JP6030158B2 - Power supply system and control method thereof - Google Patents

Description

  Embodiments described herein relate generally to a power supply system and a control method thereof.

  A renewable energy power generation device is a device that generates power using renewable energy (natural energy) such as sunlight and wind power. Renewable energy power generation devices are widely used to reduce carbon dioxide emissions.

  Renewable energy power generation devices have large fluctuations in power generation output. For this reason, in order to stabilize the power supply, the power generated by the renewable energy power generator is stored in a secondary battery. In addition, an electric power supply system that generates hydrogen using electric power generated using renewable energy and generates electric power with a fuel cell power generator using the generated hydrogen has been proposed.

"About hydrogen and fuel cells", [online], December 2013, General Energy Research Committee, [Searched on December 19, 2014], Internet <URL: http://www.meti.go.jp/ committee / kenkyukai / energy / suiso_nenryodenchi / pdf / 001_04_00.pdf>

  However, in the above power supply system, the hydrogen storage amount may become unstable due to the generation of hydrogen using the power generated using renewable energy. For this reason, when necessary, the hydrogen storage amount may not be sufficient, and thus the hydrogen supply may be insufficient. As a result, it may not be possible to generate power in the fuel cell power generator as necessary.

  A problem to be solved by the present invention is a power supply system capable of sufficiently supplying hydrogen when necessary, and capable of generating power in a fuel cell power generator as necessary, and its control Is to provide a method.

  The power supply system of the embodiment includes a hydrogen generation device, a hydrogen storage device, a fuel cell power generation device, and a control device, and supplies power to a load unit. The hydrogen generator generates hydrogen using electric power generated using renewable energy. The hydrogen storage device stores the hydrogen generated by the hydrogen generator. The fuel cell power generation device generates power using the hydrogen stored in the hydrogen storage device, and outputs the electric power generated by the power generation to the load unit. The control device controls the operation of the power supply system. Here, in the hydrogen storage mode, the control device controls the operation of the power supply system so that the amount of hydrogen stored in the hydrogen storage device reaches a target amount.

The block diagram which shows typically the whole structure of the electric power supply system which concerns on embodiment. The block diagram which shows the principal part of the member which comprises the electric power supply system which concerns on embodiment. The block diagram which shows the principal part of the member which comprises the electric power supply system which concerns on embodiment. The block diagram which shows the principal part of the member which comprises the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment. The figure which shows operation | movement of the electric power supply system which concerns on embodiment.

[A] Configuration of Power Supply System 1 FIG. 1 is a block diagram schematically showing the overall configuration of the power supply system 1 according to the embodiment. In FIG. 1, the solid line arrows indicate the flow of electric power, and the broken line arrows indicate the flow of hydrogen. Moreover, the dashed-dotted arrow has shown the flow of water, and the dashed-two dotted line has shown the flow of the signal.

  As shown in FIG. 1, the power supply system 1 of the embodiment includes a renewable energy power generation device 10, a hydrogen generation device 40, a hydrogen storage device 50, a fuel cell power generation device 60, and a control device 70.

  As will be described in detail later, the power supply system 1 is configured to supply power E10a and E60 to an external load unit 3 provided with electrical equipment. In addition, the power supply system 1 is configured to heat water and supply the heated water W60 (warm water, heat medium) to the load unit 3 provided with the hot water utilization device. In addition, the power supply system 1 is configured to output power E10c to the external power system 2.

  2, 3, and 4 are block diagrams illustrating main parts of members that constitute the power supply system 1 according to the embodiment. FIG. 2 shows a main part of the hydrogen generator 40. FIG. 3 shows a main part of the hydrogen storage device 50. FIG. 4 shows a main part of the fuel cell power generator 60.

  Each part which comprises the electric power supply system 1 is demonstrated sequentially using each figure.

[A-1] Renewable energy power generation device 10
In the power supply system 1, the renewable energy power generation device 10 is a device that generates power using renewable energy, and is configured to output electric power E10 as shown in FIG.

  Renewable energy power generation device 10 is, for example, a photovoltaic power generation (PV) device that includes a solar cell (not shown), receives sunlight with a solar cell, and performs photoelectric conversion in the solar cell, thereby generating power. I do.

  Although illustration is omitted, the electric power E10 output from the renewable energy power generation apparatus 10 is adjusted by, for example, a power conditioner apparatus (not shown). The electric power E10 output from the renewable energy power generation apparatus 10 is converted so that it can be used in the load unit 3 in the same manner as the electric power E2 supplied from the electric power system 2 (commercial power supply) in the power conditioner apparatus, for example. . Here, the DC power output from the renewable energy power generation apparatus 10 is adjusted by the converter to be within a predetermined voltage range, and the adjusted DC power is converted into AC power by the inverter.

  Electric power E10 generated by the renewable energy power generation apparatus 10 is output to at least one of the hydrogen generation apparatus 40, the power system 2, and the load unit 3. Here, the renewable energy power generation apparatus 10 outputs electric power E10a to the load unit 3 according to the control signal CTL70 output from the control apparatus 70, outputs electric power E10b to the hydrogen generator 40, and supplies electric power to the power system 2. E10c is output. Specifically, a switch (not shown) provided between the renewable energy power generation apparatus 10 and each unit is switched to an on state according to the control signal CTL 70, so that power is supplied from the renewable energy power generation apparatus 10 to each unit. E10a, E10b, and E10c are output.

[A-2] Hydrogen generator 40
In the power supply system 1, the hydrogen generator 40 is configured to generate and supply hydrogen H40 as shown in FIG.

  As shown in FIG. 2, the hydrogen generator 40 includes, for example, a pure water production apparatus 401 a and a water electrolysis apparatus 401, and water (pure water) from which impurities have been removed by the pure water production apparatus 401 a is used as the water electrolysis apparatus 401. To generate hydrogen H40. The water electrolysis apparatus 401 is, for example, a solid polymer (PEM) water electrolysis apparatus. In the present embodiment, the hydrogen generator 40 is supplied with water from the outside, and the water electrolysis device 401 applies a voltage to the supplied water to decompose the water into hydrogen and oxygen.

  Hydrogen H40 generated in the water electrolysis apparatus 401 is supplied to the hydrogen storage apparatus 50 and stored. And the oxygen produced | generated in the water electrolysis apparatus 401 is discharge | released to air | atmosphere, for example.

  As shown in FIG. 1, the hydrogen generator 40 is configured to be supplied with electric power E <b> 10 b output from the renewable energy power generation apparatus 10 and supplied with electric power E <b> 2 a from the electric power system 2. The hydrogen generator 40 uses the electric power E10b output from the renewable energy power generation apparatus 10 and the electric power E2a supplied from the power system 2 to electrolyze water in the water electrolysis apparatus 401 (see FIG. 2). To generate hydrogen H40.

  As shown in FIG. 2, the hydrogen generator 40 includes a compressor 402 and a chiller unit 403 in addition to the water electrolysis device 401 and the like. The compressor 402 compresses air and supplies it to the water electrolysis apparatus 401, for example. And the chiller unit 403 supplies cooling water to the water electrolysis apparatus 401, for example.

  The hydrogen generator 40 includes measurement devices (not shown) such as a gas sensor, a pressure gauge, and a flow meter, and data D1 measured by the measurement device is output to the control device 70 as a data signal.

  The hydrogen generator 40 is individually packaged and can be transported. That is, as shown in FIG. 2, the hydrogen generator 40 is packaged by housing components (a water electrolysis apparatus 401, a compressor 402, a chiller unit 403, etc.) in a container 400, and a vehicle such as a trailer. It is a size that can be transported using.

[A-3] Hydrogen storage device 50
In the power supply system 1, the hydrogen storage device 50 is configured to store hydrogen H40 supplied from the hydrogen generation device 40, as shown in FIG. The hydrogen storage device 50 is configured to supply the hydrogen H50 to the fuel cell power generation device 60. In addition, the hydrogen storage device 50 is configured to supply hydrogen H50a to the fuel cell vehicle 4.

  As shown in FIG. 3, the hydrogen storage device 50 includes, for example, a hydrogen storage tank 501 and an electromagnetic valve 502, and hydrogen H40 is supplied from the hydrogen generation device 40 to the hydrogen storage tank 501 via the electromagnetic valve 502. The supplied hydrogen H40 is stored in the hydrogen storage tank 501.

  The hydrogen storage device 50 includes measurement devices (not shown) such as a gas sensor, a pressure gauge, and a flow meter, and data D1 measured by the measurement device is output to the control device 70 as a data signal.

  Similar to the hydrogen generator 40, the hydrogen storage device 50 is individually packaged and can be transported. That is, as shown in FIG. 3, the hydrogen storage device 50 is packaged by housing components (hydrogen storage tank 501, electromagnetic valve 502, etc.) in a container 500, and a vehicle such as a trailer is used. It is a size that can be transported.

[A-4] Fuel cell power generator 60
In the power supply system 1, the fuel cell power generation device 60 generates power using the hydrogen H 50 stored in the hydrogen storage device 50 and outputs the power E 60 generated by the power generation to the load unit 3 as shown in FIG. Is configured to do.

  As shown in FIG. 4, the fuel cell power generation device 60 includes a fuel cell 601, and power generation is performed using the hydrogen H 50 in the fuel cell 601. The fuel cell 601 is, for example, a polymer electrolyte fuel cell (PEFC). The fuel cell power generation device 60 includes an inverter 602 that converts the power generated by the fuel cell 601 into power that can be used by the load unit 3 in the same manner as the power supplied from the power system 2. To do.

  In addition to the above, as shown in FIG. 1, the fuel cell power generator 60 heats water (not shown) supplied from the outside using heat generated by power generation. Then, the fuel cell power generator 60 supplies the heated water W60 to the load unit 3 (hot water consumption destination). As shown in FIG. 4, the fuel cell power generation device 60 includes a hot water storage tank 603, and the heated water W <b> 60 is supplied to the load unit 3 after being stored in the hot water storage tank 603.

  The fuel cell power generator 60 includes measuring devices (not shown) such as a gas sensor, a pressure gauge, and a flow meter, and data D1 measured by the measuring device is output to the control device 70 as a data signal.

  Like the hydrogen generator 40 and the hydrogen storage device 50, the fuel cell power generator 60 is individually packaged and can be transported. That is, as shown in FIG. 4, the fuel cell power generator 60 is packaged by housing components (a fuel cell 601, an inverter 602, a hot water storage tank 603, etc.) in a container 600, and a vehicle such as a trailer. It is a size that can be transported using.

[A-5] Control device 70
In the power supply system 1, the control device 70 is configured to control each part of the power supply system 1 as shown in FIG. 1. Although not shown, the control device 70 includes an arithmetic unit (not shown) and a memory device (not shown), and the arithmetic unit performs arithmetic processing using a program stored in the memory device. Control each part.

  The control device 70 receives data obtained by measuring a state of each unit by a measuring device (not shown) as a data signal. Here, the power usage amount (= D3, power demand amount) of the load unit 3 is input to the control device 70 as a data signal. For example, the power usage related to the power used by the load unit 3 during a predetermined time (for example, 30 minutes) is input to the control device 70 as a data signal. In addition, the control device 70 receives, for example, the power supply amount (= D2) of the power system 2 as a data signal. In addition to this, the amount of hot water used in the load unit 3 (not shown), the amount of power E10 generated by the renewable energy power generation device 10, and the amount of power E60 generated by the fuel cell power generation device 60 and output. Data D1 such as power generation amount, hydrogen storage amount of hydrogen (not shown) stored in the hydrogen storage device 50, hot water storage amount of hot water (not shown) heated and stored by the fuel cell power generation device 60 is data Input as a signal. Then, the control device 70 calculates and obtains the control signal CTL 70 based on the input data signal, and outputs the obtained control signal CTL 70 to each part of the power supply system 1 to control the operation of each part. .

  Moreover, the control apparatus 70 controls operation | movement of the electric power supply system 1 based on the operation command which the operator input into the operating device (illustration omitted), for example. Here, for example, the control device 70 selects one operation mode from among a plurality of operation modes, and selects the selected operation mode based on an operation command input to the operation device (not shown). The operation of the power supply system 1 is controlled so that the power supply system 1 executes. The control device 70, when executing one operation mode among a plurality of operation modes, receives an operation signal indicating that another operation mode is to be executed, from the operation in the one operation mode to another operation. Switch to mode operation.

