JP7437213B2 - 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.

Here, fuel cells have a maximum continuous power generation (operation) time (upper limit of continuous power generation time) determined for reasons such as device characteristics and safety, and it is necessary to stop power generation after continuous operation for a certain period of time. There is. For this reason, for example, if the weather is rainy on the day when the fuel cell power generation is to be stopped, the power generated by the solar power generation alone will not be able to meet the power demand by the amount of power generated by the fuel cell, and as a result, the purchased power will increase. There was a problem with this.

Japanese Patent Application Publication No. 2016-48992

The present invention has been made in view of the above circumstances, and an object thereof is to provide a power supply system that can suppress an increase in purchased power due to stopping power generation of a fuel cell. It is.

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 power generation unit capable of generating power using natural energy, a fuel cell capable of generating power using fuel and storing heat generated during power generation, and controlling the operation of the fuel cell. A control section, wherein the fuel cell has a maximum continuous power generation time that is an upper limit of continuous power generation time, and the control section is configured to adjust the amount of power generated by the power generation section to meet the power demand. Excess surplus power is predicted, and the day when the continuous power generation time of the fuel cell does not exceed the maximum continuous power generation time and the surplus power is predicted to be generated is set as the power generation stop date when the fuel cell is stopped. This is what you set.

In claim 2, the control unit sets the continuous power generation time of the fuel cell not to exceed the maximum continuous power generation time and the latest day of the days on which the surplus power is predicted to be generated. This is set as the stop date.

In a third aspect of the present invention, the control unit sets a power generation stop time during which the fuel cell is stopped during a time period during which the surplus power is expected to be generated on the power generation stop date.

In claim 4, the storage battery is provided with a storage battery capable of charging and discharging electric power, and when it is predicted that the storage battery cannot be fully charged with the amount of surplus electricity that is the sum of the surplus electricity on the day when the power generation is stopped, the control unit , the storage battery is charged using late-night electricity before the power generation stop time.

According to a fifth aspect of the present invention, the control unit includes a storage battery capable of charging and discharging electric power, and the control unit controls the surplus electric power to be the power consumption at the time of activation of the fuel cell at the scheduled power generation restart time set after the power generation stop time. or when the sum of the surplus power and the dischargeable power of the storage battery is greater than the power consumption at the time of startup of the fuel cell, instructing the fuel cell to generate power at the scheduled time to restart power generation. It is.

In claim 6, the control unit includes a storage battery capable of charging and discharging power, and the control unit calculates the sum of the surplus power and the dischargeable power of the storage battery at a scheduled power generation restart time that is set after the power generation stop time. If the power consumption is less than the power consumption of the fuel cell at startup, the fuel cell is instructed to generate power during a late night time period after the scheduled power generation restart time.

In claim 7, the control unit includes a storage battery capable of charging and discharging power, and the control unit is configured such that, at the scheduled power generation restart time, the sum of the surplus power and the dischargeable power of the storage battery is equal to the time when the fuel cell is activated. Even if it is less than the power consumption, if the heat stored in the fuel cell has not reached its maximum capacity, the fuel cell is instructed to generate power at the scheduled time to restart power generation.

The present invention has the following effects.

In the first aspect, it is possible to suppress an increase in purchased power due to stopping power generation of the fuel cell.

In claim 2, it is possible to effectively utilize the fuel cell.

In claim 3, it is possible to further suppress an increase in purchased power due to stopping the fuel cell.

In claim 4, the cost required for charging the storage battery can be reduced.

In claim 5, power consumption during startup of the fuel cell can be covered by surplus power and discharged power.

In claim 6, the cost of electric power required for starting the fuel cell can be reduced.

In claim 7, heat can be ensured.

1 is a block diagram showing the configuration of a power supply system according to an embodiment of the present invention. The flowchart which showed the operation plan control of a fuel cell and a storage battery. The flowchart which showed the operation plan control of a fuel cell and a storage battery. The flowchart which showed the operation plan control of a fuel cell and a storage battery. (a) A diagram showing power demand, PV generated power, etc. before the power generation stop time is corrected. (b) A diagram showing power demand, PV generated power, etc. after correction of power generation stop time. (c) A diagram showing discharge power, charging power, etc. of the storage battery after execution of operation plan control.

Hereinafter, a power supply system 1 according to an embodiment of the present invention will be described using FIG. 1. Note that in this specification, "upstream side" and "downstream side" are based on the direction of power supply from system power supply K.

The power supply system 1 shown in FIG. 1 supplies power from a system power supply K and generated power to a load H. The power supply system 1 is installed in a house, and supplies power to a load H of the house (for example, house equipment, etc.). The power supply system 1 mainly includes a power storage system 10, a distribution board 20, a fuel cell 30, a first sensor 40, a second sensor 50, and an EMS 60.

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

The solar power generation unit 11 is a device that generates power using sunlight. The solar power generation unit 11 is composed of a solar battery panel and the like. The solar power generation unit 11 is installed in a sunny place, such as on the roof of a house, for example.

