JP7221641B2 - Solid oxide fuel cell system - Google Patents

Description

TECHNICAL FIELD The present invention relates to a solid oxide fuel cell system having a cell stack that generates power through a fuel cell reaction between hydrogen gas and oxygen in the air.

2. Description of the Related Art Conventionally, solid oxide fuel cell systems in which a solid oxide cell stack using a solid electrolyte as a membrane that conducts oxide ions is housed in a container have been known. In this solid oxide fuel cell system, the cell stack is configured by stacking a plurality of fuel cells, and a fuel electrode for oxidizing fuel gas is provided on one side of the solid electrolyte in each fuel cell, An oxygen electrode for reducing oxygen (oxidant gas) in the air is provided on the other side. The operating temperature of this fuel cell is relatively high, about 700 to 1000° C. At such a high temperature, the hydrogen in the fuel gas and the oxygen in the air undergo an electrochemical reaction to generate electricity.

Typical small fuel cell systems for domestic use include a solid oxide fuel cell system (so-called SOFC) and a polymer electrolyte fuel cell system (so-called PEFC). In this polymer electrolyte fuel cell system (PEFC), the balance of the heat recovered from the fuel cell system (in other words, hot water stored in the hot water tank) is monitored with respect to the domestic hot water demand, and the fuel cell system Operation control is performed to stop the operation or restrict the power generation output. In addition, the solid oxide fuel cell system (SOFC) has high power generation efficiency and a small ratio of heat to power output. done. This type of operation control is also not suitable for frequent starting and stopping due to the high power generation temperature (so-called operating temperature) of the cell stack.

This solid oxide fuel cell system basically operates continuously day and night, and with regard to heat utilization, a hot water storage tank is used. keeps In the current solid oxide fuel cell system, high power generation efficiency can be obtained even at a power generation output scale of about 700 W. The efficiency is about 52% (AC sending end, lower heating value standard). If the power generation efficiency is high, the installer can obtain economic benefits even if it is installed in a house with low heat demand, and the target market is expected to expand. promoted as In the future, if the power generation efficiency is further improved, the installer will be able to obtain economic benefits and environmental friendliness with a simple form of heat utilization without heat utilization or hot water storage tanks, so further improvement of power generation efficiency is important. It has become.

A solid oxide fuel cell system suitable for home use includes a reformer for steam reforming the raw fuel gas, and fuel from the reformed fuel gas reformed by the reformer and the oxidant gas. A cell stack that generates electricity by cell reaction , an air supply means for supplying air as an oxidant gas to the oxygen electrode (air electrode) side of the cell stack, and a means for supplying raw fuel gas to the reformer. A fuel gas supply means is provided, and a cell stack and a reformer are housed in a high-temperature space in which a high temperature is maintained (see, for example, Patent Document 1).

In this solid oxide fuel cell system, a combustion zone is provided above the cell stack, and a reformer is arranged above this combustion zone. The reformed fuel gas from the reformer is supplied to the fuel electrode side of the cell stack, the air from the air supply means is supplied to the air electrode side of the cell stack, and the electrochemical reaction in the cell stack generates electricity. is done. Fuel off-gas from the fuel electrode side of the cell stack (that is, anode off-gas) and air off-gas from the air electrode side (that is, cathode off-gas) are fed to the combustion zone and burned, and the combustion heat is used to create a high-temperature space. is maintained at a high temperature, and the reformer and the like are heated.

As a solid oxide fuel cell system, instead of providing a combustion zone on the upper side of the cell stack, there has also been proposed a system provided with a dedicated combustor (see, for example, Patent Document 2). In this solid oxide fuel cell system, fuel off-gas (anode off-gas) from the fuel electrode side of the cell stack is supplied to the combustor through the fuel off-gas supply channel, and air off-gas from the air electrode side of the cell stack is supplied to the combustor. (Cathode off-gas) is fed to the combustor through the air off-gas feeding channel, where the fuel off-gas is combusted by the air off-gas, and the combustion heat is used to keep the high-temperature space at a high temperature, The reformer and the like are heated.

The power generation efficiency of such a solid oxide fuel cell system is approximately proportional to the product of the average generated voltage of the fuel cell and the fuel utilization rate. Hydrogen (H ₂ ) in the pole-side gas is consumed to produce water (H ₂ O). In general, the fuel electrode of a solid oxide fuel cell uses a cermet (a mixture of metallic nickel and ceramics) in which metallic nickel particles are present together with ceramic particles. As the hydrogen to water ratio (H ₂ /H ₂ O) increases, the metallic nickel particles will begin to oxidize. When the metal nickel particles on the fuel electrode side of the fuel cell are oxidized, their electrical resistance increases, so that no power is generated in the vicinity of the fuel electrode side exit of the fuel cell. The area where nickel particles are oxidized will expand, and the area where power generation will be difficult will expand.

On the other hand, the fuel electrode thus oxidized is reduced under other conditions during power generation (partial load operation state, start state, stop state, etc.) and returns to the nickel state, and the nickel particles are repeatedly oxidized and reduced. However, if the number of repetitions increases, there is a risk that the material on the fuel electrode side of the fuel cell will undergo dimensional changes. If the material on the fuel electrode side undergoes a dimensional change, cracks will occur in the solid electrolyte that is joined to the fuel electrode. For this reason, it is necessary to increase the fuel utilization rate of the solid oxide fuel cell system in order to increase the power generation efficiency of the system, but if it is too high, the cell stack may be damaged.

In addition, in terms of reaction equilibrium, in the operating temperature range of the solid oxide fuel cell (cell stack), if hydrogen (H ₂ ):water (H ₂ 0) is less than 5:95, hydrogen (H ₂ ) is known to oxidize. In fact, since water vapor is generated by power generation at the electrolyte/anode interface of the fuel cell, the H ₂ /H ₂ 0 value tends to be lower at the electrolyte/anode interface than in the bulk (gas flow path). . In addition, the distribution state of the fuel gas to each fuel cell and the distribution state of the fuel gas within the fuel cell are also added, and the upper limit of the fuel utilization rate that can actually be used is hydrogen (H ₂ ):water (H ₂ 0) is limited to much lower fuel utilization than 5:95.

