JP2014233144A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system in which learning function of a fuel cell is not blocked and all electric power generated at the fuel cell is effectively utilized.SOLUTION: A power supply system comprises: a first power sensor 110 which is arranged upstream of a distribution board 10; a fuel cell 90 which is arranged upstream of the distribution board 10, which includes learning function based on the detection result of the first power sensor 110, and which can generate power according to a power generation plan; a power storage device 30; and switching means which switches the placement of the power storage device 30 between downstream of the distribution board 10 and upstream of the first power sensor 110. In a case that the placement of the power storage device 30 is switched to downstream of the distribution board 10, surplus power left when power is supplied from the fuel cell 90 to the distribution board 10 is capable of being supplied to the power storage device 30. In a case that the placement of the power storage device 30 is switched to upstream of the first power sensor 110, power discharged from the power storage device 30 is capable of being supplied to the distribution board 10 after detection of the first power sensor 110.

Description

  The present invention relates to a technology of a power supply system.

  Conventionally, a distribution board provided on the downstream side in the direction of power supply from the commercial power supply and distributes power to the load, and provided upstream of the distribution board in the direction of power supply from the commercial power supply. A first power detection means for detecting the load, and a learning function that is provided on the upstream side of the distribution board and learns information related to the power consumption of the load based on a detection result of the first power detection means. A fuel cell capable of generating power according to a power generation plan that is updated as appropriate based on the learning function, and capable of charging power and discharging the charged power, and discharging the discharged power to the distribution board A technology of a power supply system including a power storage device to be supplied is publicly known. For example, as described in Patent Document 1.

  The technology (power interchange system) described in Patent Document 1 is provided on the downstream side in the supply direction of power from the commercial power supply rather than the power generation unit, and a distribution board (DC distribution board) that distributes power to the load, First power detection means (control unit) that is provided on the upstream side in the supply direction of power from the commercial power supply than the distribution board and detects power, provided on the upstream side from the distribution board, A fuel cell having a learning function for learning information related to power consumption of the load based on a detection result of the first power detection means, and capable of generating power according to a power generation plan that is appropriately updated based on the learning function; And a power storage device (storage battery) that can discharge the charged power and supply the discharged power to the distribution board.

  With such a configuration, in the technique described in Patent Document 1, not only electric power from a commercial power supply but also electric power from a fuel cell or a power storage device can be supplied to a distribution board, and load consumption is caused by electric power from these. Can provide power. Further, in the fuel cell, the power generation plan is appropriately updated by the learning function, and the power generated by the fuel cell can be supplied to the distribution board when the amount of power consumed by the load is relatively large.

  However, in the technique described in Patent Document 1, a predetermined problem may occur due to the arrangement of each device.

Below, the predetermined problem resulting from arrangement | positioning of each apparatus in the technique of patent document 1 is demonstrated using FIGS. 8-10.
8 to 10 illustrate the configuration of the technique described in Patent Document 1 in a simplified manner as appropriate.

  In the configuration of the technique (power supply system 501) described in Patent Document 1 shown in FIG. 8 (hereinafter referred to as “first configuration”), the commercial power source 200 and the distribution board 510 pass through the first power path 520. Connected through. Fuel cell 590 is arranged upstream of distribution board 510 in first power path 520. In addition, power storage device 530 is arranged upstream of fuel cell 590 in first power path 520. Further, the first power detection means 591 is disposed upstream of the fuel cell 590 and downstream of the power storage device 530 in the first power path 520 (between the fuel cell 590 and the power storage device 530). .

  In such a first configuration, even when surplus power (surplus power) is generated by supplying power generated by the fuel cell 590 to the distribution board 510, the power storage device 530 is connected to the first power path. Since the power is disposed upstream of the fuel cell 590 in 520, the power storage device 530 cannot be charged with the surplus power. That is, in the first configuration, there may be a problem that not all the electric power generated by the fuel cell 590 can be effectively used.

  In order to avoid the problem that occurs in the first configuration as described above, the configuration of the technique (power supply system 502) described in Patent Document 1 shown in FIG. 9 (hereinafter referred to as “second configuration”). is assumed. In the second configuration, the arrangement of power storage device 530 is set to be different from that in the first configuration. Specifically, the power storage device 530 is connected to the distribution board 510 via the second power path 540, and is disposed downstream of the distribution board 510 in the direction of power supply from the commercial power supply 200.

  In such a second configuration, when surplus power (surplus power) is generated by supplying the power generated by the fuel cell 590 to the distribution board 510, the surplus power is generated as shown in FIG. Can be supplied to the power storage device 530 through the second power path 540 and charged. That is, all of the electric power generated by the fuel cell 590 can be used effectively, and problems caused by the first configuration can be avoided.

  However, in the second configuration, when the power storage device 530 is discharged and supplies the discharged power to the distribution board 510, the discharged power does not pass through the first power path 520 as shown in FIG. Since the power is supplied to the distribution board 510, the first power detection means 591 does not detect it. Here, the learning function of the fuel cell 590 is to learn information related to the power consumption of the load based on the detection result of the first power detection means 591. That is, since the electric power discharged from the power storage device 530 is not detected by the first power detection unit 591, the fuel cell 590 cannot accurately learn the information regarding the power consumption of the load. Thus, in the second configuration, there may be a problem that the learning function of the fuel cell 590 is hindered.

JP 2011-101532 A

  The present invention has been made in view of the above situation, and the problem to be solved is that the learning function of the fuel cell is not hindered and that all the power generated by the fuel cell is effectively utilized. It is to provide a power supply system capable of

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

  That is, according to claim 1, a distribution board provided on the downstream side in the power supply direction from the commercial power supply to distribute power to the load, and an upstream in the power supply direction from the commercial power supply rather than the distribution board. A first power detection means provided on the side for detecting power, and information on the power consumption of the load based on the detection result of the first power detection means provided on the upstream side of the distribution board A fuel cell capable of generating power according to a power generation plan that is appropriately updated based on the learning function, and capable of charging power and discharging the charged power, and the discharged power And switching to switch the arrangement of the power storage device to either the downstream side of the distribution board or the upstream side of the first power detection means. hand When the arrangement of the power storage device is switched to the downstream side of the distribution board by the switching means, excess power supplied from the fuel cell to the distribution board is stored in the power storage When the arrangement of the power storage device is switched to the upstream side of the first power detection unit by the switching unit, the power discharged from the power storage device is supplied to the first power detection unit. After being detected, it can be supplied to the distribution board.

