JP2020156239A - Power supply system - Google Patents

Abstract

To provide a power supply system that makes it possible to accurately grasp a power selling amount from a power generation unit capable of generating power using natural energy and a power selling amount from a fuel battery.SOLUTION: A power supply system comprises: a photovoltaic power generation unit 11 provided between a system power supply K and a load H; a storage battery 12 that is provided between the system power supply K and the load H and is capable of performing charge and discharge with power from the photovoltaic power generation unit 11; a power distribution board 20 provided on the downstream side of the photovoltaic power generation unit 11 and the storage battery 12; a fuel battery 30 connected to the power distribution board 20 on the downstream side of the photovoltaic power generation unit 11 and the storage battery 12; a power selling/purchasing meter 50 that is provided on the upstream side of the photovoltaic power generation unit 11 and the storage battery 12 and is capable of detecting at least power flowing to the upstream side; and a power selling meter 60 that is provided on the downstream side of the photovoltaic power generation unit 11 and the storage battery 12 and on the upstream side of the power distribution board 20 and the fuel battery 30 and is capable of detecting at least power flowing to the upstream side. The storage battery 12 is set in an eco mode in which charging with power from the system power supply K and power from the fuel battery 30 is disabled.SELECTED DRAWING: Figure 1

Description

The present invention relates to a technique for a power supply system that supplies power to a load.

Conventionally, the technology of a power supply system that supplies power to a load has been known. For example, as described in Patent Document 1.

Patent Document 1 describes a power supply system including a solar cell that generates electricity using sunlight, a fuel cell that generates electricity using fuel such as hydrogen, and a storage battery capable of charging and discharging electric power. In the power supply system, a fuel cell is arranged on the downstream side of the solar cell and the storage battery via a distribution board.

Here, since the unit price of power that is reverse-flowed from the solar power generation device to the grid power supply (power sold) is different from the unit price of power that is reverse-flowed from the fuel cell to the grid power supply, each of them is different. It is desirable to distinguish and grasp the amount of electricity sold. In order to distinguish and grasp the amount of power sold, it is conceivable to dispose a power sales meter between the storage battery and the commercial power supply (system power supply) and between the storage battery and the distribution board.

However, since the storage battery is located on the upstream side (system power supply side) of the fuel cell, if the power is flowing backward from the fuel cell when the storage battery is charging the power from the system power supply, the storage battery is It also charges the power from the fuel cell. Then, even if it is recognized that the power is sold from the fuel cell to the grid power source according to the detection result of the power selling meter between the storage battery and the distribution board, the power is not actually sold. (The storage battery is charged), and the detection result of the power sale meter will be different from the actual situation. Due to such a difference, there is a problem that each amount of electricity sold cannot be accurately grasped.

Japanese Unexamined Patent Publication No. 2016-48992

The present invention has been made in view of the above circumstances, and the problem to be solved is to accurately determine the amount of power sold from the power generation unit capable of generating power using natural energy and the amount of power sold from the fuel cell. It is to provide a power supply system that can be grasped.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, in claim 1, a power generation unit provided between the system power source and the load and capable of generating power by using natural energy, and a power generation unit provided between the system power source and the load, from the power generation unit. A storage battery capable of charging and discharging power, a distribution board provided on the downstream side of the power generation unit and the storage battery in the power supply direction from the system power source, and distributing the power to the load, the power generation unit and the power generation unit, and the said. A fuel cell connected to the distribution panel on the downstream side of the storage battery, and power provided on the upstream side of the power generation unit and the storage battery in the power supply direction from the system power source and flowing to at least the upstream side. A first detection unit capable of detecting the above, a power generation unit and a storage battery provided on the downstream side, and a distribution panel and a fuel cell on the upstream side, and at least the electric power flowing to the upstream side. A second detection unit that can be detected is provided, and the storage battery is set to a first mode in which the power from the system power source and the power from the fuel cell cannot be charged.

According to the second aspect, the storage battery is set to the second mode in which the electric power from the system power supply and the electric power from the fuel cell can be charged when the remaining storage amount is reduced to the first value or less. When the storage battery is set to the first mode and the remaining amount of electricity is reduced to a second value or less, which is larger than the first value, the storage battery is set to be non-dischargeable.

According to claim 3, the storage battery is set to a second mode in which the power from the system power source and the power from the fuel cell can be charged when the remaining charge is reduced to the first value or less. The power supply system can connect the power generation unit and the storage battery to each other, and can output the power from the power generation unit and the power from the storage battery to the distribution line connecting the system power supply and the load. A hybrid power controller capable of outputting the power from the power generation unit and the power flowing through the distribution line to the storage battery, and the first opening / closing provided in the first electric circuit connecting the distribution board and the fuel cell. The control unit includes a device and a control unit that controls the operation of the first switch and controls the operation of the storage battery via the hybrid power controller, and the control unit sets the storage battery to the first mode. If this is the case, the first switch is closed, and when the storage battery is set to the first mode, the remaining charge of the storage battery is a value equal to or higher than the first value. When the value decreases to the value or less, the first switch is opened and a charging instruction is given to the storage battery via the hybrid power controller.

In claim 4, the second switch provided in the second electric circuit connecting the important load capable of supplying electric power from the storage battery and the hybrid power controller even when a power failure occurs, the important load and the fuel. The fuel cell is provided with a third switch provided in a third electric circuit for connecting the battery, and the fuel cell has an interconnection operation mode in which the fuel cell is operated in connection with the grid power supply and the grid power supply in the event of a power failure. When the storage battery is set to the first mode and the remaining charge of the storage battery is reduced to the fifth value or less. The fuel cell is switched to the self-sustaining operation mode when the first switch is opened and a pseudo power failure occurs, and the control unit opens the second switch. The third switch is closed.

As the effect of the present invention, the following effects are exhibited.

In claim 1, since the storage battery does not charge the electric power flowing from the fuel cell to the grid power supply side, the power generation capable of generating electricity by using natural energy is based on the detection results of the first detection unit and the second detection unit. It is possible to accurately grasp the amount of power sold from the unit and the amount of power sold from the fuel cell.

According to the second aspect, since it is difficult for the storage battery to switch to the second mode, it is possible to prevent the storage battery from charging the electric power flowing from the fuel cell to the system power supply side.

In claim 3, since power does not flow from the fuel cell to the system power supply side, the storage battery does not charge the power from the fuel cell even if it is charged. Therefore, the amount of power sold from the power generation unit and the amount of power sold from the fuel cell can be accurately grasped.

In claim 4, the electric power generated by the fuel cell can be supplied to an important load instead of reverse power flow to the grid power source. Therefore, it is possible to prevent the electric power generated by the fuel cell from being wasted.