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

The hybrid power conditioner 13 is a device (hybrid power conditioner) that converts electric power as appropriate. The hybrid power conditioner 13 can output the electric power generated by the solar power generation unit 11 and the electric power discharged from the storage battery 12 to the distribution line L (load H), and can also output the electric power flowing through the distribution line L (from the grid power supply K). It is configured to be able to output electric power and electric power generated by a fuel cell 30 (described later) to the storage battery 12. Further, the hybrid power conditioner 13 is configured to be able to acquire information regarding the performance and operating status of the solar power generation unit 11 and the storage battery 12. The hybrid power conditioner 13 is connected to a midway portion (connection point P) of a power distribution line L that connects a system power supply K and a load H (distribution board 20) via an electric line A1. The hybrid power conditioner 13 of the power storage system 10 can perform a load following operation in which the electric power to be discharged (output) is adjusted based on the detection result of the first sensor 40, which will be described later.

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

The fuel cell 30 is a device that generates power using gaseous fuel such as hydrogen. The fuel cell 30 includes a power generation unit 31 and a hot water storage tank 32.

The power generation unit 31 is a power generation section of the fuel cell 30. The power generation unit 31 includes a polymer electrolyte fuel cell (PEFC) or a solid oxide fuel cell (SOFC), a control unit, and the like. The power generation unit 31 performs load following operation according to the amount of power (total power consumption of the residential load H) detected by the second sensor 50, which will be described later. Furthermore, the fuel cell 30 has a learning function that learns information regarding the power consumption and hot water demand of the residential load H. In this way, the fuel cell 30 can create a power generation plan based on the information learned by the learning function. Furthermore, the fuel cell 30 can generate power according to the generated power generation plan in response to instructions from the EMS 60, which will be described later.

The hot water storage tank 32 stores heat (exhaust heat) generated during power generation by the power generation unit 31 as hot water. The hot water storage tank 32 stores hot water (hot water) heated by heat (exhaust heat) generated during power generation by the power generation unit 31 .

The fuel cell 30 configured in this manner stops power generation by the power generation unit 31 when the amount of hot water stored in the hot water storage tank 32 reaches its maximum capacity (when the hot water storage tank 32 is full and cannot store heat any more). There may be cases where Further, the fuel cell 30 starts generating electricity so that the amount of hot water stored in the hot water storage tank 32 reaches its maximum capacity by the time period when the demand for hot water supply occurs.

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

The second sensor 50 is provided in the middle of the power distribution line L. More specifically, the second sensor 50 is provided between the power storage system 10 (connection point P) and the electricity distribution board 20. The second sensor 50 detects the voltage (supply voltage) and current (supply current) of power (power flowing upstream and power flowing downstream) flowing through the location where the second sensor 50 is provided.

The EMS 60 is an energy management system that manages the operation of the power supply system 1. The EMS 60 includes an arithmetic processing unit such as a CPU, a storage unit such as a RAM or ROM, an input/output unit such as a touch panel, and the like. The storage unit of the EMS 60 stores in advance various information, programs, etc. used when controlling the operation of the power supply system 1. The arithmetic processing unit of the EMS 60 can operate the power supply system 1 by executing the program and performing predetermined arithmetic processing using the various pieces of information.

EMS 60 is electrically connected to hybrid power conditioner 13. The EMS 60 can transmit a predetermined signal to the hybrid power conditioner 13 and control the operation of the storage battery 12 (for example, charging and discharging the storage battery 12, etc.). Further, the EMS 60 is configured to be able to receive a predetermined signal from the hybrid power conditioner 13, and can acquire various information (such as the remaining amount of power stored in the storage battery 12).

Further, the EMS 60 is electrically connected to the fuel cell 30 and can control the operation of the fuel cell 30.

In the power supply system 1 configured as described above, the storage battery 12 can be charged with power purchased from the grid power supply K or power generated by the solar power generation section 11 and the fuel cell 30. In addition, in the power supply system 1, the power purchased from the grid power supply K, the power generated by the solar power generation unit 11 and the fuel cell 30, and the power charged in the storage battery 12 are supplied to the residential load H. can do. Further, in the power supply system 1, the surplus power (surplus power) generated by the solar power generation unit 11 can be reversely flowed to the grid power supply K and sold.

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

The power supply system 1 has a first mode and a second mode as power supply modes. In the first mode shown below, the storage battery 12 is charged and discharged based on the detection results of the first sensor 40 and the second sensor 50. Further, in the second mode shown below, the storage battery 12 is charged and discharged based on instructions from the EMS 60.

The hybrid power conditioner 13 set to the first mode supplies power from the solar power generation unit 11 to the load H when the solar power generation unit 11 is generating power. Further, when the power from the solar power generation unit 11 is surplus to the power consumption of the load H, the hybrid power conditioner 13 charges the storage battery 12 with the surplus power. If there is still surplus power from the solar power generation unit 11 even after charging the storage battery 12 with the maximum charging power (the maximum amount of power that the storage battery 12 can charge per unit time), the hybrid power conditioner 13 uses the surplus power. is caused to flow backward to the grid power supply S.

In supplying power to the load H, the hybrid power conditioner 13 performs a load following operation in which the amount of discharge of the storage battery 12 is determined based on the detection result of the first sensor 40.