  The fuel cell power generation determination means for determining whether or not the fuel cell is generating power is provided, and the fuel cell power generation determination means determines whether the fuel cell is discharged when the power storage device discharges power. If it is determined that power is being generated, the switching means switches the arrangement of the power storage device to the downstream side of the distribution board, and the fuel cell power generation determination means determines that the fuel cell is not generating power. If determined, the switching unit switches the arrangement of the power storage device to the upstream side of the first power detection unit.

  According to a third aspect of the present invention, a first power path, a second power path, and a third power path through which power can be distributed are provided. One side of the first power path is connected to the commercial power source, and the other side is the distribution line. A first connection part provided in the middle is connected to the fuel cell, and the second power path can be connected to the power storage device on one side via the switching means, and on the other side The third power path is connected to the distribution board, and one side of the third power path is connectable to the power storage device via the switching means, and the other side is upstream of the first connection part in the first power path. Connected to a second connection portion provided on the side, wherein the switching means is configured by a changeover switch that connects the power storage device to either the second power path or the third power path in a switchable manner. It is.

  According to a fourth aspect of the present invention, the first power detection means is provided between the first connection portion and the second connection portion.

  In Claim 5, in the said 1st electric power path, the 2nd electric power detection means provided between the said distribution board and the said commercial power supply, and the said 2nd connection part in the said 1st electric power path, and the said 1st electric power path A third power detection means provided between the first connection portion and the distribution board for detecting power, wherein the power storage device discharges based on a detection result of the predetermined power detection means. A load following operation for changing the amount of electric power to be performed, and when the fuel cell power generation determination unit determines that the fuel cell is generating power, based on the detection result of the third power detection unit When the fuel cell power generation determining means determines that the fuel cell is not generating power, the load following operation is performed based on the detection result of the second power detection means.

  According to a sixth aspect of the present invention, a power generation unit capable of generating power using natural energy is provided, and the power generation unit is connected to one side of the first power path.

  As effects of the present invention, the following effects can be obtained.

  According to the first aspect, the learning function of the fuel cell is not hindered, and all of the electric power generated by the fuel cell can be used effectively.

  In claim 2, by switching the arrangement of the power storage device depending on whether or not the fuel cell is generating power, the learning function of the fuel cell is not hindered, and all of the power generated by the fuel cell is made effective. Can be used.

  In claim 3, the learning function of the fuel cell is not hindered by switching the arrangement of the power storage device with the changeover switch according to whether or not the fuel cell is generating electric power, and all the electric power generated by the fuel cell is Can be used effectively.

  According to the fourth aspect of the present invention, the number of power sensors used for the learning function of the fuel cell is not plural but only one.

  According to the fifth aspect, the load following operation of the power storage device can be performed regardless of the power supply mode when the power is discharged from the power storage device using the second power detection means and the third power detection means.

  According to the sixth aspect of the present invention, even when the power generation unit is provided, the learning function of the fuel cell is not hindered, and all the electric power generated by the fuel cell can be used effectively.

The block diagram which showed the structure of the electric power supply system which concerns on one Embodiment of this invention. The schematic diagram shown about the supply aspect of the electric power in the case of making an electrical storage apparatus charge electric power. The schematic diagram shown about the 1st supply aspect among the supply aspects of the electric power in the case of discharging electric power from an electrical storage apparatus. The schematic diagram shown about the 2nd supply aspect among the supply aspects of the electric power in the case of discharging electric power from an electrical storage apparatus. (A) The schematic diagram which showed the structure of a distribution board and an electric power path | route. (B) The schematic diagram which showed the electric power which distribute | circulates to the distribution board side similarly, when the electric power generated with the fuel cell is the maximum electric power generation amount. (C) The schematic diagram which showed the electric power which distribute | circulates to the commercial power source side similarly, when the electric power generated with the fuel cell is the maximum electric power generation amount. The schematic diagram which showed the state which is performing the load follow-up driving | operation of an electrical storage apparatus using the detection result of a 2nd electric power sensor, when the supply aspect of electric power is a 2nd supply aspect. The schematic diagram which showed the state which is carrying out the load follow-up driving | operation of an electrical storage apparatus using the detection result of a 3rd electric power sensor, when the supply mode of electric power is a 1st supply mode. The schematic diagram which showed the 1st structure which is an example of the conventional electric power supply system. The schematic diagram which showed the 2nd structure which is an example of the conventional electric power supply system. Similarly, the block diagram which showed the 2nd structure.

Below, the structure of the electric power supply system 1 which is one Embodiment of the "electric power supply system" concerning this invention is demonstrated using FIG.
In the following description, “upstream side” and “downstream side” are defined based on the power supply direction from the commercial power source 200 (that is, the direction from the commercial power source 200 to the distribution board 10 side).

  The power supply system 1 is provided in a house, supplies power from the commercial power source 200, the solar power generation unit 70, and the like to the distribution board 10 and appropriately supplies it to a load (not shown) (in-house load). . As shown in FIG. 1, the power supply system 1 mainly includes a distribution board 10, a first power path 20, a power storage device 30, a second power path 40, a third power path 50, a changeover switch 60, and a solar power generation unit 70. , A power conditioner 80, a fuel cell 90, a first power sensor 110, a second power sensor 120, and a third power sensor 130.

  The distribution board 10 is an embodiment of the “distribution board” according to the present invention. The distribution board 10 distributes the power supplied according to the power consumption of the load to the load. The distribution board 10 is connected to a commercial power source 200, a solar power generation unit 70, a fuel cell 90, and a power storage device 30 as a power supply source, and is configured so that power from these is appropriately supplied.

  In addition, in this embodiment, a load is a circuit to which an electrical appliance or the like that consumes power in the house is connected. The load is provided, for example, for each room or for each outlet dedicated to a device that consumes large electric power, and is connected to the distribution board 10 (not shown).

  The first power path 20 is an embodiment of the “first power path” according to the present invention. The first power path 20 is a path through which power can be distributed. The first power path 20 is composed of a conducting wire or the like. The first power path 20 has one side connected to the commercial power source 200 and the other side connected to the distribution board 10. As described above, the commercial power source 200 and the distribution board 10 are configured to allow power to flow through the first power path 20.

