of the DC/DC converter 2, and is connected to the second electrode 14 of the input capacitor C0 and the source of the switching element Q0. The anode of the reverse current blocking diode D1 is connected to the low potential output terminal of the DC/DC converter 2, and is connected to the second electrode 16 of the output capacitor C1 via the intermediate bus MB. An “intermediate bus” as used in this disclosure is a current path between the DC/DC converter 2 and the inverter 3 .

In the DC/DC converter 2, the switching element Q0 is PWM (Pulse Width Modulation) controlled by the control circuit 10, thereby boosting the voltage across the input capacitor C0. Then, the DC/DC converter 2 outputs the boosted DC voltage to the output capacitor C1 and the inverter 3 connected to the intermediate bus MB. In other words, the DC/DC converter 2 is connected between the distributed power source 1 and the inverter 3, and converts the DC voltage output from the distributed power source 1 into a DC voltage of a predetermined magnitude.

The inverter 3 has four switching elements Q1 to Q4 connected in a full bridge. In the inverter 3, 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 terminal 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.

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 3, the switching elements Q1 to Q4 are PWM-controlled by the control circuit 10, so that between the output capacitor C1 and the filter circuit 4, the DC voltage is converted to the AC voltage, or the AC voltage is converted to the DC voltage. It is a bi-directional DC/AC converter. That is, the inverter 3 has the function of converting the DC power from the output capacitor C1 (the DC power from the intermediate bus MB) into AC power and outputting it to the power system 6, and the function of converting the AC power from the power system 6 into DC power. and output to the output capacitor C1 (intermediate bus MB).

Thus, in the present embodiment, the inverter 3 is configured to bi-directionally convert power between the output capacitor C1 and the power system 6 so as to support both charging and discharging of the storage battery 5. It is As a result, the system interconnection system 100 connects the storage battery 5 to the power system 6, charges the storage battery 5 with the power supplied from the power system 6, and connects the power output from the storage battery 5 to the power system 6. It is possible to supply to the load that is connected.

The filter circuit 4 has two inductors L1 and L2 and a capacitor C2. A first end of the inductor L1 is connected to a connection point between the source of the switching element Q1 and the drain of the switching element Q3. A second end of inductor L1 is connected to power system 6 . A first end of the inductor L2 is connected to a connection point between the source of the switching element Q2 and the drain of the switching element Q4. A second end of inductor L2 is connected to power system 6 . A capacitor C2 is connected between the second end of the inductor L1 and the second end of the inductor L2. The filter circuit 4 has a function of removing high-frequency components from the AC voltage output from the inverter 3 and generating a sinusoidal voltage.

The control circuit 10 is composed of, for example, a microcomputer having one or more processors and memory. In other words, the control circuit 10 is realized by a computer system having one or more processors and memory, and the one or more processors execute a program stored in the memory so that the computer system functions as the control circuit 10. Function. Although the program is previously recorded in the memory of the control circuit 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 circuit 10 may be configured by, for example, an FPGA (Field-Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit).

The control circuit 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 circuit 10 controls the switching elements Q0 to Q4 by a PWM system with an adjustable duty ratio.

The charging/discharging circuit 50 is a bi-directional DC/DC converter and is connected to the intermediate bus MB between the storage battery 5 and the output capacitor C1. The charge/discharge circuit 50 has a function of converting the DC power output from the storage battery 5 into DC power of a predetermined magnitude and outputting the converted DC power to the output capacitor C1. The charging/discharging circuit 50 also has a function of converting the DC power output from the output capacitor C<b>1 into DC power of a predetermined magnitude and outputting the converted DC power to the storage battery 5 .

As described above, the reverse current blocking diode D1 is located on the side of the distributed power source 1 when viewed from the inverter 3, more specifically, distributed from the connection point where the storage battery 5 (and the charging/discharging circuit 50) is connected to the intermediate bus MB. provided on the power supply 1 side.

(3) Operation First, the basic operation of the interconnection system 100 of this embodiment will be described with reference to FIG. When the distributed power source 1 receives sufficient sunlight to generate power, such as during the daytime, the distributed power source 1 outputs DC power to the inverter 3 via the DC/DC converter 2 . The inverter 3 converts the input DC power into AC power and outputs the converted AC power to the power system 6 . Thereby, the power generated by the distributed power supply 1 is supplied to the load connected to the power system 6 . Further, when there is surplus power in the power generated by the distributed power source 1, the distributed power source 1 outputs the surplus power to the storage battery 5 via the DC/DC converter 2 and the charge/discharge circuit 50, thereby charging the storage battery 5. do. Alternatively, the storage battery 5 may be charged by the power system 6 outputting DC power to the storage battery 5 via the inverter 3 and the charging/discharging circuit 50 .

