JP2014007062A - Secondary battery type fuel cell system and power feeding system provided therewith - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a secondary battery type fuel cell system capable of being efficiently charged.SOLUTION: The secondary battery type fuel cell system comprises: a fuel generation unit capable of discharging a fuel gas by chemical reaction and reproducible by the reverse reaction of the chemical reaction by which the fuel gas is generated; a power generation and electrolysis unit having a power generation function for generating power by using the fuel gas supplied from the fuel generation unit and an electrolysis function for electrolyzing the product of the reverse reaction supplied from the fuel generation unit at the time of regeneration by the fuel generation unit; a power detection unit for detecting the power supplied to the power generation and electrolysis unit at the time of regeneration by the fuel generation unit; a heater unit for heating a section of the power generation and electrolysis unit in which electrolysis is performed; and a control unit for controlling the power supplied to the heater unit on the basis of the result of detection by the power detection unit.

Description

  The present invention relates to a secondary battery type fuel cell system capable of performing not only a power generation operation but also a charging operation, and a power supply system including the same.

  In recent years, as multi-functional and high-performance portable electronic devices such as mobile phones, portable information terminals, notebook personal computers, portable audio devices, and portable visual devices have advanced, the capacity of the drive batteries has increased. There is an increasing demand for conversion. Conventionally, lithium batteries and nickel-cadmium batteries have been used as driving batteries for such portable electronic devices, but their capacities are approaching their limits and cannot be expected to increase dramatically. Therefore, fuel cells having high energy density and high capacity are being actively developed in place of lithium batteries and nickel-cadmium batteries.

  Fuel cells take out electric power when water is generated from hydrogen and oxygen, and in principle, the efficiency of electric power energy that can be taken out is high, which not only saves energy, but also produces only water during power generation. Therefore, it is an environmentally friendly power generation method and is expected as a trump card for solving global energy and environmental problems.

  Such fuel cells include, for example, a solid polymer electrolyte membrane using a solid polymer ion exchange membrane, a solid oxide electrolyte membrane using yttria-stabilized zirconia (YSZ), and the like as a fuel electrode (anode) and an oxidizer electrode ( One cell structure is sandwiched between both sides of the cathode). In the cell having such a configuration, a fuel gas flow path for supplying a fuel gas (for example, hydrogen gas) to the fuel electrode, and an oxidant gas flow for supplying an oxidant gas (for example, oxygen or air) to the oxidant electrode. The fuel gas and the oxidant gas are supplied to the fuel electrode and the oxidant electrode through these flow paths, respectively, and electricity is generated.

  However, in a fuel cell device to which fuel is supplied from the outside, infrastructure for supplying fuel (for example, hydrogen) is required.

Japanese Patent Laying-Open No. 2004-359536 (FIG. 2B)

  Therefore, in order to cope with such a problem, it is conceivable to use, as a hydrogen supply source, a metal that decomposes water and generates hydrogen. The metal (high valent metal oxide) that has been oxidized by generating hydrogen can be used again as a hydrogen supply source by reducing it to a pure metal or a low valent metal oxide.

  Patent Document 1 describes that water is removed by cooling a mixed gas of water vapor and hydrogen that is generated when a metal oxide is reduced with hydrogen gas. There is no description, and reduction efficiency is not considered.

  An object of this invention is to provide the secondary battery type fuel cell system which can be charged efficiently in view of said situation, and an electric power feeding system provided with the same.

