JP2014175144A - Solid oxide fuel cell system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solid oxide fuel cell system capable of surely avoiding a risk that an air electrode is reduced at an emergency stop.SOLUTION: A solid oxide fuel cell system (1) comprises: a fuel cell module (2) in which a fuel cell stack (14) is housed in a power generation chamber (10); a fuel supply device (38); a water supply device (28); an air supply device (45); a reformer (20) which steam-reforms the fuel supplied from the fuel supply device (38) using the water supplied from the water supply device and supplies the reformed fuel to the fuel electrode side of the fuel cell stack; a controller (110) programmed so as to execute control of power extraction from the fuel supply device, the water supply device, the air supply device, and the fuel cell module; and emergent discharging means (46) for promoting gas discharging in the power generation chamber when the controller operation is stopped due to an emergency stop.

Description

  The present invention relates to a solid oxide fuel cell system, and more particularly to a solid oxide fuel cell system that generates electric power by reacting hydrogen generated by steam reforming of fuel with an oxidant gas.

  A solid oxide fuel cell system (hereinafter also referred to as “SOFC”) uses an oxide ion conductive solid electrolyte as an electrolyte, attaches electrodes on both sides, and supplies fuel gas on one side. The fuel cell system operates at a relatively high temperature by supplying an oxidant (air, oxygen, etc.) to the other side.

  Japanese Patent Laying-Open No. 2010-27579 (Patent Document 1) describes a fuel cell system. In this fuel cell system, at the time of an emergency stop, a delivery pump that supplies fuel to the reformer, a reforming water pump that supplies water for steam reforming, and an air blower that sends air to the air electrode side of the cell stack Stop. After that, when the delivery pump and the reforming water pump are operated again by the emergency stop operation control, the fuel gas adsorbed in the adsorber is in a state where the supply of the fuel gas from the fuel supply source is shut off. Is sent to the reformer, and steam reforming is performed by the water supplied from the reforming water pump. Thereby, even after the supply of the fuel gas is interrupted, the reformed fuel is supplied to the fuel electrode of the cell stack for a predetermined period, and the oxidation of the fuel electrode due to the backflow of air is prevented.

  Furthermore, JP 2012-138186 A (Patent Document 2) describes a high-temperature operating fuel cell system. In this high temperature operation type fuel cell system, at the time of emergency stop, the raw fuel pump that supplies fuel gas is stopped, while the reforming water pump that supplies water to the reformer is operated. When the reforming water pump is operated, the supplied water expands in volume by being evaporated in the reformer. For this reason, even when the supply of the source fuel gas from the fuel supply source is shut off, the fuel gas remaining in the fuel gas supply line downstream of the reformer is expanded by the pressure of the volume-expanded water vapor. Is pushed out to the fuel cell (cell stack) side. Thereby, the oxidation of the fuel electrode due to the backflow of air is prevented.

JP 2010-27579 A JP 2012-138186 A

  However, after the emergency stop of the solid oxide fuel cell system, the inventors of the present invention contact the remaining fuel gas flowing out from the fuel electrode side of the fuel cell to the air electrode side and contact the air electrode of the fuel cell. The present inventors have found a new technical problem that the electrode may be deteriorated or damaged by reducing the pole. In the fuel cell system described in the above-mentioned patent document, an attempt is made to solve the problem that air flows backward to the fuel electrode side after an emergency stop and the fuel electrode is oxidized. No measures are taken.

  During a certain period immediately after the emergency stop of the fuel cell system, the pressure on the fuel electrode side of the fuel cell is higher than the pressure on the air electrode side, and the remaining fuel gas flows out from the fuel electrode side to the air electrode side. ing. The fuel gas that has flowed out stays in the power generation chamber in which the fuel cell (stack) is accommodated, and then is discharged to the outside of the fuel cell module through the exhaust pipe. Since hydrogen gas contained in the fuel gas is lighter than air, it stays in the upper part of the power generation chamber. Therefore, if the amount of fuel gas flowing out to the air electrode side is small, the air electrode of the fuel cell arranged at the lower part of the power generation chamber It is difficult for fuel gas to come into contact with the fuel. However, if a large amount of fuel gas flows out, the power generation chamber may be filled with fuel gas and the fuel gas may come into contact with the air electrode.

  In addition, the fuel gas remaining in the power generation chamber is discharged outside the fuel cell module through the exhaust pipe by natural convection even when forced exhaust (supply of power generation air) is lost. Is done. However, in general, since an exhaust pipe from the power generation chamber is provided with a heat exchanger or the like, there is a case where the flow path resistance is large and the fuel gas in the power generation chamber cannot be sufficiently discharged only by natural convection. . In such a case, the amount of fuel gas staying in the power generation chamber increases and the fuel gas may come into contact with the air electrode of the fuel cell. In particular, in order to sufficiently recover the heat of the exhaust from the power generation chamber and improve the energy efficiency of the fuel cell system, an exhaust pipe heat exchanger or the like is essential, so the flow resistance of the exhaust pipe is large. This increases the risk that the fuel gas contacts the air electrode during an emergency stop.

  Therefore, the present invention provides a solid oxide fuel cell system capable of reliably avoiding the risk of the air electrode being reduced during an emergency stop while sufficiently recovering the heat of the exhaust to enhance energy efficiency. It is intended to provide.

  In order to solve the above-described problems, the present invention provides a solid oxide fuel cell system that generates power by reacting hydrogen generated by steam reforming of fuel and air, and a fuel cell stack in a power generation chamber A fuel cell module containing fuel, a fuel supply device for supplying fuel to the fuel cell module, a water supply device for supplying water for steam reforming to the fuel cell module, and air on the air electrode side of the fuel cell stack An air supply device that supplies the fuel, and the fuel supplied from the fuel supply device is steam reformed using the water supplied from the water supply device, and the reformed fuel is supplied to the fuel electrode side of the fuel cell stack Reformer to be supplied and controller programmed to perform control of extraction of power from fuel supply device, water supply device, air supply device, and fuel cell module , And in a state where the controller operated by the emergency stop is stopped, the emergency ejection means to facilitate the discharge of the power generation chamber of a gas, characterized in that it has a.

  In the present invention configured as described above, fuel and water are supplied to the reformer by the fuel supply device and the water supply device, respectively, and the reformer steam reforms the fuel. The reformed fuel is supplied to the fuel electrode side of the fuel cell stack housed in the power generation chamber of the fuel cell module. On the other hand, air is supplied to the air electrode side of the fuel cell stack by an air supply device. The controller is programmed to perform control of extraction of power from the fuel supply device, the water supply device, the air supply device, and the fuel cell module. The emergency discharge means promotes the discharge of gas in the power generation chamber in a state where the operation of the controller is stopped due to an emergency stop.

  In general, in a solid oxide fuel cell system, the pressure on the fuel electrode side of the fuel cell stack is higher than the pressure on the air electrode side even after the operation of the controller is stopped due to an emergency stop. For this reason, even after the controller is stopped, the fuel gas remaining on the fuel electrode side flows out to the air electrode side. The fuel gas that has flowed out to the air electrode side stays in the power generation chamber and is then discharged out of the fuel cell module. Since the spilled fuel gas stays in the upper part of the power generation chamber, the spilled fuel gas does not normally contact the air electrode of the fuel cell stack. However, the present inventor, when there is a large amount of fuel gas that has flowed out, or when the flow path resistance of the exhaust system from the fuel cell module is large, the fuel gas that has flowed out fills the power generation chamber and contacts the air electrode. The present inventors have found a new technical problem at the time of emergency stop that there is a risk of deteriorating or damaging the air electrode of the fuel cell stack.

  According to the present invention configured as described above, in the state where the operation of the controller is stopped due to an emergency stop, emergency discharge means for promoting the discharge of gas in the power generation chamber is provided, so control by the controller is lost. Even in this state, the fuel gas that has flowed into the power generation chamber can be effectively discharged. As a result, it is possible to more reliably avoid the risk that the fuel gas that has flowed into the power generation chamber after an emergency stop comes into contact with the air electrode and deteriorates or damages the air electrode of the fuel cell stack.

  In the present invention, the emergency stop preferably includes a first emergency stop when the supply of fuel and the supply of commercial power are stopped, and a second emergency stop when only the supply of fuel is stopped. In the second emergency stop, the air supply device is programmed to operate for a predetermined time after executing the shutdown stop for stopping the fuel supply by the fuel supply device and the extraction of the electric power from the fuel cell module. In this case, after the fuel supply and the extraction of electric power are stopped due to the operation stop of the controller, the emergency discharge means autonomously promotes the discharge of the gas in the power generation chamber.

  According to the present invention configured as above, since the supply of commercial power is not lost in the second emergency stop when only the fuel supply is stopped, the air supply device is predetermined after the shutdown stop is executed. Operate for hours. As a result, the fuel gas flowing out into the power generation chamber can be forcibly exhausted, and the deterioration and damage of the air electrode can be reliably prevented. In addition, since the air supply device is operated for a predetermined time after the shutdown is stopped, the air flows back to the fuel electrode side when the fuel supply is stopped and the air is supplied in a state where the pressure on the fuel electrode side is reduced. Can be prevented. Further, in the first emergency stop when the supply of fuel and commercial power is stopped, the emergency discharge means autonomously promotes the discharge of gas in the power generation chamber in a state where the operation of the controller is stopped. Thereby, even when the supply of fuel and commercial power is stopped, it is possible to reliably prevent deterioration and damage of the air electrode.

In the present invention, preferably, the emergency discharge means is not activated in the case of the second emergency stop.
According to the present invention configured as described above, in the case of the second emergency stop in which the supply of commercial power is not lost, the fuel gas that has flowed out only by the operation of the air supply device is used without using the emergency discharge means. It is possible to exhaust reliably.

In the present invention, the emergency discharge means preferably promotes the discharge of gas in the power generation chamber by communicating between the inside of the power generation chamber and the atmosphere and promoting natural convection in the power generation chamber.
According to the present invention configured as described above, the emergency discharge means discharges the gas in the power generation chamber by promoting natural convection in the power generation chamber, so that power for forcibly discharging the gas in the power generation chamber is used. In addition, gas discharge can be promoted.

In the present invention, preferably, the emergency discharge means is constituted by a normally open type valve that is automatically opened when the supply of commercial power is stopped, and power is generated from the atmosphere by opening this normally open type valve. The channel resistance of the channel for taking air into the room is lowered.
According to the present invention configured as described above, since the emergency discharge means is constituted by the normally open valve, the emergency discharge means can be reliably operated with a simple configuration.

In the present invention, the normally open valve is preferably provided so as to bypass at least a part of an air supply system that supplies air from the atmosphere to the power generation chamber via an air supply device.
According to the present invention configured as described above, it is possible to reduce the flow path resistance for taking air from the atmosphere into the power generation chamber only by bypassing a part of the air supply system normally used for air supply. The emergency discharge means can be configured with a simple structure.