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 5 supplies DC power to the inverter 3 via the charging/discharging circuit 50. to output The inverter 3 converts the input DC power into AC power and outputs the converted AC power to the power system 6 . As a result, the power discharged by the storage battery 5 is supplied to the load connected to the power system 6 .

Here, the operation of the grid interconnection system 100 of the present embodiment will be described together with the grid interconnection system of the comparative example. In the grid interconnection system of the comparative example, as shown in FIG. 2, the backflow blocking diode D1 is not connected between the source of the switching element Q0 of the DC/DC converter 2 and the second electrode 16 of the output capacitor C1. This point is different from the grid interconnection system 100 of the present embodiment.

As described above, even when distributed power supply 1 does not generate power, such as at night, inverter 3 may operate when power is supplied from storage battery 5 to power system 6 . In this case, a ground voltage V1 is generated between the first electrode 15 of the output capacitor C1 and the reference potential Vb1, which makes the first electrode 15 a high potential. Further, a ground voltage V2 is generated between the second electrode 16 of the output capacitor C1 and the reference potential Vb1 to make the reference potential Vb1 a high potential.

In this embodiment, since the system interconnection system 100 using the solar battery as the distributed power source 1 and the storage battery 5 is described, the inverter 3 operates when the distributed power source 1 does not generate power. Although the night time is given as an example of the operation, it is not intended to be limited to this. For example, depending on the distributed power source 1 or another DC power source instead of the storage battery 5, the inverter 3 may operate when the distributed power source 1 does not generate power even in situations other than nighttime.

Here, both the positive electrode 11 and the negative electrode 12 of the distributed power supply 1 are relatively large electrodes. Therefore, between the positive electrode 11 of the distributed power source 1 and the reference potential Vb1, and between the negative electrode 12 of the distributed power source 1 and the reference potential Vb1, the first ground capacitance Ce1 and A second ground capacitance Ce2 is produced. Then, using the ground voltage V1 as a voltage generation source, a current path (hereinafter also referred to as "first path P1") through which a leakage current flows in order of the high potential of the DC/DC converter 2, the first ground capacitance Ce1, and the reference potential Vb1. can be formed. Similarly, using the ground voltage V2 as a voltage generation source, a current path through which a leakage current flows in the order of the reference potential Vb1, the second ground capacitance Ce2, and the low potential of the DC/DC converter 2 (hereinafter also referred to as "second path P2"). ) can be formed. All of these current paths include at least part of the circuit on the distributed power supply 1 side when viewed from the inverter 3 . These current paths also include at least one of the high potential and low potential of the DC/DC converter 2 . In the present embodiment, the first path P1 of the current paths includes the high potential side electric path of the DC/DC converter 2, and the second path P2 includes the low potential side electric path of the DC/DC converter 2. I'm in.

In the comparative example, in the first path P1, the diode D0 of the DC/DC converter 2 functions as a reverse blocking diode D1, thereby suppressing leakage current flowing to the reference potential Vb1. Therefore, the first ground capacitance Ce1 is less likely to be charged by the leakage current, and the ground voltage (that is, the voltage between the positive electrode 11 and the reference potential Vb1) is less likely to be applied to the positive electrode 11 of the distributed power supply 1. On the other hand, in the comparative example, since the backflow blocking diode D1 does not exist in the second path P2, a leakage current may flow to the reference potential Vb1 through the second path P2. Therefore, the second capacitance Ce2 is charged by the leakage current, and the ground voltage (that is, the voltage between the negative electrode 12 and the reference potential Vb1) can be applied to the negative electrode 12 of the distributed power supply 1 .

Application of a voltage to ground to at least one of the positive electrode 11 and the negative electrode 12 of the distributed power supply 1 in this manner may adversely affect the distributed power supply 1 . For example, when the distributed power source 1 is a photovoltaic power generation device, a PID (Potential Induced Degradation) phenomenon occurs, which may cause the photovoltaic power generation device to deteriorate and the power generation amount of the distributed power source 1 to decrease. .

In contrast, in the present embodiment, as shown in FIG. 3, since the reverse current blocking diode D1 exists in the second path P2, it is possible to suppress the leakage current flowing to the reference potential Vb1 through the second path P2. It is possible. Thus, in this embodiment, the diode D0 and the reverse blocking diode D1 of the DC/DC converter 2 cut off the charging paths of the first ground capacitance Ce1 and the second ground capacitance Ce2. Therefore, in the present embodiment, it is difficult for the voltage to ground to be applied to both the positive electrode 11 and the negative electrode 12 of the distributed power supply 1, and as a result, the possibility that the distributed power supply 1 is adversely affected can be reduced.

