JP7117191B2 - Carbon dioxide capture fuel cell power generation system - Google Patents

Description

TECHNICAL FIELD The present invention relates to a carbon dioxide recovery fuel cell power generation system, and more particularly to a carbon dioxide recovery fuel cell power generation system that generates power using a carbon compound fuel and recovers carbon dioxide generated along with the power generation.

When a carbon compound fuel is used in a fuel cell power generation system, carbon dioxide is contained in the fuel electrode off-gas discharged from the fuel electrode of the fuel cell stack. This carbon dioxide is being recovered, but the fuel electrode off-gas contains components other than carbon dioxide, including water vapor. Therefore, for example, Patent Literature 1 discloses a technique for recovering carbon dioxide in which the fuel electrode off-gas is cooled and water vapor is removed by condensation.

JP 2013-196890 A

Thus, when condensation removes water vapor and separates carbon dioxide, cooling water is required for adequate condensation in a somewhat limited size condenser. Efficient recovery of carbon dioxide, including cold heat generation for supplying this cooling water, is required.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a carbon dioxide recovery fuel cell power generation system capable of efficiently recovering carbon dioxide.

A carbon dioxide recovery fuel cell power generation system according to the first aspect of the invention generates power using a fuel gas containing a carbon compound and supplied to a fuel electrode and an oxidant gas containing oxygen and supplied to an air electrode, a fuel cell in which the fuel electrode off-gas is delivered from the fuel electrode and the air electrode off-gas is delivered from the air electrode; a cold heat generation unit into which the air electrode off-gas is introduced and which generates cold heat using the air electrode off-gas as a heat source; and the fuel electrode off-gas are supplied, and a combustion part for burning the fuel electrode off-gas, and the combustion off-gas sent from the combustion part is cooled by cold heat from the cold heat generation part to remove water vapor in the fuel electrode off-gas and a condenser for condensing.

A carbon dioxide recovery fuel cell power generation system according to claim 1 includes a fuel cell. In a fuel cell, power is generated by a fuel gas supplied to a fuel electrode and an oxidant gas supplied to an air electrode. Anode off-gas is sent from the anode, and cathode off-gas is sent from the cathode. The fuel electrode off-gas is supplied to the combustion section together with oxygen and combusted, and the combustion off-gas is delivered from the combustion section. The air electrode off-gas is introduced into the cold heat generating section, and cold heat is generated in the cold heat generating section using the air electrode off-gas as a heat source. Then, the combustion off-gas is cooled in the condenser by the cold heat generated in the cold heat generating section, and water vapor in the fuel electrode off-gas is condensed. The combustion off-gas after the water vapor is condensed can be recovered as carbon dioxide.

Since the air electrode off-gas does not contain combustible gas or carbon dioxide for recovery, it is possible to easily adjust the amount of supply to the cold energy generation part, efficiently generate cold energy, and recover carbon dioxide. .

In the carbon dioxide capture fuel cell power generation system according to claim 1 , the fuel cell includes a first fuel cell that supplies the fuel gas to a first fuel electrode, and a first fuel that is sent from the first fuel electrode. It is formed including a second fuel cell that generates power using the pole off-gas as fuel and sends out the second fuel pole off-gas from the second fuel pole as the fuel pole off-gas, and the first fuel pole off-gas is supplied from the cold heat generation part. A fuel regeneration condenser is provided for cooling with cold heat to condense water vapor in the first fuel electrode off-gas and supplying the water vapor to the second fuel electrode.

In the carbon dioxide recovery fuel cell power generation system according to claim 1 , the fuel cell is a multi-stage type having the first fuel cell and the second fuel cell, so that unreacted fuel gas can be reused. It is possible to improve power generation efficiency. Further, since the water vapor in the first fuel electrode off-gas is condensed by the fuel regeneration condenser and supplied to the second fuel electrode, the decrease in concentration of unreacted fuel gas components in the first fuel electrode off-gas is reduced. A decrease in power generation efficiency in the fuel cell can be suppressed. In addition, since cold heat for cooling the first fuel electrode off-gas in the fuel regeneration condenser is generated in the cold heat generation unit using the air electrode off-gas as a heat source, cold heat can be efficiently generated and fuel regeneration can be performed.

The carbon dioxide capture fuel cell power generation system according to claim 2 includes an oxygen separation unit to which a part of the air electrode off-gas is supplied, separates oxygen from the supplied air electrode off-gas, and supplies the oxygen to the combustion unit. I have.

In the carbon dioxide recovery fuel cell power generation system according to claim 2 , since oxygen is separated from a part of the air electrode off-gas supplied to the oxygen separation unit and used for combustion, high-temperature oxygen can be supplied to the combustion unit. can.

In the carbon dioxide recovery fuel cell power generation system according to claim 3 , the fuel cell is a proton-conducting solid oxide fuel cell (PCFC: Proton Ceramic Solid Oxide Fuel Cell).

In the carbon dioxide recovery fuel cell power generation system according to claim 3 , since the hydrogen ion conductive solid oxide fuel cell is used as the fuel cell, water is generated on the air electrode side, and water vapor is included in the air electrode off-gas. be Therefore, in the cold heat generating section, in addition to the sensible heat of the air electrode offgas, the latent heat generated when water vapor condenses through heat exchange is also used as a heat source, and cold heat can be efficiently generated.

In the carbon dioxide recovery fuel cell power generation system according to claim 4 , the fuel cell is an oxygen ion conduction solid oxide fuel cell (SOFC: Solid Oxide Fuel Cell).

In the oxygen-ion conducting solid oxide fuel cell, carbon monoxide, which is a carbon compound, is used in the power generation reaction, so power generation efficiency can be improved.

According to the carbon dioxide recovery fuel cell power generation system according to the present invention, carbon dioxide can be efficiently recovered.

1 is a schematic diagram of a fuel cell power generation system according to a first embodiment; FIG. 1 is a block diagram of a control system of a fuel cell power generation system according to a first embodiment; FIG. 4 is a flowchart of flow rate adjustment processing according to the first embodiment; 4 is a flowchart of cooling water temperature adjustment processing according to the first embodiment; FIG. 2 is a schematic diagram of a fuel cell power generation system according to a second embodiment; FIG. 3 is a schematic diagram of a fuel cell power generation system according to a third embodiment; FIG. 4 is a schematic diagram of a fuel cell power generation system according to a fourth embodiment; FIG. 11 is a schematic diagram of a fuel cell power generation system according to a fifth embodiment; FIG. 11 is a schematic diagram of a fuel cell power generation system according to a sixth embodiment; FIG. 11 is a schematic diagram of a fuel cell power generation system according to a seventh embodiment; FIG. 11 is a schematic diagram of a fuel cell power generation system according to an eighth embodiment; FIG. 11 is a schematic diagram of a fuel cell power generation system according to a ninth embodiment;

An example of an embodiment of the present invention will be described in detail below with reference to the drawings.