As a method for improving the fuel utilization rate of a solid oxide fuel cell system, part of the fuel offgas (that is, anode offgas) used for power generation in the cell stack is returned to the supply side of the cell stack, and this returned fuel is It is well known to mix the off-gas with the fuel gas and feed it back to the cell stack. In this case, it is known that the fuel utilization rate of the fuel cell system can be further increased by removing carbon dioxide (CO2) and water (H2O) contained in the fuel off-gas (see, for example, Patent Document 3). ).

JP-A-2005-285340 Japanese Unexamined Patent Application Publication No. 2008-21596 Japanese Patent No. 2981571

However, the fuel cell system of Patent Document 3 is configured assuming a power generation output of several tens of KW or more. (Anode off-gas) is returned to the fuel gas supply side, and how to grasp the recycling rate of the fuel off-gas. Throughout this specification, the recycling rate is the ratio of the fuel off-gas flowing out from the fuel electrode side of the cell stack that is returned to the fuel gas supply side. is returned to the fuel supply side, and the remaining 70% is distributed so as to flow downstream, the recycling rate is expressed as 30%.

This recycling rate is determined by the pressure loss characteristics of the flow path such as the recycling flow path, the flow path from the vaporizer/reformer to the cell stack, and the flow path from the cell stack to the atmosphere, and the fuel gas supply means (e.g., fuel gas pump). ), and the higher the recycling rate, the higher the fuel utilization rate can be set. However, if the fuel utilization rate of the cell stack is set high while the recycling rate is low, the fuel utilization rate becomes too high, which may lead to a shortened life of the cell stack.

In such a solid oxide fuel cell system, electricity can be generated using hydrogen gas as the fuel gas. In general, the DC power generation efficiency in a fuel cell system is proportional to the product of the cell average voltage of the fuel cell and the fuel utilization rate. Even with the same cell average voltage and the same fuel utilization rate, there is a demerit of 7 to 10 points lower than in the case of power generation using hydrocarbon fuel gas represented by natural gas as fuel gas.

In order to eliminate this demerit when hydrogen gas is used as the fuel gas, it is conceivable to return part of the fuel off-gas from the cell stack to the fuel gas supply means. In order to suppress damage to the cell stack, it is desired to maintain an appropriate fuel utilization rate when the power generation efficiency is to be increased by means of

SUMMARY OF THE INVENTION An object of the present invention is to provide a solid oxide fuel cell system capable of maintaining an appropriate fuel utilization rate even when fuel off-gas is recycled.

A solid oxide fuel cell system according to claim 1 of the present invention comprises a cell stack that generates power through a fuel cell reaction between hydrogen gas as a fuel gas and oxygen in the air, and hydrogen gas on the fuel electrode side of the cell stack. a fuel gas supply passage for guiding gas; a fuel gas supply means for supplying hydrogen gas through the fuel gas supply passage; a fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas; an air supply passage for guiding air to the air electrode side of the stack; air supply means for supplying air through the air supply passage; fuel off-gas after power generation reaction in the cell stack; a combustor for burning the air off-gas after the power generation reaction; a fuel off-gas supply passage for guiding the fuel off-gas from the cell stack to the combustor; and a fuel off-gas from the cell stack to the combustor. and a controller for controlling the operation of the fuel gas supply means and the air supply means, wherein

A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided , the cooler is arranged in the fuel off-gas supply passage, and the fuel gas pressure adjusting means is disposed on the upstream side of the fuel gas supply means in the fuel gas supply passage, and the upstream side of the recycling passage is disposed in the fuel off-gas supply passage at the location of the cooler. is connected further downstream, the downstream side is connected between the arrangement portion of the fuel gas pressure adjustment means and the arrangement portion of the fuel gas supply means in the fuel gas supply passage, and further the fuel off-gas An oxygen ion-conducting oxygen concentration detection means for detecting the oxygen concentration is provided in the feed channel,

The fuel off-gas from the cell stack is supplied to the combustor after being cooled by the cooler, and part of the fuel off-gas supplied to the combustor from the cooler is supplied to the fuel gas supply means. is returned to the fuel gas supply passage through the recycling passage by the negative pressure generated by the operation of the controller, and the controller reduces the rotation speed of the fuel gas supply means when the concentration detected by the oxygen concentration detection means exceeds a set value. It is characterized by increasing the supply flow rate of the fuel gas and lowering the fuel utilization rate .

Further, the solid oxide fuel cell system according to claim 2 of the present invention includes a cell stack that generates power by a fuel cell reaction of hydrogen gas as fuel gas and oxygen in the air, and a fuel electrode side of the cell stack. a fuel gas supply passage for guiding hydrogen gas to the fuel gas supply passage, a fuel gas supply means for supplying hydrogen gas through the fuel gas supply passage, a fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas; an air supply channel for introducing air to the air electrode side of the cell stack; air supply means for supplying air through the air supply channel; fuel off-gas after power generation reaction in the cell stack; a combustor for burning the air off-gas after the power generation reaction of the stack; a fuel off-gas supply passage for guiding the fuel off-gas from the cell stack to the combustor; and the air off-gas from the cell stack. A solid oxide fuel cell system comprising: an air off-gas supply passage leading to a combustor; and a controller for controlling the operation of the fuel gas supply means and the air supply means,

A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided , the cooler is arranged in the fuel off-gas supply passage , and the fuel gas pressure adjusting means is disposed on the upstream side of the fuel gas supply means in the fuel gas supply passage, and the upstream side of the recycling passage is disposed in the fuel off-gas supply passage at the location of the cooler. is connected further downstream, the downstream side is connected between the arrangement portion of the fuel gas pressure adjusting means and the arrangement portion of the fuel gas supply means in the fuel gas supply passage, and further the fuel gas temperature sensing means is provided in association with the supply means, and a recycling valve is provided in the recycling flow path;

The fuel off-gas from the cell stack is supplied to the combustor after being cooled by the cooler, and part of the fuel off-gas supplied to the combustor from the cooler is supplied to the fuel gas supply means. is returned to the fuel gas supply passage through the recycling passage by the negative pressure generated by the operation of the controller, and the controller responds to the detection signal from the temperature detection means when the temperature detected by the temperature detection means exceeds a predetermined set temperature. The recycle valve is opened based on the above.