That is, in the present embodiment, the current path through which the leakage current flows includes the first path P1 including the positive electrode 11 of the distributed power supply 1 and the second path P2 including the negative electrode 12 of the distributed power supply 1. . A backflow blocking diode D1 is provided in each of the first path P1 and the second path P2 (the backflow blocking diode D1 in the first path P1 is the diode D0 of the DC/DC converter 2). Therefore, in the present embodiment, it becomes difficult for the leakage current to flow through both the first path P1 and the second path P2, so that it becomes difficult for the voltage to ground to occur in both the positive electrode 11 and the negative electrode 12 of the distributed power supply 1. , has the advantage of

Here, as a mode of interrupting the charging path of the first ground capacitance Ce1 and the second ground capacitance Ce2, for example, providing a mechanical relay between the distributed power supply 1 and the DC/DC converter 2 can be considered. In this aspect as well, when the distributed power source 1 is not generating power, the mechanical relay cuts off the connection between the distributed power source 1 and the DC/DC converter 2, so that the first ground capacitance Ce1 and the second ground capacitance Ce2 It is possible to cut off the charging path.

However, in this aspect, there is a problem that the cost of the mechanical relay is higher than that of the reverse current blocking diode D1, and that it is necessary to secure a power supply for driving the mechanical relay. In addition, in this mode, there are problems that the number of opening and closing times of the mechanical relay is limited (that is, the mechanical relay has a life span), and that the operation may become unstable due to chattering.

On the other hand, in the present embodiment, the current path can be interrupted by a simple configuration in which the reverse current blocking diode D1 is provided in the current path through which the leakage current flows to the reference potential Vb1 (here, the charging path of the second ground capacitance Ce2). It is possible. Therefore, in this embodiment, there is an advantage that the above-described problem that may occur in the aspect of providing the mechanical relay does not occur.

Further, in the present embodiment, the reverse current blocking diode D1 in the first path P1 is also used as the diode D0 of the DC/DC converter 2 . Therefore, in the present embodiment, there is no need to newly provide the backflow blocking diode D1 for the current path including the diode D0 of the DC/DC converter 2, and there is an advantage that the circuit design can be simplified. .

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

(4.1) First Modification In the grid interconnection system 100 of the first modification, the grid interconnection system 100 is connected to a plurality of (here, two) distributed power sources 1. It differs from the grid interconnection system 100 of the embodiment. Specifically, in this modification, as shown in FIGS. 4A and 4B, one input A capacitor C0 and one DC/DC converter 2 are connected. Two distributed power sources 1 are connected to the grid interconnection system 100 of this modification. Therefore, the grid interconnection system 100 of this modification differs from the grid interconnection system 100 of the above-described embodiment in that it includes two input capacitors C0 and two DC/DC converters 2 .

In the example shown in FIGS. 4A and 4B, illustration of the distributed power supply 1, the control circuit 10, the inverter 3, the filter circuit 4, the storage battery 5, the charge/discharge circuit 50, and the power system 6 is omitted. The same applies to FIGS. 5 to 8 below.

In this modification, one input capacitor C0 and one DC/DC converter 2 constitute one set of functional units A1, and two sets of functional units A1 are connected in parallel to the output capacitor C1. In this modification, in the example shown in FIG. 4A, a backflow blocking diode D1 is connected between the low potential connection point of the two functional units A1 and the second electrode 16 of the output capacitor C1. That is, in the example shown in FIG. 4A, the reverse blocking diode D1 is shared by the two functional units A1.

On the other hand, in this modified example, in the example shown in FIG. 4B, each of the two functional units A1 is provided with a backflow blocking diode D1. Specifically, in each of the two functional units A1, a backflow blocking diode D1 is connected between the source of the switching element Q0 of the DC/DC converter 2 and the second electrode 16 of the output capacitor C1.

In this modification, for each of the plurality of distributed power sources 1, the diode D0 and the reverse blocking diode D1 of the DC/DC converter 2 cut off the charging paths of the first ground capacitance Ce1 and the second ground capacitance Ce2. Therefore, in this modification, it is difficult to apply the voltage to ground to both the positive electrode 11 and the negative electrode 12 of each of the plurality of distributed power sources 1, and as a result, the possibility of adversely affecting the plurality of distributed power sources 1 is reduced. can do.