[First Embodiment]
FIG. 1 shows a fuel cell power generation system 10A according to a first embodiment as an example of the carbon dioxide capture type fuel cell power generation system of the present invention. The fuel cell power generation system 10A mainly includes a first fuel cell stack 12, a second fuel cell stack 14, a combustor 20 with an oxygen permeable membrane, a condenser 26, a carbon dioxide recovery tank 28, and a first heat exchange. , a second heat exchanger 32 , a waste heat input type absorption chiller 36 , and a water tank 27 . Also, as shown in FIG. 2, a control section 40 is provided for controlling the fuel cell power generation system 10A.

The first fuel cell stack 12 is a proton-conducting solid oxide fuel cell (PCFC: Proton Ceramic Solid Oxide Fuel Cell). It has one fuel electrode (fuel electrode) 12A and a first air electrode (air electrode) 12B.

The basic configuration of the second fuel cell stack 14 is the same as that of the first fuel cell stack 12, with a second fuel electrode 14A corresponding to the first fuel electrode 12A and a second fuel electrode 14A corresponding to the first air electrode 12B. It has two air electrodes 14B and an electrolyte layer 14C corresponding to the electrolyte layer 12C.

One end of the fuel gas pipe P1 is connected to the first fuel electrode 12A of the first fuel cell stack 12, and the other end of the fuel gas pipe P1 is connected to a gas source (not shown). Fuel gas is delivered from the gas source to the first fuel electrode 12A by the fuel supply blower B1. In this embodiment, methane is used as the fuel gas, but any gas capable of generating hydrogen by reforming is not particularly limited, and a hydrocarbon fuel can be used. Examples of hydrocarbon fuels include natural gas, LP gas (liquefied petroleum gas), biogas, reformed coal gas, and low hydrocarbon gas. Examples of the lower hydrocarbon gas include lower hydrocarbons having 4 or less carbon atoms such as methane, ethane, ethylene, propane and butane, and methane used in the present embodiment is preferred. The hydrocarbon fuel may be a mixture of the above-mentioned lower hydrocarbon gases, and the above-mentioned lower hydrocarbon gases may be gases such as natural gas, city gas, and LP gas. If the source gas contains impurities, a desulfurizer or the like is required, but is omitted in the figure.

A water vapor pipe P2 is joined to the fuel gas pipe P1, and water vapor is appropriately sent from a water vapor source (not shown) at the time of starting or stopping. Methane and water vapor are combined in the fuel gas pipe P1 and supplied to the first fuel electrode 12A. In the present embodiment, as will be described later, part of the second fuel electrode offgas is returned to the first fuel electrode 12A and the water vapor is reused. Supplementary supply when necessary in the start-up or shutdown process of the

At the first fuel electrode 12A, the fuel gas is steam-reformed to produce hydrogen and carbon monoxide as shown in the following equation (1). Further, as shown in the following formula (2), carbon monoxide and hydrogen are produced by a shift reaction between the produced carbon monoxide and water.

CH ₄ +H ₂ O→3H ₂ +CO (1)
CO+ _H2O → _CO2 +H2 ( ₂ )

Then, in the first fuel electrode 12A, hydrogen is separated into hydrogen ions and electrons as shown in the following formula (3).

(Anode reaction)
H ₂ →2H ⁺ +2e ⁻ (3)

The hydrogen ions move through the electrolyte layer 12C to the first air electrode 12B. The electrons travel through an external circuit (not shown) to the first cathode. As a result, power is generated in the first fuel cell stack 12 . During power generation, the first fuel cell stack 12 generates heat.

An oxidant gas (air) is supplied to the first air electrode 12B of the first fuel cell stack 12 from an oxidant gas pipe P5. Air is introduced into the oxidant gas pipe P5 by the oxidant gas blower B2. The oxidant gas pipe P5 is provided with a second heat exchanger 32, and the air flowing through the oxidant gas pipe P5 is heated by heat exchange with the cathode offgas flowing through the cathode offgas pipe P6, which will be described later. The heated air is supplied to the first air electrode 12B.

In the first air electrode 12B, as shown in the following equation (4), hydrogen ions that have migrated from the first fuel electrode 12A through the electrolyte layer 12C and electrons that have migrated from the first fuel electrode 12A through the external circuit are , reacts with oxygen in the oxidant gas to produce water vapor.

(air electrode reaction)
2H ⁺ +2e ⁻ +1/2O ₂ →H ₂ O (4)

An air electrode offgas pipe P6 is connected to the first air electrode 12B. The cathode off-gas is discharged from the first cathode 12B to the cathode off-gas pipe P6. The oxidant gas pipe P5 and the air electrode off-gas pipe P6 are also connected to the second air electrode 14B in the same manner, and the first air electrode 12B and the second air electrode 14B are connected in parallel.

One end of the first fuel electrode off-gas pipe P7 is connected to the first fuel electrode 12A of the first fuel cell stack 12, and the other end of the first fuel electrode off-gas pipe P7 is connected to the second fuel cell stack 14 of the second fuel cell stack 14. 2 is connected to the fuel electrode 14A. The first fuel electrode off-gas is delivered from the first fuel electrode 12A to the first fuel electrode off-gas pipe P7. The fuel electrode off-gas contains unreformed fuel gas components, unreacted hydrogen, unreacted carbon monoxide, carbon dioxide, water vapor, and the like.

One end of a second fuel electrode off-gas pipe P7-2 is connected to the second fuel electrode 14A of the second fuel cell stack 14, and the second fuel electrode off-gas is delivered from the second fuel electrode 14A. The other end of the second anode offgas pipe P7-2 is connected to the combustor 20 with an oxygen permeable membrane. A circulating gas pipe P3 is branched from the second fuel electrode offgas pipe P7-2, and the circulating gas pipe P3 is connected to the fuel gas pipe P1 connected to the first fuel electrode 12A. A circulation gas blower B3 is provided in the circulation gas pipe P3.

In the second fuel cell stack 14, a power generation reaction similar to that in the first fuel cell stack 12 occurs, and the cathode offgas is sent from the second cathode 14B to the cathode offgas pipe P6. The air electrode off-gas pipe P6 connected to the second air electrode 14B is branched upstream of the junction with the air electrode off-gas pipe P6 connected to the first air electrode 12B. -2 is formed. The branch air electrode offgas pipe P6-2 is provided with a flow control valve 42 capable of flow control. The flow control valve 42 is connected with the control section 40 . The flow control valve 42 is controlled by the controller 40 to adjust the flow rate of the cathode offgas branched to the branched cathode offgas pipe P6-2. The downstream end of the branched cathode offgas pipe P6-2 is connected to the combustor 20 with an oxygen permeable membrane.

The combustor 20 with an oxygen permeable membrane has a multi-cylindrical shape, and has a combustion section 22 forming an outer cylinder of the multi-cylindrical structure and an oxygen separation section 24 arranged radially inside the combustion section 22 . . A combustion space 22A is formed in the combustion section 22 .

