JP2004127640A - Heat exchange structure of fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat exchange structure of carrying out heat exchange effectively inside a fuel cell. <P>SOLUTION: The fuel cell 1 is constituted such that fuel gas 4 is supplied inside a cell tube of a cylindrical shape and oxidizer gas 6 is supplied to the fuel cell 8 provided on the outside of the cell tube 2, and by making the inside of the fuel cell a high temperature environment of 800-1,000°C, the fuel gas 4 and the oxidizer gas 6 are chemically reacted and power is generated. A core 13 is fixed by a current collector cap (not shown in the figure) inside the cell tube 2, and the passage of the fuel gas 4 is made narrower, and thereby the heat of the fuel gas 4 is conducted to the oxidizer gas 6 via a base tube 10 with high thermal conductivity and the oxidizer gas 6 is preheated sufficiently. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a heat exchange structure for a fuel cell.
[0002]
[Prior art]
A fuel cell is a power generation device using a power generation method by an electrochemical reaction, and has characteristics such as excellent power generation efficiency and environmental friendliness. For this reason, research and development for practical use are progressing as an urban-type energy supply system for the 21st century.
[0003]
FIG. 8 is a schematic configuration diagram showing a one-through type fuel cell which is an example of a conventional fuel cell. Note that, in FIG. 8, structures relating to preheating and heat exchange of various gases used for operation of the fuel cell and structures relating to current collection of generated power are omitted. A one-through type fuel cell is a type of fuel cell in which fuel gas supplied from one end of a cell tube is discharged from the other end of the cell tube with respect to the flow method of the fuel gas.
[0004]
As shown in FIG. 1, the fuel cell 1 includes a plurality of cylindrical cell tubes 2 (three in the figure), a supply chamber 3 a for supplying a fuel gas 4 to the cell tubes 2, An exhaust chamber 3b for discharging the exhaust fuel gas 5 and an oxidant supply chamber 25 to which the oxidant gas 6 is supplied.
[0005]
The upper tube sheet 21 and the lower tube sheet 22 are provided with holes through which the cell tubes 2 pass. By passing the cell tubes 2 through the holes, the cell tubes 2 are supported, and the supply chamber 3a and the discharge chamber 3b are oxidized. The agent supply chamber 25 is isolated. The upper support 23 and the lower support 24 support the cell tube 2 in an auxiliary manner. The cylindrical cell tube 2 is made of a porous material, and a plurality of fuel cells 8 are formed on the outer peripheral surface thereof. The fuel cell may be configured by providing only one element of the fuel cell 8 on the outer surface of the cell tube 2, and this type of fuel cell is referred to as a single element type fuel cell.
[0006]
When power is generated by the fuel cell 1, hydrogen, methane, or the like is supplied as fuel gas 4 from the supply chamber 3 a into the cell tube 2, and oxygen, air, or the like is supplied as oxidant gas 6 to the outer peripheral surface of the cell tube 2. Supply. Further, by setting the inside of the fuel cell 1 to a high temperature environment of about 800 ° C. to 1000 ° C., the fuel gas 4 and the oxidizing gas 6 electrochemically react in the fuel cell 8 to generate power.
[0007]
The fuel gas 4 (unreacted fuel gas or the like) that has passed through the cell tube 2 is discharged from the discharge chamber 3b to the outside of the fuel cell 1 as a discharged fuel gas 5. The oxidant gas 6 (such as unreacted oxidant gas) that has passed through the oxidant supply chamber 25 is discharged to the outside of the fuel cell 1 as a discharged oxidant gas 7. Note that an oxidizing gas may be supplied to the cell tube 2 and a fuel gas may be supplied to the outer peripheral surface of the cell tube 2. In this case, a fuel electrode (not shown) and an air electrode constituting the fuel cell 8 are provided. The arrangement of (not shown) may be reversed.
[0008]
As described above, in order to use a chemical reaction in a high temperature environment of about 800 ° C. to 1000 ° C. to generate power, when supplying the fuel gas 4 and the oxidizing gas 6 from the outside, the gas is preheated in advance. Need to be kept. This is because, if the supplied gas is not preheated, the temperature of the fuel cell unit 8 is lowered, which may cause a reduction in power generation efficiency and instability of power generation itself.
[0009]
The preheating is performed by using high-temperature exhaust gas for efficiency. That is, heat exchange is performed between the high-temperature discharged fuel gas 5 discharged from the discharge chamber 3b and the oxidizing gas 6 supplied to the fuel cell 1, and the oxidizing gas 6 is preheated. Further, heat exchange is performed between the high-temperature exhaust oxidant gas 7 and the fuel gas 4 supplied to the fuel cell 1 to preheat the fuel gas 4. For this reason, equipment and pipes for heat exchange are installed in the exhaust gas discharge path (for example, see Patent Document 1).
[0010]
[Patent Document 1]
JP 2002-63916 A
[0011]
In the fuel cell described in Patent Document 1, the preheating of the fuel gas supplied to the cell tube (corresponding to the base tube in the document) is not particularly described. However, when a fuel gas that is not preheated is used, the power generation efficiency is low, and the fuel cell described in the literature requires the above-described heat exchange equipment and the like to improve the power generation efficiency.
