JP2018166081A - Solid Electrolyte Fuel Cell Module - Google Patents

Abstract

A solid oxide fuel cell module capable of maintaining a stable combustion state and generating power stably at a high fuel utilization rate even in a situation where the air flow rate must be increased.
An air side electrode is provided on the air flow passage side of the cell, and the downstream end of the air side electrode is disposed at a position spaced apart upstream from the downstream end of the cell. The bypass that draws a part of the air A1 that flows from the downstream end of the air side electrode to the downstream end of the cell 9 so as not to reach the mixed combustion unit 3 A path 22 is provided.
[Selection] Figure 1

Description

  In the present invention, a solid oxide fuel cell supplied with fuel gas and air, a part of the fuel gas is used for power generation, and the remaining fuel gas (anode offgas) is partially consumed with power generation. The present invention relates to a solid oxide fuel cell module that includes a mixed combustion section that mixes with air (cathode off-gas) and burns, maintains the operating temperature using the combustion heat, and continues power generation.

  A solid oxide fuel cell (SOFC) burns fuel gas (anode offgas) that has not been consumed in a fuel cell reaction in a combustion chamber, and uses the combustion heat as an evaporation and reforming reaction (pretreatment of fuel gas). Used to heat endothermic reactions. In a home SOFC system (rated power generation 700 W class), the fuel utilization rate of fuel gas used for power generation (hereinafter abbreviated as “Uf”) is 70% to 78%, and the remaining 22% to 30%. Is burning. As an oxidant for combustion, air (cathode offgas) in which oxygen is partially consumed by the air-side electrode of the fuel cell is used (see, for example, Patent Document 1).

  As a means for realizing high power generation efficiency, there is a method of setting the fuel utilization rate (Uf) higher. As a contradiction, the amount of heat of the anode off gas decreases, and at that time, the temperature of the combustion chamber decreases, so that a uniform combustion state cannot be maintained, and there is a risk of increasing the risk of misfire that suddenly deteriorates combustion.

  On the other hand, the air flow rate and the air utilization ratio are determined as optimal control ranges from the viewpoint of keeping the operating temperature of the fuel cell unit (cell stack) within an appropriate range. That is, if the air flow rate is reduced, the temperature of the cell stack rises and the voltage of the cell increases, which is advantageous for obtaining high power generation efficiency. The air flow rate is determined as follows. In particular, when it is desired to cool the cell stack in order to offset the temperature rise due to aging degradation of the cell stack, the air flow rate is increased from the initial stage, that is, the air utilization rate is decreased, so that the appropriate temperature of the cell stack is increased. It will be maintained.

  As described above, the fuel utilization rate and the air utilization rate are determined from the viewpoint of further increasing the power generation performance of the cell and the viewpoint of maintaining an appropriate temperature, whereas the fuel utilization rate is set to approximately 70% to 80%. The air utilization rate is set to 30% to 50%. That is, air is supplied in a large excess. The anode off-gas and cathode off-gas generated when fuel gas (anode gas) and air (cathode gas) pass through the cell stack form a flame (combustion space) near the upper end of the cell stack. However, since the cathode off-gas is excessively supplied in the combustion space, lean combustion occurs and the combustion state becomes very unstable.

  As a method of stabilizing the combustion state with such a configuration, the downstream end of the cover that covers the periphery of the cell in the fuel cell unit is arranged at an interval upstream from the downstream end of the cell, Proposed a method to improve the combustion state by relatively reducing the amount of cathode offgas introduced into the combustion space by letting some of the cathode offgas flow out not only from the cell tip but also from the side of the cell. (For example, refer to Patent Document 2).

JP 2010-225454 A Japanese Patent No. 5812927

  However, according to the above-described method, it is possible to maintain stable combustion and power generation performance at a higher fuel utilization rate of, for example, 78% to 80% in a normal rated power generation state, but a higher fuel utilization rate. In the case where the air flow rate is increased in order to more effectively cool the cell stack, an increase in the cathode off-gas amount may also cause instability of combustion.

  Accordingly, an object of the present invention is to provide a solid oxide fuel cell module capable of stably generating power at a high fuel utilization rate while maintaining a stable combustion state even in a situation where the air flow rate must be increased. It is in.