(4.2) Second Modification In the grid interconnection system 100 of the second modification, as shown in FIG. It differs from the grid interconnection system 100 of the first modification in that it is housed in the body 8 . The second housing 8 has two reverse blocking diodes D1. The second housing 8 is connected between the first housing 7 and the positive electrodes 11 and negative electrodes 12 of the plurality of (here, two) distributed power sources 1 . By connecting the second housing 8 as described above, the reverse current blocking diode D1 is connected between the negative electrode 12 and the second electrode 14 of the input capacitor C0 for each of the plurality of distributed power sources 1. be.

In this modification, as in the first modification, it is difficult to apply the ground voltage to both the positive electrode 11 and the negative electrode 12 of each of the plurality of distributed power sources 1, and as a result, the plurality of distributed power sources 1 are adversely affected. can reduce the possibility of Further, in this modified example, the reverse current blocking diode D1 is not built in the first housing 7, and the reverse current blocking diode D1 can be externally attached. That is, in this modification, there is an advantage that the backflow blocking diode D1 can be easily connected to the existing inverter 3 by externally attaching the second housing 8 to the first housing 7 .

(4.3) Third Modification In the grid interconnection system 100 of the third modification, as shown in FIG. This is different from the grid interconnection system 100 of the second modified example. In addition, the grid interconnection system 100 of this modified example also has the second feature that the detection circuit 9 is connected in parallel to the input capacitor C0 with respect to the DC/DC converter 2 in each of the two functional units A1. It is different from the grid interconnection system 100 of the modification.

The second housing 8 has two switching elements SW1 in addition to the two reverse blocking diodes D1. In the state where the second housing 8 is connected to the first housing 7, the two switching elements SW1 are connected between the positive electrode 11 of the distributed power supply 1 and the high-potential input end of the functional unit A1. be. The switching element SW1 is controlled by the control circuit 10, for example, to switch on/off, thereby opening and closing the path between the positive electrode 11 of the distributed power supply 1 and the high-potential input terminal of the functional unit A1. The switching element SW1 may be a mechanical relay or a semiconductor switching element such as a MOSFET.

The detection circuit 9 is a circuit that detects the voltage across the input capacitor C0, that is, the output voltage of the distributed power supply 1. FIG. The detection circuit 9 has, for example, a series circuit of multiple resistors. In this modification, the control circuit 10 monitors the voltage detected by the detection circuit 9, and operates the DC/DC converter 2 and the inverter 3 according to the detected voltage. Specifically, when the detected voltage exceeds a predetermined voltage value, the control circuit 10 operates the DC/DC converter 2 and the inverter 3 on the assumption that the power generation amount of the distributed power supply 1 is sufficient. On the other hand, when the detected voltage falls below a predetermined voltage value, the control circuit 10 stops the DC/DC converter 2 and the inverter 3 on the assumption that the power generation amount of the distributed power supply 1 is insufficient. Note that the control circuit 10 operates the inverter 3 when the storage battery 5 is discharged.

The control according to the detection circuit 9 and the detection voltage of the detection circuit 9 by the control circuit 10 can be performed in the above-described embodiment, the first modification, the second modification, and the fourth modification and the fifth modification described below. Examples can also be applied.

Here, in a mode in which the second housing 8 does not have the opening/closing element SW1 as in the second modified example, the following problems may occur. That is, as already described, when the distributed power supply 1 is not generating power and the inverter 3 is operating to supply power from the storage battery 5 to the power system 6, ground voltages V1 and V2 are generated. At this time, a current path (hereinafter also referred to as “third path P3”) through which a leakage current flows in order of the reference potential Vb1, the first ground capacitance Ce1, and the resistance component of the detection circuit 9 is formed using the ground voltage V2 as a voltage generation source. can be Therefore, the leakage current flows through the third path P3, thereby charging the first ground capacitance Ce1 and applying the ground voltage to the negative electrode 12 of the distributed power supply 1. FIG.

Therefore, in this modified example, the opening/closing element SW1 is provided in the second housing 8 to solve the above problem. That is, the control circuit 10 turns off the switching element SW1 when the voltage detected by the detection circuit 9 is below a predetermined voltage value, that is, when the distributed power supply 1 is not generating power. As a result, it is possible to cut off the charging path of the first ground capacitance Ce1 via the third path P3 and make it difficult for the ground voltage to be applied to the negative electrode 12 of the distributed power supply 1 .

Here, it is conceivable to provide a backflow blocking diode D1 instead of the switching element SW1 in the third path P3. However, in this embodiment, the backflow blocking diode D1 will block current flow from the distributed power source 1 towards the power grid 6 . In other words, in this aspect, the backflow blocking diode D1 prevents the distributed power supply 1 from being interconnected with the power system 6 . In other words, the third path P3 is a path that prevents the distributed power supply 1 from being interconnected with the power system 6 by inserting the backflow blocking diode D1 in the current path through which the leakage current flows.