[0012]
[Problems to be solved by the invention]
However, the operating environment of the fuel cell is an extremely high temperature environment of 800 ° C. to 1000 ° C. In order to compensate for the shortage of preheating, heating by a heat source such as a heater or heat exchange equipment installed in an exhaust path is large. Had to be converted.
[0013]
The present invention has been made in view of the above circumstances, and has a heat exchange structure of a fuel cell capable of efficiently exchanging heat inside the fuel cell and effectively utilizing heat generated inside the fuel cell. The purpose is to provide.
[0014]
[Means for Solving the Problems]
A first aspect of the present invention to solve the above-mentioned problem is to supply a first gas into a cylindrical base tube and to supply a second gas to a fuel cell provided on an outer surface of the base tube. Thereby, when the first gas and the second gas are electrochemically reacted in the fuel cell to generate power, the first gas passing through the inside of the base tube and the outside of the base tube pass through the fuel cell. In the heat exchange structure of a fuel cell, wherein the second gas and the second gas exchange heat through the base tube,
A core that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
Centering means for centering the core with respect to the base tube;
And a core supporting means for supporting the core on the base tube.
[0015]
The core is supported by the core support means inside the base tube, and the first gas flows through the gap between the base tube and the core formed by installing the core, thereby forming the first gas and the base tube. And efficiently conducts heat with the second gas flowing outside. The core supporting means may be provided on the core or on the base tube side. The core may have any shape and size as long as it can enter the inside of the base tube. Examples of the shape of the core include a columnar shape (cross section is circular), a prismatic shape (cross section is polygonal), a columnar shape having a star or ellipse cross section, and the like.
[0016]
A second aspect of the present invention to solve the above-mentioned problem is to supply a first gas into a cylindrical base tube and supply a second gas to a fuel cell provided on an outer surface of the base tube. Thereby, when the first gas and the second gas are electrochemically reacted in the fuel cell to generate power, the first gas passing through the inside of the base tube and the outside of the base tube pass through the fuel cell. In the heat exchange structure of a fuel cell, wherein the second gas and the second gas exchange heat through the base tube,
A core body that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
Centering means provided on the surface of the core body, for centering the core body with respect to the base tube,
A heat exchange structure for a fuel cell, comprising a core provided at one end of the core main body and comprising a core supporting means for supporting the core main body on the base tube.
[0017]
The core is supported inside the base tube by the core support means installed in the core body, and the first gas flows through the gap between the base tube and the core formed by installing the core. Thereby, heat conduction between the first gas and the second gas flowing outside the base tube is efficiently performed. The core body may have any shape and size as long as it can enter the inside of the base tube. Examples of the shape of the core include a columnar shape (cross section is circular), a prismatic shape (cross section is polygonal), a columnar shape having a star or ellipse cross section, and the like.
[0018]
[Third invention] which solves the above-mentioned problem is a heat exchange structure for a fuel cell according to [Second invention],
The heat exchange structure for a fuel cell, wherein the core is suspended from the base tube by the core support means being hooked on an end of the base tube.
[0019]
[Fourth invention] which solves the above-mentioned problem is a fuel cell heat exchange structure according to [Second invention],
Further, a cap provided at an end of the base tube,
A heat exchange structure for a fuel cell, wherein the core is supported by the base tube by sandwiching the core support means between the cap and an end of the base tube.
[0020]
The core support means is installed on the core (core body), and the core (core body) is supported by the base tube by the core support means being sandwiched between the ends of the base tube.
[0021]
A fifth aspect of the present invention to solve the above-mentioned problem is to supply a first gas into a cylindrical base tube and supply a second gas to fuel cells provided on an outer surface of the base tube. Thereby, when the first gas and the second gas are electrochemically reacted in the fuel cell to generate power, the first gas passing through the inside of the base tube and the outside of the base tube pass through the fuel cell. In the heat exchange structure of a fuel cell, wherein the second gas and the second gas exchange heat through the base tube,
A core body that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
A core provided on the surface of the core body, and having a centering means for centering the core body with respect to the base tube;
A cap provided at a lower end of the base tube,
At the lower end of the core body, a flow path changing unit that changes the flow path of the first gas between the outside and the inside of the core is further provided,
The heat exchange structure for a fuel cell, wherein the core is supported by the base tube by being supported by the cap so that the core does not move in the vertical direction.
[0022]
The flow path changing unit is a structural unit having a function of guiding the first gas from the outer surface of the core body to the inside and changing the flow path so that the first gas is discharged from the center of the core. Conversely, it is a structural part having a function of changing the flow path so that the first gas is supplied from the center of the core and guided to the outside of the core body. The flow path changing unit has one of the two functions according to the flow direction of the first gas.
[0023]
The core body may have any shape and size as long as it can enter the inside of the base tube. Examples of the shape of the core include a columnar shape (cross section is circular), a prismatic shape (cross section is polygonal), a columnar shape having a star or ellipse cross section, and the like.
[0024]
[Sixth invention] which solves the above-mentioned problem is a heat exchange structure for a fuel cell according to any one of [First invention] to [Fifth invention].