On the other hand, the hybrid power conditioner 13 set to the second mode charges and discharges the storage battery 12 based on instructions from the EMS 60. The hybrid power conditioner 13 set to the second mode can charge the storage battery 12 with, for example, power from the system power supply S (late night power) based on instructions from the EMS 60.

Here, the maximum continuous power generation time, which is the upper limit of the continuous power generation time, is determined for the above-mentioned fuel cell 30 in consideration of safety aspects such as the characteristics of the equipment and the safety of gas fuel, and if the fuel cell 30 is operated continuously for a certain period of time, the maximum continuous power generation time is determined. , it is necessary to temporarily stop power generation. Normally, the date on which power generation of the fuel cell 30 is to be stopped (power generation stop date) is set in advance in consideration of this maximum continuous power generation time (so that the continuous power generation time does not exceed the maximum continuous power generation time). Hereinafter, for convenience of explanation, the power generation stop date of the fuel cell 30 that is scheduled (set) in consideration of the maximum continuous power generation time will be referred to as the "scheduled power generation stop date." On the other hand, although the details will be described later, the corrected (reset) power generation stop date will be simply referred to as the "power generation stop date."

On the other hand, if surplus power from the solar power generation unit 11 cannot be expected on the scheduled power generation stop date due to bad weather or other reasons, on the scheduled power generation stop date, the system There is a possibility that the amount of power purchased from the power source K will increase. An increase in the amount of power purchased from the grid power supply K may be economically unfavorable.

Therefore, in the power supply system 1 according to the present embodiment, operation plan control of the storage battery and fuel cell shown in FIGS. 2 to 4 is executed. This operation plan control advances the power generation stop date from the scheduled power generation stop date as necessary (corrects (resets) the power generation stop date), and also controls the operation (operation) of fuel cells and storage batteries on the revised power generation stop date. This is to plan.

Hereinafter, operation plan control for fuel cells and storage batteries will be specifically explained using FIGS. 2 to 4.

Note that the fuel cell and storage battery operation plan control shown in FIGS. 2 to 4 is started before the scheduled power generation stop date (for example, one week before the power generation stop date). Further, in this embodiment, it is assumed that the scheduled power generation stop date is the 27th day from the previous power generation stop date. Furthermore, if the power generation stop date is not brought forward (corrected), the operation plan control of the fuel cell and storage battery is executed again on the next day.

In step S10 shown in FIG. 2, the EMS 60 acquires information such as a weather forecast. In this process, the EMS 60 uses any method to acquire information (weather forecast, etc.) for making predictions in step S11, which will be described later. The weather forecast is a weather forecast from the current next day (hereinafter simply referred to as "the next day") to the scheduled power generation stop date. In addition to the weather forecast, the information can also include data on past power generation by the solar power generation unit 11 and fuel cell 30, data on past purchased power, and the like. After performing the process in step S10, the EMS 60 moves to step S11.

In step S11 shown in FIG. 2, the EMS 60 predicts power demand, PV generated power, surplus power, and purchased power. In this process, the EMS 60 performs the prediction based on information such as the weather forecast acquired in step S10. The EMS 60 predicts the power demand, etc. from the next day until the scheduled power generation stop date, assuming that the fuel cell 30 will not generate any power from the next day until the power generation scheduled stop date.

Here, "PV generated power" indicates the power generated by the solar power generation unit 11. Moreover, "surplus power" indicates the surplus amount of power generated by the solar power generation unit 11 and the fuel cell 30 with respect to the power demand. Note that since it is assumed that the fuel cell 30 does not generate any power, the "surplus power" predicted in step S11 is the surplus of the PV generated power relative to the power demand. After performing the process in step S11, the EMS 60 moves to step S12.

In step S12 shown in FIG. 2, the EMS 60 calculates the final surplus day. Here, the "last surplus day" indicates the last day on which surplus power is generated among the days from the next day to the scheduled power generation stop date (the 27th day from the previous power generation stop date). If it is predicted that no surplus power will be generated on the 25th, 26th, and 27th day from the previous power generation stop date, the last surplus power will be the 24th day from the previous power generation stop date. In this process, the EMS 60 calculates the final surplus day based on the prediction result in step S11.

In addition, in step S12, the EMS 60 determines a day in which surplus power amount>α is a "day when surplus power is generated." Here, the "surplus power amount" indicates the total amount of surplus power for one day. Further, α is an arbitrary threshold value of 0 or more. Further, by setting α to a value larger than 0, it is possible to suppress an increase in purchased power even if the prediction in step S11 is slightly off. After performing the process in step S12, the EMS 60 moves to step S13.

In step S13 shown in FIG. 2, the EMS 60 determines whether the next day is the last surplus day or the scheduled power generation stop date. When the EMS 60 determines that the next day is the final surplus day or the scheduled power generation stop date ("YES" in step S13), the process proceeds to step S14. On the other hand, if the EMS 60 determines that the next day is not the final surplus day or the scheduled power generation stop date ("NO" in step S13), the process proceeds to step S28 shown in FIG. 4.

