JP2006313687A - Solid oxide fuel cell system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solid oxide fuel cell system with its maintenance cost reduced and a system structure simplified. <P>SOLUTION: The solid oxide fuel cell system is provided with a desulfurizer 6 for removing sulfur components in fuel gas, a humidifier 8 humidifying the fuel gas, an fuel reformer 10 reforming the humidified fuel gas with vapor, a solid oxide fuel cell 4 generating power through fuel cell power generation reaction with the reformed gas as fuel, and a carbon dioxide gas mixing means for mixing carbon dioxide gas in the fuel gas at an upstream side of the humidifier. The carbon dioxide gas mixing means is constituted of a reformed gas recycling flow channel 53, in which, part of the reformed gas reformed at the fuel reformer 10 is recycled to an upstream side of a booster 28 through the reformed gas recycling flow channel 53, and part of the reformed gas containing carbon dioxide gas is mixed in the fuel gas, whereby, deposition of calcium components in the humidifier 8 can be restrained. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a solid oxide fuel cell system that performs fuel cell reaction by humidifying a fuel gas and steam reforming the humidified fuel gas.

  Currently, solid oxide fuel cells are being developed as one of the fuel cells because they can generate power with high power generation efficiency. In this solid oxide fuel cell, a solid electrolyte that conducts oxygen ions is used as an electrolyte, and a fuel electrode and an air electrode are provided on both sides of the solid electrolyte. As the solid electrolyte, zirconia doped with yttria is generally used. For example, when a fuel gas mainly composed of methane (for example, natural gas) is used as a raw fuel gas, a reformed gas (including hydrogen, carbon monoxide, hydrocarbons, etc.) obtained by a reforming reaction of the raw fuel gas is included. Is supplied to the fuel electrode, and air (containing oxygen) is supplied to the air electrode. In such a solid oxide fuel cell, electric power is generated by electrochemical reaction of reformed gas (hydrogen, carbon monoxide, hydrocarbon) and oxygen at a high temperature of 700 to 1000 ° C.

  When a hydrocarbon such as methane gas is used as the raw fuel gas, it is necessary to reform the fuel gas and supply the reformed gas to the solid oxide fuel cell. Known reforming methods for fuel gas include steam reforming using steam and partial oxidation reforming using oxygen. In the steam reforming, a steam reforming reaction represented by the reaction formula (1) is performed, and in the partial oxidation reforming, a partial oxidation reforming reaction represented by the reaction formula (2) is performed.

CH ₄ + H ₂ O → 3H ₂ + CO (1)
CH ₄ + 1 / 2O ₂ → 2H ₂ + CO (2)
As understood from the reforming reaction described above, in the partial oxidation reforming reaction, a part of the fuel gas is combusted, so that the power generation efficiency is lower than when reforming is performed by the steam reforming reaction. Therefore, in order to increase the power generation efficiency of the fuel cell system, the steam reforming reaction is generally used, but the steam reforming reaction and the partial oxidation reforming reaction may be performed in combination. In order to perform this steam reforming, steam (water) is required to reform the fuel gas. For this reason, in a solid oxide fuel cell system that performs a steam reforming reaction, water is supplied to the fuel gas. It is equipped with a steam generator and a humidifier.

  In such a fuel cell system, as water supplied to a steam generator or the like, pure water obtained by purifying water (tap water) by removing salt from a reverse osmosis membrane or an ion exchange resin is usually used. Is used (see, for example, Patent Document 1). If clean water is supplied to a steam generator or the like without refining treatment, the calcium salt or sodium salt contained in the clean water may precipitate in the steam generator or the pipe and the pipe may be clogged. Because there is.

JP-A-61-253770

  However, when a reverse osmosis membrane device or ion exchange resin device is used to supply pure water to a steam generator or the like, the life of the reverse osmosis membrane or ion exchange resin is managed to maintain the purity of pure water. Therefore, there is a problem that maintenance work for that purpose is complicated and maintenance costs are generated. Further, the provision of such a reverse osmosis membrane device or ion exchange resin device has a problem that the fuel cell system itself becomes complicated and large. For these reasons, it is not suitable to employ a reverse osmosis membrane device or an ion exchange resin device in a fuel cell system for home use or small-scale business. On the other hand, in the solid oxide fuel cell system, pure water is used only for reforming the fuel gas. Therefore, if water vapor can be stably supplied for a long time using clean water, The apparatus for producing | generating this becomes unnecessary.

  An object of the present invention is to provide a solid oxide fuel cell system capable of reducing maintenance costs and simplifying the system configuration.

A solid oxide fuel cell system according to claim 1 of the present invention includes a desulfurizer for removing sulfur components contained in fuel gas, a humidifier for humidifying the desulfurized fuel gas, and a humidifier. A fuel reformer for steam reforming the generated fuel gas, a fuel electrode and an air electrode, and the reformed gas fed to the fuel electrode side after steam reforming and the gas reformer sent to the air electrode side A solid oxide fuel cell system comprising: a solid oxide fuel cell that generates power by performing a fuel cell power generation reaction with air that is generated;
The humidifier is supplied with clean water, and in association with the humidifier, a carbon dioxide gas mixing means for mixing carbon dioxide gas into the fuel gas is provided, and the carbon dioxide gas mixing means is the humidifier or the humidifier. In the humidifier, the fuel gas containing carbon dioxide and the clean water are brought into contact with each other, thereby preventing the precipitation of calcium components contained in the clean water. It is characterized by that.

  Further, in the solid oxide fuel cell system according to claim 2 of the present invention, the carbon dioxide mixing means is adapted to recycle part of the reformed gas steam-reformed by the fuel reformer. A reformed gas recycling channel, one end of the reformed gas recycling channel is connected to the humidifier or upstream of the humidifier, and a part of the reformed gas is mixed into the fuel gas. Features.