  The power storage device 30 is an embodiment of a “power storage device” according to the present invention. The power storage device 30 is a device that can charge power and discharge the charged power. The power storage device 30 includes a lithium ion battery, a power conditioner, a control unit, and the like (not shown). The power storage device 30 can discharge the charged power and supply it to the distribution board 10. Note that the power storage device 30 is configured to be capable of interconnecting with the commercial power source 200 (capable of system linkage). In addition, the power storage device 30 is configured to be capable of load following operation that changes the amount of electric power to be discharged based on detection results of a second power sensor 120 and a third power sensor 130 described later.

  The second power path 40 is an embodiment of the “second power path” according to the present invention. The second power path 40 is a path through which power can be distributed. The second power path 40 is composed of a conducting wire or the like. The second power path 40 has one side connected to the distribution board 10 and the other side connectable to the power storage device 30 via the changeover switch 60. As described above, the distribution board 10 and the power storage device 30 are configured to allow power to flow through the second power path 40 and the changeover switch 60.

  The third power path 50 is an embodiment of the “third power path” according to the present invention. The third power path 50 is a path through which power can be distributed. The third power path 50 is composed of a conducting wire or the like. One side of the third power path 50 is connected to the middle part of the first power path 20 (hereinafter referred to as “second connection part 22”), and the other side can be connected to the power storage device 30 via the changeover switch 60. It is said. As described above, the distribution board 10 and the power storage device 30 are configured to allow power to flow through the first power path 20, the third power path 50, and the changeover switch 60.

  The changeover switch 60 is an embodiment of the “switching means” and “changeover switch” according to the present invention. The change-over switch 60 is used to switch the availability and direction of power distribution. The changeover switch 60 is provided at a connection portion between the second power path 40, the third power path 50, and the power storage device 30.

  More specifically, in the changeover switch 60, when both the contact 61 on the second power path 40 side and the contact 62 on the third power path 50 side are turned off, the distribution board 10 and the power storage device 30 are Not connected. That is, when both the contact 61 on the second power path 40 side and the contact 62 on the third power path 50 side are turned off, the distribution board 10 and the power storage device 30 are in a state in which power cannot be distributed. (See FIG. 1).

  In the changeover switch 60, when the contact 61 on the second power path 40 side is turned on and the contact 62 on the third power path 50 side is turned off, the distribution board 10 and the power storage device 30 are connected to each other. Two power paths 40 are connected. That is, when the contact 61 on the second power path 40 side is turned on and the contact 62 on the third power path 50 side is turned off, the distribution board 10 and the power storage device 30 are connected to the second power path 40 and The state is switched to a state in which power can be distributed via the changeover switch 60 (see FIGS. 2 and 3).

  In the changeover switch 60, when the contact 62 on the third power path 50 side is turned on and the contact 61 on the second power path 40 side is turned off, the distribution board 10 and the power storage device 30 are connected to each other. The first power path 20, the third power path 50, and the changeover switch 60 are connected. That is, when the contact 62 on the third power path 50 side is turned on and the contact 61 on the second power path 40 side is turned off, the distribution board 10 and the power storage device 30 are connected to the first power path 20, It is switched to a state in which power can be distributed via the third power path 50 and the changeover switch 60 (see FIG. 4).

  The solar power generation unit 70 is an embodiment of the “power generation unit” according to the present invention. The solar power generation unit 70 is a device that generates power using sunlight. The photovoltaic power generation unit 70 is configured by a solar cell panel (not shown). The solar power generation unit 70 is installed in a sunny place such as on the roof of the house. The solar power generation unit 70 can generate electric power (DC power) and output the generated electric power.

  The power conditioner 80 converts power appropriately. The power conditioner 80 includes an inverter circuit (not shown). In the power conditioner 80, the power input side is connected to the solar power generation unit 70, and the power output from the solar power generation unit 70 (DC power) is input. The power conditioner 80 can convert the DC power input from the photovoltaic power generation unit 70 into AC power, and output the converted AC power.

  In the power conditioner 80, the power output side is connected to a midway portion of the first power path 20 (hereinafter referred to as “third connection portion 23”). The third connection unit 23 is downstream of the commercial power source 200 in the first power path 20 and upstream of the second connection unit 22 (between the commercial power source 200 and the second connection unit 22). Be placed.

  The fuel cell 90 is an embodiment of a “fuel cell” according to the present invention. The fuel cell 90 is a device that generates electric power using a supplied fuel such as hydrogen. The fuel cell 90 is configured by a solid oxide fuel cell (SOFC: Solid Oxide Fuel Cell), a control unit, and the like. The fuel cell 90 can generate power in accordance with a power generation plan to be described later and output the generated power. Further, the fuel cell 90 includes a hot water storage unit (not shown), and can boil hot water in the hot water storage unit using heat generated during power generation.

  Further, the fuel cell 90 has a function of learning information related to power consumption of the load (hereinafter referred to as “learning”) based on predetermined information (more specifically, information acquired from a detection result of the first power sensor 110 described later). Called "function"). The fuel cell 90 can appropriately update (create) the power generation plan based on the information learned by the learning function. The power generation plan is to estimate the time period and day of the week when the amount of power consumed by the load is relatively large, and to control the power generation of the fuel cell 90 so as to generate power in the estimated time period and day of the week. Refers to the plan.

  Thus, the power generated by the fuel cell 90 when the amount of power consumed by the load is relatively large (at the optimal timing) by generating power according to the power generation plan in which the fuel cell 90 is appropriately updated. Can be supplied to the distribution board 10. That is, the power generated by the fuel cell 90 can be used efficiently, and the amount of power (the amount of power purchased) supplied from the commercial power source 200 to the distribution board 10 can be reduced to save power charges. .

  In the present embodiment, the fuel cell 90 is set so that the maximum power generation amount is 700 W. Further, in the present embodiment, the fuel cell 90 is periodically (or irregularly) stopped due to maintenance, the amount of hot water in the hot water storage unit being a certain amount or more, and the operation is stopped. It is set not to generate electricity while

  Further, the fuel cell 90 is connected to the middle part of the first power path 20 (hereinafter referred to as “first connection part 21”) on the power output side. The first connection part 21 is downstream of the second connection part 22 in the first power path 20 and upstream of the distribution board 10 (between the second connection part 22 and the distribution board 10). Arranged).

  The first power sensor 110 is an embodiment of the “first power detection means” according to the present invention. The first power sensor 110 detects power at the installation location. The first power sensor 110 is installed between the first connection portion 21 and the second connection portion 22 in the first power path 20. The first power sensor 110 is electrically connected to the fuel cell 90. The first power sensor 110 can output a signal related to the detection result to the fuel cell 90.