In the present invention, preferably, an exhaust port for exhausting gas in the power generation chamber during power generation operation is provided in the upper portion of the power generation chamber, and the air inflow port into which outside air that has passed through the normally open valve flows is the exhaust of the power generation chamber. It is provided below the port.
According to the present invention configured as described above, since the outside air is introduced from the lower side of the power generation chamber and the gas in the power generation chamber having a high temperature is discharged from the upper exhaust port, the fuel is efficiently discharged by natural convection. Can do.

In the present invention, it is preferable that the flow path resistance from the atmosphere to the power generation chamber through the normally open valve is such that when the normally open valve is opened, the gas in the power generation chamber is discharged from the exhaust port by natural convection. The outside air is set to be sucked into the power generation chamber from the air inflow port.
According to the present invention configured as described above, when the normally open type valve is opened, the gas in the power generation chamber does not flow back through the normally open type valve and is discharged to the outside air. It is possible to prevent the air from being discharged from the outlet which is not the exhaust path.

In the present invention, preferably, the flow path resistance of the flow path for discharging the gas in the power generation chamber to the outside air through the exhaust port is greater than the flow path resistance of the flow path from the fuel electrode side to the air electrode side of the fuel cell stack. Is also made smaller.
According to the present invention configured as described above, the flow rate of the fuel flowing out from the fuel electrode side to the air electrode side can be made smaller than the flow rate of the gas discharged to the outside air through the exhaust port. It is possible to prevent the fuel from filling the power generation chamber.

  In the present invention, preferably, the fuel cell stack is composed of a plurality of fuel cell units, and a thin tube that connects the fuel electrode side and the air electrode side is provided at the upper end of each fuel cell unit. The outlet extends upward so that the outlet is close to the exhaust port.

  According to the present invention configured as described above, after the shutdown is stopped, the fuel is injected from the fuel electrode side to the air electrode side through the thin tube at the upper end of the fuel cell unit, and the outlet of the thin tube is close to the exhaust port. Since it extends, the fuel injected from each fuel cell unit to the air electrode side quickly flows into the exhaust port, and the risk that the injected fuel contacts the air electrode can be further reduced. In addition, by changing the cross-sectional area of the thin tube, the flow resistance of the flow path exhausted through the exhaust port can be easily made smaller than the flow resistance of the flow path from the fuel electrode side to the air electrode side. Can be adjusted.

  In the present invention, preferably, the emergency discharge means is constituted by a discharge fan that forcibly discharges the gas in the power generation chamber, and the discharge fan autonomously operates by the power of the storage battery after the operation of the controller is stopped. Operated for a predetermined time.

  According to the present invention configured as described above, even when the supply of fuel and the supply of commercial power are stopped, the gas in the power generation chamber can be forcibly discharged, and the fuel gas contacts the air electrode. Risks can be avoided more reliably.

  According to the solid oxide fuel cell system of the present invention, it is possible to reliably avoid the risk of the air electrode being reduced during an emergency stop while sufficiently recovering the heat of the exhaust to increase the energy efficiency. .

1 is an overall configuration diagram showing a fuel cell system according to an embodiment of the present invention. It is a front sectional view showing a fuel cell module of a fuel cell system by one embodiment of the present invention. FIG. 3 is a cross-sectional view taken along line III-III in FIG. 2. It is a fragmentary sectional view showing a fuel cell unit of a fuel cell system by one embodiment of the present invention. 1 is a perspective view showing a fuel cell stack of a fuel cell system according to an embodiment of the present invention. 1 is a block diagram showing a fuel cell system according to an embodiment of the present invention. 1 is a perspective view of a reformer of a fuel cell system according to an embodiment of the present invention. FIG. 3 is a perspective view illustrating the inside of the reformer with the top plate of the reformer of the fuel cell system according to the embodiment of the present invention removed. It is a top sectional view showing a flow of fuel inside a reformer of a fuel cell system by one embodiment of the present invention. 1 is a perspective view showing a metal case and an air heat exchanger housed in a housing of a fuel cell system according to an embodiment of the present invention. It is sectional drawing which shows the positional relationship of the heat insulating material for heat exchangers of the fuel cell system by one Embodiment of this invention, and an evaporation part. It is a time chart which shows an example of each supply_amount | feed_rate of fuel etc. in the starting process of the fuel cell system by one Embodiment of this invention, and the temperature of each part. 5 is a flowchart of stop determination for selecting an emergency stop mode in the fuel cell system according to the embodiment of the present invention. 4 is a time chart schematically showing an example of a stop behavior when a first emergency stop mode is executed in a fuel cell system according to an embodiment of the present invention. 5 is a time chart schematically showing an example of a stop behavior when a second emergency stop mode is executed in the fuel cell system according to the embodiment of the present invention. 1 is an overall configuration diagram of a solid oxide fuel cell system according to a modified embodiment of the present invention.

Next, a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is an overall configuration diagram showing a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention. As shown in FIG. 1, a solid oxide fuel cell system (SOFC) 1 according to an embodiment of the present invention includes a fuel cell module 2 and an auxiliary unit 4.

  The fuel cell module 2 includes a housing 6, and a metal case 8 is built in the housing 6 via a heat insulating material 7. A fuel cell assembly 12 that performs a power generation reaction with fuel and oxidant gas (air) is disposed in a power generation chamber 10 that is a lower portion of the case 8 that is a sealed space. The fuel cell assembly 12 includes ten fuel cell stacks 14 (see FIG. 5), and the fuel cell stack 14 includes 16 fuel cell unit 16 (see FIG. 4). Yes. Thus, the fuel cell assembly 12 has 160 fuel cell units 16, and all of these fuel cell units 16 are connected in series.

A combustion chamber 18 that is a combustion section is formed above the above-described power generation chamber 10 of the case 8 of the fuel cell module 2. In this combustion chamber 18, the remaining fuel and the remaining oxidant that have not been used for the power generation reaction. (Air) is combusted to generate exhaust gas. Further, the case 8 is covered with a heat insulating material 7 to suppress the heat inside the fuel cell module 2 from being diffused to the outside air.
Further, a reformer 20 for reforming the fuel is disposed above the combustion chamber 18, and the reformer 20 is heated to a temperature at which a reforming reaction can be performed by the combustion heat of the residual gas. Yes. Further, an air heat exchanger 22, which is a heat exchanger for heating the power generation air with the remaining combustion gas and preheating the power generation air, is disposed above the reformer 20.

  Next, the auxiliary unit 4 stores pure water tank 26 that stores water condensed from moisture contained in the exhaust from the fuel cell module 2 and makes it pure water with a filter, and water supplied from the water storage tank. Is provided with a water flow rate adjusting unit 28 (such as a “water pump” driven by a motor). In addition, the auxiliary unit 4 adjusts the flow rate of the fuel gas, the gas shutoff valve 32 for shutting off the fuel supplied from the fuel supply source 30 such as city gas, the desulfurizer 36 for removing sulfur from the fuel gas, A fuel flow adjustment unit 38 (such as a “fuel pump” driven by a motor) and a valve 39 that shuts off fuel gas flowing out from the fuel flow adjustment unit 38 when power is lost. Further, the auxiliary unit 4 includes a check valve 42 that prevents backflow of air that is an oxidant gas supplied from the air supply source 40, a reforming air flow rate adjustment unit 44 that adjusts the flow rate of air, and a power generation unit. An air flow rate adjusting unit 45 (such as an “air blower” driven by a motor).

Next, a hot water production apparatus 50 to which exhaust gas is supplied is connected to the fuel cell module 2. The hot water production apparatus 50 is supplied with tap water from the water supply source 24, and the tap water is heated by the heat of the exhaust gas and supplied to a hot water storage tank of an external hot water heater (not shown).
The fuel cell module 2 is provided with a control box 52 for controlling the amount of fuel gas supplied and the like.
Furthermore, the fuel cell module 2 is connected to an inverter 54 that is a power extraction unit (power conversion unit) for supplying the power generated by the fuel cell module to the outside.

Next, the internal structure of the fuel cell module of the solid oxide fuel cell system (SOFC) according to the embodiment of the present invention will be described with reference to FIGS. 2 is a side sectional view showing a fuel cell module of a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention, and FIG. 3 is a sectional view taken along line III-III in FIG. is there.
As shown in FIGS. 2 and 3, the case 8 in the housing 6 of the fuel cell module 2 has a fuel cell assembly 12, a reformer 20, and an air heat exchanger in order from the bottom as described above. 22 is arranged.

The reformer 20 is provided with a reformer introduction pipe 62 for introducing pure water, fuel gas to be reformed, and reforming air on the end side surface on the upstream end side.
The reformer introduction pipe 62 is a circular pipe extending from the side wall surface at one end of the reformer 20, is bent by 90 ° and extends in a substantially vertical direction, and penetrates the upper end surface of the case 8. The reformer introduction pipe 62 functions as a water introduction pipe for introducing water into the reformer 20. Further, a T-shaped tube 62a is connected to the upper end of the reformer introduction tube 62, and fuel gas and pure water are supplied to both ends of the T-shaped tube 62a extending in a substantially horizontal direction. Pipes for connecting are connected to each other. The water supply pipe 63a extends obliquely upward from one side end of the T-shaped pipe 62a. The fuel gas supply pipe 63b extends in the horizontal direction from the other side end of the T-shaped pipe 62a, then bends in a U shape, and extends substantially horizontally in the same direction as the water supply pipe 63a.

  On the other hand, an evaporation unit 20a, a mixing unit 20b, and a reforming unit 20c are formed in the reformer 20 sequentially from the upstream side, and the reforming unit 20c is filled with a reforming catalyst. The fuel gas and air mixed with the steam (pure water) introduced into the reformer 20 are reformed by the reforming catalyst filled in the reformer 20. As the reforming catalyst, a catalyst obtained by imparting nickel to the alumina sphere surface or a catalyst obtained by imparting ruthenium to the alumina sphere surface is appropriately used.

  A fuel gas supply pipe 64 is connected to the downstream end side of the reformer 20, and the fuel gas supply pipe 64 extends downward and further in an manifold 66 formed below the fuel cell assembly 12. It extends horizontally. A plurality of fuel supply holes 64 b are formed in the lower surface of the horizontal portion 64 a of the fuel gas supply pipe 64, and the reformed fuel gas is supplied into the manifold 66 from the fuel supply holes 64 b. Further, in the middle of the vertical portion of the fuel gas supply pipe 64, a pressure fluctuation suppressing flow path resistance portion 64c having a narrow flow path is provided, and the flow path resistance of the fuel gas supply flow path is adjusted. The adjustment of the channel resistance will be described later.