The oxygen separation section 24 is arranged radially inside the combustion section 22, and an air flow path 24A is formed adjacent to the combustion space 22A. The air flow path 24A and the combustion space 22A are separated by an oxygen permeable membrane 23. As shown in FIG. For the oxygen permeable film 23, for example, mixed conductive ceramics of electrons and oxygen ions, such as LSCF, or oxygen ion conductive dense ceramics, such as YSZ, can be used. The other end of the second anode offgas pipe P7-2 is connected to the inlet of the combustion space 22A, and the downstream end of the branched cathode offgas pipe P6-2 is connected to the inlet of the air flow path 24A. An oxidation catalyst is arranged inside the combustion space 22A. As the oxidation catalyst, for example, nickel or ruthenium can be used.

The second cathode off-gas is supplied to the air flow path 24A, and oxygen contained in the second cathode off-gas permeates the oxygen permeable membrane 23 and moves to the combustion space 22A. The second cathode off-gas that does not move to the combustion space 22A is exhausted to the outside from an exhaust pipe P12 connected to the outlet side of the air flow path 24A.

The second fuel electrode off-gas is supplied to the combustion space 22A and mixed with oxygen that has moved from the oxygen separator 24 through the oxygen permeable membrane 23 . As a result, a combustion reaction occurs between combustible gas components (unreformed methane, unreacted hydrogen, unreacted carbon monoxide, etc.) in the second fuel electrode offgas and oxygen through the oxidation catalyst, resulting in carbon dioxide and steam is produced. A combustion off-gas pipe P8 is connected to the outlet side of the combustion space 22A, and combustion off-gas is delivered from the combustion space 22A.

The combustion off-gas pipe P8 passes through the first heat exchanger 30 and is connected to the condenser 26 at the other end. In the first heat exchanger 30, the fuel gas is heated by heat exchange between the fuel gas and the combustion off-gas. A cooling water circulation passage 26A is piped in the condenser 26, and cooling water from an exhaust heat input type absorption chiller 36, which will be described later, is circulated and supplied by driving a pump 26P to cool the combustion off-gas. This causes water vapor in the combustion off-gas to condense. The condensed water is delivered to the water tank 27 through the water pipe P9. One end of a pipe P11 is connected to the water tank 27, and the other end of the pipe P11 is branched into two and connected to the cooling tower 38 and the cooling water circulation flow path 26A.

The combustion off-gas from which water vapor has been separated and removed is sent to the carbon dioxide gas pipe P10. The combustion off-gas from which water (liquid phase) has been removed by the condenser 26 is a gas with a high carbon dioxide concentration, and the combustion off-gas is referred to as a carbon dioxide-rich gas. A composition detector 44 is provided in the carbon dioxide gas pipe P10. The composition detector 44 detects the composition of the carbon dioxide-rich gas delivered from the condenser 26 . Specifically, the concentrations of combustible gases such as methane, carbon monoxide, and hydrogen, and the concentrations of carbon dioxide and oxygen are detected. The composition detection unit 44 is connected to the control unit 40 , and transmits composition information of the detected carbon dioxide-rich gas to the control unit 40 .

The carbon dioxide gas pipe P10 is branched downstream of the composition detector 44, and one of the branches, the carbon dioxide gas pipe P10-1, is connected to the carbon dioxide recovery tank . The other branched carbon dioxide gas pipe P10-2 is connected to the carbon dioxide supply line 29. As shown in FIG. The carbon dioxide gas pipe P10-1 and the carbon dioxide gas pipe P10-2 are provided with on-off valves V1 and V2, respectively. A carbon dioxide blower B4 is provided upstream of the above-described branch of the carbon dioxide gas pipe P10.

A second heat exchanger 32 is provided downstream of the junction where the air electrode offgas pipes P6 from the first air electrode 12B and the second air electrode 14B are merged. In the second heat exchanger 32, heat is exchanged between the cathode offgas flowing through the cathode offgas pipe P6 and the oxidizing gas flowing through the oxidizing gas pipe P5, the oxidizing gas is heated, and the cathode offgas is converted into Cooled. The cathode off-gas passes through the second heat exchanger 32 and is supplied to the exhaust heat input type absorption chiller 36 .

The exhaust heat input type absorption chiller 36 is a heat pump that uses exhaust heat to generate cold heat, and as an example, a steam/exhaust heat input type absorption chiller can be used. In a steam/exhaust heat input type absorption chiller, water is separated from the absorbent by heating the absorbent (for example, lithium bromide aqueous solution or ammonia aqueous solution) that has absorbed water vapor with the heat of the air electrode off-gas. do. Water vapor is condensed in the air electrode off-gas obtained by heating and cooling the absorbing liquid, and the condensed water is supplied to the water tank 27 through the water pipe P36-2. After the water vapor is condensed and removed, the air electrode off-gas is sent to the exhaust pipe P36-1 and exhausted to the outside of the exhaust heat input type absorption chiller .

The absorbent regenerated by heating promotes the evaporation of water by absorbing water vapor and contributes to the generation of cold energy. The exhaust heat input type absorption chiller 36 is connected to a cooling tower 38 via a heat radiation circuit 37 . A pump 37P is installed in the heat radiation circuit 37, and cooling water is supplied to the heat radiation circuit 37 by the pump 37P. Absorption heat generated when the absorption liquid absorbs water vapor in the exhaust heat input type absorption chiller 36 is released to the atmosphere from the cooling tower 38 via the cooling water flowing through the radiation circuit 37 .

Cold heat generated by the exhaust heat input type absorption chiller 36 is sent to the condenser 26 via the cooling water flowing through the cooling water circulation flow path 26A, where the combustion off-gas is cooled in the condenser 26, and the combustion off-gas is cooled. Water vapor is condensed out.

The water tank 27 is connected to a cooling water circulation channel 26A, a heat dissipation circuit 37, and a heat medium channel (not shown) through which water flows as a heat medium for the absorption chiller 36 with waste heat input. In the cooling water circulation flow path 26A, the heat radiation circuit 37, and the heat medium flow path, water is appropriately replenished from the water tank 27 when the water is insufficient.

The control unit 40 controls the entire fuel cell power generation system 10A, and includes a CPU, ROM, RAM, memory, and the like. The memory stores data, procedures, and the like necessary for flow rate adjustment processing, cooling water temperature adjustment processing, and processing during normal operation, which will be described later. As shown in FIG. 2, the control unit 40 is connected to a flow control valve 42, a composition detection unit 44, an exhaust heat input type absorption chiller 36, an opening/closing valve V1, and an opening/closing valve V2. The control unit 40 controls the flow control valve 42 , the composition detection unit 44 , the exhaust heat input type absorption chiller 36 , the opening/closing valve V<b>1 , and the opening/closing valve V<b>2 . FIG. 2 shows part of the connection relationship of the control unit 40 in the fuel cell power generation system 10A. Although not shown in FIG. 2, the control unit 40 is also connected to other devices.