  In the solid oxide fuel cell system according to claim 3 of the present invention, a booster for pumping fuel gas is disposed upstream of the desulfurizer, and the reformed gas recycling flow is provided. An upstream side of the path is connected to a downstream side of the fuel reformer, a downstream side of the reformed gas recycle channel is connected to an upstream side of the booster, and the reforming is steam reformed in the fuel reformer A part of the gas is recycled from the fuel reformer to the upstream side of the booster through the reformed gas recycling flow path.

  Moreover, in the solid oxide fuel cell system according to claim 4 of the present invention, the carbon dioxide gas mixing means is a part of the exhaust gas after the fuel cell power generation reaction is performed in the solid oxide fuel cell. The exhaust gas recycle channel is configured to be connected to one end of the exhaust gas recycle channel to the humidifier or the upstream side of the humidifier, and a part of the exhaust gas is mixed into the fuel gas. It is characterized by that.

  Furthermore, in the solid oxide fuel cell system according to claim 5 of the present invention, the carbon dioxide gas mixing means is composed of an oxidation reactor that oxidizes a part of the fuel gas, and is oxidized in the oxidation reactor. The oxidation reaction gas of the reacted fuel gas is mixed into the fuel gas.

  According to the solid oxide fuel cell system of the first aspect of the present invention, the carbon dioxide gas mixing means for mixing the carbon dioxide gas is provided, and the carbon dioxide gas mixing means is provided at the upstream side of the humidifier or the humidifier. Since carbon dioxide gas is mixed into the fuel gas, the fuel gas containing carbon dioxide gas flows through the humidifier. Therefore, fuel gas containing carbon dioxide comes into contact with tap water (tap water) in the humidifier, and precipitation of calcium components contained in tap water can be suppressed by the action of carbon dioxide in the fuel gas. It is possible to supply clean water to the humidifier stably in the long term. Accordingly, it is not necessary to provide a water purification device such as a reverse osmosis membrane device or an ion exchange resin device, and there is no maintenance cost associated with cleaning or replacement of these devices, which is convenient as a fuel cell system for home use or small-scale business. Things can be provided.

  The effect of suppressing the precipitation of the calcium component by including carbon dioxide in the fuel gas will be described as follows. Generally, tap water (tap water) contains several mg / L to several tens mg / L of calcium component, and the calcium component is dissolved as calcium bicarbonate as shown by the equilibrium equation (a). The calcium hydrogen carbonate is precipitated as calcium carbonate.

Ca (HCO ₃ ) ₂ = CaCO ₃ + CO ₂ + H ₂ O (a)
As shown in Table 1, the solubility of this calcium carbonate in pure water is lower at a higher temperature (80 ° C.) than at room temperature (20 ° C.). Therefore, the higher the temperature of calcium bicarbonate contained in clean water, the higher the temperature. It is known to precipitate as calcium carbonate.

一方、例えばメタンを主成分とする燃料ガスを燃料電池に供給するためには、カーボンの析出を防止するために、スチーム／カーボン比（燃料ガス中の水蒸気と炭素のモル比）を１．５以上にする必要があり、このようにするためには、加湿後の燃料ガスとスチームとの混合ガスの露点を８８〜９０℃にする必要があり、このような露点にするためには、加湿器内の上水を９０℃以上に加熱しなければならない。そのために、加湿するための水として上水を用いた場合、上水に含まれるカルシウム成分は炭酸カルシウムとして析出しやすく、長期的に安定して加湿器を作動させることが難しくなる。

On the other hand, for example, in order to supply a fuel cell containing methane as a main component to a fuel cell, a steam / carbon ratio (molar ratio of water vapor to carbon in the fuel gas) is set to 1.5 in order to prevent carbon deposition. In order to do so, it is necessary to set the dew point of the mixed gas of fuel gas and steam after humidification to 88 to 90 ° C. In order to obtain such a dew point, humidification is required. The water in the vessel must be heated above 90 ° C. Therefore, when clean water is used as water for humidification, the calcium component contained in clean water tends to precipitate as calcium carbonate, making it difficult to operate the humidifier stably for a long period of time.

  Also, as shown in Table 2, the solubility of carbon dioxide gas in pure water is smaller at room temperature than normal temperature, and it is known that the solubility of calcium bicarbonate and the solubility of carbon dioxide gas have a strong correlation. Yes.

炭酸ガスの溶存下においては、上述した平衡式（ａ）において平衡反応が左側に進み、炭酸カルシウムは炭酸水素カルシウムとなって上水に溶解しているが、上水が高温になって溶解する炭酸ガスの濃度が低下すると、上記平衡式（ａ）において平衡反応が右側に進み、炭酸カルシウムの析出が生成されるようになる。

Under the dissolution of carbon dioxide gas, the equilibrium reaction proceeds to the left side in the above-described equilibrium equation (a), and calcium carbonate is dissolved in the water as calcium hydrogen carbonate, but the water is dissolved at a high temperature. When the concentration of carbon dioxide gas decreases, the equilibrium reaction proceeds to the right side in the equilibrium equation (a), and precipitation of calcium carbonate is generated.

  When the fuel gas is, for example, a fuel gas based on liquefied natural gas, that is, a fuel gas mainly composed of methane (for example, city gas), the composition is as shown in Table 3, and carbon dioxide gas is produced in the LNG production stage. Has been removed.

このような組成の燃料ガス（例えば、都市ガス）を加湿器において上水（水道水）と接触させて加湿すると、加湿器内の上水中に溶存していた炭酸ガスはほぼ完全に上水からなくなり、それ故に、上記平衡式（ａ）が右側に進行し、上水中に溶存していた炭酸水素カルシウムが炭酸カルシウムとして析出するようになる。

When fuel gas (for example, city gas) having such a composition is brought into contact with water (tap water) in a humidifier and humidified, carbon dioxide dissolved in the water in the humidifier is almost completely removed from the water. Therefore, the equilibrium equation (a) proceeds to the right side, and the calcium bicarbonate dissolved in the tap water is precipitated as calcium carbonate.