  A lower support plate 68 having a through hole for supporting the fuel cell stack 14 described above is attached above the manifold 66, and the fuel gas in the manifold 66 flows into the fuel cell unit 16. Supplied.

On the other hand, an air heat exchanger 22 is provided above the reformer 20.
Further, as shown in FIG. 2, an ignition device 83 for starting combustion of fuel gas and air is provided in the combustion chamber 18.

Next, the fuel cell unit 16 will be described with reference to FIG. FIG. 4 is a partial cross-sectional view showing a fuel cell unit of a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention.
As shown in FIG. 4, the fuel cell unit 16 includes a fuel cell 84 and inner electrode terminals 86 that are caps respectively connected to both ends of the fuel cell 84.
The fuel cell 84 is a tubular structure extending in the vertical direction, and includes a cylindrical inner electrode layer 90 that forms a fuel gas flow path 88 therein, a cylindrical outer electrode layer 92, an inner electrode layer 90, and an outer side. An electrolyte layer 94 is provided between the electrode layer 92 and the electrode layer 92. The inner electrode layer 90 is a fuel electrode through which fuel gas passes and becomes a (−) electrode, while the outer electrode layer 92 is an air electrode in contact with air and becomes a (+) electrode.

  Since the inner electrode terminal 86 attached to the upper end side and the lower end side of the fuel cell 84 has the same structure, the inner electrode terminal 86 attached to the upper end side will be specifically described here. The upper portion 90 a of the inner electrode layer 90 includes an outer peripheral surface 90 b and an upper end surface 90 c exposed to the electrolyte layer 94 and the outer electrode layer 92. The inner electrode terminal 86 is connected to the outer peripheral surface 90b of the inner electrode layer 90 through a conductive sealing material 96, and is further in direct contact with the upper end surface 90c of the inner electrode layer 90, thereby Electrically connected. At the center of the inner electrode terminal 86, a fuel gas channel capillary 98 that communicates with the fuel gas channel 88 of the inner electrode layer 90 is formed.

  The fuel gas passage narrow tube 98 is an elongated thin tube provided so as to extend in the axial direction of the fuel cell 84 from the center of the inner electrode terminal 86. For this reason, a predetermined pressure loss occurs in the flow of the fuel gas flowing from the manifold 66 (FIG. 2) into the fuel gas passage 88 through the fuel gas passage narrow tube 98 of the lower inner electrode terminal 86. . Accordingly, the fuel gas flow passage narrow tube 98 of the lower inner electrode terminal 86 acts as an inflow side flow passage resistance portion, and the flow passage resistance is set to a predetermined value. Further, a predetermined pressure loss also occurs in the flow of the fuel gas flowing out from the fuel gas flow path 88 to the combustion chamber 18 (FIG. 2) through the fuel gas flow path narrow tube 98 of the upper inner electrode terminal 86. Therefore, the fuel gas flow passage narrow tube 98 of the upper inner electrode terminal 86 acts as an outflow side flow passage resistance portion, and the flow passage resistance is set to a predetermined value.

  The inner electrode layer 90 includes, for example, a mixture of Ni and zirconia doped with at least one selected from rare earth elements such as Ca, Y, and Sc, and Ni and ceria doped with at least one selected from rare earth elements. The mixture is formed of at least one of Ni and a mixture of lanthanum garade doped with at least one selected from Sr, Mg, Co, Fe, and Cu.

  The electrolyte layer 94 includes, for example, zirconia doped with at least one selected from rare earth elements such as Y and Sc, ceria doped with at least one selected from rare earth elements, lanthanum gallate doped with at least one selected from Sr and Mg, Formed from at least one of the following.

  The outer electrode layer 92 includes, for example, lanthanum manganite doped with at least one selected from Sr and Ca, lanthanum ferrite doped with at least one selected from Sr, Co, Ni and Cu, Sr, Fe, Ni and Cu. It is formed from at least one of lanthanum cobaltite doped with at least one selected from the group consisting of silver and silver.

Next, the fuel cell stack 14 will be described with reference to FIG. FIG. 5 is a perspective view showing a fuel cell stack of a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention.
As shown in FIG. 5, the fuel cell stack 14 includes 16 fuel cell units 16, and these fuel cell units 16 are arranged in two rows of 8 each. Each fuel cell unit 16 is supported at its lower end by a rectangular lower support plate 68 (FIG. 2) made of ceramic. It is supported by the upper support plate 100. The lower support plate 68 and the upper support plate 100 are formed with through holes through which the inner electrode terminal 86 can pass.

  Furthermore, a current collector 102 and an external terminal 104 are attached to the fuel cell unit 16. The current collector 102 includes a fuel electrode connection portion 102a that is electrically connected to an inner electrode terminal 86 attached to the inner electrode layer 90 that is a fuel electrode, and an outer peripheral surface of the outer electrode layer 92 that is an air electrode. It is integrally formed so as to connect the air electrode connecting portion 102b that is electrically connected. In addition, a silver thin film is formed on the entire outer surface of the outer electrode layer 92 (air electrode) of each fuel cell unit 16 as an electrode on the air electrode side. When the air electrode connecting portion 102b contacts the surface of the thin film, the current collector 102 is electrically connected to the entire air electrode.

  Furthermore, two external terminals 104 are connected to the air electrode 86 of the fuel cell unit 16 located at the end of the fuel cell stack 14 (the far left side in FIG. 5). These external terminals 104 are connected to the inner electrode terminal 86 of the fuel cell unit 16 at the end of the adjacent fuel cell stack 14, and as described above, all 160 fuel cell units 16 are connected in series. It has come to be.

Next, sensors and the like attached to the solid oxide fuel cell system (SOFC) according to the present embodiment will be described with reference to FIG. FIG. 6 is a block diagram illustrating a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention.
As shown in FIG. 6, the solid oxide fuel cell system 1 includes a control unit 110. The control unit 110 includes operation buttons such as “ON” and “OFF” for operation by the user. The operation device 112, a display device 114 for displaying various data such as a power generation output value (wattage), and a notification device 116 for issuing a warning (warning) in an abnormal state are connected. In addition, the control unit 110 incorporates a microprocessor, a memory, and a program (not shown) for operating these components, and thereby, based on input signals from the respective sensors, the auxiliary unit 4, The inverter 54 and the like are controlled. The notification device 116 may be connected to a remote management center and notify the management center of an abnormal state.

Next, signals from various sensors described below are input to the control unit 110.
First, the combustible gas detection sensor 120 is for detecting a gas leak, and is attached to the fuel cell module 2 and the auxiliary unit 4.
The CO detection sensor 122 detects whether or not CO in the exhaust gas originally discharged to the outside through the exhaust gas passage 80 or the like leaks to an external housing (not shown) that covers the fuel cell module 2 and the auxiliary unit 4. Is to do.
The hot water storage state detection sensor 124 is for detecting the temperature and amount of hot water in a water heater (not shown).

The power state detection sensor 126 is for detecting the current and voltage of the inverter 54 and the distribution board (not shown).
The power generation air flow rate detection sensor 128 is for detecting the flow rate of power generation air supplied to the power generation chamber 10.
The reforming air flow sensor 130 is for detecting the flow rate of the reforming air supplied to the reformer 20.
The fuel flow sensor 132 is for detecting the flow rate of the fuel gas supplied to the reformer 20.

The water flow rate sensor 134 is for detecting the flow rate of pure water supplied to the reformer 20.
The water level sensor 136 is for detecting the water level of the pure water tank 26.
The pressure sensor 138 is for detecting the pressure on the upstream side outside the reformer 20.
The exhaust temperature sensor 140 is for detecting the temperature of the exhaust gas flowing into the hot water production apparatus 50.

As shown in FIG. 3, the power generation chamber temperature sensor 142 is provided on the front side and the back side in the vicinity of the fuel cell assembly 12, and detects the temperature in the vicinity of the fuel cell stack 14 to thereby detect the fuel cell stack. 14 (ie, the fuel cell 84 itself) is estimated.
The combustion chamber temperature sensor 144 is for detecting the temperature of the combustion chamber 18.
The exhaust gas chamber temperature sensor 146 is for detecting the temperature of the exhaust gas in the exhaust gas chamber 78.
The reformer temperature sensor 148 is for detecting the temperature of the reformer 20, and calculates the temperature of the reformer 20 from the inlet temperature and the outlet temperature of the reformer 20.
The outside air temperature sensor 150 is for detecting the temperature of the outside air when the solid oxide fuel cell system (SOFC) is disposed outdoors. Further, a sensor for measuring the humidity or the like of the outside air may be provided.

  Signals from these sensors are sent to the control unit 110, and the control unit 110, based on data based on these signals, the water flow rate adjustment unit 28, the fuel flow rate adjustment unit 38, the reforming air flow rate adjustment unit 44, A control signal is sent to the power generation air flow rate adjusting unit 45 to control each flow rate in these units.

Next, the detailed configuration of the reformer 20 will be described with reference to FIGS.
FIG. 7 is a perspective view of the reformer 20, and FIG. 8 is a perspective view showing the inside of the reformer 20 with the top plate removed. FIG. 9 is a plan sectional view showing the flow of fuel inside the reformer 20.

  As shown in FIG. 7, the reformer 20 is a rectangular parallelepiped metal box, and is filled with a reforming catalyst for reforming fuel. A reformer introduction pipe 62 for introducing water, fuel, and reforming air is connected to the upstream side of the reformer 20. Further, a fuel gas supply pipe 64 for discharging the internally reformed fuel is connected to the downstream side of the reformer 20.

  As shown in FIG. 8, inside the reformer 20, an evaporation unit 20a that is an evaporation chamber is provided on the upstream side, and a mixing unit 20b is provided on the downstream side adjacent to the evaporation unit 20a. ing. Further, a reforming section 20c is provided on the downstream side adjacent to the mixing section 20b. Inside the evaporation part 20a, a plurality of partition plates are arranged to form a meandering and meandering passage. The water introduced into the reformer 20 is evaporated in the evaporation unit 20a in a state where the temperature is increased, and becomes water vapor. Furthermore, the mixing part 20b is comprised from the chamber which has a predetermined | prescribed volume, and the path | route which meanders meanderingly by the several partition plate being arrange | positioned also in the inside is formed. The fuel gas and the reforming air introduced into the reformer 20 are mixed with the water vapor generated in the evaporation unit 20a while passing through the winding path of the mixing unit 20b.

On the other hand, a meandering passage is formed in the reforming section 20c by arranging a plurality of partition plates, and the passage is filled with a catalyst. When a mixture of fuel gas, water vapor and reforming air is introduced through the evaporation unit 20a and the mixing unit 20b, a partial oxidation reforming reaction and a steam reforming reaction occur in the reforming unit 20c. Furthermore, when a mixture of fuel gas and steam is introduced, only the steam reforming reaction occurs in the reforming unit 20c.
In this embodiment, the evaporation unit, the mixing unit, and the reforming unit are integrally configured to form one reformer. However, as a modification, a reformer including only the reforming unit is used. It is also possible to provide a mixing section and an evaporation chamber adjacent to the upstream side.