In the fuel cell power generation system 10A, pumps, blowers, and other accessories are driven by electric power generated by the fuel cell power generation system 10A. In order to efficiently use the direct current power generated by the fuel cell power generation system 10A without converting it to alternating current, the auxiliary equipment is preferably driven by direct current.

Next, the operation of the fuel cell power generation system 10A of this embodiment will be described.

In the fuel cell power generation system 10A, the fuel supply blower B1 sends methane from the gas source to the fuel gas pipe P1, passes through the first heat exchanger 30, heats it, and supplies it to the first fuel electrode 12A. Steam for steam reforming is supplied from the steam pipe P2 to the first fuel electrode 12A through the fuel gas pipe P1. Water vapor is supplied at startup and when it is insufficient, and during rated operation, the water vapor in the second fuel electrode off-gas returned from the circulating gas pipe P3 is used as reforming water, as will be described later.

At the first fuel electrode 12A of the first fuel cell stack 12, the fuel gas is steam reformed to produce hydrogen and carbon monoxide. In addition, carbon monoxide and hydrogen are produced by a shift reaction between the produced carbon monoxide and water.

Air is supplied to the first air electrode 12B of the first fuel cell stack 12 through the oxidant gas pipe P5. In the first fuel cell stack 12, hydrogen ions move in the first fuel electrode 12A and the first air electrode 12B, and the reactions described above occur to generate power. From the first fuel electrode 12A of the first fuel cell stack 12, the first fuel electrode off-gas is sent to the first fuel electrode off-gas pipe P7. Further, from the first air electrode 12B, the air electrode off-gas is sent to the air electrode off-gas pipe P6.

The first fuel electrode off-gas sent out from the first fuel electrode 12A is guided to the first fuel electrode off-gas pipe P7 and supplied to the second fuel electrode 14A of the second fuel cell stack 14 . Air is supplied to the second air electrode 14B of the second fuel cell stack 14 through the oxidant gas pipe P5. Electric power is generated in the second fuel cell stack 14 in the same manner as in the first fuel cell stack 12 . From the second fuel electrode 14A of the second fuel cell stack 14, the second fuel electrode off-gas is sent to the second fuel electrode off-gas pipe P7-2. Further, from the second air electrode 14B, the air electrode off-gas is sent to the air electrode off-gas pipe P6. Part of the cathode off-gas delivered from the second cathode 14B is branched to the branched cathode off-gas pipe P6-2, and the rest joins with the cathode off-gas delivered from the first cathode 12B.

The cathode off-gas is supplied to the exhaust heat input type absorption chiller 36 via the second heat exchanger 32 . In the second heat exchanger 32, heat is exchanged between the cathode off-gas and the oxidizing gas, and the oxidizing gas is heated by the cathode off-gas. In the exhaust heat input type absorption chiller 36, as described above, cold heat is generated using the heat of the air electrode off-gas.

A part of the second fuel electrode off-gas branches to the circulating gas pipe P3 and is returned to the first fuel electrode 12A. The rest of the second fuel electrode off-gas is supplied to the combustion section 22 of the combustor 20 with an oxygen permeable membrane and flows through the combustion space 22A.

The cathode offgas branched to the branched cathode offgas pipe P6-2 is supplied to the oxygen separator 24 of the combustor 20 with an oxygen permeable membrane. The air electrode off-gas supplied to the oxygen separation section 24 flows through the air flow path 24A. In the air passage 24A, oxygen contained in the cathode off-gas permeates the oxygen permeable membrane 23 and moves toward the combustion space 22A. In the combustion space 22A, a combustion reaction occurs between combustible gas (methane, hydrogen, carbon monoxide, etc.) in the second fuel electrode off-gas and oxygen to produce carbon dioxide and water vapor. Combustion off-gas containing carbon dioxide and water vapor is delivered from combustion space 22A to combustion off-gas pipe P8. The combustion off-gas delivered to the combustion off-gas pipe P8 is supplied to the condenser 26 via the first heat exchanger 30. As shown in FIG.

The combustion off-gas supplied to the condenser 26 is cooled by the cooling water from the exhaust heat input type absorption chiller 36 circulated through the cooling water circulation passage 26A, and water vapor in the combustion off-gas is condensed. The condensed water is delivered to the water tank 27 via the water pipe P9. Water is stored in the water tank 27, and the cooling water in the heat radiation circuit 37 of the cooling tower 38 and the cooling water circulation flow path 26A of the exhaust heat input type absorption chiller 36 is appropriately replenished with the stored water.

The combustion off-gas from which water vapor has been removed by the condenser 26 becomes a carbon dioxide-rich gas having a high carbon dioxide concentration, and is sent to the carbon dioxide gas pipe P10 by the carbon dioxide blower B4 and sent to the composition detection unit 44. The composition detector 44 detects the composition of the carbon dioxide-rich gas and transmits the detected information to the controller 40 .

Based on the composition information transmitted from the composition detection unit 44, the control unit 40 controls the flow rate adjustment valve 42 to adjust the amount of air electrode offgas branched to the branch air electrode offgas pipe P6-2, and the exhaust heat input. The temperature of the cooling water sent to the cooling water circulation passage 26A is controlled by the type absorption chiller 36 . Specifically, the control unit 40 executes the following flow rate adjustment process and cooling water temperature adjustment process.

As shown in FIG. 3, in the flow rate adjustment process, in step S10, it is determined whether the concentration of the combustible gas is within the threshold value G1 in the composition information of the carbon dioxide-rich gas detected by the composition detector 44. Here, the threshold value G1 is a sufficiently low concentration in the carbon dioxide rich gas, and can be set to about 0.1 to 5 vol%, more preferably in the range of 0.1 to 1 vol%. If the combustible gas concentration is higher than the threshold value G1, the flow control valve 42 is controlled in step S12 to increase the flow rate of the cathode offgas branched to the branched cathode offgas pipe P6-2. As a result, the amount of oxygen that permeates the oxygen-permeable membrane 23 and moves to the combustion space 22A increases, and the combustion reaction in the combustion space 22A reduces the combustible gas contained in the carbon dioxide-rich gas.

If the combustible gas concentration is equal to or less than the threshold value G1 in step S10, it is determined in step S14 whether the oxygen concentration is within the threshold value O1 in the composition information of the carbon dioxide-rich gas detected by the composition detection unit 44. Here, the threshold value O1 is a sufficiently low concentration in the carbon dioxide rich gas, and can be set to about 0.1 to 5 vol %. If the oxygen concentration is higher than the threshold value O1, the flow control valve 42 is controlled in step S16 to reduce the flow rate of the cathode offgas branched to the branched cathode offgas pipe P6-2. As a result, the amount of oxygen that permeates the oxygen-permeable membrane 23 and moves to the combustion space 22A is reduced, and the amount of oxygen that remains in the combustion space 22A without being used in the combustion reaction can be reduced.