  In the power supply system 1 of the present embodiment, an internal load mode, a power sale mode, a self-sustaining operation mode, a hydrogen external supply mode, and a hydrogen storage mode are set as operation modes, and are selected from the plurality of operation modes. The control device 70 controls the operation of each unit so as to execute the single operation mode.

  The internal load mode is executed when the power E10a and E60 of the power supply system 1 is supplied to the load unit 3 with priority over the power E2 of the power system 2. In the present embodiment, when an operation command for performing the internal load mode is input, the control device 70 generates power E10a generated by the renewable energy power generation device 10 based on the amount of power used by the load unit 3. Of the power supply system 1 is controlled so as to be supplied to the load unit 3 with priority over the power E2 of the power system 2 and the power E60 generated by the fuel cell power generator 60. At the same time, when performing the internal load mode, the control device 70 gives priority to the electric power E60 generated by the fuel cell power generation device 60 over the electric power E2 of the electric power system 2 and supplies it to the load unit 3. The operation of the power supply system 1 is controlled. In addition, when performing the internal load mode, the control device 70 generates the renewable energy power when the amount of the electric power E10 generated by the renewable energy power generation device 10 is larger than the amount of power used by the load unit 3. Operation of the power supply system 1 so that the hydrogen generator 40 generates hydrogen using the electric power E10b generated by the device 10 and the hydrogen storage device 50 stores the hydrogen H40 generated by the hydrogen generator 40. To control. Furthermore, when the control device 70 performs the internal load mode, the amount of power E10 generated by the renewable energy power generation device 10 is larger than the amount of power used by the load unit 3, and the hydrogen storage device 50 When the hydrogen is stored to the limit, the operation of the power supply system 1 is controlled so that the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2.

  The power sale mode is executed when priority is given to selling power by outputting it to the power system 2 rather than supplying the power E10 of the power supply system 1 to the load unit 3. In the present embodiment, when an operation command for performing the power sale mode is input, the control device 70 of the power supply system 1 is configured to output the electric power E10c generated by the renewable energy power generation device 10 to the power system 2. Control the behavior. When performing the power sale mode, the control device 70 uses the power E10a generated by the renewable energy power generation device 10 based on the amount of power used by the load unit 3 as the power E2 of the power system 2 and The operation of the power supply system 1 is controlled so as to give priority to the electric power E60 generated by the fuel cell power generation device 60 and supply it to the load unit 3. Here, when performing the power sale mode, the control device 70 gives priority to the power E60 generated by the fuel cell power generation device 60 over the power E2 of the power system 2 and supplies it to the load unit 3. The operation of the power supply system 1 is controlled. In addition, when the control device 70 performs the power sale mode and the amount of power E10 generated by the renewable energy power generation device 10 is larger than the power sale limit amount, the power generated by the renewable energy power generation device 10 Using E10b, the operation of the power supply system 1 is controlled such that the hydrogen generator 40 generates hydrogen H40, and the hydrogen storage device 50 stores the hydrogen H40 generated by the hydrogen generator 40.

  The self-sustained operation mode is executed in a state where the electric power E2 of the electric power system 2 is not supplied, for example, in the case of an abnormality (such as a disaster) or when installed on an isolated island. When an operation command for performing the self-sustained operation mode is input, the control device 70 outputs power E10a, E60 from at least one of the renewable energy power generation device 10 and the fuel cell power generation device 60 to the load unit 3. Control the behavior. At the same time, the control device 70 generates power by the fuel cell power generation device 60 using the hydrogen H50 stored in the hydrogen storage device 50 based on the amount of power used by the load unit 3, and generated by the power generation. The operation of the fuel cell power generator 60 is controlled so as to output the electric power E60 to the load unit 3.

  Note that the control device 70 controls each part of the power supply system 1 so as to perform the self-sustained operation mode when an operation command for performing the self-sustained operation mode is input. Based on (= D2), when it is determined that the power supply of the power system 2 has stopped, the operation of each part of the power supply system 1 is controlled so as to perform the above-described self-sustained operation mode. May be.

  In the hydrogen external supply mode, when hydrogen H50 stored in the hydrogen storage device 50 is supplied to the fuel cell vehicle 4 (external hydrogen using device), the hydrogen generation device 40 generates the hydrogen H40 and the hydrogen storage device 50 It is executed when hydrogen H40 is replenished. When an operation command for performing the hydrogen external supply mode is input and hydrogen H50 is supplied to the fuel cell vehicle 4, the control device 70 causes the hydrogen generator 40 to generate hydrogen H40, and the hydrogen generated by the hydrogen generator 40 is generated. The operation of the power supply system 1 is controlled so that storing the H40 in the hydrogen storage device 50 is performed with priority over other operations. Here, the control device 70 supplies the hydrogen generation device 40 with the hydrogen H40 by giving the electric power E10b generated by the renewable energy power generation device 10 to the hydrogen generation device 40 in preference to the electric power E2a of the power system 2. And hydrogen H40 generated by the hydrogen generator 40 is stored in the hydrogen storage device 50. Then, the control device 70 supplies the hydrogen H50 stored in the hydrogen storage device 50 to the fuel cell vehicle 4 (external hydrogen using device).

  The hydrogen storage mode is an operation mode for controlling the operation of the power supply system 1 so that the amount of hydrogen stored in the hydrogen storage device 50 reaches a target amount. In the present embodiment, when an operation command for performing the hydrogen storage mode is input, the controller 70 configures each part of the power supply system 1 so that the hydrogen storage amount reaches the target amount at the target time point (target time limit). To control the operation. When performing the hydrogen storage mode, the control unit 70 performs control so that, for example, the hydrogen storage amount reaches a preset target amount at the target time point input by the operator. For example, when the time point before the event is input as the target time point and the maximum storage amount Smax is set as the target amount, the control device 70 stores hydrogen at the time point before the event is performed. Control is performed so that the amount becomes the maximum storage amount Smax. Note that the control unit 70 may perform control so that the hydrogen storage amount reaches the target amount input by the operator instead of the preset target amount. Here, for example, the control device 70 may calculate and set a target amount of the hydrogen storage amount based on the amount of power required for an event to be performed later. In the above description, the operation of each part is controlled so that the hydrogen storage amount reaches the target amount at the target time point (target time limit). However, the hydrogen storage amount is not set without setting the target time point (target time limit). The operation of each unit may be controlled so that the target amount is reached.

  When an operation command for performing the hydrogen storage mode is input and the amount of stored hydrogen is smaller than the target amount, the control device 70 causes the hydrogen generator 40 to generate hydrogen H40, and the hydrogen generator 40 The operation of the power supply system 1 is controlled so that the operation of storing the generated hydrogen H40 by the hydrogen storage device 50 is preferentially executed. Here, the control device 70 supplies the hydrogen generation device 40 with the hydrogen H40 by giving the electric power E10b generated by the renewable energy power generation device 10 to the hydrogen generation device 40 in preference to the electric power E2a of the power system 2. And hydrogen H40 generated by the hydrogen generator 40 is stored in the hydrogen storage device 50. In the hydrogen storage mode, unlike the hydrogen external supply mode, the control device 70 restricts the operation of supplying the hydrogen H50 stored in the hydrogen storage device 50 to the external fuel cell vehicle 4 (external hydrogen using device). After the hydrogen generator 40 generates hydrogen H40 and the hydrogen storage device 50 stores the hydrogen H40 generated by the hydrogen generator 40 based on the operation command for performing the hydrogen storage mode, Based on the operation command to operate the battery power generation device 60, the fuel cell power generation device 60 generates power and controls the operation of the power supply system 1 so as to output the electric power E60 generated by the power generation to the load unit 3. For example, when an event is performed, an operation command for operating the fuel cell power generation device 60 is input, and the fuel cell power generation device 60 generates power based on the operation command.

[B] Operation of Power Supply System 1 The operation of the power supply system 1 described above will be described more specifically.

  5A, 5B, 6A, 6B, 7A, 7B, 8A, 8B, 9A, and 9B are diagrams illustrating the operation of the power supply system 1 according to the embodiment.

  5A and 5B show an operation when the internal load mode is executed. 6A and 6B show an operation when the power sale mode is executed. 7A and 7B show an operation when executing the self-sustained operation mode. 8A and 8B show the operation when the hydrogen external supply mode is executed. 9A and 9B show an operation when the hydrogen storage mode is executed.

  In each figure, when power supply, power sale, hydrogen supply, or the like is performed in each part of the power supply system 1, “present” is described. On the other hand, when each part of the power supply system 1 does not perform power supply, power sale, hydrogen supply, etc., it is described as “none”.

  Hereinafter, the details of the operation when each mode is executed will be sequentially described with reference to each drawing.

[B-1] Internal Load Mode In the internal load mode, the electric power E10a of the renewable energy power generation apparatus 10 and the electric power E60 of the fuel cell power generation apparatus 60 are preferentially given to the load unit 3 over the electric power E2 of the power system 2. It is executed when supplying.

  As shown in FIGS. 5A and 5B, when executing the internal load mode, the power usage status of the load unit 3, the power generation status of the renewable energy power generation device 10, and the hydrogen storage status of the hydrogen storage device 50 are stored. The control device 70 controls the operation of each unit in accordance with each situation.

  For this reason, depending on whether there is power usage of the load unit 3 (condition 1-1-1 to condition 1-3-3) or not (condition 2-1-1 to condition 2-2), the internal load The mode is executed with different operations. That is, when the power usage (= D3) used in the load unit 3 is greater than zero (D3> 0) and when the power usage (= D3) of the load unit 3 is zero (D3 = 0) ) And the operation is different.

  Further, when the renewable energy power generation apparatus 10 generates power (condition 1-1-1 to condition 1-2-3, condition 2-1-1 to condition 2-1-3) and when there is no condition (condition 1-3) The operation in the internal load mode is controlled in accordance with -1 to conditions 1-3-3 and condition 2-2). That is, when the power generation amount (= P10) of the renewable energy power generation apparatus 10 is greater than zero (P10> 0) and when the power generation amount (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0) ) To control the operation. Furthermore, when there is power generation by the renewable energy power generation apparatus 10 (P10> 0), the power generation amount (= P10) of the renewable energy power generation apparatus 10 is larger than the power consumption amount (= D3) of the load unit 3 (P10> D3, condition 1-1-1 to condition 1-1-3) and the amount of power generated by the renewable energy power generation apparatus 10 (= P10) is less than or equal to the amount of power used by the load unit 3 (= D3) The operation is controlled in accordance with (P10 ≦ D3, condition 1-2-1 to condition 1-2-3).

  At the same time, when there is hydrogen storage in the hydrogen storage device 50 (from condition 1-1-1 to condition 1-1-2, from condition 1-2-1 to condition 1-2-2, from condition 1-3-1 Condition 1-3-2, Condition 2-1-1 to Condition 2-1-2) and when not (Condition 1-1-3, Condition 1-2-3, Condition 1-3-3, Condition 2-1 -3), the operation in the internal load mode is controlled. That is, when the hydrogen storage amount (= S50) of the hydrogen storage device 50 is greater than zero (S50> 0), and when the hydrogen storage amount (= S50) of the hydrogen storage device 50 is zero (S50 = 0). The operation is controlled according to the above. Furthermore, when there is hydrogen storage in the hydrogen storage device 50 (S50> 0), the hydrogen storage device 50 has no space for hydrogen storage (condition 1-1-1, condition 1-2-1, condition 1). -3-1, Condition 2-1-1) and the operation according to (Condition 1-1-2, Condition 1-2-2, Condition 1-3-2, Condition 2-1-2). Be controlled. In other words, when the hydrogen storage amount (= S50) of the hydrogen storage device 50 is the maximum hydrogen storage amount Smax (S50 = Smax), the hydrogen storage amount (= S50) of the hydrogen storage device 50 is greater than the maximum hydrogen storage amount Smax. The operation is controlled according to the case where the number is also small (S50 <Smax).