In order to achieve this object, the characteristic configuration of the solid oxide fuel cell module according to the present invention includes: a solid oxide fuel cell unit that generates power by reacting fuel gas and oxygen in the air in a storage container; And a mixed combustion section that is disposed adjacent to the fuel cell section and mixes and burns fuel gas and oxidant remaining after the reaction in the fuel cell section,
The fuel cell unit is configured by arranging a plurality of cells in a parallel state, and has a fuel flow part through which fuel gas flows and an air flow part through which air flows,
The mixed combustion section is a downstream end in the fuel flow direction in the cell as a combustion space for mixing and burning the fuel gas flowing through the fuel flow section and the air flowing through the air flow section. Provided adjacent to
The fuel flow part causes fuel gas to flow through a flow path surrounded by the fuel gas, and jets fuel gas from a fuel jet part arranged at a downstream end of the cell in the fuel flow direction. Configured,
The air flow portion is configured to flow air through a space formed between the fuel flow portion and the fuel flow portion in the juxtaposed direction of the cells,
A cover that covers the periphery of the plurality of cells arranged side by side in the fuel cell unit and closes a lateral side portion of the air flow part in a direction perpendicular to the direction in which the cells are arranged;
An air side electrode is provided on the air flow portion side of the cell, and a downstream end portion of the air side electrode is disposed at a position spaced from the downstream end of the cell at an upstream side. And
A bypass path is provided that draws a part of the flowing air from the downstream end of the air side electrode to the downstream end of the cell so as not to reach the mixed combustion section. It is in.

  A further characteristic configuration of the solid oxide fuel cell module according to the present invention resides in that the bypass path is connected to an exhaust gas path for exhausting the exhaust gas generated in the mixed combustion section to the outside. .

  A further characteristic configuration of the solid oxide fuel cell module according to the present invention is that the mixed combustion section is installed so as to apply heat to a reformer that reforms the raw fuel.

  A further characteristic configuration of the solid oxide fuel cell module according to the present invention is that the bypass path is formed in the cover.

  According to this characteristic configuration, the air-side electrode is a path in which the lateral side portion of the air flow portion in the direction orthogonal to the parallel arrangement direction of the cells is closed around the plurality of cells arranged in parallel in the fuel cell portion. By extracting a part of the flowing air from the downstream end of the cell to the downstream end of the cell, the amount of air supplied to the mixed combustion unit is reduced, and air and fuel gas The mixing ratio (air amount / fuel gas amount) can be reduced. As a result, by preventing the temperature of the flame from decreasing, combustion in the mixed combustion section does not become excessive lean combustion, and combustion in the mixed combustion section can be performed stably.

  As a result, even at a higher fuel utilization rate than in the past, the flame temperature is relatively increased, the amount of unburned components of the fuel gas is reduced, and the temperature in the evaporator or reformer installed in the mixed combustion section is reduced. Therefore, it is easy to maintain the reaction conditions appropriately, so that misfire due to high Uf operation (fuel utilization rate of 82% to 84%) can be prevented and power generation efficiency can be improved.

1 is a schematic cross-sectional view of a solid oxide fuel cell module (first embodiment) as viewed from the side of a cell. It is a perspective view of the principal part of a fuel cell part. It is sectional drawing of the principal part of the fuel cell part by the parallel arrangement direction of a cell. It is a schematic sectional drawing of the solid oxide form fuel cell module (2nd Embodiment) by the parallel arrangement direction of a cell. It is a figure which shows typically the consumption condition of the air and oxygen in the conventional solid oxide fuel cell module. It is a figure which shows typically the consumption condition of the air and oxygen in the solid oxide fuel cell module of this invention. It is a schematic sectional drawing of the conventional solid oxide fuel cell module in the parallel arrangement direction of a cell.

[First Embodiment]
Embodiments of the present invention will be described below.
As shown in FIG. 1, the solid oxide fuel cell module 100 of the present invention is reformed by a reformer 1 that reforms a raw fuel G1 using reformed water M1, and the reformer 1. A solid oxide fuel cell unit 2 (cell stack) for generating power by reacting the reformed gas G2 and air A, and a fuel cell unit 2 disposed adjacent to the upper side of the fuel cell unit 2 And a mixed combustion section 3 that mixes an oxidizing agent with the reformed gas G2 remaining after the reaction and burns it.