  Therefore, as described above, when the fuel gas is humidified through the humidifier while the carbon dioxide gas is contained in the fuel gas, the fuel gas containing the carbon dioxide gas comes into contact with the clean water. The equilibrium formula (a) proceeds to the left side, whereby the precipitation of calcium carbonate can be suppressed.

  When fuel gas is humidified using clean water, impurities existing in clean water, such as chloride ions, nitrate ions, sulfate ions, etc., accumulate, so the clean water in the humidifier is continuously or It is desirable to drain the water intermittently, and by adjusting the concentration of carbon dioxide gas contained in the fuel gas and the discharge amount of clean water, it is possible to use clean water with a wide range of water quality.

  In the solid oxide fuel cell system according to claim 2 of the present invention, the carbon dioxide gas mixing means includes the reformed gas recycling flow path for recycling a part of the reformed gas. One end side of the gas recycle channel is connected to the humidifier or the upstream side of the humidifier. When the fuel gas is steam reformed, hydrogen, carbon dioxide gas, carbon monoxide and water are generated, so that part of the reformed gas containing carbon dioxide gas is mixed into the fuel gas through the reformed gas recycling flow path, and the humidifier is installed. The flowing fuel gas contains carbon dioxide gas, and accordingly, precipitation of calcium components in the humidifier can be suppressed.

  In the solid oxide fuel cell system according to claim 3 of the present invention, a booster, for example, a booster blower is disposed on the upstream side of the desulfurizer, and the upstream side of the reformed gas recycle flow path is the fuel. Connected to the downstream side of the reformer, the downstream side of the reformed gas recycling flow path is connected to the upstream side of the booster. With this configuration, the downstream side of the booster is in a high pressure state, and therefore, the upstream side of the reformed gas recycling flow path is in a higher pressure state than the downstream side, and the reformed gas from the fuel reformer The part flows to the upstream side of the booster due to the pressure difference in the reformed gas recycling flow path, and a part of the reformed gas can be recycled to the upstream side of the booster without requiring a recycling blower or the like.

  According to the solid oxide fuel cell system of claim 4 of the present invention, the carbon dioxide gas mixing means is constituted by the exhaust gas recycling passage for recycling a part of the exhaust gas, and this exhaust gas recycling The flow path is connected to the humidifier or the upstream side of the humidifier. The exhaust gas after the fuel cell reaction is performed contains water, carbon dioxide gas, hydrogen, and carbon monoxide, so that a part of the exhaust gas containing carbon dioxide is mixed into the fuel gas through the exhaust gas recycle channel. The fuel gas flowing through the humidifier contains carbon dioxide gas, which can suppress the precipitation of calcium components in the humidifier.

  Furthermore, in the solid oxide fuel cell system according to claim 5 of the present invention, the carbon dioxide gas mixing means comprises an oxidation reactor that oxidizes a part of the fuel gas. When the fuel gas undergoes an oxidation reaction, carbon dioxide gas and water are produced. Therefore, the oxidation reaction gas containing carbon dioxide gas is mixed into the fuel gas, and the fuel gas flowing through the humidifier contains carbon dioxide gas. Precipitation of calcium components in the vessel can be suppressed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a solid oxide fuel cell system according to the present invention will be described below with reference to the accompanying drawings.
First Embodiment First, a solid oxide fuel cell system according to a first embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a system diagram schematically illustrating the entire solid oxide fuel cell system according to the first embodiment, and FIG. 2 is a simplified diagram of the humidifier of the solid oxide fuel cell system of FIG. It is sectional drawing shown.

  In FIG. 1, the illustrated solid oxide fuel cell system 2 includes a solid oxide fuel cell 4, a desulfurizer 6, a humidifier 8, a fuel reformer 10, and a combustion unit 12. Yes. The solid oxide fuel cell 4 includes a solid electrolyte 16 that conducts oxygen ions, a fuel electrode 18 is provided on one side (left side in FIG. 1) of the solid electrolyte 16, and an air electrode on the other side (right side in FIG. 1). 20 is provided. The solid electrolyte 16 is made of, for example, zirconia doped with yttria. The reformed gas steam-reformed as described later is oxidized at the fuel electrode 18, and oxygen in the air is reduced at the air electrode 20, and the oxygen ions pass through and move through the solid electrolyte 16 to be steam-reformed gas. Power generation is performed by performing an electrochemical reaction with. Such an electrochemical reaction is performed at a high temperature of 700 to 1000 ° C. In this embodiment, the solid oxide fuel cell 4 is surrounded by the high-temperature heat insulating plate 22, and the solid oxide fuel cell 4 is maintained at a high temperature by being configured in this way. The fuel cell reformer 10 and the oxidation reactor 12 are also installed in a high temperature part surrounded by the high temperature heat insulating plate 22.

  An air supply passage 26 is connected to the air electrode 20 side of the solid oxide fuel cell 10, and an air supply means 24, for example, an air blower is provided in the air supply passage 26 to supply air. Air from the means 24 is supplied to the air electrode 20 side through the air supply passage 26.

  The desulfurizer 6, the humidifier 8, and the fuel reformer 10 are disposed in a fuel gas supply passage 27 connected to the fuel electrode 18 side of the solid oxide fuel cell 10. The desulfurizer 6 is filled with a desulfurizing agent for removing a sulfur component contained in the fuel gas, for example, a copper-zinc-based desulfurizing agent. For example, at a temperature of 150 to 250 ° C., the sulfur component contained in the raw fuel gas is reduced. Desulfurized to 0.1 ppb or less. Since the desulfurizer 6 can efficiently perform desulfurization by maintaining a relatively high temperature (about 150 to 250 ° C.), the high-temperature heat insulating plate 30 that extends the high-temperature heat insulating plate 22 surrounding the solid oxide fuel cell 4 is used. It is desirable to arrange in the enclosed part.

