JP7452967B2 - power supply system - Google Patents

Description

The present invention relates to a technology for a power supply system having a fuel cell.

2. Description of the Related Art Conventionally, the technology of a power supply system having a fuel cell is well known. For example, as described in Patent Document 1.

Patent Document 1 describes a solar cell that uses sunlight to generate electricity, a fuel cell that can generate electricity using fuel such as hydrogen and can boil water using waste heat generated during power generation, and A power supply system is described that includes a storage battery that can be charged and discharged. In the power supply system, power from these fuel cells and the like is supplied to the power load.

In power supply systems having such fuel cells, there are known power supply systems that indirectly control the amount of power generated by the fuel cell by controlling the charging and discharging of the storage battery, but there are power supply systems that indirectly control the amount of power generated by the fuel cell by controlling the charging and discharging of the storage battery. It is desired to control the fuel cell more appropriately by doing so.

Japanese Patent Application Publication No. 2016-48992

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power supply system that can appropriately control fuel cells.

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

That is, in claim 1, there is provided a fuel cell capable of generating electricity using fuel and capable of supplying the generated power to a load connected to a grid power supply, a control unit controlling the operation of the fuel cell, and the fuel cell. a power storage system having a storage battery that can be charged and discharged according to the power demand of the load after the generated power is supplied, and the fuel cell can set a power generation upper limit value that is the upper limit value that can be generated. and if it is possible to generate power within the range up to the power generation upper limit according to the power demand of the load, the control unit controls the fuel cell to The power generation upper limit value of the fuel cell can be updated based on a comparison between the power generation cost and the power purchase cost from the grid power source , and the power storage system is capable of generating power using natural energy and The fuel cell has a power generation unit that can charge the storage battery, the fuel cell has a hot water storage tank, and the hot water produced using heat generated during power generation is stored in the hot water storage tank, and the control unit includes: If there is power generated by the power generation unit to be sold to the grid power source, and the power generated by the power generation unit to be sold to the grid power source is larger than the power generated by the fuel cell, and the power generation by the fuel cell When it is determined that a predetermined amount of hot water can be stored by a predetermined time, the fuel cell is changed from a state where it can generate electricity to a standby state .

In claim 2, when the control unit determines that the predetermined amount of hot water cannot be stored by the predetermined time by the power generation of the fuel cell, the control unit changes the fuel cell from a standby state to a state capable of generating power. It is.

In claim 3, when the power generation cost of the fuel cell is lower than the power purchase cost of the grid power source, the control unit adjusts the power generation upper limit value within a range up to a power generation capacity that is the maximum value that the fuel cell can generate. It will be updated to increase .

In claim 4, when the power generation cost of the fuel cell is greater than or equal to the power purchase cost of a grid power source, the control unit updates the power generation upper limit value to be lowered to the power generation lower limit value when the fuel cell generates power. It is something.

In claim 5 , the control unit is configured such that power equal to or less than the predetermined amount is supplied to the load from the grid power supply, the storage battery is in a discharge state, and the power generation cost of the fuel cell is equal to or less than the power of the grid power supply. If it is lower than the purchase cost and is smaller than a lower discharge limit which is the lower limit at which the discharge power of the storage battery can be efficiently discharged, the upper limit of power generation is updated to lower the upper limit of power generation within the range up to the lower limit of power generation. It is.

In claim 6, when the control unit purchases power equal to or less than the predetermined amount from the grid power source, and the storage battery is not in a discharged state, and the storage battery has a remaining charge to the extent that it can be discharged, , the power generation upper limit value is updated to become the power generation lower limit value .

The present invention has the following effects.

In the first aspect, the fuel cell can be appropriately controlled. Further, the fuel cell can be appropriately controlled together with the solar power generation section.

In claim 2, the fuel cell can be more appropriately controlled together with the solar power generation section .

In claim 3, the fuel cell can be controlled more appropriately.

In claim 4, the fuel cell can be controlled more appropriately .

In claim 5, the fuel cell can be appropriately controlled together with the storage battery.

In claim 6, the fuel cell can be more appropriately controlled together with the storage battery .

1 is a block diagram showing the configuration of a power supply system according to an embodiment of the present invention. Flowchart showing a flow related to specific processing. 3 is a flowchart showing a continuation of FIG. 2. 4 is a flowchart showing a continuation of FIG. 3. 5 is a flowchart showing a continuation of FIG. 4. (a) A block diagram showing an example of a power supply mode in pattern 1 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 6(a). (a) A block diagram showing an example of the power supply mode in pattern 2 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 7(a). (a) A block diagram showing an example of the power supply mode in pattern 3 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 8(a). (a) A block diagram showing an example of the power supply mode in pattern 4 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 9(a). (a) A block diagram showing an example of the power supply mode in pattern 5 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 10(a). (a) A block diagram showing an example of the power supply mode in pattern 6 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 11(a). (a) A block diagram showing an example of the power supply mode in pattern 7 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 12(a). (a) A block diagram showing an example of the power supply mode in pattern 8 when specific processing is executed. (b) A block diagram showing a continuation of FIG. 13(a).

Hereinafter, a power supply system 1 according to an embodiment of the present invention will be described using FIG. 1.

The power supply system 1 is provided in a house, and is for supplying electric power to the load of the house (hereinafter referred to as "house load 50"). The power supply system 1 includes a power distribution line 10, a power storage system 20, a fuel cell 30, and a control unit 40.

The power distribution line 10 is an electric wire that connects the system power supply S and the residential load 50. In addition, below, the system power supply S side in the distribution line 10 may be called the "upstream side," and the residential load 50 side may be called the "downstream side."

The power storage system 20 is capable of generating power using sunlight, and is also capable of charging and discharging power. The power storage system 20 includes a solar power generation unit 21, a storage battery 22, and a power conditioner 23.

The solar power generation unit 21 is a device that generates power using sunlight. The solar power generation unit 21 is composed of a solar battery panel and the like. The solar power generation unit 21 is installed in a sunny place such as on the roof of a house.

The storage battery 22 is capable of charging and discharging power. The storage battery 22 is composed of, for example, a lithium ion battery. The storage battery 22 has a plurality of operating modes. The plurality of modes include a standby mode in which the storage battery 22 is not charged or discharged, a charging mode in which the storage battery 22 is forcibly charged, a discharge mode in which the storage battery 22 is discharged according to the residential load 50, and a discharge mode in which the storage battery 22 is discharged in accordance with the residential load 50. This includes charge/discharge modes for charging and discharging. In this embodiment, the storage battery 22 mainly executes the charge/discharge mode among the plurality of modes. Note that a detailed explanation of the charge/discharge mode will be given later. When executing the charging mode or charging/discharging mode, the storage battery 22 uses a load following function to respond to the measurement result of the first sensor 24 (that is, the power demand of the residential load 50) acquired via the power conditioner 23, which will be described later. can be operated. Further, in this embodiment, the maximum discharge power of the storage battery 22 is assumed to be 2000 [W]. Further, it is assumed that the maximum charging power of the storage battery 22 is 2000 [W].

A predetermined remaining amount (hereinafter referred to as "minimum storage amount") is set in the storage battery 22 as a remaining amount of charge to ensure power in an emergency such as a power outage. That is, the minimum amount of electricity stored in the storage battery 22 indicates the minimum remaining charge that is always ensured during normal times.

The power conditioner 23 is a hybrid power conditioner that can convert electric power as appropriate. The power conditioner 23 is connected to the solar power generation unit 21 and the storage battery 22 via predetermined electric wires, respectively. Moreover, the power conditioner 23 is connected to a midway part of the power distribution line 10 (hereinafter referred to as "connection point 20a") via a predetermined electric wire. In this way, the power conditioner 23 is provided between the solar power generation unit 21, the storage battery 22, and the power distribution line 10.

In this way, the power generated by the solar power generation unit 21 can be output to the power distribution line 10 via the power conditioner 23. Further, the power generated by the solar power generation unit 21 can be charged to the storage battery 22 via the power conditioner 23. Further, the discharged power of the storage battery 22 can be output to the power distribution line 10 via the power conditioner 23. Further, the power flowing through the power distribution line 10 (power from the system power supply S) can be charged into the storage battery 22 via the power conditioner 23.

Moreover, the power conditioner 23 is electrically connected to the storage battery 22. Thereby, the power conditioner 23 can acquire information regarding the operation and charging power of the storage battery 22. Further, the power conditioner 23 can control the operation of the storage battery 22 (for example, execution of the driving mode).

Further, the power conditioner 23 is provided with a first sensor 24 . The first sensor 24 measures the electric power (size and direction) at the installation location. The first sensor 24 is installed in the distribution line 10 immediately upstream of the connection point 20a. No other electric wire or electrical equipment is connected between the first sensor 24 and the connection point 20a. The first sensor 24 is electrically connected to the power conditioner 23 and configured to be able to transmit measurement results. Thereby, the power conditioner 23 can acquire power information at the location where the first sensor 24 is installed.

The fuel cell 30 generates electricity using fuel such as hydrogen. The fuel cell 30 includes a solid oxide fuel cell (SOFC), a control section, and the like. The fuel cell 30 is connected to a midway portion of the power distribution line 10 (hereinafter referred to as a "connection point 30a"). The connection point 30a is arranged downstream of the connection point 20a in the power distribution line 10. That is, fuel cell 30 is arranged downstream of power storage system 20 in power distribution line 10 . In addition to generating power, the fuel cell 30 can also be in a standby state. In addition, in this embodiment, the maximum generated power of the fuel cell 30 is assumed to be 700 [W]. The fuel cell 30 is provided with a second sensor 31 and a hot water storage tank 32.

The second sensor 31 measures the electric power (size and direction) at the installation location. The second sensor 31 is installed on the distribution line 10 immediately upstream of the connection point 30a. No other electric wire or electrical equipment is connected between the second sensor 31 and the connection point 30a. The second sensor 31 is electrically connected to the fuel cell 30 and configured to be able to transmit measurement results. Thereby, the fuel cell 30 can acquire power information at the location where the second sensor 31 is installed. The fuel cell 30 can generate power according to the measurement result of the second sensor 31 (that is, the power demand of the residential load 50) using a load following function.

The hot water storage tank 32 is used to boil water using heat generated during power generation by the fuel cell 30 and to store the boiled water. The hot water stored in the hot water storage tank 32 can be used to supply hot water according to the hot water demand of the residence. Note that hereinafter, the amount of hot water stored in the hot water storage tank 32 may be simply referred to as "tank hot water amount."

Further, the fuel cell 30 has a function (hereinafter referred to as a "learning function") of learning information regarding the power consumption and hot water demand of the residential load 50. Based on the information learned by the learning function, the fuel cell 30 determines, for example, the time when the tank should have the maximum amount of hot water during the day (0:00 to 24:00), the maximum amount of hot water (the amount of hot water at the peak time), etc. ) can be estimated.

Note that hereinafter, the time at which the maximum amount of hot water in the tank should be reached during one day will be referred to as the "specified value attainment deadline time." Further, the maximum amount of hot water (the amount of hot water at the peak time) is referred to as a "specified value." The specified value is a value indicating the ratio of the amount of hot water stored in the tank to the amount of hot water when the tank is full, and is set to 80% in this embodiment. Further, the designated value attainment deadline time is set to 18:00. Note that the specified value attainment deadline time and the specified value may not be estimated based on information learned by the learning function, but may be arbitrarily determined, for example, by a resident of the house. Further, the specified value is not limited to 80% as in this embodiment. Further, the specified value attainment deadline time is not limited to 18:00.