The block diagram which showed the structure of the power supply system which concerns on 1st Embodiment of this invention. The block diagram which showed an example of the electric power supply mode of the eco mode in 1st Embodiment. The block diagram which showed an example of the power supply mode of the supplementary charge mode in 1st Embodiment. The block diagram which showed the structure of the power supply system which concerns on 2nd Embodiment of this invention. The block diagram which showed an example of the electric power supply mode of the eco mode in 2nd Embodiment. The block diagram which showed an example of the electric power supply mode of the charge instruction mode in 2nd Embodiment. The block diagram which showed the structure of the power supply system which concerns on 3rd Embodiment of this invention. The block diagram which showed an example of the electric power supply mode of the eco mode in 3rd Embodiment. The block diagram which showed an example of the electric power supply mode of the charge instruction mode in 3rd Embodiment. The block diagram which showed the structure of the power supply system which concerns on 4th Embodiment of this invention. The block diagram which showed an example of the electric power supply mode of the eco mode in 4th Embodiment. The block diagram which showed an example of the electric power supply mode of the charge instruction mode in 4th Embodiment.

Hereinafter, the power supply system 1 according to the embodiment of the present invention will be described with reference to FIG. In this specification, the "upstream side" and the "downstream side" are based on the power supply direction from the system power supply K.

The power supply system 1 shown in FIG. 1 supplies the power from the system power supply K and the generated power to the load H. The power supply system 1 is provided in a building such as a house, and supplies power to a load H (for example, housing equipment or the like) of the building. The power supply system 1 mainly includes a power storage system 10, a distribution board 20, a fuel cell 30, a sensor 40, a power trading meter 50, and a power selling meter 60.

The power storage system 10 stores electric power and supplies it to the load H. The power storage system 10 is provided between the system power supply K and the load H. The power storage system 10 includes a solar power generation unit 11, a storage battery 12, and a hybrid power conditioner 13.

The photovoltaic power generation unit 11 is a device that uses sunlight to generate electricity. The photovoltaic power generation unit 11 is composed of a solar cell panel or the like. The photovoltaic power generation unit 11 is installed in a sunny place such as on the roof of a house.

The storage battery 12 is configured to be rechargeable with electric power. The storage battery 12 is composed of, for example, a lithium ion battery. The storage battery 12 is connected to the photovoltaic power generation unit 11 via a hybrid power conditioner 13 described later.

The hybrid power conditioner 13 is a device (hybrid power conditioner) that appropriately converts electric power. The hybrid power controller 13 can output the electric power generated by the solar power generation unit 11 and the electric power discharged from the storage battery 12 to the distribution line L (load H), and the electric power flowing through the distribution line L (from the system power supply K). The electric power and the electric power generated by the fuel cell) can be output to the storage battery 12. Further, the hybrid power conditioner 13 is configured to be able to acquire information on the performance and operating state of the photovoltaic power generation unit 11 and the storage battery 12. The hybrid power conditioner 13 is connected to the middle portion (connection point P) of the distribution line L connecting the system power supply K and the load H (distribution board 20) via the electric line A1. The hybrid power conditioner 13 of the power storage system 10 can perform a load following operation for adjusting the electric power to be discharged (output) based on the detection result of the sensor 40 described later.

The distribution board 20 distributes electric power to the load H. The distribution board 20 is provided on the downstream side of the power storage system 10 (connection point P) and is connected to each load H. Although only one load H is shown in FIG. 1, the distribution board 20 is connected to a plurality of loads and distributes electric power to each load. The distribution board 20 supplies the electric power from the system power supply K, the electric power discharged from the storage battery 12, and the electric power from the fuel cell 30, which will be described later, to the load H.

The fuel cell 30 is a device that generates electricity using gas fuel such as hydrogen. The fuel cell 30 is composed of a solid oxide fuel cell (SOFC: Solid Oxide Fuel Cell), a control unit, and the like. The fuel cell 30 is connected to the distribution board 20 via the electric circuit A2, and is connected to the load H via the distribution board 20.

The sensor 40 is provided in the middle of the distribution line L. More specifically, the sensor 40 is provided on the upstream side (immediately upstream side of the connection point P) of the power storage system 10 (connection point P). The sensor 40 detects the voltage (supply voltage) and the current (supply current) of the electric power (electric power flowing to the upstream side and electric power flowing to the downstream side) flowing through the location where the sensor 40 is provided.

The trading power meter 50 measures the amount of power flowing upstream at the location where the trading power meter 50 is provided (the middle part of the distribution line L), that is, the amount of power sold to the grid power supply K (electric power company). is there. Further, the trading power meter 50 measures the amount of power flowing downstream at the location where the trading power meter 50 is provided, that is, the amount of power purchased from the grid power supply K. The trading power meter 50 is provided on the upstream side of the power storage system 10. More specifically, the trading power meter 50 is provided between the system power supply K and the sensor 40.

The amount of power that is reversely flowed from the power storage system 10 to the grid power supply K (the amount of power sold from the solar power generation unit 11) and the amount of power sold from the fuel cell 30 to the grid power supply K by the power trading meter 50 arranged in this way. It is possible to measure the total electric energy (electric energy sold) with the amount of power that is reverse power flow (electric energy sold from the fuel cell 30).

The power selling meter 60 measures the amount of electric power flowing to the upstream side at a location (midway portion of the distribution line L) where the power selling meter 60 is provided. The power selling meter 60 is provided on the downstream side of the power storage system 10 and on the upstream side of the load H and the fuel cell 30. More specifically, the power selling meter 60 is provided between the power storage system 10 (connection point P) and the distribution board 20.

The power selling meter 60 arranged in this way can measure the amount of power (the amount of power sold from the fuel cell 30) that is reversely flowed from the fuel cell 30 to the system power supply K. Further, the amount of power sold from the power storage system 10 (solar power generation unit 11) can be calculated from the difference between the detected value of the power selling meter 50 and the detected value of the power selling meter 60. However, when the storage battery 12 charges the power flowing from the fuel cell 30 to the upstream side (system power supply K side), the detected value of the power selling meter 60 does not indicate the amount of power sold from the fuel cell 30. .. Details of this point will be described later.

Next, the power supply mode (mode) in the power supply system 1 will be described.

The power supply system 1 has an eco mode (first mode) and a supplementary charging mode (second mode) as power supply modes (modes).

The eco-mode is a mode for the purpose of consuming the electric power generated by the photovoltaic power generation unit 11 at the load H (obtaining an energy saving effect by consuming the electric power at the load H). In the eco mode, the hybrid power conditioner 13 charges and discharges the storage battery 12 by load following operation based on the detection result of the sensor 40.

Specifically, when the sensor 40 detects the electric power flowing to the downstream side (distribution board 20 side), the hybrid power conditioner 13 discharges the storage battery 12 based on the detection result. Further, when the sensor 40 detects the electric power flowing to the upstream side (system power supply K side), the hybrid power conditioner 13 charges the storage battery 12 based on the detection result. The hybrid power conditioner 13 does not charge / discharge the storage battery 12 (standby) when the sensor 40 does not detect the power flowing to the downstream side (distribution board 20 side) and the upstream side (system power supply K side). ..

In this way, when the sensor 40 detects the electric power flowing to the downstream side (distribution board 20 side) in the power storage system 10, the electric power discharged from the storage battery 12 flows to the distribution line L based on the detection result. Is done. In this case, if there is electric power generated by the photovoltaic power generation unit 11, the electric power is also sent to the distribution line L. In this way, the electric power flowing through the distribution line L flows to the load H side.