  In order to achieve the above object, a secondary battery type fuel cell system according to the present invention can release a fuel gas by a chemical reaction, and can generate a renewable fuel by a reverse reaction of the chemical reaction to generate the fuel gas. And electrolysis that electrolyzes the product of the reverse reaction supplied from the fuel generator during regeneration of the fuel generator and the power generation function that generates power using the fuel gas supplied from the fuel generator A power generation / electrolysis unit having a function, circulates a gas containing the fuel gas between the fuel generation unit and the power generation / electrolysis unit, and at the time of regeneration of the fuel generation unit, A secondary battery type fuel cell system in which power is supplied to the decomposition unit from the outside, and a power detection unit that detects power supplied to the power generation / electrolysis unit during regeneration of the fuel generation unit; A configuration including a heater unit for heating a portion of the power generation / electrolysis unit that performs electrolysis, and a control unit that controls electric power supplied to the heater unit based on a detection result of the power detection unit; To do. Note that the power generation / electrolysis unit includes, for example, a power generation operation that generates power using the fuel gas supplied from the fuel generation unit, and the reverse supplied from the fuel generation unit during regeneration of the fuel generation unit. The fuel cell may be configured to switch between an electrolysis operation for electrolyzing a reaction product, and, for example, a fuel cell that generates power using the fuel gas supplied from the fuel generation unit; A configuration may be provided separately with an electrolyzer that electrolyzes the product of the reverse reaction supplied from the fuel generator during regeneration of the fuel generator.

  According to such a configuration, an increase in the ratio of the power consumption of the heater unit to the power consumed by the electrolysis reaction itself of the power generation / electrolysis unit can be suppressed by fluctuations in the power supplied to the heater unit. So it can be charged efficiently.

  A determination unit that determines whether or not the temperature of the electrolysis portion of the power generation / electrolysis unit is equal to or higher than a predetermined value; and a determination result by the determination unit is NO, the fuel generation unit It is desirable to provide a playback stop unit that stops playback.

  According to such a configuration, it is possible to reliably prevent the ratio of the power consumption of the heater unit to the power consumed by the electrolysis reaction itself of the power generation / electrolysis unit from exceeding an arbitrarily set upper limit value.

  Furthermore, when the regeneration stop unit stops regeneration of the fuel generation unit, the power supplied to the power generation / electrolysis unit is supplied to the battery for supplying power to the heater unit. A switch for switching may be provided.

  In order to achieve the above object, a power feeding system according to the present invention includes a secondary battery type fuel cell system having any one of the above-described configurations, power generation using natural energy, and the secondary battery type fuel cell system. And a power generation facility for supplying electric power to the power generation / electrolysis unit when the fuel generation unit is regenerated.

  According to the secondary battery type fuel cell system and the power supply system including the same according to the present invention, the ratio of the power consumption of the heater unit to the power consumed by the electrolysis reaction of the power generation / electrolysis unit itself increases. Since it can suppress by the fluctuation | variation of the electric power supplied to a heater part, it can charge efficiently.

1 is a diagram illustrating a schematic configuration of a power feeding system according to an embodiment of the present invention. It is a schematic diagram which shows the connection relationship of the solid oxide fuel cell and external load at the time of electric power generation operation | movement of a secondary battery type fuel cell system. It is a schematic diagram which shows the connection relationship of the solid oxide fuel cell and external power supply at the time of charge operation of a secondary battery type fuel cell system. It is a figure which shows the time change example of the electric power supplied to a fuel cell part from a solar power generation facility, and the electric power supplied to a heater part from a battery. It is a figure which shows the relationship between the electric power supplied to a heater part from a battery, and the temperature of a heater part. It is a figure which shows the electric current-voltage characteristic of the fuel cell part when performing electrolysis. It is a figure which shows the relationship between the temperature of a fuel cell part, and electric power loss. It is a figure which shows the time change example of the electric power supplied to the fuel cell part from a solar power generation facility, the electric power supplied to a heater part from a battery, and the electric power consumed by the electrolysis reaction of a fuel cell part itself. It is a flowchart which shows the control which a system controller performs at the time of charge of a secondary battery type fuel cell system.

  Embodiments of the present invention will be described below with reference to the drawings. In addition, this invention is not restricted to embodiment mentioned later.