The fuel cell 30 creates a power generation plan that takes into account the lifestyle of the occupants of the house, based on the estimation results as described above. The fuel cell 30 can increase the amount of hot water in the tank to 80% (designated value) by the designated value reaching deadline time by generating power according to the created power generation plan. Note that the power generation plan is updated as appropriate based on information learned by the learning function.

Further, when generating power, the fuel cell 30 does not always generate power according to the residential load 50 using the load following function, but can generate power of any value instructed by the control unit 40. Specifically, when the residential load 50 is 1000 [W], for example, instead of generating the maximum power of 700 [W] using the load following function, for example, 500 [W] is generated according to an instruction from the control unit 40. Electric power (power smaller than 700 [W]) can be generated. Note that, hereinafter, generating power smaller than the power corresponding to the residential load 50 as described above may be referred to as "power generation suppression" (or simply "suppression reinforcement").

In this embodiment, the fuel cell 30 can generate electricity even when the tank is full (100%) of hot water. In this way, when power is generated when the tank is full, the heat generated during power generation is not used to boil the water and is discarded. Therefore, the power generation cost of the fuel cell 30 when power is generated when the tank is full (i.e., the generated heat is not used to boil water) is lower than the cost when the tank is not full (i.e., when the generated heat is not used to boil water). (if the generated heat is used to boil water), the cost will be higher than if electricity was generated.

The control unit 40 is an energy management system that manages the operation of the power supply system 1. The control unit 40 includes a storage unit such as a RAM or ROM, an arithmetic processing unit such as a CPU, an input/output unit such as an I/O, and the like. The control unit 40 can perform predetermined calculation processing, storage processing, and the like. The control unit 40 stores in advance various information, programs, etc. used when controlling the operation of the power supply system 1.

Further, the control unit 40 has information regarding the power plan of the system power supply S. The control unit 40 can calculate, for example, the cost of purchasing power from the system power supply S at the current time based on the information regarding the power plan. Note that purchase does not necessarily indicate payment of money to the system power supply S. For example, the purchase may indicate the payment of money to a third party such as a power retailer interposed between the system power supply S and the residence. In this case, the power purchase cost may include fees to the third party. As described above, in the present invention, the object to which electric power is transferred (system power source S) and the object to which money is transferred are not necessarily the same.

Further, the control unit 40 has information regarding the power generation cost of the fuel cell 30. Specifically, the control unit 40 calculates the power generation cost of the fuel cell 30 when power is generated when the tank is full, and the power generation cost of the fuel cell 30 when power is generated when the tank is not full. ,have. The control unit 40 can acquire information regarding power generation costs using any method (for example, calculation by itself using a predetermined formula, or direct numerical input from a resident of the house). In this embodiment, the power generation cost of the fuel cell 30 when power is generated when the tank is full is, for example, 20 yen/kW, while the cost of power generation of the fuel cell 30 when power is generated when the tank is not full. The power generation cost is, for example, 10 yen/kW.

Further, the control unit 40 is electrically connected to the power conditioner 23. Thereby, the control unit 40 can acquire information regarding the power storage system 20. For example, the control unit 40 can acquire the measurement results of the first sensor 24 via the power conditioner 23, and can acquire information regarding the electric power sold to the grid power supply S (the electric power flowing downstream through the first sensor 24). . Further, the control unit 40 can obtain information regarding the operating states of the solar power generation unit 21 and the storage battery 22 via the power conditioner 23 . Further, the control unit 40 can control the operation of the power storage system 20. Specifically, the control unit 40 can control the operation of the storage battery 22 via the power conditioner 23.

Further, the control unit 40 is electrically connected to the fuel cell 30. Thereby, the control unit 40 can acquire information regarding the fuel cell 30 (for example, the magnitude of generated power, the amount of hot water in the tank, etc.). Further, the control unit 40 can control the operation of the fuel cell 30. Specifically, for example, the control unit 40 can issue a standby instruction to the fuel cell 30 to place the fuel cell 30 in a standby state. Further, the control unit 40 can instruct the fuel cell 30 in a standby state to restart, thereby causing the fuel cell 30 to resume power generation. Further, the control unit 40 can suppress the power generated by the fuel cell 30 by instructing the fuel cell 30 to suppress power generation.

The charging and discharging mode executed by the storage battery 22 of the power storage system 20 will be described below.

As described above, the charge/discharge mode is a mode in which the storage battery 22 is charged/discharged by the load following function. When the charge/discharge mode is executed, the storage battery 22 becomes in a chargeable/dischargeable state according to the measurement result of the first sensor 24 . Specifically, when the first sensor 24 measures the power flowing downstream, the storage battery 22 discharges power corresponding to the measured power. The discharged power of the storage battery 22 is output to the power distribution line 10 via the power conditioner 23. Furthermore, when the first sensor 24 measures the power flowing upstream, the storage battery 22 is charged with power corresponding to the measured power.

In this manner, in the power storage system 20, when the first sensor 24 measures the power flowing downstream, the power generated by the solar power generation unit 21 is first output to the power distribution line 10, and if the power is still insufficient (the first sensor 24 (measures the power flowing downstream), the discharged power of the storage battery 22 is then output to the distribution line 10. Further, when the first sensor 24 measures the power flowing to the upstream side, the storage battery 22 is first charged with the power generated by the solar power generation unit 21 . When the power generated by the solar power generation unit 21 is surplus to the charging of the storage battery 22, the surplus power is output to the power distribution line 10.

In addition, when the charge/discharge mode is executed, if the storage battery 22 does not have the minimum remaining power storage (charging) amount, the storage battery 22 cannot be discharged even if it is in a situation where it should be discharged as described above. . Further, when the storage battery 22 is fully charged, the storage battery 22 cannot be charged even if it is in a situation where it should be charged as described above.

Below, the power supply mode of the power supply system 1 will be briefly explained.

The power supply system 1 is configured so that power can be supplied to the residential load 50 from three power supply sources (namely, the system power supply S, the fuel cell 30, and the power storage system 20). Among the three power supply sources, when the fuel cell 30 generates power using the load following function, power according to the measurement result of the second sensor 31 is output to the power distribution line 10 . Similarly, in the power storage system 20, the storage battery 22 that executes the charging/discharging mode performs charging/discharging using the load following function, so that power according to the measurement result of the first sensor 24 is output to the distribution line 10. Furthermore, when comparing the arrangement of the fuel cell 30 and the power storage system 20, the fuel cell 30 is connected to the downstream side (the residential load 50 side) than the power storage system 20.

According to such a configuration, when there is power consumption (power demand) in the residential load 50, the power generated by the fuel cell 30 among the grid power supply S, the power storage system 20, and the fuel cell 30 is first preferentially applied to the residential load 50. is supplied to Then, when the power generated by the fuel cell 30 alone is insufficient for the residential load 50, power from the power storage system 20 is then supplied to the residential load 50. In this case, in the power storage system 20, the power generated by the solar power generation unit 21 is first supplied to the residential load 50 on a priority basis, and when the power generated by the solar power generation unit 21 is insufficient, the discharged power of the storage battery 22 is is supplied to the residential load 50. Then, when the power generated by the fuel cell 30 and the power from the power storage system 20 (the power generated by the solar power generation unit 21 and the discharged power of the storage battery 22) are insufficient for the residential load 50, power from the grid power source S is used. (purchased power) is supplied to the residential load 50. Note that the purchased power indicates the power received from the system power supply S to the distribution line 10.

Further, when the residential load 50 can be covered only by the discharge power of the fuel cell 30, the power generated by the solar power generation unit 21 of the power storage system 20 is charged to the storage battery 22, or the power generated by the solar power generation unit 21 of the power storage system 20 is The surplus power is reversely flowed (sold) to the grid power supply S. Similarly, when the residential load 50 can be covered only by the power generated by the fuel cell 30 and a part of the power generated by the solar power generation section 21, the remaining power generated by the solar power generation section 21 is used to charge the storage battery 22. Alternatively, the surplus of the charge of the storage battery 22 is reversely flowed (sold) to the system power supply S.

In this way, the power supply system 1 is configured such that power can be supplied to the residential load 50 from an appropriate power supply source among the three power supply sources (i.e., the grid power supply S, the fuel cell 30, and the power storage system 20). be done. Further, in the power storage system 20, surplus power generated by the solar power generation unit 21 can be sold to the grid power supply S.

Here, in the above-described power supply mode, the fuel cell 30 generates power without considering the states of the solar power generation unit 21 and the storage battery 22. That is, in recent years, self-consumption of the power generated by the solar power generation unit 21 has been desired, but since the fuel cell 30 generates power regardless of the power generated by the solar power generation unit 21, the power generation by the solar power generation unit 21 is It is difficult to improve the self-consumption rate of electricity.

Further, since the fuel cell 30 supplies power to the residential load 50 with priority over the grid power supply S and the power storage system 20, for example, when generating electricity when the tank is full, the above-mentioned Thus, the power generated by the fuel cell 30, which has a high power generation cost, is supplied to the residential load 50.

In addition, as a power supply source that supplies power to the residential load 50, the storage battery 22 has a lower priority compared to other devices (fuel cell 30 and solar power generation unit 21), so the power output (discharged) is The target tends to be small. That is, the discharge of the storage battery 22 tends to result in low output, and the discharge efficiency of the storage battery 22 tends to deteriorate.

Therefore, in the power supply system 1, (1) the self-consumption rate of the power generated by the solar power generation unit 21 is improved (suppression of surplus power generated by the solar power generation unit 21), (2) the power generation cost of the fuel cell 30 is reduced. Processing (hereinafter referred to as "specific processing") can be executed to solve three problems: (3) suppressing power generation by the fuel cell 30 when the fuel cell 30 is high, and (3) improving the discharge efficiency of the storage battery 22.

The identification process will be described below using flowcharts shown in FIGS. 2 to 5 and block diagrams shown in FIGS. 6 to 13.

Note that FIGS. 6 to 13 show examples of specific power supply modes (pattern 1 to pattern 8) when specific processing is executed. In FIGS. 6 to 13, the memory (four rectangular frames) shown inside the storage battery 22 is an image of the remaining charge of the storage battery 22. Specifically, the number of black frames among the four rectangular frames indicates the approximate ratio of the remaining charge to the maximum capacity. Similarly, the colored part in the frame described inside the hot water storage tank 32 is an image of the amount of stored hot water (tank hot water amount). Specifically, the height of the colored part relative to the height of the frame indicates the approximate ratio of the amount of hot water in the tank to the maximum amount of hot water stored.

The specific process is repeatedly executed by the control unit 40 at predetermined timings (for example, at one-minute intervals). In this way, the control unit 40 repeatedly makes various judgments and executes predetermined control in real time based on the obtained judgment results.

In the following, for convenience of explanation, the processing from step S101 to step S104 shown in FIG. 2 will be described later, and the processing from step S105 shown in FIG. 3 will be described first.

In step S105, the control unit 40 determines whether the sold power is greater than 0, that is, whether there is sold power to the system power supply S. When the control unit 40 determines that there is no electricity to sell (“NO” in step S105), the process proceeds to step S121. On the other hand, when the control unit 40 determines that there is power for sale ("YES" in step S105), the process proceeds to step S106.