As shown in FIGS. 8 and 9, the fuel gas, water, and reforming air introduced into the evaporator 20a of the reformer 20 meander in the transverse direction of the reformer 20, and are introduced during this period. The evaporated water evaporates to become water vapor. An evaporation / mixing unit partition 20d is provided between the evaporation unit 20a and the mixing unit 20b, and a partition opening 20e is provided in the evaporation / mixing unit partition 20d. This partition opening 20e is a rectangular opening provided in an upper half of the half of one side of the evaporation / mixing section partition 20d.
Further, a mixing / reforming section partition wall 20f is provided between the mixing section 20b and the reforming section 20c, and a narrow flow path is formed by providing a large number of communication holes 20g in the mixing / reforming section partition wall 20f. Has been. The fuel gas or the like mixed in the mixing unit 20b flows into the reforming unit 20c through these communication holes 20g.

  The fuel or the like that has flowed into the reforming unit 20c flows in the longitudinal direction in the center of the reforming unit 20c, and then splits into two to be folded back, and the two passages are folded back again toward the downstream end of the reforming unit 20c. Therefore, they are merged and flow into the fuel gas supply pipe 64. The fuel is reformed by the catalyst filled in the passage while passing through the meandering passage. In the evaporation unit 20a, bumping may occur in which a certain amount of water rapidly evaporates in a short time, and the internal pressure may increase. However, since the mixing unit 20b has a chamber with a predetermined volume and the mixing / reforming unit partition wall 20f has a narrow flow path, the reforming unit 20c has a sudden pressure fluctuation in the evaporation unit 20a. The influence of is difficult to reach. Therefore, the chamber of the mixing unit 20b and the narrow channel of the mixing / reforming unit partition 20f function as pressure fluctuation absorbing means.

  Next, referring to FIGS. 10 and 11 again, and referring again to FIGS. 2 and 3, the structure of the air heat exchanger 22 which is a heat exchanger for the power generation oxidant gas will be described in detail. FIG. 10 is a perspective view showing the metal case 8 and the air heat exchanger 22 housed in the housing 6. FIG. 11 is a cross-sectional view showing the positional relationship between the evaporation chamber heat insulating material and the evaporation section.

  As shown in FIG. 10, the air heat exchanger 22 is a heat exchanger disposed above the case 8 in the fuel cell module 2. Further, as shown in FIGS. 2 and 3, a combustion chamber 18 is formed inside the case 8, and a plurality of fuel cell units 16, a reformer 20 and the like are accommodated therein. 22 is located above these. The air heat exchanger 22 collects and uses the heat of the combustion gas that is combusted in the combustion chamber 18 and discharged as exhaust gas so as to preheat the power generation air introduced into the fuel cell module 2. It is configured. Further, as shown in FIG. 10, an evaporation chamber heat insulating material 23, which is an internal heat insulating material, is disposed between the upper surface of the case 8 and the bottom surface of the air heat exchanger 22 so as to be sandwiched between them. Has been. That is, the evaporation chamber heat insulating material 23 is disposed between the reformer 20 and the air heat exchanger 22. Furthermore, the outside of the air heat exchanger 22 and the case 8 shown in FIG. 10 is covered with a heat insulating material 7 as an outer heat insulating material (FIG. 2).

  As shown in FIGS. 2 and 3, the air heat exchanger 22 includes a plurality of combustion gas pipes 70 and a power generation air flow path 72. As shown in FIG. 2, an exhaust gas collecting chamber 78 is provided at one end of the plurality of combustion gas pipes 70, and the exhaust gas collecting chamber 78 is communicated with each combustion gas pipe 70. ing. Further, an exhaust gas discharge pipe 82 is connected to the exhaust gas collecting chamber 78. Further, the other end of each combustion gas pipe 70 is open, and this open end communicates with the combustion chamber 18 in the case 8 via a communication opening 8 a formed on the upper surface of the case 8. Has been.

  The combustion gas pipe 70 is a plurality of metal circular pipes oriented in the horizontal direction, and the circular pipes are arranged in parallel. On the other hand, the power generation air flow path 72 is constituted by a space outside each combustion gas pipe 70. A power generation air introduction pipe 74 (FIG. 10) is connected to the end of the power generation air flow path 72 on the exhaust gas discharge pipe 82 side so that the air outside the fuel cell module 2 is used for power generation. The air is introduced into the power generation air flow path 72 through the air introduction pipe 74. As shown in FIG. 10, the power generation air introduction pipe 74 protrudes in the horizontal direction from the air heat exchanger 22 in parallel with the exhaust gas discharge pipe 82. Further, a pair of communication flow paths 76 (FIGS. 3 and 10) are connected to both side surfaces of the other end of the power generation air flow path 72, and the power generation air flow path 72 and each communication flow path 76 are connected. Are communicated with each other via an exit port 76a.

  As shown in FIG. 3, a power generation air supply passage 77 is provided on each side surface of the case 8. Each communication channel 76 provided on both side surfaces of the air heat exchanger 22 communicates with an upper portion of a power generation air supply channel 77 provided on both side surfaces of the case 8. In addition, a large number of air outlets 77 a are arranged in the horizontal direction at the lower portion of each power generation air supply passage 77. The power generation air supplied through each power generation air supply path 77 is injected toward the lower side surface of the fuel cell stack 14 in the fuel cell module 2 from a large number of air outlets 77a.

A rectifying plate 21 that is a partition wall is attached to the ceiling surface inside the case 8, and the rectifying plate 21 has an opening 21 a.
The rectifying plate 21 is a plate member disposed horizontally between the ceiling surface of the case 8 and the reformer 20. The rectifying plate 21 is configured to adjust the flow of the gas flowing upward from the combustion chamber 18 and to guide it to the inlet of the air heat exchanger 22 (communication opening 8a in FIG. 2). The power generation air and the combustion gas traveling upward from the combustion chamber 18 flow into the upper side of the rectifying plate 21 through the opening 21 a provided in the center of the rectifying plate 21, and the upper surface of the rectifying plate 21 and the ceiling surface of the case 8. 2 flows to the left in FIG. 2 and is led to the inlet of the heat exchanger 22 for air. Further, as shown in FIG. 11, the opening 21a is provided above the reforming unit 20c of the reformer 20, and the gas rising through the opening 21a is on the side opposite to the evaporation unit 20a. , Flows to the left exhaust passage 21b in FIGS. For this reason, the space above the evaporation unit 20a (the right side in FIGS. 2 and 11) acts as a gas retention space 21c in which the flow of exhaust gas is slower than the space above the reforming unit 20c and the flow of exhaust gas is stagnant.

  Further, a vertical wall 21d is provided at the edge of the opening 21a of the rectifying plate 21 over the entire circumference, and the vertical wall 21d allows the exhaust above the rectifying plate 21 from the space below the rectifying plate 21. The flow path flowing into the passage 21b is narrowed. Further, a falling wall 8b (FIG. 2) is provided over the entire circumference at the edge of the communication opening 8a that allows the exhaust passage 21b and the air heat exchanger 22 to communicate with each other. The flow path flowing into the air heat exchanger 22 is narrowed. By providing the vertical wall 21d and the falling wall 8b, the flow resistance in the exhaust passage from the combustion chamber 18 to the outside of the fuel cell module 2 through the air heat exchanger 22 is adjusted. The adjustment of the channel resistance will be described later.

  The heat insulating material 23 for the evaporation chamber is a heat insulating material attached to the bottom surface of the air heat exchanger 22 so as to substantially cover the whole. Therefore, the heat insulating material 23 for evaporation chamber is arrange | positioned over the whole evaporation part 20a. The evaporating chamber heat insulating material 23 is formed so that the high-temperature gas in the exhaust passage 21 b and the gas retention space 21 c formed between the upper surface of the rectifying plate 21 and the ceiling surface of the case 8 flows on the bottom surface of the air heat exchanger 22. It arrange | positions so that it may suppress direct heating. For this reason, during the operation of the fuel cell module 2, the heat directly transferred to the bottom surface of the air heat exchanger 22 from the exhaust gas remaining in the exhaust passage above the evaporation unit 20a is reduced, and the surroundings of the evaporation unit 20a are reduced. The temperature tends to rise. In addition, after the fuel cell module 2 is stopped, the evaporation chamber heat insulating material 23 is disposed, so that heat dissipation from the reformer 20 is suppressed, that is, the heat around the evaporation unit 20a is used for air. The heat exchanger 22 is less likely to be deprived, and the temperature drop of the evaporation unit 20a is moderated.

  In addition, the heat insulating material 23 for the evaporation chamber includes a heat insulating material 7 that is an outer heat insulating material covering the case 8 of the fuel cell module 2 and the entire air heat exchanger 22 in order to suppress the dissipation of heat to the outside air. Apart from this, it is a heat insulating material arranged inside the heat insulating material 7. The heat insulating material 7 is configured to have higher heat insulating properties than the heat insulating material 23 for the evaporation chamber. That is, the thermal resistance between the inner surface and the outer surface of the heat insulating material 7 is larger than the thermal resistance between the upper surface and the lower surface of the evaporation chamber heat insulating material 23. That is, when the heat insulating material 7 and the evaporation chamber heat insulating material 23 are made of the same material, the heat insulating material 7 is made thicker than the evaporation chamber heat insulating material 23.

Next, the flow of fuel, power generation air, and exhaust gas during the power generation operation of the solid oxide fuel cell system 1 will be described.
First, the fuel is introduced into the evaporation section 20a of the reformer 20 through the fuel gas supply pipe 63b, the T-shaped pipe 62a, and the reformer introduction pipe 62, and the pure water is supplied to the water supply pipe 63a, It is introduced into the evaporator 20a through the T-shaped tube 62a and the reformer introducing tube 62. Accordingly, the supplied fuel and water are merged in the T-shaped tube 62 a and introduced into the evaporation unit 20 a through the reformer introduction tube 62. During the power generation operation, since the evaporation unit 20a is heated to a high temperature, the pure water introduced into the evaporation unit 20a is evaporated relatively quickly to become water vapor. The evaporated water vapor and fuel are mixed in the mixing unit 20 b and flow into the reforming unit 20 c of the reformer 20. The fuel introduced into the reforming unit 20c together with the steam is steam reformed here and reformed into a fuel gas rich in hydrogen. The fuel reformed in the reforming unit 20c goes down through the fuel gas supply pipe 64 and flows into the manifold 66 which is a dispersion chamber.