In addition, a solid oxide fuel cell system according to claim 3 of the present invention comprises a cell stack that generates power by a fuel cell reaction of hydrogen gas as a fuel gas and oxygen in the air, and a fuel electrode side of the cell stack. a fuel gas supply passage for guiding hydrogen gas to the fuel gas supply passage, a fuel gas supply means for supplying hydrogen gas through the fuel gas supply passage, a fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas; an air supply channel for introducing air to the air electrode side of the cell stack; air supply means for supplying air through the air supply channel; fuel off-gas after power generation reaction in the cell stack; a combustor for burning the air off-gas after the power generation reaction of the stack; a fuel off-gas supply passage for guiding the fuel off-gas from the cell stack to the combustor; and the air off-gas from the cell stack. A solid oxide fuel cell system comprising: an air off-gas supply passage leading to a combustor; and a controller for controlling the operation of the fuel gas supply means and the air supply means,

A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided, the cooler is arranged in the recycling passage, and the fuel gas pressure adjusting means The fuel gas supply means is arranged in the fuel gas supply channel upstream of the location where the fuel gas supply means is arranged, the upstream side of the recycling channel is connected to the fuel off-gas supply channel, and the downstream side of the recycling channel is connected to the fuel off-gas supply channel. It is connected between the portion where the fuel gas pressure adjusting means is arranged and the portion where the fuel gas supply means is arranged in the gas supply passage . An ionically conductive oxygen concentration detection means is provided,

Part of the fuel off-gas from the cell stack flows into the fuel gas supply passage through the recycling passage due to the negative pressure generated by the operation of the fuel gas supply means, and the fuel off-gas flowing through the recycling passage is After being cooled by a cooler, it is returned to the fuel gas supply passage, and the controller increases the rotation speed of the fuel gas supply means when the concentration detected by the oxygen concentration detection means exceeds a set value, and the fuel gas is is characterized by increasing the supply flow rate of the fuel and lowering the fuel utilization rate .

Further, the solid oxide fuel cell system according to claim 4 of the present invention comprises a cell stack that generates power by a fuel cell reaction with hydrogen gas as fuel gas and oxygen in the air, and a fuel electrode side of the cell stack. a fuel gas supply passage for guiding hydrogen gas to the fuel gas supply passage, a fuel gas supply means for supplying hydrogen gas through the fuel gas supply passage, a fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas; an air supply channel for introducing air to the air electrode side of the cell stack; air supply means for supplying air through the air supply channel; fuel off-gas after power generation reaction in the cell stack; a combustor for burning the air off-gas after the power generation reaction of the stack; a fuel off-gas supply passage for guiding the fuel off-gas from the cell stack to the combustor; and the air off-gas from the cell stack. A solid oxide fuel cell system comprising: an air off-gas supply passage leading to a combustor; and a controller for controlling the operation of the fuel gas supply means and the air supply means,

A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided, the cooler is arranged in the recycling passage, and the fuel gas pressure adjusting means The fuel gas supply means is arranged in the fuel gas supply channel upstream of the location where the fuel gas supply means is arranged, the upstream side of the recycling channel is connected to the fuel off-gas supply channel, and the downstream side of the recycling channel is connected to the fuel off-gas supply channel. A temperature detection means is connected between a portion where the fuel gas pressure adjusting means is arranged and a portion where the fuel gas supply means is arranged in the gas supply flow path, and further a temperature detection means is arranged in relation to the fuel gas supply means. and a recycling valve is disposed in the recycling flow path,
Part of the fuel off-gas from the cell stack flows into the fuel gas supply passage through the recycling passage due to the negative pressure generated by the operation of the fuel gas supply means, and the fuel off-gas flowing through the recycling passage is After the fuel gas is cooled by a cooler, it is returned to the fuel gas supply passage, and when the temperature detected by the temperature detection means exceeds a predetermined set temperature, the controller closes the recycle valve based on a detection signal from the temperature detection means. is opened.

According to the solid oxide fuel cell system according to claims 1 and 3 of the present invention, a cell stack that generates power by a fuel cell reaction of hydrogen gas as a fuel gas and oxygen in the air, and a fuel electrode of the cell stack fuel gas supply means for supplying hydrogen gas through the fuel gas supply channel to the side of the cell stack, air supply means for supplying air through the air supply channel to the air electrode side of the cell stack, and power generation reaction in the cell stack a combustor for combusting the post-fuel off-gas and air off-gas after the power generation reaction of the cell stack, and further a cooler for cooling the fuel off-gas and a recycle stream for recycling a portion of the fuel off-gas. Since the passage is provided, the fuel off-gas is cooled by the cooler, the water vapor contained in this fuel off-gas is condensed and removed, and the fuel off-gas from which the water vapor is removed (almost hydrogen gas only) becomes the fuel gas. It is returned to the feed channel, which can increase the power generation efficiency of the system.

Further, the fuel gas pressure adjusting means for adjusting the pressure of the hydrogen gas as the fuel gas is arranged upstream of the arrangement portion of the fuel gas supply means in the fuel gas supply channel, and the downstream side of the recycling channel is the fuel gas. Since it is connected between the location of the fuel gas pressure adjustment means and the location of the fuel gas supply means in the gas supply passage, part of the fuel off-gas supplied to the combustor is supplied to the fuel gas supply means. can be returned to the fuel gas supply channel through the recycling channel using the negative pressure generated by the operation of .

Further, since an oxygen ion-conducting oxygen concentration detection means for detecting the oxygen concentration is provided in the fuel off-gas supply passage, the operation of the fuel gas supply means is controlled based on the concentration detected by the oxygen concentration detection means. That is, when the detected concentration exceeds the set value, the fuel gas supply flow rate is increased to lower the fuel utilization rate, so that even if the fuel off-gas recycling rate deviates over time, the fuel utilization rate will fluctuate greatly. Therefore, it is possible to maintain an appropriate fuel utilization rate over a long period of time.