Therefore, in this modified example, the above problem is solved by providing the switching element SW1 in the third path P3. That is, the control circuit 10 opens and closes when the voltage detected by the detection circuit 9 exceeds a predetermined voltage value, that is, when the distributed power source 1 is generating power and the distributed power source 1 is interconnected with the power system 6. Switch on the device SW1. As a result, the switching element SW1 does not hinder the system interconnection of the distributed power supply 1 with the power system 6 .

As described above, in this modified example, it is possible to implement control such that the switching element SW1 is closed when the distributed power supply 1 is interconnected with the electric power system 6, and the switching element SW1 is opened otherwise. This control has the advantage that it is easy to prevent the voltage to ground from being applied to the electrode of the distributed power source 1 without hindering the current flowing between the distributed power source 1 and the power system 6 .

(4.4) Fourth Modification The grid interconnection system 100 of the fourth modification further includes switches SW2 and SW3 connected in parallel to the backflow blocking diode D1 as shown in FIG. It differs from the grid interconnection system 100 of the embodiment. Switch SW2 is connected in parallel with diode D0 of DC/DC converter 2 . The switch SW3 is connected in parallel with the backflow blocking diode D1. Both of the switches SW2 and SW3 may be mechanical relays or semiconductor switch elements such as MOSFETs.

Both of the switches SW2 and SW3 are switched on/off by being controlled by the control circuit 10 . Specifically, the switches SW2 and SW3 are controlled by the control circuit 10 so that they are turned on when the distributed power supply 1 is interconnected with the power system 6, and turned off otherwise. An example of control of the switches SW2 and SW3 by the control circuit 10 will be described below.

The control circuit 10 uses the detection circuit 9 (see the third modification) to turn the switch SW2 when the detected voltage exceeds a predetermined voltage value, that is, when the distributed power supply 1 is interconnected with the power system 6. It turns on/off according to on/off of the switching element Q0. Specifically, the control circuit 10 controls the switch SW2 so that the switch SW2 is turned off when the switching element Q0 is on and the switch SW2 is turned on when the switching element Q0 is off. By controlling the DC/DC converter 2 in a synchronous rectification manner in this way, it is possible to suppress the loss due to the conduction of the diode D0. Also, the control circuit 10 turns off the switch SW2 when the detected voltage is below a predetermined voltage value. This allows the diode D0 of the DC/DC converter 2 to function as the reverse blocking diode D1 in the first path P1.

The control circuit 10 uses the detection circuit 9 to turn on the switch SW3 when the detected voltage exceeds a predetermined voltage value, that is, when the distributed power supply 1 is interconnected with the power system 6 . As a result, it is possible to suppress loss due to conduction of the reverse current blocking diode D1 at the time of system interconnection. Further, the control circuit 10 turns off the switch SW3 when the detected voltage is below a predetermined voltage value. This allows the reverse current blocking diode D1 to function in the second path P2.

As described above, in this modification, when the distributed power supply 1 is interconnected with the power system 6, the current flowing between the distributed power supply 1 and the power system 6 causes a loss in the reverse current blocking diode D1. It has the advantage of being able to prevent it from occurring.

By the way, in this modified example, as in the example shown in FIG. 7B, a switch SW4, which is a semiconductor switch element, may be connected instead of the reverse blocking diode D1. The switch SW4 is a depletion-type n-channel MOSFET. The source of switch SW4 is connected to the second electrode 16 of the output capacitor C1. A drain of the switch SW4 is connected to a connection point between the second electrode of the input capacitor C0 and the source of the switching element Q0. A parasitic diode (body diode) D2 of the switch SW4 functions as a reverse current blocking diode D1.

In the example shown in FIG. 7B, the control circuit 10 uses the detection circuit 9 to turn the switch SW4 on when the detected voltage exceeds a predetermined voltage value, that is, when the distributed power supply 1 is interconnected with the power system 6. turn on. As a result, it is possible to suppress loss due to conduction of the reverse current blocking diode D1 at the time of system interconnection. Also, the control circuit 10 turns off the switch SW4 when the detected voltage is below a predetermined voltage value. This allows the parasitic diode D2 of the switch SW4 to function as the reverse blocking diode D1 in the second path P2.

As described above, even in the mode shown in FIG. 7B, the same effect as described above can be obtained. Note that the switch SW4 is not limited to a MOSFET, and may be another semiconductor switch element such as an IGBT. If the switch SW4 is an IGBT, a commutation diode incorporated in the IGBT functions as the reverse blocking diode D1.