The heat exchange structure of a fuel cell, wherein the core includes a catalyst for reforming the first gas.
[0025]
For the first gas passing through the inside of the base tube, the core provided with the catalyst provided on the upstream side of the base tube plays the following two roles. The first role is to reform the first gas into a gas usable in a fuel cell. The heat required for the reforming uses the heat generated by the fuel cell, so that a separate reformer is not required and the efficiency is improved. The second role is to purify the supplied gas, for example, to remove sulfur and the like harmful to the cell. Conversely, when a core having a catalyst is provided downstream of the base tube, the heat of the first gas discharged from the fuel cell is used to promote the preheating of the supply air, and the exhaust gas is discharged from the fuel cell. The first gas to be purified can be purified.
[0026]
[Seventh invention] which solves the above-mentioned problem is a heat exchange structure for a fuel cell according to a [fourth invention] or a [fifth invention],
The cap is
A heat exchange structure for a fuel cell, characterized in that the heat exchange structure is a current collection cap that is in close contact with a conductive lead film provided on the base tube and collects power generated by the fuel cell to the outside.
[0027]
As a power collection method, there are an external power collection and an internal power collection. Therefore, the current collecting cap may be an external current collecting type current collecting cap or an internal current collecting type current collecting cap. The outer surface current collecting type is a method in which a lead film is formed up to the end of the outer surface of the base tube, and power generated in the fuel cell is collected from the outer surface of the base tube. On the other hand, a method in which the lead film is provided to be folded back to the inside at the end of the base tube and the current is collected by fitting a current collecting cap inside the base tube is called inner surface current collection.
[0028]
According to an eighth aspect of the present invention, a first gas is supplied into a cylindrical base tube, and a second gas is supplied to fuel cells provided on an outer surface of the base tube. Thereby, in the fuel cell that generates electric power by electrochemically reacting the first gas and the second gas in the fuel cell,
A fuel cell comprising the fuel cell heat exchange structure according to any one of [First Invention] to [Seventh Invention].
[0029]
By sufficiently preheating the first or second gas supplied to the fuel cell, the power generation efficiency of the fuel cell is improved.
[0030]
A ninth invention for solving the above-mentioned problem is the fuel cell according to the eighth invention, wherein:
The fuel cell is a one-through type fuel cell in which the first gas is supplied from one end of the base tube and the first gas is discharged from the other end of the base tube.
[0031]
A one-through type fuel cell is a type of fuel cell in which fuel gas supplied from one end of a cell tube is discharged from the other end of the cell tube with respect to the flow method of the fuel gas.
[0032]
[Tenth invention] which solves the above-mentioned problem is a fuel cell according to an [eighth invention] or a [ninth invention],
The first gas is a fuel gas, and the second gas is an oxidizing gas.
[0033]
An eleventh invention for solving the above-mentioned problem is a fuel cell according to the eighth invention or the ninth invention,
The fuel cell according to claim 1, wherein the first gas is an oxidizing gas, and the second gas is a fuel gas.
[0034]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described more specifically based on embodiments, but the following embodiments do not limit the present invention.
[0035]
[First Embodiment]
FIG. 1 is a schematic configuration diagram of a fuel cell to which a heat exchange structure for a fuel cell according to a first embodiment of the present invention is attached. In FIG. 1, the structure related to the collection of the generated power is omitted.
[0036]
As shown in FIG. 1, the fuel cell 1 includes a plurality of cylindrical cell tubes 2 (three in the figure), a supply chamber 3 a for supplying a fuel gas 4 to the cell tubes 2, An exhaust chamber 3b for discharging the exhaust fuel gas 5 and an oxidant supply chamber 25 to which the oxidant gas 6 is supplied.
[0037]
The upper tube sheet 21 and the lower tube sheet 22 are provided with holes through which the cell tubes 2 pass. By passing the cell tubes 2 through the holes, the cell tubes 2 are supported, and the supply chamber 3a and the discharge chamber 3b are oxidized. The agent supply chamber 25 is isolated. The upper support 23 and the lower support 24 support the cell tube 2 in an auxiliary manner.
[0038]
The core 13 is a member that is formed into a cylindrical shape having a diameter slightly smaller than the inner diameter of the cell tube 2 and is attached to a lower end inside the cell tube 2 by a method described later. 4 is provided to narrow the flow path.
[0039]
The cylindrical cell tube 2 is made of a porous material, and a plurality of fuel cells 8 are formed on the outer peripheral surface thereof. The fuel cell may be configured by providing only one element of the fuel cell 8 on the outer surface of the cell tube 2, and this type of fuel cell is referred to as a single element type fuel cell.
[0040]
When power is generated by the fuel cell 1, hydrogen, methane, or the like is supplied as fuel gas 4 from the supply chamber 3 a into the cell tube 2, and oxygen, air, or the like is supplied as oxidant gas 6 to the outer peripheral surface of the cell tube 2. Supply. Further, by setting the inside of the fuel cell 1 to a high temperature environment of about 800 ° C. to 1000 ° C., the fuel gas 4 and the oxidizing gas 6 electrochemically react in the fuel cell 8 to generate power.