When the sensor 40 detects the electric power flowing to the upstream side (system power supply K side), the electric power generated by the photovoltaic power generation unit 11 is charged to the storage battery 12 based on the detection result. At this time, the hybrid power conditioner 13 does not charge the storage battery 12 with the electric power flowing through the distribution line L. That is, the hybrid power conditioner 13 does not charge the storage battery 12 with the electric power from the system power supply K, and does not charge the storage battery 12 with the electric power flowing from the fuel cell 30 to the upstream side (system power supply K side). Of the electric power generated by the photovoltaic power generation unit 11, the electric power that cannot be fully charged by the storage battery 12 is reverse-flowed to the grid power source K.

The supplementary charging mode is a mode for maintaining the performance of the storage battery 12. In the supplementary charging mode, when the remaining charge of the storage battery 12 is reduced to a predetermined value x 1 (first value) or less, the hybrid power conditioner 13 charges the storage battery 12. Here, the "remaining storage amount" indicates the remaining amount of electric power stored in the storage battery 12, and in the present specification, it is expressed as the ratio of the stored amount to the maximum capacity of the storage battery 12. Further, the "predetermined value x1" is set to an appropriate value, for example, 5%.

In the supplementary charging mode, the storage battery 12 is charged with a predetermined charging power (for example, maximum charging power). Here, the "maximum charging power" refers to the maximum amount of power that the storage battery 12 can charge per unit time. In the present embodiment, the maximum charging power of the storage battery 12 is assumed to be 2000 W.

In the supplementary charging mode, the hybrid power conditioner 13 can charge the storage battery 12 from any of the photovoltaic power generation unit 11, the system power supply K, and the fuel cell 30. If there is electric power generated by the photovoltaic power generation unit 11, the hybrid power conditioner 13 charges the storage battery 12 with the electric power. If the maximum charging power (2000W) is still less than the maximum charging power (2000W), the hybrid power conditioner 13 charges the storage battery 12 with the power generated by the fuel cell 30. If the maximum charging power (2000 W) is still not reached, the hybrid power conditioner 13 charges the storage battery 12 with the power from the system power supply K.

In the power supply system 1 according to the present embodiment, the mode of the storage battery 12 (hybrid power conditioner 13) is set so that only the eco mode can be selected by the user of the system. Then, the mode is forcibly switched to the supplementary charging mode only when the remaining charge of the storage battery 12 becomes a predetermined value x 1 (5%) or less. In the supplementary charging mode, when the remaining charge of the storage battery 12 increases to a predetermined value (for example, 30%), the mode of the storage battery 12 is switched to the eco mode again.

Hereinafter, the power supply mode by the power supply system 1 when the storage battery 12 is set to the eco mode will be specifically described with reference to FIG.

In FIG. 2, it is assumed that the total power consumption of the load H is 500 W, the generated power of the photovoltaic power generation unit 11 is 0 W (in a state where no power is generated), and the generated power of the fuel cell 30 is 700 W.

At this time, a part of the electric power (500W) generated by the fuel cell 30 (700W) is supplied to the load H via the distribution board 20. Then, the remaining electric power (200 W) of the generated electric power (700 W) of the fuel cell 30 is reverse-flowed to the system power supply K without being charged in the storage battery 12. This electric power passes through the power selling meter 60 and the trading power meter 50. Therefore, the detected value of the power selling meter 60 and the detected value of the trading power meter 50 are 200 W (power selling), respectively.

Therefore, from the detected value of the power selling meter 60, it can be grasped that the amount of power sold from the fuel cell 30 is 200 W. Further, from the detected value of the power trading meter 50, it can be grasped that the total power sales amount of the power sales amount from the solar power generation unit 11 and the power sales amount from the fuel cell 30 is 200 W. Therefore, it is possible to calculate (understand) that the amount of power sold from the photovoltaic power generation unit 11 is 0 W by the difference between the detected value (200 W) of the power selling meter 50 and the detected value (200 W) of the power selling meter 60. it can.

As described above, in the eco mode, the electric power flowing from the fuel cell 30 to the upstream side (system power supply K side) is not charged by the storage battery 12. Therefore, even if it is recognized that the power is sold from the fuel cell 30 to the system power supply K according to the detected value of the power selling meter 60, the power is not actually sold (the storage battery 12 is charged). The situation such as) does not occur. Therefore, the amount of power sold from the photovoltaic power generation device and the amount of power sold from the fuel cell can be accurately grasped from the detection results of the power selling meter 50 and the power selling meter 60.

Next, with reference to FIG. 3, the power supply mode by the power supply system 1 when the storage battery 12 is set to the supplementary charging mode will be specifically described.

In FIG. 3, the total power consumption of the load H is 500 W, the generated power of the photovoltaic power generation unit 11 is 0 W (in a state where no power is generated), the generated power of the fuel cell 30 is 700 W, and the charging power of the storage battery 12 is 2000 W. Suppose there is.

At this time, a part of the electric power (500W) generated by the fuel cell 30 (700W) is supplied to the load H via the distribution board 20. Then, the remaining electric power (200 W) of the generated electric power (700 W) of the fuel cell 30 is sent to the upstream side (system power supply K side).

The storage battery 12 charges the electric power (200 W) from the fuel cell 30. Even so, the maximum charging power (2000W) is not reached, so the storage battery 12 purchases a shortage of power (1800W) with respect to the maximum charging power (2000W) from the system power supply K and charges the power.

At this time, the detected value of the trading power meter 50 is 1800 W (power purchase), which matches the actual situation. On the other hand, the detected value of the power selling meter 60 is 200 W (power sold), but in reality, the power (200 W) from the fuel cell 30 is not reverse power flowed to the grid power supply K (power sold). The storage battery 12 is charged.

As described above, in the supplementary charging mode, the detection result of the power selling meter 60 and the actual situation are different. Due to such a difference, it may not be possible to accurately grasp each amount of electricity sold.

Therefore, in the power supply system 1 according to the present embodiment, when the storage battery 12 is set to the eco mode and the remaining charge is reduced to a predetermined value x 2 (second value) or less, the storage battery 12 is discharged. Is set so that Here, the "predetermined value x2" is set to an appropriate value larger than the predetermined value x1 (threshold value when switching from the eco mode to the supplementary charging mode), and is set to, for example, 30%.

As a result, it is possible to suppress a decrease in the remaining storage amount of the storage battery 12, so that it is possible to suppress the remaining storage amount from becoming a predetermined value x 1 (5%) or less, and by extension, the storage battery 12 is supplemented from the eco mode. It becomes difficult to switch to the charging mode. In the eco mode, the power flowing from the fuel cell 30 to the upstream side (system power supply K side) is not charged by the storage battery 12, so that the detection results of the power trading meter 50 and the power selling meter 60 and the actual situation (power). It is possible to prevent a difference from the flow).