  FIG. 1 shows a schematic configuration of a power supply system according to an embodiment of the present invention. The power supply system according to the present embodiment includes the secondary battery type fuel cell system according to the present embodiment, and a solar power generation facility 100 that generates power using solar energy, and to an external load (not shown). Is supplied by either the secondary battery type fuel cell system or the photovoltaic power generation facility 100 according to the present embodiment. The secondary battery type fuel cell system according to this embodiment generates a fuel gas by an oxidation reaction and can be regenerated by a reduction reaction, an oxidant containing oxygen, and a fuel supplied from the fuel generation unit 1 A fuel cell unit 2 for generating power by reaction with gas, a heater unit 3 for heating the fuel cell unit 2, a temperature sensor 4 for detecting the temperature of the fuel cell unit 2, and a container for housing the fuel generation unit 1 5, a container 6 that accommodates the fuel cell unit 2, the heater unit 3, and the temperature sensor 4, a pipe 7 for circulating a gas containing fuel gas between the fuel generation unit 1 and the fuel cell unit 2, A power detection unit 8 for detecting power supplied to the fuel cell unit 2 during charging of the secondary battery type fuel cell system; and a battery 9 such as a lithium ion secondary battery or a lead storage battery for supplying power to the heater unit 3; , Heater part from battery 9 The battery output detection unit 10 for detecting the power supplied to the solar cell, the switch 11 for switching the connection state between the photovoltaic power generation equipment 100, the fuel cell unit 2 and the battery 9, and the entire secondary battery type fuel cell system are controlled. And a system controller 12 such as a microcomputer. If necessary, the pipe 7 may be provided with a circulator such as a blower or a pump, or may be provided with a heater for adjusting the temperature around the fuel generating unit 1. Further, in this embodiment, the solar power generation facility 100 that generates power using solar energy is used as the power generation facility that generates power using natural energy, but power generation is performed using natural energy other than solar energy. For example, a wind power generation facility that generates power using wind energy may be used.

As the fuel generation unit 1, for example, a fuel generation unit made of a fine particle compact whose base material (main component) is iron can be used. In FIG. 1, as an example of the fuel cell unit 2, an MEA (Membrane Electrode Assembly; membrane / electron assembly) having a fuel electrode 2 </ b> B and an oxidant electrode 2 </ b> C formed on both sides of a solid electrolyte ^{2 </} b ^{> A} that transmits O ²⁻ is sandwiched. FIG. 2 shows a solid oxide fuel cell portion having an (electrode assembly) structure. Although FIG. 1 illustrates a structure in which only one MEA is provided, a plurality of MEAs may be provided, or a plurality of MEAs may be stacked.

The solid oxide fuel cell is connected to an external load 200 as shown in FIG. 2 during power generation of the secondary battery type fuel cell system. In the solid oxide fuel cell, the following reaction (1) occurs in the fuel electrode 2B during power generation of the secondary battery type fuel cell system.
H ₂ + O ²⁻ → H ₂ O + 2e ⁻ (1)

The electrons generated by the reaction of the above expression (1) pass through the external load 200 and reach the oxidant electrode 2C, and the reaction of the following expression (2) occurs at the oxidant electrode 2C.
1 / 2O ₂ + 2e ⁻ → O ²⁻ (2)

And the oxygen ion produced | generated by reaction of said (2) Formula passes through the solid electrolyte 2A, and arrives at the fuel electrode 2B. By repeating the above series of reactions, the solid oxide fuel cell performs a power generation operation. Further, as can be seen from the above equation (1), during the power generation operation of the secondary battery type fuel cell system, H ₂ is consumed and H ₂ O is generated on the fuel electrode 2B side.

From the above formulas (1) and (2), the reaction in the solid oxide fuel cell during the power generation operation of the secondary battery type fuel cell system is as shown in the following formula (3).
H ₂ + 1 / 2O ₂ → H ₂ O (3)

On the other hand, the fuel generating unit 1 whose base material (main component) is iron is formed on the fuel electrode 2B side of the fuel cell unit 2 during power generation of the secondary battery type fuel cell system by an oxidation reaction expressed by the following equation (4). The produced H ₂ O is consumed to produce H ₂ .
3Fe + 4H ₂ O → Fe ₃ O ₄ + 4H ₂ (4)

  When the oxidation reaction of iron shown in the above formula (4) proceeds, the change from iron to iron oxide proceeds and the remaining amount of iron decreases, but by the reverse reaction (reduction reaction) of the above formula (4), The hydrogen generator 1 can be regenerated and the secondary battery type fuel cell system can be charged.