  On the upstream side of the desulfurizer 6, a booster 28, for example, a booster fan is provided, and the pressure of the fuel gas supplied to the desulfurizer 6 is increased by the booster 28. As the fuel gas, for example, a fuel gas based on liquefied natural gas, that is, a fuel gas mainly composed of methane (for example, city gas) is used, and such fuel gas is desulfurized through the booster 28 as a raw fuel gas. Is supplied to the vessel 6.

  The humidifier 8 is disposed on the downstream side of the desulfurizer 6, and the humidifier 8 is connected to a water supply channel 31 for supplying clean water (tap water). Suspension removing means 32 is provided in the water supply channel 31, and a water supply pump 33 is disposed between the suspension removing means 32 and the humidifier 8. The clean water feed pump 33 feeds clean water to the humidifier 8, and the suspended matter removing means 32 removes suspensions contained in the clean water supplied to the humidifier 8, such as small dust. Then, the clean water from which the suspension has been removed is fed to the humidifier 8. The suspension removing means 32 is composed of, for example, a filtration membrane.

  The humidifier 8 will be described with reference to FIG. 2. The illustrated humidifier 8 includes a humidifier housing 34 formed in a cylindrical shape, for example, and partition walls 46 and 48 are provided at both ends of the humidifier housing 4. A fuel gas introduction chamber 47 is defined between one end wall 35 (left end wall in FIG. 2) of the humidifier housing 34 and one partition wall 46, and humidification is performed between the pair of partition walls 46 and 48. A chamber 49 is defined, and a fuel gas outlet chamber 51 is defined between the other partition wall 46 and the other end wall (the right end wall in FIG. 2) of the humidifier housing 34. A plurality of humidification tubes 36 are disposed between the pair of partition walls 46, 48, one end side of these humidification tubes 36 opens into the fuel gas introduction chamber 47, and the other end side thereof into the fuel gas outlet chamber 51. It is open. These humidification tubes 36 are composed of porous tubes having water repellency and water vapor permeability, such as tubes formed of porous polytetrafluoroethylene (PTFE), and such humidification tubes 36 are used. Thus, it is possible to humidify the fuel gas by bringing the clean water and the fuel gas into contact with each other.

  In this embodiment, the end wall 35 of the humidifier housing 34 is provided with a fuel gas introduction portion 38, and this fuel gas introduction portion 38 is connected to the desulfurizer 6 via the fuel supply passage 27. Further, a fuel gas discharge part 40 is provided on the other end wall 37 of the humidifier housing 34, and this fuel gas discharge part 40 is connected to the fuel reformer 10 via the fuel gas supply passage 27. Furthermore, an upper water inflow portion 42 is provided at one end of the side wall 39 of the humidifier housing 34 (inside the one partition wall 46 in the longitudinal direction of the humidifier housing 34). An upper water discharge portion 45 is provided at the other end portion of the side wall 39 (inside the other partition wall 48 in the longitudinal direction of the humidifier housing 34). A drain valve 44 is provided. By opening and closing the drain valve 44, it is possible to control the discharge of clean water in the humidification chamber 49 of the humidifier housing 34. For example, the drain valve 44 may be constantly released so that the clean water in the humidification chamber 49 is continuously drained, or the drain valve 44 may be released at predetermined time intervals to Impurities contained in the fresh water in the humidifying chamber 49, such as various ions contained in the fresh water, may be provided by intermittently draining the water or draining the fresh water in the humidifying chamber 49. (For example, chloride ions, nitrate ions, sulfate ions, sodium ions, etc.) and metals (for example, potassium, calcium, magnesium, silica, etc.) can be prevented from accumulating and By increasing the amount of water discharged, the accumulation of impurities can be further reduced, and the fuel gas can be humidified using clean water even in areas with poor water quality.

  In such a humidifier 8, the fuel gas from the desulfurizer 6 is introduced into the fuel gas introduction chamber 47 from the fuel gas introduction section 38, and the fuel gas supplied to the fuel gas introduction chamber 47 is used for each humidification. The fuel flows into the fuel gas outlet chamber 51 through the tube 36 and is fed from the fuel gas discharge unit 40 to the fuel reformer 10. On the other hand, the clean water from the clean water supply flow path 31 is supplied from the clean water inflow portion 42 to the humidification chamber 49, flows through the humidification chamber 49 from one end side to the other end side, and is discharged from the clean water discharge portion 45. . In the humidifier 8, the fuel gas flowing through the humidifying tubes 36 and the clean water flowing through the humidifying chamber 49 come into contact with each other through the tube wall of the porous humidifying tube 36, and the fuel is brought into contact with the clean water. The gas is humidified, and the humidified fuel gas is supplied to the fuel reformer 10. The humidification of the fuel gas is performed by heating the temperature of the clean water to, for example, 90 to 97 ° C. Therefore, it is desirable to dispose the fuel gas in a portion surrounded by the high temperature heat insulating plate 30. Since the carbon dioxide gas is mixed in the fuel gas flowing through the humidifier 8 as described later, it is possible to suppress the precipitation of calcium generated on the surface of the tube wall of the humidifying tube 36. Will be described later.

  In the fuel reformer 10, the steam reforming reaction of the fuel gas humidified by the humidifier 8 is performed. The fuel reformer 10 incorporates a catalyst in which ruthenium is supported on an alumina carrier. For example, a steam reforming reaction is performed at a high temperature of 750 to 900 ° C., and the reformed gas subjected to steam reforming is converted into a solid oxide. The fuel cell 4 is fed to the fuel electrode 18 side. Accordingly, the fuel reformer 10 is preferably disposed at a portion surrounded by the high-temperature heat insulating plate 22, and by providing the fuel reformer 10 at such a portion, the fuel from the solid oxide fuel cell 4 is utilized using the heat. Steam reforming of gas can be performed efficiently.