  The solid oxide fuel cell module 100 includes an evaporator 4 that generates water vapor using the supplied reforming water M1 in addition to the reformer 1, the fuel cell unit 2, and the like. The raw fuel G1 and the reformed water M1 desulfurized by an external desulfurizer are mixed and supplied to the evaporator 4. Although not shown, the evaporator 4 and the reformer 1 are connected to each other, and the steam and raw fuel G1 generated in the evaporator 4 are supplied to the reformer 1 by the connection. Yes. The reformer 1 is configured to steam reform the raw fuel G1 desulfurized by a desulfurizer (not shown) using the steam generated by the evaporator 4.

  The solid oxide fuel cell module 100 includes a storage container 5, and an evaporator 4, a reformer 1, a fuel cell unit 2, and a mixed combustion unit 3 are provided in the storage container 5. A pair of the fuel cell units 2 are arranged at intervals in the left-right direction (X direction in FIG. 1) of the storage container 5, and a space adjacent to the upper side with respect to each of the pair of fuel cell units 2. The mixed combustion unit 3 is configured.

  As shown in FIGS. 1 and 2, the fuel cell unit 2 (cell stack) is configured by arranging a plurality of cells 9 in a parallel state, and a fuel flow through which the reformed gas G2 flows from the lower side to the upper side. Part 7 and an air flow part 8 through which air A flows from the lower side to the upper side. Here, as shown in FIG. 2, the parallel direction of the cells 9 is defined as the Y direction, and the direction perpendicular to the parallel direction of the cells 9 is defined as the X direction. The direction orthogonal to the direction is the same. FIG. 1 shows a schematic cross-sectional view of a solid oxide fuel cell module 100 when the cells 9 are arranged in parallel.

  Then, the reformed gas G2 flows through the fuel flow portion 7 so that the reformed gas G2 is supplied to the fuel side electrode (not shown), and the air A flows through the air flow portion 8 to the air side. Air A is supplied to the electrode 10 (see FIG. 2), and a solid oxide electrolyte (not shown) made of yttria-doped zirconia or the like is provided between the fuel side electrode and the air side electrode 10. .

  As shown in FIG. 2, the fuel flow part 7 is configured by a cylindrical body formed in a hollow flat plate shape. The fuel flow part 7 flows from the fuel ejection part 11 through a flow path surrounded by the fuel flow part 7. The reformed gas G2 is ejected. The fuel ejection portion 11 is disposed at the downstream end in the fuel flow direction in the cell 9, and the upper end of the fuel flow portion 7 is spaced apart in a direction (X direction) perpendicular to the parallel arrangement direction of the cells 9. It is comprised by the several ejection hole formed in the surface part.

  The air flow part 8 is a space formed between the fuel flow part 7 and the fuel flow part 7 (between the cell 9 and the cell 9) in the direction in which the cells 9 are arranged side by side (Y direction). It is comprised so that it may flow through. The air flow portion 8 is configured such that the air flow direction of the air A is the same as the fuel flow direction in the fuel flow portion 7. And in the air flow part 8, the position corresponded in the downstream end of the fuel flow direction in the cell 9 was formed in series over the full length of the direction (X direction) orthogonal to the parallel arrangement direction of the cell 9. It is comprised by the upper side opening 12, and it is comprised so that the air A which flowed the air flow part 8 from this upper side opening 12 can be ejected.

  As described above, the fuel ejection portion 11 is disposed at the upper end 9a of the cell 9 (the downstream end of the cell 9 in the fuel flow direction). The upper opening 12 in the air flow portion 8 is also disposed at the upper end 9a of the cell 9 (downstream end in the fuel flow direction in the cell 9). In this way, the fuel flow part 7 jets the reformed gas G2 from the fuel jet part 11 to the upper side, and the air flow part 8 sends the air A from the upper side opening 12 to the upper side. Erupting.