When charging the secondary battery type fuel cell system, the solid oxide fuel cell is connected to the photovoltaic power generation facility 100 as shown in FIG. In the solid oxide fuel cell device, when the secondary battery type fuel cell system is charged, an electrolysis reaction shown in the following equation (5), which is a reverse reaction of the above equation (3), occurs, and the H 2 is on the fuel electrode 2B side. _In the fuel generating unit 1 in which ₂ O is consumed, H ₂ is generated, and the base material (main component) is iron, the reduction shown in the following formula (6), which is the reverse reaction of the oxidation reaction shown in the formula (4) above. Reaction occurs, H ₂ generated on the fuel electrode 2B side of the fuel cell unit ₂ is consumed, and H ₂ O is generated.
H ₂ O → H ₂ + 1 / 2O ₂ (5)
Fe ₃ O ₄ + 4H ₂ → 3Fe + 4H ₂ O (6)

  Next, control performed by the system controller 12 at the time of charging the secondary battery type fuel cell system will be described with reference to FIGS. 1 and 3 to 9.

  When charging the secondary battery type fuel cell system, the system controller 12 controls the switch 11 so that the fuel cell unit 2 and the photovoltaic power generation facility 100 are connected. Thereby, electric power is supplied from the solar power generation facility 100 to the fuel cell unit 2. And the electric power detection part 6 detects the electric power supplied to the fuel cell part 2 from the solar power generation equipment 100, and the system controller 12 collects the detection result of the electric power detection part 6. FIG.

  The electric power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 varies depending on the weather and the like. Hereinafter, the case where the electric power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 changes as the characteristic line CL1 shown in FIG. 4 with time elapses will be described as an example.

  The electric power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 is W1_0 until the time t0, decreases at a certain rate after the time t0, and W1_1 at the time t1 (> t0). (<W1_0).

  The system controller 12 controls the power supplied from the battery 9 to the heater unit 3 based on the detection result of the power detection unit 6. Specifically, the system controller 12 detects the battery output so that the power supplied from the battery 9 to the heater unit 3 is smaller than the power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 by a certain value. The output of the battery 9 is controlled while monitoring the detection result of the unit 10. As a result, the electric power supplied from the battery 9 to the heater unit 3 changes as indicated by the characteristic line CL2 shown in FIG. 4 and becomes W2_0 (<W1_0) until the time t0, and is constant after the time t0. It decreases at a rate and becomes W2_1 (<W2_0) at time t1.

  In addition, since it is possible to control the output of the battery 9 without providing the battery output detection unit 10, the battery output detection unit 10 may not be provided. In the example shown in FIG. 4, the electric power supplied from the battery 9 to the heater unit 3 is instantaneously changed according to the change in the electric power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2. The present invention is not limited to this. For example, the system controller 12 calculates an average value of the power supplied from the battery 9 to the heater unit 3 every predetermined period, The electric power supplied from the battery 9 to the heater unit 3 may be controlled during a predetermined period based on the average value of the electric power supplied from the battery 9 to the heater unit 3. In any case, as the power supplied from the solar power generation facility 100 to the fuel cell unit 2 decreases, the power supplied from the battery 9 to the heater unit 3 tends to decrease, so that the system controller 12 performs control. You can do it.

  The relationship between the electric power supplied from the battery 9 to the heater unit 3 and the temperature of the heater unit 3 (≈the temperature of the fuel cell unit 2) is as shown in FIG. When the electric power supplied from the battery 9 to the heater unit 3 is W2_0, the temperature of the heater unit 3 is T0, and when the electric power supplied from the battery 9 to the heater unit 3 is W2_1, the temperature of the heater unit 3 is T1 (< T0).