As described above, the power supply system 1 according to the present embodiment is provided between the system power supply K and the load H, and has a solar power generation unit 11 (power generation unit) capable of generating electricity by using natural energy and the system. A storage battery 12 provided between the power source K and the load H and capable of charging and discharging the power from the solar power generation unit 11, and power from the system power supply K rather than the solar power generation unit 11 and the storage battery 12. The fuel cell 30 connected to the load H on the downstream side in the supply direction is provided on the upstream side in the power supply direction from the system power supply K with respect to the solar power generation unit 11 and the storage battery 12, and at least the upstream side. A power trading meter 50 (first detection unit) capable of detecting the electric power flowing to the solar power generation unit 11, the downstream side of the solar power generation unit 11 and the storage battery 12, and the upstream side of the load H and the fuel cell 30. A power selling meter 60 (second detection unit) provided on the side and capable of detecting at least the power flowing to the upstream side is provided, and the storage battery 12 includes power from the system power supply K and the fuel cell 30. It is set to the eco mode (first mode) in which the electricity from the battery cannot be charged.
With this configuration, the storage battery 12 does not charge the power flowing from the fuel cell 30 to the grid power supply K side, so that the photovoltaic power generation unit 11 determines the detection results of the power trading meter 50 and the power selling meter 60. It is possible to accurately grasp the amount of power sold and the amount of power sold from the fuel cell 30.

Further, the power supply system 1 according to the present embodiment is provided between the system power supply K and the load H, and has a solar power generation unit 11 (power generation unit) capable of generating electricity by using natural energy and the system power supply K. A storage battery 12 provided between the and the load H and capable of charging and discharging the electric power from the solar power generation unit 11, and a power supply direction from the system power supply K rather than the solar power generation unit 11 and the storage battery 12. A distribution board 20 provided on the downstream side of the above, which distributes electric power to the load H, and a fuel cell 30 connected to the distribution board 20 on the downstream side of the solar power generation unit 11 and the storage battery 12. A power trading meter 50 (first detection) provided on the upstream side of the solar power generation unit 11 and the storage battery 12 in the power supply direction from the system power supply K and capable of detecting at least the power flowing to the upstream side. Unit) and the electric power flowing to at least the upstream side provided on the downstream side of the solar power generation unit 11 and the storage battery 12 and on the upstream side of the distribution board 20 and the fuel cell 30. The storage battery 12 includes a detectable power selling meter 60 (second detection unit), and the storage battery 12 is in an eco-mode (first mode) in which the power from the system power supply K and the power from the fuel cell 30 cannot be charged. ) Is set.
With this configuration, the storage battery 12 does not charge the power flowing from the fuel cell 30 to the grid power supply K side, so that the photovoltaic power generation unit 11 determines the detection results of the power trading meter 50 and the power selling meter 60. It is possible to accurately grasp the amount of power sold and the amount of power sold from the fuel cell 30.

Further, the storage battery 12 is capable of charging the electric power from the system power source K and the electric power from the fuel cell 30 when the remaining storage amount is reduced to a predetermined value x 1 (first value, for example, 5%) or less. It is set to the charging mode (second mode), and when the storage battery 12 is set to the eco mode, the stored remaining amount is a predetermined value x2 (second value, which is larger than the predetermined value x1. For example, when it decreases to 30%) or less, it is set so that it cannot be discharged.
With such a configuration, it becomes difficult for the storage battery 12 to switch to the supplementary charging mode, so that it is possible to prevent the storage battery 12 from charging the electric power flowing from the fuel cell 30 to the system power supply K side.

The solar power generation unit 11 according to this embodiment is an embodiment of the power generation unit.
Further, the trading power meter 50 according to this embodiment is an embodiment of the first detection unit.
Further, the power selling meter 60 according to this embodiment is an embodiment of the second detection unit.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the present embodiment, the power generation unit uses sunlight to generate power (photovoltaic power generation unit 11), but other natural energy (for example, hydraulic power or wind power) is used to generate power. There may be.

Further, in the present embodiment, the trading power meter 50 is used as the first detection unit, but the first detection unit detects the amount of power (power sales amount) flowing to the upstream side (system power supply K side). It may be possible, and the amount of power flowing to the downstream side (load H side) (power purchase amount) may not be detectable.

Further, in the present embodiment, the power selling meter 60 is used as the second detection unit, but the second detection unit is in addition to the amount of power flowing to the upstream side (system power supply K side) (power sales amount). Therefore, the amount of power flowing to the downstream side (load H side) (power purchase amount) may also be detectable (trading meter).

Further, in the present embodiment, both the photovoltaic power generation unit 11 and the storage battery 12 are connected to the distribution line L via the hybrid power conditioner 13, but the photovoltaic power generation unit 11 and the storage battery 12 each use different power conditioners. It may be connected to the distribution line L via.

Next, the power supply system 2 according to the second embodiment of the present invention will be described with reference to FIG.

The main difference between the power supply system 2 according to the second embodiment and the power supply system 1 according to the first embodiment is that it further includes a first switch 70, an electric circuit A3, a second switch 80, and an EMS 90. Is. Therefore, in the following, among the power supply systems 2 according to the second embodiment, the same configurations as the power supply system 1 according to the first embodiment are designated by the same reference numerals and description thereof will be omitted.

The first switch 70 switches whether or not electric power can be distributed. The first switch 70 is provided in the electric line A1 that connects the distribution line L and the hybrid power conditioner 13 between the sensor 40 and the power selling meter 60.

The electric circuit A3 is formed so as to connect the distribution line L and the hybrid power conditioner 13 on the downstream side of the power selling meter 60 and on the upstream side of the load H and the fuel cell 30. More specifically, one end of the electric circuit A3 is connected to the distribution board 20, and the other end of the electric circuit A3 is connected to the electric circuit A1 between the first switch 70 and the hybrid power conditioner 13.

The second switch 80 switches whether or not electric power can be distributed. The second switch 80 is provided in the electric circuit A3.

The EMS 90 is an energy management system (Energy Management System) that manages the operation of the power supply system 1. The EMS 90 includes an arithmetic processing unit such as a CPU, a storage unit such as a RAM or ROM, an input / output unit such as a touch panel, and the like. Various information, programs, and the like used when controlling the operation of the power supply system 1 are stored in advance in the storage unit of the EMS 90. The arithmetic processing unit of the EMS 90 can operate the power supply system 1 by executing the program and performing predetermined arithmetic processing or the like using the various information.

The EMS 90 is electrically connected to the hybrid power conditioner 13. The EMS 90 can transmit a predetermined signal to the hybrid power conditioner 13 to control the operation of the storage battery 12 (for example, charging / discharging of the storage battery 12). Further, the EMS 90 is configured so that a predetermined signal can be input from the hybrid power conditioner 13, and the remaining charge of the storage battery 12 can be acquired.

Further, the EMS 90 is electrically connected to the first switch 70 and the second switch 80. The EMS 90 can control the operation (opening / closing) of the first switch 70 and the second switch 80.

In the eco mode, the EMS 90 sets the first switch 70 in the closed state and the second switch 80 in the open state (see FIG. 4). As a result, electric power can be circulated in the electric circuit A1, and electric power cannot be circulated in the electric circuit A3.

The power supply system 2 according to the second embodiment has a charging instruction mode in addition to the eco mode and the supplementary charging mode as the power supply mode.

The charging instruction mode is a mode in which the storage battery 12 is charged according to a charging instruction from the EMS 90 before switching to the supplementary charging mode.