[0041]
The fuel gas 4 (unreacted fuel gas or the like) that has passed through the cell tube 2 is discharged from the discharge chamber 3b to the outside of the fuel cell 1 as a discharged fuel gas 5. The oxidant gas 6 (such as unreacted oxidant gas) that has passed through the oxidant supply chamber 25 is discharged to the outside of the fuel cell 1 as a discharged oxidant gas 7. Note that an oxidizing gas may be supplied to the cell tube 2 and a fuel gas may be supplied to the outer peripheral surface of the cell tube 2. In this case, a fuel electrode (not shown) and an air electrode constituting the fuel cell 8 are provided. The arrangement of (not shown) may be reversed.
[0042]
As described above, in order to use a chemical reaction in a high temperature environment of about 800 ° C. to 1000 ° C. to generate power, when supplying the fuel gas 4 and the oxidizing gas 6 from the outside, the gas is preheated in advance. Need to be kept. This is because if the gas to be supplied is not preheated, the temperature of the fuel cell unit 8 is reduced, which may cause a reduction in power generation efficiency and instability of power generation itself.
[0043]
In the present embodiment, the gas is preheated by providing the core 13 inside the cell tube 2. Hereinafter, a mechanism in which the core 13 performs preheating of the gas will be described in detail.
[0044]
FIG. 2 is an enlarged view of a lower end portion of the cell tube 2 in FIG. 1 and is a schematic configuration diagram of a heat exchange structure according to the first embodiment. 3 is an external view schematically showing the core 13, wherein FIG. 3 (a) is a schematic side view of the core 13, and FIG. 3 (b) is a view in the direction of arrow B in FIG. FIG. 1C is a schematic view, and FIG. 1C is a cross-sectional view taken along the line CC in FIG. FIG. 4 is a schematic external view (a) and a side sectional view (b) of the current collecting cap 20 in FIG.
[0045]
As shown in FIG. 3, the core 13 includes a cylindrical core body 15, a centering portion 14 (centering means) which is a protrusion provided on the surface of the core body 15, and one end of the core body 15. And a gas flow port 16-2 provided on the side surface of the core body 15 and communicating from the outer surface of the core body 15 to the recess 16-1. The diameter of the core body 15 is smaller than the inner diameter of the base tube 10, and when the core 13 is installed inside the base tube 10, the centering portion 14 is in contact with the inner surface of the base tube 10. .
[0046]
As shown in FIG. 4, the current collecting cap 20 has a gas hole 30 provided above a cylindrical member formed of a conductive material such as nickel, and an elastic portion 31 provided inside the cylinder. Become. The elastic portion 31 can be elastically moved inside the cylindrical current collecting cap 20 in the direction toward the center of the cylinder and radially outward.
[0047]
As shown in FIG. 2, a lead film 11 serving as a lead wire is formed on the outer peripheral surface of the base tube 10 from the lowermost fuel cell (not shown) to the lower end of the base tube 10. . The protective film 12 is not formed near the lower portion of the lead film 11 and is in a bare state, and the elastic part 31 of the current collecting cap 20 is urged to come into close contact with the exposed lead film 11. The current collecting cap 20 is attached.
[0048]
A conducting wire 35 is connected to the current collecting cap 20, and the generated power is taken out of the fuel cell. As described above, a method of collecting power generated in the fuel cell from the outer surface of the base tube 10 is referred to as outer surface current collecting, and the current collecting cap 20 is an outer surface current collecting type. On the other hand, a method in which the lead film 11 is provided to the inside at the lower end of the base tube 10 and the current is collected by fitting a current collecting cap inside the base tube 10 is called inner surface current collection.
[0049]
The gas hole 30 provided in the current collecting cap 20 is formed slightly smaller than the diameter of the core 13. For this reason, the core 13 inserted into the inside of the base tube 10 is supported by the current collecting cap 20 attached to the lower end of the base tube 10 so as not to shift in the vertical direction. That is, the current collecting cap 20 is a member that also functions as “core supporting means” for supporting the core 13.
[0050]
The core 13 has a centering part 14 as a centering means. For this reason, the centering portion 14 centers the core 13 so that the center axis of the core body 15 and the center axis of the base tube 10 overlap, and a certain gap is formed between the base tube 10 and the core body 15. Is done.
[0051]
In the heat exchange structure 26 according to the present embodiment, the core 13 is supported by the current collecting cap 20 as “core supporting means”, is attached inside the base tube 10, and passes through the inside of the base tube 10. The heat exchange is performed by conducting the heat of the fuel gas 4 to the oxidizing gas 6 passing through the outside of the base tube 10 through the base tube 10.
[0052]
That is, the fuel gas 4 is heated by the heat inside the fuel cell while passing through the base tube 10 from the supply chamber 3a, and becomes a gas of 800 ° C. to 1000 ° C. at the lower end of the base tube 10. On the other hand, the oxidizing gas 6 supplied from the outside of the fuel cell is not sufficiently heated in the lower portion of the base tube 10 immediately after being supplied to the fuel cell.