In step S14 shown in FIG. 2, the EMS 60 sets a power generation stop time. Here, the "power generation stop time" indicates the time during which power generation (operation) of the fuel cell 30 is stopped. In this process, the EMS 60 sets the power generation stop time to the surplus generation time of the next day (last surplus day or scheduled power generation stop date). Here, the "surplus generation time" indicates a time period in which surplus power is generated. The EMS 60 sets the power generation stop time so that the power generation stop of the fuel cell 30 starts at the next day's surplus start time (the time when surplus power starts to be generated, for example, 9 o'clock). For example, the power generation stop time is set from 9:00 to 12:00 the next day.

Note that if the next day is the scheduled power generation stop date and there is no surplus generation time, the power generation stop time can be set to any time period.For example, the power generation stop time can be set to the time period immediately after the maximum continuous power generation time. I can do it. Further, when the length of the surplus generation time is shorter than the length of the power generation stop time, the power generation stop time can be set to include the entire surplus generation time. After performing the process in step S14, the EMS 60 moves to step S15.

In step S15 shown in FIG. 2, the EMS 60 updates the prediction of surplus power and purchased power. In this process, the EMS 60 updates the prediction of surplus power and purchased power among the predictions of power demand, PV generated power, surplus power, and purchased power obtained in step S11. Specifically, the EMS 60 determines whether the fuel cell 30 does not generate power during the power generation stop time set in step S14 (for example, from 9 o'clock to 12 noon) and the time period until the start of power generation stop (i.e., surplus start time). The update is performed on the assumption that the fuel cell 30 generates power from 0 to 9 o'clock (for example, from 0 to 9 o'clock). After performing the process in step S15, the EMS 60 moves to step S16.

In step S16 shown in FIG. 2, the EMS 60 determines whether there is a late-night power unit price (set). In this process, the EMS 60 determines that there is a late-night power unit price if the late-night power unit price (power unit price in the late-night time period) is set to be cheaper than the power unit price in other time periods. On the other hand, the EMS 60 determines that there is no late-night power unit price if the late-night power unit price is not set lower than the power unit price in other time zones. If the EMS 60 determines that there is a late-night power unit price ("YES" in step S16), the process proceeds to step S17. On the other hand, when the EMS 60 determines that there is no late-night power unit price ("NO" in step S16), the process proceeds to step S20.

In step S17 shown in FIG. 2, the EMS 60 determines that surplus power amount<storage capacity−remaining power storage amount (the next day's surplus power amount is the value obtained by subtracting (the predicted value of) the remaining power storage amount at the surplus start time from the power storage capacity. ). Furthermore, the term “storage capacity” indicates the maximum capacity that can be stored in the storage battery 12. Furthermore, the “remaining amount of power storage” indicates the amount of power stored (remaining) in the storage battery 12. When the EMS 60 determines that the surplus power amount<the storage capacity - the remaining amount of storage power ("YES" in step S17), the process proceeds to step S18. On the other hand, when the EMS 60 determines that the surplus power amount<the storage capacity - the remaining amount of storage power ("NO" in step S17), the process proceeds to step S20.

Note that the case of "YES" in step S17 indicates that the storage battery 12 cannot be fully charged with the surplus power of the next day. On the other hand, the case of "NO" in step S17 indicates that the storage battery 12 can be fully charged with the next day's surplus power.

In step S18 shown in FIG. 2, the EMS 60 fully charges the storage battery 12 during the late night time period (the time period in which the late night power unit price is set). In this process, the EMS 60 sets the hybrid power conditioner 13 to the second mode during the late night time period before the power generation stop time set in step S14, and fully charges the storage battery 12 using the late night power from the grid power supply K. do. After performing the process in step S18, the EMS 60 moves to step S19.

In step S19 shown in FIG. 2, the EMS 60 sets the storage battery 12 (hybrid power conditioner 13) to the first mode at the midnight end time. Here, the "midnight end time" indicates the time when the late night time zone (the time zone in which the late night power unit price is set) ends. After performing the process in step S18, the EMS 60 moves to step S19.

In step S20 shown in FIG. 2, the EMS 60 issues a power generation request instruction until the surplus start time. In this process, the EMS 60 instructs the fuel cell 30 to request power generation during the time (for example, from 0 to 9 o'clock) until the next day's surplus start time. Here, the "power generation request instruction" is an instruction from the EMS 60 to the fuel cell 30 regarding the power generation time. The fuel cell 30 that has received the power generation request instruction will generate power if a predetermined condition is satisfied during the instructed power generation time. In other words, the fuel cell 30 does not necessarily generate power even if it receives a power generation request instruction; for example, if the amount of hot water stored in the hot water storage tank 32 has reached its maximum capacity (if the hot water storage tank 32 is full), it will not necessarily generate power. Not performed. After performing the process in step S20, the EMS 60 moves to step S21.

In step S21 shown in FIG. 2, the EMS 60 issues a power generation stop instruction at the surplus start time. In this process, the EMS 60 issues a power generation stop instruction (instruction to stop power generation) to the fuel cell 30 at the next day's surplus start time (for example, 9 o'clock). The fuel cell 30 that receives the power generation stop instruction stops power generation. After performing the process in step S21, the EMS 60 moves to step S22.