  The manifold 66 is a rectangular parallelepiped space having a relatively large volume, which is disposed on the lower side of the fuel cell stack 14, and a plurality of holes provided on the upper surface thereof constitute each fuel cell constituting the fuel cell stack 14. It communicates with the inside of the unit 16. The fuel introduced into the manifold 66 flows out from the upper end of the fuel cell unit 16 through the many holes provided on the upper surface thereof, through the fuel electrode side of the fuel cell unit 16, that is, through the inside of the fuel cell unit 16. . Further, when hydrogen gas as a fuel passes through the inside of the fuel cell unit 16, it reacts with oxygen in the air passing outside the fuel cell unit 16 as an air electrode (oxidant gas electrode) to generate a charge. Is done. The remaining fuel that is not used for power generation flows out from the upper end of each fuel cell unit 16 and is combusted in a combustion chamber 18 provided above the fuel cell stack 14.

  On the other hand, power generation air that is an oxidant gas is sent into the fuel cell module 2 through a power generation air introduction pipe 74 by a power generation air flow rate adjustment unit 45 that is a power generation air supply device. The air sent into the fuel cell module 2 is introduced into the power generation air passage 72 of the air heat exchanger 22 via the power generation air introduction pipe 74 and preheated. The preheated air flows out to each communication channel 76 via each outlet port 76a (FIG. 3). The power generation air flowing into each communication channel 76 flows downward through the power generation air supply passages 77 provided on both side surfaces of the fuel cell module 2, and the fuel cell stack 14 from a number of outlets 77a. Toward the power generation chamber 10.

  The air injected into the power generation chamber 10 comes into contact with the outer surface of each fuel cell unit 16 on the air electrode side (oxidant gas electrode side) of the fuel cell stack 14, and a part of oxygen in the air is in contact with it. Used for power generation. Moreover, the air injected to the lower part of the power generation chamber 10 through the blower outlet 77a rises in the power generation chamber 10 while being used for power generation. The air rising in the power generation chamber 10 burns the fuel flowing out from the upper end of each fuel cell unit 16. The combustion heat generated by this combustion heats the evaporation section 20a, the mixing section 20b, and the reforming section 20c of the reformer 20 disposed above the fuel cell stack 14. The combustion gas generated by burning the fuel heats the upper reformer 20 and then flows into the upper side of the rectifying plate 21 through the opening 21 a above the reformer 20. The combustion gas that has flowed into the upper side of the rectifying plate 21 is guided to the communication opening 8 a that is the inlet of the air heat exchanger 22 through the exhaust passage 21 b formed by the rectifying plate 21. The combustion gas that has flowed into the air heat exchanger 22 from the communication opening 8 a flows into the open end of each combustion gas pipe 70 and flows through the power generation air flow path 72 outside each combustion gas pipe 70. Are exchanged with each other and collected in an exhaust gas collecting chamber 78. The exhaust gas collected in the exhaust gas collection chamber 78 is discharged to the outside of the fuel cell module 2 through the exhaust gas discharge pipe 82. As a result, the evaporation of water in the evaporation unit 20a and the steam reforming reaction, which is an endothermic reaction in the reforming unit 20c, are promoted, and the power generation air in the air heat exchanger 22 is preheated.

Next, control in the starting process of the solid oxide fuel cell system 1 will be described with reference to FIG.
FIG. 12 is a time chart showing an example of each supply amount of fuel and the like and the temperature of each part in the startup process. In addition, the scale of the vertical axis | shaft of FIG. 12 has shown temperature, and each supply amount of fuel etc. has shown those increase / decrease roughly.

In the starting process shown in FIG. 12, the temperature of the fuel cell stack 14 at room temperature is raised to a temperature at which power generation is possible.
First, at time t0 in FIG. 12, the supply of power generation air and reforming air is started. Specifically, the control unit 110 serving as a controller sends a signal to the power generation air flow rate adjustment unit 45 serving as a power generation air supply device to operate it. As described above, the power generation air is introduced into the fuel cell module 2 through the power generation air introduction pipe 74 and flows into the power generation chamber 10 through the air heat exchanger 22 and the power generation air supply path 77. . In addition, the control unit 110 sends a signal to the reforming air flow rate adjustment unit 44 which is a reforming air supply device to operate it. The reforming air introduced into the fuel cell module 2 flows into the interior of each fuel cell unit 16 through the reformer 20 and the manifold 66, and flows out from the upper end thereof. Note that at time t0, no reforming reaction occurs in the reformer 20 because fuel has not yet been supplied. In this embodiment, the supply amount of power generation air started at time t0 in FIG. 12 is about 100 L / min, and the supply amount of reforming air is about 10.0 L / min.

  Next, fuel supply is started at time t1 after a predetermined time from time t0 in FIG. Specifically, the control unit 110 sends a signal to the fuel flow rate adjustment unit 38 which is a fuel supply device to operate it. In the present embodiment, the fuel supply amount started at time t1 is about 5.0 L / min. The fuel introduced into the fuel cell module 2 flows into the interior of each fuel cell unit 16 through the reformer 20 and the manifold 66, and flows out from the upper end thereof. At time t1, the reformer reaction is not generated in the reformer 20 because the temperature of the reformer is still low.

  Next, at time t2 when a predetermined time has elapsed from time t1 in FIG. 12, an ignition process for the supplied fuel is started. Specifically, in the ignition process, the control unit 110 sends a signal to an ignition device 83 (FIG. 2) that is an ignition means, and ignites the fuel flowing out from the upper end of each fuel cell unit 16. The ignition device 83 repeatedly generates a spark in the vicinity of the upper end of the fuel cell stack 14 and ignites the fuel flowing out from the upper end of each fuel cell unit 16.

When ignition is completed at time t3 in FIG. 12, supply of reforming water is started. Specifically, the control unit 110 sends a signal to the water flow rate adjustment unit 28 (FIG. 6), which is a water supply device, to activate it. In the present embodiment, the supply amount of water started at time t3 is 2.0 cc / min. At time t3, the fuel supply amount is maintained at about 5.0 L / min. Further, the supply amounts of the power generation air and the reforming air are also maintained at the previous values. At this time t3, the ratio O ₂ / C of oxygen O ₂ in the reforming air and carbon C in the fuel becomes about 0.32.

  After being ignited at time t3 in FIG. 12, the supplied fuel flows out as off-gas from the upper end of each fuel cell unit 16, and is burned here. This combustion heat heats the reformer 20 disposed above the fuel cell stack 14. Here, an evaporating chamber heat insulator 23 is disposed above the reformer 20 (above the case 8), so that immediately after the start of fuel combustion, the temperature of the reformer 20 suddenly increases from room temperature. To rise. Since the outside air is introduced into the air heat exchanger 22 disposed on the heat insulating material 23 for the evaporation chamber, the air heat exchanger 22 has a low temperature, particularly immediately after the start of combustion, and serves as a cooling source. Cheap. In the present embodiment, the evaporation chamber heat insulating material 23 is disposed between the upper surface of the case 8 and the bottom surface of the air heat exchanger 22, so that the reformer 20 disposed in the upper portion of the case 8 The movement of heat to the air heat exchanger 22 is suppressed, and heat is easily trapped in the vicinity of the reformer 20 in the case 8. In addition, the space above the rectifying plate 21 above the evaporation unit 20a is configured as a gas retention space 21c (FIG. 2) in which the flow of combustion gas is slow, so that the vicinity of the evaporation unit 20a is double insulated. And the temperature rises more rapidly.

  As described above, the temperature of the evaporation unit 20a rapidly increases, so that water vapor can be generated in a short time after the start of off-gas combustion. In addition, since the reforming water is supplied to the evaporation unit 20a little by little, it is possible to heat the water to the boiling point with a slight amount of heat compared to the case where a large amount of water is stored in the evaporation unit 20a. The supply of water vapor can be started immediately. Furthermore, since water flows in immediately after the start of the operation of the water flow rate adjustment unit 28, it is possible to avoid an excessive increase in temperature of the evaporation unit 20a and a delay in supply of water vapor due to a delay in supply of water.

  When a certain amount of time elapses after the start of off-gas combustion, the temperature of the air heat exchanger 22 also rises due to the exhaust gas flowing from the combustion chamber 18 into the air heat exchanger 22. The evaporation chamber heat insulating material 23 that insulates between the reformer 20 and the air heat exchanger 22 is a heat insulating material provided inside the heat insulating material 7. Therefore, the heat insulating material 23 for the evaporation chamber does not suppress the dissipation of heat from the fuel cell module 2, but immediately increases the temperature of the reformer 20, particularly the evaporation section 20a immediately after the start of off-gas combustion. Let

In this way, at time t4 when the temperature of the reformer 20 rises, the fuel and the reforming air that have flowed into the reforming unit 20b through the evaporation unit 20a undergo the partial oxidation reforming reaction represented by the equation (1). Get up.
_{C m H n + xO 2 →} aCO 2 + bCO + cH 2 (1)
Since this partial oxidation reforming reaction is an exothermic reaction, when the partial oxidation reforming reaction occurs in the reforming part 20b, the ambient temperature rapidly rises locally.

On the other hand, in the present embodiment, the supply of the reforming water is started from time t3 immediately after the ignition is confirmed, and the temperature of the evaporation unit 20a is rapidly increased. At time t4, water vapor has already been generated in the evaporator 20a and supplied to the reformer 20b. That is, after the off-gas is ignited, the supply of water is started a predetermined time before the temperature of the reforming unit 20b reaches the temperature at which the partial oxidation reforming reaction occurs, and reaches the temperature at which the partial oxidation reforming reaction occurs. At that time, a predetermined amount of water is stored in the evaporation unit 20a, and water vapor is generated. For this reason, when the temperature rapidly rises due to the occurrence of the partial oxidation reforming reaction, a steam reforming reaction occurs in which the reforming steam supplied to the reforming unit 20b reacts with the fuel. This steam reforming reaction is an endothermic reaction shown in Formula (2), and occurs at a higher temperature than the partial oxidation reforming reaction.
C _m H _n + xH ₂ O → aCO ₂ + bCO + cH ₂ (2)

As described above, when the time t4 in FIG. 12 is reached, the partial oxidation reforming reaction occurs in the reforming unit 20b, and the steam reforming is caused by the temperature rise caused by the partial oxidation reforming reaction. Reaction will also occur at the same time. Therefore, the reforming reaction that occurs in the reforming unit 20b after time t4 is an autothermal reforming reaction (ATR) shown in Formula (3) in which the partial oxidation reforming reaction and the steam reforming reaction are mixed. That is, the ATR1 process is started at time t4.
_{C m H n + xO 2 +} yH 2 O → aCO 2 + bCO + cH 2 (3)

  Thus, in the solid oxide fuel cell system 1 according to the embodiment of the present invention, water is supplied during the entire start-up process, and the partial oxidation reforming reaction (POX) does not occur alone. In the time chart shown in FIG. 12, the reformer temperature at time t4 is about 200.degree. The reformer temperature is lower than the temperature at which the partial oxidation reforming reaction occurs, but the temperature detected by the reformer temperature sensor 148 (FIG. 6) is the average temperature of the reforming unit 20b. Actually, even at time t4, the reforming unit 20b partially reaches the temperature at which the partial oxidation reforming reaction occurs, and the steam reforming reaction is performed by the reaction heat of the generated partial oxidation reforming reaction. Is also triggered. As described above, in this embodiment, after the ignition, the supply of water is started before the reforming unit 20b reaches the temperature at which the partial oxidation reforming occurs, and the partial oxidation reforming reaction is performed independently. Will not occur.