[0053]
Here, at the lower end of the base tube 10, the core 13 is attached, and a certain gap is formed between the base tube 10 and the core main body 15, so that the flow path of the fuel gas 4 is narrowed. ing. For this reason, the heat of the fuel gas 4 is transmitted to the oxidizing gas 6 via the base tube 10 with high thermal conductivity. The fuel gas 4 that has passed through the gap between the base tube 10 and the core body 15 is supplied to the gas flow port 16-2, which is a flow path changing path provided at one end (lower end) of the core 13, and the recess 16-1. And exhausted into the exhaust chamber 3b as the exhaust fuel gas 5.
[0054]
Thereby, the residual heat of the fuel gas 4 can be efficiently transmitted to the oxidizing gas 6. That is, it is possible to prevent a decrease in power generation efficiency and an unstable power generation itself due to the supply of the oxidizing gas 6 with insufficient preheating. Further, it is not necessary to increase the size of an external heat exchange facility or heater to compensate for the shortage of the preheating of the oxidizing gas 6.
[0055]
In the present embodiment, the fuel gas 4 is supplied to the cell tube 2 and the oxidant gas is supplied to the outer surface of the cell tube 2. The fuel gas may be supplied to the outer surface of the cell tube 2. In this case, the arrangement of the fuel electrode (not shown) and the air electrode (not shown) constituting the fuel cell 8 may be reversed.
[0056]
Further, the current collecting cap 20 may be an inner surface current collecting type current collecting cap or a cap having no current collecting function.
[0057]
Further, the flow directions of the fuel gas 4 and the oxidizing gas 6 are reversed, the fuel gas 4 is supplied from the lower end of the cell tube 2, and the oxidizing gas 6 flows from the upper support 23 to the lower support 24. You may do so. In this case, the core 13 attached to the lower end of the cell tube 2 performs heat exchange based on heat conduction opposite to the heat exchange described above. That is, the heat of the oxidizing gas heated from 800 ° C. to 1000 ° C. through the oxidizing agent supply chamber 25 is transferred to the fuel gas immediately after being supplied to the base tube 10 from the outside via the base tube 10. Thereby, the fuel gas is preheated.
[0058]
When the fuel gas 4 is supplied from the lower end of the cell tube 2, the surface of the core 13 is covered with a reforming catalyst, so that the fuel gas 4 supplied to the base tube 10 is reformed in advance, and The reaction efficiency in the cell can be improved. As the reforming catalyst, a catalyst in which a metal (Ni, Ru, Rh, or the like) is supported on a porous support having a high surface area (alumina, silica, magnesia, zirconia, or the like) can be used.
[0059]
[Second Embodiment]
FIG. 5 is a schematic configuration diagram of a heat exchange structure of a fuel cell according to the second embodiment of the present invention. The heat exchange structure of the fuel cell according to this embodiment is attached to the one-through type fuel cell shown in FIG. 8 (further attached to the upper end of the cell tube 2), and relates to the configuration of the entire fuel cell. The description is as described above. FIG. 6 is an external view schematically showing the core 13 according to the present embodiment. FIG. 6A is a schematic side view of the core 13, and FIG. FIG. 2C is a schematic view in the direction of the arrow B, and FIG. 2C is a sectional view taken along the line CC in FIG.
[0060]
As shown in FIG. 6, the core 13 includes a cylindrical core main body 15, a centering portion 14 (centering means) which is a protrusion provided on the surface of the core main body 15, and one end of the core main body 15. And a flange portion 17 (core support means) of a disk member slightly larger than the diameter of the core body 15. The collar portion 17 is provided with three notches 18, and the notch portion 18 has a structure in which a part of the collar portion 17 has been cut off until the diameter of the core body 15 is reached. The diameter of the core body 15 is smaller than the inner diameter of the base tube 10, and the centering portion 14 is in contact with the inner surface of the base tube 10 inside the base tube 10.
[0061]
As shown in FIG. 5, a lead film 11 serving as a lead wire is formed on the outer peripheral surface of the base tube 10 from the uppermost fuel cell (not shown) to the upper end of the base tube 10. . The protection film 12 is not formed near the upper portion of the lead film 11 and is in a bare state. The elastic part 31 of the current collecting cap 20 is urged to come into close contact with the exposed lead film 11. The current collecting cap 20 is attached. A conducting wire 35 is connected to the current collecting cap 20, and the generated power is taken out of the fuel cell.
[0062]
The basic structure of the current collecting cap 20 is the same as that of the current collecting cap described in the first embodiment (see FIG. 4), but the gas holes 30 are slightly different from those in the first embodiment. Largely molded. That is, the diameter of the gas hole 30 of the current collecting cap 20 according to the present embodiment is the same as the inner diameter of the base tube 10.
[0063]
The diameter of the flange 17 provided at one end of the core 13 is substantially the same as the outer diameter of the base tube 10. For this reason, the collar portion 17 is hooked on the upper end of the base tube 10, and the core 13 is suspended inside the base tube 10. That is, the collar portion 17 has a function as “core supporting means”. Further, the flange 17 of the core 13 is sandwiched between the upper end of the base tube 10 and the current collecting cap 20 by the current collecting cap 20 attached to the upper end of the base tube 10. Therefore, the current collecting cap 20 also has a function as a core supporting means. As a result, the core 13 is supported inside the base tube 10.