Further, according to the solid oxide fuel cell systems of claims 2 and 4 of the present invention , the basic configuration thereof is the same as that of the inventions of claims 1 and 3 of the present invention. Similar effects can be obtained. In addition, a temperature detection means is provided in relation to the fuel gas supply means, and when the temperature detected by the temperature detection means exceeds a predetermined set temperature, the recycle valve is opened and a part of the fuel off-gas is converted into fuel gas. Since it is recycled to the upstream side of the fuel gas supply means, the fuel off-gas does not flow to the upstream side of the fuel gas supply means through the recycling channel when the temperature of the fuel gas supply means is low. Condensation can be suppressed.

1 is a simplified diagram showing the entirety of a first embodiment of a solid oxide fuel cell system according to the present invention; FIG. FIG. 4 is a simplified diagram showing the entirety of a second embodiment of a solid oxide fuel cell system according to the present invention;

Hereinafter, embodiments of the solid oxide girder fuel cell system according to the present invention will be described with reference to the accompanying drawings. First, referring to FIG. 1, the solid oxide fuel cell system of the first embodiment will be described.

In FIG. 1, the illustrated solid oxide fuel cell system 2 consumes hydrogen gas at a low pressure (for example, about 2 kPa) as fuel gas to generate power, and hydrogen gas as fuel gas and It is equipped with a solid oxide cell stack 6 that generates electricity using the air.

The cell stack 6 is configured by stacking a plurality of solid oxide fuel cells for generating power through a fuel cell reaction via current collecting members, and conducts oxygen ions (not shown). It comprises a solid electrolyte, a fuel electrode provided on one side of the solid electrolyte, and an air electrode provided on the other side of the solid electrolyte, and zirconia doped with yttria, for example, is used as the solid electrolyte.

The fuel electrode side 8 of the cell stack 6 is connected to a fuel gas supply source (not shown) (consisting of, for example, a hydrogen gas tank) for supplying hydrogen gas through a fuel gas supply passage 14. , hydrogen gas from a fuel gas supply source is supplied to the fuel electrode side 8 of the cell stack 6 through the fuel gas supply channel 14 .

In this fuel gas supply channel 14, there are, in order from the cell stack 6 toward the upstream side, a first throttling member 22, a fuel gas pump 24 (constituting fuel gas supply means), a second throttling member 26, and a pressure adjusting member. A zero governor 28, a fuel flow rate sensor 30 (constituting fuel flow rate measuring means), and a shutoff valve 32 are provided. The fuel gas pump 24 pressurizes the hydrogen gas flowing through the fuel gas supply passage 14 and supplies it to the fuel electrode side 8 of the cell stack 6 . Further, the zero governor 28 adjusts the hydrogen gas supplied from the fuel gas supply source (not shown) through the fuel gas supply passage 14 to a predetermined pressure near atmospheric pressure, and the fuel gas flow rate sensor 30 detects the fuel gas supply flow rate. The flow rate of the hydrogen gas supplied through the passage 14 is measured, and when the shutoff valve 32 is closed, it shuts off the fuel gas supply passage 14 to stop the supply of hydrogen gas.

First and second throttle members 22 and 26 located on both sides of the fuel gas pump 24 are provided to stabilize the flow rate of hydrogen gas flowing through the fuel gas supply passage 14. The first throttle member 22 is, for example, a capillary. Consisting of a tube, the second throttling member 26 consists of, for example, a throttling member having a small orifice. Further, the fuel gas flow sensor 30 can be composed of, for example, a thermal flow sensor, and by using this thermal flow sensor, the flow rate of hydrogen gas can be instantaneously measured. When hydrogen gas can be stably supplied, the first throttle member 22 may be omitted, or the second throttle member 26 may be replaced with a buffer tank.

The air electrode side 36 of the cell stack 6 is connected through an air supply passage 38 to an air blower 40 as air supply means. ) are provided. The air blower 40 supplies air ( oxidant ) through the air supply channel 38 to the air electrode side 36 of the cell stack 6 , and the air flow rate sensor 42 measures the flow rate of the air flowing through the air supply channel 38 .

In this embodiment, the fuel gas pump 24 and air blower 40 are controlled by, for example, a controller (eg, comprising a microprocessor) (not shown) for controlling the overall system. The rotation control of the fuel gas pump 24 (and the air blower 40) is controlled by the duty ratio of the drive current (so-called drive duty ratio). increases and the supply flow rate of hydrogen gas (and air) increases. and thus the hydrogen gas (and air) feed rate is controlled.

Fuel off-gas (that is, anode off-gas) discharged from the fuel electrode side 8 of the cell stack 6 is supplied to the combustor 46 through the fuel off-gas supply passage 44, as will be described in detail later. Air off-gas discharged from the cathode side 36 (that is, cathode off-gas) is fed through an air off-gas feed channel 48 to a combustor 46 where it is fed from the fuel electrode side 8 of the cell stack 6. The fuel off-gas (containing hydrogen gas) and the air off-gas (containing oxygen) from the cathode side 36 are combusted, and the combustion heat of the fuel off-gas is used to heat the inside of the high temperature housing 54 (described later). heated. Combustion exhaust gas from the combustor 46 is discharged to the atmosphere through an exhaust gas discharge passage 50 .

In this embodiment, a first heat exchanger 56 is disposed in association with the exhaust gas discharge flow path 50 , the first heat exchanger 56 disposing the combustion exhaust gas flowing through the exhaust gas discharge flow path 50 from the combustor 46 . and the air flowing through the air supply passage 38 , and the air heated by this heat exchange is supplied to the air electrode side 36 of the cell stack 6 .

In this embodiment, cell stack 6 , combustor 46 and first heat exchanger 56 are housed in high temperature housing 54 . The high-temperature housing 54 is made of metal (for example, stainless steel), the inner surface of which is covered with a heat insulating member (not shown), and defines a high-temperature space 58 inside thereof, the cell stack 6 and the combustor. 46 and first heat exchanger 56 are kept hot in this hot space 58 .