Here, when there is sold power, it is assumed that a surplus occurs in the power generated by the solar power generation unit 21, and the surplus power flows backward to the system power supply S. In such a case, from the viewpoint of improving the self-consumption rate of the power generated by the solar power generation unit 21, it may be desirable to put the power generation of the fuel cell 30 on standby. Therefore, in the processes after step S106, it is confirmed whether it is desirable to put the fuel cell 30 in a standby state, and depending on the result of the check, the fuel cell 30 is put in a standby state (see step S113, which will be described later). Note that the standby state of the fuel cell 30 refers to a state in which the generated power is completely zero, and a state in which the external output of the generated power is suppressed.

Note that when restarting (restarting) the power generation of the fuel cell 30 in the standby state, a relatively long time is required until the power generation is restarted. Furthermore, frequent restarting of the fuel cell 30 places an excessive burden on the stack, which is undesirable from the viewpoint of durability of the fuel cell 30. Therefore, in this embodiment, the fuel cell 30 is set to be restarted only once a day.

In step S106, the control unit 40 determines whether the sold power is greater than the power generated by the fuel cell 30. When the control unit 40 determines that the sold power is larger than the power generated by the fuel cell 30 (“YES” in step S106), the process proceeds to step S107. On the other hand, if the control unit 40 determines that the sold power is less than or equal to the power generated by the fuel cell 30 ("NO" in step S106), it temporarily ends the identification process.

Here, the case where the sold power is less than or equal to the power generated by the fuel cell 30 means that, for example, when the fuel cell 30 is placed in a standby state (that is, if the power generated by the fuel cell 30 is set to 0), the power is stored for the residential load 50. This indicates that the power from the system 20 (power from the solar power generation unit 21 and storage battery 22) may be insufficient. In such a case, if the fuel cell 30 is placed in a standby state, there is a possibility that power will be purchased from the system power supply S. In this way, it is undesirable from the viewpoint of utility costs that electric power is purchased from the system power supply S by placing the fuel cell 30 in a standby state. Therefore, if it is determined that the sold power is less than or equal to the power generated by the fuel cell 30 ("NO" in step S106), the specific processing is temporarily ended without putting the fuel cell 30 into a standby state.

In step S107, the control unit 40 determines whether or not a standby instruction has not been used (no standby instruction has been given to the fuel cell 30 even once) on the current day (today based on the current time). If the control unit 40 determines that the standby instruction is not used on that day (“YES” in step S107), the process proceeds to step S108. On the other hand, if the control unit 40 determines that the standby instruction is not unused on that day ("NO" in step S107), it temporarily ends the identification process.

That is, as described above, in this embodiment, the fuel cell 30 is set to be restarted at most once a day. Therefore, on that day, if it is determined that the fuel cell 30 has not been instructed to stand by (that is, the fuel cell 30 has been in the standby state once) ("NO" in step S107), the fuel cell 30 is The specific processing is temporarily ended without entering the standby state for the second time.

In step S108, the control unit 40 determines whether the power generated by the fuel cell 30 is greater than zero. If the control unit 40 determines that the power generated by the fuel cell 30 is greater than 0 (that is, the fuel cell 30 is generating power) ("YES" in step S108), the process proceeds to step S109. On the other hand, if the control unit 40 determines that the power generated by the fuel cell 30 is 0 or less (that is, the fuel cell 30 is not generating power) ("NO" in step S108), it temporarily ends the specific process. .

Note that in the case where the fuel cell 30 is not generating power even though there is electricity for sale ("YES" in step S105), it is assumed that the fuel cell 30 is currently in a standby state. Here, as described above, the processing after step S106 is the processing for placing the fuel cell 30 in a standby state in a predetermined case. Therefore, if it is determined that the fuel cell 30 is not generating power ("NO" in step S108), there is no need to execute the process of placing the fuel cell 30 in a standby state, so the specific process is temporarily ended.

In step S109, the control unit 40 determines whether the power generation of the fuel cell 30 continues for n (3 in this embodiment) minutes. If the control unit 40 determines that the fuel cell 30 has been generating power for three minutes ("YES" in step S109), the process proceeds to step S110. On the other hand, if the control unit 40 determines that the power generation of the fuel cell 30 has not continued for three minutes ("NO" in step S109), it temporarily ends the specific process.

Here, as described above, the fuel cell 30 generates power according to the residential load 50 using the load following function. Therefore, if the fuel cell 30 does not continuously generate power for three minutes, it is assumed that the power consumption of the residential load 50 fluctuates significantly over a relatively short period of time. In such a case, it is not desirable to put the fuel cell 30 in a standby state because there is a possibility that it will be necessary to restart the fuel cell 30 immediately even if the fuel cell 30 is in a standby state. Therefore, if it is determined that the power generation of the fuel cell 30 has not continued for three minutes ("NO" in step S109), the specific processing is temporarily ended.

In addition, in this embodiment, although 3 is adopted as the numerical value of n, it is not limited to 3. That is, as long as it can be determined whether the fuel cell 30 is stably generating power, any numerical value can be adopted as needed.

In step S110, the control unit 40 calculates the required time until the amount of hot water in the tank of the fuel cell 30 reaches a specified value or more. Note that, as described above, the designated value is set to 80% in this embodiment. That is, in this process, the control unit 40 determines, for example, if the current amount of hot water in the tank is 50%, how many hours the fuel cell 30 needs to generate electricity in order to increase the amount of hot water in the tank from 50% to 80% or more. calculate. After performing the process in step S110, the control unit 40 moves to step S111.

In step S111, the control unit 40 determines whether the time obtained by adding the required time to the current time is earlier than the specified value attainment deadline time (the time when the tank hot water amount should be maximized (i.e., the specified value) on that day). do. If the control unit 40 determines that the time obtained by adding the necessary time to the current time is earlier than the specified value attainment deadline time ("YES" in step S111), the process proceeds to step S112. On the other hand, if the control unit 40 determines that the time obtained by adding the required time to the current time is after the specified value attainment deadline time ("NO" in step S111), it temporarily ends the specific processing.

Here, the case where the time obtained by adding the required time to the current time is after the specified value attainment deadline time means that even if power is generated from the current time, the amount of hot water required by the specified value attainment deadline time (specified value) is not reached. In this way, a situation in which the required amount of hot water (specified value) is insufficient at the designated value reaching deadline time is undesirable because there is a risk that hot water will run out in response to the demand for hot water supply. That is, in such a case, it is not desirable to execute the process of placing the fuel cell 30 in a standby state (that is, the process of stopping the increase in the amount of hot water in the tank). Therefore, if it is determined that the time obtained by adding the required time to the current time is after the specified value attainment deadline time ("NO" in step S111), the specific processing is temporarily ended.

In step S112, the control unit 40 calculates the restart time of the fuel cell 30. Here, the restart time of the fuel cell 30 means that, for example, when the fuel cell 30 is in a standby state, the amount of hot water in the tank cannot be increased to the specified value (80%) by the specified value attainment deadline time (6:00 p.m.). This is the time at which the fuel cell 30 is allowed to resume power generation. The restart time of the fuel cell 30 is calculated by subtracting the required time from the specified value attainment deadline time. After performing the process in step S112, the control unit 40 moves to step S113.

In step S113, the control unit 40 issues a standby instruction to the fuel cell 30. In this way, the fuel cell 30 changes from the power generation state to the standby state. That is, by temporarily stopping the power generation of the fuel cell 30, it is possible to supply the residential load 50 with surplus power that is flowing backward into the system power supply S out of the power generated by the solar power generation unit 21. In this way, it is possible to improve the self-consumption rate of the power generated by the solar power generation unit 21. After performing the process of step S113, the control unit 40 temporarily ends the identification process.

Here, an example of the power supply mode (pattern 1) when the process of step S113 is executed will be described using FIG. 6.

FIG. 6A shows an example of the power supply mode immediately before executing the process of step S113. Specifically, the residential load 50 is 1000 [W], the power generated by the solar power generation unit 21 is 1200 [W], and the power generated by the fuel cell 30 is 700 [W]. In addition, the amount of hot water in the tank is set to be 80% or more.

That is, in FIG. 6(a), the sold power is 900 [W] ("YES" in step S105), and the sold power (900 [W]) is the generated power of the fuel cell 30 (700 [W]). ) (“YES” in step S106), the standby instruction is not used on that day (“YES” in step S107), and the power generated by the fuel cell 30 is greater than 0 (“YES” in step S108). YES"), and the state continues for 3 minutes ("YES" in step S109), and the time obtained by adding the required time to the current time is earlier than the specified value attainment deadline time ("YES" in step S111). It shows.

In this way, in the state shown in FIG. 6(a), the power generated by the fuel cell 30 is supplied to the residential load 50, and the power generated by the solar power generation unit 21 is sold to the grid power supply S. ). Furthermore, since the sold power (900 [W]) is greater than the power generated by the fuel cell 30 (700 [W]), even if the power generation of the fuel cell 30 is stopped, power cannot be purchased from the grid power source S. There isn't. Further, since the time obtained by adding the necessary time to the current time is earlier than the specified value attainment deadline time, even if the power generation of the fuel cell 30 is stopped, the amount of hot water in the tank will not run out.

In such a case, the process of step S113 causes the fuel cell 30 to change from the power generation state to the standby state, as shown in FIG. 6(b). In this way, as a result of the power generation of the fuel cell 30 being temporarily stopped, the power generated by the solar power generation section 21 is supplied to the residential load 50 instead of the power generated by the fuel cell 30. That is, since a part of the electric power sold to the grid power supply S is supplied to the residential load 50, the electric power sold by the solar power generation unit 21 decreases from 900 [W] to 200 [W]. In this way, it is possible to improve the self-consumption rate of the power generated by the solar power generation unit 21.

Next, the processing from step S101 to step S104 shown in FIG. 2 described above will be explained.

Note that the processing from step S101 to step S104 is processing related to restarting the fuel cell 30 that has been put into a standby state in the processing of step S113 as described above.

In step S101, the control unit 40 determines whether the fuel cell 30 is executing a standby instruction (in a standby state). When the control unit 40 determines that the fuel cell 30 is executing the standby instruction (“YES” in step S101), the process proceeds to step S102. On the other hand, if the control unit 40 determines that the fuel cell 30 is not executing the standby instruction ("NO" in step S101), the process proceeds to step S105.

That is, as described above, the processes from step S101 to step S104 are processes related to restarting the fuel cell 30 that has been put into a standby state, so if the fuel cell 30 is not in a standby state, the processes from steps S101 to S104 are The process moves to a process different from the process (step S105).

In step S102, the control unit 40 determines whether the current time is before the restart time of the fuel cell 30. Note that the restart time of the fuel cell 30 is calculated in the process of step S112, as described above. When the control unit 40 determines that the current time is before the restart time of the fuel cell 30 (“YES” in step S102), the process proceeds to step S103. On the other hand, if the control unit 40 determines that the current time is after the restart time of the fuel cell 30 ("NO" in step S102), the process proceeds to step S104.

In step S104, the control unit 40 instructs the fuel cell 30 to generate power so that the upper limit value of power generation=power generation capacity. Note that the power generation capacity means the maximum power that the fuel cell 30 can generate, and is set to 700 [W] in this embodiment. Moreover, the power generation upper limit value means the upper limit value (value at the time of suppression) at which the fuel cell 30 can generate power. That is, when the process of step S104 is executed, the fuel cell 30 generates power according to the residential load 50 without suppressing power generation.