  The current-voltage characteristics of the fuel cell unit 2 during electrolysis are as shown in FIG. The characteristic line CL3 is a characteristic line when the temperature of the fuel cell unit 2 is T0, and the characteristic line CL4 is a characteristic line when the temperature of the fuel cell unit 2 is T0. The power loss L0 of the fuel cell unit 2 at time t0 shown in FIG. 4, that is, the power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 is W1_0, and the temperature of the fuel cell unit 2 is T0. The power loss L0 in a certain case is the product of I1_0 and ΔV1_0 in FIG. Also, the power loss L1 of the fuel cell unit 2 at time t1 shown in FIG. 4, that is, the power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 is W1_1, and the temperature of the fuel cell unit 2 is The power loss L1 when T1 is the product of I1_1 and ΔV1_1 in FIG.

  When the system controller 12 controls the power supplied from the battery 9 to the heater unit 3 as shown in FIG. 4, when the temperature of the fuel cell unit 2 decreases, the power loss of the fuel cell unit 2 is as shown in FIG. Exponentially increases. For this reason, the power loss is subtracted from the power consumed by the electrolysis reaction (the reaction of the above formula (5)) of the fuel cell unit 2, that is, the power supplied from the photovoltaic power generation equipment 100 to the fuel cell unit 2. The power changes like a characteristic line CL5 as shown in FIG.

  Therefore, when the system controller 12 controls the power supplied from the battery 9 to the heater unit 3 as shown in FIG. 4, the fuel cell does not change the power supplied from the battery 9 to the heater unit 3. An increase in the ratio of the power consumption of the heater unit 3 to the power consumed by the electrolysis reaction itself of the unit 2 can be suppressed, and charging can be performed efficiently.

  At time t2 in FIG. 8, the power consumed by the electrolysis reaction of the fuel cell unit 2 and the power supplied from the battery 9 to the heater unit 3 become equal. As shown in FIG. 8, when the system controller 12 performs the same control after the time point t <b> 2, the electric power consumed in the electrolysis reaction of the fuel cell unit 2 is supplied from the battery 9 to the heater unit 3. A reversal phenomenon occurs in which the power becomes larger.

  In order to prevent the occurrence of this reverse phenomenon, when the secondary battery type fuel cell system is charged, the system controller 12 determines whether or not the temperature of the fuel cell unit 2 is equal to or higher than the temperature T2 of the fuel cell unit 2 at time t2. If the switch 11 is controlled so that the photovoltaic power generation facility 100 and the battery 9 are connected, the battery 9 is charged with the power supplied from the photovoltaic power generation facility 100. The charging of the system may be stopped so that power is not supplied to the fuel cell unit 2.

  Therefore, the system controller 12 at the time of charging the secondary battery type fuel cell system performs the control shown in the flowchart of FIG.

  First, the system controller 12 determines whether or not to charge the secondary battery type fuel cell system (step S10). As a case where the secondary battery type fuel cell system is charged, for example, a case where the oxidation degree of the fuel generation unit 1 is equal to or greater than a threshold value and a case where there is surplus power of the photovoltaic power generation facility 100 are considered. As a method for detecting the degree of oxidation of the fuel generation unit 1, for example, a method for detecting the degree of oxidation of the fuel generation unit 1 based on a change in the weight of the fuel generation unit 1 or the fuel generation unit 1 as in the present embodiment. For example, a method of detecting the degree of oxidation of the fuel generator 1 based on the change in the magnetic permeability of the fuel generator 1 when Fe is used.

  When it is determined that the secondary battery type fuel cell system is to be charged (YES in step S10), the system controller 12 controls the switch 11 so that the fuel cell unit 2 and the photovoltaic power generation facility 100 are connected ( Step S20) When it is determined not to charge the secondary battery type fuel cell system (NO in Step S10), the switch 11 is controlled so that the battery 9 and the photovoltaic power generation facility 100 are connected (Step S30). ).