(4.5) Fifth Modification In a grid interconnection system 100 of a fifth modification, as shown in FIG. 8, one first It differs from the grid interconnection system 100 of the first modification in that one resistor R1 and two second resistors R2 are connected.

The first resistor R1 is connected to the DC/DC converter 2 in parallel with the input capacitor C0. When the detection circuit 9 (see the third modification) is used, the resistance component of the detection circuit 9 corresponds to the first resistor R1. The first resistor R1 may be configured by combining a plurality of resistors.

One second resistor R2 of the two second resistors R2 is connected between the connection point between the high-potential output end of the DC/DC converter 2 and the first electrode 15 of the output capacitor C1 and the first end of the first resistor R1. 17. The other second resistor R2 is connected between the connection point between the low-potential output end of the DC/DC converter 2 and the second electrode 16 of the output capacitor C1 and the second end 18 of the first resistor R1. there is Each of the two second resistors R2 may be configured by combining a plurality of resistors.

The resistance value of the second resistor R2 is greater than the resistance value of the first resistor R1. The resistance value of the second resistor R2 should be greater than the resistance value of the first resistor R1 such that the value obtained by dividing the resistance value of the first resistor R1 by the resistance value of the second resistor R2 is approximately zero. preferable.

The operation of this modification will be described below. As already described, when the distributed power supply 1 is not generating power and the inverter 3 is operating to supply power from the storage battery 5 to the power system 6, ground voltages V1 and V2 are generated. The ground voltages V1 and V2 are each divided by a series circuit of a first resistor R1 and a second resistor R2. As already described, since the resistance value of the second resistor R2 is greater than the resistance value of the first resistor R1, the voltage across the first resistor R1 becomes smaller than the ground voltages V1 and V2. . Specifically, if the ground voltages V1 and V2 are one hundred and several tens [V], the voltage across the first resistor R1 is about several [V] to ten and several [V].

As described above, in this modified example, the voltage across the first resistor R1, that is, the voltage applied between the positive electrode 11 and the negative electrode 12 of the distributed power supply 1 can be brought close to zero voltage. Therefore, in this modified example, the voltage applied to the first ground capacitor Ce1 and the voltage applied to the second ground capacitor Ce2 are brought close to zero voltage, so that both the positive electrode 11 and the negative electrode 12 have the ground voltage. It is possible to make it difficult to apply.

By the way, in this modified example, as described above, the single first resistor R1 and the two second resistors R2 make it difficult to apply the ground voltage to both the positive electrode 11 and the negative electrode 12 of the distributed power supply 1. is possible, the backflow blocking diode D1 may not be provided. That is, the grid interconnection system 100 of this modified example may have the following configuration. That is, the grid interconnection system 100 includes an inverter 3, one first resistor R1, and two second resistors R2. The inverter 3 is connected between the distributed power source 1 and the power system 6 and converts DC power from the distributed power source 1 into AC power. A first resistor R1 is connected between the positive electrode 11 and the negative electrode 12 of the distributed power supply 1 . One of the two second resistors R2 is connected to the high-potential input terminal of the inverter 3 and is connected in series with the first resistor R1. The other second resistor R2 of the two second resistors R2 is connected to the low-potential input terminal of the inverter 3 and is connected in series with the first resistor R1. Each resistance value of the two second resistors R2 is greater than the resistance value of the first resistor R1.

(5) Other Modifications Other modifications are listed below. The modifications described below, including the modifications listed in "(4) Modifications", can be applied in combination as appropriate.

In the above-described embodiment, the backflow blocking diode D1 may not be provided at the position shown in FIG. 1, and may be provided on the second path P2.

In the above-described embodiment, the input capacitor C0 and the output capacitor C1, the DC/DC converter 2, the inverter 3, the filter circuit 4, and the control circuit 10 are housed in one housing (first housing) 7. , may be distributed and housed in a plurality of housings.

In the above-described embodiment, the DC/DC converter 2 is a step-up DC/DC converter, but it is not intended to be limited to this. For example, the DC/DC converter 2 may be a step-down DC/DC converter or a DC/DC converter capable of both stepping up and stepping down.

In the above-described embodiment, the inverter 3 is configured to convert power bi-directionally, but the invention is not limited to this. For example, the inverter 3 may be configured to convert power only in one direction (unidirectional) from the DC/DC converter 2 to the filter circuit 4 . In this case, the storage battery 5 is not charged by the power supplied from the power system 6, but is charged by the surplus power of the power generated by the distributed power supply 1.