In this way, the fuel cell 30 that was in the standby state resumes power generation and generates power according to the residential load 50 within the range of power generation capacity (700 [W]). Here, if it is determined that the current time is after the restart time of the fuel cell 30 ("NO" in step S102), there is a possibility that hot water will run out in response to the hot water demand after the specified value reaching deadline time. There is. However, since the fuel cell 30 restarts power generation, it is possible to prevent the hot water from running out even after the designated value reaching deadline. After performing the process of step S104, the control unit 40 temporarily ends the identification process.

In step S103, the control unit 40 determines whether the purchased power from the system power supply S is less than or equal to the minimum purchased power. Note that the minimum purchased power is the purchased power guaranteed when the storage battery 22 or the fuel cell 30 outputs. In other words, the minimum purchase power is used to suppress the power generated by the solar power generation unit 21, whose output tends to fluctuate depending on the weather, from being sold to the grid power source S when the storage battery 22 or fuel cell 30 is outputting. Therefore, it is the power purchased from the system power supply S. In this embodiment, 100 [W] is set as the minimum purchase power. Note that the minimum purchase power is not limited to 100 [W], but it is desirable to use a small amount of power from the viewpoint of utility costs.

If the control unit 40 determines that the purchased power is less than or equal to the minimum purchased power ("YES" in step S103), the process proceeds to step S105. On the other hand, if the control unit 40 determines that the purchased power is greater than or equal to the minimum purchased power ("NO" in step S103), the process proceeds to step S104 as described above. Here, the case where the purchased power is larger than the minimum purchased power (100 [W]) indicates a state in which a relatively large amount of power is purchased from the grid power source S because the fuel cell 30 is not generating power. ing. In such a state, it is not desirable to maintain the fuel cell 30 in a standby state.

As described above, in step S104, the control unit 40 instructs the fuel cell 30 to generate power so that the power generation upper limit value=power generation capacity. As a result, the fuel cell 30 that was in the standby state resumes power generation and generates power according to the residential load 50 within the range of power generation capacity (700 [W]). Thereby, the power purchased from the system power source S can be reduced, and utility costs can be reduced.

Next, the process after step S121 shown in FIG. 4, which is proceeded to when it is determined in the process of step S105 shown in FIG. 3 that there is no sold power ("NO" in step S105) as described above, will be described.

In step S121, the control unit 40 determines whether the purchased power is greater than the minimum purchased power. When the control unit 40 determines that the purchased power is larger than the minimum purchased power ("YES" in step S121), the process proceeds to step S122. On the other hand, if the control unit 40 determines that the purchased power is less than or equal to the minimum purchased power ("NO" in step S121), the process proceeds to step S131.

Here, if the purchased power is larger than the minimum purchased power ("YES" in step S121), the fuel cell 30 is in a power generation state, and the power storage system 20 is in a standby state or stores power for the residential load 50. In a state where the power from the system 20 is insufficient (that is, when the solar power generation unit 21 is not generating power, or even if it is generating power, the generated power is insufficient, and it is outside the discharge time of the storage battery 22, This is assumed to be the case (when the remaining charge of the storage battery 22 is insufficient, when the storage battery 22 is in a standby state, etc.).

In step S122, the control unit 40 determines whether the tank is full of hot water. When the control unit 40 determines that the tank water amount is full ("YES" in step S122), the process proceeds to step S124. On the other hand, if the control unit 40 determines that the tank hot water amount is not full ("NO" in step S122), the process proceeds to step S123.

Note that, as described above, whether or not the amount of hot water in the tank is full affects the power generation cost of the fuel cell 30. Specifically, the power generation cost of the fuel cell 30 when the tank is full of hot water is the same as the cost of the fuel cell 30 when generating power when the tank is not full (not full). It will be higher than the power generation cost.

In step S123, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to the power generation capacity (700 [W] in this embodiment). Thereby, if the fuel cell 30 is suppressing power generation, the control unit 40 can temporarily release the suppression of power generation. In this way, when the amount of hot water in the tank is not full, it is possible to increase the generated power and the amount of hot water in the tank. After performing the process of step S123, the control unit 40 temporarily ends the identification process.

In this way, if it is determined that the tank hot water amount is not full ("NO" in step S122), that is, if it is determined that the power generation cost of the fuel cell 30 is low, the power is not purchased from the grid power source S. , the fuel cell 30 can be encouraged to generate electricity (step S123).

In step S124, the control unit 40 determines whether the power generation cost of the fuel cell 30 is lower than the power purchase cost when power is purchased from the grid power source S. When the control unit 40 determines that the power generation cost of the fuel cell 30 is lower than the power purchase cost (“YES” in step S124), the process proceeds to step S126. On the other hand, if the control unit 40 determines that the power generation cost of the fuel cell 30 is greater than or equal to the power purchase cost ("NO" in step S124), the process proceeds to step S125.

In step S125, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to the power generation lower limit value of the fuel cell 30. In this embodiment, the lower limit of power generation is set to 50 [W]. As a result, the power generated by the fuel cell 30 is suppressed so that the upper limit value of power generation becomes the lower limit value of power generation. Note that the power generation lower limit value means the value of generated power that should be guaranteed during suppression in the fuel cell 30. That is, the fuel cell 30 does not perform power generation such that the generated power falls below the power generation lower limit value. In other words, the power generated by the fuel cell 30 is generally maintained at the lower limit of power generation. Note that an instruction from the control unit 40 to update the power generation upper limit value of the fuel cell 30 to a smaller value is referred to as a suppression instruction.

In this way, if it is determined that the power generation cost of the fuel cell 30 is greater than or equal to the power purchase cost ("NO" in step S124), the power generation upper limit value of the fuel cell 30 is updated to the power generation lower limit value of the fuel cell 30. (Step S125). Thereby, the residential load 50 can be supplied with purchased power from the low-cost system power source S instead of the high-cost power generated by the fuel cell 30. After performing the process of step S125, the control unit 40 temporarily ends the identification process.

Note that an example of the power supply mode (pattern 4) when the process of step S125 is executed will be described later.

On the other hand, if it is determined in step S124 that the power generation cost of the fuel cell 30 is lower than the power purchase cost ("YES" in step S124), the control unit 40 controls the addition of the fuel cell 30 in step S126. Calculate the required power. Note that the additional required power is an additional output value required of the fuel cell 30. The additional required power is calculated by subtracting the minimum purchased power (100 [W]) from the purchased power. After performing the process in step S126, the control unit 40 moves to step S127.

In step S127, the control unit 40 determines whether the value obtained by adding the additional required power to the (current) power generation upper limit value of the fuel cell 30 is smaller than the power generation capacity of the fuel cell 30. If the control unit 40 determines that the value obtained by adding the additional requested power to the power generation upper limit value of the fuel cell 30 is smaller than the power generation capacity of the fuel cell 30 (“YES” in step S127), the process proceeds to step S128. On the other hand, if the control unit 40 determines that the value obtained by adding the additional required power to the power generation upper limit of the fuel cell 30 is greater than or equal to the power generation capacity of the fuel cell 30 ("NO" in step S127), the control unit 40 performs the steps described above. The process moves to S123.

Note that an example of the power supply mode (pattern 2) when the process of step S123 transferred from step S127 is executed will be described later.

In step S128, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to a value obtained by adding the additional required power to the current power generation upper limit value. Thereby, if the fuel cell 30 is suppressing power generation, the control unit 40 can partially cancel the power generation suppression and generate a larger amount of power than before the update.

Note that an example of the power supply mode (pattern 3) when the process of step S128 is executed will be described later.

In this way, if the purchased power is larger than the minimum purchase power and it is determined that the tank is full, the power generation cost of the fuel cell 30 and the power purchase cost are compared and the Control is performed based on the results ("YES" in step S121, "YES" in step S122, step S124).

Specifically, if it is determined that the power generation cost of the fuel cell 30 is equal to or higher than the power purchase cost ("NO" in step S124), the power generation upper limit value of the fuel cell 30 is set to the power generation cost of the fuel cell 30, as described above. The power generation lower limit value is updated (step S125).

On the other hand, if it is determined that the power generation cost of the fuel cell 30 is smaller than the power purchase cost ("YES" in step S124), even if the tank is full, the amount of fuel required for the residential load 50 is It is desirable to give priority to the power generated by the battery 30 and to suppress purchased power. Therefore, first, the additional power required by the fuel cell 30 (i.e., the amount of power that should be increased from the current power generated by the fuel cell 30 when the current purchased power is reduced to the minimum purchased power (100 [W])) is calculated (step S126).

Next, check whether the value obtained by adding the additional required power to the (current) power generation upper limit value of the fuel cell 30 is smaller than the power generation capacity of the fuel cell 30, that is, the fuel cell (with a power generation capacity of 700 [W]). 30 determines whether it is possible to generate power by adding the additional required power to the generated power without exceeding the power generation capacity (step S127).

If the fuel cell 30 is capable of generating power by adding the additional requested power to the generated power without exceeding the power generation capacity ("YES" in step S127), the current power generation upper limit value of the fuel cell 30 is is updated to a value obtained by adding the additional required power to the power generation upper limit value (step S128). That is, the power generation of the fuel cell 30 can be increased, and the power purchased from the system power source S can be reduced to the minimum purchased power. In this way, the electric power generated by the fuel cell 30 can be supplied to the residential load 50 with priority over purchased electric power which costs more.

Further, if the fuel cell 30 is not capable of generating the power generated by adding the additional requested power to the generated power without exceeding the power generation capacity ("NO" in step S127), the power generation upper limit value of the fuel cell 30 is The capacity is updated to (700 [W] in this embodiment) (step S123). That is, although it is not possible to increase the power generation of the fuel cell 30 and reduce the purchased power from the grid power source S to the minimum purchased power, it is possible to reduce the purchased power from the grid power source S to the extent possible. . In this way, the electric power generated by the fuel cell 30 can be supplied to the residential load 50 with priority over purchased electric power which costs more.

Here, with reference to FIG. 7, an example (pattern 2) of the power supply mode when the process of step S123, which is a transition from step S127, is executed will be described.

FIG. 7A shows an example of the power supply mode immediately before executing the process of step S123 after the process of step S127. Specifically, the residential load 50 is set to 3000 [W], the power generated by the solar power generation unit 21 is set to 0 [W], and the power generated by the fuel cell 30 is set to 400 [W] (power generation is being suppressed). , the discharge power of the storage battery 22 is 2000 [W]. Further, the tank hot water amount is assumed to be 100%.

In other words, in FIG. 7(a), the sold power is 0 [W] ("NO" in step S105), and the purchased power (600 [W]) is lower than the minimum purchased power (100 [W]). ("YES" in step S121), the tank hot water amount is full ("YES" in step S122), and the power generation cost of the fuel cell 30 is smaller than the power purchase cost ("YES" in step S124). ), and the value obtained by adding the additional required power to the power generation upper limit value of the fuel cell 30 is greater than or equal to the power generation capacity of the fuel cell 30 (“NO” in step S127).

In such a case, as shown in FIG. 7B, the power generation upper limit value of the fuel cell 30 is updated to the power generation capacity (700 [W]) through the process of step S123. That is, the suppression of power generation by the fuel cell 30 is temporarily released. In this way, as a result of the power generation suppression of the fuel cell 30 being released, the purchased power from the system power supply S decreases by the amount (300 [W]) that the power generated by the fuel cell 30 increases. Specifically, the power purchased from the system power supply S decreases from 600 [W] to 300 [W]. In this way, although it is not possible to reduce the initial power purchased from the grid power source S (600 [W]) to the minimum purchased power (100 [W]), it is possible to reduce the purchased power from the grid power source S to the extent possible. This can lead to a reduction in utility costs.