  As described above, the fuel cell 90 receives the signal related to the detection result from the first power sensor 110, and can acquire the information related to the power at the place where the first power sensor 110 is installed. Then, the fuel cell 90 uses the acquired information regarding the power at the installation location of the first power sensor 110 and the information regarding the power generated by the fuel cell 90, and the power supplied to the distribution board 10 (and thus the power consumption of the load). ) Can be obtained (calculated).

  Thus, the fuel cell 90 acquires and learns information regarding the power consumption of the load based on the detection result of the first power sensor 110, and appropriately updates (creates) the power generation plan of the fuel cell 90 based on the learned information. )can do.

  The 2nd electric power sensor 120 detects the electric power in an installation location. The second power sensor 120 is installed between the third connection part 23 and the second connection part 22 in the first power path 20. Second power sensor 120 is electrically connected to power storage device 30. Second power sensor 120 can output a signal related to the detection result to power storage device 30.

  The third power sensor 130 detects the power at the installation location. The third power sensor 130 is installed between the first connection portion 21 and the distribution board 10 in the first power path 20. Third power sensor 130 is electrically connected to power storage device 30. Third power sensor 130 can output a signal related to the detection result to power storage device 30.

  As described above, the power storage device 30 receives the signals related to the detection results from the second power sensor 120 and the third power sensor 130, and acquires information about the power at the installation location of the second power sensor 120 and the third power sensor 130. can do.

  In addition, the power storage device 30 can determine whether or not the fuel cell 90 is generating power based on information regarding the power at the location where the second power sensor 120 and the third power sensor 130 are installed.

  For example, when the power storage device 30 is not discharged, if the power amount of power that is the detection result of the second power sensor 120 is different from the power amount of power that is the detection result of the third power sensor 130, It can be determined that power is output from the fuel cell 90 (the fuel cell 90 is generating power). On the other hand, for example, when the power storage device 30 is not discharged, the amount of power that is the detection result of the second power sensor 120 is the same as the amount of power that is the detection result of the third power sensor 130. In this case, it can be determined that no power is output from the fuel cell 90 (the fuel cell 90 is not generating power).

Thus, the power storage device 30 can determine whether or not the fuel cell 90 is generating power based on the detection results of the second power sensor 120 and the third power sensor 130.
The power storage device 30, the second power sensor 120, and the third power sensor 130 are an embodiment of the “fuel cell power generation determination unit” according to the present invention.

  The “fuel cell power generation determination means” according to the present invention determines whether the fuel cell 90 is generating power based on the detection results of the second power sensor 120 and the third power sensor 130 as in the present embodiment. It is possible to determine whether or not the fuel cell 90 is generating power based on the detection results of the first power sensor 110 and the third power sensor 130.

  More specifically, when determining whether or not the fuel cell 90 is generating power based on the detection results of the first power sensor 110 and the third power sensor 130 as described above, the first power sensor 110 is connected to the fuel cell. It is configured to be electrically connected not only to 90 but also to the power storage device 90. Thereby, the electrical storage apparatus 90 can acquire the information regarding the electric power in the installation location of the 1st electric power sensor 110. FIG.

  For example, when the power storage device 30 is not discharged, the amount of power that is the detection result of the first power sensor 110 is different from the amount of power that is the detection result of the third power sensor 130. Can be determined that power is output from the fuel cell 90 (the fuel cell 90 is generating power). On the other hand, for example, when the power storage device 30 is not discharged, the amount of power that is the detection result of the first power sensor 110 and the amount of power that is the detection result of the third power sensor 130 are the same. In this case, it can be determined that no power is output from the fuel cell 90 (the fuel cell 90 is not generating power).

  In addition, the power storage device 30 is connected to a power sensor (not shown) installed between the commercial power source 200 and the third connection unit 23 in the first power path 20, and whether or not power is supplied from the commercial power source 200 and the commercial power source. Information regarding the presence or absence of power supply (reverse power flow) to 200 can be acquired.

  In addition, the power storage device 30 is configured to be capable of load following operation that changes the amount of electric power to be discharged based on the detection results of the second power sensor 120 and the third power sensor 130. A detailed description of the load following operation in the power storage device 30 will be described later.

  The solar power generation unit 70, the power conditioner 80, the fuel cell 90, the power storage device 30, the changeover switch 60, and the like are each connected to a control device (not shown), and various information in the power supply system 1 is transmitted by the control device. It is managed and the operation is controlled.

  Below, the supply mode of the electric power in the electric power supply system 1 is demonstrated easily.

  In addition, the change of the distribution direction of the electric power in the following description shall be controlled by the said control apparatus.

  The electric power generated by the solar power generation unit 70 is converted from DC power to AC power by the power conditioner 80 and then supplied to the distribution board 10 via the first power path 20. In addition, power from the commercial power source 200 is supplied to the distribution board 10 via the first power path 20. The electric power generated by the fuel cell 90 is supplied to the distribution board 10 via the first electric power path 20. Thus, a resident such as the house can turn on the lighting or use the cooking utensil or the air conditioner by the electric power from the solar power generation unit 70, the commercial power source 200, and the fuel cell 90.

  As described above, in the power supply system 1, the power distributed to the load by the distribution board 10 (power consumption of the load) is not limited to the power from the commercial power supply 200, The power generated by the fuel cell 90 can be used. As a result, the amount of power (amount of power purchased) supplied from the commercial power source 200 to the distribution board 10 can be reduced, and the power charge can be saved. Further, the power generated by the fuel cell 90 is configured to be efficiently used by the learning function of the fuel cell 90.

  Further, the power consumption of the load can be provided only by the power other than the power from the commercial power source 200 (that is, the power generated by the solar power generation unit 70 or the power generated by the fuel cell 90), and the solar power generation unit 70. When surplus power (surplus power) is generated in the power generated by the fuel cell 90 or the power generated by the fuel cell 90, the surplus power can be reversely flowed to the commercial power source 200 to be sold. As a result, it is possible to save electric power charges and to obtain economic benefits.

  Further, similarly to the power generated by the solar power generation unit 70 and the power generated by the fuel cell 90, the power discharged from the power storage device 30 can be supplied to the distribution board 10. Further, the power from the commercial power source 200, the power generated by the solar power generation unit 70, or the power generated by the fuel cell 90 is supplied to the power storage device 30 via the distribution board 10, and the supplied power is supplied. The power storage device 30 can also be charged. A detailed description of the power supply mode relating to charging / discharging of the power storage device 30 will be described later.