In step S30 following step S20, the system controller 12, the temperature T _FC of the fuel cell unit 2 is equal to or temperature T2 or higher (step S40).

If the temperature T _FC of the fuel cell unit 2 is determined to be a temperature equal to or higher than T2 in step S40 (YES in step S40), the system controller 12, the heater control, i.e. control of the power supplied from the battery 9 to the heater unit 3 Is performed (step S50). In this heater control, it is preferable that the power supplied from the battery 9 to the heater unit 3 tends to decrease as the power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 decreases.

On the other hand, the switch such that the temperature T _FC of the fuel cell unit 2 in step S40 when it determines that not the temperature T2 or higher (NO in step S40), the system controller 12 includes a battery 9 and solar power generation facility 100 is connected 11 is controlled (step S30). At this time, the heater unit 3 may be turned off.

  In step S60 following step S30 or step S50, it is determined whether or not to generate power in the secondary battery type fuel cell system. As a case where power generation of the secondary battery type fuel cell system is performed, for example, the case where the generated power of the solar power generation facility 100 is less than the power required by the external load can be considered.

  When it is determined that the secondary battery type fuel cell system is not discharged (NO in step S60), the system controller 12 returns to step S10 and when it is determined that the secondary battery type fuel cell system is to generate power (step). The control at the time of charging the secondary battery type fuel cell system is terminated.

  In the present embodiment, when the system controller 12 determines that the temperature of the fuel cell unit 2 is not equal to or higher than a predetermined value, the system controller 12 controls the switch 11 so that the photovoltaic power generation facility 100 and the battery 9 are connected, The battery 9 is charged with the power supplied from the solar power generation facility 100. For example, when the battery 9 is fully charged, the power supplied from the solar power generation facility 100 is other than the secondary battery type fuel cell system. You may make it use with another electric equipment and electric installation.

  In the present embodiment, the system controller 12 determines the temperature of the fuel cell unit 2 using the detection result of the temperature sensor 4 when determining whether or not the temperature of the fuel cell unit 2 is equal to or higher than a predetermined value. It will be appreciated that the invention is not limited to this. For example, since the system controller 12 itself grasps the power supplied from the battery 9 to the heater unit 3, the fuel cell unit is not provided based on the power supplied from the battery 9 to the heater unit 3 without providing the temperature sensor 4. The temperature of 2 may be estimated (see FIG. 5). That is, step S40 of FIG. 9 may be changed to a step of determining whether or not the electric power supplied from the battery 9 to the heater unit 3 is a predetermined value or more. For example, in the control of the present embodiment, the power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2, the power supplied from the battery 9 to the heater unit 3, and the temperature of the fuel cell unit 2 are associated with each other. Therefore, the temperature of the fuel cell unit 2 may be estimated based on the electric power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 without providing the temperature sensor 4. In particular, when all the power generated by the solar power generation facility 100 is supplied to the fuel cell unit 2, the temperature of the fuel cell unit 2 may be estimated based on the power generated by the solar power generation facility 100. That is, step S40 in FIG. 9 is a step of determining whether or not the power supplied from the photovoltaic power generation facility 100 to the fuel cell unit 2 is equal to or greater than a predetermined value, or the generated power of the photovoltaic power generation facility 100 is You may change to the step which determines whether it is more than a predetermined value.