When the storage battery 12 is set to the eco mode, if the remaining charge of the storage battery 12 decreases to a predetermined value x 3 (third value) or less, the mode of the storage battery 12 is switched from the eco mode to the charging instruction mode. .. In the charging instruction mode, the EMS 90 switches the first switch 70 to the open state and the second switch 80 to the closed state. Here, the "predetermined value x3" is set to an appropriate value equal to or higher than the predetermined value x1 (threshold value when switching from the eco mode to the supplementary charging mode), and is set to, for example, 10%. Then, the EMS 90 gives a charging instruction to the storage battery 12 via the hybrid power conditioner 13. The storage battery 12 that has received the charging instruction charges with the maximum charging power (2000 W).

When the remaining charge of the storage battery 12 is increased to a predetermined value x 4 (fourth value) by the charging instruction, the mode of the storage battery 12 is switched from the charging instruction mode to the eco mode. In the eco mode, the EMS 90 switches the first switch 70 to the closed state and the second switch 80 to the open state. Then, the EMS 90 stops the charging instruction. Here, the "predetermined value x4" is set to an appropriate value larger than the predetermined value x3 (threshold value when switching from the eco mode to the charging instruction mode), and is set to, for example, 30%.

Hereinafter, the power supply mode by the power supply system 2 when the storage battery 12 is set to the eco mode will be specifically described with reference to FIG.

In FIG. 5, it is assumed that the total power consumption of the load H is 500 W, the generated power of the photovoltaic power generation unit 11 is 0 W (in a state where no power is generated), and the generated power of the fuel cell 30 is 700 W.

As described above, in the eco mode, electric power can be circulated in the electric circuit A1 and electric power cannot be circulated in the electric circuit A3. Therefore, the power flow is the same as in the first embodiment. That is, a part of the electric power (500W) generated by the fuel cell 30 (700W) is supplied to the load H via the distribution board 20. Then, the remaining electric power (200 W) of the generated electric power (700 W) of the fuel cell 30 is reverse-flowed to the system power supply K without being charged in the storage battery 12.

When the remaining charge of the storage battery 12 becomes a predetermined value x3 (10%) or less due to a reason such as a temporary increase in the power consumption of the load H, the mode of the storage battery 12 is switched from the eco mode to the charging instruction mode. ..

Hereinafter, the power supply mode by the power supply system 2 when the storage battery 12 is set to the charge instruction mode will be specifically described with reference to FIG.

In FIG. 6, the total power consumption of the load H is 500 W, the generated power of the photovoltaic power generation unit 11 is 0 W (in a state where no power is generated), the generated power of the fuel cell 30 is 700 W, and the charging power of the storage battery 12 is 2000 W. Suppose there is.

In the charging instruction mode, the EMS 90 switches the first switch 70 to the open state and the second switch 80 to the closed state. Then, the EMS 90 gives a charging instruction to the storage battery 12 via the hybrid power conditioner 13.

The storage battery 12 that has received the charging instruction charges with the maximum charging power (2000 W). As shown in FIG. 6, the storage battery 12 charges the electric power (200 W) from the fuel cell 30. Even so, the maximum charging power (2000W) is not reached, so the storage battery 12 purchases a shortage of power (1800W) with respect to the maximum charging power (2000W) from the system power supply K and charges the power.

At this time, since the first switch 70 is in the open state and the second switch 80 is in the closed state, the electric power (200 W) from the fuel cell 30 and the electric power (1800 W) from the system power supply K are transmitted through the electric circuit A3. It is supplied to the storage battery 12. Therefore, the electric power (200 W) from the fuel cell 30 is charged to the storage battery 12 without passing through the power selling meter 60. Therefore, the detected value of the power selling meter 60 is 0 W, which matches the actual situation.

In this way, when the remaining charge of the storage battery 12 becomes a predetermined value x3 (10%) or less, the first switch 70 and the second switch 80 are switched, and a charging instruction is given to the storage battery 12 to supplement from the eco mode. It is possible to prevent the switch to the charging mode. Further, even if the storage battery 12 charges the electric power flowing from the fuel cell 30 to the upstream side (system power supply K side) according to the charging instruction, this electric power is not detected by the power selling meter 60. That is, the power sale meter 60 detects the power sale only when the power from the fuel cell 30 is actually reverse-flowed to the system power supply K. Therefore, the amount of power sold from the fuel cell 30 can be accurately grasped.

In the charging instruction mode, when the remaining charge of the storage battery 12 increases to a predetermined value x 4 (30%) by the charging instruction, the mode of the storage battery 12 is switched from the charging instruction mode to the eco mode. In the eco mode, the EMS 90 switches the first switch 70 to the closed state and the second switch 80 to the open state (returns to the state shown in FIG. 5). Then, the EMS 90 stops the charging instruction.

As a result, when there is power that is reversely flowed from the photovoltaic power generation unit 11 to the system power supply K, it is possible to prevent the power from being detected by the power selling meter 60. More specifically, when the charging instruction is stopped, if the first switch 70 remains in the open state and the second switch 80 remains in the closed state (the state shown in FIG. 6), the system power supply from the photovoltaic power generation unit 11 The electric power that is reversely flowed to K flows to the system power supply K via the electric circuit A3, and is therefore detected by the power selling meter 60. Since the power selling meter 60 detects the amount of power sold from the fuel cell 30, if the amount of power sold from the photovoltaic power generation unit 11 is also detected, the accurate amount of power sold cannot be grasped.

On the other hand, in the present embodiment, when the charging instruction is stopped, the first switch 70 is returned to the closed state and the second switch 80 is returned to the open state. Therefore, the power that is reversely flowed from the photovoltaic power generation unit 11 to the grid power supply K flows to the grid power supply K via the electric circuit A1 and is not detected by the power selling meter 60. Therefore, the amount of power sold from the photovoltaic power generation unit 11 and the amount of power sold from the fuel cell 30 can be accurately grasped.

As described above, in the power supply system 2 according to the second embodiment, when the remaining charge of the storage battery 12 is reduced to a predetermined value x 1 (first value, for example, 5%) or less, the storage battery 12 is supplied from the system power supply K. It is set to a supplementary charging mode (second mode) capable of charging electric power and electric power from the fuel cell 30, and the electric power supply system 2 connects the solar power generation unit 11 and the storage battery 12 to each other. At the same time, the electric power from the solar power generation unit 11 and the electric power from the storage battery 12 can be output to the distribution wire L connecting the system power supply K and the load H, and the electric power from the solar power generation unit 11 can be output. The hybrid power controller 13 capable of outputting the electric power of the above and the electric power flowing through the distribution line L to the storage battery 12, and the distribution on the downstream side of the power trading meter 50 and on the upstream side of the power selling meter 60. From the first switch 70 provided in the electric path A1 (first electric path) connecting the electric wire L and the hybrid power controller 13, the downstream side of the trading power meter, the load H, and the fuel battery 30. The second switch 80 provided in the electric line A3 (second electric line) connecting the distribution wire L and the hybrid power controller 13 on the upstream side, and the first switch 70 and the second switch 80. It includes an EMS 90 (control unit) that controls the operation and controls the operation of the storage battery 12 via the hybrid power controller 13, and the EMS 90 is when the storage battery 12 is set to the eco mode. When the remaining charge of the storage battery 12 decreases to a predetermined value x3 (third value, for example, 10%) or less, which is a value equal to or higher than the predetermined value x1 (5%), the first switch 70 is opened. The second switch 80 is closed, and a charging instruction is given to the storage battery 12 via the hybrid power controller 13.
With this configuration, even if the storage battery 12 charges the electric power flowing from the fuel cell 30 to the system power supply K side, it is possible to prevent the electric power from being detected by the power selling meter 60. Therefore, the amount of power sold from the photovoltaic power generation unit 11 and the amount of power sold from the fuel cell 30 can be accurately grasped.