In the above-described embodiment, the storage battery 5 is connected in parallel to the distributed power supply 1, but the invention is not limited to this. For example, the distributed power source 1 may be connected to another distributed power source instead of the storage battery 5 . In this aspect as well, when the distributed power source 1 is not generating power and other distributed power sources are outputting power, the ground voltage is applied to both the positive electrode 11 and the negative electrode 12 of the distributed power source 1. It can be made difficult.

In the above-described embodiment, the grid interconnection system 100 includes the input capacitor C0, the DC/DC converter 2, the output capacitor C1, and the filter circuit 4, but some or all of these may not be included. . For example, in the grid interconnection system 100 , the DC/DC converter 2 may not be connected between the distributed power source 1 and the inverter 3 . In this aspect, the diode D0 of the DC/DC converter 2 cannot function as the reverse current blocking diode D1, so it is preferable to provide the reverse current blocking diode D1 in each of the first path P1 and the second path P2.

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.

In the above-described embodiment, the grid interconnection system 100 is configured to open the parallel breaker and perform self-sustained operation when there is an abnormality in the power system 6, but the present invention is not limited to this. For example, the grid interconnection system 100 may be configured not to perform self-sustained operation when the power grid 6 is abnormal.

In the above-described embodiment, the grid interconnection system 100 is installed in a non-residential facility, but the present invention is not limited to this. For example, the grid interconnection system 100 may be installed in a house, or may be applied to places other than facilities such as electric vehicles.

In the third to fifth modifications, a plurality of distributed power sources 1 are connected to the interconnection system 100, but only one distributed power source 1 may be connected.

(summary)
As described above, the grid interconnection system (100) according to the first aspect includes the inverter (3). The inverter (3) is connected between the distributed power source (1) and the power system (6), and converts DC power from the distributed power source (1) into AC power. The grid interconnection system (100) further includes a backflow blocking diode (D1). A reverse current blocking diode (D1) is provided in a current path (P1, P2) including at least part of the circuit on the side of the distributed power supply (1) when viewed from the inverter (3), and is connected to a reference current path (P1, P2) through the current path (P1, P2). It blocks leakage current flowing to the potential (Vb1).

According to this aspect, there is an advantage that the voltage to ground is less likely to be applied to the electrodes of the distributed power supply (1).

The grid interconnection system (100) according to the second aspect further includes a non-isolated DC/DC converter (2) in the first aspect. The DC/DC converter (2) is connected between the distributed power supply (1) and the inverter (3), and converts the DC voltage output from the distributed power supply (1) into a DC voltage of a predetermined magnitude. Current paths (P1, P2) include at least one of a high potential and a low potential of the DC/DC converter (2).

According to this aspect, a ground voltage is applied to the electrodes of the distributed power supply (1) while having the function of converting the DC voltage output from the distributed power supply (1) into a DC voltage of a predetermined magnitude. There is an advantage that it is easy to prevent

In the grid interconnection system (100) according to the third aspect, in the second aspect, the reverse current blocking diode (D1) is also used as the diode (D0) of the DC/DC converter (2).

According to this aspect, the current path including the diode (D0) of the DC/DC converter (2) does not require a new backflow blocking diode (D1), thereby simplifying the circuit design. , has the advantage of

In the grid interconnection system (100) according to the fourth aspect, in any one of the first to third aspects, the current path (P1, P2) includes the positive electrode (11) of the distributed power supply (1). It has one path (P1) and a second path (P2) including the negative pole (12) of the distributed power source (1). A backflow blocking diode (D1) is provided in each of the first path (P1) and the second path (P2).

According to this aspect, it becomes difficult for leakage current to flow through both the first path (P1) and the second path (P2), so There is also an advantage that the ground voltage is less likely to occur.

A grid interconnection system (100) according to a fifth aspect, in any one of the first to fourth aspects, further comprises switches (SW2, SW3, SW4) connected in parallel to the reverse current blocking diode (D1). . The switches (SW2, SW3, SW4) are controlled to be turned on when the distributed power supply (1) is interconnected with the electric power system (6), and to be turned off otherwise.

According to this aspect, when the distributed power supply (1) is interconnected with the power system (6), the current flowing between the distributed power supply (1) and the power system (6) causes the reverse current blocking diode ( There is an advantage that the generation of loss in D1) can be suppressed.

In the grid interconnection system (100) according to the sixth aspect, in any one of the first to fifth aspects, the backflow blocking diode (D1) includes the first housing (7) housing the inverter (3) and are housed in a different second housing (8).

According to this aspect, by externally attaching the second housing (8) to the first housing (7), it is possible to easily connect the reverse current blocking diode (D1) to the existing inverter (3). There is an advantage.