The solid oxide fuel cell system 2 is further configured such that part of the fuel off-gas (anode off-gas) from the fuel electrode side 8 of the cell stack 6 is returned to the fuel gas supply channel 14 . In this embodiment, a recycle channel 66 is provided by branching from the fuel offgas supply channel 44 , and the second heat exchanger 60 is arranged in this recycle channel 66 . One end of the recycle channel 66 is connected to the fuel off-gas supply channel 44 inside the high temperature housing 54, and the other end is led out of the high temperature housing 54 and connected to the fuel gas supply channel 14 (specifically, the fuel gas supply channel 14). , a portion between the fuel gas pump 24 and the second throttle member 26 ), and the second heat exchanger 60 is disposed in a portion of the recycle flow path 66 led out of the high temperature housing 54 .

This second heat exchanger 60 is used, for example, in combination with a circulation flow path 62 of a hot water storage device (not shown) for a co-generation system for storing the heat of the fuel off-gas as hot water. Heat is exchanged between the fuel off-gas flowing through the water tank and the water from the hot water storage device, and hot water heated by this heat exchange is stored in a hot water storage tank (not shown) of the hot water storage device. This second heat exchanger 60 functions as a cooler for cooling the fuel off-gas, and the cooled fuel off-gas is returned to the fuel gas supply passage 14 .

A drain separator 64 is disposed downstream of the second heat exchanger 60, and water vapor contained in the fuel off-gas cooled by heat exchange by the second heat exchanger 60 is condensed into water. is separated from the fuel off-gas at the drain separator 64 and drained to the outside.

Next, the power generation operation of this solid oxide fuel cell system 2 will be described. During power generation operation, hydrogen gas as fuel gas from a fuel gas supply source (not shown) is supplied by the fuel gas pump 24 through the fuel gas supply passage 14, and the supplied fuel gas (hydrogen gas) , the fuel off-gas (anode off-gas) recycled through the recycling passage 66 as described above is mixed, the mixed gas is fed to the fuel gas pump 24, and the mixed gas pressurized by the fuel gas pump 24 becomes the fuel gas. It is fed to the fuel electrode side 8 of the cell stack 6 through the feed channel 14 . Also, the air from the air blower 40 is supplied to the air electrode side 36 of the cell stack 6 through the air supply channel 38 .

In the cell stack 6, power is generated by a fuel cell reaction of hydrogen gas flowing on the fuel electrode side 8 and air (oxygen in the air) flowing on the air electrode side 36. However, it is converted to AC power through a power conditioner and supplied to the household demand end. The fuel utilization rate in such a solid oxide fuel cell system means that the fuel gas (hydrogen gas) that has passed through the fuel gas flow rate sensor 30 (fuel gas flow rate measuring means) is oxidized at the fuel electrode side 8 of the cell stack 6. In other words, it refers to the rate of consumption in power generation in the cell stack 6 .

Fuel off-gas (containing hydrogen gas) from the anode side 8 of the cell stack 6 is delivered to the combustor 46 through the fuel off-gas delivery passage 44, and air off-gas (containing oxygen) from the cathode side 36 is delivered to the combustor 46. ) is fed to the combustor 46 through the air off-gas feed passage 48, where the fuel off-gas is combusted by the air off-gas, and the combustion exhaust gas from the combustor 46 is discharged through the exhaust gas discharge passage 50 emitted to the atmosphere through

During the power generation operation, in the first heat exchanger 56, heat is exchanged between the combustion exhaust gas flowing through the exhaust gas discharge passage 50 and the air flowing through the air supply passage 38, and heat is generated by this heat exchange. The depressurized air is delivered to the cathode side 36 of the cell stack 6 .

Also, part of the fuel off-gas that is delivered to the combustor 46 through the fuel off-gas delivery channel 44 is returned to the fuel gas supply channel 14 through the recycling channel 66 . At this time, in the second heat exchanger 60, heat is exchanged between the fuel off-gas flowing through the recycling flow path 66 and the water flowing through the circulation flow path 62 of the hot water storage device, for example. is condensed, and after this condensed water is removed by the drain separator 64, it is returned to the fuel gas supply passage 14 (specifically, the portion between the fuel gas pump 24 and the second throttle member 26), and this heat Hot water heated by the exchange is stored in a hot water storage tank (not shown) of the hot water storage device.

In this embodiment, the downstream side of the recycling passage 66 is located between the fuel gas pump 24 and the second throttle member 26 in the fuel gas supply passage 14, in other words, between the fuel gas pump 24 and the zero governor 8 (pressure adjusting member). , a negative pressure is generated on the upstream side of the fuel gas pump 24 when the fuel gas pump 24 is in operation, and part of the fuel off-gas flowing through the fuel off-gas supply passage 44 is recycled due to the negative pressure. It flows through the flow path 66 to the fuel gas supply flow path 14 , whereby a recycling blower (a blower for feeding a portion of the fuel off-gas through the recycling flow path 66 ) or an ejector (fuel off-gas using the fuel gas flow) A part of the fuel off-gas can be returned to the fuel gas supply channel 14 without using a suction device for sucking a part of the gas.

In this solid oxide fuel cell system 2, since hydrogen gas is used as the fuel gas, the hydrogen gas is only oxidized at the fuel electrode side 8 of the cell stack 6 to produce water. becomes a mixed gas in which hydrogen gas and water vapor are mixed, and the mixed gas is fed to the combustor 46, and the gas (i.e., hydrogen gas) obtained by removing the water vapor from the mixed gas is passed through the recycle flow path 66 as fuel gas. It is returned to the supply channel 14 .

In such a solid oxide fuel cell system, the recycling rate of the fuel off-gas is mainly: b) the flow resistance of the fuel off-gas flow path from the fuel electrode side outlet of the cell stack 6 to the discharge port of the exhaust gas discharge flow path 50; and c d) the negative pressure generated upstream of the fuel gas pump 24; The recycling rate refers to the ratio of the fuel off-gas supplied to the combustor 46 through the fuel off-gas supply channel 44 that is returned to the fuel gas supply channel 14 through the recycling channel 66 .