In step S22 shown in FIG. 3, the EMS 60 determines whether surplus power>β (surplus power is greater than β) at the scheduled power generation restart time. Here, the "scheduled power generation restart time" indicates the time at which the fuel cell 30 will restart power generation after it has stopped generating power in response to a power generation stop instruction. Further, β indicates the power (for example, 500 W) consumed when starting up the fuel cell 30 (required for starting up). If the EMS 60 determines that surplus power>β at the scheduled power generation restart time (“YES” in step S22), the process proceeds to step S26. On the other hand, if the EMS 60 determines that the surplus power is not >β at the scheduled power generation restart time (“NO” in step S22), the process proceeds to step S23.

Note that the case of "YES" in step S22 indicates that the power β consumed at the time of starting the fuel cell 30 can be covered by the surplus power. On the other hand, the case of "NO" in step S22 indicates that the power β consumed when starting the fuel cell 30 cannot be covered by the surplus power.

In step S23 shown in FIG. 3, the EMS 60 determines that the dischargeable power + surplus power - purchased power > β at the scheduled time to restart power generation (the value obtained by subtracting the purchased power from the sum of the dischargeable power and surplus power of the storage battery 12 , is larger than the electric power β consumed at the time of starting the fuel cell 30). Here, "dischargeable power" indicates the maximum power that can be discharged from the storage battery 12. If the EMS 60 determines that dischargeable power + surplus power - purchased power>β ("YES" in step S23), the process proceeds to step S26. On the other hand, if the EMS 60 determines that dischargeable power + surplus power - purchased power>β ("NO" in step S23), the process proceeds to step S24.

Note that the case of "YES" in step S23 indicates that the power β consumed when starting the fuel cell 30 can be covered by the power discharged from the storage battery 12 (the power stored in the storage battery 12) and the surplus power. ing. On the other hand, if "NO" in step S23, it means that the power β consumed when starting the fuel cell 30 cannot be covered by the power discharged from the storage battery 12 (the power stored in the storage battery 12) and the surplus power. It shows.

In step S24 shown in FIG. 3, the EMS 60 determines whether there is a late-night power unit price (set). In this process, the EMS 60 determines that there is a late-night power unit price if the power unit price in the late-night time period is set to be cheaper than the power unit price in other time periods. On the other hand, the EMS 60 determines that there is no late-night power unit price if the power unit price in the late-night time period is not set to be cheaper than the power unit price in other time periods. When the EMS 60 determines that there is a late-night power unit price ("YES" in step S24), the process proceeds to step S25. On the other hand, when the EMS 60 determines that there is no late-night power unit price ("NO" in step S24), the process proceeds to step S26.

In step S25 shown in FIG. 3, the EMS 60 determines whether the hot water storage tank 32 of the fuel cell 30 is full (the amount of hot water stored in the hot water tank 32 has reached its maximum capacity). When the EMS 60 determines that the hot water storage tank 32 is full ("YES" in step S25), the process proceeds to step S27. On the other hand, if the EMS 60 determines that the hot water storage tank 32 is not full ("YES" in step S25), the process proceeds to step S26.

In step S26 shown in FIG. 3, the EMS 60 instructs the fuel cell 30 to generate power at the scheduled time to restart power generation. The fuel cell 30 that has received the power generation instruction restarts power generation at the scheduled power generation restart time. After performing the process of step S26, the EMS 60 ends the operation plan control.

On the other hand, in step S27 shown in FIG. 3, the EMS 60 instructs the fuel cell 30 to generate power at the midnight start time. The fuel cell 30 that has received the power generation instruction restarts power generation at midnight start time. Here, the "late night start time" indicates the time when the late night time zone (that is, the time zone in which the late night power unit price is set) starts, and is, for example, 23:00. In this process, the EMS 60 does not restart the power generation of the fuel cell 30 at the scheduled power generation restart time, and at the first midnight start time (23:00 on that day) after the power generation stop time set in step S14, the EMS 60 issues the power generation instruction. I do. After performing the process of step S27, the EMS 60 ends the operation plan control.

On the other hand, as described above, if NO in step S13 shown in FIG. 2, the process moves to step S28 shown in FIG. When the process moves to step S28 shown in FIG. 4, the power generation stop date is not corrected. Note that the operation plan control shown in FIGS. 2 to 4 is executed before the scheduled power generation stop date (for example, one week before the power generation stop date), but on other days, the steps shown in FIG. Processes from S28 to S34 are performed.

In step S28 shown in FIG. 4, the EMS 60 updates the prediction of surplus power and purchased power. In this process, the EMS 60 updates the prediction of surplus power and purchased power among the predictions of power demand, PV generated power, surplus power, and purchased power obtained in step S11. Specifically, the EMS 60 performs the update on the assumption that the fuel cell 30 will generate power the next day. After performing the process in step S28, the EMS 60 moves to step S29.