  In addition, as the electric power supplied to the distribution board 10, the electric power generated by the fuel cell 90 is other electric power (electric power from the commercial power source 200, electric power generated by the solar power generation unit 70, and the power storage device 30. It is set to be used in preference to the discharged power.

  Below, the electric power supply aspect regarding charging / discharging of the electrical storage apparatus 30 among the electric power supply aspects in the electric power supply system 1 is demonstrated in detail.

  First, of the power supply modes related to charging / discharging of the power storage device 30, a power supply mode in the case where the power storage device 30 is charged with power will be described with reference to FIG.

  As shown in FIG. 2, in the power supply mode when the power storage device 30 is charged with power, the changeover switch 60 is turned on when the contact 61 on the second power path 40 side is turned on and on the third power path 50 side. The contact 62 is turned off. In other words, in the power supply mode in the case where the power storage device 30 is charged with power, the distribution board 10 and the power storage device 30 are switched to a state in which power can be distributed via the second power path 40 and the changeover switch 60. It is done.

  With such a configuration, when surplus power (surplus power) is generated by supplying power generated by the fuel cell 90 to the distribution board 10, the surplus power is transferred to the second power path 40 and the changeover switch 60. It can be supplied to the power storage device 30 via the battery and charged. That is, all the electric power generated by the fuel cell 90 can be used effectively.

  2 shows a state in which only the electric power generated by the fuel cell 90 is supplied to the power storage device 30 via the distribution board 10, but the electric power from the commercial power source 200 or solar power generation is shown. Similarly, the electric power generated by the unit 70 can be supplied to the power storage device 30 via the distribution board 10.

  Next, among power supply modes related to charging / discharging of power storage device 30, a power supply mode when power is discharged from power storage device 30 will be described.

The power supply mode in the case of discharging power from the power storage device 30 is configured to be a different supply mode depending on whether or not the fuel cell 90 is generating power.
More specifically, the power supply mode in the case of discharging power from the power storage device 30 is a supply mode when it is determined that the fuel cell 90 is generating power (hereinafter referred to as “first supply mode”). And a supply mode (hereinafter referred to as “second supply mode”) when it is determined that the fuel cell 90 is not generating power.

  Below, the 1st supply aspect is demonstrated in detail among the supply aspects of the electric power in the case of discharging electric power from the electrical storage apparatus 30. FIG.

  As shown in FIG. 3, in the first supply mode among the power supply modes when discharging power from the power storage device 30, the changeover switch 60 is turned on when the contact 61 on the second power path 40 side is turned on. The contact 62 on the three power path 50 side is turned off. That is, in the first supply mode, the distribution board 10 and the power storage device 30 are switched to a state in which power can be distributed via the second power path 40 and the changeover switch 60.

  First, the power generated by the fuel cell 90 is supplied to the distribution board 10 via the first power path 20. Then, when the power consumption of the load cannot be met only with the power supplied from the fuel cell 90 (that is, when the power consumption of the load is 700 W or more of the maximum power generation amount of the fuel cell 90), the power consumption is insufficient. Electric power for supplementing electric power (insufficient electric power) is supplied to the distribution board 10 from the commercial power source 200, the solar power generation unit 70, and the power storage device 30.

  Specifically, when the insufficient power occurs, the power storage device 30 generates power from the commercial power source 200 or the solar power generation unit 70 based on the detection results of the second power sensor 120 or the third power sensor 130. Information that the generated power is supplied to the distribution board 10 is acquired. And the electrical storage apparatus 30 discharges the electric power of the electric energy equivalent to the electric energy of the said insufficient electric power. The electric power discharged from the power storage device 30 is supplied to the distribution board 10 via the changeover switch 60 and the second power path 40. In addition, when the power generated by the fuel cell 90 and the power discharged from the power storage device 30 cannot cover the power consumption of the load, the power from the commercial power source 200 or the power generated by the solar power generation unit 70 is further increased. Is supplied to the distribution board 10.

  In FIG. 3, the power generated by the fuel cell 90, the power discharged from the power storage device 30, the power from the commercial power source 200, and the power generated by the solar power generation unit 70 are divided. The state in which it is supplied to the board 10 is shown.

  As shown in FIG. 3, in the first supply state, the first power sensor 110 can detect the power from the commercial power source 200 and the power generated by the solar power generation unit 70. Thereby, the fuel cell 90 supplies the power (load power consumption) supplied to the distribution board 10 based on the acquired information about the power at the installation location of the first power sensor 110 and the information about the power generated by itself. Information about can be obtained. For example, in the state shown in FIG. 3, the fuel cell 90 can acquire (learn) information that the amount of power consumed by the load is at least 700 W, which is the maximum power generation amount of the fuel cell 90. .

  In this way, the fuel cell 90 has information on the power consumption of the load in the learned time zone and day of the week (the amount of power consumption of the load is at least 700 W or more, and the maximum power generation amount in the learned time zone and day of the week. Information) that it is sufficient to generate electric power. Thus, in the first supply mode among the power supply modes in the case of discharging power from the power storage device 30, the fuel cell 90 can learn information on the power consumption of the load, and the learning function of the fuel cell 90 is obstructed. Not.

  In FIG. 3, the case where the first power sensor 110 detects the power from the commercial power source 200 and the power generated by the solar power generation unit 70 is described as an example, but the power from the commercial power source 200 and the solar power generation are described. Even if the power generated by the unit 70 is not detected, the learning function of the fuel cell 90 is not hindered.

  Below, the 2nd supply aspect is demonstrated in detail among the supply aspects of the electric power in the case of discharging electric power from the electrical storage apparatus 30. FIG.

  As shown in FIG. 4, in the second supply mode of the power supply mode when discharging power from the power storage device 30, the changeover switch 60 is turned on when the contact 62 on the third power path 50 side is turned on. The contact 61 on the second power path 40 side is turned off. That is, in the second supply mode, the distribution board 10 and the power storage device 30 are switched to a state in which power can be distributed via the first power path 20, the third power path 50, and the changeover switch 60.

  Then, the power storage device 30 discharges the amount of power corresponding to the amount of power consumed by the load based on the detection results of the second power sensor 120 and the third power sensor 130. The electric power discharged from the power storage device 30 is supplied to the distribution board 10 via the changeover switch 60, the third power path 50, and the first power path 20. When the electric power discharged from the power storage device 30 alone cannot cover the power consumption of the load, the electric power from the commercial power source 200 or the electric power generated by the solar power generation unit 70 is supplied to the distribution board 10. .