  As shown in FIG. 1, the mixed combustion unit 3 mixes and burns the reformed gas G <b> 2 ejected from the fuel ejection unit 11 in each of the plurality of cells 9 and the air A ejected from the upper side opening 12. The combustion space is provided adjacent to the upper end 9a of the cell 9 (the downstream end in the fuel flow direction in the cell 9). Here, the mixed combustion section 3 uses only the space adjacent to the upper side 9a and the upper side of the plurality of cells 9 arranged side by side as a combustion space, and the direction in which the cells 9 are arranged (Y direction) and the arrangement of the cells 9 are arranged. In a direction orthogonal to the direction (X direction), a space adjacent to the combustion space is not a combustion space but a space for guiding the exhaust gas C in the mixed combustion unit 3 to the exhaust gas exhaust passage 16.

  The reformer 1 and the evaporator 4 are arranged above the mixed combustion unit 3, and the heat obtained by the combustion of the mixed combustion unit 3 is used to reform the reformer 1 and the steam in the evaporator 4. In addition to being used for generation, it is also used for preheating air A supplied to the fuel cell unit 2 through the air supply path 6. Incidentally, since the heat is generated by the reaction in the fuel cell unit 2, the heat is also used for steam reforming in the reformer 1, generation of steam in the evaporator 4 and preheating of the air A supplied to the fuel cell unit 2. It is used.

  The fuel cell unit 2 includes a gas manifold 14 that receives the reformed gas G2 supplied from the reformer 1 through the fluid supply path 13. The plurality of cells 9 are arranged in the horizontal direction above the gas manifold 14. The gas manifold 14 and each of the fuel flow portions 7 in the plurality of cells 9 are connected to each other, and the reformed gas G2 supplied to the gas manifold 14 is connected to each fuel flow portion 7 from below. Supplied. Thereby, the fuel flow part 7 is configured such that the reformed gas G2 flows from the lower side toward the upper side.

  In order to supply the air A to the fuel cell unit 2, an air supply path 6 is provided for allowing the air A to flow through the storage container 5 and supplying the air A from the air outlet 15 to the fuel cell unit 2. The air supply path 6 includes a first air flow path part 6a, a second air flow path part 6b, and a third air flow path part 6c, and an air flow is provided at the lower end part of the third air flow path part 6c. An outlet 15 is provided.

  The first air flow path portion 6 a receives air A from the outside of the storage container 5 at one end in the left-right direction of the storage container 5 (right end in the X direction in FIG. 1) and flows to the upper end of the storage container 5. Then, the air A is allowed to flow along the left-right direction (X direction in FIG. 1) of the storage container 5 toward the center thereof.

  The second air flow path portion 6b receives air A from the outside of the storage container 5 at the other end in the left-right direction of the storage container 5 (the left end in the X direction in FIG. 1) and passes it to the upper end of the storage container 5. After flowing, the air A is allowed to flow along the left-right direction (X direction in FIG. 1) of the storage container 5 toward the center thereof.

  The third air flow path part 6c joins the air A of the first air flow path part 6a and the air A of the second air flow path part 6b in the central portion in the left-right direction of the storage container 5, and from the upper side to the lower side. Let it flow toward.

  As described above, the air A flows through the first to third air flow path portions 6 a to 6 c provided in the storage container 5, so that the heat obtained by the combustion in the mixed combustion unit 3 and the fuel cell unit 2. The air A supplied to the fuel cell unit 2 is preheated by the heat generated by the reaction in step (b). And the air A spouted from the air outlet 15 of the 3rd air flow-path part 6c toward the left-right direction of the storage container 5 flows in into each of the air flow parts 8 from the side of the cell 9 side. The air flow part 8 is configured to flow the air A from the lower side toward the upper side.

  The storage container 5 is provided with an exhaust gas exhaust passage 16 that exhausts the exhaust gas C generated by combustion in the mixed combustion unit 3 to the outside of the storage container 5. The exhaust gas exhaust passage 16 includes a first exhaust flow passage portion 16a, a second exhaust flow passage portion 16b, and a third exhaust flow passage portion 16c.

  The first exhaust flow path portion 16 a receives the exhaust gas C from the mixed combustion unit 3 at one end portion in the left-right direction of the storage container 5 (right end portion in the X direction in FIG. 1). The first exhaust passage portion 16 a allows the exhaust gas C to flow to the lower end portion of the storage container 5, and then allows the air-fuel mixture to flow through the central portion along the left-right direction of the storage container 5.