In step S29 shown in FIG. 4, the EMS 60 determines whether surplus power<power storage capacity−remaining power storage amount (the next day's surplus power amount is less than the value obtained by subtracting the remaining power storage amount at the surplus start time from the power storage capacity). Determine whether or not. When the EMS 60 determines that the surplus power amount<the storage capacity - the remaining amount of storage power ("YES" in step S29), the process proceeds to step S30. On the other hand, when the EMS 60 determines that the surplus electric energy is not less than the storage capacity - the remaining amount of storage ("NO" in step S29), the process proceeds to step S34.

In step S30 shown in FIG. 4, the EMS 60 determines whether there is a late-night power unit price (set). When the EMS 60 determines that there is a late-night power unit price ("YES" in step S30), the process proceeds to step S31. On the other hand, when the EMS 60 determines that there is no late-night power unit price ("NO" in step S30), the process proceeds to step S33.

In step S31 shown in FIG. 4, the EMS 60 fully charges the storage battery 12 during the late night time period (the time period in which the late night power unit price is set). In this process, the EMS 60 sets the hybrid power conditioner 13 to the second mode during the most recent late-night time period, and fully charges the storage battery 12 using late-night power from the system power supply K. After performing the process in step S31, the EMS 60 moves to step S32.

In step S32 shown in FIG. 4, the EMS 60 sets the storage battery 12 (hybrid power conditioner 13) to the first mode at the midnight end time. After performing the process in step S32, the EMS 60 moves to step S33.

In step S33 shown in FIG. 4, the EMS 60 does not instruct the fuel cell 30 to request power generation. In this case, the fuel cell 30 will continue generating electricity without stopping. The EMS 60 ends the operation plan control after performing the process of step S33.

On the other hand, in step S34 shown in FIG. 4, the EMS 60 instructs the fuel cell 30 to request power generation at times other than the surplus generation time. In this case, the fuel cell 30 will generate power during periods other than the surplus generation time. After performing the process of step S34, the EMS 60 ends the operation plan control.

A specific example of setting the power generation stop time of the fuel cell 30 will be shown below. In the example shown in FIG. 5, it is assumed that the maximum generated power of the fuel cell 30 is 700W.

FIG. 5A is a diagram showing (predictions of) the power demand, PV generated power, etc. predicted in step S11 (before the power generation stop time is corrected). Here, it is assumed that the fuel cell 30 does not generate electricity. In this example, the d day from the previous power generation stop date is the scheduled power generation stop date, and the power generation stop time is scheduled to start at 10 o'clock on the d day (the scheduled power generation stop date). In this example, no surplus power is generated on day d (scheduled power generation stop date).

FIG. 5(b) is a diagram showing (predictions of) the power demand, PV generated power, etc. (after correction of the power generation stop time) set in step S14. As mentioned above, since no surplus power is generated on day d (scheduled power generation stop date), the power generation stop date is set on the day before surplus power is generated ((d-1) day from the previous power generation stop date). It's brought forward. Furthermore, since surplus power has been generated since 10 o'clock on the (d-1) day, the power generation stop time starts at 10 o'clock on the (d-1) day. By doing so, even if the power generation of the fuel cell 30 is stopped, the power demand can be covered by the PV generated power, thereby suppressing the generation of purchased power during the power generation stop time.

FIG. 5C is a diagram showing (predictions of) power demand, PV generated power, etc. after execution of operation plan control. In the example shown in FIG. 5C, since the storage battery 12 is not fully charged due to surplus power, the storage battery 12 is fully charged using late-night power. Further, since the hot water storage tank 32 is full, the restart of the fuel cell 30 is on standby until the midnight power time.

As described above, in the power supply system 1 according to the present embodiment, the scheduled power generation stop date (time) of the fuel cell 30 is set (advanced) to the day (time) when surplus power is predicted to be generated. Thereby, an increase in purchased power due to stopping the fuel cell 30 can be suppressed.

Furthermore, during the power generation stop time, the power generation of the fuel cell 30 is stopped, so that the PV generated power consumed for electric power demand increases. For this reason, there is a possibility that the PV generated power cannot be used to charge the storage battery 12. Therefore, if it is predicted that the storage battery 12 cannot be fully charged with surplus power during the power generation stop time (YES in S17 shown in FIG. 2), by charging the storage battery 12 with late-night power in advance, the storage battery 12 can be charged. While reducing such costs, it is possible to utilize the electric power stored in the storage battery 12 after the power generation stop time.

Further, at the scheduled time to restart power generation, if the power consumption (β) at the time of startup of the fuel cell 30 can be covered by the surplus power (and the dischargeable power of the storage battery 12) (YES in S22 or S23 shown in FIG. 3), the fuel cell 30 Since the power generation of the fuel cell 30 is restarted, it is possible to suppress the power purchased for the power consumption at the time of startup of the fuel cell 30. In addition, if the power consumption (β) at the time of startup of the fuel cell 30 cannot be covered by the surplus power and the dischargeable power of the storage battery 12 at the scheduled time to restart power generation (NO in S23 shown in FIG. 3), and the hot water storage tank 32 is If the tank is full (YES in S25 shown in FIG. 3), the power generation of the fuel cell 30 is not restarted at the scheduled power generation restart time, but the power generation of the fuel cell 30 is restarted until midnight (midnight start time). In order to restart the fuel cell 30, the electricity required to start up the fuel cell 30 can be covered by the low-priced late-night electricity, and the cost can be reduced. Furthermore, it is possible to prevent the heat produced by the fuel cell 30 from being ineffectively utilized.