  FIG. 4 shows a state where only the electric power discharged from power storage device 30 is supplied to distribution board 10 (the power consumption of the load is covered only by the electric power discharged from power storage device 30). Yes.

  Further, as shown in FIG. 4, in the second supply state, the first power sensor 110 can detect the power discharged from the power storage device 30. As a result, the fuel cell 90 uses the acquired information regarding the power at the installation location of the first power sensor 110 and the information regarding the power generated by itself (that is, information indicating that power generation is not being performed) based on the distribution board 10. It is possible to acquire information related to the power supplied to the power (the power consumption of the load). For example, in the state shown in FIG. 4, the fuel cell 90 can acquire (learn) information on the power discharged from the power storage device 30 as the amount of power consumed by the load.

  In this way, the fuel cell 90 can learn information regarding the power consumption of the load in the learned time zone and day of the week. As described above, in the second supply mode of the power supply modes in the case of discharging power from the power storage device 30, the fuel cell 90 can learn information on the power consumption of the load, and the learning function of the fuel cell 90 is obstructed. Not.

  In addition, although FIG. 4 demonstrated as an example the case where the 1st electric power sensor 110 detected only the electric power discharged from the electrical storage apparatus 30, the electric power from the commercial power source 200 and the electric power generated by the solar power generation part 70 were used. Even in the case of detection, the learning function of the fuel cell 90 is not hindered.

  Thus, when discharging power from the power storage device 30, the power supply mode is changed to the first supply mode or the second supply mode even if the fuel cell 90 is generating power or not generating power. By appropriately switching, it is possible to prevent the learning function of the fuel cell 90 from being hindered.

  Hereinafter, the load following operation in the power storage device 30 will be described in detail.

  In the present embodiment, power (AC power) drawn into the house from the commercial power source 200 is supplied to the distribution board 10 by a single-phase three-wire power distribution method. Here, the schematic diagram of FIG. 5A shows a simplified configuration of the distribution board 10 and the first power path 20 and the second power path 40 connected to the distribution board 10. is there. As shown to Fig.5 (a), the 1st electric power path | route 20 and the 2nd electric power path | route 40 are each comprised from the neutral phase 112 and a pair of voltage phase (L1 phase 111 and L2 phase 113). In addition, although illustration is abbreviate | omitted, the 3rd electric power path | route 50 is similarly comprised from the neutral phase 112 and a pair of voltage phase (L1 phase 111 and L2 phase 113).

  In the present embodiment, the power sensors connected to the power storage device 30, that is, the second power sensor 120 and the third power sensor 130 are configured to detect the respective powers of the L1 phase 111 and the L2 phase 113 at the installation location. Is done. Thereby, the power storage device 30 can acquire information related to the power of the L1 phase 111 and the L2 phase 113 at the locations where the second power sensor 120 and the third power sensor 130 are installed.

  Then, the power storage device 30 detects the detection result of the second power sensor 120 and the third power sensor 130 (more specifically, one of the second power sensor 120 or the third power sensor 130 as described later), that is, Load following operation for changing the amount of electric power to be discharged for each of the L1 phase 111 and the L2 phase 113 based on the information regarding the power of the L1 phase 111 and the L2 phase 113 acquired from the second power sensor 120 and the third power sensor 130 Configured to be possible. More specifically, the power storage device 30 distributes electric power of an amount corresponding to each need to the L1 phase 111 and the L2 phase 113, and supplies the electric power to the distribution board 10 via the L1 phase 111 and the L2 phase 113. be able to. As described above, the power storage device 30 is configured to be capable of highly accurate load following operation based on the detection results of the second power sensor 120 and the third power sensor 130.

  When the power storage device 30 performs the load following operation with high accuracy as described above, the detection result of the power sensor acquired for performing the load following operation is negative in either the L1 phase 111 or the L2 phase 113. If the amount of power is less (that is, when power is distributed to the commercial power source 200), the power storage device 30 is controlled not to be discharged (so that the power storage device 30 stops). Thereby, it is prevented that the electric power discharged from the electrical storage device 30 flows backward and is sold.

  Below, the specific example of the highly accurate load follow-up driving | operation in the electrical storage apparatus 30 as mentioned above is demonstrated using FIGS.

  In FIG. 5A, the distribution board 10 has, for example, a load DL1 as a circuit to which an electric device such as a television is connected and a load as a circuit to which an electric device such as a microwave oven is connected. DL2 is connected. The load DL1 is connected to the L1 phase 111 and the neutral phase 112, and is supplied with 100V power. The load DL2 is connected to the L2 phase 113 and the neutral phase 112, and is supplied with 100V power. The load DL1 consumes 200 W (100 V × 2 A), the load DL2 consumes 1500 W (100 V × 15 A), and the distribution board 10 requires 1700 W as a whole.

  It is assumed that the fuel cell 90 generates 700 W of maximum power generation according to the power generation plan.

  The electric power generated by the fuel cell 90 is averaged and distributed to the L1 phase 111 and the L2 phase 113 in the first power path 20. That is, as shown in FIG. 5B, 350 W of power is distributed to the L1 phase 111 and the L2 phase 113 in the first power path 20 as power averaged from 700 W of power.

  When 350 W of power flows through the L2 phase 113 and is supplied to the load DL2 via the distribution board 10, 1150 W of insufficient power (insufficient power) is generated. As shown in FIG. 5C, the power of 1150 W corresponding to the amount of the insufficient power is stored in the commercial power source 200, the solar power generation unit 70, and the power storage via the L2 phase 113 of the first power path 20. It will be supplied from the device 30.

  On the other hand, when 350 W of power flows through the L1 phase 111 and is supplied to the load DL1 via the distribution board 10, 150 W of surplus power (surplus power) is generated. Then, as shown in FIG. 5C, this 150 W of surplus power is transmitted via the L1 phase 111 of the first power path 20 (more specifically, from the first connection portion 21 in the first power path 20). It will be distributed to the commercial power source 200 side.

  In addition, since the 2nd power sensor 120 is installed in the 1st power path | route 20 at the commercial power supply 200 side rather than the 1st connection part 21, when surplus electric power arises as mentioned above, the said 2nd power sensor 120 is In the L1 phase 111, a negative amount of power (power distributed from the first connection portion 21 to the commercial power supply 200 side in the first power path 20) is detected (see FIG. 7). As a result, the power storage device 30 is controlled so as not to be discharged (stopped).

  In such a case, the sum of the amounts of power flowing through the L1 phase 111 and the L2 phase 113 at the place where the second power sensor 120 is installed is 1000 W (positive power amount), and the power is sold as a whole. Although it should not have been done, the power storage device 30 is stopped, which is a problem.