Next, with reference to FIG. 8, an example of the power supply mode (pattern 3) when the process of step S128 is executed will be described.

FIG. 8A shows an example of the power supply mode immediately before executing the process of step S128. Specifically, the residential load 50 is set to 2700 [W], the power generated by the solar power generation unit 21 is set to 0 [W], and the power generated by the fuel cell 30 is set to 400 [W] (power generation is being suppressed). , the discharge power of the storage battery 22 is 2000 [W]. Further, the tank hot water amount is assumed to be 100%.

In other words, in FIG. 8(a), the sold power is 0 [W] ("NO" in step S105), and the purchased power (600 [W]) is lower than the minimum purchased power (100 [W]). ("YES" in step S121), the tank hot water amount is full ("YES" in step S122), and the power generation cost of the fuel cell 30 is smaller than the power purchase cost ("YES" in step S124). ), and the value obtained by adding the additional required power to the power generation upper limit value of the fuel cell 30 is smaller than the power generation capacity of the fuel cell 30 (“YES” in step S127).

Note that the major difference from pattern 2 shown in FIG. "NO"), and pattern 3 is a point where the value obtained by adding the additional required power to the power generation upper limit of the fuel cell 30 is smaller than the power generation capacity of the fuel cell 30 ("YES" in step S127).

In such a case, as shown in FIG. 8(b), the power generation upper limit value of the fuel cell 30 is updated to a value obtained by adding the additional required power to the current power generation upper limit value by the process of step S128. In other words, the suppression of power generation by the fuel cell 30 is not completely canceled, but only a part of it is canceled. In this way, as a result of (partially) canceling the power generation suppression of the fuel cell 30, the purchased power from the system power source S decreases by the amount (200 [W]) that the power generated by the fuel cell 30 increases. Specifically, the power purchased from the system power supply S decreases from 300 [W] to 100 [W]. In this way, the original power purchased from the system power supply S (300 [W]) can be reduced to the minimum purchased power (100 [W]). That is, it is possible to reduce the power purchased from the system power supply S to the maximum extent possible, and it is possible to reduce utility costs.

Next, with reference to FIG. 9, an example of the power supply mode (pattern 4) when the process of step S125 is executed will be described.

FIG. 9A shows an example of the power supply mode immediately before executing the process of step S125. Specifically, the residential load 50 is set to 3000 [W], the power generated by the solar power generation unit 21 is set to 0 [W], and the power generated by the fuel cell 30 is set to 400 [W] (power generation is being suppressed). , the discharge power of the storage battery 22 is 2000 [W]. Further, the tank hot water amount is assumed to be 100%.

In other words, in FIG. 9(a), the sold power is 0 [W] ("NO" in step S105), and the purchased power (600 [W]) is lower than the minimum purchased power (100 [W]). is large (“YES” in step S121), the tank hot water amount is full (“YES” in step S122), and the power generation cost of the fuel cell 30 is greater than the power purchase cost (“NO” in step S124). ) indicates the condition.

In such a case, as shown in FIG. 9(b), the upper limit value of power generation of the fuel cell 30 is updated to the lower limit value (50 [W]) of power generation by the process of step S125. That is, since the power generation cost of the fuel cell 30 is greater than the power purchase cost, the power generation of the fuel cell 30 is suppressed more strongly. In this way, as a result of the stronger suppression of power generation by the fuel cell 30, the power purchased from the system power supply S increases by the amount (350 [W]) that the power generated by the fuel cell 30 has decreased. Specifically, the power purchased from the system power supply S increases from 600 [W] to 950 [W]. In this way, the residential load 50 can be supplied with purchased power from the low-cost system power supply S instead of the high-cost power generated by the fuel cell 30, thereby reducing utility costs.

Next, as described above, when it is determined in the process of step S121 shown in FIG. 4 that the purchased power is less than or equal to the minimum purchase power ("NO" in step S121), the process after step S131 shown in FIG. 5 will be described. explain.

Here, the case where the purchased power is less than or equal to the minimum purchased power ("NO" in step S121) means that the purchased power and the minimum purchased power are the same, or the purchased power is smaller than the minimum purchased power, is included.

The case where the purchased power and the minimum purchased power are the same is assumed to be a case where at least one of the storage battery 22 or the fuel cell 30 is in an output state, or a case where it is a coincidence. Furthermore, the case where the purchased power is smaller than the minimum purchase power is a state in which the amount of power generated by the solar power generation unit 21 is insufficient (regardless of the power generation state of the fuel cell 30) is purchased, and Since the insufficient power is not large enough to be discharged, it is assumed that the storage battery 22 is in a standby state.

In step S131, the control unit 40 determines whether the power generated by the fuel cell 30 is greater than zero. If the control unit 40 determines that the power generated by the fuel cell 30 is greater than 0, that is, the fuel cell 30 is generating power ("YES" in step S131), the process proceeds to step S133. On the other hand, if the control unit 40 determines that the power generated by the fuel cell 30 is 0 or less, that is, the fuel cell 30 is not generating power ("NO" in step S131), the process proceeds to step S132.

In step S132, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to the power generation capacity. Thereby, if the fuel cell 30 is suppressing power generation, the control unit 40 can temporarily release the suppression of power generation. In this way, when the amount of hot water in the tank is not full, it is possible to increase the generated power and the amount of hot water in the tank. After performing the process of step S132, the control unit 40 temporarily ends the identification process.

In step S133, the control unit 40 determines whether the storage battery 22 is in a discharge state. When the control unit 40 determines that the storage battery 22 is in a discharged state ("YES" in step S133), the process proceeds to step S141. On the other hand, if the control unit 40 determines that the storage battery 22 is not in a discharge state ("NO" in step S133), the process proceeds to step S134.

Here, if the storage battery 22 is in a discharge state in step S133 (“YES” in step S133), it is assumed that the discharged power of the storage battery 22 can cover the shortage of the residential load 50. On the other hand, if the storage battery 22 is not in a discharge state in step S133 ("NO" in step S133), it means that only the power generated by the fuel cell 30 or the power generated by the fuel cell 30 and the solar power generation unit 21 is used to reduce the residential load 50. It is assumed that the remaining capacity of the storage battery 22 is insufficient.

In step S134, the control unit 40 determines whether the tank is full of hot water. When the control unit 40 determines that the tank water amount is full ("YES" in step S134), the process proceeds to step S135. On the other hand, if the control unit 40 determines that the tank hot water amount is not full ("NO" in step S134), the process proceeds to step S132 as described above.

In step S132 following step S134, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to the power generation capacity. That is, if it is determined that the tank hot water amount is not full ("NO" in step S134), that is, if it is determined that the power generation cost is low, for example, rather than purchasing power from the grid power source S, the fuel cell 30 It is desirable to encourage power generation. Therefore, if the fuel cell 30 is suppressing power generation, the control unit 40 cancels the suppression of power generation.

In step S135, the control unit 40 determines whether the power generation cost of the fuel cell 30 is lower than the power purchase cost when power is purchased from the grid power source S. When the control unit 40 determines that the power generation cost of the fuel cell 30 is lower than the power purchase cost (“YES” in step S135), the process proceeds to step S136. On the other hand, if the control unit 40 determines that the power generation cost of the fuel cell 30 is equal to or higher than the power purchase cost ("NO" in step S135), the process proceeds to step S137.

In step S136, the control unit 40 determines whether the remaining amount of the storage battery 22 (remaining amount of stored power) is greater than the minimum amount of stored power. When the control unit 40 determines that the remaining amount of the storage battery 22 is greater than the minimum storage amount ("YES" in step S136), the process proceeds to step S137. On the other hand, when the control unit 40 determines that the remaining amount of the storage battery 22 is less than or equal to the minimum storage amount (“NO” in step S136), the control unit 40 temporarily ends the specific processing.

In step S137, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to the power generation lower limit value (50 [W]) of the fuel cell 30. Thereby, the power generated by the fuel cell 30 is suppressed so that the upper limit of power generation becomes the lower limit of power generation. In this way, when the power generation of the fuel cell 30 is suppressed so that the upper limit of power generation becomes the lower limit of power generation, the power generated by the fuel cell 30 is generally maintained at the lower limit of power generation. After performing the process of step S137, the control unit 40 temporarily ends the identification process.

Note that an example of the power supply mode (pattern 7) when the process of step S137 that has proceeded from step S136 is executed will be described later. Further, an example of the power supply mode (pattern 8) when the process of step S137 that has proceeded from step S135 is executed will be described later.

In this way, when the storage battery 22 is not in a discharge state and it is determined that the tank hot water is full, the power generation cost of the fuel cell 30 and the power purchase cost are compared and the result is The control is performed based on the control ("NO" in step S133, "YES" in step S134, step S135).

Specifically, if it is determined that the power generation cost of the fuel cell 30 is equal to or higher than the power purchase cost ("NO" in step S135), the power generation upper limit value of the fuel cell 30 is set to the power generation lower limit value ( 50 [W]) (step S137). Thereby, the residential load 50 can be supplied with purchased power from the low-cost system power supply S instead of the high-cost power generated by the fuel cell 30.

On the other hand, if it is determined that the power generation cost of the fuel cell 30 is lower than the power purchase cost ("YES" in step S135), it is determined whether the remaining amount of the storage battery 22 is greater than the minimum storage amount. (Step S136). That is, in step S136, it is checked whether the storage battery 22 that is not in the discharge state has a remaining capacity that can be discharged, and if it has a remaining capacity that can be discharged ("YES" in step S136), The power generation upper limit value of the fuel cell 30 is updated to the power generation lower limit value of the fuel cell 30 (step S137). In this way, when the tank hot water amount is full ("YES" in step S134), even if the power generation cost of the fuel cell 30 is lower than the power purchase cost, the power generation of the fuel cell 30 is suppressed ( (without forcing power generation), the discharged power of the storage battery 22 is given priority and supplied to the residential load 50.

On the other hand, in step S136, it is checked whether the storage battery 22 which is not in the discharge state has a remaining capacity that can be discharged, and if it does not have a remaining capacity that can be discharged ("NO" in step S136). Since the storage battery 22 cannot be discharged, the specific processing is temporarily ended without updating the power generation upper limit value of the fuel cell 30 (that is, without suppressing the power generation of the fuel cell 30).

Next, in step S141, which is proceeded to when the storage battery 22 is in a discharge state in step S133 ("YES" in step S133), the control unit 40 determines whether or not the tank is full of hot water. When the control unit 40 determines that the tank hot water amount is full ("YES" in step S141), the process proceeds to step S143. On the other hand, when the control unit 40 determines that the tank hot water amount is not full ("NO" in step S141), the process proceeds to step S142.

In step S142, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the power generation upper limit value of the fuel cell 30 is updated to the power generation capacity. Thereby, if the fuel cell 30 is suppressing power generation, the control unit 40 can temporarily release the suppression of power generation. In this way, when the amount of hot water in the tank is not full, it is possible to increase the generated power and the amount of hot water in the tank. That is, if it is determined that the tank water volume is not full ("NO" in step S141), that is, if it is determined that the power generation cost is low, power generation by the fuel cell 30 is performed instead of purchasing power from the grid power source S. can be encouraged.