  As shown in FIG. 5A and FIG. 5B, when executing the internal load mode, if there is power usage of the load unit 3 (condition 1-1-1 to condition 1-3-3), renewable energy power generation Electric power E10a, E60, E2 is supplied to the load unit 3 from at least one of the device 10, the fuel cell power generation device 60, and the power system 2. Here, the power E10a generated by the renewable energy power generation device 10 is supplied to the load unit 3 with priority over the power E2 of the power system 2 and the power E60 generated by the fuel cell power generation device 60. At the same time, the electric power E60 generated by the fuel cell power generator 60 is supplied to the load unit 3 with priority over the electric power E2 of the electric power system 2. On the other hand, when there is no power usage of the load unit 3 (conditions 2-1-1 to 2-2), naturally, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The power E10a, E60, E2 is not supplied to the load unit 3 from each of the above.

  In addition, when executing the internal load mode, the amount of power generated by the renewable energy power generation apparatus 10 (= P10) is greater than the amount of power used by the load unit 3 (= D3) (P10> D3), When there is a vacancy in hydrogen storage in the storage device 50 (condition 1-1-2, condition 1-1-3, condition 2-1-2, condition 2-1-3), the renewable energy power generation apparatus 10 Electric power E10b is supplied to the hydrogen generator 40. As a result, hydrogen H40 is generated in the hydrogen generator 40, and the hydrogen H40 generated in the hydrogen generator 40 is stored in the hydrogen storage device 50. When the internal load mode is executed, the electric power E2a is not supplied from the electric power system 2 to the hydrogen generator 40.

  Further, when the internal load mode is executed, the amount of power generated by the renewable energy power generation apparatus 10 (= P10) is larger than the amount of power used by the load unit 3 (= D3) (P10> D3, condition 1-1) 1 to condition 1-1-3 and condition 2-1-1 to condition 2-1-3), the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. Do.

  When executing the internal load mode, the hydrogen H 50 a is not supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

  In the case of executing the internal load mode, specific contents of operations performed in accordance with each condition (conditions 1-1-1 to 2-2) will be sequentially described.

[B-1-1] Condition 1-1-1
First, the operation in the case of condition 1-1-1 will be described. That is, there is power usage of the load unit 3 (D3> 0), the power generation amount of the renewable energy power generation apparatus 10 (= P10) is larger than the power usage amount of the load unit 3 (= D3) (P10> D3), The operation under the condition when the hydrogen storage device 50 has no free space for hydrogen storage (S50 = Smax) will be described.

  In the case of the condition 1-1-1, electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. Here, the electric power according to the electric power consumption (= D3) of the load unit 3 is supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, the electric power E60 and E2 are not supplied from the fuel cell power generation device 60 and the electric power system 2 to the load unit 3, respectively.

  In the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the electric power system 2 to the hydrogen generation apparatus 40, respectively. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-1-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. Here, the amount of power sold (= S2) is the amount obtained by subtracting the amount of power used (= D3) of the load unit 3 from the amount of power generated by the renewable energy power generation apparatus 10 (= P10) (S2 = P10-D3).

[B-1-2] Condition 1-1-2
An operation in the case of the condition 1-1-2 will be described. That is, the operation under the same conditions as in the case of the above conditions 1-1-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of condition 1-1-2, similarly to the case of condition 1-1-1, electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. Here, the electric power according to the electric power consumption (= D3) of the load unit 3 is supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, the electric power E60 and E2 are not supplied from the fuel cell power generation device 60 and the electric power system 2 to the load unit 3, respectively.

  In the case of the condition 1-1-2, unlike the case of the condition 1-1-1, electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is equal to or less than the power generation amount (= P10) of the renewable energy power generation device 10 minus the power usage amount (= D3) of the load unit 3. (D40 ≦ P10−D3). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-2, as in the case of the condition 1-1-1, the electric power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. . Here, the amount of power sold (= S2) is the amount of power used by the load unit 3 (= D3) and the amount of power supplied to the hydrogen generator 40 from the amount of power generated by the renewable energy power generation device 10 (= P10). The amount is obtained by subtracting (= D40) (S2 = P10-D3-D40).

[B-1-3] Condition 1-1-3
An operation in the case of condition 1-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 1-1-1 and 1-1-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-1 and the condition 1-1-2, the electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. Here, the electric power according to the electric power consumption (= D3) of the load unit 3 is supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, the electric power E60 and E2 are not supplied from the fuel cell power generation device 60 and the electric power system 2 to the load unit 3, respectively.

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is equal to or less than the power generation amount (= P10) of the renewable energy power generation device 10 minus the power usage amount (= D3) of the load unit 3. (D40 ≦ P10−D3). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-1 and the condition 1-1-2, the electric power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2. To sell electricity. Here, the amount of power sold (= S2) is the amount of power used by the load unit 3 (= D3) from the amount of power generated by the renewable energy power generation apparatus 10 (= P10), as in the case of the condition 1-1-2. And it becomes the quantity which subtracted the electric power supply amount (= D40) supplied to the hydrogen generator 40 (S2 = P10-D3-D40).

[B-1-4] Condition 1-2-1
An operation in the case of condition 1-2-1 will be described. That is, except for the point (P10 ≦ D3) where the power generation amount (= P10) of the renewable energy power generation apparatus 10 is equal to or less than the power consumption amount (= D3) of the load unit 3, The operation under the same conditions will be described.

  In the case of the condition 1-2-1, unlike the case of the condition 1-1-1, electric power E10a, E60 is supplied to the load unit 3 from each of the renewable energy power generation device 10 and the fuel cell power generation device 60. Here, all of the electric power E10 generated by the renewable energy power generation apparatus 10 is supplied to the load section 3, and further, the electric power E60 is supplied from the fuel cell power generation apparatus 60 to the load section 3. And the electric power E2 is further supplied to the load part 3 from the electric power grid | system 2 as needed. Here, when the total amount of the power generation amount of the renewable energy power generation device 10 and the power generation amount of the fuel cell power generation device 60 is smaller than the power consumption amount of the load unit 3, the power is further supplied from the power system 2 to the load unit 3. E2 is supplied.

  In the case of the condition 1-2-1, similarly to the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-1, unlike the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-1-5] Condition 1-2-2
An operation in the case of condition 1-2-2 will be described. That is, the operation under the same conditions as in the case of the above condition 1-2-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, electric power E10a and E60 are supplied to the load unit 3 from each of the renewable energy power generation device 10 and the fuel cell power generation device 60. . Here, all of the electric power E10 generated by the renewable energy power generation apparatus 10 is supplied to the load section 3, and further, the electric power E60 is supplied from the fuel cell power generation apparatus 60 to the load section 3. Moreover, the electric power E2 is further supplied from the electric power grid | system 2 to the load part 3 as needed. Here, when the total amount of the power generation amount of the renewable energy power generation device 10 and the power generation amount of the fuel cell power generation device 60 is smaller than the power consumption amount of the load unit 3, the power is further supplied from the power system 2 to the load unit 3. E2 is supplied.

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, the electric power E10b, E2a is not supplied to the hydrogen generator 40 from each of the renewable energy power generation apparatus 10 and the power system 2. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the electric power system 2 (E10c = 0). That is, no power is sold.

[B-1-6] Condition 1-2-3
An operation in the case of condition 1-2-3 will be described. That is, the operation under the same conditions as in the above conditions 1-2-1 and 1-2-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-2-3, unlike the cases of the condition 1-2-1 and the condition 1-2-2, power is supplied from the renewable energy power generation apparatus 10 and the power system 2 to the load unit 3. Here, all of the electric power E10 generated by the renewable energy power generation apparatus 10 is supplied to the load unit 3. The fuel cell power generator 60 does not supply power E60 to the load unit 3.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-1 and the condition 1-2-2, from each of the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40 Electric power E10b and E2a are not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-1 and the condition 1-2-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-1-7] Condition 1-3-1
An operation in the case of the condition 1-3-1 will be described. That is, the operation under the same conditions as in the case of the above condition 1-1-1 will be described except that the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0).

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, electric powers E60 and E2 are supplied from the fuel cell power generation device 60 and the power system 2 to the load unit 3, respectively. Here, the electric power E60 of the fuel cell power generator 60 is supplied to the load unit 3 with priority over the electric power E2 of the electric power system 2. At this time, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of the condition 1-3-1, similarly to the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-1-8] Condition 1-3-2
An operation in the case of condition 1-3-2 will be described. That is, the operation under the same condition as in the case of the above condition 1-3-1 will be described except that the hydrogen storage device 50 has a free space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, electric power E60 and E2 are supplied to the load unit 3 from each of the fuel cell power generation device 60 and the power system 2. Here, the electric power E60 of the fuel cell power generator 60 is supplied to the load unit 3 with priority over the electric power E2 of the electric power system 2. At this time, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-1-9] Condition 1-3-3
An operation in the case of condition 1-3-3 will be described. That is, the operation under the same conditions as in the above conditions 1-3-1 and 1-3-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-3-3, unlike the case of the condition 1-3-1 and the condition 1-3-2, power is supplied from the power system 2 to the load unit 3. Here, the electric power E10a, E60 is not supplied from the renewable energy power generation device 10 and the fuel cell power generation device 60 to the load unit 3.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the renewable energy power generation device 10 and the power system 2 are respectively transferred to the hydrogen generator 40. Electric power E10b and E2a are not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-1-10] Condition 2-1-1
An operation in the case of condition 2-1-1 will be described. That is, the operation under the same conditions as those in the conditions 1-1-1 to 1-2-3 will be described except that the load unit 3 does not use power (D3 = 0).

  In the case of the condition 2-1-1, unlike the case of the above condition 1-1-1 to the condition 1-2-3, each of the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 is provided. Therefore, the electric power E10a, E60, E2 is not supplied to the load unit 3.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the electric power E10b and E2a are not supplied to the hydrogen generator 40 from each of the renewable energy power generation apparatus 10 and the power system 2. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. Here, the power sale amount (= S2) is the same as the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-1-1] Condition 2-1-2
The operation in the case of condition 2-1-2 will be described. That is, the operation under the same conditions as in the case of the above condition 2-1-1 will be described except that the hydrogen storage device 50 has a vacancy (S50 <Smax).

  In the case of the condition 2-1-2, as in the case of the condition 2-1-1, the electric power E10a is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. , E60, E2 are not supplied.

  In the case of the condition 2-1-2, unlike the case of the condition 2-1-1, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is equal to or less than the power generation amount (= P10) of the renewable energy power generation device 10 (D40 ≦ P10). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  Then, in the case of the condition 2-1-2, as in the case of the condition 2-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. . Here, the power sale amount (= S2) is an amount obtained by subtracting the power supply amount (= D40) supplied to the hydrogen generator 40 from the power generation amount (= P10) of the renewable energy power generation device 10 (S2 = P10). -D40).

[B-1-12] Condition 2-1-3
An operation in the case of condition 2-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 2-1-1 and 2-2-1 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 2-1-3, as in the case of the condition 2-1-1 and the condition 2-1-2, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The electric power E10a, E60, E2 is not supplied to the load part 3 from each.

  In the case of the condition 2-1-3, similarly to the case of the condition 2-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is equal to or less than the power generation amount (= P10) of the renewable energy power generation device 10 (D40 ≦ P10). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  Then, in the case of the condition 2-1-3, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 as in the case of the condition 2-1-1 and the condition 2-1-2. To sell electricity. Here, the amount of power sold (= S2) is the amount of power supplied to the hydrogen generator 40 (= P10) from the amount of power generated by the renewable energy power generator 10 (= P10) as in the case of the condition 2-1-2 (= D40) is subtracted (S2 = P10−D40).

[B-1-13] Condition 2-2
The operation in the case of condition 2-2 will be described. That is, except for the point that the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0), the operation under the same conditions as those in the above conditions 2-1-1 to 2-2-1 Will be described.

  In the case of Condition 2-2, as in the case of Condition 2-1-1 to Condition 2-1-3, from each of the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The power E10a, E60, E2 is not supplied to the load unit 3.

  In the case of the condition 2-2, as in the case of the condition 2-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of condition 2-2, unlike the case of condition 2-1-1 to condition 2-1-3, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). . That is, no power is sold.