  Therefore, in order to cope with the above-described problem, in the power supply system 1, the load follow-up of the power storage device 30 is performed based on the detection results of different power sensors depending on the power supply mode when the power is discharged from the power storage device 30. It is used as information for driving.

  More specifically, in the power supply system 1, when the power supply mode in the case where the power is discharged from the power storage device 30 is the first supply mode, the detection result of the third power sensor 130 is obtained from the power storage device 30. Used as information for load following operation. Further, when the power supply mode when discharging power from power storage device 30 is the second supply mode, second power sensor 120 is used as information for performing load following operation of power storage device 30.

  FIG. 6 illustrates the power supply system 1 using the detection result of the second power sensor 120 when the power supply mode in the case of discharging power from the power storage device 30 is the second supply mode. It shows the state of load following operation.

  In such a case, since the second power sensor 120 is installed on the upstream side of the second connection unit 22, the power discharged from the power storage device 30 is not detected, and the commercial power source 200 and the solar power generation unit 70 are detected. The power supplied from is detected. Then, the power storage device 30 changes the amount of power to be discharged based on the detection result of the second power sensor 120. FIG. 6 shows a state in which the detection result of the second power sensor 120 is 350 W for the L1 phase 111 and 1500 W for the L2 phase. Then, the power storage device 30 discharges 350 W of power in the L1 phase 111 and 1500 W of power in the L2 phase 113 based on the detection result of the second power sensor 120.

  Thus, in the power supply system 1, when the power supply mode in the case of discharging power from the power storage device 30 is the second supply mode, the detection result of the second power sensor 120 is used to store the power storage device 30. Load following operation can be performed.

  FIG. 7 illustrates the power supply system 1 using the detection result of the third power sensor 130 when the power supply mode in the case of discharging power from the power storage device 30 is the first supply mode. It shows the state of load following operation.

  In such a case, the third power sensor 130 is installed on the downstream side (between the fuel cell 90 and the distribution board 10) from the first connection portion 21, and in the state shown in FIG. When the fuel cell 90 generates 700 W of maximum power generation, the detection result of the third power sensor 130 is 200 W in the L1 phase 111 and 1500 W in the L2 phase 113 as shown in FIG. Then, based on the detection result of the third power sensor 130, the power storage device 30 discharges the amount of power corresponding to the amount of power that is insufficient with only the power from the fuel cell 90. That is, the power storage device 30 does not discharge power in the L1 phase 111, and 1000 W (the amount of power obtained by subtracting 700 W from the fuel cell 90 from 1700 W required by the distribution board 10 as a whole) in the L2 phase 113. To discharge.

  As described above, in the power supply system 1, when the power supply mode in the case where the power is discharged from the power storage device 30 is the first supply mode, the detection result of the third power sensor 130 is used to store the power storage device 30. Load following operation can be performed.

  When the power supply mode in the case of discharging power from the power storage device 30 is the first supply mode, the detection result of the second power sensor is minus 150 W, L2 in the L1 phase 111, as shown in FIG. It becomes 1150W in the phase 113. That is, when the detection result of the second power sensor 120 (not the third power sensor 130) is used in the first supply mode in the power supply system 1, a negative amount of power is detected in the L1 phase 111. The power storage device 30 is stopped and the load following operation cannot be performed.

As described above, the power supply system 1 is
A distribution board 10 provided on the downstream side in the supply direction of power from the commercial power source 200 and distributing power to the load;
First power detection means (first power sensor 110) that is provided upstream of the distribution board 10 in the direction of supply of power from the commercial power supply 200 and detects power;
Provided on the upstream side of the distribution board 10 and having a learning function for learning information on power consumption of the load based on a detection result of the first power detection means (first power sensor 110), A fuel cell 90 capable of generating power according to a power generation plan that is appropriately updated based on a learning function;
A power storage device 30 capable of charging power and discharging the charged power, and supplying the discharged power to the distribution board 10;
Switching means for switching the arrangement of the power storage device 30 so as to be either on the downstream side of the distribution board 10 or on the upstream side of the first power detection means (first power sensor 110);
Comprising
When the arrangement of the power storage device 30 is switched to the downstream side of the distribution board 10 by the switching means, surplus power supplied from the fuel cell 90 to the distribution board 10 is supplied to the power storage device 30. Can be supplied to
When the switching unit switches the arrangement of the power storage device 30 to the upstream side of the first power detection unit (first power sensor 110), the power discharged from the power storage device 30 is changed to the first power. After being detected by the detection means (first power sensor 110), it can be supplied to the distribution board 10.

  With such a configuration, in the power supply system 1, the learning function of the fuel cell 90 is not hindered, and all the electric power generated by the fuel cell 90 can be used effectively.

In the power supply system 1,
Fuel cell power generation determination means (second power sensor 120 or first power sensor 110, third power sensor 130 and power storage device 30) for determining whether or not the fuel cell 90 is generating power;
When the power storage device 30 discharges power,
When it is determined by the fuel cell power generation determination means (second power sensor 120 (or first power sensor 110), third power sensor 130 and power storage device 30) that the fuel cell 90 is generating power, The arrangement of the power storage device 30 is switched to the downstream side of the distribution board 10 by switching means,
When the fuel cell power generation determination means (second power sensor 120 (or first power sensor 110), third power sensor 130, and power storage device 30) determines that the fuel cell 90 is not generating power, The arrangement of the power storage device 30 is switched to the upstream side of the first power detection means (first power sensor 110) by the switching means.

With such a configuration, in the power supply system 1, the learning function of the fuel cell 90 is not hindered by switching the arrangement of the power storage devices depending on whether or not the fuel cell 90 is generating power, and the fuel cell 90 It is possible to effectively use all the power generated in
When the first power sensor 110 is used instead of the second power sensor 120 as the fuel cell power generation determination unit according to the present invention, the number of sensors to be used is smaller than when the second power sensor 120 is used. can do.

In the power supply system 1,
A first power path 20, a second power path 40, and a third power path 50 through which power can be distributed;
The first power path 20 has one side connected to the commercial power source 200, the other side connected to the distribution board 10, and a first connection portion 21 provided midway connected to the fuel cell 90,
One side of the second power path 40 can be connected to the power storage device 30 via the switching means, and the other side is connected to the distribution board 10.
One side of the third power path 50 can be connected to the power storage device 30 via the switching means, and the other side is provided on the upstream side of the first connection portion 21 in the first power path 20. Connected to the second connection portion 22,
The switching unit includes a changeover switch 60 that connects the power storage device 30 to either the second power path 40 or the third power path 50 so as to be switchable.