In the grid interconnection system (100) according to the seventh aspect, in the sixth aspect, the switching element (SW1) is provided in the predetermined path (third path) (P3) instead of the reverse current blocking diode (D1). Connected. The predetermined path (P3) is a path that prevents the distributed power supply (1) from being interconnected with the electric power system (6) by inserting the backflow blocking diode (D1) in the current path.

According to this aspect, it is possible to implement control such that the switching element (SW1) is closed when the distributed power supply (1) is interconnected with the electric power system (6), and the switching element (SW1) is opened otherwise. . This control makes it easy to prevent the voltage to ground from being applied to the electrodes of the distributed power source (1) without interfering with the current flowing between the distributed power source (1) and the electric power system (6). There is an advantage.

In the grid interconnection system (100) according to the eighth aspect, in any one of the first to seventh aspects, the inverter (3) is connected in parallel to the distributed power supply (1) from the storage battery (5) of DC power to AC power. The distributed power source (1) is a photovoltaic power plant.

This aspect has the advantage that power can be supplied to the power system (6) even when either the distributed power source (1) or the storage battery (5) is unavailable.

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

100 grid interconnection system 1 distributed power supply 11 positive electrode 12 negative electrode 2 DC/DC converter 3 inverter 5 storage battery 6 power system 7 first housing 8 second housing D0 diode of DC/DC converter D1 backflow blocking diode P1 first path (current path)
P2 Second path (current path)
SW1 switching element SW2, SW3 switch Vb1 reference potential

Claims (6)

an inverter connected between the distributed power source and the power system ;
a storage battery connected in parallel with the distributed power supply;
a backflow blocking diode;
a switch ;
A current path on the distributed power supply side when viewed from the inverter is
a first path including the positive electrode of the distributed power supply;
a second path including the negative electrode of the distributed power supply;
The storage battery is connected in the current path to a first connection point of the first path and a second connection point of the second path,
The inverter is configured to convert DC power from the distributed power source and the storage battery to AC power,
the reverse current blocking diode is provided closer to the distributed power supply than the second connection point in the second path of the current path, and blocks leakage current flowing through the second path to the distributed power supply;
The switch is
connected in parallel with the reverse current blocking diode,
A system interconnection system that is controlled so that the distributed power supply is always on when it is interconnected with the electric power system and is off otherwise. further comprising a non-insulated DC/DC converter connected between the distributed power supply and the inverter for converting the DC voltage output from the distributed power supply into a DC voltage of a predetermined magnitude;
The DC/DC converter is
a high-potential-side electric path provided closer to the distributed power source than the first connection point in the first path of the current path;
a low-potential-side electric path provided closer to the distributed power source than the second connection point in the second path of the current path;
The system interconnection system according to claim 1. Further comprising a second reverse-blocking diode different from the first reverse-blocking diode, which is the reverse-blocking diode;
The second backflow blocking diode,
is also used as a diode provided in the high potential side electric circuit of the DC/DC converter,
provided closer to the distributed power supply than the first connection point in the first path of the current path, and blocks leakage current flowing to the distributed power supply through the first path ;
The system interconnection system according to claim 2. The backflow blocking diode is housed in a second housing different from the first housing housing the inverter.
The interconnection system according to any one of claims 1 to 3. an inverter connected between the distributed power source and the power system;
a storage battery connected in parallel with the distributed power supply;
a backflow blocking diode;
a detection circuit connected in parallel with the distributed power supply for detecting the output voltage of the distributed power supply;
a switch;
A current path on the distributed power supply side when viewed from the inverter is
a first path including the positive electrode of the distributed power supply;
a second path including the negative electrode of the distributed power supply;
The storage battery is connected in the current path to a first connection point of the first path and a second connection point of the second path,
The inverter is configured to convert DC power from the distributed power source and the storage battery to AC power,
The backflow blocking diode is
Housed in a second housing different from the first housing housing the inverter,
provided closer to the distributed power supply than the second connection point in the second path of the current path, and prevents leakage current flowing through the second path to the distributed power supply;
The detection circuit is
a third connection point closer to the distributed power supply than the first connection point in the first path of the current path;
connected to a fourth connection point between the second connection point and the reverse blocking diode in the second path of the current path,
The switch is
provided closer to the distributed power source than the third connection point on the first path,
controlled to be turned on when the distributed power supply is interconnected with the power system, and turned off when the distributed power supply is not interconnected with the power system;
Grid-connected system. The distributed power source is a photovoltaic power generation device
The interconnection system according to any one of claims 1 to 5.

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