  Similarly to the first exhaust flow passage portion 16a, the second exhaust flow passage portion 16b receives the exhaust gas C at the other end portion in the left-right direction of the storage container 5 (left end portion in the X direction in FIG. 2). After flowing C to the lower end portion of the storage container 5, the air-fuel mixture is passed through the central portion along the left-right direction of the storage container 5.

  The third exhaust flow path part 16c is configured to join the exhaust gas C of the first exhaust flow path part 16a and the exhaust gas C of the second exhaust flow path part 16b in the central portion of the storage container 5 in the left-right direction. Exhaust to the outside.

  As described above, as shown in FIGS. 1 and 2, the fuel cell unit 2 is configured by arranging a plurality of cells 9 in parallel, and around the plurality of cells 9 arranged in parallel in the fuel cell unit 2. A first cover body 20 and a second cover body 21 are provided. As shown in FIG. 2, the first cover body 20 and the second cover body 21 close the lateral side portion of the air flow portion 8 in the direction (X direction) orthogonal to the parallel arrangement direction of the cells 9. Is provided. The first cover body 20 is disposed on the first and second exhaust gas exhaust passages 16a and 16b side, and the second cover body 21 is disposed on the third air flow path portion 6c side.

  Thereby, the air flow part 8 is a space formed between the fuel flow part 7 and the fuel flow part 7 (between the cell 9 and the cell 9) in the parallel arrangement direction (Y direction) of the cells 9. And in the direction (X direction) orthogonal to the juxtaposition direction of the cells 9, it is comprised in the space formed between the 1st cover 20 and the 2nd cover 21. FIG.

  The first cover body 20 and the second cover body 21 are constituted by a heat insulator (for example, a heat-resistant board made of alumina / silica), and a series of surroundings of the plurality of cells 9 arranged side by side are arranged over the entire circumference. It is comprised so that it may cover. That is, in each of the side-by-side direction (Y direction) of the cells 9 and the direction (X direction) orthogonal to the side-by-side direction of the cells 9, the lateral side portion of the cell 9 and the first and second exhaust gas exhaust passages 16a and 16b are connected. The space between the part to be formed is filled with the first cover body 20, and the space between the lateral side portion of the cell 9 and the part to form the third air flow path part 6c is the second cover body. 21 is filled.

  The lower end 20a of the first cover 20 and the lower end 21a of the second cover 21 (upstream end in the fuel flow direction in the cell 9) are air outlets of the air supply path 6, as shown in FIG. It is arranged above 15. As a result, the air A ejected from the air outlet 15 flows into the lower portion of the air flow portion 8 surrounded by the fuel flow portion 7, the first cover body 20, and the second cover body 21. The air flow part 8 flows from the lower side toward the upper side.

  The upper end portion 20b of the first cover 20 is formed in a planar shape, and as shown in the figure, is substantially at the same height as the upper end 9a of the cell 9 (the downstream end in the fuel flow direction in the cell 9). Has been placed.

  The bypass path 22 penetrating in the thickness direction (X direction) of the first cover 20 is connected to the cell 9 from the upper end portion 10a of the air side electrode 10 (the downstream end portion in the air flow direction in the air flow portion 8). Provided along the Y direction so as to reach the upper end 9a (downstream end in the fuel flow direction in the cell 9) and over all of the plurality of air flow portions 8 in the fuel cell unit 2. Yes. Note that the bypass path 22 in the present embodiment is provided such that the height position of the lower end thereof coincides with the height position of the upper end portion 10 a of the air-side electrode 10. Further, the lengths of the bypass path 22 in the vertical width and the horizontal width are not limited to the present embodiment, and may be appropriately changed as necessary.

  Each of the left and right bypass paths 22 is connected to the first exhaust gas exhaust path 16a and the second exhaust gas exhaust path 16b. Thereby, the bypass path 22 does not draw out part A1 of the flowing air A from the middle of the path from the upper end portion 10a of the air side electrode 10 to the upper end 9a of the cell 9 so as to reach the mixed combustion section 3. To.