In the case of aiming for maintenance-free operation for about 10 years, the degree of change among these is large due to b) the influence on the pressure loss from the fuel electrode side outlet of the cell stack 6 to the outlet of the exhaust gas discharge passage 50. Large air flow rate. When the cell stack 6 deteriorates over time, heat generation increases. In order to suppress the temperature rise of the cell stack 6 due to this heat generation, the air supply flow rate is increased, and the temperature of the cell stack 6 is controlled by this air supply flow rate. to do

Therefore, in order to suppress the influence of fluctuations in the recycling rate due to changes in the flow path resistance, etc., an oxygen concentration detection means 68 (oxygen concentration detection sensor) for detecting the oxygen concentration is arranged in the fuel offgas supply flow path 66. is set. The oxygen concentration detection means 68 is disposed upstream of the fuel off-gas supply flow path 66 (in other words, downstream of the fuel electrode 8 side of the cell stack 6), and detects fuel flowing from the fuel electrode 8 side of the cell stack 6. Detects oxygen concentration in off-gas.

The oxygen concentration detection means 68 can be composed of an oxygen ion conductive oxygen concentration detection means such as a zirconia type oxygen concentration detection sensor. It can be detected with a fast response speed.

In this embodiment, a controller (not shown) controls the fuel gas pump 24 based on the detection signal (detection concentration) of the oxygen concentration detection means 68 as follows. That is, the number of rotations of the fuel gas pump 24 is controlled based on the detection signal of the oxygen concentration detection means 68, and the detection concentration is a predetermined value (that is, the set ratio of water (H ₂ O)/hydrogen (H ₂ )). The fuel gas supply flow rate is controlled so as not to exceed , and by controlling in this manner, the fuel utilization rate in the cell stack 6 can be maintained at an appropriate value.

For example, when the ratio of water/hydrogen exceeds this predetermined value, the ratio of hydrogen gas in the fuel off-gas is small. When the ratio of water/hydrogen is somewhat smaller than this predetermined value, the ratio of hydrogen gas in the fuel off-gas is large, and in such a case, the rotation of the fuel gas pump 24 is controlled. By reducing the number of fuel gas (hydrogen gas) supply flow rates to increase the fuel utilization rate and controlling the fuel gas pumps 24 in this way, even if the recycling rate changes over time, the Fuel utilization can continue to be maintained at a proper value over a period of time.

When hydrogen gas is used as the fuel gas, the product in the cell stack 6 is only water vapor, so cooling the fuel off-gas (anode off-gas) and removing water vapor in this fuel off-gas (that is, removing condensed water by cooling) ) is extremely effective in increasing power generation efficiency. In addition, under operating conditions of high power generation efficiency, the average cell voltage is in a high range, for example, 0.08 V or more, but when power is generated using hydrogen gas, natural gas (for example, city gas) is steam reformed. Since the current-voltage characteristics in the high voltage region are higher (for example, about several tens of mV higher) than in Due to the recycling of the fuel off-gas and the high current-voltage characteristics due to the use of hydrogen gas, sufficiently high power generation efficiency can be obtained even when hydrogen gas is used as the fuel gas.

In order to verify the effect when hydrogen gas is used as the fuel gas and the fuel off-gas is recycled, the following simulation was performed. For example, when using hydrogen gas as the fuel gas and using a cell stack that can stably generate power up to a fuel utilization rate of 85% without recycling, as shown in Table 1, the DC power generation efficiency (lower calorific value standard) is 56.6%.

In such a solid oxide fuel cell system, the recycling rate is set to 60%, and the temperature of the fuel off-gas returned through the recycling channel is cooled to a temperature of 20 ° C. (cooled to a dew point of 20 ° C. to remove water vapor). When simulating under the conditions, the fuel utilization rate when the supply flow rate of the fuel gas (hydrogen gas) is lowered until the detection concentration of the oxygen concentration detection sensor (oxygen concentration detection means) reaches the detection concentration under the conditions without recycling is The DC power generation efficiency at this time was 93.3%, and the DC power generation efficiency at this time was 62.1%, and the improvement of this DC power generation efficiency was 5.5 points (see Table 1).

家庭用の固体酸化物形燃料電池システムにおける補機類、パワーコンディショナーなどの消費電力を考慮すると、ＤＣ発電端効率に約０．９を積算した値がＡＣ送電端発電効率（低位発熱量基準）となる。尚、燃料オフガスのリサイクル率は実用構成では直接測定することができないが、リサイクル流路に圧力損失の小さい流量計測センサを挿入することにより、流量計測センサの計測流量を利用してリサイクル率を求めることができる。

Considering the power consumption of auxiliary equipment, power conditioners, etc. in a solid oxide fuel cell system for home use, the value obtained by multiplying the DC net power generation efficiency by about 0.9 is the AC net power generation efficiency (lower calorific value standard). becomes. The fuel off-gas recycling rate cannot be directly measured in a practical configuration, but by inserting a flow rate measuring sensor with low pressure loss into the recycling flow path, the recycling rate can be obtained using the flow rate measured by the flow rate measuring sensor. be able to.

In such a solid oxide fuel cell system, the air blower is controlled so as to increase the supply flow rate of air by about 1.5 times as the cell stack changes over time. When the air supply flow rate is increased to about 1.5 times as described above, the fuel off-gas recycling rate naturally increases to about 63%. When the supply flow rate of the fuel gas (hydrogen gas) is lowered until the detection concentration reaches the detection concentration under the conditions without recycling, the fuel utilization rate is 93.8%, and the DC power generation efficiency at this time is 62. .4%, and the improvement in DC power generation efficiency was 5.8 points.

In the solid oxide fuel cell system 2 of the embodiment shown in FIG. A portion of the flowing fuel off-gas is directed out of the high temperature housing 54 through a recycle passage 66 and cooled outside the high temperature housing 54 in the second heat exchanger 60 to condense and remove water vapor, which cools and removes water vapor. Although the removed fuel off-gas is returned to the upstream side of the fuel gas pump 24, it can be similarly applied to solid oxide fuel cell systems of the following forms.