Next, when the temperature detected by the reformer temperature sensor 148 reaches about 500 ° C. or higher, the process shifts from the ATR1 process to the ATR2 process at time t5 in FIG. At time t5, the water supply amount is changed from 2.0 cc / min to 3.0 cc / min. Further, the fuel supply amount, the reforming air supply amount, and the power generation air supply amount are maintained at the previous values. As a result, the steam / carbon ratio S / C in the ATR2 step is increased to 0.64, while the reforming air / carbon ratio O ₂ / C is maintained at 0.32. Thus, by maintaining the ratio of reforming air and carbon O ₂ / C constant, the ratio S / C of steam and carbon is increased, so that the amount of carbon that can be partially oxidized and reformed is not reduced. In addition, the amount of carbon that can be steam reformed is increased. This makes it possible to increase the amount of carbon subjected to steam reforming as the temperature of the reforming unit 20b increases while reliably avoiding the risk of carbon deposition in the reforming unit 20b.

Further, in the present embodiment at time t6 in FIG. 12, when the temperature detected by the power generation chamber temperature sensor 142 reaches about 400 ° C. or more, the ATR2 process is shifted to the ATR3 process. Accordingly, the fuel supply amount is changed from 5.0 L / min to 4.0 L / min, and the reforming air supply amount is changed from 9.0 L / min to 6.5 L / min. Also, the previous values are maintained for the water supply amount and the power generation air supply amount. This increases the steam / carbon ratio S / C in the ATR3 step to 0.80, while the reforming air to carbon ratio O ₂ / C is reduced to 0.29.

  Furthermore, when the temperature detected by the power generation chamber temperature sensor 142 reaches about 550 ° C. or higher at time t7 in FIG. 12, the process proceeds to the SR1 process. Along with this, the fuel supply amount is changed from 4.0 L / min to 3.0 L / min, and the water supply amount is changed from 3.0 cc / min to 7.0 cc / min. Further, the supply of the reforming air is stopped, and the power supply air supply amount is maintained at the previous value. Thus, in the SR1 process, steam reforming occurs exclusively in the reforming unit 20b, and the steam / carbon ratio S / C is 2 which is appropriate for steam reforming the entire amount of supplied fuel. .49. At time t7 in FIG. 12, since the temperature of both the reformer 20 and the fuel cell stack 14 is sufficiently increased, the steam reforming is performed even if the partial oxidation reforming reaction has not occurred in the reforming unit 20b. The reaction can be generated stably.

  Next, at time t8 in FIG. 12, when the temperature detected by the power generation chamber temperature sensor 142 reaches about 600 ° C. or more, the process proceeds to the SR2 process. Accordingly, the fuel supply amount is changed from 3.0 L / min to 2.5 L / min, and the water supply amount is changed from 7.0 cc / min to 6.0 cc / min. In addition, the previous value of the power supply air supply amount is maintained. Thereby, in the SR2 step, the ratio S / C of water vapor to carbon is set to 2.56.

  Further, after executing the SR2 process for a predetermined time, the process proceeds to the power generation process. In the power generation process, power is extracted from the fuel cell stack 14 to the inverter 54 (FIG. 6), and power generation is started. In the power generation process, the reforming unit 20b reforms the fuel exclusively by steam reforming. Further, in the power generation process, the fuel supply amount, the power generation air supply amount, and the water supply amount are changed corresponding to the output power required for the fuel cell module 2.

Next, with reference to FIG. 1 again, the normally open valve 46 for communicating between the power generation chamber 10 of the fuel cell module 2 and the outside air will be described.
As shown in FIG. 1, the power generation air is supplied from the air supply source 40 into the power generation chamber 10 of the fuel cell module 2 via the check valve 42 and the power generation air flow rate adjustment unit 45. On the other hand, the normally open valve 46 is provided in the middle of a pipe line directly connecting the air supply source 40 and the power generation chamber 10, and when this is opened, the check valve 42 and the power generation valve in the air supply system are provided. The air flow rate adjusting unit 45 is bypassed, and the outside air as the air supply source 40 and the power generation chamber 10 are directly communicated with each other. Thereby, the channel resistance of the channel for taking in air from the atmosphere into the power generation chamber 10 is reduced. Note that an air filter (not shown) or the like is provided between the air supply source 40 and the normally open valve 46, and the air supply source 40 and the power generation chamber even when the normally open valve 46 is opened. There is a predetermined flow path resistance. The normally open type valve 46 is a so-called normally open type valve, and is opened when the power source for operating it is lost. During the normal operation of the solid oxide fuel cell system 1, the normally open valve 46 is always closed, and automatically opens when power supply to the normally open valve 46 becomes impossible due to an emergency stop. Is done. That is, the normally open valve 46 is autonomously opened without receiving a control signal from the control unit 110 when the power supply is interrupted.

Next, stop of the solid oxide fuel cell system 1 according to the embodiment of the present invention will be described with reference to FIGS.
FIG. 13 is a flowchart of stop determination for selecting the emergency stop mode in the solid oxide fuel cell system 1 according to the embodiment of the present invention. The flowchart of FIG. 13 is a flowchart for determining which emergency stop mode to select based on a predetermined condition, and is repeated at predetermined time intervals during operation of the solid oxide fuel cell system 1. Executed.

  First, in step S1 of FIG. 13, it is determined whether or not the supply of fuel gas from the fuel supply source 30 (FIG. 1) and the supply of electric power from the commercial power source are stopped. When the supply of both fuel gas and electric power is stopped, the process proceeds to step S2, and in step S2, the first emergency stop mode is selected, and one process of the flowchart of FIG. 13 ends. As a case where the first emergency stop mode is selected, it is assumed that the supply of fuel gas and electric power is stopped due to a natural disaster or the like, and it is considered that the frequency of such a stop is extremely low.

  On the other hand, when at least one of the fuel gas and the electric power is supplied, the process proceeds to step S3. In step S3, it is determined whether the supply of the fuel gas is stopped and the electric power is supplied. To be judged. When the supply of the fuel gas is stopped and the electric power is supplied, the process proceeds to step S4. In other cases, the one-time process of the flowchart of FIG. 13 is ended. In step S4, the second emergency stop mode is selected, and the one-time process in the flowchart of FIG. 13 ends. As a case where the second emergency stop mode is selected, it is assumed that the supply of fuel gas is temporarily stopped due to construction of the fuel gas supply path, etc., and such a stop is performed less frequently. Conceivable.

  Note that when the supply of electric power is stopped and the supply of fuel gas is continued, no emergency stop mode is selected according to the flowchart of FIG. In such a case, the solid oxide fuel cell system 1 according to the present embodiment can continue the power generation by operating the auxiliary unit 4 with the electric power generated by the fuel cell stack 14. Note that the present invention can also be configured so that power generation is stopped when the supply of power continues for a predetermined long time.

Next, stop processing in each emergency stop mode will be described with reference to FIGS.
FIG. 14 schematically shows an example of stop behavior when the solid oxide fuel cell system 1 according to the embodiment of the present invention is stopped in the first emergency stop mode (step S2 in FIG. 13) in time series. It is a time chart.

  First, at time t101 in FIG. 14, the supply of fuel gas from the fuel supply source 30 (FIG. 1) and the supply of power from the commercial power supply are stopped, and this is determined in step S1 of the flowchart shown in FIG. Then, the operation of the control unit 110 is immediately stopped by the first emergency stop mode (step S2). When the operation of the control unit 110 is stopped, the supply of fuel by the fuel flow rate adjustment unit 38, the supply of water by the water flow rate adjustment unit 28, and the supply of power generation air by the power generation air flow rate adjustment unit 45 are stopped in a short time. To do. Further, the extraction of electric power from the fuel cell module 2 by the inverter 54 is also stopped (output current = 0). When the solid oxide fuel cell system 1 is stopped in the first emergency stop mode, the power supply to the normally open valve 46 (FIG. 1) is lost, and the normally open valve 46 is opened.

  The fuel cell module 2 is naturally left in this state after a shutdown stop in which fuel supply and power extraction are stopped. For this reason, the fuel existing on the fuel electrode side in each fuel cell unit 16 passes through the fuel gas flow channel 98 (FIG. 4) based on the pressure difference from the external air electrode side. Erupted to the side. Moreover, the air (and the fuel ejected from the fuel electrode side) that existed on the air electrode side of each fuel cell unit 16 is the pressure on the air electrode side (pressure in the power generation chamber 10 (FIG. 1)) and atmospheric pressure. Is discharged to the outside of the fuel cell module 2 through the exhaust passage 21b, the air heat exchanger 22 and the like. Therefore, as shown in FIG. 14, after the shutdown stop at time t101, the pressure on the fuel electrode side and the air electrode side of each fuel cell unit 16 naturally decreases. As described above, when the shutdown is stopped at time t101, the normally open valve 46 is also opened, and the power generation chamber 10 and the outside air (air supply source 40) communicate with each other through this route. However, the flow path resistance of the flow path that communicates the outside air with the power generation chamber 10 via the normally open valve 46 is set to be larger than the flow path resistance of the flow path that reaches the outside air through the air heat exchanger 22 or the like. ing. For this reason, almost all of the gas in the power generation chamber 10 is discharged through the air heat exchanger 22 and the like, and air is sucked from the flow path communicating with the outside air through the normally open valve 46.

  Further, as shown in FIG. 14, immediately after the shutdown stop at time t101, the pressure difference between the fuel electrode side and the air electrode side of each fuel cell unit 16 is the largest, and the fuel present on the fuel electrode side is A large amount flows out to the air electrode side through the fuel gas passage narrow tube 98 at the upper end of the fuel cell unit 16. In the state where the temperature of the fuel cell unit 16 immediately after the shutdown is stopped, if hydrogen or the like in the fuel touches the air electrode of the fuel cell unit 16, the air electrode may be reduced and damaged. However, since hydrogen flowing out from the fuel electrode side to the air electrode side is lighter than air, it stays above the fuel cell stack 14 in the fuel cell module 2 and avoids contact with the air electrode. Further, the fuel gas staying in the upper part in the fuel cell module 2 flows into the air heat exchanger 22 through the opening 21a (FIG. 2) of the rectifying plate 21 above the fuel cell stack 14, and the fuel cell module. 2 discharged outside. Therefore, the opening 21a of the rectifying plate 21 functions as an exhaust port for discharging the gas in the power generation chamber 10 to the air heat exchanger 22 side.