[B-2] Power Sale Mode As described above, in the power sale mode, the power E10c of the renewable energy power generator 10 is supplied to the power system rather than supplying the power E10a of the renewable energy power generator 10 to the load unit 3. It is executed when priority is given to output to 2 and selling power.

  As shown in FIGS. 6A and 6B, when the power sale mode is executed, the power usage status of the load unit 3, the power generation status of the renewable energy power generation device 10, and the hydrogen storage status of the hydrogen storage device 50 are stored. The control device 70 controls the operation of each unit in accordance with each situation.

  For this reason, the operation in the power selling mode is performed when the power of the load unit 3 is used (Condition 1-1-1 to Condition 1-3-3) and not (Condition 2- It is controlled according to 1-1 to condition 2-3).

  Further, the operation in the power selling mode is performed when there is power generation by the renewable energy power generation apparatus 10 (condition 1-1-1 to condition 1-2-3, condition 2-1-1), as in the case of the internal load mode. To condition 2-1-3) and when not (condition 1-3-1 to condition 1-3-3, condition 2-2). When there is power generation by the renewable energy power generation apparatus 10 (P10> 0), the power generation amount (= P10) of the renewable energy power generation apparatus 10 is larger than the power sale limit (= Cx) (P10> Cx, Condition 1-1-1 to Condition 1-1-3, Condition 2-1-1 to Condition 2-1-3), and the power generation amount (= P10) of the renewable energy power generation apparatus 10 is the power sale limit amount (= Cx) or less (P10 ≦ Cx, condition 1-2-1 to condition 1-2-3, condition 2-2-1 to condition 2-2-3), the operation is controlled.

  At the same time, the operation in the power sale mode is similar to that in the internal load mode when hydrogen is stored in the hydrogen storage device 50 (from condition 1-1-1 to condition 1-1-2, condition 1-2). 1 to condition 1-22, condition 1-3-1 to condition 1-3-2, condition 2-1-1 to condition 2-1-2, condition 2-2-1 to condition 2-2-2 ) And not (condition 1-1-3, condition 1-2-3, condition 1-3-3, condition 2-1-3, condition 2-2-3). Furthermore, when there is hydrogen storage in the hydrogen storage device 50 (S50> 0), the hydrogen storage device 50 has no space for hydrogen storage (condition 1-1-1, condition 1-2-1, condition 1). -3-1, condition 2-1-1, condition 2-2-1) (condition 1-1-2, condition 1-2-2, condition 1-3-2, condition 2-1-2) , Condition 2-2-2), the operation of the power selling mode is controlled.

  As shown in FIG. 6A and FIG. 6B, when executing the power selling mode, when there is power usage of the load unit 3 (condition 1-1-1 to condition 1-3-3), renewable energy power generation Electric power E10a, E60, E2 is supplied to the load unit 3 from at least one of the device 10, the fuel cell power generation device 60, and the power system 2. Here, the power E10a generated by the renewable energy power generation device 10 is supplied to the load unit 3 with priority over the power E2 of the power system 2 and the power E60 generated by the fuel cell power generation device 60. On the other hand, when there is no power usage of the load unit 3 (conditions 2-1-1 to 2-3), of course, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The power E10a, E60, E2 is not supplied to the load unit 3 from each of the above.

  Further, when executing the power sale mode, the amount of power generated by the renewable energy power generation apparatus 10 (= P10) is larger than the power sale limit (= Cx) (P10> Cx), and the hydrogen storage device 50 When there is a vacancy in hydrogen storage (condition 1-1-2, condition 1-1-3, condition 2-1-2, condition 2-1-3), the renewable energy power generator 10 to the hydrogen generator Electric power E10b is supplied to 40. As a result, hydrogen H40 is generated in the hydrogen generator 40, and the hydrogen H40 generated in the hydrogen generator 40 is stored in the hydrogen storage device 50. When executing the power sale mode, the electric power E2a is not supplied from the electric power system 2 to the hydrogen generator 40.

  Further, when the power sale mode is executed, when there is power generation by the renewable energy power generation apparatus 10 (P10> 0, condition 1-1-1 to condition 1-2-3, condition 2-1-1 to condition 2) In -2-3), electric power is sold by outputting electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. That is, the electric power E10c of the renewable energy power generation apparatus 10 is sold.

  When executing the power sale mode, the hydrogen H50a is not supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

  In the case of the power sale mode, specific contents of operations performed in accordance with each condition (conditions 1-1-1 to 2-3) will be sequentially described.

[B-2-1] Condition 1-1-1
First, the operation in the case of condition 1-1-1 will be described. That is, there is power usage of the load unit 3 (D3> 0), the power generation amount of the renewable energy power generation apparatus 10 (= P10) is larger than the power sale limit amount (= Cx) (P10> Cx), and hydrogen The operation under the condition when the storage device 50 has no free space for hydrogen storage (S50 = Smax) will be described.

  In the case of the condition 1-1-1, electric power E10a and E60 are supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, electric power E60 is supplied from the fuel cell power generator 60 to the load unit 3 as necessary. Here, when the power generation amount (= P10) of the renewable energy power generation device 10 is smaller than the power usage amount (= D3) of the load unit 3, the power E60 is further supplied from the fuel cell power generation device 60 to the load unit 3. To do. Further, when the power is further insufficient, the power E2 is further supplied from the power system 2 to the load unit 3. That is, here, when the total amount of the power generation amount of the renewable energy power generation device 10 and the power generation amount of the fuel cell power generation device 60 is smaller than the power usage amount of the load portion 3, the load portion 3 is further removed from the power system 2. Is supplied with electric power E2.

  In the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the electric power system 2 to the hydrogen generation apparatus 40, respectively. That is, the hydrogen generator 40 does not generate hydrogen H40. However, when hydrogen is consumed by the fuel cell power generation device 60, the electric power E10b and E2a may be supplied to the hydrogen generation device 40 so as to supplement the consumed amount.

  In the case of the condition 1-1-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  In addition, when the electric power E10 generated by the renewable energy power generation apparatus 10 is surplus, for example, by adding a hydrogen storage tank 501 in the hydrogen storage apparatus 50, the hydrogen storage capacity of the hydrogen storage apparatus 50 is increased to generate hydrogen. The apparatus is configured to store more hydrogen produced by the apparatus 40. In addition, in this case, the power generation amount of the renewable energy power generation apparatus 10 may be adjusted.

[B-2-2] Condition 1-1-2
An operation in the case of the condition 1-1-2 will be described. That is, the operation under the same conditions as in the case of the above conditions 1-1-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-1-2, the electric power E10a is supplied from the renewable energy power generation device 10 to the load unit 3, but unlike the case of the condition 1-1-1, the fuel cell power generation device 60 supplies the load unit 3. The electric power E60 is not supplied. At this time, electric power E2 is further supplied from the electric power system 2 to the load unit 3 as necessary.

  In the case of the condition 1-1-2, unlike the case of the condition 1-1-1, electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. The amount of power supplied to the hydrogen generator 40 (= D40) is calculated from the amount of power generated by the renewable energy power generation device 10 (= P10), the amount of power used by the load unit 3 (= D3), and the sale of power to the power system 2. It is the amount obtained by subtracting the amount of electricity sold S2 (D40 = P10-D3-S2). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-2, as in the case of the condition 1-1-1, the electric power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. . Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

[B-2-3] Condition 1-1-3
An operation in the case of condition 1-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 1-1-1 and 1-1-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-1-3, as in the case of the condition 1-1-2, the electric power E10a is supplied from the renewable energy power generation device 10 to the load unit 3, but from the fuel cell power generation device 60 to the load unit 3 Electric power E60 is not supplied. At this time, electric power E2 is further supplied from the electric power system 2 to the load unit 3 as necessary.

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is derived from the power generation amount (= P10) of the renewable energy power generation device 10, the power usage amount (= D3) of the load unit 3, and the power system 2 Is the amount obtained by subtracting the amount S2 of electricity sold (D40 = P10-D3-S2). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-1 and the condition 1-1-2, the electric power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2. To sell electricity. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

[B-2-4] Condition 1-2-1
An operation in the case of condition 1-2-1 will be described. In other words, except for the point (P10 ≦ Cx) where the power generation amount (= P10) of the renewable energy power generation apparatus 10 is equal to or less than the power sale limit amount (= Cx), The operation will be described.

  In the case of the condition 1-2-1, unlike the case of the condition 1-1-1, electric powers E60 and E2 are supplied from the fuel cell power generation device 60 and the power system 2 to the load unit 3, respectively. Here, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0). Further, when reducing the electric power E <b> 2 a introduced from the electric power system 2, priority is given to the electric power supply of the fuel cell power generator 60 over the electric power supply of the electric power system 2.

  In the case of the condition 1-2-1, similarly to the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-1, as in the case of the condition 1-1-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-2-5] Condition 1-2-2
An operation in the case of condition 1-2-2 will be described. That is, the operation under the same conditions as in the case of the above condition 1-2-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, electric power E60 and E2 are supplied to the load unit 3 from each of the fuel cell power generation device 60 and the power system 2. Here, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0). Further, when reducing the electric power E <b> 2 a introduced from the electric power system 2, priority is given to the electric power supply of the fuel cell power generator 60 over the electric power supply of the electric power system 2.

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, the electric power E10b, E2a is not supplied to the hydrogen generator 40 from each of the renewable energy power generation apparatus 10 and the power system 2. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-2-6] Condition 1-2-3
An operation in the case of condition 1-2-3 will be described. That is, the operation under the same conditions as in the above conditions 1-2-1 and 1-2-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of condition 1-2-3, unlike the cases of condition 1-2-1 and condition 1-2-2, power is supplied from the power system 2 to the load unit 3. Here, the electric power E10a, E60 is not supplied from the renewable energy power generation device 10 and the fuel cell power generation device 60 to the load unit 3.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-1 and the condition 1-2-2, from each of the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40 Electric power E10b and E2a are not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-1 and the condition 1-2-2, by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2 , Sell electricity. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-2-7] Condition 1-3-1
An operation in the case of the condition 1-3-1 will be described. That is, the operation under the same conditions as in the case of the above condition 1-1-1 will be described except that the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0).

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, electric powers E60 and E2 are supplied from the fuel cell power generation device 60 and the power system 2 to the load unit 3, respectively. At this time, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of the condition 1-3-1, similarly to the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-2-8] Condition 1-3-2
An operation in the case of condition 1-3-2 will be described. That is, the operation under the same condition as in the case of the above condition 1-3-1 will be described except that the hydrogen storage device 50 has a free space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, electric power E60 and E2 are supplied to the load unit 3 from each of the fuel cell power generation device 60 and the power system 2. At this time, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-2-9] Condition 1-3-3
An operation in the case of condition 1-3-3 will be described. That is, the operation under the same conditions as in the above conditions 1-3-1 and 1-3-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-3-3, unlike the case of the condition 1-3-1 and the condition 1-3-2, power is supplied from the power system 2 to the load unit 3. Here, the electric power E10a, E60 is not supplied from the renewable energy power generation device 10 and the fuel cell power generation device 60 to the load unit 3.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the renewable energy power generation device 10 and the power system 2 are respectively transferred to the hydrogen generator 40. Electric power E10b and E2a are not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-2-10] Condition 2-1-1
An operation in the case of condition 2-1-1 will be described. That is, the operation under the same condition as in the case of the above condition 1-1-1 will be described except that the load unit 3 does not use power (D3 = 0).

  In the case of the condition 2-1-1, unlike the case of the condition 1-1-1, the power is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. E10a, E60, and E2 are not supplied.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the electric power E10b and E2a are not supplied to the hydrogen generator 40 from each of the renewable energy power generation apparatus 10 and the power system 2. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  In addition, when the electric power E10 generated by the renewable energy power generation apparatus 10 is surplus, for example, by adding a hydrogen storage tank 501 in the hydrogen storage apparatus 50, the hydrogen storage capacity of the hydrogen storage apparatus 50 is increased to generate hydrogen. The apparatus is configured to store more hydrogen produced by the apparatus 40. In addition, in this case, the power generation amount of the renewable energy power generation apparatus 10 may be adjusted.

[B-2-11] Condition 2-1-2
The operation in the case of condition 2-1-2 will be described. That is, the operation under the same conditions as in the case of the above condition 2-1-1 will be described except that the hydrogen storage device 50 has a vacancy (S50 <Smax).