  With such a configuration, in the power supply system 1, the learning function of the fuel cell 90 is not hindered by switching the arrangement of the power storage device with the changeover switch according to whether or not the fuel cell 90 is generating power, and All of the electric power generated by the fuel cell 90 can be used effectively.

In the power supply system 1,
The first power detection means (first power sensor 110) is provided between the first connection portion 21 and the second connection portion 22.

  With such a configuration, in the power supply system 1, the learning function of the fuel cell 90 is not hindered and the learning function of the fuel cell 90 is used in order to effectively use all of the electric power generated by the fuel cell 90. Therefore, it is not necessary to provide a plurality of power sensors used for this purpose. That is, the number of power sensors used for the learning function of the fuel cell 90 can be only one instead of a plurality.

In the power supply system 1,
Second power detection means (second power sensor 120) that is provided between the distribution board 10 and the commercial power source 200 and the second connection portion 22 in the first power path 20, and detects power.
Third power detection means (third power sensor 130) that is provided between the first connection portion 21 and the distribution board 10 in the first power path 20 and detects power;
Comprising
The power storage device 30 includes:
Based on the detection result of the predetermined power detection means, it is configured to enable load following operation to change the amount of electric power to be discharged,
When it is determined by the fuel cell power generation determination means (second power sensor 120 (or first power sensor 110), third power sensor 130 and power storage device 30) that the fuel cell 90 is generating power, Based on the detection result of the third power detection means (third power sensor 130), the load following operation is performed.
When the fuel cell power generation determination means (second power sensor 120 (or first power sensor 110), third power sensor 130, and power storage device 30) determines that the fuel cell 90 is not generating power, The load following operation is performed based on the detection result of the second power detection means (second power sensor 120).

  With such a configuration, the power supply system 1 uses the second power sensor 120 (or the first power sensor 110) and the third power sensor 130 to discharge power from the power storage device 30. Regardless, it is possible to prevent the power storage device 30 from stopping and perform the load following operation of the power storage device 30.

In the power supply system 1,
It has a power generation unit (solar power generation unit 70) that can generate power using natural energy,
The power generation unit (solar power generation unit 70) is connected to one side of the first power path 20.

  With such a configuration, in the power supply system 1, even when the solar power generation unit 70 is provided, the learning function of the fuel cell 90 is not hindered, and all the power generated by the fuel cell 90 is reduced. It can be used effectively.

  In addition, in this embodiment, although the electric power supply system 1 was set as the structure provided in a house, it is not limited to this structure. For example, the power supply system 1 may be configured in a building such as an office or a public facility.

  In the present embodiment, the configuration using sunlight as natural energy (the configuration including the solar power generation unit 70 as the “power generation unit” according to the present invention) is not limited to this. The natural energy to be used may be, for example, hydropower, wind power, tidal power and the like.

  In the present embodiment, the maximum power generation amount of the fuel cell 90 is set to be 700 W, but the present invention is not limited to this. For example, the maximum power generation amount of the fuel cell 90 may be 750 W or the like, and the power generation amount may be set to an arbitrary power generation amount.

DESCRIPTION OF SYMBOLS 1 Power supply system 10 Distribution board 30 Power storage device 70 Solar power generation part 90 Fuel cell 110 1st electric power sensor 200 Commercial power supply

Claims (6)

A distribution board provided on the downstream side in the direction of supply of electric power from the commercial power source and distributing power to the load;
A first power detection means provided on the upstream side in the supply direction of power from a commercial power supply than the distribution board to detect power;
Provided on the upstream side of the distribution board, and having a learning function for learning information related to the power consumption of the load based on the detection result of the first power detection means, and updated appropriately based on the learning function A fuel cell capable of generating power according to the power generation plan
A power storage device capable of charging power and discharging the charged power, and supplying the discharged power to the distribution board;
Switching means for switching the arrangement of the power storage device to be either on the downstream side of the distribution board or on the upstream side of the first power detection means;
Comprising
When the arrangement of the power storage device is switched to the downstream side of the distribution board by the switching means, it becomes possible to supply the power storage device with surplus power supplied from the fuel cell to the distribution board,
When the switching unit switches the arrangement of the power storage device to the upstream side of the first power detection unit, the first power detection unit detects the power discharged from the power storage device, and then the distribution is performed. Can be supplied to the electrical panel,
A power supply system characterized by that. Comprising fuel cell power generation determination means for determining whether or not the fuel cell is generating power;
When the power storage device discharges power,
When it is determined by the fuel cell power generation determination means that the fuel cell is generating power, the switching means switches the arrangement of the power storage device to the downstream side of the distribution board,
If the fuel cell power generation determination means determines that the fuel cell is not generating power, the switching means switches the arrangement of the power storage device to the upstream side of the first power detection means;
The power supply system according to claim 1. Comprising a first power path, a second power path and a third power path through which power can be distributed;
In the first power path, one side is connected to the commercial power source, the other side is connected to the distribution board, and a first connection portion provided midway is connected to the fuel cell,
The second power path, one side can be connected to the power storage device via the switching means, the other side is connected to the distribution board,
The third power path can be connected to the power storage device on one side via the switching means, and the other side is a second connection provided on the upstream side of the first connection part in the first power path. Connected to the
The switching means includes a changeover switch that connects the power storage device to either the second power path or the third power path in a switchable manner.
The power supply system according to claim 1, wherein the power supply system is a power supply system. The first power detection means is provided between the first connection portion and the second connection portion.
The power supply system according to claim 3. A second power detection means for detecting power provided between the distribution board and the commercial power source and the second connection in the first power path;
A third power detection means for detecting power provided between the first connection portion and the distribution board in the first power path;
Comprising
The power storage device
Based on the detection result of the predetermined power detection means, it is configured to enable load following operation to change the amount of electric power to be discharged,
When the fuel cell power generation determination unit determines that the fuel cell is generating power, a load following operation is performed based on the detection result of the third power detection unit,
When the fuel cell power generation determination unit determines that the fuel cell is not generating power, a load following operation is performed based on the detection result of the second power detection unit.
The power supply system according to claim 3 or 4, wherein It has a power generation unit that can generate power using natural energy,
The power generation unit is connected to one side of the first power path.
The power supply system according to any one of claims 3 to 5, wherein:

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