After steps S12, S14, and S16, the process returns to step S10 to repeat the above-described processing. This flow rate adjustment process is started when the fuel cell power generation system 10A starts operating, continues during operation, and ends when the operation is stopped.

Further, as shown in FIG. 4, in the condensation amount adjustment process, in step S20, it is determined whether the concentration of water vapor is within the threshold value M in the composition information of the carbon dioxide-rich gas detected by the composition detector 44. Here, the threshold value M is a sufficiently low concentration in the carbon dioxide rich gas, and can be set to about 0.1 to 5 vol%, more preferably in the range of 0.1 to 1 vol%. If the concentration of water vapor is higher than the threshold value M, condensation enhancement is performed in step S22. Specifically, the exhaust heat input type absorption chiller 36 is controlled to lower the temperature of the cooling water sent to the cooling water circulation passage 26A, or to increase the circulation flow rate of the cooling water. As a result, the amount of water separated from the combustion off-gas by condensation in the condenser 26 increases, and the proportion of water vapor contained in the carbon dioxide-rich gas can be reduced.

After steps S20 and S22, the process returns to step S20 and repeats the above-described processing. This condensation amount adjustment process is started when the operation of the fuel cell power generation system 10A is started, continues during operation, and ends when the operation is stopped.

The carbon dioxide-rich gas sent to the carbon dioxide gas pipe P10 is sent to the carbon dioxide recovery tank 28 or the carbon dioxide supply line according to demand. When sent to the carbon dioxide recovery tank 28, the on-off valve V1 is opened and the on-off valve V2 is closed. When sending to the carbon dioxide line, the on-off valve V1 is closed and the on-off valve V2 is opened.

In the fuel cell power generation system 10A of the present embodiment, since the second fuel electrode off-gas sent from the second fuel electrode 14A of the second fuel cell stack 14 is burned in the combustion unit 22, the second fuel cell stack 14 The amount of unreacted fuel gas used for power generation in the second fuel cell stack 14 increases compared to the case where the first fuel electrode off-gas is burned before it is used for power generation. Therefore, power generation efficiency in the second fuel cell stack 14 can be enhanced.

Further, in the combustion section 22, carbon dioxide and water vapor are generated by a combustion reaction between combustible gas contained in the second fuel electrode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered. In addition, only oxygen in the air electrode off-gas is supplied to the combustion unit 22, and the second fuel electrode off-gas contains a smaller amount of unreacted fuel gas than the first fuel electrode off-gas, and carbon dioxide high content of Therefore, the amount of unreacted fuel gas to be burned in the combustion section 22 and the amount of oxygen required to burn the unreacted fuel gas can be reduced.

Further, since the fuel cell power generation system 10A of the present embodiment has the branched air electrode offgas pipe P6-2 branched from the air electrode offgas pipe P6, the composition of the carbon dioxide rich gas detected by the composition detector 44 is Based on the information, it is possible to easily adjust the cathode offgas flow rate branched to the branched cathode offgas pipe P6-2. As a result, the amount of oxygen flowing into the combustion space 22A of the combustion section 22 can be adjusted so that the amount of combustible gas and oxygen contained in the combustion off-gas is lower than the predetermined threshold value.

In the present embodiment, oxygen is separated from the air electrode off-gas and supplied to the combustion unit 22. However, it is not always necessary to supply oxygen separated from the air electrode off-gas. may be prepared and supplied. By supplying oxygen separately from the air electrode off-gas as in the present embodiment, high-temperature oxygen can be supplied to the combustor 22, and the combustion reaction with the combustible gas can be facilitated.

In addition, in this embodiment, the second fuel cell stack 14 is provided, and the fuel electrode off-gas sent from the first fuel cell stack 12 is reused as fuel gas in the second fuel cell stack 14. Although a battery power generation system has been described, multistage is not essential to the present invention. A fuel cell power generation system that does not have the second fuel cell stack 14 is also possible.

Furthermore, in the fuel cell power generation system 10A of the present embodiment, the amount of water condensed by the condenser 26 is adjusted based on the composition information of the carbon dioxide-rich gas detected by the composition detection unit 44, so that the amount of carbon dioxide-rich gas is Carbon dioxide concentration can be increased.

Further, in the fuel cell power generation system 10A of the present embodiment, since the hydrogen ion conducting solid oxide fuel cell is used in the fuel cell stack, water vapor is not generated at the first fuel electrode 12A. Therefore, since the amount of water vapor contained in the first fuel electrode off-gas is reduced, the power generation efficiency of the second fuel cell can be improved. Moreover, since the amount of water vapor contained in the second fuel electrode off-gas is also reduced, the amount of water vapor to be removed from the second fuel electrode off-gas can be reduced.

Further, the fuel cell power generation system 10A of the present embodiment includes a circulating gas pipe P3 that supplies part of the second fuel electrode off-gas from the upstream side of the combustion section 22 to the first fuel electrode 12A. Therefore, part of the unreacted fuel gas and steam in the second anode off-gas can be reused for power generation and steam reforming of the fuel gas, respectively.

In addition, in the fuel cell power generation system 10A of the present embodiment, by arranging the combustion section 22 adjacent to the oxygen permeable membrane 23 of the oxygen separation section 24, a compact oxygen permeation membrane in which the combustion section 22 and the oxygen separation section 24 are integrally formed. A membrane combustor 20 can be constructed.

In addition, in the fuel cell power generation system 10A of the present embodiment, the heat of the air electrode off-gas is used to generate cold heat in the exhaust heat input type absorption chiller 36, so the first fuel cell stack 12 and the second fuel cell stack The exhaust heat of the cathode off-gas from 14 can be effectively utilized. Further, since the air electrode off-gas contains a large amount of water vapor, the water vapor is condensed during heat exchange in the exhaust heat input type absorption chiller 36, and the heat of condensation can also be effectively used. In addition, since the air electrode off-gas has a larger flow rate than the fuel electrode off-gas, by controlling the oxidant gas blower B2, the air electrode off-gas supply amount to the exhaust heat input type absorption chiller 36 can be easily adjusted to improve the efficiency. Can generate cold heat well. Furthermore, since the air electrode off-gas does not contain combustible gas or carbon dioxide for recovery, which tend to deteriorate the exhaust heat input type absorption chiller 36, the performance of the exhaust heat input type absorption chiller 36 is deteriorated. Degradation can also be suppressed. The air electrode off-gas supply amount to the exhaust heat input type absorption chiller 36 may be adjusted by providing a vent portion in the air electrode off-gas pipe P6.

[Second embodiment]
Next, a second embodiment of the invention will be described. In this embodiment, the same reference numerals are assigned to the same parts as in the first embodiment, and detailed description thereof will be omitted.