  In the embodiment described above, a solid oxide electrolyte is used as the electrolyte membrane 2A of the fuel cell unit 2, and water is generated on the fuel electrode 2B side during power generation. According to this configuration, water is generated on the side where the fuel generation unit 1 is provided, which is advantageous for simplification and miniaturization of the apparatus. On the other hand, as a fuel cell disclosed in Japanese Patent Application Laid-Open No. 2009-99491, a solid polymer electrolyte that allows hydrogen ions to pass through may be used as the electrolyte membrane 2A of the fuel cell unit 2. However, in this case, since water is generated on the oxidant electrode 2C side that is the oxidant electrode of the fuel cell unit 2 during power generation, a flow path for propagating the water to the fuel generation unit 1 is provided. What is necessary is just to provide. In the above-described embodiment, one fuel cell unit 2 performs both power generation and water electrolysis. However, a fuel cell (for example, a solid oxide fuel cell dedicated to power generation) and a water electrolyzer (for example, water) A solid oxide fuel cell dedicated to electrolysis may be connected to the fuel generator 1 in parallel on the gas flow path.

  In the above-described embodiment, the fuel generation unit 1 and the fuel cell unit 2 are stored in separate containers, but may be stored in the same container.

  In the above-described embodiment, the fuel gas of the fuel cell unit 2 is hydrogen. However, a reducing gas other than hydrogen, such as carbon monoxide or hydrocarbon, may be used as the fuel gas of the fuel cell unit 2.

  In the above-described embodiment, the battery 9 is used as a power source for supplying power to the heater unit 2, but other power sources such as an AC / DC converter that converts commercial AC power into DC power may be used. When there is surplus power of a power generation facility that generates power using natural energy such as the solar power generation facility 100, power may be supplied from the power generation facility to the heater unit 2.

  In the embodiment described above, the determination reference value in step S40 of FIG. 9 is set to the temperature T2, but the temperature T2 is secondary consumed by the power consumed in the electrolysis reaction of the fuel cell unit 2, that is, by charging. Since it is the boundary temperature whether or not the reverse phenomenon occurs in which the electric power supplied from the battery 9 to the heater unit 3 is larger than the electric power stored in the battery type fuel cell system, the criterion in step S40 of FIG. The value may be set to a value higher than the temperature T2 to give a margin for the occurrence of the reverse phenomenon.

DESCRIPTION OF SYMBOLS 1 Fuel generation part 2 Fuel cell part 2A Electrolyte membrane 2B Fuel electrode 2C Oxidant electrode 3 Heater part 4 Temperature sensor 5, 6 Container 7 Piping 8 Electric power detection part 9 Battery 10 Battery output detection part 11 Switch 12 System controller 100 Solar power generation Equipment 200 External load

Claims (4)

A fuel generator capable of releasing a fuel gas by a chemical reaction and regenerating by a reverse reaction of the chemical reaction in which the fuel gas is generated;
A power generation function for generating power using the fuel gas supplied from the fuel generation unit, and an electrolysis function for electrolyzing the product of the reverse reaction supplied from the fuel generation unit during regeneration of the fuel generation unit With power generation / electrolysis section,
While circulating the gas containing the fuel gas between the fuel generation unit and the power generation / electrolysis unit,
A secondary battery type fuel cell system in which power is supplied from the outside to the power generation / electrolysis unit during regeneration of the fuel generation unit,
A power detection unit that detects power supplied to the power generation / electrolysis unit during regeneration of the fuel generation unit;
A heater unit for heating a portion for electrolysis of the power generation / electrolysis unit;
A secondary battery type fuel cell system comprising: a control unit that controls electric power supplied to the heater unit based on a detection result by the electric power detection unit. A determination unit that determines whether or not the temperature of the portion that performs electrolysis of the power generation / electrolysis unit is equal to or higher than a predetermined value;
The secondary battery type fuel cell system according to claim 1, further comprising a regeneration stop unit that stops regeneration of the fuel generation unit when the determination result by the determination unit is negative. A battery for supplying power to the heater section;
3. A switch for switching to supply the electric power supplied to the power generation / electrolysis unit to the battery when the regeneration stop unit stops the regeneration of the fuel generation unit. The secondary battery type fuel cell system described in 1. The secondary battery type fuel cell system according to any one of claims 1 to 3,
A power supply comprising a power generation facility that generates power using natural energy and supplies power to the power generation / electrolysis unit during regeneration of the fuel generation unit of the secondary battery type fuel cell system system.