  In the solid oxide fuel cell system 2, a part of the reformed gas supplied from the fuel reformer 10 to the solid oxide fuel cell 4 is transferred to the booster 28 in the fuel gas supply passage 27. It is configured to be fed to a site upstream of the arrangement site. That is, a reformed gas recycle channel 53 is provided in relation to the fuel reformer 10, and one end side (upstream side) of the reformed gas recycle channel 53 is connected to the downstream side of the fuel reformer 10, A downstream side 54 of the reformed gas recycle channel 53 is connected to an upstream side of the booster 28. Since the booster 28 pumps the fuel gas toward the desulfurizer 6, the upstream side of the booster 28 has a higher pressure than the downstream side thereof. In the high pressure state, the downstream side 54 is maintained in the low pressure state, and a pressure difference exists between the upstream side and the downstream side. Since such a pressure state is maintained, a part of the reformed gas flows from the upstream side to the downstream side of the reformed gas recycling passage 53 due to the pressure difference and is recycled to the upstream side of the booster 28. The fuel gas mixed into the fuel gas fed to the desulfurizer 6 and thus mixed with the reformed gas is fed to the humidifier 8 through the desulfurizer 6. Carbon dioxide gas is contained in the reformed gas. By returning a part of the reformed gas to the upstream side of the booster 28 in this way, the carbon dioxide gas is mixed into the fuel gas supplied to the humidifier 8. The reformed gas is recycled so that the concentration of carbon dioxide in the fuel gas is, for example, about 0.5 to 2.0%.

  A flow rate control valve 56 for controlling the supply flow rate of the reformed gas may be provided at a connection portion between the fuel gas supply flow channel 27 and the reformed gas recycle channel 53. By providing the flow control valve 56 in this manner, the amount of reformed gas recycled can be controlled, and thereby the amount of carbon dioxide mixed in the fuel gas can be adjusted. Further, for example, a carbon dioxide gas detection sensor 58 is provided on the upstream side of the humidifier 8 (or the fuel gas introduction part 38 of the humidifier 8), and the carbon dioxide gas concentration in the fuel gas is measured by the carbon dioxide gas detection sensor 58. Using the measurement result, the flow control valve 56 may be controlled to open and close so that the concentration of carbon dioxide in the fuel gas is constant.

  In the embodiment described above, the downstream side 54 of the reformed gas recycle channel 53 is connected to the upstream side of the booster 28. However, the downstream side 54 of the reformed gas recycle channel 53 is connected to the booster 28 and the desulfurizer. 6, between the desulfurizer 6 and the humidifier 8, or may be connected to the humidifier 8, for example, when directly connected to the humidifier 8, The downstream side can be communicated with the fuel gas introduction chamber 47, and even with this configuration, carbon dioxide gas can be mixed into the fuel gas flowing through the humidifying tube 36 of the humidifier 8. When the reformed gas recycle channel 53 is connected to the downstream side of the booster 28, it is desirable to provide a recycle fan in the reformed gas recycle channel 53 so that the reformed gas is reliably recycled. Further, the upstream side of the reformed gas recycle channel 53 is connected between the fuel reformer 10 and the solid oxide fuel cell 4. The upstream side of the reformed gas recycle channel 53 is connected to the fuel reformer. The reformer gas from the fuel reformer 10 may be recycled by connecting directly to the mass device 10.

  A combustion section 12 is provided on the discharge side of the solid oxide fuel cell 4 in which the fuel cell reaction described above is performed, and an exhaust passage 62 for discharging combustion gas is connected to the combustion section 12. Reacted fuel gas from the fuel electrode 18 side and air from the air electrode 20 side are discharged to the combustion unit 12, and the reaction fuel gas is burned using oxygen in the air. The reaction fuel gas discharged from the fuel electrode 18 side contains residual hydrogen gas, and the remaining combustion gas is burned in the combustion section 12. In addition, it is desirable to arrange the combustion part 12 in the site | part enclosed by the high temperature heat insulation board 22 in order to promote combustion.

  A heat exchanger 64 is disposed in the exhaust passage 62, and the heat exchanger 64 exchanges heat between the air passing through the air supply passage 26 and the exhaust gas flowing through the exhaust passage 62. By the heat exchange, the air supplied to the air electrode 20 side of the solid oxide fuel cell 4 is heated, and the exhaust gas after the heat exchange is discharged to the outside.

  Next, the operation of the above-described solid oxide fuel cell system 2 will be described mainly with reference to FIG. 1. A fuel gas (for example, city gas) mainly composed of methane as a raw fuel gas is supplied as a fuel gas. The fuel gas fed through the flow path 27 and thus fed is boosted by the booster 28 and then fed to the desulfurizer 6, where the sulfur component contained in the fuel gas is removed. .

  The fuel gas desulfurized in the desulfurizer 6 is supplied to the humidifier 8, and the humidifier 8 performs the humidification process. That is, clean water (tap water) supplied through a water pipe or the like is sent to the humidifying chamber 49 of the humidifier 8 after the suspended matter is removed by the suspended matter removing means 32, while the fuel gas is It flows through the humidifying tube 36 of the humidifier 8. Since the humidifying tube 36 is formed of a porous material, the water and the fuel gas are brought into contact with each other through the humidifying tube, and the fuel gas is humidified by the contact. At the time of humidification, the temperature of clean water is set to about 90 to 97 ° C., and the steam / carbon ratio is set to, for example, 1.5 to 2 due to contact between the fuel gas and clean water by setting to such a temperature. The fuel gas can be humidified to 0.0. At this time, as will be described later, since part of the reformed gas, particularly carbon dioxide, is contained in the fuel gas, the fuel gas containing carbon dioxide comes into contact with the clean water through the humidifying tube 36, and the fuel gas Precipitation of calcium components contained in clean water as calcium carbonate is suppressed by the carbon dioxide gas therein, and fuel gas can be humidified stably over a long period of time.