Further, the EMS 90 is the first switch when the remaining charge of the storage battery 12 is increased to a predetermined value x4 (fourth value, for example, 30%) larger than the third value by the charging instruction. The 70 is closed, the second switch 80 is opened, and the charging instruction is stopped.
With such a configuration, it is possible to prevent the electric power flowing back from the photovoltaic power generation unit 11 to the system power supply K from being detected by the power selling meter 60. Therefore, the amount of power sold from the photovoltaic power generation unit 11 and the amount of power sold from the fuel cell 30 can be accurately grasped.

Although the second embodiment of the present invention has been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the second embodiment, when the charging instruction is given by the EMS 90, the storage battery 12 is charged with the maximum charging power, but the charging power (charge amount per unit time) is set to an arbitrary value. (The same applies to the third embodiment and the fourth embodiment described later).

Next, the power supply system 3 according to the third embodiment of the present invention will be described with reference to FIG. 7.

The main difference between the power supply system 3 according to the third embodiment and the power supply system 1 according to the first embodiment is that the power supply system 3 further includes the first switch 100 and the EMS 90. Therefore, in the following, among the power supply systems 3 according to the third embodiment, the same configurations as those of the power supply system 1 according to the first embodiment are designated by the same reference numerals and description thereof will be omitted.

The first switch 100 switches whether or not electric power can be distributed. The first switch 100 is provided in the electric circuit A2 that connects the distribution board 20 and the fuel cell 30.

The configuration and function of the EMS 90 are as described in the second embodiment. The EMS 90 is electrically connected to the first switch 100. The EMS 90 can control the operation (opening / closing) of the first switch 100.

In the eco mode, the EMS 90 closes the first switch 100 (see FIG. 7). As a result, electric power can be distributed in the electric circuit A2.

Similar to the second embodiment, the power supply system 3 according to the third embodiment has a charging instruction mode in addition to the eco mode and the supplementary charging mode as the power supply mode.

When the storage battery 12 is set to the eco mode and the remaining charge of the storage battery 12 decreases to a predetermined value x 5 (fifth value) or less, the mode of the storage battery 12 is switched from the eco mode to the charging instruction mode. .. In the charging instruction mode, the EMS 90 switches the first switch 100 to the open state. Here, the "predetermined value x5" is set to an appropriate value equal to or higher than the predetermined value x1 (threshold value when switching from the eco mode to the supplementary charging mode), and is set to, for example, 10%. Then, the EMS 90 gives a charging instruction to the storage battery 12 via the hybrid power conditioner 13. The storage battery 12 that has received the charging instruction charges with the maximum charging power (2000 W).

When the remaining charge of the storage battery 12 is increased to a predetermined value x 6 (sixth value) by the charging instruction, the mode of the storage battery 12 is switched from the charging instruction mode to the eco mode. In the eco mode, the EMS 90 switches the first switch 100 to the closed state. Then, the EMS 90 stops the charging instruction. Here, the "predetermined value x6" is set to an appropriate value larger than the predetermined value x5 (threshold value when switching from the eco mode to the charging instruction mode), and is set to, for example, 30%.

Hereinafter, the power supply mode by the power supply system 3 when the storage battery 12 is set to the eco mode will be specifically described with reference to FIG.

In FIG. 8, it is assumed that the total power consumption of the load H is 500 W, the generated power of the photovoltaic power generation unit 11 is 0 W (in a state where no power is generated), and the generated power of the fuel cell 30 is 700 W.

As described above, in the eco mode, electric power can be distributed in the electric circuit A2. Therefore, the power flow is the same as in the first embodiment. That is, a part of the electric power (500W) generated by the fuel cell 30 (700W) is supplied to the load H via the distribution board 20. Then, the remaining electric power (200 W) of the generated electric power (700 W) of the fuel cell 30 is reverse-flowed to the system power supply K without being charged in the storage battery 12.

When the remaining charge of the storage battery 12 becomes a predetermined value x 5 (10%) or less due to a reason such as a temporary increase in the power consumption of the load H, the mode of the storage battery 12 is switched from the eco mode to the charging instruction mode. ..

Hereinafter, the power supply mode by the power supply system 3 when the storage battery 12 is set to the charge instruction mode will be specifically described with reference to FIG.

In FIG. 9, the total power consumption of the load H is 500 W, the generated power of the photovoltaic power generation unit 11 is 0 W (in a state where no power is generated), the generated power of the fuel cell 30 is 700 W, and the charging power of the storage battery 12 is 2000 W. Suppose there is.

In the charging instruction mode, the EMS 90 switches the first switch 100 to the open state. Then, the EMS 90 gives a charging instruction to the storage battery 12 via the hybrid power conditioner 13.

Since the first switch 100 is in the open state, it is impossible to distribute electric power in the electric circuit A2. Therefore, even if the storage battery 12 receives a charging instruction, the power from the fuel cell 30 does not flow back to the system power supply K. Further, since the electric power from the fuel cell 30 does not pass through the power selling meter 60, the detected value of the power selling meter 60 is 0 W. Therefore, the detected value (0W) of the power selling meter 60 matches the actual situation where the power selling amount is 0. As shown in FIG. 9, the storage battery 12 charges the electric power (2000 W) from the system power supply K. Further, the electric power (500 W) from the system power supply K is supplied to the load H.

In this way, when the remaining charge of the storage battery 12 becomes a predetermined value x 5 (10%) or less, the first switch 100 is switched and the storage battery 12 is instructed to charge, so that the eco mode can be switched to the supplementary charging mode. Can be prevented. Further, even if the storage battery 12 receives the charging instruction according to the charging instruction, the power from the fuel cell 30 does not flow to the upstream side (system power supply K side) because the first switch 100 is opened. Absent. Therefore, the electric power flowing from the fuel cell 30 to the upstream side (system power supply K side) is not detected by the power selling meter 60. Therefore, it is possible to prevent a difference between the detection result of the power selling meter 60 and the actual situation.

In the charging instruction mode, when the remaining charge of the storage battery 12 increases to a predetermined value x 6 (30%) by the charging instruction, the mode of the storage battery 12 is switched from the charging instruction mode to the eco mode. In the eco mode, the EMS 90 switches the first switch 100 to the closed state (returns to the state shown in FIG. 8). Then, the EMS 90 stops the charging instruction.