A second embodiment of the solid oxide fuel cell system will be described with reference to FIG. In the solid oxide fuel cell system of the second embodiment, members that are substantially the same as those of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

In FIG. 2, in the illustrated solid oxide fuel cell system 2A, the fuel offgas feed passage 44A that guides the fuel offgas from the cell stack 6 to the combustor 46 is led out of the high temperature housing 54 and then again into the high temperature housing. 54 and connected to combustor 46 . In relation to this, a third heat exchanger 72 is disposed within the high temperature housing 54, and in this third heat exchanger 72, heat is supplied to the outside of the high temperature housing 54 through the upstream portion of the fuel offgas feed passage 44A. and the fuel off-gas flowing to the combustor 46 through the downstream portion of the fuel off-gas supply passage 44A, and the fuel off-gas cooled outside the high temperature housing 54 is heated by heat exchange. Afterwards, it is delivered to combustor 46 .

A second heat exchanger 60 and a drain separator 64 are arranged at an intermediate portion of the fuel off-gas supply flow path 44A (in other words, a portion located outside the high temperature housing 54). This second heat exchanger 60 is, for example, a circulation flow path of a hot water storage device (not shown) for a co-generation system for storing the heat of the fuel off-gas as hot water, as in the first embodiment described above. 62, heat exchange is performed between the fuel off-gas flowing through the fuel off-gas supply passage 44A and the water flowing through the circulation passage 62 from the hot water storage device, and hot water heated by this heat exchange is stored. It is stored in the hot water storage tank (not shown) of the device. This second heat exchanger 60 also functions as a cooler for cooling the fuel off-gas, water vapor in the cooled fuel off-gas is condensed, and this condensed water is drained outside through the drain separator 64 .

In the second embodiment, the fuel offgas feed channel 44A branches from an intermediate portion (specifically, a portion located outside the high temperature housing 54 and downstream of the drain separator 64). A recycle flow path 66A is provided at the end, and the downstream side of the recycle flow path 66A is connected to the fuel gas supply flow path 14 (specifically, the portion between the fuel gas pump 24 and the second throttle member 26). With this configuration, the fuel off-gas from which water vapor has been removed by cooling is returned to the fuel gas supply channel 14 through the recycling channel 66A.

In this second embodiment, a recycle valve 74 may be further provided in the recycle flow path 66A, and the recycle valve 74 may be controlled as follows. For example, the fuel gas pump 24 (fuel gas supply means) is provided with temperature detection means (for example, a temperature detection sensor), and when the temperature detected by this temperature detection means exceeds a predetermined temperature (for example, 30° C.), this temperature detection is performed. The recycle valve 74 may be opened based on the detection signal from the means. With this configuration, when the temperature of the fuel gas pump 24 is low, the fuel off-gas does not flow to the upstream side of the fuel gas pump 24 through the recycle flow path 66A. Condensation is prevented.

The configuration provided with such a recycle valve 74 can also be applied to the first embodiment, and the temperature detected by the temperature detection means includes the temperature inside the power generation system, the cooling temperature of the fuel off-gas, and the like. This temperature sensing means may be provided in association with the fuel gas pump 24 . Other configurations of the solid oxide fuel cell system 2A of the second embodiment are substantially the same as those of the first embodiment described above.

In the solid oxide fuel cell system 2A of the second embodiment, the fuel off-gas from the fuel electrode side of the cell stack 6 is supplied to the combustor 46 through the fuel off-gas supply passage 44A. The fuel off-gas thus produced is combusted by the air off-gas supplied from the air electrode side of the cell stack 6 through the air off-gas supply passage 48 . In addition, part of the fuel off-gas flowing through the fuel off-gas supply channel 44A is returned to the fuel gas supply channel 14 (specifically, the upstream portion of the fuel gas pump 24) through the recycling channel 66A, and the fuel gas supply flow It is mixed with the fuel gas (hydrogen gas) flowing through the passage 14 and supplied to the cell stack 6 .

The fuel off-gas flowing through the recycle flow path 66A is cooled by heat exchange in the second heat exchanger 60, water in the fuel off-gas is condensed by this cooling, and the condensed water is separated from the fuel off-gas by the drain separator 64. Afterwards, the fuel off-gas from which water vapor has been removed is returned to the fuel gas supply channel 14 .

Also in this solid oxide fuel cell system 2A, an oxygen concentration detection means 68 (oxygen concentration detection sensor) is disposed in the fuel off-gas supply passage 44A, and the fuel gas pump is operated based on the concentration detected by this oxygen concentration detection means 68. 24 is controlled, even if the recycling rate changes over time, the flow rate of the fuel gas (hydrogen gas) supplied by the fuel gas pump 24 can be controlled as required. , the fuel utilization rate can be maintained at a proper value for a long period of time.

2, 2A Solid oxide fuel cell system 6 Cell stack 14 Fuel gas supply channel 24 Fuel gas pump 44, 44A Fuel off-gas supply channel 46 Combustor 54 High temperature housing 66, 66A Recycle channel 74 Recycle valve

Claims (4)