  The upper end portion 21b (the downstream end portion in the fuel flow direction in the cell 9) of the second cover body 21 is formed in a planar shape, and as shown in FIGS. 2 and 3, the upper end portion 9a (cell 9 at a position spaced from the downstream end in the fuel flow direction in FIG. In this embodiment, for example, the upper end portion 21b of the second cover body 21 is disposed at a position away from the upper end 9a of the cell 9 by the first set distance K1 (K1> 0). Moreover, since the fuel ejection part 11 is arrange | positioned in the downstream end of the fuel flow direction in the cell 9, in this example, the upper end part 21b of the 2nd cover 21 is also below the fuel ejection part 11 below. They are arranged at positions spaced apart by the first set distance K1.

  By setting the upper end portion 21b of the second cover body 21 at a position spaced apart from the upper end 9a of the cell 9 in the direction in which the cells 9 are arranged side by side (Y direction), fuel is supplied to the upper end 9a of the cell 9. Although it is blocked by the flow-through portion 7, it is not blocked by the second cover 21 up to the upper end 9 a of the cell 9 in the direction (X direction) orthogonal to the juxtaposed direction of the cells 9. Thereby, the open space 18 is formed above the upper end portion 21 b of the second cover body 21, and a part of the air A <b> 2 flowing through the air flow portion 8 is guided to the upper end 9 a of the cell 9. However, it is allowed to flow upward through the open space 18.

  In this way, the entire amount of the air A flowing through the air flow portion 8 is not guided to the upper end 9a of the cell 9, but a part thereof is ejected from the upper opening 12 formed at the upper end 9a of the cell 9. Then, the remaining part A1 is guided to the first exhaust gas exhaust path 16a and the second exhaust gas exhaust path 16b through the bypass path 22, and the remaining part A2 is passed through the open space 18 to the lateral side of the mixed combustion section 3. To supply.

  The space on the lateral side of the mixed combustion unit 3 is a space for guiding the exhaust gas C in the mixed combustion unit 3 to the exhaust gas exhaust passage 16, and the remaining part A2 is mixed and burned through the open space 18. It merges with the exhaust gas C in part 3. The exhaust gas C in the present embodiment reaches the exhaust gas exhaust passage 16 through both lateral sides and the upper side of the reformer 1.

  With the above-described configuration, the amount of air supplied to the mixed combustion unit 3 can be reduced, combustion in the mixed combustion unit 3 does not become excessive lean combustion, and combustion in the mixed combustion unit 3 is stabilized. Can be done. Further, since the amount of air supplied to the mixed combustion unit 3 can be reduced, for example, even if the fuel utilization rate is increased at the end of deterioration, the fuel gas component relative to the air component is reduced in the combustion in the mixed combustion unit 3. By relatively increasing, combustion in the mixed combustion unit 3 can be performed stably.

  As described above, when the upper end 21b of the second cover 21 is disposed at a position spaced downward from the upper end 9a of the cell 9, as shown in FIG. The upper end portion 21b of the second cover 21 is arranged with reference to the upper end portion 10a of the air-side electrode 10 provided (downstream end portion in the air flow direction in the air flow portion 8).

  The air-side electrode 10 provided on the air flow portion 8 side of the cell 9 is in consideration of its durability and the like, and the upper end portion 10a of the air-side electrode 10 (the air side in the air flow direction in the air flow portion 8) The downstream end portion of the electrode 10 is disposed at a position lower than the upper end 9a of the cell 9 (upstream in the fuel flow direction in the cell 9) by a second set distance K2 (K2> 0). Has been. Therefore, the set range S is set with the upper end portion 10a of the air-side electrode 10 as a reference, and the upper end portion 21b of the second cover 21 is arranged in the set range S. In this embodiment, for example, as shown in FIG. 3, the upper end portion 21 b of the second cover 21 is disposed between the upper end 9 a of the cell 9 and the upper end portion 10 a of the air-side electrode 10. Here, the setting range S is set so that sufficient air A is supplied to the upper end portion 10a of the air-side electrode 10. The set range S is, for example, a range between the upper end portion 10a of the air side electrode 10 and the upper end portion 9a of the cell 9 in the fuel flow direction in the cell 9, or lower than the upper end portion 10a of the air side electrode 10. Between a position spaced apart by a third set distance K3 (for example, ½ of the distance between the upper end 9a of the cell 9 and the upper end portion 10a of the air-side electrode 10) to the upper end 9a of the cell 9 Can be set to a range.