As described above, the power supply system 1 according to the present embodiment includes a solar power generation unit 11 (power generation unit) that can generate electricity using natural energy, and a solar power generation unit 11 (power generation unit) that can generate electricity using fuel and heat generated during power generation. and an EMS 60 (control unit) that controls the operation of the fuel cell 30, and the fuel cell 30 has a maximum continuous power generation time that is the upper limit of the continuous power generation time, The EMS 60 predicts the surplus power that is surplus to the power demand among the power generated by the solar power generation unit 11, and the continuous power generation time of the fuel cell does not exceed the maximum continuous power generation time, and The day on which the surplus power is predicted to be generated is set as the power generation stop date for stopping the fuel cell 30 (steps S12 to S14 shown in FIG. 2).

With this configuration, it is possible to suppress an increase in purchased power due to stopping the power generation of the fuel cell 30.
Specifically, for example, even if the weather is rainy on the day when fuel cell power generation is scheduled to stop (scheduled power generation stop date) and surplus power cannot be expected, it is predicted that surplus power will be generated on the day when power generation is stopped. By bringing the power forward to the day when the power is purchased (that is, the day when it is expected that most of the power demand can be covered by the power generated by the solar power generation unit 11 (PV power generation)), it is possible to suppress an increase in the amount of purchased power.

Further, the EMS 60 sets the continuous power generation time of the fuel cell not to exceed the maximum continuous power generation time and the latest day (last surplus day) of the days on which the surplus power is predicted to be generated. This is set as the stop date (steps S12 to S14 shown in FIG. 2).

With this configuration, it is possible to effectively utilize the fuel cell 30 while suppressing an increase in purchased power.
Specifically, since the fuel cell 30 can be operated for a time close to the maximum continuous power generation time, it is possible to suppress a decrease in the electric power generated by the fuel cell 30.

Further, the EMS 60 sets a power generation stop time for stopping the fuel cell in a time period during which the surplus power is expected to be generated on the power generation stop date (step S14 shown in FIG. 2).

With this configuration, it is possible to further suppress an increase in purchased power due to stopping the fuel cell 30.
Specifically, since the power demand can be covered by the power generated by the solar power generation unit 11 during the power generation stop time, it is possible to further suppress an increase in purchased power due to stopping the fuel cell 30.
Further, the fuel cell 30 may not be able to generate electricity when the hot water storage tank 32 is full. Therefore, if the fuel cell 30 is operated to generate electricity during a time period when surplus power is generated (surplus generation time period), the hot water storage tank 32 will quickly become full, and the fuel cell 30 will be activated during a time period when surplus power is not generated. Even if you try to generate electricity, it may not be possible. In the power supply system 1 according to the present embodiment, the power generation of the fuel cell 30 is stopped during the time period when surplus power is generated (surplus generation time period), thereby preventing the hot water storage tank 32 from filling up early. In addition, it is possible to prevent the fuel cell 30 from being unable to generate electricity during a time period when surplus power is not generated.

Further, the power supply system 1 according to the present embodiment includes a storage battery 12 capable of charging and discharging power, and the EMS 60 is configured to operate when it is predicted that the storage battery 12 cannot be fully charged with the surplus power during the power generation stop time. (YES in step S17 shown in FIG. 2), the storage battery 12 is charged using late-night power before the power generation stop time (step S18 shown in FIG. 2).

With this configuration, the cost required for charging the storage battery 12 can be reduced.
Specifically, by charging the storage battery 12 with late-night power in advance, the power stored in the storage battery 12 can be used after the power generation has stopped, and the cost of charging the storage battery 12 can be reduced. can.

Further, the power supply system 1 according to the present embodiment includes a storage battery 12 capable of charging and discharging power, and the EMS 60 is configured such that the surplus power is transferred to the fuel cell at the scheduled power generation restart time set after the power generation stop time. 30 (YES in step S22 shown in FIG. 3), or the sum of the surplus power and the dischargeable power of the storage battery 12 is greater than the power consumption β at the time of startup of the fuel cell. If there are many (YES in step S23 shown in FIG. 3), the fuel cell 30 is instructed to generate power at the scheduled power generation restart time (step S26 shown in FIG. 3).

With this configuration, the power consumption during startup of the fuel cell 30 can be covered by surplus power and discharged power.
Specifically, the power consumption during startup of the fuel cell 30 can be covered by the surplus power and the discharged power of the storage battery 12, so it is possible to reduce costs.

Further, the power supply system 1 according to the present embodiment includes a storage battery 12 capable of charging and discharging power, and the EMS 60 uses the surplus power and the storage battery 12 at the scheduled power generation restart time set after the power generation stop time. If the sum of the dischargeable power and the power consumption β at the time of startup of the fuel cell 30 is less than the power consumption β at the time of startup of the fuel cell 30 (NO in step S23 shown in FIG. 3), the fuel cell 30 to generate power (step S27 shown in FIG. 3).