As described above, in the power supply system 3 according to the third embodiment, when the remaining charge of the storage battery 12 is reduced to a predetermined value x 1 (first value, for example, 5%) or less, the storage battery 12 is supplied from the system power supply K. It is set to a supplementary charging mode (second mode) capable of charging electric power and electric power from the fuel cell 30, and the electric power supply system 3 connects the solar power generation unit 11 and the storage battery 12 to each other. At the same time, the electric power from the solar power generation unit 11 and the electric power from the storage battery 12 can be output to the distribution wire L connecting the system power supply K and the load H, and the power from the solar power generation unit 11 can be output. A hybrid power controller 13 capable of outputting the electric power of the above and the electric power flowing through the distribution line L to the storage battery 12, and a first electric circuit A2 (first electric circuit) for connecting the distribution board 20 and the fuel cell 30. The switch 100 includes an EMS 90 (control unit) that controls the operation of the first switch 100 and controls the operation of the storage battery 12 via the hybrid power controller 13, and the EMS 90 is the storage battery. When 12 is set to the eco mode, the first switch 100 is closed, and when the storage battery 12 is set to the eco mode, the remaining charge of the storage battery 12 is the predetermined value x1. When the value decreases to a predetermined value x 5 (fifth value, for example, 10%) or less, which is the above value, the first switch 100 is opened and the storage battery 12 is instructed to be charged via the hybrid power controller 13. Is to do.
With this configuration, power does not flow from the fuel cell 30 to the grid power supply K side, so that the storage battery 12 does not charge the power from the fuel cell 30 even if it is charged. Therefore, the amount of power sold from the photovoltaic power generation unit 11 and the amount of power sold from the fuel cell 30 can be accurately grasped.

Next, the power supply system 4 according to the fourth embodiment of the present invention will be described with reference to FIG.

The main difference between the power supply system 4 according to the fourth embodiment and the power supply system 3 according to the third embodiment is that the first specific circuit 110, the second specific circuit 120, the power failure circuit 130, the electric circuit A4, and the like. A second switch 140, an electric circuit A5, and a third switch 150 are provided. Therefore, in the following, the same configuration as the power supply system 3 according to the third embodiment of the power supply system 4 according to the fourth embodiment will be designated by the same reference numerals and description thereof will be omitted.

The first specific circuit 110 supplies electric power to an appropriate electric product or the like (electric power load). The first specific circuit 110 is connected to the hybrid power conditioner 13 and receives the electric power supplied through the hybrid power conditioner 13. Among the power loads provided in buildings such as houses, those that are preferably supplied with power even in the event of a power failure (important loads such as refrigerators and living room outlets) are connected to the first specific circuit 110. To.

The second specific circuit 120 supplies electric power to an appropriate electric product or the like (electric power load). The second specific circuit 120 is connected to the hybrid power conditioner 13 and receives the electric power supplied through the hybrid power conditioner 13. The second specific circuit 120 is connected to a power load provided in a building such as a house, which is preferably supplied with power even when a power failure occurs.

Both the first specific circuit 110 and the second specific circuit 120 are connected to the distribution board 20 via the hybrid power conditioner 13. During normal times (during non-power failure), electric power from the system power supply K can be supplied to the first specific circuit 110 and the second specific circuit 120 via the distribution board 20 and the hybrid power conditioner 13. Whether the load is classified into the first specific circuit 110 or the second specific circuit 120 is determined according to an appropriate standard (for example, power consumption).

The power failure circuit 130 supplies electric power to an appropriate electric product or the like (electric power load). The power failure circuit 130 is connected to the fuel cell 30 and receives the electric power supplied through the fuel cell 30. The power load provided in a building such as a house, which is preferably supplied with power when a power failure occurs (outlet or the like), is connected to the power failure circuit 130. The power failure circuit 130 is not connected to the distribution board 20.

In the fourth embodiment, the electric circuit A4 is arranged so as to connect the first specific circuit 110 and the hybrid power conditioner 13.

The second switch 140 switches whether or not electric power can be distributed. The second switch 140 is provided in the electric circuit A4.

In the fourth embodiment, the electric circuit A5 is arranged so as to connect the first specific circuit 110 and the fuel cell 30. More specifically, one end of the electric circuit A5 is connected to the fuel cell 30, and the other end of the electric circuit A5 is connected to the electric circuit A4 between the second switch 140 and the first specific circuit 110.

The third switch 150 switches whether or not electric power can be distributed. The third switch 150 is provided in the electric circuit A5.

In a fourth embodiment, the EMS 90 is electrically connected to the first switch 100, the second switch 140 and the third switch 150. The EMS 90 can control the operation (opening / closing) of the first switch 100, the second switch 140, and the third switch 150.

In the fourth embodiment, the fuel cell 30 has an interconnection operation mode and an independent operation mode as operation modes.

The interconnection operation mode is a mode in which the operation is performed in interconnection with the grid power supply K. The fuel cell 30 is normally set to the interconnection operation mode (during non-power failure). In the interconnection operation mode, the fuel cell 30 can output electric power via the electric circuit A2.

The self-sustaining operation mode is a mode in which self-sustaining operation is possible independently of the system power supply K when a power failure occurs. When the occurrence of a power failure is detected, the fuel cell 30 is set to the self-sustaining operation mode. In the self-sustaining operation mode, the fuel cell 30 can output electric power via the electric circuit A5.

In the fourth embodiment, when the storage battery 12 is set to the eco mode, the EMS 90 sets the first switch 100 in the closed state, the second switch 140 in the closed state, and the third switch 150 in the open state. (See FIG. 10). As a result, electric power can be circulated in the electric circuit A2 and A4, and electric power cannot be circulated in the electric circuit A5.

Similar to the second embodiment and the third embodiment, the power supply system 4 according to the fourth embodiment has a charging instruction mode in addition to the eco mode and the supplementary charging mode as the power supply mode.

Similar to the third embodiment, when the storage battery 12 is set to the eco mode and the remaining charge of the storage battery 12 is reduced to a predetermined value x 5 (10%) or less, the mode of the storage battery 12 is charged from the eco mode. You can switch to the instruction mode. In the charging instruction mode, the EMS 90 switches the first switch 100 to the open state, the second switch 140 to the open state, and the third switch 150 to the closed state. Then, the EMS 90 gives a charging instruction to the storage battery 12 via the hybrid power conditioner 13. The storage battery 12 that has received the charging instruction charges with the maximum charging power (2000 W).

When the remaining charge of the storage battery 12 is increased to a predetermined value x 6 (30%) by the charging instruction, the mode of the storage battery 12 is switched from the charging instruction mode to the eco mode. In the eco mode, the EMS 90 switches the first switch 100 to the closed state, the second switch 140 to the closed state, and the third switch 150 to the open state. Then, the EMS 90 stops the charging instruction.

Hereinafter, the power supply mode by the power supply system 4 when the storage battery 12 is set to the eco mode will be specifically described with reference to FIG.

In FIG. 11, the total power consumption of the load H is 400 W, the power consumption of the first specific circuit 110 is 100 W, the power consumption of the second specific circuit 120 is 0 W, and the power generated by the solar power generation unit 11 is 0 W (power generation). It is assumed that the generated power of the fuel cell 30 is 700 W.