  In the case of the condition 2-1-2, as in the case of the condition 2-1-1, the electric power E10a is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. , E60, E2 are not supplied.

  In the case of the condition 2-1-2, unlike the case of the condition 2-1-1, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is a value obtained by subtracting the power sale amount S2 from the power generation amount (= P10) of the renewable energy power generation device 10 (D40 = P10-S2). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  Then, in the case of the condition 2-1-2, as in the case of the condition 2-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. . Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

[B-2-12] Condition 2-1-3
An operation in the case of condition 2-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 2-1-1 and 2-2-1 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 2-1-3, as in the case of the condition 2-1-1 and the condition 2-1-2, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The electric power E10a, E60, E2 is not supplied to the load part 3 from each.

  In the case of the condition 2-1-3, similarly to the case of the condition 2-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is a value obtained by subtracting the power sale amount S2 from the power generation amount (= P10) of the renewable energy power generation device 10 (D40 = P10-S2). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  Then, in the case of the condition 2-1-3, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 as in the case of the condition 2-1-1 and the condition 2-1-2. To sell electricity. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

[B-2-13] Condition 2-2-1
An operation in the case of condition 2-2-1 will be described. That is, in the same conditions as in the case of the above condition 2-1-1 except that the power generation amount (= P10) of the renewable energy power generation apparatus 10 is equal to or less than the power sale limit amount (= Cx) (P10 ≦ Cy). The operation will be described.

  In the case of the condition 2-2-1, as in the case of the above condition 2-1-1, from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. Electric power E10a, E60, E2 is not supplied.

  In the case of the condition 2-2-1, similarly to the case of the condition 2-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-1-1, as in the case of the condition 2-1-1, the electric power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-2-14] Condition 2-2-2
An operation in the case of condition 2-2-2 will be described. That is, the operation under the same conditions as in the case of the above condition 2-2-1 will be described, except that the hydrogen storage device 50 has a vacancy (S50 <Smax).

  In the case of the condition 2-2-2, as in the case of the condition 2-2-1, the electric power E10a is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. , E60, E2 are not supplied.

  In the case of the condition 2-2-2, as in the case of the condition 2-2-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-2-2, as in the case of the condition 2-2-1, power is sold by outputting the power E10c generated by the renewable energy power generation apparatus 10 to the power system 2. . Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-2-15] Condition 2-2-3
The operation in the case of condition 2-2-3 will be described. That is, the operation under the same conditions as those in the above conditions 2-2-1 and 2-2-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 2-2-3, as in the case of the condition 2-2-1 and the condition 2-2-2, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The electric power E10a, E60, E2 is not supplied to the load part 3 from each.

  In the case of the condition 2-2-3, as in the case of the condition 2-2-2, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-2-3, as in the case of the condition 2-2-1 and the condition 2-2-2, the electric power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2. To sell electricity. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

[B-2-16] Condition 2-3
An operation in the case of Condition 2-3 will be described. That is, except for the point (P10 = 0) where the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0), the above condition 2-1-1 to the condition 2-1-3 and the condition 2-2 The operation under the same conditions as in the case of -1 to Condition 2-2-3 will be described.

  In the case of the condition 2-3, the renewable energy power generation apparatus 10 is the same as the case of the condition 2-1-1 to the condition 2-1-3 and the condition 2-2-1 to the condition 2-2-3. In addition, the electric power E10a, E60, E2 is not supplied to the load unit 3 from each of the fuel cell power generator 60 and the power system 2.

  In the case of the condition 2-3, the renewable energy power generation apparatus 10 is the same as the case of the condition 2-1-1 to the condition 2-1-3 and the condition 2-2-1 to the condition 2-2-3. And the electric power E10b and E2a are not supplied to the hydrogen generator 40 from each of the electric power system 2. That is, the hydrogen generator 40 does not generate hydrogen H40. However, as necessary, the electric power E10b and E2a may be supplied to the hydrogen generator 40 to generate hydrogen H40 in the hydrogen generator 40.

  In the case of the condition 2-3, unlike the cases of the condition 2-1-1 to the condition 2-1-3 and the condition 2-2-1 to the condition 2-2-3, the renewable energy power generation apparatus 10 The generated power E10c is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3] Self-sustained operation mode As described above, the self-sustained operation mode is supplied with the electric power E2 of the power system 2 when, for example, an abnormality occurs when a power failure occurs due to a disaster or when it is installed on an isolated island. It is executed when it is not.

  As shown in FIGS. 7A and 7B, when executing the self-sustained operation mode, as in the case of executing the internal load mode, the power usage status of the load unit 3 and the power generation of the renewable energy power generation apparatus 10 are The control device 70 controls the operation of each unit according to the situation and the hydrogen storage situation of the hydrogen storage device 50.

  As shown in FIG. 7A and FIG. 7B, when the self-sustained operation mode is executed, if there is power usage of the load unit 3 (condition 1-1-1 to condition 1-3-3), renewable energy power generation Electric power E10a, E60 is supplied to the load unit 3 from at least one of the device 10 and the fuel cell power generation device 60. Here, the electric power E <b> 10 a generated by the renewable energy power generation apparatus 10 is supplied to the load unit 3 with priority over the electric power E <b> 60 generated by the fuel cell power generation apparatus 60. On the other hand, when there is no power usage of the load unit 3 (conditions 2-1-1 to 2-2), of course, from each of the renewable energy power generation device 10 and the fuel cell power generation device 60, The power E10a and E60 are not supplied to the load unit 3.

  Further, when the self-sustained operation mode is executed, the amount of power generated by the renewable energy power generation apparatus 10 (= P10) is larger than the amount of power used by the load unit 3 (= D3) (P10> D3), and hydrogen When there is a vacancy in hydrogen storage in the storage device 50 (condition 1-1-2, condition 1-1-3, condition 2-1-2, condition 2-1-3), the renewable energy power generation apparatus 10 Electric power E10b is supplied to the hydrogen generator 40. As a result, hydrogen H40 is generated in the hydrogen generator 40, and the hydrogen H40 generated in the hydrogen generator 40 is stored in the hydrogen storage device 50.

  When the self-sustained operation mode is executed, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the electric power system 2 (E10c = 0). That is, no power is sold.

  Further, when executing the self-sustained operation mode, the hydrogen H 50 a is not supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

  In the case of executing the self-sustained operation mode, specific contents of operations performed in accordance with the respective conditions (conditions 1-1-1 to 2-2) will be sequentially described.

[B-3-1] Condition 1-1-1
First, the operation in the case of condition 1-1-1 will be described. That is, there is power usage of the load unit 3 (D3> 0), the power generation amount of the renewable energy power generation apparatus 10 (= P10) is larger than the power usage amount of the load unit 3 (= D3) (P10> D3), The operation under the condition when the hydrogen storage device 50 has no free space for hydrogen storage (S50 = Smax) will be described.

  In the case of the condition 1-1-1, electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, the electric power E60 is not supplied from the fuel cell power generator 60 to the load unit 3.

  In the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, as described above, power is not sold.

  In addition, when the electric power E10 generated by the renewable energy power generation apparatus 10 is surplus, for example, by adding a hydrogen storage tank 501 in the hydrogen storage apparatus 50, the hydrogen storage capacity of the hydrogen storage apparatus 50 is increased to generate hydrogen. The apparatus is configured to store more hydrogen produced by the apparatus 40. In addition, in this case, the power generation amount of the renewable energy power generation apparatus 10 may be adjusted.

[B-3-2] Condition 1-1-2
An operation in the case of the condition 1-1-2 will be described. That is, the operation under the same conditions as in the case of the above conditions 1-1-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of condition 1-1-2, similarly to the case of condition 1-1-1, electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, the electric power E60 is not supplied from the fuel cell power generator 60 to the load unit 3.

  In the case of the condition 1-1-2, unlike the case of the condition 1-1-1, electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is an amount obtained by subtracting the power consumption amount (= D3) of the load unit 3 from the power generation amount (= P10) of the renewable energy power generation device 10. Yes (D40 = P10-D3). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-2, as in the case of the condition 1-1-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-3] Condition 1-1-3
An operation in the case of condition 1-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 1-1-1 and 1-1-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-1 and the condition 1-1-2, the electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. At this time, the electric power E60 is not supplied from the fuel cell power generator 60 to the load unit 3.

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is an amount obtained by subtracting the power consumption amount (= D3) of the load unit 3 from the power generation amount (= P10) of the renewable energy power generation device 10. Yes (D40 = P10-D3). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-3, as in the case of the condition 1-1-1 and the condition 1-1-2, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2. (E10c = 0). That is, no power is sold.

[B-3-4] Condition 1-2-1
An operation in the case of condition 1-2-1 will be described. That is, except for the point (P10 ≦ D3) where the power generation amount (= P10) of the renewable energy power generation apparatus 10 is equal to or less than the power consumption amount (= D3) of the load unit 3, The operation under the same conditions will be described.

  In the case of the condition 1-2-1, unlike the case of the condition 1-1-1, electric power E10a, E60 is supplied to the load unit 3 from each of the renewable energy power generation device 10 and the fuel cell power generation device 60.

  In the case of the condition 1-2-1, the electric power E10b, E2a is not supplied from the renewable energy power generation device 10 to the hydrogen generator 40 as in the case of the condition 1-1-1. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-1, similarly to the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-5] Condition 1-2-2
An operation in the case of condition 1-2-2 will be described. That is, the operation under the same conditions as in the case of the above condition 1-2-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-2-2, similarly to the case of the condition 1-2-1, power is supplied to the load unit 3 from each of the renewable energy power generation device 10 and the fuel cell power generation device 60.

  In the case of the condition 1-2-2, similarly to the case of the condition 1-2-1, the electric power E10b is not supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-2, as in the case of the condition 1-2-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the electric power system 2 (E10c = 0). That is, no power is sold.

[B-3-6] Condition 1-2-3
An operation in the case of condition 1-2-3 will be described. That is, the operation under the same conditions as in the above conditions 1-2-1 and 1-2-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-2-3, the electric power E10a is supplied from the renewable energy power generation apparatus 10 to the load unit 3. Unlike the cases of the conditions 1-2-1 and 1-2-2, the fuel cell power generation The power E60 is not supplied from the device 60 to the load unit 3.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-1 and the condition 1-2-2, the electric power E10b is not supplied from the renewable energy power generation device 10 to the hydrogen generator 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-1 and the condition 1-2-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-7] Condition 1-3-1
An operation in the case of the condition 1-3-1 will be described. That is, the operation under the same conditions as in the case of the above condition 1-1-1 will be described except that the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0).

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, electric power E60 is supplied from the fuel cell power generator 60 to the load unit 3. At this time, power is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of condition 1-3-1, similarly to the case of condition 1-1-1, the electric power E10b is not supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-1, similarly to the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-8] Condition 1-3-2
An operation in the case of condition 1-3-2 will be described. That is, the operation under the same condition as in the case of the above condition 1-3-1 will be described except that the hydrogen storage device 50 has a free space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-3-2, the electric power E60 is supplied from the fuel cell power generation device 60 to the load unit 3 as in the case of the condition 1-3-1. At this time, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of the condition 1-3-2, as in the case of the condition 1-3-1, the electric power E10b is not supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-9] Condition 1-3-3
An operation in the case of condition 1-3-3 will be described. That is, the operation under the same conditions as in the above conditions 1-3-1 and 1-3-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-3-3, unlike the cases of the conditions 1-3-1 and 1-3-2, the electric power E10a, E60 is supplied from the renewable energy power generation device 10 and the fuel cell power generation device 60 to the load unit 3. Do not supply.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the renewable energy power generation device 10 and the power system 2 are respectively transferred to the hydrogen generator 40. Electric power E10b and E2a are not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-10] Condition 2-1-1
An operation in the case of condition 2-1-1 will be described. That is, the operation under the same conditions as those in the conditions 1-1-1 to 1-2-3 will be described except that the load unit 3 does not use power (D3 = 0).