With this configuration, the cost of electric power required to start up the fuel cell 30 can be reduced.
Specifically, since the electricity required to start up the fuel cell 30 can be covered by late-night electricity, which has a low unit price, it is possible to reduce costs.

Furthermore, the power supply system 1 according to the present embodiment includes a storage battery 12 that can charge and discharge power, and the EMS 60 determines that at the scheduled power generation restart time, the sum of the surplus power and the dischargeable power of the storage battery 12 is Even if the power consumption β at the time of startup of the fuel cell 30 is lower (NO in step S23 shown in FIG. 3), the heat stored in the fuel cell 30 (hot water storage tank 32) has not reached its maximum capacity. If not, the power generation of the fuel cell 30 is restarted at the scheduled power generation restart time (step S26 shown in FIG. 3).

With this configuration, heat can be ensured.
Specifically, by restarting the power generation of the fuel cell 30 at the scheduled power generation restart time, it is possible to prevent the heat stored in the hot water storage tank 32 from running out.

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 an office or the like.

Further, in this embodiment, the power generation unit is the solar power generation unit 11 that generates power using sunlight, but it may generate power using other natural energy (for example, hydropower or wind power). It's okay.

In addition, in the present embodiment, in step S22 shown in FIG. 3, it is determined whether the surplus power is greater than the power β consumed when starting the fuel cell 30 at the scheduled power generation restart time (surplus power>β). However, it may be determined whether the surplus power is greater than or equal to β (surplus power≧β).

In addition, in the present embodiment, in step S23 shown in FIG. However, it is determined whether the subtracted value is greater than or equal to β (dischargeable power + surplus power - purchased power ≧ β). It may also be used to determine whether

In addition, in the present embodiment, in step S17 shown in FIG. 2 and step S29 shown in FIG. Although the predicted value of is used, the remaining power storage amount at the present time (the processing time of the step) may be regarded as the remaining power storage amount at the surplus start time.

In addition, in this embodiment, all the steps shown in FIGS. 2 to 4 are for planning the operation of the fuel cell 30 and the storage battery 12, but the processing from steps S18 to S26 and the steps S31 to S34 are The process may include operating the fuel cell 30 and the storage battery 12.

Note that when the fuel cell 30 generates power based on a plan based on operation plan control (that is, when generating power at a scheduled time), the fuel cell 30 generates power of a magnitude based on the load following operation. Alternatively, the amount of power may be generated according to a power generation plan created by the learning function.

1 Power supply system 11 Solar power generation section 12 Storage battery 30 Fuel cell 32 Hot water storage tank 60 EMS

Claims (7)

A power generation section that can generate electricity using natural energy,
A fuel cell that can generate electricity using fuel and stores the heat generated during electricity generation,
a control unit that controls the operation of the fuel cell;
Equipped with
The fuel cell has a maximum continuous power generation time that is the upper limit of the continuous power generation time,
The control unit includes:
Predicting the surplus power that is surplus to the power demand among the power generated by the power generation unit,
setting a day when the continuous power generation time of the fuel cell does not exceed the maximum continuous power generation time and when the surplus power is expected to be generated as a power generation stop date for stopping the fuel cell;
Power supply system. The control unit includes:
setting the latest day among the days when the continuous power generation time of the fuel cell does not exceed the maximum continuous power generation time and the surplus power is expected to be generated as the power generation stop date;
The power supply system according to claim 1. The control unit includes:
On the power generation stop date, setting a power generation stop time for stopping the fuel cell in a time period in which the surplus power is expected to be generated;
The power supply system according to claim 1 or claim 2. Equipped with a storage battery that can charge and discharge electricity,
The control unit includes:
If it is predicted that the storage battery cannot be fully charged with the amount of surplus power that is the sum of the surplus power on the power generation stop date, charging the storage battery using late-night power before the power generation stop time;
The power supply system according to claim 3. Equipped with a storage battery that can charge and discharge electricity,
The control unit includes:
At the scheduled power generation restart time set after the power generation stop time, if the surplus power is greater than the power consumption at startup of the fuel cell, or the sum of the surplus power and the dischargeable power of the storage battery is If the power consumption is greater than the power consumption at startup of the battery, instructing the fuel cell to generate power at the scheduled time to restart power generation;
The power supply system according to claim 3 or 4. Equipped with a storage battery that can charge and discharge electricity,
The control unit includes:
If the sum of the surplus power and the dischargeable power of the storage battery is less than the power consumption at startup of the fuel cell at the scheduled power generation restart time set after the power generation stop time, then the power generation restart time is set after the power generation stop time. instructing the fuel cell to generate power later during the late night hours;
The power supply system according to any one of claims 3 to 5. Equipped with a storage battery that can charge and discharge electricity,
The control unit includes:
At the scheduled power generation restart time, even if the sum of the surplus power and the dischargeable power of the storage battery is less than the power consumption at startup of the fuel cell, the heat stored in the fuel cell reaches its maximum capacity. If the power generation time has not been reached, instructing the fuel cell to generate power at the scheduled power generation restart time;
The power supply system according to claim 6.

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