As described above, in the eco mode, electric power can be distributed in the electric circuit A2. Therefore, a part of the electric power (400 W) generated by the fuel cell 30 (700 W) is supplied to the load H via the distribution board 20. Further, a part of the electric power (100 W) of the generated electric power (700 W) of the fuel cell 30 is supplied to the first specific circuit 110 via the distribution board 20, the hybrid power conditioner 13, and the electric circuit A4. Then, the remaining electric power (200 W) of the generated electric power (700 W) of the fuel cell 30 is reverse-flowed to the system power supply K without being charged in the storage battery 12.

When the remaining charge of the storage battery 12 becomes a predetermined value x 5 (10%) or less due to a reason such as a temporary increase in the power consumption of the load H, the mode of the storage battery 12 is switched from the eco mode to the charging instruction mode. ..

In the following, the power supply mode by the power supply system 4 when the storage battery 12 is set to the charge instruction mode will be specifically described with reference to FIG.

In FIG. 12, the total power consumption of the load H is 400 W, the power consumption of the first specific circuit 110 is 100 W, the power consumption of the second specific circuit 120 is 0 W, and the power generated by the solar power generation unit 11 is 0 W (power generation). It is assumed that the generated power of the fuel cell 30 is 100 W and the charging power of the storage battery 12 is 2000 W.

In the charging instruction mode, the EMS 90 switches the first switch 100 to the open state, the second switch 140 to the open state, and the third switch 150 to the closed state. Then, the EMS 90 gives a charging instruction to the storage battery 12 via the hybrid power conditioner 13.

Since the first switch 100 is in the open state, it is impossible to distribute electric power in the electric circuit A2. Therefore, even if the storage battery 12 receives a charging instruction, the power from the fuel cell 30 does not flow back to the system power supply K. Further, since the electric power from the fuel cell 30 does not pass through the power selling meter 60, the detected value of the power selling meter 60 is 0 W. Therefore, the detected value (0W) of the power selling meter 60 matches the actual situation where the power selling amount is 0. As shown in FIG. 12, the storage battery 12 charges the electric power (2000 W) from the system power supply K. Further, the electric power (400 W) from the system power supply K is supplied to the load H.

Further, when the first switch 100 is opened, the fuel cell 30 is put into a pseudo power failure state. Therefore, the operation mode of the fuel cell 30 can be switched from the interconnection mode to the independent operation mode.

At this time, since the second switch 140 is in the open state and the third switch 150 is in the closed state, the electric power (100 W) generated by the independent operation of the fuel cell 30 is stored in the storage battery via the electric circuit A4 and the hybrid power controller 13. It is not supplied to 12, but is supplied to the first specific circuit 110 via the electric circuit A5. Therefore, it is possible to prevent the electric power generated by the fuel cell 30 from being wasted.

As described above, the power supply system 4 according to the fourth embodiment connects the first specific circuit 110 (important load) capable of supplying power from the storage battery 12 even when a power failure occurs and the hybrid power controller 13. A second switch 140 provided in the electric circuit A4 (second electric circuit) and a third switch 150 provided in the electric circuit A5 (third electric circuit) connecting the first specific circuit 110 and the fuel cell 30. The fuel battery 30 has an interconnection operation mode in which the fuel battery 30 is operated in connection with the system power supply K, and an independent operation mode in which the fuel battery 30 can be operated independently from the system power supply K in the event of a power failure. When the storage battery 12 is set to the eco-mode, the storage remaining amount of the storage battery 12 is a predetermined value x5 (fifth value) larger than the predetermined value x1 (first value, for example, 5%). When the value is reduced to, for example, 10%) or less, the fuel battery 30 is switched to the self-sustaining operation mode when the first switch 100 is opened and a pseudo power failure occurs. The EMS 90 keeps the second switch 140 in the open state and the third switch 150 in the closed state.
With this configuration, the electric power generated by the fuel cell 30 can be supplied to the first specific circuit 110 instead of reverse power flow to the system power supply K. Therefore, it is possible to prevent the electric power generated by the fuel cell 30 from being wasted.

1 Power supply system 10 Power storage system 20 Distribution board 30 Fuel cell 50 Trading power meter 60 Power selling meter 70 First switch 80 Second switch 90 EMS
100 1st switch 110 1st specified circuit 140 2nd switch 150 3rd switch

Claims (4)

A power generation unit that is installed between the grid power supply and the load and can generate electricity using natural energy,
A storage battery provided between the system power supply and the load and capable of charging / discharging the power from the power generation unit,
A distribution board provided on the downstream side of the power generation unit and the storage battery in the power supply direction from the system power source and distributing power to the load.
A fuel cell connected to the distribution board on the downstream side of the power generation unit and the storage battery, and
A first detection unit provided on the upstream side of the power generation unit and the storage battery in the power supply direction from the system power source and capable of detecting at least the power flowing to the upstream side.
A second detection unit provided on the downstream side of the power generation unit and the storage battery and on the upstream side of the distribution board and the fuel cell and capable of detecting at least the electric power flowing to the upstream side.
Equipped with
The storage battery is
The power from the grid power source and the power from the fuel cell are set to the non-chargeable first mode.
Power supply system. The storage battery is
When the remaining charge is reduced to the first value or less, the power from the system power supply and the power from the fuel cell are set to the second mode in which the power can be charged.
When the storage battery is set to the first mode and the remaining charge is reduced to a second value larger than the first value, it is set to be non-dischargeable.
The power supply system according to claim 1. The storage battery is
When the remaining charge is reduced to the first value or less, the power from the system power supply and the power from the fuel cell are set to the second mode in which the power can be charged.
The power supply system
The power generation unit and the storage battery can be connected to each other, and the power from the power generation unit and the power from the storage battery can be output to the distribution line connecting the system power supply and the load, and from the power generation unit. And a hybrid power controller that can output the electric power flowing through the distribution line to the storage battery.
A first switch provided in the first electric circuit connecting the distribution board and the fuel cell, and
A control unit that controls the operation of the first switch and controls the operation of the storage battery via the hybrid power conditioner.
Equipped with
The control unit
When the storage battery is set to the first mode, the first switch is closed and the first switch is closed.
When the storage battery is set to the first mode and the remaining charge of the storage battery decreases to a value equal to or more than the first value and not more than a fifth value, the first switch is opened. At the same time, a charging instruction is given to the storage battery via the hybrid power conditioner.
The power supply system according to claim 1 or 2. A second switch provided in the second electric circuit connecting the important load capable of supplying electric power from the storage battery and the hybrid power conditioner even in the event of a power failure.
A third switch provided in the third electric circuit connecting the important load and the fuel cell,
Equipped with
The fuel cell
An interconnection operation mode in which operation is performed in connection with the system power supply,
Independent operation mode that enables independent operation independent of the system power supply when a power failure occurs,
Have,
When the remaining charge of the storage battery is reduced to the fifth value or less while the storage battery is set to the first mode,
The fuel cell is switched to the self-sustaining operation mode when the first switch is opened and a pseudo power failure occurs.
The control unit opens the second switch and closes the third switch.
The power supply system according to claim 3.

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