  The humidified fuel gas is supplied to the fuel reformer 10, where steam reforming is performed in the fuel reformer 10, and the reformed gas subjected to steam reforming is the fuel electrode of the solid oxide fuel cell 4. It is sent to the 18th side. A part of the reformed gas is also sent to the upstream side of the booster 28 through the reformed gas recycle channel 53, mixed in the fuel gas fed to the desulfurizer 6, and flows through the humidifier 8. Thus, by recycling a part of the reformed gas, it is possible to suppress the precipitation of calcium in the tap water.

  The reformed gas is fed to the fuel electrode 18 side of the solid oxide fuel cell 4, and the air heated by the heat exchanger 64 passes through the air feed channel 26 to the air electrode 20 side. In this solid oxide fuel cell 4, a fuel cell power generation reaction is performed by the reformed gas and oxygen in the air. The reaction fuel gas from the fuel electrode 18 side and the air from the air electrode 20 side are supplied to the combustion unit 12, and the hydrogen gas remaining in the reaction fuel gas is burned in the combustion unit 12.

  The combustion exhaust gas of the combustion section 12 is discharged to the outside through the exhaust flow path 62, and at the time of this discharge, in the heat exchanger 64, the exhaust gas in the exhaust flow path 62 and the air in the air supply flow path 26 are Heat is exchanged between them to heat the air, and the heated air is supplied to the air electrode 20 side of the solid oxide fuel cell 4.

  In the embodiment described above, the carbon dioxide gas mixing means is constituted by the reformed gas recycle channel 53, and a part of the reformed gas steam-reformed by the fuel reformer 10 is returned to the upstream side of the booster 28. However, instead of such a configuration, the carbon dioxide gas mixing means is configured from an exhaust gas recycle channel (not shown), and a part of the exhaust gas discharged through the exhaust channel 62 through this exhaust gas recycle channel May be returned to the humidifier 8 or its upstream side through the exhaust gas recycle channel. In this case, one end side (upstream side) of the exhaust gas recycle flow path is connected to the combustion section 12 or the downstream discharge flow path 62, and the other end side (downstream side) is connected to the upstream side of the booster 28. The carbon dioxide gas contained in the exhaust gas can be directly connected between the desulfurizer 6 and the desulfurizer 6, between the desulfurizer 6 and the humidifier 8, or directly connected to the humidifier 8. Can be mixed with the fuel gas and flowed through the humidifier 8 (specifically, the humidifying tube 36), whereby precipitation of calcium in the water in the humidifier 8 can be suppressed.

Second Embodiment Next, a second solid oxide fuel cell system will be described with reference to FIG. FIG. 3 is a system diagram schematically showing the entire solid oxide fuel cell system of the second embodiment. In the following embodiments, substantially the same members as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

  In FIG. 3, in the illustrated solid oxide fuel cell system 2 </ b> A, the carbon dioxide mixing means includes an oxidation reactor 70 that oxidizes the fuel gas, and the oxidation reaction gas oxidized in the oxidation reactor 70 is the fuel. The fuel gas flowing through the gas supply passage 27 is mixed.

  In this embodiment, the upstream side of the fuel gas flow path 76 in which the oxidation reactor 70 is disposed is connected to the downstream portion of the desulfurizer 6 of the fuel gas supply flow path 27A, and the downstream side thereof is the fuel gas supply path. It is connected to the upstream portion of the humidifier 8 in the flow path 27A. An oxidation reaction catalyst (not shown) for oxidizing the fuel gas is built in the oxidation reactor 70, and an oxidation air channel 80 is connected to the oxidation reactor 70 from the outside. Is supplied to the oxidation reactor 70 through the oxidation air flow path 80. The other configuration of the solid oxide fuel cell system 2A of the second embodiment is substantially the same as that of the first embodiment shown in FIGS.

  In this solid oxide fuel cell system 2 </ b> A, the fuel gas is boosted by the booster 28, then supplied to the desulfurizer 6, and desulfurized in the desulfurizer 6. The desulfurized fuel gas is fed to the humidifier 8 through the fuel gas feed channel 27A. At this time, a part of the desulfurized fuel gas is supplied to the oxidation reactor 70 through the fuel gas passage 76. In the oxidation reactor 70, the fuel gas fed through the fuel gas flow path 76 undergoes an oxidation reaction under the oxidation catalyst with the air flowing through the oxidation air flow path 80, and the oxidation reaction gas from the oxidation reactor 70 flows into the fuel gas flow. The fuel gas is supplied to the fuel gas supply passage 27A through the passage 76, and the oxidation reaction gas is mixed into the fuel gas flowing therethrough. The oxidation reaction gas is a gas generated by the oxidation reaction of the fuel gas, and this combustion gas contains carbon dioxide gas. Therefore, by using such an oxidation reactor 70, a part of the fuel gas is oxidized. Also, the carbon dioxide gas can be mixed into the fuel gas as required, and the same effect as the first embodiment can be achieved. The amount of the fuel gas to be oxidized in this oxidation reactor 70 may be about 1 to 3% of the fuel gas fed from the desulfurizer 6 to the humidifier 8, and the carbon dioxide generated by this oxidation reaction is used as the fuel gas. By mixing and feeding to the humidifier 8 (specifically, the humidifying tube 36), precipitation of calcium components in the tap water is suppressed, and the fuel gas is humidified stably in the humidifier 8 for a long period of time. be able to. The oxidation reactor 70 is desirably maintained at a temperature of, for example, 200 ° C. or higher so that the oxidation reaction of the oxidation reaction gas can be performed efficiently.

  In the above-described embodiment, the fuel gas flow path 76 including the oxidation reactor 70 is connected between the desulfurizer 6 and the humidifier 8. However, the present invention is not limited to this configuration, and the oxidation reactor The oxidation reaction gas from 70 may be directly fed to the humidifier 8 (specifically, the fuel gas introduction chamber) and mixed into the fuel gas. Alternatively, a part of the fuel gas supplied from the booster 28 to the desulfurizer 6 may be supplied to the oxidation reactor 70 to cause an oxidation reaction. Or you may make it oxidize by burning fuel gas in the oxidation reactor 70, for example using a combustion burner.