[Second Embodiment]
A second embodiment of the solid oxide fuel cell module 100 of the present invention will be described. In the present embodiment, only the configuration different from the first embodiment will be described.

  As shown in FIG. 4, the upper end portion 20 b of the first cover 20 in the present embodiment extends to the same height position as the upper end portion 1 b of the reformer 1. Therefore, the exhaust gas C in the mixed combustion unit 3 in the present embodiment reaches the exhaust gas exhaust passage 16 through the lateral side of the reformer 1 on the second cover 21 side and above the reformer 1. become.

[Another embodiment]
(1) In the above embodiment, in the fuel cell unit 2, the reformed gas G2 and the air A are allowed to flow from the lower side to the upper side, but the reformed gas G2 and the air A are allowed to flow. The direction is not limited to the direction along the vertical direction, and for example, it can be along the width direction of the fuel cell unit 2 and can be changed as appropriate.

(2) In the said embodiment, although the 1st cover and the 2nd cover are comprised with the heat insulating body, another member can also be used.

(3) In the above embodiment, as the cell 9, cells having various shapes and configurations including a fuel flow portion and an air flow portion are applicable, and the shape and configuration are the same as those of the above embodiment. Not limited.

(4) In the above embodiment, the position of the upper end portion 21b of the second cover body 21 is not limited to the above-described configuration, and for example, extends to the same height as the upper end 9a of the cell 9. May be. In this case, the open space 18 is not formed above the upper end portion 21 b of the second cover body 21, and a part of the air A <b> 2 that has flowed through the air flow portion 8 flows upward through the open space 18. Therefore, the amount of air supplied to the mixed combustion unit 3 is reduced by the amount of air A1 flowing through the bypass path 22.

  As an example, the solid oxide fuel cell module shown in FIG. 1 was used, the amount of air drawn from the bypass passage 22 was 30%, and the drawn air was joined to the exhaust gas exhaust passage. As a comparative example, a conventional solid electrolyte fuel cell module as shown in FIG. 7 was used.

  Table 1 below shows the CO concentration (ppm) in the exhaust gas when the fuel utilization rate Uf is 82% and 84% and the air utilization rate is 36%, and when the fuel is extracted from the exhaust gas exhaust passage. The temperature of the mixed combustion section is shown in Table 2 below.

  Note that the CO concentration at this time is extracted from the exhaust gas exhaust passage. In actual use, a combustion catalyst (not shown) is installed in the middle of the exhaust gas exhaust passage and burned there to remove CO in the exhaust gas. At the same time, the increased amount of heat of the exhaust gas is recovered by hot water in a subsequent heat exchanger for exhaust heat recovery (not shown), and the amount of heat of the hot water increases.

  When the CO concentration is high, the combustion state in the mixed combustion section is not good, and the internal heat of the module goes to the external hot water heat recovery section, which is not a good state for improving the power generation efficiency. Therefore, it is desired to lower the CO concentration.

  In addition, a relatively good combustion state can be obtained at a temperature of 700 ° C. or higher at the temperature of the mixed combustion section, but instability increases at a temperature of 600 ° C. Therefore, it is desirable to maintain 700 ° C. or higher.

  As shown in Tables 1 and 2, when the conventional solid oxide fuel cell module is used, the CO concentration increases from 550 ppm to 1300 ppm when the fuel utilization rate Uf is increased from 82% to 84%. The temperature also dropped to the 600 ° C. range (680 ° C.).

  On the other hand, in the solid oxide fuel cell module of the present invention, even when the fuel utilization rate Uf is increased from 82% to 84%, the CO concentration remains at 800 ppm, the temperature of the mixed combustion section becomes 705 ° C., and maintains the 700 ° C. level. did.

  Therefore, according to the solid oxide fuel cell module of the present invention, it was confirmed that a good state for combustion can be maintained even when the fuel utilization rate Uf is set high.

  FIG. 5 schematically shows the state of consumption of fuel gas, air, and oxygen in the air in a conventional solid oxide fuel cell module. Here, a situation is shown in which power generation is performed with a fuel utilization rate Uf of 82% and an air utilization rate of 40%.