[0064]
The core 13 has a centering part 14 as a centering means. For this reason, the centering portion 14 centers the core 15 so that the center axis of the core body 15 and the center axis of the base tube 10 overlap, and a certain gap is formed between the base tube 10 and the core body 15. Is done.
[0065]
In the heat exchange structure 26 according to the present embodiment, the core 13 is attached to the inside of the base tube 10, and the heat of the exhausted oxidant gas 7 passing outside the base tube 10 is transferred through the base tube 10. Heat exchange is performed by conduction to the fuel gas 4 passing through the inside of the fuel cell 10.
[0066]
That is, the oxidizing gas 6 is heated by the heat inside the fuel cell while passing through the oxidizing agent supply chamber 25, and is discharged from the upper portion of the base tube 10 at 800 ° C. to 1000 ° C. On the other hand, the fuel gas 4 supplied from the outside of the fuel cell is not sufficiently heated at the upper end portion (near the supply chamber 3a) of the base tube 10 immediately after being supplied to the fuel cell.
[0067]
Here, the core 13 is attached to the upper end of the base tube 10, and a certain gap is formed between the base tube 10 and the core main body 15, so that the flow path of the fuel gas 4 is narrowed. ing. For this reason, the heat of the discharged oxidizing gas 7 is transmitted to the fuel gas 4 through the base tube 10 with high thermal conductivity. The flange 17 is provided with a notch 18, and the oxidizing gas 4 is supplied from the notch 18 into the inside of the base tube 10 (a gap between the base tube 10 and the core body 15).
[0068]
As a result, the residual heat of the exhausted oxidizing gas 7 can be efficiently transmitted to the fuel gas 4, and a decrease in power generation efficiency and instability of power generation itself due to the supply of the insufficiently preheated fuel gas 4 can be prevented. Can be prevented. Further, it is not necessary to increase the size of an external heat exchange facility or heater to compensate for the shortage of the preheating of the fuel gas 4. If the preheating of the fuel gas 4 is sufficient only by heat conduction from the power generation section of the cell, the discharged oxidizing gas 7 passes through the space between the upper support body 23 and the upper tube sheet 21 to cause Instead of being discharged to the outside, it may be discharged from the oxidant supply chamber 25 as it is.
[0069]
In the present embodiment, the oxidizing gas may be supplied to the cell tube 2 and the fuel gas may be supplied to the outer surface of the cell tube 2. In this case, the fuel electrode (see FIG. ) And the air electrode (not shown) may be reversed.
[0070]
Further, the current collecting cap 20 may be an inner surface current collecting type current collecting cap or a cap having no current collecting function.
[0071]
Furthermore, the core 13 according to the present embodiment can be supported to some extent by the collar 17 being hooked on the upper end of the base tube 10. Further, by covering the surface of the core 13 with the reforming catalyst, the fuel gas 4 supplied to the base tube 10 can be reformed, and the reaction efficiency in the fuel cell unit can be improved.
[0072]
In addition, since the core 13 according to the present embodiment has the flange 17, it can be installed at the lower end of the cell tube 2. In this case, the core 13 is supported by sandwiching the collar 17 at the lower end of the base tube with the current collecting cap 20.
[0073]
Further, the flow directions of the fuel gas 4 and the oxidizing gas 6 are reversed, the fuel gas 4 is supplied from the lower end of the cell tube 2, and the oxidizing gas 6 flows from the upper support 23 to the lower support 24. You may do so. In this case, the core 13 attached to the upper end of the cell tube 2 performs heat exchange based on heat conduction opposite to the heat exchange described above. That is, the heat of the fuel gas heated from 800 ° C. to 1000 ° C. after passing through the base tube 10 is transferred to the fuel gas immediately after being supplied to the oxidant supply chamber 25 from the outside via the base tube 10. Thereby, the oxidizing gas is preheated.
[0074]
[Third Embodiment]
FIG. 7 is an external view schematically showing a core 13 according to a third embodiment of the present invention. FIG. 7 (a) is a schematic side view of the core 13, and FIG. (a) is a schematic view in the direction of arrow B, and (c) is a cross-sectional view as viewed in the direction of arrow CC in FIG.
[0075]
As shown in FIG. 7, the core 13 includes a cylindrical core main body 15, a centering portion 14 (centering means) which is a protrusion provided on the surface of the core main body 15, and one end of the core main body 15. And a projection 19 (core support means) projecting slightly larger than the diameter of the core body 15. Two protrusions 19 are provided at one end of the core body 15. The diameter of the core body 15 is smaller than the inner diameter of the base tube 10, and when the core 13 is installed inside the base tube 10, the centering portion 14 is in contact with the inner surface of the base tube 10.