  As mentioned above, although the embodiment of the solid oxide fuel cell system according to the present invention has been described, the present invention is not limited to such an embodiment, and various variations and modifications can be made without departing from the scope of the present invention. It is.

  For example, in the above-described embodiment, a plurality of humidification tubes are provided in the humidification chamber of the humidifier housing, fuel gas is allowed to flow through the humidification tubes, and clean water is allowed to flow around the humidification tube. Fuel gas is humidified by contact with gas, but this is not a limitation. Humidification is provided in a humidifier chamber in a humidifier, and fuel gas containing carbon dioxide is bubbled into the collected fresh water for humidification. May be performed.

  Further, for example, in the above-described embodiment, the carbon dioxide gas mixing means includes a reformed gas recycling channel for recycling the reformed gas, an exhaust gas recycling channel for recycling the exhaust gas, or a part of the fuel gas. Although comprised from the oxidation reactor which burns and produces | generates a carbon dioxide, it is not limited to this, It comprises from a humidifier or the carbon dioxide supply means for mixing a carbon dioxide directly in the upstream of a humidifier You may do it.

Examples and Comparative Examples In order to confirm the effect of suppressing the precipitation of calcium components in the solid oxide fuel cell system of the present invention, the following experiment was conducted. In addition, all the following solid oxide fuel cell systems used 1 kW output.

Example 1
As Example 1, a solid oxide fuel cell system having a reformed gas recycle channel shown in FIG. 1 is used, and a part of the reformed gas is mixed with the fuel gas fed through the fuel gas feed channel. I let you. Fuel cell power generation was performed using city gas containing methane as a main component as the fuel gas, and the concentration of carbon dioxide in the fuel gas after mixing the reformed gas was 1.1%. In addition, water (tap water) is used as water for humidification, and a tube made of PTFE is used as the humidification tube of the humidifier, and this humidification tube is immersed in the humidified water of the humidifier chamber. Fuel gas was allowed to flow through, so that there was clean water around the humidification tube. Further, drainage was performed by opening and closing the drain valve of the humidifier intermittently, and the timing of the drain valve was adjusted in advance so that the amount of drainage was equal to the reduction due to water evaporation. The water temperature of the humidifier was kept at about 95 ° C., the steam / carbon ratio at the fuel reformer inlet was about 1.8, and the power generation test was conducted by continuously operating the fuel cell system in this state. The humidified fuel gas can be measured for water vapor with a dew point meter.

  After generating power by operating continuously for 100 days, the state of the fuel cell system was examined. As a result of examining the amount of water vapor added to the fuel gas in the humidifier, the amount added was equal to the initial value at the beginning of operation, and the humidification of the fuel gas was performed without change from the beginning of operation. In addition, when the humidifier was disassembled and the precipitation of calcium components in tap water was confirmed, precipitation of calcium components on the outer and inner surfaces of the humidifying tube and the humidifying chamber inner surface (deposition as calcium carbonate) Was not confirmed. From this result, in the solid oxide fuel cell system of Example 1, humidification of fuel gas is stably performed for a long period of time using clean water without providing a clean water purification device such as an ion exchange resin device. It was confirmed that it was possible.

  In addition, after 100 days of continuous operation, the humidified fuel gas fed from the humidifier to the fuel reformer is condensed to generate condensed water, and the composition analysis of the condensed water is performed by ion chromatography and IPC emission spectroscopic analysis. The analysis results as shown in Table 4 were obtained.

表４の結果から明らかなように、凝縮水中の不純物成分、例えば塩化物イオン、硝酸イオン、硫酸イオンなどは検出限界以下であった。このことから、上水による加湿によって、イオン交換樹脂装置などの純水生成装置を用いることなく、長期にわたって安定的に燃料ガスを加湿することができることが確認できた。

As is clear from the results in Table 4, impurity components in the condensed water, such as chloride ions, nitrate ions, sulfate ions, etc. were below the detection limit. From this, it was confirmed that the fuel gas can be stably humidified over a long period of time without using a pure water generating device such as an ion exchange resin device by humidification with clean water.

Example 2
As Example 2, a power generation experiment was conducted using a solid oxide fuel cell system 2A equipped with an oxidation reactor shown in FIG. As in Example 1, fuel cell power generation was performed using city gas containing methane as a main component as fuel gas, and tap water (tap water) was used as water for humidification. In the oxidation reactor, air containing oxygen amount necessary for burning 2% of the fuel gas fed from the desulfurizer to the fuel gas was fed to the oxidation reactor as oxidized air. The concentration of carbon dioxide contained in the fuel gas after mixing and other conditions were the same as in Example 1.

  After generating power by operating continuously for 100 days, the state of the fuel cell system was examined. The amount of water vapor added to the fuel gas in the humidifier is equal to the initial value at the beginning of operation, and the humidification of the fuel gas is performed without change from the initial operation. Moreover, when the humidifier was disassembled and the precipitation of calcium components in the tap water was confirmed, the precipitation of calcium components on the outer and inner surfaces of the humidifying tube and the inner surface of the humidifying chamber of the humidifier was not confirmed. From this result, it was confirmed that the solid oxide fuel cell of Example 2 was able to stably humidify the fuel gas for a long period of time using clean water.

Comparative Example 1
As Comparative Example 1, a solid oxide fuel cell system as an example of the prior art shown in FIG. 4 was used, and this fuel cell system was continuously operated. In the fuel cell system of Comparative Example 1, a steam generator 106 is provided between the desulfurizer 6 and the fuel reformer 10, and pure water obtained by refining clean water is fed to the steam generator 106. It is configured as follows. Suspension is removed from the clean water by the suspension removal filter device 116, purified by the ion exchange resin device 118 to be purified water, and this pure water is supplied to the steam generator 106. In the steam generator 106, steam is generated by pure water, and the generated steam is mixed with the fuel gas fed through the fuel gas feed channel 27, and the fuel gas containing the steam is sent to the fuel reformer 10. Be paid. Other configurations of the comparative example 1 are substantially the same as those of the first embodiment shown in FIG.