  Further, the fuel on the fuel electrode side is ejected to the air electrode side through the fuel gas flow passage narrow tube 98 which is a narrow tube. The fuel gas passage narrow tube 98 extends upward so that the outlet is close to the opening 21a which is an exhaust port. Since the fuel is injected toward the upper opening 21a, the injected fuel is kept away from the air electrode side, and the risk of air electrode reduction is reduced. Further, the flow path resistance in which the fuel on the fuel electrode side ejects to the air electrode side through the fuel gas flow path narrow tube 98 is such that the gas in the power generation chamber 10 is discharged to the outside air through the exhaust port (opening 21a). It is configured to be larger than the channel resistance of the channel. For this reason, the flow rate of the fuel flowing out from the fuel electrode side to the air electrode side becomes smaller than the flow rate of the gas discharged to the outside air through the opening 21a, and the discharged fuel is filled in the power generation chamber 10. Can be prevented.

  In addition, after the shutdown stop at time t101, the normally open valve 46 (FIG. 1) is opened. The flow path from the outside air (air supply source 40) through the normally open valve 46 to the fuel cell module 2 includes a power generation air introduction pipe 74 (FIG. 10) and a power generation air flow path 72 of the air heat exchanger 22. (FIG. 3), the outlet port 76a (FIG. 3), and the power generation air supply passage 77 (FIG. 3) are communicated with a large number of outlets 77a opened in the power generation chamber 10. Therefore, when the high temperature fuel flowing out from each fuel cell unit 16 is discharged from the opening 21a (FIG. 2) above the power generation chamber 10 by natural convection, the outside air taken in through the normally open valve 46 is discharged. Is drawn into the power generation chamber 10 from the outlet 77a provided at the lower portion of the power generation chamber 10. In other words, when the air is sucked into the power generation chamber 10 from the outlet 77a via the normally open valve 46, the fuel flowing out from each fuel cell unit 16 is easily discharged from the power generation chamber 10. Accordingly, the air outlet 77a functions as an air inflow port through which the outside air that has passed through the normally open valve 46 flows. Further, the normally open valve 46 functions as an emergency discharge unit that promotes the discharge of gas in the power generation chamber 10 by promoting natural convection in a state where the operation of the control unit 110 is stopped by an emergency stop. Thus, when the normally-open type valve 46 is opened when the shutdown stop is performed in the first emergency stop mode, the fuel flowing out from the fuel electrode side to the air electrode side touches the air electrode and is damaged. Risk is more reliably avoided.

Next, the second emergency stop mode will be described with reference to FIG.
FIG. 15 schematically shows an example of stop behavior when the second emergency stop mode (step S4 in FIG. 13) is executed in the solid oxide fuel cell system 1 according to the embodiment of the present invention. It is a time chart.

  First, the second emergency stop mode is a stop mode that is executed when only the fuel gas supply is stopped. When shutdown stop is performed at time t201 in FIG. 15, the supply of fuel by the fuel flow rate adjustment unit 38 and the supply of water by the water flow rate adjustment unit 28 are stopped in a short time. Further, the extraction of electric power from the fuel cell module 2 by the inverter 54 is also stopped (output current = 0). When the second emergency stop mode is executed, since the supply of commercial power is not lost, the operation of the control unit 110 is not stopped, and the normally open valve 46 is also closed. . In the second emergency stop mode, the shutdown stop circuit 110a incorporated in the control unit 110 executes temperature drop control immediately after the shutdown stop at time t201, and keeps the power generation air flow rate adjustment unit 45 at a maximum for a predetermined time. Operate with output. In the present embodiment, the time for operating the power generation air flow rate adjustment unit 45 is about 2 minutes. Further, after the power generation air flow rate adjustment unit 45 is stopped at time t202 in FIG. 15, it is left as it is in the same manner as in the first emergency stop mode, but the normally open valve 46 is kept closed. The That is, the emergency discharge means is not operated in the second emergency stop mode.

  In the stop in the second emergency stop mode, air is sent to the air electrode side of the fuel cell unit 16 after the shutdown stop. Thereby, in the A part of FIG. 15, the temperature by the side of the air electrode has fallen more rapidly than the case of the 1st emergency stop mode (FIG. 14). In the conventional fuel cell system, after the fuel supply is completely stopped, until the temperature of the fuel cell stack 14 decreases to the oxidation suppression temperature, air flows backward to the fuel electrode side to oxidize the fuel electrode, The air supply was always turned off because it was considered a risk of damage. However, the present inventors have found that power generation air can be safely supplied to the air electrode side for a predetermined time even after the fuel supply is stopped.

  That is, immediately after the shutdown is stopped, a sufficient amount of fuel gas remains on the fuel electrode side of each fuel cell unit 16, and this is in a state of being ejected from the upper end of each fuel cell unit 16. By sending air to the side, air does not flow backward to the fuel electrode side. That is, in this state, the pressure on the air electrode side is increased by sending air by the power generation air flow rate adjusting unit 45, but the pressure on the fuel electrode side is still higher than the pressure on the air electrode side. The fuel gas flowing out from the fuel electrode side to the air electrode side is discharged out of the fuel cell module 2 together with the supplied air when the air is sent by the power generation air flow rate adjusting unit 45.

  Furthermore, after the supply of air is stopped at time t202, it is left to stand as in the first emergency stop mode. However, in the second emergency stop mode, the power generation air flow rate adjustment unit 45 is operated after the shutdown stop, so that the fuel gas flowing out from the fuel electrode side to the air electrode side is discharged out of the fuel cell module 2. . Also at time t202 in FIG. 15, the pressure on the fuel electrode side is higher than that on the air electrode side, so that the fuel gas flows out from the fuel electrode side even after the power generation air flow rate adjustment unit 45 is stopped. However, at time t202, since the pressure on the fuel electrode side and the air electrode side are close to each other, the fuel gas flowing out from the fuel electrode side is greatly reduced.

  For this reason, hydrogen, which is the fuel gas ejected after the power generation air flow rate adjustment unit 45 is stopped, stays in the upper part of the fuel cell module 2 (above the fuel cell stack 14), but the ejected fuel gas is The air electrode of each fuel cell unit 16 does not substantially contact. Therefore, even when the normally open valve 46 is closed, the fuel gas is reduced by contacting the hot air electrode, and the air electrode is not deteriorated.

  According to the solid oxide fuel cell system 1 of the embodiment of the present invention, as an emergency discharge means for promoting the discharge of gas in the power generation chamber 10 in a state where the operation of the control unit 110 is stopped by an emergency stop, Since the open valve 46 (FIG. 1) is opened, the fuel gas that has flowed into the power generation chamber 10 can be effectively discharged even when the control by the control unit 110 is lost. As a result, it is possible to more reliably avoid the risk that the fuel gas that has flowed into the power generation chamber 10 after an emergency stop comes into contact with the air electrode, thereby degrading or damaging the air electrode of the fuel cell stack 14.

  Further, according to the solid oxide fuel cell system 1 of the present embodiment, the supply of commercial power is not lost in the second emergency stop (step S4 in FIG. 13) when only the fuel supply is stopped. Then, after the shutdown stop (time t201 in FIG. 15) is executed, the power generation air flow rate adjustment unit 45 is operated for a predetermined time (time t201 to t202 in FIG. 15). As a result, the fuel gas that has flowed into the power generation chamber 10 can be forcibly exhausted, and deterioration and damage of the air electrode can be reliably prevented. Further, since the power generation air flow rate adjusting unit 45 is operated for a predetermined time after the shutdown is stopped, after the fuel supply is stopped, air is supplied in a state where the pressure on the fuel electrode side is lowered, so that the fuel electrode of the air Backflow to the side can be prevented. Further, in the first emergency stop (step S2 in FIG. 13) when the supply of fuel and commercial power is stopped, in the state where the operation of the control unit 110 is stopped (after time t101 in FIG. 14), the normally open type By discharging the valve 46 autonomously, discharge of gas in the power generation chamber 10 is promoted. Thereby, even when the supply of fuel and commercial power is stopped, it is possible to reliably prevent deterioration and damage of the air electrode.

  Furthermore, according to the solid oxide fuel cell system 1 of the present embodiment, in the case of the second emergency stop in which the supply of commercial power is not lost (step S4 in FIG. 13), the emergency discharge means is normally open. The mold valve 46 is not opened, and the fuel gas flowing out only by the operation of the power generation air flow rate adjustment unit 45 can be surely exhausted.

  Further, according to the solid oxide fuel cell system 1 of the present embodiment, natural convection in the power generation chamber 10 is promoted by opening the normally open valve 46 (FIG. 1), and the gas in the power generation chamber 10 is discharged. Therefore, the discharge of the gas can be promoted without using power for forcibly discharging the gas in the power generation chamber 10.

  Furthermore, according to the solid oxide fuel cell system 1 of the present embodiment, the normally open valve 46 (FIG. 1) is used as an emergency discharge means, so that emergency discharge can be reliably performed with a simple configuration. Can do.

  Moreover, according to the solid oxide fuel cell system 1 of the present embodiment, the air supply system 10 can be passed from the atmosphere into the power generation chamber 10 only by bypassing a part of the air supply system normally used for air supply (FIG. 1). The flow path resistance for taking in air can be reduced, and the emergency discharge means can be configured with a simple structure.

  Furthermore, according to the solid oxide fuel cell system 1 of the present embodiment, the outside air that has passed through the normally open valve 46 (FIG. 1) flows in from the lower side of the power generation chamber 10, and the gas in the power generation chamber 10 having a high temperature. Is discharged from the upper opening 21a (FIG. 3), so that the fuel can be efficiently discharged by natural convection.

  In the solid oxide fuel cell system 1 of the present embodiment, the normally open valve 46 is open to the flow path resistance from the atmosphere to the power generation chamber 10 via the normally open valve 46 (FIG. 1). When set, the gas in the power generation chamber 10 is exhausted through the opening 21a by natural convection, and the outside air is set to be sucked into the power generation chamber 10 from each outlet 77a (FIG. 3). Thus, when the normally open valve 46 is opened, the gas in the power generation chamber 10 does not flow back through the normally open valve 46 and is discharged to the outside air, and the high temperature gas is not a normal exhaust path. Exhaust air from the outlet can be prevented.