[0076]
When the core 13 according to the present embodiment is used as a heat exchange structure, it can be used in the same manner as in the second embodiment. That is, the protrusion 19 corresponds to the flange 17 (core support means) of the core 13 according to the second embodiment. Therefore, the core 13 is supported inside the base tube 10 by the projection 19 serving as the core supporting means being hooked on the upper end of the base tube 10. Further, the base tube 10 may be sandwiched and fixed between the base tube 10 and the current collecting cap 20. In addition to this, it goes without saying that the core 13 according to the present embodiment can be used in the form described in the section of the second embodiment.
[0077]
【The invention's effect】
In the invention according to [claim 1], the first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cells provided on the outer surface of the base tube. When the first gas and the second gas are electrochemically reacted in the battery cell to generate power, the first gas passing inside the base tube and the second gas passing outside the base tube And the heat exchange structure of the fuel cell performing heat exchange through the base tube,
A core that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
Centering means for centering the core with respect to the base tube;
With the core support means for supporting the core to the base tube,
The core is supported by the core support means inside the base tube, and the first gas flows through the gap between the base tube and the core formed by installing the core, thereby forming the first gas and the base tube. Can efficiently conduct heat with the second gas flowing outside. Thus, it is possible to prevent a decrease in power generation efficiency and an unstable power generation itself due to the supply of the first gas or the second gas with insufficient preheating. In addition, it is not necessary to increase the size of an external heat exchange facility or heater to compensate for the shortage of the preheating of the supply gas.
[0078]
In the invention according to [Claim 2], the first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cell provided on the outer surface of the base tube, whereby the fuel is supplied. When the first gas and the second gas are electrochemically reacted in the battery cell to generate power, the first gas passing inside the base tube and the second gas passing outside the base tube And the heat exchange structure of the fuel cell performing heat exchange through the base tube,
A core body that is provided inside the base tube and narrows the flow path of the first gas in the base tube; and a core body that is provided on the surface of the core body and centers the core body with respect to the base tube. A centering means, and a core provided at one end of the core body and a core supporting means for supporting the core body on the base tube,
In addition to the effects achieved by the invention according to claim 1, a core can be integrally manufactured as a core having core support means.
[0079]
In the invention according to [Claim 3], in the heat exchange structure for a fuel cell according to [Claim 2],
The core is suspended from the base tube by the core supporting means being hooked on the end of the base tube, so that the core can be fixed to the base tube by a simple method.
[0080]
In the invention according to [Claim 4], in the heat exchange structure for a fuel cell according to [Claim 2],
Further, a cap provided at an end of the base tube,
Since the core supporting means is sandwiched between the cap and the end of the base tube, the core is supported by the base tube.
The core can be supported on the base tube by a simple method, and the core can be reliably supported by the cap.
[0081]
In the invention according to claim 5, the first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cells provided on the outer surface of the base tube, whereby the fuel is supplied. When the first gas and the second gas are electrochemically reacted in the battery cell to generate power, the first gas passing inside the base tube and the second gas passing outside the base tube And the heat exchange structure of the fuel cell performing heat exchange through the base tube,
A core body provided inside the base tube and narrowing a flow path of the first gas in the base tube; and a core body provided on a surface of the core body and centering the core body with respect to the base tube. And a centering means,
A cap provided at a lower end of the base tube,
At the lower end of the core body, a flow path changing unit that changes the flow path of the first gas between the outside and the inside of the core is further provided,
Since the core is supported by the cap so as not to move in the vertical direction, the core is supported by the base tube,
The core can be fixed by a simple method.
[0082]
In the invention according to [Claim 6], in the heat exchange structure for a fuel cell according to any one of [Claim 1] to [Claim 5],
Since the core is provided with a catalyst for reforming the first gas,
When a core having a catalyst is provided on the upstream side of the base tube for the first gas passing through the inside of the base tube, the first gas is reformed into a gas that improves the efficiency of the power generation reaction in the fuel cell, Power generation efficiency can be improved. Conversely, when a core including a catalyst is provided downstream of the base tube, the first gas discharged from the fuel cell can be purified.
[0083]
In the invention according to [claim 7], in the heat exchange structure for a fuel cell according to [claim 4] or [claim 5],
Since the cap is in close contact with the conductive lead film provided on the base tube, it is a current collecting cap for collecting the power generated by the fuel cell outside the battery,
The core can be fixed by a simple method using a current collecting cap.
[0084]
In the invention according to claim 8, the first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cell provided on the outer surface of the base tube, whereby the fuel is supplied. In a fuel cell that generates electric power by electrochemically reacting the first gas and the second gas in a battery cell,
With the fuel cell heat exchange structure according to any one of [Claim 1] to [Claim 7],
In addition to making the fuel cell preheating equipment compact, the supply gas can be sufficiently preheated, and the power generation efficiency can be improved.
[0085]
In the invention according to [claim 9], in the fuel cell according to [claim 8],
Since the first gas is supplied from one end of the base tube and the first gas is discharged from the other end of the base tube, a one-through type fuel cell is provided.
In a one-through type fuel cell having a simple structure, the cell scale and power generation efficiency can be improved.
[0086]
In the invention according to [Claim 10], in the fuel cell according to [Claim 8] or [Claim 9],
Since the first gas is a fuel gas and the second gas is an oxidizing gas,
It can be applied to general fuel cells.