  In this comparative example 1, the steam / carbon ratio at the fuel reformer inlet is set to 2.0, and about 0.5 L of ion exchange resin is used in the ion exchange resin device 118, and the steam generator 106 is about 6 g / min. Pure water was supplied. When this fuel cell system was continuously operated, the water quality dropped significantly on the 14th day, and the operation of the fuel cell system was stopped because the ion exchange resin had reached the end of its life. In this experiment, when the electric conductivity of pure water at the outlet of the ion exchange resin device 118 tripled the normal, it was determined that the lifetime of the ion exchange resin. As described above, in the fuel cell system of Comparative Example 1, the ion exchange resin reached the end of its life in 14 days, and maintenance such as replacement was required.

  Further, Table 5 shows the results of analyzing impurities in clean water when the ion exchange resin of the ion exchange resin device 118 has reached the end of its life using an ion chromatograph and an ICP emission spectroscopic analyzer.

比較例２
比較例２として、実施例１の燃料電池システムから、炭酸ガス混入手段としての改質ガスリサイクル流路を省略した以外は実質上同一の構成のものを用いて、連続作動運転を行った。比較例２においても、実施例１と同様に、加湿器の加湿用チューブにはＰＴＦＥチューブを使用し、加湿器の水温を約９５℃に保持し、燃料改質器入口のスチーム／カーボン比を約１．８となるように加湿を行い、この状態で燃料電池システムを運転させた。

Comparative Example 2
As Comparative Example 2, continuous operation was performed using a fuel cell system of Example 1 having substantially the same configuration except that the reformed gas recycle channel as carbon dioxide mixing means was omitted. Also in Comparative Example 2, as in Example 1, a PTFE tube was used as the humidifying tube of the humidifier, the water temperature of the humidifier was maintained at about 95 ° C., and the steam / carbon ratio at the inlet of the fuel reformer was adjusted. Humidification was performed so as to be about 1.8, and the fuel cell system was operated in this state.

  On the ninth day of continuous operation, the fuel cell system was stopped because the amount of water vapor added to the fuel gas per hour decreased by 15% from the beginning. When the humidifier was disassembled, crystals of about 0.1 mm were deposited on the outer surface of the humidifying tube, and the crystals were analyzed and found to be calcium crystals. In this way, it was found that when water is supplied directly to the humidifier, calcium precipitation occurs in about 9 days, and the amount of water vapor added to the fuel gas decreases rapidly.

1 is a system diagram schematically showing an entire solid oxide fuel cell system according to a first embodiment. It is a figure which shows simply the humidifier of the solid oxide fuel cell system of FIG. It is a system diagram showing the whole solid oxide fuel cell system of a 2nd embodiment simply. 1 is a system diagram schematically showing an entire solid oxide fuel cell system as a conventional example as Comparative Example 1. FIG.

Explanation of symbols

2, 2A, 102 Solid oxide fuel cell system 4 Solid oxide fuel cell 6 Desulfurizer 8 Humidifier 10 Fuel reformer 12 Combustion unit 28 Booster 36 Humidifier tube 53 Reformed gas recycle channel 70 Oxidation reaction vessel

Claims (5)

A desulfurizer for removing sulfur components contained in the fuel gas, a humidifier for humidifying the desulfurized fuel gas, a fuel reformer for steam reforming the humidified fuel gas, and fuel Solid oxidation which has an electrode and an air electrode and generates electricity by performing a fuel cell power generation reaction between reformed gas supplied to the fuel electrode side after steam reforming and air supplied to the air electrode side A solid oxide fuel cell system comprising a physical fuel cell,
The humidifier is supplied with clean water, and in association with the humidifier, a carbon dioxide gas mixing means for mixing carbon dioxide gas into the fuel gas is provided, and the carbon dioxide gas mixing means is the humidifier or the humidifier. In the humidifier, the fuel gas containing carbon dioxide and the clean water are brought into contact with each other, thereby preventing the precipitation of calcium components contained in the clean water. A solid oxide fuel cell system.   The carbon dioxide mixing means is constituted by a reformed gas recycle channel for recycling a part of the reformed gas steam-reformed by the fuel reformer, and one end side of the reformed gas recycle channel is 2. The solid oxide fuel cell system according to claim 1, wherein the solid oxide fuel cell system is connected to the humidifier or an upstream side of the humidifier, and a part of the reformed gas is mixed into the fuel gas.   A booster for pumping fuel gas is disposed on the upstream side of the desulfurizer, and the upstream side of the reformed gas recycle channel is connected to the downstream side of the fuel reformer, and the reformed gas A downstream side of the recycle channel is connected to an upstream side of the booster, and a part of the reformed gas steam-reformed in the fuel reformer passes through the reformed gas recycle channel from the fuel reformer. The solid oxide fuel cell system according to claim 2, wherein the solid oxide fuel cell system is recycled upstream of the booster.   The carbon dioxide mixing means includes an exhaust gas recycle channel for recycling a part of the exhaust gas after a fuel cell power generation reaction is performed in the solid oxide fuel cell, and the exhaust gas recycle channel 2. The solid oxide fuel cell system according to claim 1, wherein one end of the exhaust gas is connected to the humidifier or an upstream side of the humidifier, and a part of the exhaust gas is mixed into the fuel gas.   The carbon dioxide mixing means comprises an oxidation reactor that oxidizes a part of the fuel gas, and the oxidation reaction gas of the fuel gas oxidized in the oxidation reactor is mixed into the fuel gas. The solid oxide fuel cell system according to claim 1.

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