A fuel cell power generation system 10B of the present embodiment, as shown in FIG. 5, includes a high-temperature oxygen production device 50 and a combustor 52 instead of the combustor 20 with an oxygen permeable membrane of the first embodiment. Configurations other than the high-temperature oxygen production device 50 and the combustor 52 are the same as those of the first embodiment.

The inlet side of the high-temperature oxygen production device 50 is connected to the downstream end of the branch cathode offgas pipe P6-2. The high-temperature oxygen production device 50 is a device that separates oxygen from the air electrode off-gas, and as an example, a PSA device that performs adsorption and desorption at high temperatures can be used. One end of an oxygen supply pipe PO is connected to the oxygen outlet side of the high-temperature oxygen production device 50 . An exhaust pipe P13 is connected to the air electrode off-gas outlet side of the high-temperature oxygen production device 50 after oxygen is separated. The other end of the oxygen supply pipe PO is connected to the inlet side of the combustor 52 . The exhaust pipe P13 is open to the outside of the fuel cell power generation system 10B.

The inlet side of the combustor 52 is connected to the other end of the aforementioned oxygen supply pipe PO and the downstream end of the second fuel electrode offgas pipe P7-2. Inside the combustor 52, combustible gas components (unreformed methane, unreacted hydrogen, unreacted carbon monoxide, etc.) in the second fuel electrode offgas and oxygen supplied from the oxygen supply pipe PO A combustion reaction occurs, producing carbon dioxide and water vapor. A combustion off-gas pipe P8 is connected to the exit side of the combustor 52, and combustion off-gas is delivered from the combustor 52.

Next, the operation of the fuel cell power generation system 10B of this embodiment will be described.

Also in this embodiment, power generation is performed in the first fuel cell stack 12 and the second fuel cell stack 14 in the same manner as in the fuel cell power generation system 10A of the first embodiment. The second air electrode off-gas sent from the second air electrode 14B and branched to the branch air electrode off-gas pipe P6-2 is supplied to the high-temperature oxygen production device 50. In the high-temperature oxygen production device 50, oxygen is separated from the second air electrode off-gas, and the separated oxygen is supplied to the combustor 52 through the oxygen supply pipe PO. The air electrode off-gas from which oxygen has been separated is discharged to the outside through an exhaust pipe P13.

In the combustor 52, a combustion reaction occurs between combustible gas components (unreformed methane, unreacted hydrogen, unreacted carbon monoxide, etc.) in the second fuel electrode offgas and oxygen, and carbon dioxide and water vapor are produced. generated. Combustion off-gas is sent to combustion off-gas pipe P8, water is separated by condenser 26 in the same manner as in the first embodiment, the separated water is recovered in water tank 27, and carbon dioxide-rich gas is collected in carbon dioxide recovery tank. 28 or fed to the carbon dioxide line.

Also in this embodiment, in the combustor 52, carbon dioxide and water vapor are generated by the combustion reaction between the combustible gas contained in the second anode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Third Embodiment]
Next, a third embodiment of the invention will be described. In this embodiment, the same reference numerals are assigned to the same parts as in the first and second embodiments, and detailed description thereof will be omitted.

The fuel cell power generation system 10C of the present embodiment mainly includes the reformer 54, does not include the circulating gas pipe P3, and the piping flow paths related to these configurations are different from those of the first embodiment. is different from Other configurations are the same as those of the first embodiment.

As shown in FIG. 6 , the fuel cell power generation system 10C has a reformer 54 . One end of a fuel gas pipe P1-1 is connected to the inlet side of the reformer . One end of a water supply pipe P2-2 is connected to the inlet side of the reformer . The other end of the water supply pipe P2-2 is connected to the water tank 27. As shown in FIG. The water supply pipe P2-2 is provided with an ion exchange resin 56 and a pump 27B. The water stored in the water tank 27 is supplied to the reformer 54 through the ion exchange resin 56 by driving the pump 27B.

One end of a reformed gas pipe P1-2 is connected to the outlet side of the reformer . The other end of the reformed gas pipe P1-2 is connected to the first fuel electrode 12A of the first fuel cell stack 12. As shown in FIG.

Next, the operation of the fuel cell power generation system 10C of this embodiment will be described.

In the reformer 54, the mixed gas of fuel gas and steam is heated by heat exchange with the combustion off-gas, and hydrogen and carbon monoxide are produced by the steam reforming reaction. In addition, carbon monoxide and hydrogen are produced by a shift reaction between the produced carbon monoxide and water vapor. A reformed gas containing unreacted fuel gas (methane), hydrogen, carbon monoxide and carbon dioxide is supplied to the first fuel electrode 12A through the reformed gas pipe P1-2. Electric power is generated in the first fuel cell stack 12 and the second fuel cell stack 14 in the same manner as in the first embodiment.

The second fuel electrode off-gas is delivered from the second fuel electrode 14A to the second fuel electrode off-gas pipe P7-2. The second fuel electrode off-gas is supplied to the combustor 22 of the combustor 20 with an oxygen permeable membrane without being branched. From the second air electrode 14B, the air electrode off-gas is sent to the air electrode off-gas pipe P6, and part of the air electrode off-gas is branched to the branch air electrode off-gas pipe P6-2 as in the first embodiment. It joins with the air electrode off-gas sent from the first air electrode 12B.

In the combustor 20 with an oxygen permeable membrane and the condenser 26, the same processing as in the first embodiment is performed, and the carbon dioxide-rich gas is recovered in the carbon dioxide recovery tank 28 or supplied to the carbon dioxide line.

Also in this embodiment, carbon dioxide and water vapor are produced by the combustion reaction between the combustible gas contained in the second fuel electrode off-gas and oxygen in the combustor 20 with the oxygen permeable membrane. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Fourth Embodiment]
Next, a fourth embodiment of the invention will be described. In this embodiment, parts similar to those in the first to third embodiments are denoted by the same reference numerals, and detailed description thereof is omitted.

A fuel cell power generation system 10D of this embodiment includes a high-temperature oxygen production device 50 and a combustor 52 of the second embodiment instead of the combustor 20 with an oxygen permeable membrane of the third embodiment. Configurations other than the high-temperature oxygen production device 50 and the combustor 52 are the same as those of the third embodiment.

The inlet side of the high-temperature oxygen production device 50 is connected to the downstream end of the branch air electrode offgas pipe P6-2, and the oxygen outlet side of the high-temperature oxygen production device 50 is connected to one end of the oxygen supply pipe PO. An exhaust pipe P13 is connected to the air electrode off-gas outlet side of the high-temperature oxygen production device 50 after oxygen is separated. The other end of the oxygen supply pipe PO is connected to the inlet side of the combustor 52 . The exhaust pipe P13 is open to the outside of the fuel cell power generation system 10D.

The inlet side of the combustor 52 is connected to the other end of the aforementioned oxygen supply pipe PO and the downstream end of the second fuel electrode offgas pipe P7-2. Inside the combustor 52, combustible gas components (unreformed methane, unreacted hydrogen, unreacted carbon monoxide, etc.) in the second fuel electrode offgas and oxygen supplied from the oxygen supply pipe PO A combustion reaction occurs, producing carbon dioxide and water vapor. A combustion off-gas pipe P8 is connected to the exit side of the combustor 52, and combustion off-gas is delivered from the combustor 52.