  Furthermore, in the solid oxide fuel cell system 1 of the present embodiment, the flow resistance of the flow path for discharging the gas in the power generation chamber 10 to the outside air through the opening 21a (FIG. 3) is the fuel cell stack 14. The flow path resistance of the flow path through which the fuel flows out from the fuel electrode side to the air electrode side via the fuel gas flow path narrow tube 98 (FIG. 4) is configured. Thereby, the flow rate of the fuel flowing out from the fuel electrode side to the air electrode side can be made smaller than the flow rate of the gas discharged to the outside air through the opening 21a, and the discharged fuel is filled in the power generation chamber 10. Can be prevented.

  Further, according to the solid oxide fuel cell system 1 of the present embodiment, after the shutdown is stopped (time t101 in FIG. 14 and time t201 in FIG. 15), the fuel is a fuel gas flow channel tube 98 at the upper end of the fuel cell unit 16. (FIG. 4) is injected from the fuel electrode side to the air electrode side, and the outlet of the fuel gas channel narrow tube 98 extends so as to be close to the opening 21a (FIG. 3). The fuel injected to the air electrode side quickly flows into the opening 21a, and the risk that the injected fuel contacts the air electrode can be further reduced. Further, by changing the cross-sectional area of the fuel gas flow passage narrow tube 98, the flow passage resistance of the flow passage exhausted through the opening 21a is larger than the flow passage resistance of the flow passage from the fuel electrode side to the air electrode side. It can be adjusted easily so as to be small.

Next, a solid oxide fuel cell system according to a modified embodiment of the present invention will be described with reference to FIG. FIG. 16 is an overall configuration diagram of a solid oxide fuel cell system according to a modified embodiment of the present invention.
In the embodiment of the present invention described above, the normally open valve 46 is used as an emergency discharge means for promoting the discharge of the gas in the power generation chamber 10 in a state where the operation of the control unit 110 is stopped by an emergency stop. . In the present modification, a discharge fan operated by a storage battery is used as an emergency discharge means, unlike the above-described embodiment, and other configurations are the same as the above-described embodiment.

  As shown in FIG. 16, a solid oxide fuel cell system 200 according to a modified embodiment of the present invention includes a discharge fan 202 as an emergency discharge unit. The exhaust fan 202 is a blower fan provided in an exhaust gas exhaust pipe (corresponding to “exhaust gas exhaust pipe 82” in FIG. 10) from the fuel cell module 2. The discharge fan 202 is configured to operate by the power of the storage battery 202a, and is autonomously operated for a predetermined time after the operation of the control unit is stopped by the first emergency stop mode. That is, the discharge fan 202 operates for a predetermined time by the power of the storage battery 202a without receiving a control signal from the control unit 110 or supply of power, and discharges the gas in the power generation chamber 10. By operating the discharge fan 202, the gas in the power generation chamber 10 (fuel gas and air flowing out from the fuel electrode side) is forcibly forced out of the fuel cell module 2 via the air heat exchanger 22. Discharged. As a result, even when the supply of fuel and the supply of commercial power are stopped, the fuel gas that has flowed from the fuel electrode side to the air electrode side after the shutdown is stopped touches the air electrode of the fuel cell unit 16 to reduce the air electrode. Thus, the risk of damage can be avoided more reliably.

  The exhaust fan 202 is provided on the exhaust side of the fuel cell module 2, but the exhaust fan is provided on the intake side of the fuel cell module 2 instead of or in addition to the exhaust fan 202. Can also be provided. As indicated by an imaginary line in FIG. 16, a discharge fan 204 can be provided on the intake side of the fuel cell module 2. Similarly to the discharge fan 202, the discharge fan 204 is configured to be operated by the electric power of the storage battery 204a, and operates autonomously for a predetermined time after the operation of the control unit is stopped by the first emergency stop mode. Is done. When the discharge fan 204 is operated, the outside air is forcibly pushed from the lower part of the power generation chamber 10, and the fuel gas staying above the power generation chamber 10 passes through the air heat exchanger 22 and the fuel cell module. 2 is discharged outside. Thereby, the risk that the fuel gas flowing out from the fuel electrode side touches the air electrode and is damaged can be avoided more reliably.

  Further, in the above-described embodiment of the present invention, when the solid oxide fuel cell system 1 is shut down and stopped in the second emergency stop mode, the normally open valve 46 is maintained in a closed state. . As a modification of this embodiment, the present invention can also be configured so that the normally open valve 46 is opened even when stopped in the second emergency stop mode. As a further modification of the above-described modified embodiment, the discharge fan 202 and / or the discharge fan 204 are operated for a predetermined time even when the solid oxide fuel cell system 200 is stopped in the second emergency stop mode. The present invention can also be configured as described.

DESCRIPTION OF SYMBOLS 1 Solid oxide fuel cell system 2 Fuel cell module 4 Auxiliary machine unit 7 Heat insulation material (heat storage material)
8 Case 8a Communication opening 8b Falling wall 10 Power generation chamber 12 Fuel cell assembly 14 Fuel cell stack 16 Fuel cell unit (solid oxide fuel cell)
18 Combustion chamber (combustion section)
20 Reformer 20a Evaporating section (evaporating chamber)
20b Mixing part (pressure fluctuation absorbing means)
20c reforming part 20d evaporation / mixing part partition 20e partition opening 20f mixing / reforming part partition (pressure fluctuation absorbing means)
20g communication hole (narrow channel)
21 Rectifier plate (partition wall)
21a Opening (exhaust port)
21b Exhaust passage 21c Gas residence space 21d Vertical wall 22 Air heat exchanger (heat exchanger)
23 Heat insulating material for evaporation chamber (internal heat insulating material)
24 Water supply source 26 Pure water tank 28 Water flow rate adjustment unit (water supply device)
30 Fuel supply source 38 Fuel flow rate adjustment unit (fuel supply device)
39 Valve 40 Air supply source 42 Check valve 44 Reforming air flow rate adjustment unit (reforming air supply device)
45 Air flow rate adjustment unit for power generation (air supply device for power generation)
46 Normally open valve (emergency discharge means)
50 Hot water production equipment (heat exchanger for exhaust heat recovery)
52 Control box 54 Inverter 62 Reformer introduction pipe (water introduction pipe, preheating part, condensation part)
62a T-shaped tube (condensation part)
63a Water supply pipe 63b Fuel gas supply pipe 64 Fuel gas supply pipe 64c Pressure fluctuation suppressing flow path resistance 66 Manifold (dispersion chamber)
76 Air introduction pipe 77a Air outlet (Air inflow port)
82 Exhaust gas discharge pipe 83 Ignition device 84 Fuel cell 85 Exhaust valve 86 Inner electrode terminal (cap)
98 Fuel gas passage narrow tube (narrow tube)
110 Controller (Controller)
110a Shutdown stop circuit 110b Pressure hold control circuit 112 Operation device 114 Display device 116 Alarm device 126 Power state detection sensor (demand power detection means)
132 Fuel flow sensor (fuel supply detection sensor)
138 Pressure sensor (reformer pressure sensor)
142 Power generation chamber temperature sensor (temperature detection means)
148 Reformer Temperature Sensor 150 Outside Air Temperature Sensor 200 Solid Oxide Fuel Cell System 202 Discharge Fan (Emergency Discharge Unit) According to Modified Embodiment of the Present Invention
202a Storage battery 204 Discharge fan (emergency discharge means)
204a storage battery

Claims (11)

A solid oxide fuel cell system that generates electricity by reacting hydrogen generated by steam reforming of fuel and air,
A fuel cell module containing a fuel cell stack in a power generation chamber;
A fuel supply device for supplying fuel to the fuel cell module;
A water supply device for supplying water for steam reforming to the fuel cell module;
An air supply device for supplying air to the air electrode side of the fuel cell stack;
A reformer for steam reforming the fuel supplied from the fuel supply device using the water supplied from the water supply device and supplying the reformed fuel to the fuel electrode side of the fuel cell stack When,
A controller programmed to perform control of extraction of power from the fuel supply device, the water supply device, the air supply device, and the fuel cell module;
In a state where the operation of the controller is stopped by an emergency stop, emergency discharge means for promoting the discharge of gas in the power generation chamber,
A solid oxide fuel cell system comprising:   The emergency stop includes a first emergency stop when the supply of fuel and the supply of commercial power are stopped, and a second emergency stop when only the supply of fuel is stopped. In the first emergency stop, the air supply device is programmed to operate for a predetermined time after executing the shutdown stop for stopping the fuel supply by the fuel supply device and the extraction of electric power from the fuel cell module. 2. The solid oxide fuel cell according to claim 1, wherein the emergency discharge means autonomously promotes the discharge of gas in the power generation chamber after the fuel supply and the extraction of electric power are stopped due to the operation stop of the controller. system.   The solid oxide fuel cell system according to claim 2, wherein the emergency discharge means is not operated in the case of the second emergency stop.   4. The solid oxide fuel according to claim 3, wherein the emergency discharge means communicates the inside of the power generation chamber and the atmosphere and promotes natural convection in the power generation chamber to promote gas discharge in the power generation chamber. Battery system.   The emergency discharge means is composed of a normally open valve that is automatically opened when the supply of commercial power is stopped, and the normally open valve is opened to take air from the atmosphere into the power generation chamber. The solid oxide fuel cell system according to claim 4, wherein the flow path resistance of the flow path is lowered.   6. The solid oxide fuel according to claim 5, wherein the normally open valve is provided so as to bypass at least a part of an air supply system for supplying air from the atmosphere to the power generation chamber via the air supply device. Battery system.   An exhaust port for exhausting the gas in the power generation chamber during power generation operation is provided in the upper part of the power generation chamber, and the air inflow port for the outside air that has passed through the normally open valve flows from the exhaust port of the power generation chamber. The solid oxide fuel cell system according to claim 6, which is also provided below.   The flow path resistance of the flow path from the atmosphere to the power generation chamber via the normally open valve is such that when the normally open valve is opened, the gas in the power generation chamber is discharged from the exhaust port by natural convection, The solid oxide fuel cell system according to claim 7, wherein outside air is set to be sucked into the power generation chamber from the air inflow port.   The flow path resistance of the flow path for discharging the gas in the power generation chamber to the outside air through the exhaust port is configured to be smaller than the flow path resistance of the flow path from the fuel electrode side to the air electrode side of the fuel cell stack. The solid oxide fuel cell system according to claim 1.   The fuel cell stack is composed of a plurality of fuel cell units, and a thin tube that connects the fuel electrode side and the air electrode side is provided at the upper end of each fuel cell unit, and the outlet of the narrow tube is the exhaust port. The solid oxide fuel cell system according to claim 9, which extends upward so as to be close to the fuel cell.   The emergency discharge means includes a discharge fan that forcibly discharges the gas in the power generation chamber, and the discharge fan is autonomously operated for a predetermined time by the power of the storage battery after the operation of the controller is stopped. The solid oxide fuel cell system according to claim 2.

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