  In the case of the condition 2-1-1, unlike the case of the above condition 1-1-1 to the condition 1-2-3, the load unit 3 is supplied from each of the renewable energy power generation device 10 and the fuel cell power generation device 60. Electric power E10a, E60 is not supplied to

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the electric power E10b is not supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  In addition, when the electric power E10 generated by the renewable energy power generation apparatus 10 is surplus, for example, by adding a hydrogen storage tank 501 in the hydrogen storage apparatus 50, the hydrogen storage capacity of the hydrogen storage apparatus 50 is increased to generate hydrogen. The apparatus is configured to store more hydrogen produced by the apparatus 40. In addition, in this case, the power generation amount of the renewable energy power generation apparatus 10 may be adjusted.

[B-3-11] Condition 2-1-2
The operation in the case of condition 2-1-2 will be described. That is, the operation under the same conditions as in the case of the above condition 2-1-1 will be described except that the hydrogen storage device 50 has a vacancy (S50 <Smax).

  In the case of the condition 2-1-2, as in the case of the condition 2-1-1, the electric power E10a and E60 are supplied to the load unit 3 from each of the renewable energy power generation device 10 and the fuel cell power generation device 60. do not do.

  In the case of the condition 2-1-2, unlike the case of the condition 2-1-1, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is the same as the power generation amount (= P10) of the renewable energy power generation device 10 (D40 = 10). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 2-1-2, as in the case of the condition 2-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

[B-3-12] Condition 2-1-3
An operation in the case of condition 2-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 2-1-1 and 2-2-1 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 2-1-3, as in the case of the condition 2-1-1 and the condition 2-1-2, the load is generated from each of the renewable energy power generation device 10 and the fuel cell power generation device 60. The power E10a and E60 are not supplied to the unit 3.

  In the case of the condition 2-1-3, similarly to the case of the condition 2-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40) supplied to the hydrogen generator 40 is the same as the power generation amount (= P10) of the renewable energy power generation device 10 (D40 = P10). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 2-1-3, as in the case of the condition 2-1-2, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the electric power system 2 (E10c = 0). That is, no power is sold.

[B-3-13] Condition 2-2
The operation in the case of condition 2-2 will be described. That is, except for the point that the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0), the operation under the same conditions as those in the above conditions 2-1-1 to 2-2-1 Will be described.

  In the case of the condition 2-2, as in the case of the condition 2-1-1 to the condition 2-1-3, the load unit 3 is supplied from each of the renewable energy power generation device 10 and the fuel cell power generation device 60. Electric power E10a, E60 is not supplied to

  In the case of the condition 2-2, similarly to the case of the condition 2-1-1, the electric power E10b is not supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-2, as in the case of the condition 2-1-1 to the condition 2-1-3, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0) ). That is, no power is sold.

[B-4] Hydrogen External Supply Mode In the hydrogen external supply mode, when the hydrogen H50 stored in the hydrogen storage device 50 is supplied to the external fuel cell vehicle 4 (external hydrogen using device), the hydrogen generation device 40 It is executed when hydrogen H40 is generated and the hydrogen storage device 50 is replenished with hydrogen H40.

  As shown in FIGS. 8A and 8B, when the hydrogen external supply mode is executed, the power usage status of the load unit 3, the power generation status of the renewable energy power generation device 10, and the hydrogen storage of the hydrogen storage device 50 are stored. The control device 70 controls the operation of each unit in accordance with the situation.

  For this reason, the operation in the hydrogen external supply mode is performed when the power of the load unit 3 is used (condition 1-1-1 to condition 1-3-3) and not (condition 2), as in the case of the internal load mode. Control is performed according to the conditions from 1-1-1 to 2-3).

  Further, the operation in the hydrogen external supply mode is performed when the renewable energy power generation apparatus 10 generates power (condition 1-1-1 to condition 1-2-3, condition 2-1), as in the internal load mode. 1 to Condition 2-1-3) and when there is no condition (Condition 1-3-1 to Condition 1-3-3, Condition 2-2), the operation in the hydrogen external supply mode is controlled. When there is power generation by the renewable energy power generation device 10 (P10> 0), the power generation amount (= P10) of the renewable energy power generation device 10 is the amount of electrolytic power (= P10) used when the hydrogen generator 40 performs electrolysis. Cy) or more (P10 ≧ Cy, Condition 1-1-1 to Condition 1-1-3, Condition 2-1-1 to Condition 2-1-3), and the amount of power generated by the renewable energy power generation apparatus 10 ( = P10) is less than the amount of electrolysis power (= Cy) of the hydrogen generator 40 (P10 <Cy, Condition 1-2-1 to Condition 1-2-3, Condition 2-2-1 to Condition 2-2 -3), the operation is controlled.

  At the same time, the operation in the hydrogen external supply mode is performed when hydrogen is stored in the hydrogen storage device 50 as in the internal load mode (from condition 1-1-1 to condition 1-1-2, condition 1-2). -1 to condition 1-22, condition 1-3-1 to condition 1-3-2, condition 2-1-1 to condition 2-1-2, condition 2-2-1 to condition 2-2 2) and the hydrogen external supply mode depending on the case (Condition 1-1-3, Condition 1-2-3, Condition 1-3-3, Condition 2-1-3, Condition 2-2-3) Is controlled. When there is hydrogen storage in the hydrogen storage device 50 (S50> 0), there is no space for hydrogen storage in the hydrogen storage device 50 (condition 1-1-1, condition 1-2-1, condition 1-3). -1, condition 2-1-1, condition 2-2-1) (condition 1-1-2, condition 1-2-2, condition 1-3-2, condition 2-1-2, condition The operation is controlled according to 2-2-2).

  As shown in FIG. 8A and FIG. 8B, when executing the hydrogen external supply mode, if there is power usage of the load unit 3 (condition 1-1-1 to condition 1-3-3), renewable energy Electric power E10a, E60, E2 is supplied to the load unit 3 from at least one of the power generation device 10, the fuel cell power generation device 60, and the power system 2. Here, the power E10a generated by the renewable energy power generation device 10 is supplied to the load unit 3 with priority over the power E2 of the power system 2 and the power E60 generated by the fuel cell power generation device 60. On the other hand, when there is no power usage of the load unit 3 (conditions 2-1-1 to 2-3), of course, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The power E10a, E60, E2 is not supplied to the load unit 3 from each of the above.

  Further, when the hydrogen external supply mode is executed, the amount of power generated by the renewable energy power generation device 10 (= P10) exceeds zero (P10> 0), and the hydrogen storage device 50 has a vacancy in hydrogen storage. Case (condition 1-1-2, condition 1-1-3, condition 1-2-2, condition 1-2-3, condition 2-1-2, condition 2-1-3, condition 2-2-2 , Condition 2-2-3), electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. At the same time, when the power generation amount (= P10) of the renewable energy power generation apparatus 10 is smaller than the electrolytic power amount (= Cy) of the hydrogen generation apparatus 40 (P10 <Cy), the power system 2 transfers to the hydrogen generation apparatus 40. Supply power. As a result, hydrogen H40 is generated in the hydrogen generator 40, and the hydrogen H40 generated in the hydrogen generator 40 is stored in the hydrogen storage device 50.

  Further, when the hydrogen external supply mode is executed, when there is power generation by the renewable energy power generation apparatus 10 and there is a surplus in the power generation amount (= P10) of the renewable energy power generation apparatus 10 (P10> 0, Condition 1-1-1 to Condition 1-2-1, Condition 2-1-1 to Condition 2-2-1), and output of electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2 To sell electricity.

  When executing the hydrogen external supply mode, hydrogen H50a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4 regardless of the conditions (conditions 1-1-1 to 2-3).

  In the case of the hydrogen external supply mode, specific contents of operations performed in accordance with each condition (conditions 1-1-1 to 2-3) will be sequentially described.

[B-4-1] Condition 1-1-1
First, the operation in the case of condition 1-1-1 will be described. That is, there is power usage of the load unit 3 (D3> 0), and the power generation amount (= P10) of the renewable energy power generation device 10 is equal to or greater than the electrolytic power amount (= Cy) of the hydrogen storage device 50 (P10 ≧ Cy). The operation under the condition when the hydrogen storage device 50 has no space for hydrogen storage (S50 = Smax) will be described.

  In the case of the condition 1-1-1, electric power E10a and E60 are supplied from the renewable energy power generation device 10 and the fuel cell power generation device 60 to the load unit 3. At this time, electric power E2 is further supplied from the electric power system 2 to the load unit 3 as necessary. Here, when the total amount of the power generation amount of the renewable energy power generation device 10 and the power generation amount of the fuel cell power generation device 60 is smaller than the power consumption amount of the load unit 3, the power is further supplied from the power system 2 to the load unit 3. E2 is supplied.

  In the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the electric power system 2 to the hydrogen generation apparatus 40, respectively. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-1-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-2] Condition 1-1-2
An operation in the case of the condition 1-1-2 will be described. That is, the operation under the same conditions as in the case of the above conditions 1-1-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-1-2, the electric power E10a is supplied from the renewable energy power generation device 10 to the load unit 3, but unlike the case of the condition 1-1-1, the fuel cell power generation device 60 supplies the load unit 3. The electric power E60 is not supplied. At this time, electric power E2 is further supplied from the electric power system 2 to the load unit 3 as necessary.

  In the case of the condition 1-1-2, unlike the case of the condition 1-1-1, electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied to the hydrogen generator 40 is the same as the electrolytic power amount (= Cy) (D40a = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40. The electric power E2 is not supplied from the electric power system 2 to the hydrogen generator 40. That is, the power supply amount (= D40b) of the power E2 supplied from the power system 2 to the hydrogen generator 40 is zero (D40b = 0). For this reason, all the electric power supply amounts (= D40) supplied to the hydrogen generator 40 are the same as the electrolytic power amount (= Cy) (D40 = D40a + D40b = Cy).

  In the case of the condition 1-1-2, similarly to the case of the condition 1-1-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-3] Condition 1-1-3
An operation in the case of condition 1-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 1-1-1 and 1-1-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-1-3, as in the case of the condition 1-1-2, the electric power E10a is supplied from the renewable energy power generation device 10 to the load unit 3, but from the fuel cell power generation device 60 to the load unit 3 Electric power E60 is not supplied. At this time, electric power E2 is further supplied from the electric power system 2 to the load unit 3 as necessary.

  In the case of the condition 1-1-3, similarly to the case of the condition 1-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied to the hydrogen generator 40 is the same as the electrolytic power amount (= Cy) (D40a = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-1-3, as in the case of the condition 1-1-1 and the condition 1-1-2, by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2 , Sell electricity. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-4] Condition 1-2-1
An operation in the case of condition 1-2-1 will be described. That is, in the case of the above condition 1-1-1, except that the power generation amount (= P10) of the renewable energy power generation device 10 is smaller than the electrolytic power amount (= Cy) of the hydrogen storage device 50 (P10 <Cy) The operation under the same conditions as will be described.

  In the case of the condition 1-2-1, unlike the case of the condition 1-1-1, the electric power E2 is supplied from the power system 2 to the load unit 3. Moreover, the electric power E60 is supplied to the load part 3 from the fuel cell power generation device 60 as needed. For example, the electric power E <b> 2 a introduced from the electric power system 3 is reduced, and the electric power E <b> 60 is supplied from the fuel cell power generator 60 to the load unit 3 so as to secure the amount of hydrogen supplied to the fuel cell automobile 4. Here, the electric power E10a is not supplied from the renewable energy power generation apparatus 10 to the load unit 3 (E10a = 0).

  In the case of the condition 1-2-1, similarly to the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-2-1, as in the case of the condition 1-1-1, power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-5] Condition 1-2-2
An operation in the case of condition 1-2-2 will be described. That is, the operation under the same conditions as in the case of the above condition 1-2-1 will be described except that the hydrogen storage device 50 has an empty space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-2-2, the electric power E2 is supplied from the power system 2 to the load unit 3 as in the case of the condition 1-2-1. Here, the electric power E10a, E60 is not supplied from the renewable energy power generation apparatus 10 and the fuel cell power generation apparatus 60 to the load unit 3.