Next, the operation of the fuel cell power generation system 10D of this embodiment will be described.

Also in this embodiment, similarly to the fuel cell power generation system 10C of the third embodiment, the reformer 54 steam-reforms the fuel gas to generate a reformed gas. Electric power is generated in the fuel cell stack 14 . The second air electrode off-gas sent from the second air electrode 14B and branched to the branch air electrode off-gas pipe P6-2 is supplied to the high-temperature oxygen production device 50. In the high-temperature oxygen production device 50, oxygen is separated from the second air electrode off-gas, and the separated oxygen is supplied to the combustor 52 through the oxygen supply pipe PO. The air electrode off-gas from which oxygen has been separated is discharged to the outside through an exhaust pipe P13.

In the combustor 52, a combustion reaction occurs between combustible gas components (unreformed methane, unreacted hydrogen, unreacted carbon monoxide, etc.) in the second fuel electrode offgas and oxygen, and carbon dioxide and water vapor are produced. generated. Combustion off-gas is sent to combustion off-gas pipe P8, water is separated by condenser 26 in the same manner as in the first embodiment, the separated water is recovered in water tank 27, and carbon dioxide-rich gas is collected in carbon dioxide recovery tank. 28 or fed to the carbon dioxide line.

Also in this embodiment, in the combustor 52, carbon dioxide and water vapor are generated by the combustion reaction between the combustible gas contained in the second anode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Fifth embodiment]
Next, a fifth embodiment of the invention will be described. In this embodiment, parts similar to those in the first to fourth embodiments are denoted by the same reference numerals, and detailed description thereof will be omitted.

The fuel cell power generation system 10E of this embodiment differs from the first embodiment in that a third heat exchanger 34 and a condenser 35 are provided in the path of the first anode offgas pipe P7.

The first fuel electrode offgas pipe P7 extends from the first fuel electrode 12A and is connected to the condenser 35 via the third heat exchanger 34 . A first anode off-gas pipe P7 from the first fuel electrode 12A to the condenser 35 is denoted by P7A. The first fuel electrode offgas pipe P7A extends from the gas side outlet of the condenser 35 and is connected to the second fuel electrode 14A via the third heat exchanger 34 . A first anode off-gas pipe P7 from the condenser 35 to the second fuel electrode 14A is denoted by P7B. One end of a water pipe P9-2 is connected to the liquid side outlet of the condenser . The other end of the water pipe P9-2 is connected to the water tank 27. As shown in FIG. A cooling water circulation passage 35A is connected to the condenser 35, and the cooling water from the exhaust heat input type absorption chiller 36 is circulated and supplied by driving a pump 35P. As a result, the first anode off-gas is cooled and water vapor in the first anode off-gas is condensed. The condensed water is sent to the water tank 27 through the water pipe P9-2.

Next, the operation of the fuel cell power generation system 10E of this embodiment will be described.

Also in this embodiment, power generation is performed in the first fuel cell stack 12 in the same manner as in the fuel cell power generation system 10A of the first embodiment. The first fuel electrode off-gas sent from the first fuel electrode 12A to the first fuel electrode off-gas pipe P7-1 is cooled by heat exchange with the regenerated fuel gas described later in the third heat exchanger 34 and supplied to the condenser 35. be done. In the condenser 35, the first fuel electrode off-gas is further cooled by cooling water circulating in the cooling water circulation flow path 35A, and water vapor in the first fuel electrode off-gas is condensed. Here, the temperature of the cooling water circulating in the cooling water circulation passage 35A is such that the amount of water vapor remaining in the regenerated fuel gas is such that the power generation efficiency in the second fuel cell stack 14 is improved. is set to condense. The condensed water is sent to the water tank 27 through the water pipe P9-2.

The first fuel electrode off-gas from which the condensed water has been separated is sent to the first fuel electrode off-gas pipe P7B as regenerated fuel gas, and the heat from the first fuel electrode off-gas before water is separated by the third heat exchanger 34 is It is heated by the exchange and supplied to the second fuel electrode 14A. In the second fuel cell stack 14, power is generated in the same manner as in the fuel cell power generation system 10A of the first embodiment.

In the present embodiment, since the regenerated fuel gas generated by separating a part of water vapor from the first fuel electrode off-gas is supplied to the second fuel electrode 14A, the power generation efficiency in the second fuel cell stack 14 can be improved. can be done.

Also in the present embodiment, carbon dioxide and water vapor are produced in the combustion section 22 of the combustor 20 with the oxygen permeable membrane by the combustion reaction between the combustible gas contained in the second fuel electrode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Sixth Embodiment]
Next, a sixth embodiment of the present invention will be described. In this embodiment, the same reference numerals are assigned to the same parts as in the first to fifth embodiments, and detailed description thereof will be omitted.

As shown in FIG. 9, in the fuel cell power generation system 10F of the present embodiment, the first fuel cell stack 62 and the second fuel cell stack 64 are the hydrogen ion conducting solid oxide fuel cells of the first embodiment. Instead, a solid oxide fuel cell (SOFC: Solid Oxide Fuel Cell) is used. Therefore, the following reactions occur at the first fuel electrode 62A (fuel electrode) and the first air electrode 62B (air electrode). The same applies to the second fuel electrode 64A and the second air electrode 64B.

At the first air electrode 62B, oxygen in the oxidant gas reacts with electrons to generate oxygen ions, as shown in the following equation (5). The generated oxygen ions reach the first fuel electrode 62A of the first fuel cell stack 62 through the electrolyte layer 62C.

(air electrode reaction)
1/2O ₂ +2e ⁻ →O ²⁻ (5)

On the other hand, in the first fuel electrode 62A of the first fuel cell stack 62, as shown in the following equations (6) and (7), oxygen ions passing through the electrolyte layer 62C are converted into hydrogen and monoxide in the fuel gas. It reacts with carbon to produce water vapor, carbon dioxide and electrons. Electrons generated in the first fuel electrode 62A move from the first fuel electrode 62A through an external circuit to the first air electrode 62B, thereby generating power.

(Anode reaction)
H ₂ +O ²⁻ →H ₂ O+2e ⁻ (6)
CO+O ²⁻ →CO ₂ +2e ⁻ (7)

In the solid oxide fuel cell, water vapor is generated at the first fuel electrode 62A and the second fuel electrode 64A. 2 The amount of water vapor contained in the fuel electrode off-gas is large. On the other hand, no water vapor is generated at the first air electrode 62B and the second air electrode 64B. The air electrode off-gas supplied to the exhaust heat input type absorption chiller 36 is exhausted from the exhaust pipe P36-1 after heat exchange.