In step S143, the control unit 40 determines whether the power generation cost of the fuel cell 30 is lower than the power purchase cost when power is purchased from the grid power source S. When the control unit 40 determines that the power generation cost of the fuel cell 30 is lower than the power purchase cost (“YES” in step S143), the process proceeds to step S144. On the other hand, if the control unit 40 determines that the power generation cost of the fuel cell 30 is greater than or equal to the power purchase cost ("NO" in step S143), the process proceeds to step S137 as described above.

In this way, when it is determined that the power generation cost of the fuel cell 30 is greater than or equal to the power purchase cost ("NO" in step S143), the power generation upper limit value of the fuel cell 30 is set to the power generation lower limit value of the fuel cell 30 (50 [W ]) (step S137). Thereby, when the storage battery 22 has a remaining charge, the discharged power of the storage battery 22 can be supplied to the residential load 50. Further, when there is no charge remaining in the storage battery 22, the residential load 50 can be supplied with purchased power from the low-cost system power source S instead of the high-cost power generated by the fuel cell 30.

In step S144, the control unit 40 determines whether the remaining amount (remaining charge amount) of the storage battery 22 is smaller than the lower discharge limit. Note that the discharge lower limit value is a lower limit value at which the storage battery 22 can be efficiently discharged. That is, when the discharge power of the storage battery 22 becomes less than the lower discharge limit value, the discharge efficiency of the storage battery 22 deteriorates. In this embodiment, the discharge lower limit value is set to 1000 [W]. When the control unit 40 determines that the remaining capacity of the storage battery 22 is smaller than the lower discharge limit ("YES" in step S144), the process proceeds to step S145. On the other hand, when the control unit 40 determines that the remaining amount of the storage battery 22 is equal to or higher than the lower discharge limit (“NO” in step S144), the control unit 40 temporarily ends the specific processing.

In step S145, the control unit 40 calculates the required power to be suppressed from the fuel cell 30. Note that the requested suppression power is a suppression value of the electric power required of the fuel cell 30. The required suppression power of the fuel cell 30 is calculated by subtracting the discharge power of the storage battery 22 from the lower limit of discharge of the storage battery 22 (1000 [W]). After performing the process in step S145, the control unit 40 moves to step S146.

In step S<b>146 , the control unit 40 determines whether the value obtained by subtracting the suppression request power from the upper limit of power generation of the fuel cell 30 is equal to or greater than the lower limit of power generation of the fuel cell 30 . If the control unit 40 determines that the value obtained by subtracting the requested power from the power generation upper limit of the fuel cell 30 is equal to or greater than the lower power generation limit of the fuel cell 30 (“YES” in step S146), the process proceeds to step S147. On the other hand, if the control unit 40 determines that the value obtained by subtracting the suppression request power from the upper limit of power generation of the fuel cell 30 is smaller than the lower limit of power generation of the fuel cell 30 ("NO" in step S146), the control unit 40 performs the steps described above. The process moves to S137.

Note that an example of the power supply mode (pattern 6) when the process of step S137 that has proceeded from step S146 is executed will be described later.

In step S147, the control unit 40 updates the power generation upper limit value of the fuel cell 30. Specifically, the (updated) power generation upper limit value of the fuel cell 30 is updated to a value obtained by subtracting the suppression requested power from the current power generation upper limit value. As a result, the power generated by the fuel cell 30 is suppressed to the updated power generation upper limit value. After performing the process of step S147, the control unit 40 temporarily ends the identification process.

Note that an example of the power supply mode (pattern 5) when the process of step S147 is executed will be described later.

In this way, when the storage battery 22 is in a discharge state and it is determined that the tank hot water is full, the power generation cost of the fuel cell 30 and the power purchase cost are compared and the result is ("YES" in step S133, "YES" in step S141, step S143).

Specifically, if it is determined that the power generation cost of the fuel cell 30 is equal to or higher than the power purchase cost (“NO” in step S143), the power generation upper limit value of the fuel cell 30 is set to the power generation lower limit value of the fuel cell 30. It is updated (step S137). Thereby, the residential load 50 can be supplied with purchased power from the low-cost system power supply S instead of the high-cost power generated by the fuel cell 30.

Here, if the power generation cost of the fuel cell 30 is lower than the power purchase cost ("YES" in step S143), even if the tank is full ("YES" in step S141), the fuel It is desirable to supply the generated power of the battery 30 to the residential load 50 with priority over purchased power. On the other hand, if the storage battery 22 is discharging with poor discharge efficiency, the power generated by the fuel cell 30 when the tank is full is suppressed to improve the discharge efficiency of the storage battery 22. This is desirable. Therefore, in this embodiment, the discharge efficiency of the storage battery 22 in the discharge state is checked, and if the storage battery 22 is discharging with poor discharge efficiency, the power generated by the fuel cell 30 is suppressed. The aim is to improve the discharge efficiency of the storage battery 22.

Specifically, first, if the storage battery 22 is discharging with poor discharge efficiency ("YES" in step S144), the suppression request power of the fuel cell 30 (i.e., based on the current power generated by the fuel cell 30) is The amount of power that is insufficient to reach the lower discharge limit (1000 [W]) is calculated (step S145). If the value obtained by subtracting the requested power from the upper limit of power generation of the fuel cell 30 is equal to or higher than the lower limit of power generation of the fuel cell 30, that is, if the storage battery 22 can be used efficiently (in other words, the discharge power is set to 1000 [W] or more). If it is possible to suppress the power generation of the fuel cell 30 to the extent that it is possible to do so (“YES” in step S146), the (updated) power generation upper limit value of the fuel cell 30 is suppressed from the current power generation upper limit value. The value is obtained by subtracting the required power (step S147). Thereby, the power generated by the fuel cell 30 when the tank is full of hot water can be suppressed, and the discharge efficiency of the storage battery 22 can be improved.

Further, if the value obtained by subtracting the requested power from the power generation upper limit of the fuel cell 30 is smaller than the power generation lower limit of the fuel cell 30, that is, if the discharge power of the storage battery 22 cannot be increased to 1000 [W] or more (step If “NO” in S146), the upper limit value of power generation of the fuel cell 30 is updated to the lower limit value of power generation of the fuel cell 30. In this way, the power generated by the fuel cell 30 is suppressed to the lower limit of power generation. Thereby, the power generated by the fuel cell 30 when the tank is full can be suppressed to the extent possible, and the discharge efficiency of the storage battery 22 can be improved (to the extent possible).

Here, an example of the power supply mode (pattern 5) when the process of step S147 is executed will be described using FIG. 10.

FIG. 10A shows an example of the power supply mode immediately before executing the process of step S147. Specifically, the residential load 50 is 1600 [W], the power generated by the solar power generation unit 21 is 0 [W], the power generated by the fuel cell 30 is 700 [W], and the discharge of the storage battery 22 is The power is assumed to be 800 [W]. Further, the tank hot water amount is assumed to be 100%.

That is, in FIG. 10(a), the sold power is 0 [W] ("NO" in step S105), and the purchased power is less than or equal to the minimum purchase power (100 [W]) ("NO" in step S121). NO”), the power generated by the fuel cell 30 is greater than 0 (“YES” in step S131), the storage battery 22 is in a discharge state (“YES” in step S133), and the tank has a full amount of hot water. ("YES" in step S141), the power generation cost of the fuel cell 30 is smaller than the power purchase cost ("YES" in step S143), and the discharge power of the storage battery 22 (800 [W]) is is smaller than the discharge lower limit value (1000 [W]) (“YES” in step S144), and the value obtained by subtracting the suppression request power from the power generation upper limit value of the fuel cell 30 is greater than or equal to the power generation lower limit value of the fuel cell 30 ( YES in step S146). Thus, in the state shown in FIG. 10(a), the discharge efficiency of the storage battery 22 is poor.

In such a case, as shown in FIG. 10(b), the (updated) power generation upper limit value of the fuel cell 30 is set to the value obtained by subtracting the suppression request power from the (pre-update) power generation upper limit value by the process of step S147. It is said that That is, since the discharge efficiency of the storage battery 22 is poor, the power generation suppression of the fuel cell 30 is strengthened. Note that the power generation suppression of the fuel cell 30 is not strengthened to the maximum extent (rather than being suppressed to the lower limit value of power generation), but the power generation suppression is strengthened by the amount necessary to improve the discharge efficiency. In this way, the power generation control of the fuel cell 30 is strengthened by the necessary amount, and as a result, the discharge power of the storage battery 22 increases by the amount (200 [W]) that the power generated by the fuel cell 30 decreases. Specifically, the discharge power of the storage battery 22 increases from 800 [W] to 1000 [W], which is the lower limit of discharge. Thereby, it is possible to suppress the power generated by the fuel cell 30 when the tank has a full amount of hot water, and to improve the discharge efficiency of the storage battery 22.

Next, with reference to FIG. 11, an example of the power supply mode (pattern 6) when the process of step S137 that has proceeded from step S146 is executed will be described.

FIG. 11A shows an example of the power supply mode immediately before executing the process of step S137 after the process of step S146. Specifically, the residential load 50 is 1100 [W], the power generated by the solar power generation unit 21 is 0 [W], the power generated by the fuel cell 30 is 700 [W], and the discharge of the storage battery 22 is The power is assumed to be 300 [W]. Further, the tank hot water amount is assumed to be 100%.

That is, in FIG. 11A, the sold power is 0 [W] ("NO" in step S105), and the purchased power is less than the minimum purchase power (100 [W]) ("NO" in step S121). NO”), the power generated by the fuel cell 30 is greater than 0 (“YES” in step S131), the storage battery 22 is in a discharge state (“YES” in step S133), and the tank has a full amount of hot water. ("YES" in step S141), the power generation cost of the fuel cell 30 is smaller than the power purchase cost ("YES" in step S143), and the discharge power of the storage battery 22 (300 [W]) is is smaller than the discharge lower limit value (1000 [W]) (“YES” in step S144), and the value obtained by subtracting the suppression request power from the power generation upper limit value of the fuel cell 30 is smaller than the power generation lower limit value of the fuel cell 30 ( (“NO” in step S146).

Note that the major difference from pattern 5 shown in FIG. In pattern 6, the value obtained by adding the additional required power to the power generation upper limit of the fuel cell 30 is smaller than the power generation capacity of the fuel cell 30 (“NO” in step S146).

In such a case, as shown in FIG. 11(b), the upper limit value of power generation of the fuel cell 30 is updated to the lower limit value (50 [W]) of power generation by the process of step S137. That is, since the discharge efficiency of the storage battery 22 is poor, the power generation suppression of the fuel cell 30 is strengthened. Note that the fuel cell 30 cannot completely suppress the amount of power required to completely improve the discharge efficiency of the storage battery 22 (in other words, it is not possible to suppress the power generation by 700 [W]), so the upper limit of power generation Power generation is suppressed so that the value becomes the power generation lower limit value. In this way, as a result of the stronger suppression of power generation by the fuel cell 30, the discharged power of the storage battery 22 increases by the amount (650 [W]) that the power generated by the fuel cell 30 decreases. Specifically, the discharge power of the storage battery 22 increases from 300 [W] to 950 [W]. In this way, although it is insufficient to reach the minimum discharge power of 1000 [W], the discharge power of the storage battery 22 can be increased to the extent possible, and the discharge efficiency of the storage battery 22 can be improved.

Next, with reference to FIG. 12, an example of the power supply mode (pattern 7) when the process of step S137 that has proceeded from step S136 is executed will be described.