  As shown in FIG. 5, when the fuel utilization rate Uf is 82%, 18% of the fuel gas remains when the fuel gas reaches the upper end of the air side electrode. When the oxygen amount (initial input amount) at the lower end (upstream) of the air electrode is 100%, 60% of oxygen remains at the upper end (downstream end) of the air-side electrode. This amount of residual oxygen is about 6.8 times the amount of oxygen required for complete combustion of the fuel gas for 18%, and the amount of oxygen is excessively large, which is not suitable for combustion.

  Conventionally, the fuel gas and oxygen reach the mixed combustion section with the above flow ratio and burn. Even after the combustion in the mixed combustion section, 51.2% of the initial input amount remains as the amount of oxygen, which accounts for 11.3% as the exhaust gas component (dry).

  On the other hand, as shown in FIG. 6, according to the solid oxide fuel cell module of the present invention, for example, 30% of the air that has passed through the downstream end of the air electrode is drawn out so as not to reach the mixed combustion section. In this case, the amount of oxygen at the downstream end of the cell can be reduced to 42% of the amount of oxygen (initial charge amount). The amount of oxygen at this time is about 4.8 times the amount of oxygen that completely burns 18% of the remaining fuel, and the amount of oxygen decreases, which is advantageous for combustion. Also, here, an example has been shown in which the rate of drawing air from the downstream side of the air side electrode is 30%. However, if the air utilization rate is 40%, the cell can be drawn even if the rate of drawing is about 80%. The amount of oxygen at the downstream end of the fuel can be about 1.3 times the theoretical combustion amount of the remaining fuel gas, and combustion can be performed without causing oxygen shortage in the mixed combustion portion.

  INDUSTRIAL APPLICABILITY The present invention can be suitably used in the industrial technical field that uses a solid oxide fuel cell.

100 Solid oxide fuel cell module 1 Reformer 2 Fuel cell section (cell stack)
DESCRIPTION OF SYMBOLS 3 Mixed combustion part 4 Evaporator 5 Storage container 6 Air supply path 7 Fuel flow part 8 Air flow part 9 Cell 10 Air side electrode 17 Conventional cover 20 First cover 21 Second cover 22 Bypass path G1 Original Fuel G2 Reformed gas A Air A1 Part of air

Claims (4)

A solid oxide fuel cell unit that generates power by reacting fuel gas and oxygen in the air in the storage container, and is disposed adjacent to the fuel cell unit, and remains after the reaction in the fuel cell unit A mixed combustion section for mixing and burning fuel gas and oxidant,
The fuel cell unit is configured by arranging a plurality of cells in a parallel state, and has a fuel flow part through which fuel gas flows and an air flow part through which air flows,
The mixed combustion section is a downstream end in the fuel flow direction in the cell as a combustion space for mixing and burning the fuel gas flowing through the fuel flow section and the air flowing through the air flow section. Provided adjacent to
The fuel flow part causes fuel gas to flow through a flow path surrounded by the fuel gas, and jets fuel gas from a fuel jet part arranged at a downstream end of the cell in the fuel flow direction. Configured,
The air flow portion is configured to flow air through a space formed between the fuel flow portion and the fuel flow portion in the juxtaposed direction of the cells,
A cover that covers the periphery of the plurality of cells arranged side by side in the fuel cell unit and closes a lateral side portion of the air flow part in a direction perpendicular to the direction in which the cells are arranged;
An air side electrode is provided on the air flow portion side of the cell, and a downstream end portion of the air side electrode is disposed at a position spaced from the downstream end of the cell at an upstream side. And
Provided with a bypass path that draws a part of the flowing air from the downstream end of the air side electrode to the downstream end of the cell so as not to reach the mixed combustion section. A solid oxide fuel cell module.   2. The solid oxide fuel cell module according to claim 1, wherein the bypass path is connected to an exhaust gas path for discharging exhaust gas generated in the mixed combustion section to the outside.   3. The solid oxide fuel cell module according to claim 1, wherein the mixed combustion unit is installed so as to apply heat to a reformer that reforms the raw fuel. 4.   The solid electrolyte fuel cell module according to claim 1, wherein the bypass path is formed in the cover.

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