Other configurations of the fuel cell power generation system 10F of the present embodiment are the same as those of the fifth embodiment, and a third heat exchanger 34 and a condenser 35 are provided in the path of the first anode offgas pipe P7. ing. Here, since the amount of water vapor contained in the first fuel electrode off-gas and the second fuel electrode off-gas is larger than that in the fuel cell power generation system 10E, The temperature of the cooling water circulating through the cooling water circulation flow path 35A is set. The condensed water is sent to the water tank 27 through the water pipe P9-2.

In the present embodiment, since the regenerated fuel gas generated by separating a part of water vapor from the first fuel electrode off-gas is supplied to the second fuel electrode 14A, the power generation efficiency in the second fuel cell stack 14 can be improved. can be done.

Also in the present embodiment, carbon dioxide and water vapor are produced in the combustion section 22 of the combustor 20 with the oxygen permeable membrane by the combustion reaction between the combustible gas contained in the second fuel electrode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Seventh Embodiment]
Next, a seventh embodiment of the invention will be described. In this embodiment, the same reference numerals are assigned to the same parts as in the first to sixth embodiments, and detailed description thereof will be omitted.

As shown in FIG. 10, in the fuel cell power generation system 10G of the present embodiment, instead of the combustor 20 with the oxygen permeable membrane of the sixth embodiment, a high-temperature oxygen production device 50 similar to that of the second embodiment and a combustor A vessel 52 is provided. Configurations other than the high-temperature oxygen production device 50, the combustor 52, and the associated piping are the same as those of the sixth embodiment.

Also in the present embodiment, the regeneration fuel gas produced by separating a part of water vapor from the first fuel electrode off-gas is supplied to the second fuel electrode 14A, so that the power generation efficiency in the second fuel cell stack 14 is improved. be able to.

Also in this embodiment, in the combustor 52, carbon dioxide and water vapor are generated by the combustion reaction between the combustible gas contained in the second fuel electrode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Eighth Embodiment]
Next, an eighth embodiment of the invention will be described. In this embodiment, parts similar to those in the first to seventh embodiments are denoted by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 11, in the fuel cell power generation system 10H of this embodiment, as in the third embodiment, the reformer 54 is provided, the circulating gas pipe P3 is not provided, and these A piping channel related to the configuration is different from that of the sixth embodiment. Other configurations are the same as those of the sixth embodiment.

Also in the present embodiment, the regeneration fuel gas produced by separating a part of water vapor from the first fuel electrode off-gas is supplied to the second fuel electrode 14A, so that the power generation efficiency in the second fuel cell stack 14 is improved. be able to.

Also in the present embodiment, carbon dioxide and water vapor are generated by the combustion reaction between the combustible gas contained in the second fuel electrode off-gas and oxygen in the combustion section 22 . Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

[Ninth Embodiment]
Next, a ninth embodiment of the present invention will be described. In this embodiment, the same reference numerals are assigned to the same parts as in the first to eighth embodiments, and detailed description thereof will be omitted.

As shown in FIG. 11, in the fuel cell power generation system 10I of the present embodiment, instead of the combustor 20 with the oxygen permeable membrane of the eighth embodiment, the high-temperature oxygen production device 50 of the seventh embodiment and the combustor 52 It has Configurations other than the high-temperature oxygen production device 50 and the combustor 52 are the same as those of the eighth embodiment.

Also in the present embodiment, the regeneration fuel gas produced by separating a part of water vapor from the first fuel electrode off-gas is supplied to the second fuel electrode 14A, so that the power generation efficiency in the second fuel cell stack 14 is improved. be able to.

Also in this embodiment, in the combustor 52, carbon dioxide and water vapor are generated by the combustion reaction between the combustible gas contained in the second fuel electrode off-gas and oxygen. Therefore, the combustible gas can be reduced from the second anode off-gas, and high-concentration carbon dioxide can be recovered.

Other fuel cells such as molten carbonate fuel cells (MCFC), phosphoric acid fuel cells (PAFC), and polymer electrolyte fuel cells (PEFC) can also be used as the fuel cell of the present invention.

Alternatively, the carbon dioxide supply line 29 may be connected to a carbon dioxide liquefaction device or a carbon separation device to produce liquid carbon dioxide, powdered carbon, or the like.

In the above-described first to ninth embodiments, cold heat is generated using the exhaust heat input type absorption chiller 36, but other exhaust heat is used instead of the exhaust heat input type absorption chiller 36. Heat pumps, such as adsorption chillers, may also be used to generate cold.

10A to 10I Fuel cell power generation system (carbon dioxide recovery fuel cell power generation system)
12, 62 first fuel cell stack (fuel cell, first fuel cell)
12A, 62A first fuel electrode (fuel electrode)
12B, 62B first air electrode (air electrode)
14, 64 second fuel cell stack (fuel cell, second fuel cell)
14A, 64A Second fuel electrode (fuel electrode)
14B, 64B Second air electrode (fuel electrode)
22 Combustion Section 24 Oxygen Separation Section 26 Condenser 35 Condenser (Fuel Regeneration Condenser)
50 high-temperature oxygen production device (oxygen separator)
52 combustor (combustion part)
P6 air electrode offgas pipe (air electrode offgas channel)

Claims (4)

Electricity is generated by a fuel gas containing a carbon compound and supplied to the fuel electrode and an oxidant gas containing oxygen and supplied to the air electrode, and the fuel electrode off-gas is sent from the fuel electrode and the air electrode off-gas is sent from the air electrode. A first fuel cell that supplies the fuel gas to the first fuel electrode, a fuel cell that generates power using the first fuel electrode off-gas sent from the first fuel electrode as fuel, and a second fuel a fuel cell formed including a second fuel cell in which a second anode off-gas is delivered from an electrode as said anode off-gas ;
a cold heat generation unit into which the air electrode off-gas is introduced and which generates cold heat using the air electrode off-gas as a heat source;
a combustion unit supplied with oxygen and the fuel electrode off-gas and burning the fuel electrode off-gas;
a condenser that cools the combustion off-gas delivered from the combustion unit with cold heat from the cold heat generating unit to condense water vapor in the fuel electrode off-gas;
a fuel regeneration condenser that cools the first fuel electrode off-gas with cold heat from the cold heat generation unit to condense water vapor in the first fuel electrode off-gas and supplies the water vapor to the second fuel electrode;
A carbon dioxide capture fuel cell power generation system. 2. The carbon dioxide capture fuel cell according to claim 1 , further comprising an oxygen separation section to which a part of the air electrode off-gas is supplied, separating oxygen from the supplied air electrode off-gas, and supplying the oxygen to the combustion section. power generation system. 3. The carbon dioxide recovery fuel cell power generation system according to claim 1, wherein said fuel cell is a hydrogen ion conduction solid oxide fuel cell. 3. The carbon dioxide recovery fuel cell power generation system according to claim 1, wherein said fuel cell is an oxygen ion conduction solid oxide fuel cell.

Images