FIG. 12A shows an example of the power supply mode immediately before executing the process of step S137 after the process of step S136. Specifically, the residential load 50 is 800 [W], the power generated by the solar power generation unit 21 is 0 [W], the power generated by the fuel cell 30 is 700 [W], and the discharge of the storage battery 22 is The power is set to 0 [W]. Further, the tank hot water amount is assumed to be 100%.

That is, in FIG. 12(a), the sold power is 0 [W] ("NO" in step S105), and the purchased power is less than or equal to the minimum purchase power (100 [W]) ("NO" in step S121). NO"), the power generated by the fuel cell 30 is greater than 0 (YES in step S131), the storage battery 22 is not in a discharge state (NO in step S133), and the tank is full of hot water. ("YES" in step S134), the power generation cost of the fuel cell 30 is lower than the power purchase cost ("YES" in step S135), and the remaining charge of the storage battery 22 is less than the minimum storage amount. This indicates a state in which the value is large (“YES” in step S136).

The major difference from pattern 6 shown in FIG. 11 is that in pattern 6, the storage battery 22 is in a discharge state ("YES" in step S133), whereas in pattern 7, the storage battery 22 is not in a discharge state (step S133) ``NO'').

In such a case, as shown in FIG. 12(b), the upper limit value of power generation of the fuel cell 30 is updated to the lower limit value (50 [W]) of power generation by the process of step S137. That is, since the power generation cost of the fuel cell 30 is greater than the power purchase cost, power generation control of the fuel cell 30 is strengthened. In this way, as a result of the power generation suppression of the fuel cell 30 being strengthened, discharge of the storage battery 22 is started, and the discharge power of the storage battery 22 becomes 650 [W], and the power generation of the fuel cell 30 is reduced to the power generation lower limit value (50 [W]. ]). In this manner, when the tank is full of hot water and the storage battery 22 is not discharging, discharging of the storage battery 22 is started. That is, the residential load 50 can be covered by the discharged power of the storage battery 22 instead of the generated power of the fuel cell 30 (which generated power by force). According to this, it is also possible to improve the operating rate of the storage battery 22.

Next, with reference to FIG. 13, an example of the power supply mode (pattern 8) when the process of step S137 that has proceeded from step S135 is executed will be described.

FIG. 13A shows an example of the power supply mode immediately before executing the process of step S137 after the process of step S135. Specifically, the residential load 50 is 800 [W], the power generated by the solar power generation unit 21 is 0 [W], the power generated by the fuel cell 30 is 700 [W], and the discharge of the storage battery 22 is The power is set to 0 [W]. Further, the remaining charge of the storage battery 22 is insufficient to the extent that it cannot be discharged. Further, the tank hot water amount is assumed to be 100%.

That is, in FIG. 13(a), the sold power is 0 [W] ("NO" in step S105), and the purchased power is less than or equal to the minimum purchase power (100 [W]) ("NO" in step S121). NO"), the power generated by the fuel cell 30 is greater than 0 (YES in step S131), the storage battery 22 is not in a discharge state (NO in step S133), and the tank is full of hot water. ("YES" in step S134), and the power generation cost of the fuel cell 30 is greater than the power purchase cost ("NO" in step S135).

The major difference between pattern 7 and pattern 7 shown in FIG. This is the point at which the power generation cost is greater than the power purchase cost ("NO" in step S135).

In such a case, as shown in FIG. 13(b), the upper limit value of power generation of the fuel cell 30 is set to the lower limit value (50 [W]) of power generation by the process of step S137. That is, since the power generation cost of the fuel cell 30 is high, the power generation of the fuel cell 30 is suppressed more strongly. In this way, as a result of the enhanced suppression of power generation by the fuel cell 30, in this example, the storage battery 22 whose remaining charge is insufficient as described above does not start discharging, so that power is purchased from the system power supply S. Specifically, electric power is purchased from the system power supply S by the amount (650 [W]) that the generated electric power of the fuel cell 30 has decreased. In this way, when the amount of hot water in the tank is full and the power generation cost of the fuel cell 30 is more than the power purchase cost, the low cost grid power source S is used instead of the high cost power generated by the fuel cell 30. It is possible to supply the purchased power from the house to the residential load 50, thereby reducing utility costs. In addition, in the example shown in FIG. 13, the case where the remaining charge of the storage battery 22 is insufficient is shown, but when the remaining charge of the storage battery 22 is not insufficient, the power generation suppression of the fuel cell 30 is strengthened. Then, the discharged power of the storage battery 22 can be supplied to the residential load 50 first (before the power is purchased from the system power supply S).

In this way, in the power supply system 1, the control unit 40 executes the specific process, for example, by the process of step S113, to improve the self-consumption rate of the power generated by the solar power generation unit 21 (the solar power generation unit 21 (reduction of surplus generated power). Further, for example, by the process of step S137 that is transferred from step S143, it is possible to suppress the power generation of the fuel cell 30 when the power generation cost of the fuel cell 30 is high. Further, for example, by the process of step S147, it is possible to solve the three problems of improving the discharge efficiency of the storage battery 22.

As described above, in the power supply system 1 according to an embodiment of the present invention,
A fuel cell 30 that can generate power using fuel and can supply generated power to a residential load 50 connected to a system power supply S;
a control unit 40 that controls the operation of the fuel cell 30;
Equipped with
The fuel cell 30 includes:
It is possible to set the power generation upper limit value, which is the upper limit value that can be generated.
When it is possible to generate power within the range up to the power generation upper limit according to the power demand of the residential load 50,
The control unit 40
When purchasing power larger than the predetermined amount (minimum purchase power) from the grid power supply S (“YES” in step S121),
The power generation upper limit value of the fuel cell 30 can be updated based on a comparison between the power generation cost of the fuel cell 30 and the power purchase cost from the grid power source S (for example, if "YES" in step S124 or step S126 - "YES" in step S127 - "YES" in step S128 or step S124 - "NO" in step S126 - step S127 - "NO" in step S123 or step S124 - step S125).

With such a configuration, the fuel cell 30 can be appropriately controlled.
Specifically, when purchasing power larger than the minimum purchase power from the grid power source S, the power generation upper limit value is set based on a comparison between the power generation cost of the fuel cell 30 and the power supply cost from the grid power source S. It can be the power generation capacity (700 [W]) (step S123), the power generation lower limit value (50 [W]) (step S125), or the value obtained by adding the additional required power to the current power generation upper limit value. .

Furthermore, in the power supply system 1,
The control unit 40
If the power generation cost of the fuel cell 30 is lower than the power purchase cost of the grid power source S (“YES” in step S124),
The upper limit value of power generation is updated to increase the upper limit value within the range up to the maximum power generation capacity that the fuel cell 30 can generate (step S123 or step S128).

With such a configuration, the fuel cell 30 can be controlled more appropriately.
Specifically, when the power generation cost of the fuel cell 30 is lower than the power purchase cost of the grid power source S, the power generated by the fuel cell 30 is given priority to the residential load 50 over the purchased power that costs more. can be supplied.

Furthermore, in the power supply system 1,
The control unit 40
If the power generation cost of the fuel cell 30 is greater than or equal to the power purchase cost of the grid power source S (“NO” in step S124),
When the fuel cell 30 generates power, the power generation upper limit value is updated to be lowered to the power generation lower limit value (which is at least the value that should be guaranteed) (step S125).

With such a configuration, the fuel cell 30 can be controlled more appropriately.
Specifically, when the power generation cost of the fuel cell 30 is more than the power purchase cost of the grid power source S, the purchased power from the low cost grid power source S is used in place of the high cost generated power of the fuel cell 30. It can be supplied to the load 50.

Furthermore, in the power supply system 1,
Equipped with a power storage system 20 having a storage battery 22 that can be charged and discharged according to the power demand of the residential load 50 after the power generated by the fuel cell 30 is supplied,
The control unit 40 includes:
Power equal to or less than the predetermined amount (minimum purchased power) is supplied from the grid power supply S to the residential load 50 (“NO” in step S121),
and the storage battery 22 is in a discharge state (“YES” in step S133);
and the power generation cost of the fuel cell 30 is lower than the power purchase cost of the grid power source S (“YES” in step S143);
In addition, when the discharge power of the storage battery 22 is smaller than the discharge lower limit value, which is the lower limit value at which the storage battery 22 can be efficiently discharged ("YES" in step S144),
The power generation upper limit value is updated to be lower within the range up to the power generation lower limit value (step S137 or step S147).

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, even if the cost of the power generated by the fuel cell 30 is low, the discharged power of the storage battery 22 can be used preferentially in certain cases.

Furthermore, in the power supply system 1,
Equipped with a power storage system 20 having a storage battery 22 that can be charged and discharged according to the power demand of the residential load 50 after the power generated by the fuel cell 30 is supplied,
The control unit 40
Purchases power equal to or less than the predetermined amount from the grid power supply S (“NO” in step S121),
and the storage battery 22 is not in a discharge state (“NO” in step S133),
In addition, when the storage battery 22 has a remaining charge level (minimum storage capacity) to the extent that it can be discharged ("YES" in step S136),
The power generation upper limit value is updated to become the power generation lower limit value.

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, in certain cases, the discharged power of the storage battery 22 can be used in preference to the generated power of the fuel cell 30.

Furthermore, in the power supply system 1,
The electricity storage system 20 includes:
It has a solar power generation unit 21 (power generation unit) that can generate electricity using natural energy and can charge the generated power into the storage battery 22,
The fuel cell 30 includes:
It has a hot water storage tank 41, and stores hot water produced using heat generated during power generation in the hot water storage tank 41,
The control unit 40 includes:
There is power generated by the solar power generation unit 21 (power generation unit) to be sold to the grid power supply S (“YES” in step S105);
And if the power generated by the solar power generation unit 21 (power generation unit) sold to the grid power supply S is larger than the power generated by the fuel cell 30 (“YES” in step S106),
In addition, if it is possible to store a predetermined amount of hot water by a predetermined time by the power generation of the fuel cell 30 (specifically, if the fuel cell 30 generates power, the specified value (predetermined amount ) is calculated (step S110), and the time when the necessary time (required time) is added to the current time is when heat is stored up to the specified value (predetermined amount). If it is before the desired time (designated value attainment deadline time) (“YES” in step S111),
The fuel cell 30 is changed from a state capable of generating electricity to a standby state (step S113).

With such a configuration, the fuel cell 30 can be appropriately controlled together with the solar power generation section 21.
Specifically, as described above, there is power generated by the solar power generation unit 21 that is sold to the grid power supply S, and the power generated by the solar power generation unit 21 that is sold to the grid power supply S is generated by the fuel cell 30. If the current time plus the required time is before the specified value arrival deadline time, the fuel cell 30 is put into a standby state and the power generation by the fuel cell 30 is stopped. Instead of electric power, the power generated by the solar power generation unit 21 can be supplied to the residential load 50. Thereby, it is possible to improve the self-consumption rate of the power generated by the solar power generation unit 21.

Furthermore, in the power supply system 1,
The control unit 40 includes:
When it is determined that the predetermined amount of hot water cannot be stored by the predetermined time by the power generation of the fuel cell 30 (specifically, when the fuel cell 30 is in a standby state (step S113), the specified value The re-operation time of the fuel cell 30 is calculated, which is the time when the necessary time (required time) is subtracted from the time when it is desired to store hot water up to a predetermined amount (designated value attainment deadline time) (step S112 ), if the current time is after the restart time (“NO” in step S102),
The fuel cell 30 is changed from a standby state to a state capable of generating electricity (step S104).