A cell stack that generates electricity by a fuel cell reaction of hydrogen gas as a fuel gas and oxygen in the air, a fuel gas supply channel for guiding the hydrogen gas to the fuel electrode side of the cell stack, and the fuel gas supply channel. fuel gas supply means for supplying hydrogen gas through, fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas, an air supply passage for introducing air to the air electrode side of the cell stack, and the air supply means for supplying air through an air supply passage; a combustor for burning fuel off-gas after power generation reaction in the cell stack and air off-gas after power generation reaction in the cell stack; a fuel offgas feed passage for guiding fuel offgas from the stack to the combustor; an air offgas feed passage for guiding air offgas from the cell stack to the combustor; the fuel gas supply means; A solid oxide fuel cell system comprising a controller for controlling the operation of the air supply means,
A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided , the cooler is arranged in the fuel off-gas supply passage, and the fuel gas pressure adjusting means is disposed on the upstream side of the fuel gas supply means in the fuel gas supply passage, and the upstream side of the recycling passage is disposed in the fuel off-gas supply passage at the location of the cooler. is connected further downstream, the downstream side is connected between the arrangement portion of the fuel gas pressure adjustment means and the arrangement portion of the fuel gas supply means in the fuel gas supply passage, and further the fuel off-gas An oxygen ion-conducting oxygen concentration detection means for detecting the oxygen concentration is provided in the feed channel,
The fuel off-gas from the cell stack is supplied to the combustor after being cooled by the cooler, and part of the fuel off-gas supplied to the combustor from the cooler is supplied to the fuel gas supply means. is returned to the fuel gas supply passage through the recycling passage by the negative pressure generated by the operation of the controller, and the controller reduces the rotation speed of the fuel gas supply means when the concentration detected by the oxygen concentration detection means exceeds a set value. A solid oxide fuel cell system characterized by increasing the supply flow rate of the fuel gas and lowering the fuel utilization rate . A cell stack that generates electricity by a fuel cell reaction of hydrogen gas as a fuel gas and oxygen in the air, a fuel gas supply channel for guiding the hydrogen gas to the fuel electrode side of the cell stack, and the fuel gas supply channel. fuel gas supply means for supplying hydrogen gas through, fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas, an air supply passage for introducing air to the air electrode side of the cell stack, and the air supply means for supplying air through an air supply passage; a combustor for burning fuel off-gas after power generation reaction in the cell stack and air off-gas after power generation reaction in the cell stack; a fuel offgas feed passage for guiding fuel offgas from the stack to the combustor; an air offgas feed passage for guiding air offgas from the cell stack to the combustor; the fuel gas supply means; A solid oxide fuel cell system comprising a controller for controlling the operation of the air supply means,
A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided, the cooler is arranged in the fuel off-gas supply passage, and the fuel gas pressure adjusting means is disposed on the upstream side of the fuel gas supply means in the fuel gas supply passage, and the upstream side of the recycling passage is disposed in the fuel off-gas supply passage at the location of the cooler. is connected further downstream, the downstream side is connected between the arrangement portion of the fuel gas pressure adjusting means and the arrangement portion of the fuel gas supply means in the fuel gas supply passage, and further the fuel gas temperature sensing means is provided in association with the supply means, and a recycling valve is provided in the recycling flow path;
The fuel off-gas from the cell stack is supplied to the combustor after being cooled by the cooler, and part of the fuel off-gas supplied to the combustor from the cooler is supplied to the fuel gas supply means. is returned to the fuel gas supply passage through the recycling passage by the negative pressure generated by the operation of the controller, and the controller responds to the detection signal from the temperature detection means when the temperature detected by the temperature detection means exceeds a predetermined set temperature. A solid oxide fuel cell system, characterized in that the recycle valve is opened based on the above. A cell stack that generates electricity by a fuel cell reaction of hydrogen gas as a fuel gas and oxygen in the air, a fuel gas supply channel for guiding the hydrogen gas to the fuel electrode side of the cell stack, and the fuel gas supply channel. fuel gas supply means for supplying hydrogen gas through, fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas, an air supply passage for introducing air to the air electrode side of the cell stack, and the air supply means for supplying air through an air supply passage; a combustor for burning fuel off-gas after power generation reaction in the cell stack and air off-gas after power generation reaction in the cell stack; a fuel offgas feed passage for guiding fuel offgas from the stack to the combustor; an air offgas feed passage for guiding air offgas from the cell stack to the combustor; the fuel gas supply means; A solid oxide fuel cell system comprising a controller for controlling the operation of the air supply means,
A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided , the cooler is arranged in the recycling passage, and the fuel gas pressure adjusting means The fuel gas supply means is arranged in the fuel gas supply channel upstream of the location where the fuel gas supply means is arranged, the upstream side of the recycling channel is connected to the fuel off-gas supply channel, and the downstream side of the recycling channel is connected to the fuel off-gas supply channel. It is connected between the portion where the fuel gas pressure adjusting means is arranged and the portion where the fuel gas supply means is arranged in the gas supply passage. An ionically conductive oxygen concentration detection means is provided,
Part of the fuel off-gas from the cell stack flows into the fuel gas supply passage through the recycling passage due to the negative pressure generated by the operation of the fuel gas supply means, and the fuel off-gas flowing through the recycling passage is After being cooled by a cooler, it is returned to the fuel gas supply passage, and the controller increases the rotation speed of the fuel gas supply means when the concentration detected by the oxygen concentration detection means exceeds a set value, and the fuel gas is A solid oxide fuel cell system characterized by increasing the supply flow rate of and lowering the fuel utilization rate . A cell stack that generates electricity by a fuel cell reaction of hydrogen gas as a fuel gas and oxygen in the air, a fuel gas supply channel for guiding the hydrogen gas to the fuel electrode side of the cell stack, and the fuel gas supply channel. fuel gas supply means for supplying hydrogen gas through, fuel gas pressure adjustment means for adjusting the pressure of the hydrogen gas, an air supply passage for introducing air to the air electrode side of the cell stack, and the air supply means for supplying air through an air supply passage; a combustor for burning fuel off-gas after power generation reaction in the cell stack and air off-gas after power generation reaction in the cell stack; a fuel offgas feed passage for guiding fuel offgas from the stack to the combustor; an air offgas feed passage for guiding air offgas from the cell stack to the combustor; the fuel gas supply means; A solid oxide fuel cell system comprising a controller for controlling the operation of the air supply means,
A cooler for cooling the fuel off-gas and a recycling passage for recycling a part of the fuel off-gas are provided, the cooler is arranged in the recycling passage, and the fuel gas pressure adjusting means The fuel gas supply means is arranged in the fuel gas supply channel upstream of the location where the fuel gas supply means is arranged, the upstream side of the recycling channel is connected to the fuel off-gas supply channel, and the downstream side of the recycling channel is connected to the fuel off-gas supply channel. A temperature detection means is connected between a portion where the fuel gas pressure adjustment means is arranged and a portion where the fuel gas supply means is arranged in the gas supply passage, and temperature detection means is connected to the fuel gas supply means. and a recycling valve is disposed in the recycling flow path,
Part of the fuel off-gas from the cell stack flows into the fuel gas supply passage through the recycling passage due to the negative pressure generated by the operation of the fuel gas supply means, and the fuel off-gas flowing through the recycling passage is After the fuel gas is cooled by a cooler, it is returned to the fuel gas supply passage, and when the temperature detected by the temperature detection means exceeds a predetermined set temperature, the controller closes the recycle valve based on a detection signal from the temperature detection means. in an open state.

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