  In the case of the condition 1-2-2, unlike the case of the condition 1-2-1, electric power E10b, E2 is supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied from the renewable energy power generation device 10 to the hydrogen generation device 40 is the same as the power generation amount (= P10) of the renewable energy power generation device 10 (D40a = P10). The power supply amount (= D40b) supplied from the power system 2 to the hydrogen generator 40 is the same as the amount of power generation (= P10) of the renewable energy power generation device 10 minus the amount of electrolytic power (= Cy). Yes (D40b = P10-Cy). For this reason, all the electric power supply amounts (= D40) supplied to the hydrogen generator 40 are the same as the electrolytic power amount (= Cy) (D40 = D40a + D40b = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-2-2, unlike the case of the condition 1-2-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-6] Condition 1-2-3
An operation in the case of condition 1-2-3 will be described. That is, the operation under the same conditions as in the above conditions 1-2-1 and 1-2-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-2-3, the electric power E2 is supplied from the power system 2 to the load unit 3 as in the case of the condition 1-2-2. Here, the electric power E10a, E60 is not supplied from the renewable energy power generation apparatus 10 and the fuel cell power generation apparatus 60 to the load unit 3.

  In the case of the condition 1-2-3, similarly to the case of the condition 1-2-2, the electric power E10b and E2 are supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied from the renewable energy power generation device 10 to the hydrogen generation device 40 is the same as the power generation amount (= P10) of the renewable energy power generation device 10 (D40a = P10). The power supply amount (= D40b) supplied from the power system 2 to the hydrogen generator 40 is the same as the amount of power generation (= P10) of the renewable energy power generation device 10 minus the amount of electrolytic power (= Cy). Yes (D40b = P10-Cy). For this reason, all the electric power supply amounts (= D40) supplied to the hydrogen generator 40 are the same as the electrolytic power amount (= Cy) (D40 = D40a + D40b = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 1-2-3, as in the case of the condition 1-2-2, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-7] Condition 1-3-1
An operation in the case of the condition 1-3-1 will be described. That is, the operation under the same conditions as in the case of the above condition 1-1-1 will be described except that the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0).

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, the power E10a, the fuel E10a, E60 and E2 are not supplied. Here, electric power E <b> 2 is supplied from the electric power system 2 to the load unit 3.

  In the case of the condition 1-3-1, similarly to the case of the condition 1-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-1, unlike the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-8] Condition 1-3-2
An operation in the case of condition 1-3-2 will be described. That is, the operation under the same condition as in the case of the above condition 1-3-1 will be described except that the hydrogen storage device 50 has a free space for hydrogen storage (S50 <Smax).

  In the case of the condition 1-3-2, as in the case of the condition 1-3-1, the electric power E10a is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. , E60, E2 are not supplied. Here, electric power E <b> 2 is supplied from the electric power system 2 to the load unit 3.

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-2, similarly to the case of the condition 1-3-1, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-9] Condition 1-3-3
An operation in the case of condition 1-3-3 will be described. That is, the operation under the same conditions as in the above conditions 1-3-1 and 1-3-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, from each of the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2. The power E10a, E60, E2 is not supplied to the load unit 3. Here, electric power E <b> 2 is supplied from the electric power system 2 to the load unit 3.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the renewable energy power generation device 10 and the power system 2 are respectively transferred to the hydrogen generator 40. Electric power E10b and E2a are not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 1-3-3, as in the case of the condition 1-3-1 and the condition 1-3-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-10] Condition 2-1-1
An operation in the case of condition 2-1-1 will be described. That is, the operation under the same condition as in the case of the above condition 1-1-1 will be described except that the load unit 3 does not use power (D3 = 0).

  In the case of the condition 2-1-1, unlike the case of the condition 1-1-1, the power is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. E10a, E60, and E2 are not supplied.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the electric power E10b and E2a are not supplied to the hydrogen generator 40 from each of the renewable energy power generation apparatus 10 and the power system 2. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-1-1, as in the case of the condition 1-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

[B-4-11] Condition 2-1-2
The operation in the case of condition 2-1-2 will be described. That is, the operation under the same conditions as in the case of the above condition 2-1-1 will be described except that the hydrogen storage device 50 has a vacancy (S50 <Smax).

  In the case of the condition 2-1-2, as in the case of the condition 2-1-1, the electric power E10a is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. , E60, E2 are not supplied.

  In the case of the condition 2-1-2, unlike the case of the condition 2-1-1, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied to the hydrogen generator 40 is the same as the electrolytic power amount (= Cy) (D40a = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40. The electric power E2 is not supplied from the electric power system 2 to the hydrogen generator 40. That is, the power supply amount (= D40b) of the power E2 supplied from the power system 2 to the hydrogen generator 40 is zero (D40b = 0). For this reason, all the electric power supply amounts (= D40) supplied to the hydrogen generator 40 are the same as the electrolytic power amount (= Cy) (D40 = D40a + D40b = Cy).

  In the case of the condition 2-1-2, as in the case of the condition 2-1-1, the power E10c generated by the renewable energy power generation apparatus 10 is output to the power system 2 to sell power. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-12] Condition 2-1-3
An operation in the case of condition 2-1-3 will be described. That is, the operation under the same conditions as those of the above conditions 2-1-1 and 2-2-1 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 2-1-3, as in the case of the condition 2-1-1 and the condition 2-1-2, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The electric power E10a, E60, E2 is not supplied to the load part 3 from each.

  In the case of the condition 2-1-3, similarly to the case of the condition 2-1-2, the electric power E10b is supplied from the renewable energy power generation apparatus 10 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied to the hydrogen generator 40 is the same as the electrolytic power amount (= Cy) (D40a = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40. The electric power E2 is not supplied from the electric power system 2 to the hydrogen generator 40.

  In the case of the condition 2-1-3, as in the case of the condition 2-1-1 and the condition 2-1-2, by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the power system 2 , Sell electricity. Here, the power sale amount (= S2) becomes the power sale limit amount (= Cx) (S2 = Cx).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-13] Condition 2-2-1
An operation in the case of condition 2-2-1 will be described. In other words, except for the point (P10 <Cy) where the power generation amount (= P10) of the renewable energy power generation device 10 is smaller than the electrolytic power amount (= Cy) of the hydrogen storage device 50, in the case of the above condition 2-1-1 The operation under the same conditions as will be described.

  In the case of the condition 2-2-1, as in the case of the above condition 2-1-1, from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. Electric power E10a, E60, E2 is not supplied.

  In the case of the condition 2-2-1, similarly to the case of the condition 2-1-1, the electric power E10b and E2a are not supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40, respectively. . That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-1-1, as in the case of the condition 2-1-1, the electric power is sold by outputting the electric power E10c generated by the renewable energy power generation apparatus 10 to the electric power system 2. Here, the power sale amount (= S2) becomes the power generation amount (= P10) of the renewable energy power generation apparatus 10 (S2 = P10).

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-14] Condition 2-2-2
An operation in the case of condition 2-2-2 will be described. That is, the operation under the same conditions as in the case of the above condition 2-2-1 will be described, except that the hydrogen storage device 50 has a vacancy (S50 <Smax).

  In the case of the condition 2-2-2, as in the case of the condition 2-2-1, the electric power E10a is supplied from the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 to the load unit 3. , E60, E2 are not supplied.

  In the case of the condition 2-2-2, unlike the case of the condition 2-2-1, the electric power E10b, E2 is supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied from the renewable energy power generation device 10 to the hydrogen generation device 40 is the same as the power generation amount (= P10) of the renewable energy power generation device 10 (D40a = P10). The power supply amount (= D40b) supplied from the power system 2 to the hydrogen generator 40 is the same as the amount of power generation (= P10) of the renewable energy power generation device 10 minus the amount of electrolytic power (= Cy). Yes (D40b = P10-Cy). For this reason, all the electric power supply amounts (= D40) supplied to the hydrogen generator 40 are the same as the electrolytic power amount (= Cy) (D40 = D40a + D40b = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 2-2-2, unlike the case of the condition 2-2-1, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2. That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-15] Condition 2-2-3
The operation in the case of condition 2-2-3 will be described. That is, the operation under the same conditions as those in the above conditions 2-2-1 and 2-2-2 will be described except that the hydrogen storage device 50 does not store hydrogen (S50 = 0).

  In the case of the condition 2-2-3, as in the case of the condition 2-2-1 and the condition 2-2-2, the renewable energy power generation device 10, the fuel cell power generation device 60, and the power system 2 The electric power E10a, E60, E2 is not supplied to the load part 3 from each.

  In the case of the condition 2-2-3, similarly to the case of the condition 2-2-2, the electric power E10b and E2 are supplied from the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40. Here, the power supply amount (= D40a) supplied from the renewable energy power generation device 10 to the hydrogen generation device 40 is the same as the power generation amount (= P10) of the renewable energy power generation device 10 (D40a = P10). The power supply amount (= D40b) supplied from the power system 2 to the hydrogen generator 40 is the same as the amount of power generation (= P10) of the renewable energy power generation device 10 minus the amount of electrolytic power (= Cy). Yes (D40b = P10-Cy). For this reason, all the electric power supply amounts (= D40) supplied to the hydrogen generator 40 are the same as the electrolytic power amount (= Cy) (D40 = D40a + D40b = Cy). Thereby, in the hydrogen generator 40, the hydrogen H40 is produced | generated and the hydrogen storage device 50 stores the produced | generated hydrogen H40.

  In the case of the condition 2-2-3, as in the case of the condition 2-2-2, the power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-4-16] Condition 2-3
An operation in the case of Condition 2-3 will be described. That is, except for the point (P10 = 0) where the amount of power generation (= P10) of the renewable energy power generation apparatus 10 is zero (P10 = 0), the above condition 2-1-1 to the condition 2-1-3 and the condition 2-2 The operation under the same conditions as in the case of -1 to Condition 2-2-3 will be described.

  In the case of the condition 2-3, the renewable energy power generation apparatus 10 is the same as the case of the condition 2-1-1 to the condition 2-1-3 and the condition 2-2-1 to the condition 2-2-3. In addition, the electric power E10a, E60, E2 is not supplied to the load unit 3 from each of the fuel cell power generator 60 and the power system 2.

  In the case of the condition 2-3, as in the case of the condition 2-1-1 and the condition 2-2-1, the electric power E10b is supplied from each of the renewable energy power generation apparatus 10 and the power system 2 to the hydrogen generation apparatus 40. , E2a is not supplied. That is, the hydrogen generator 40 does not generate hydrogen H40.

  In the case of the condition 2-3, as in the case of the condition 2-2-1 and the condition 2-2-3, the electric power E10c generated by the renewable energy power generation apparatus 10 is not output to the power system 2 (E10c = 0) ). That is, no power is sold.

  As described above, the hydrogen H 50 a is supplied from the hydrogen storage device 50 to the fuel cell vehicle 4.

[B-5] Hydrogen Storage Mode As described above, the hydrogen storage mode is an operation mode for controlling the operation of the power supply system 1 so that the amount of hydrogen stored in the hydrogen storage device 50 reaches the target amount. . For example, when the time point before the event is input as the target time point and the maximum storage amount Smax is set as the target amount, the control device 70 stores hydrogen at the time point before the event is performed. Control is performed so that the amount becomes the maximum storage amount Smax.

  As shown in FIGS. 9A and 9B, when the hydrogen storage mode is executed, the power usage status of the load unit 3 and the power generation status of the renewable energy power generation apparatus 10 are the same as in the hydrogen external supply mode. And the control apparatus 70 controls operation | movement of each part according to each of the hydrogen storage condition of the hydrogen storage apparatus 50. FIG.

  As can be seen by comparing FIGS. 8A and 8B with FIGS. 9A and 9B, in the hydrogen external supply mode, the hydrogen storage device 50 can be used regardless of the conditions (conditions 1-1-1 to 2-3). However, in the hydrogen storage mode, the hydrogen H50a is not supplied from the hydrogen storage device 50 to the fuel cell vehicle 4. Except for this point, in the hydrogen storage mode, each part is controlled as in the case of the hydrogen external supply mode.

  By executing the hydrogen storage mode, the hydrogen storage amount stored in the hydrogen storage device 50 is set to the target amount (for example, the maximum storage amount Smax) at the target time point (for example, the time point before the start time of the event). To do.