With such a configuration, the fuel cell 30 and the solar power generation unit 21 can be controlled more appropriately.
Specifically, if the current time is after the restart time, the fuel cell 30 may suppress power generation even if the power consumption of the residential load 50 can be covered by the power generated by the solar power generation unit 21, for example. Instead, electricity is generated according to the residential load 50. Thereby, the amount of hot water in the tank can be effectively increased so as to approach the specified value (80%) by the specified value reaching deadline time. That is, it is possible to suppress the occurrence of running out of hot water in response to the demand for hot water supply.

Furthermore, in the power supply system 1 according to an embodiment of the present invention,
A fuel cell 30 that can generate power using fuel and can supply generated power to a residential load 50 connected to a system power supply S;
A storage battery 22 that can be charged and discharged according to the power demand of the residential load 50 after the power generated by the fuel cell 30 is supplied, and a storage battery 22 that can generate electricity using natural energy and charge the generated power to the storage battery 22. A power storage system 20 having a solar power generation unit 21 (power generation unit) that can
a control unit 40 that controls the operation of the fuel cell 30;
Equipped with
The control unit 40 includes:
When a predetermined condition set in accordance with power buying and selling (step S105) is satisfied, the power generated by the fuel cell 30 can be suppressed (step S113, step S137, etc.).

With such a configuration, the fuel cell 30 can be appropriately controlled. That is, when a predetermined condition is satisfied, it is possible to suppress the generated power from being supplied to the residential load 50 (which should normally be actively supplied to the residential load 50). In this way, for example, the self-consumption rate of the power generated by the solar power generation unit 21 can be improved. Moreover, the purchased power from the low-cost system power supply S can be supplied to the residential load 50 with priority over the power generated by the fuel cell 30.

Furthermore, in the power supply system 1,
The fuel cell 30 includes:
It is possible to set the power generation upper limit value, which is the upper limit value that can be generated.
The control unit 40
If less than the predetermined amount of power is purchased from the grid power supply S (“NO” in step S121),
As the predetermined condition,
The storage battery 22 is not in a discharge state (“NO” in step S133),
and the power generation cost of the fuel cell 30 is lower than the power purchase cost of the grid power source S (“YES” in step S135);
In addition, when the storage battery 22 has a sufficient amount of charge remaining to be dischargeable ("YES" in step S136),
The power generation upper limit value is updated to become the power generation lower limit value (step S137).

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, in certain cases, even if the cost of the power generated by the fuel cell 30 is low, the discharged power of the storage battery 22 can be used preferentially.

Furthermore, in the power supply system 1,
The control unit 40
If you purchase less than a predetermined amount of electricity from the grid power supply S,
As the predetermined condition,
The storage battery 22 is not in a discharge state (“NO” in step S133),
And if the power generation cost of the fuel cell 30 is higher than the power purchase cost of the grid power source S (“NO” in step S135),
The power generation upper limit value is updated to become the power generation lower limit value (step S137).

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, in a predetermined case, purchased power from the low-cost system power source S can be supplied to the residential load 50 instead of the high-cost power generated by the fuel cell 30.

Furthermore, in the power supply system 1,
The control unit 40
If you purchase less than a predetermined amount of electricity from the grid power supply S,
As the predetermined condition,
The storage battery 22 is in a discharge state (“YES” in step S133),
and the power generation cost of the fuel cell 30 is lower than the power purchase cost of the grid power source S (“YES” in step S143);
In addition, when the discharge power of the storage battery 22 is smaller than the discharge lower limit value, which is the lower limit value at which the storage battery 22 can be efficiently discharged ("YES" in step S144),
The power generation upper limit value is updated to be lower within the range up to the power generation lower limit value (step S137 or step S147).

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, in certain cases, even if the cost of the power generated by the fuel cell 30 is low, the discharged power of the storage battery 22 can be used preferentially.

Furthermore, in the power supply system 1,
The control unit 40
If you purchase less than a predetermined amount of electricity from the grid power supply S,
As the predetermined condition,
The storage battery 22 is in a discharge state (“YES” in step S133),
And if the power generation cost of the fuel cell 30 is higher than the power purchase cost of the grid power source S (“NO” in step S143),
The upper limit value of power generation is updated to the lower limit value of power generation (step S137).

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, in a predetermined case, purchased power from the low-cost system power source S can be supplied to the residential load 50 instead of the high-cost power generated by the fuel cell 30.

Furthermore, in the power supply system 1,
The fuel cell 30 includes:
It has a hot water storage tank 41, and stores hot water produced using heat generated during power generation in the hot water storage tank 41,
The control unit 40 includes:
If you purchase less than the specified amount of electricity from the grid power supply S,
As the predetermined condition,
Regardless of whether the storage battery is in a discharged state,
When the hot water storage tank 41 is full,
The power generation upper limit value is updated to the maximum value that the fuel cell can generate power ("NO" in step S121, "YES" in step S133, "NO" in step S141, "NO" in step S142 or step S121). "NO" in step S133, "NO" in step S134, step S132).

With such a configuration, the fuel cell 30 and the storage battery 22 can be controlled more appropriately.
Specifically, the amount of hot water stored in the hot water storage tank 41 can be taken into consideration when controlling the fuel cell 30 and the storage battery 22.

Furthermore, in the power supply system 1,
The fuel cell 30 includes:
It has a hot water storage tank 41, and stores hot water produced using heat generated during power generation in the hot water storage tank 41,
The control unit 40 includes:
If there is power generated by the solar power generation unit 21 (power generation unit) to be sold to the grid power supply S (“YES” in step S105),
As the predetermined condition,
If the power generated by the solar power generation unit 21 (power generation unit) sold to the grid power supply S is larger than the power generated by the fuel cell 30 (“YES” in step S106),
In addition, if it is possible to store a predetermined amount of hot water by a predetermined time by the power generation of the fuel cell 30 (specifically, if the fuel cell 30 generates power, the specified value (predetermined amount ) is calculated (step S110), and the time when the necessary time (required time) is added to the current time is when heat is stored up to the specified value (predetermined amount). If it is before the desired time (designated value attainment deadline time) (“YES” in step S111),
The fuel cell 30 is changed from a state capable of generating electricity to a standby state (step S113).

With such a configuration, the fuel cell 30 can be appropriately controlled together with the solar power generation section 21.
Specifically, as described above, there is power generated by the solar power generation unit 21 that is sold to the grid power supply S, and the power generated by the solar power generation unit 21 that is sold to the grid power supply S is generated by the fuel cell 30. If the current time plus the required time is before the specified value arrival deadline time, the fuel cell 30 is put into a standby state and the power generation by the fuel cell 30 is stopped. Instead of electric power, the power generated by the solar power generation unit 21 can be supplied to the residential load 50. Thereby, it is possible to improve the self-consumption rate of the power generated by the solar power generation unit 21.

Furthermore, in the power supply system 1,
The control unit 40 includes:
As the predetermined condition,
When it is determined that the predetermined amount of hot water cannot be stored by the predetermined time by the power generation of the fuel cell 30 (specifically, when the fuel cell 30 is in a standby state (step S113), the specified value The re-operation time of the fuel cell 30 is calculated, which is the time when the necessary time (required time) is subtracted from the time when it is desired to store hot water up to a predetermined amount (designated value attainment deadline time) (step S112 ), if the current time is after the restart time (“NO” in step S102),
The fuel cell 30 is changed from a standby state to a state capable of generating electricity (step S104).

With such a configuration, the fuel cell 30 and the solar power generation unit 21 can be controlled more appropriately.
Specifically, if the current time is after the restart time, the fuel cell 30 may suppress power generation even if the power consumption of the residential load 50 can be covered by the power generated by the solar power generation unit 21, for example. Instead, electricity is generated according to the residential load 50. Thereby, the amount of hot water in the tank can be effectively increased so as to approach the specified value (80%) by the specified value reaching deadline time. That is, it is possible to suppress the occurrence of running out of hot water in response to the demand for hot water supply.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above configuration, and various changes can be made within the scope of the invention described in the claims.

For example, in the present embodiment, the power supply system 1 is installed in a house, but the power supply system 1 is not limited to this, and may be installed in any place or building such as a factory, an apartment, a hospital, etc.

Furthermore, although the fuel cell 30 is provided in the middle of the power distribution line 10, the present invention is not limited thereto. For example, it may be connected to the residential load 50 through a distribution line different from the distribution line 10. However, in that case as well, the second sensor 31 needs to be provided on the downstream side of the power storage system 20 in the power distribution line 10.

1 Power supply system 30 Fuel cell 40 Control unit 50 Residential load S System power supply

Claims (6)

A fuel cell that can generate power using fuel and can supply generated power to a load connected to a grid power source;
a control unit that controls the operation of the fuel cell;
an electricity storage system having a storage battery that can be charged and discharged according to the power demand of the load after the power generated by the fuel cell is supplied;
Equipped with
The fuel cell includes:
It is possible to set the power generation upper limit value, which is the upper limit value that can be generated.
If it is possible to generate power within the range up to the power generation upper limit according to the power demand of the load,
The control unit includes:
If you are purchasing more electricity than the specified amount from the grid power supply,
The power generation upper limit value of the fuel cell can be updated based on a comparison between the power generation cost of the fuel cell and the power purchase cost from a grid power source,
The electricity storage system includes:
A power generation unit capable of generating power using natural energy and charging the generated power to the storage battery,
The fuel cell includes:
It has a hot water storage tank, and stores hot water produced using heat generated during power generation in the hot water storage tank,
The control unit includes:
There is power generated by the power generation section that is sold to the grid power source,
and when the power generated by the power generation unit sold to the grid power source is larger than the power generated by the fuel cell,
And if it is determined that a predetermined amount of hot water can be stored by a predetermined time by the power generation of the fuel cell,
changing the fuel cell from a state capable of generating electricity to a standby state;
Power supply system. The control unit includes:
If it is determined that the predetermined amount of hot water cannot be stored by the predetermined time due to the power generation of the fuel cell,
changing the fuel cell from a standby state to a state capable of generating electricity;
The power supply system according to claim 1. The control unit includes:
When the power generation cost of the fuel cell is lower than the power purchase cost of the grid power source,
Updating the power generation upper limit value within a range up to the power generation capacity that is the maximum value that the fuel cell can generate;
The power supply system according to claim 1 or claim 2. The control unit includes:
When the power generation cost of the fuel cell is more than the power purchase cost of the grid power source,
updating the power generation upper limit value to lower the power generation lower limit value when the fuel cell generates electricity;
The power supply system according to any one of claims 1 to 3. The control unit includes:
Electric power equal to or less than the predetermined amount is supplied to the load from the grid power supply,
and the storage battery is in a discharged state,
and the power generation cost of the fuel cell is lower than the power purchase cost of the grid power source,
and when the discharge power of the storage battery is smaller than a lower discharge limit value that is a lower limit value that can be efficiently discharged,
updating the power generation upper limit value to lower it within a range up to the power generation lower limit value;
The power supply system according to claim 4. The control unit includes:
Purchase electricity below the predetermined amount from the grid power supply,
and the storage battery is not in a discharged state,
and when the storage battery has a remaining charge to the extent that it can be discharged,
updating the power generation upper limit value to become the power generation lower limit value;
The power supply system according to claim 4 or claim 5 .

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