[0087]
In the invention according to [Claim 11], in the fuel cell according to [Claim 8] or [Claim 9],
Since the first gas is an oxidizing gas and the second gas is a fuel gas,
It can be applied to general fuel cells.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a fuel cell to which a heat exchange structure for a fuel cell according to a first embodiment is attached.
FIG. 2 is a schematic configuration diagram of a heat exchange structure according to the first embodiment.
3A and 3B are schematic diagrams of a core according to the first embodiment, in which FIG. 3A is a schematic side view, FIG. 3B is a schematic diagram in the direction of arrow B in FIG. 3A, and FIG. It is CC sectional view taken on the line in FIG.
FIG. 4 is a schematic external view (a) and a side sectional view (b) of the current collecting cap in FIG.
FIG. 5 is a schematic configuration diagram of a heat exchange structure of a fuel cell according to a second embodiment.
6A and 6B are schematic views of a core according to a second embodiment, in which FIG. 6A is a schematic side view, FIG. 6B is a schematic view in the direction of arrow B in FIG. It is CC sectional view taken on the line in FIG.
FIGS. 7A and 7B are schematic views of a core according to a third embodiment, in which FIG. 7A is a schematic side view, FIG. 7B is a schematic view in the direction of arrow B in FIG. It is CC sectional view taken on the line in FIG.
FIG. 8 is a schematic configuration diagram of a one-through type fuel cell which is an example of a conventional fuel cell.
[Explanation of symbols]
1 fuel cell
2 cell tube
3a Supply room
3b discharge chamber
4 Fuel gas
5 Exhaust fuel gas
6 Oxidizing gas
7 Exhausted oxidizing gas
8 Fuel cell
10 Base tube
11 Lead film
12 Protective film
13 core
14 Centering part
15 Core body
16-1 recess
16-2 Gas flow port
17 brim
18 Notch
19 Projection
20 Current collection cap
21 Upper tube sheet
22 Lower tube sheet
23 Upper support
24 Lower support
25 Oxidant supply chamber
26 Heat exchange structure
30 gas hole
31 elastic part
35 conductor

Claims (11)

The first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cell provided on the outer surface of the base tube. When generating electric power by electrochemically reacting the two gases, the first gas passing through the inside of the base tube and the second gas passing outside the base tube exchange heat through the base tube. In the heat exchange structure of the fuel cell performing
A core that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
Centering means for centering the core with respect to the base tube;
And a core supporting means for supporting the core on the base tube. The first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cell provided on the outer surface of the base tube. When generating electric power by electrochemically reacting the two gases, the first gas passing through the inside of the base tube and the second gas passing outside the base tube exchange heat through the base tube. In the heat exchange structure of the fuel cell performing
A core body that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
Centering means provided on the surface of the core body, for centering the core body with respect to the base tube,
A heat exchange structure for a fuel cell, comprising: a core provided at one end of the core body, and a core supporting means for supporting the core body on the base tube. The heat exchange structure for a fuel cell according to claim 2,
The heat exchange structure for a fuel cell, wherein the core is suspended on the base tube by the core supporting means being hooked on an end of the base tube. The heat exchange structure for a fuel cell according to claim 2,
Further, a cap provided at an end of the base tube,
A heat exchange structure for a fuel cell, wherein the core is supported by the base tube by sandwiching the core support means between the cap and an end of the base tube. The first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cell provided on the outer surface of the base tube. When generating electric power by electrochemically reacting the two gases, the first gas passing through the inside of the base tube and the second gas passing outside the base tube exchange heat through the base tube. In the heat exchange structure of the fuel cell performing
A core body that is provided inside the base tube and narrows a flow path of the first gas in the base tube;
A core provided on the surface of the core body, and having a centering means for centering the core body with respect to the base tube;
A cap provided at a lower end of the base tube,
At the lower end of the core body, a flow path changing unit that changes the flow path of the first gas between the outside and the inside of the core is further provided,
A heat exchange structure for a fuel cell, wherein the core is supported by the base tube by being supported by the cap so that the core does not move in the vertical direction. The heat exchange structure for a fuel cell according to any one of claims 1 to 5,
The heat exchange structure for a fuel cell, wherein the core includes a catalyst for reforming the first gas. The heat exchange structure for a fuel cell according to claim 4 or 5,
The cap is
A heat exchange structure for a fuel cell, wherein the heat exchange structure is a current collecting cap which is in close contact with a conductive lead film provided on the base tube and collects power generated by the fuel cell to the outside. The first gas is supplied to the inside of the cylindrical base tube, and the second gas is supplied to the fuel cell provided on the outer surface of the base tube. In a fuel cell that generates electricity by electrochemically reacting two gases,
A fuel cell comprising the heat exchange structure for a fuel cell according to claim 1. The fuel cell according to claim 8,
A fuel cell, wherein the first gas is supplied from one end of the base tube and the first gas is exhausted from the other end of the base tube. 10. The fuel cell according to claim 8, wherein the first gas is a fuel gas, and the second gas is an oxidizing gas. 10. The fuel cell according to claim 8, wherein the first gas is an oxidizing gas, and the second gas is a fuel gas.

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