  After execution of the hydrogen storage mode, for example, when an event is performed, the fuel cell power generation device 60 generates power using the hydrogen H50 stored in the hydrogen storage device 50 in the hydrogen storage mode, and the power generation The generated electric power E60 is output to the load unit 3.

  In this embodiment, after executing the hydrogen storage mode, control is performed so as to execute one of the internal load mode and the self-sustaining operation mode. For example, one of the internal load mode and the independent operation mode is selected and executed according to an operation signal input by the operator. When one of the internal load mode and the self-sustained operation mode is executed, the fuel cell power generator 60 generates power as necessary, and the power E60 generated by the power generation is output to the load unit 3.

  After executing the hydrogen storage mode, one of the internal load mode and the self-sustaining operation mode is automatically executed. For example, the operator inputs the date and time when the event is performed, and the control device 70 controls the operation of each unit so as to execute one of the internal load mode and the independent operation mode in accordance with the input date and time. . In addition to this, after the hydrogen storage mode is executed, one of the internal load mode and the self-sustaining operation mode may be executed in accordance with an operation signal input by the operator.

[C] Summary As described above, in the power supply system 1 of the present embodiment, by executing the hydrogen storage mode, the power supply system so that the amount of hydrogen stored in the hydrogen storage device 50 reaches the target amount. The operation of 1 is controlled. For this reason, in this embodiment, it is possible to easily avoid a state in which the amount of stored hydrogen is insufficient when necessary.

  In the present embodiment, when an operation command for performing the hydrogen storage mode is input, the operation of the power supply system 1 is performed so that the amount of hydrogen stored in the hydrogen storage device 50 reaches the above target amount at the target time point. Control. For this reason, in the present embodiment, for example, when a large amount of electric power is required, such as when an event is performed, the hydrogen storage amount is sufficient, and the electric power is stably supplied from the fuel cell power generation device 60. Can do. That is, in the present embodiment, since the hydrogen storage mode is set, it is possible to respond to a request “I want to store hydrogen in preparation for an event that requires a lot of power”. As a result, the power supply system 1 of the present embodiment can easily realize the stable supply of power.

  In the power supply system 1 of the present embodiment, an internal load mode, a power sale mode, a self-sustaining operation mode, a hydrogen external supply mode, and a hydrogen storage mode are set as operation modes. The selected operation mode can be executed. Therefore, in the present embodiment, it is possible to easily supply power stably according to the situation. Specifically, in this embodiment, since the hydrogen external supply mode is set, it is possible to meet the demand for preferentially producing and storing hydrogen in order to supply to the outside. In addition, since the power sale mode is set, it is possible to respond to a request to increase the income from power sale. Further, since the internal load mode is set, it is possible to respond to a request to supply the power E10a and E60 of the power supply system 1 to the load unit 3 with priority over the power E2 of the power system 2. In addition, since the self-sustained operation mode is set, for example, power is supplied to the load unit 3 when the power E2 of the power system 2 is not supplied as in the case of an abnormality (such as a disaster) or when installed on an isolated island. Can respond to the request to supply.

  In the power supply system 1 of the present embodiment, each of the hydrogen generator 40, the hydrogen storage device 50, and the fuel cell power generator 60 is individually packaged and can be transported. For this reason, for example, at the time of a disaster, the power supply system 1 can be quickly installed in the disaster area.

[D] Modified Example In the above-described embodiment, the power supply system 1 supplies the DC power (= E10b) to the hydrogen generator while the DC power output from the renewable energy power generator 10 is adjusted by the converter. It may be configured to be.

  In the above-described embodiment, the power supply system 1 is configured so that the hydrogen generator 40 is operated using the electric power generated using the renewable energy in the renewable energy power generation apparatus 10 that is already installed. It may be configured.

  In said embodiment, although the renewable energy electric power generating apparatus 10 demonstrated the case where it was a solar power generation device, it is not restricted to this. The renewable energy power generation apparatus 10 may be a power generation apparatus that generates power using other renewable energy such as wind power, solar heat, geothermal heat, and biomass in addition to sunlight.

  In the above embodiment, the case where the water electrolysis apparatus 401 of the hydrogen generation apparatus 40 generates hydrogen by solid polymer (PEM) water electrolysis has been described, but the present invention is not limited thereto. The water electrolysis apparatus 401 may be configured to generate hydrogen by alkaline water electrolysis or high temperature steam electrolysis by SOEC (Solid Oxide Electrolysis Cell).

  In the above embodiment, the hydrogen generation device 40 has been described with respect to the case where hydrogen is generated by electrolysis of water, but the present invention is not limited thereto. The hydrogen generator 40 may be configured to generate hydrogen by causing a dehydrogenation reaction with respect to the organic hydride. The hydrogen generator 40 may be configured to generate hydrogen by catalytic reaction, photocatalysis, or thermal decomposition.

  In the above embodiment, the case where the power supply system 1 includes the renewable energy power generation apparatus 10 has been described, but the present invention is not limited thereto. The renewable energy power generation apparatus 10 may not be provided. In this case, the hydrogen generator 40 generates hydrogen using the power supplied from the external power system 2.

  In the above embodiment, the case where the hydrogen storage device 50 includes the hydrogen storage tank 501 has been described, but is not limited thereto. The hydrogen storage device 50 may be configured to store hydrogen using a hydrogen storage alloy.

  In the above embodiment, the power supply system 1 is connected to the power system 2 (commercial power supply) and is configured to be supplied with power from the power system 2, but is not limited thereto. The power supply system 1 may not be supplied with power from the power system 2.

  In said embodiment, although the electric power supply system 1 demonstrated the case where each of the hydrogen generator 40, the hydrogen storage apparatus 50, and the fuel cell power generation apparatus 60 was individually packaged, it is not restricted to this. . Each may not be packaged. In addition, for example, the renewable energy power generation apparatus 10 may be transportable by installing the renewable energy power generation apparatus 10 (solar power generation (PV) apparatus) on a container (200, 400, 600, etc.). .

  The power supply system 1 of the present embodiment includes a plurality of hydrogen generators 40 as necessary, and each of the plurality of hydrogen generators 40 is configured to supply hydrogen to the hydrogen storage device 50. Also good. Thereby, the generation amount of hydrogen can be increased.

  The power supply system 1 of the present embodiment includes a plurality of hydrogen storage devices 50 as necessary, and each of the plurality of hydrogen storage devices 50 stores the hydrogen supplied from the hydrogen generation device 40, and The stored hydrogen may be configured to be supplied to the fuel cell power generator 60. Thereby, the storage amount of hydrogen can be increased.

  The power supply system 1 of the present embodiment includes a plurality of fuel cell power generation devices 60 as necessary, and each of the plurality of fuel cell power generation devices 60 is configured to supply power and hot water to the load unit 3. May be. Thereby, the electric power generation amount can be increased.

  The power supply system 1 of the present embodiment may be configured to include a storage battery (not shown). In this case, the storage battery stores the power generated by the renewable energy power generation device 10 and supplies the stored power to the load unit 3. At the same time, the storage battery stores the power generated by the fuel cell power generation device 60 and supplies the stored power to the load unit 3. Thereby, electric power can be supplied more stably.

  The power supply system 1 of the present embodiment may be configured to include a water storage device (not shown). In this case, the water storage device has, for example, a water supply tank (not shown), stores the water supplied via the water supply in the water supply tank, and supplies the stored water to the hydrogen generator 40. Thereby, as needed, water is supplied to the hydrogen generator 40 from the water storage device, and hydrogen can be generated. At the same time, the water storage device may be configured to supply the stored water to the fuel cell power generation device 60. Thereby, the water W60 heated in the fuel cell power generator 60 is stably supplied to the load section 3.

  The power supply system 1 of the present embodiment is configured such that the control device 70 controls the supply amount of the water W60 heated by the fuel cell power generation device 60 in accordance with the amount of hot water used in the load unit 3. It may be. In this case, the controller 70 is heated when the amount of hot water supplied by the water W60 heated and supplied by the fuel cell power generator 60 is larger than the amount of hot water used by the load unit 3. The water W60 is returned to the water storage device. For this reason, in this embodiment, water can be effectively secured in the water storage device.

  In the power supply system 1 of the present embodiment, the case where hydrogen is supplied to the fuel cell vehicle 4 when executing the hydrogen external supply mode has been described, but the present invention is not limited thereto. Naturally, hydrogen may be supplied to the fuel cell vehicle 4 when the hydrogen external supply mode is not executed. At this time, the hydrogen generator 40 need not be driven.

  According to at least one embodiment described above, there is provided a power supply system capable of sufficiently supplying hydrogen when necessary, and capable of generating power with a fuel cell power generator as necessary. Can be provided.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Electric power supply system, 2 ... Electric power system, 3 ... Load part, 4 ... Fuel cell vehicle, 10 ... Renewable energy power generator, 40 ... Hydrogen generator, 50 ... Hydrogen storage apparatus, 60 ... Fuel cell power generator, 70 DESCRIPTION OF SYMBOLS ... Control apparatus, 400 ... Container, 401 ... Water electrolysis apparatus, 401a ... Pure water manufacturing apparatus, 402 ... Compressor, 403 ... Chiller unit, 500 ... Container, 501 ... Hydrogen storage tank, 502 ... Solenoid valve, 600 ... Container, 601 ... Fuel cell, 602 ... Inverter, 603 ... Hot water storage tank

Claims (6)

A power supply system for supplying power to a load unit,
A hydrogen generator that generates hydrogen using electric power generated by using renewable energy and / or electric power supplied from an external power system ;
A hydrogen storage device for storing hydrogen generated by the hydrogen generator;
A fuel cell power generator that generates power using hydrogen stored in the hydrogen storage device and outputs the power generated by the power generation to the load unit;
A control device for controlling the operation of the power supply system,
The control device includes:
In the hydrogen storage mode in which the operation of the hydrogen generator is controlled so that the amount of hydrogen stored in the hydrogen storage device reaches the target amount at a target time, the power consumed by the load unit uses the renewable energy. Power supplied from the power system is supplied to the load unit, and power generated using the renewable energy and power supplied from the power system A power supply system that controls the operation of the hydrogen generator so that the amount of hydrogen stored in the hydrogen storage device reaches a target amount at a target time point by generating hydrogen using both or one of the above . Having a renewable energy power generation device that generates electric power using the renewable energy,
The control device, the power sale mode, the renewable energy power generated by the power generating device to preferentially output to the outside of the electric power system, controls the operation of the power supply system, according to claim 1 Power supply system. Having a renewable energy power generation device that generates electric power using the renewable energy,
In the internal load mode, the control device uses the power generated by the renewable energy power generation device based on the amount of power used by the load unit, the power supplied from an external power system, and the fuel to supply to the load section by preferentially than the electric power generated by the cell generator, for controlling the operation of the power supply system, the power supply system according to claim 1. Having a renewable energy power generation device that generates electric power using the renewable energy,
In the self-sustained operation mode, the control device does not receive power supply from an external power system, and outputs the power generated by the renewable energy power generation device with priority to the load unit. It controls the operation of the power supply system, the power supply system according to claim 1. Having a renewable energy power generation device that generates electric power using the renewable energy,
In the hydrogen external supply mode in which hydrogen is supplied from the hydrogen storage device to an external hydrogen using device, the control device supplies power generated by the renewable energy power generation device preferentially to the hydrogen generation device. It controls the operation of the power supply system, the power supply system according to claim 1. Hydrogen generator that generates hydrogen using electric power generated using renewable energy and / or electric power supplied from an external power system, and hydrogen that stores hydrogen generated by the hydrogen generator A control method for a power supply system comprising: a storage device; and a fuel cell power generation device that generates power using hydrogen stored in the hydrogen storage device and outputs power generated by the power generation to a load unit,
In the hydrogen storage mode in which the operation of the hydrogen generator is controlled so that the amount of hydrogen stored in the hydrogen storage device reaches the target amount at a target time, the power consumed by the load unit uses the renewable energy. Power supplied from the power system is supplied to the load unit, and power generated using the renewable energy and power supplied from the power system A method for controlling an electric power supply system , wherein the operation of the hydrogen generator is controlled so that the amount of hydrogen stored in the hydrogen storage device reaches a target amount at a target time by generating hydrogen using either or both of the above .

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