JP3963762B2 - Oxygen pump - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a laminated structure oxygen pump using a plate-like solid electrolyte.
[0002]
[Prior art]
Various methods for producing oxygen have been put into practical use. Examples of pure oxygen producing methods include a method of extracting air by liquefying air and utilizing a difference in boiling point, a method of extracting water by electrolysis, and the like. . As a method for concentrating oxygen in gas or air, a method using a membrane that selectively transmits oxygen has been put into practical use. In addition, an ion conductive material made of an organic substance or an inorganic oxide is used, an anode electrode and a cathode electrode are formed on both sides thereof, a voltage is applied, and the movement of oxygen ions in the electrolyte in the ion conductive material is utilized. A method for producing concentrated oxygen on one side is known. As an apparatus using such an ion conductive material, there is an apparatus for concentrating or removing oxygen in air or oxygen in various gases by using an oxide-based plate-like solid electrolyte material.
[0003]
Various inventions have been disclosed as oxygen pumps using conventional solid electrolyte cells, but there are few inventions related to the structure, and the following are examples using plate-like solid electrolytes. It has been published.
In the oxygen pump disclosed in JP-T-1-50993, an yttrium-stabilized zirconium ceramic plate is used, and a structure in which a plurality of structures in which a honeycomb structure oxygen electrode and air electrode are formed on one side is laminated. is there. In the opening adjacent to the honeycomb structure, one side is the oxygen electrode side where the oxygen is concentrated, and the other side is the air electrode side where oxygen is reduced. The manufacturing method of the cell-structured element of the honeycomb structure is a green sheet method, and a film body of an anode electrode and a cathode electrode is formed on both surfaces of a planar solid electrolyte green sheet. The honeycomb structure of the oxygen pump is configured by laminating corrugated sheets on the planar solid electrolyte green sheet and further stacking the laminated bodies.
[0004]
Moreover, the oxygen pump disclosed in Japanese Patent Laid-Open No. 6-150945 has a structure in which solid electrolyte plates are stacked with a spacer interposed therebetween. FIG. 28 is a perspective view showing details of the laminated structure of the oxygen pump disclosed in Japanese Patent Laid-Open No. 6-150945. In FIG. 28, different electrodes are formed on both surfaces of each of the solid electrolyte plates 431, 432, 433, and 434, and anode electrode films 435a and 435b are formed on one surface, and cathode electrode films 436a and 436b are formed on the other surface. Has been. In the stacked solid electrolyte plates 431, 432, 433, and 434, the opposing surfaces are alternately arranged so as to be the same electrode. The solid electrolyte plates 431, 432, 433, and 434 are formed by alternately arranging U-shaped spacers 437a and 437b made of the same material as the solid electrolyte plates 431, 432, 433, and 434 and a pair of left and right I-shaped spacers 438a and 438b. Are sequentially stacked. The openings 441a and 441b formed by the U-shaped spacers 437a and 437b and the openings 442a and 442b formed by the pair of I-shaped spacers 438a and 438b arranged in opposition to each other are disposed at positions rotated by 90 ° in the horizontal plane. The space formed by the U-shaped spacers 437a and 437b is a space that is open at only one place, and a voltage is applied to each electrode so as to extract oxygen from the solid electrolyte plates 431, 432, 433, and 434 facing this space. Is done. The space formed by the pair of I-shaped spacers 438a and 438b has openings 442a and 442b on both sides, and is on the air electrode side for supplying air. The U-shaped spacers 437a and 437b and the I-shaped spacers 438a and 438b are welded to the solid electrolyte plates 431, 432, 433, and 434 at a high temperature.
[0005]
The four corners of the solid electrolyte plates 431, 432, 433, and 434 are constituted by corner portions 445 a and 445 b and corner portions 446 a and 446 b cut off. Conductors 447 and 448 connected to the anode electrode and the cathode electrode are formed in the corner portions 445a and 445b, and the same electrodes in the stacked body are electrically connected in the vertical direction. Each of the opening side 441a and 441b of the U-shaped spacers 437a and 437b of these laminates has a structure in which a manifold for taking out oxygen is hermetically sealed.
In addition, the oxygen pump disclosed in Japanese Patent Application Laid-Open No. 10-15068 has a structure in which the electrode area to be energized can be varied in the electrode formed on the surface of the solid electrolyte, and the oxygen concentration can be varied. is there.
[0006]
[Problems to be solved by the invention]
In conventional oxygen pumps, the method of liquefying air and utilizing the difference in boiling point is the best method for producing a large amount of pure oxygen, but the device is large and very expensive. When manufacturing, it was an unsuitable apparatus. In addition, the method using water electrolysis can produce pure oxygen with a simple configuration and low cost. However, this production method has a problem in the treatment of hydrogen generated during electrolysis, and there is a risk of explosion when mixed with air by mistake and there is a big problem in handling and safety. In addition, the method of using a membrane that selectively permeates oxygen is a simple and safe method. However, since it is configured to pressurize and supply air to the apparatus, an air pressurizing pump is provided and noise is supplied. There was a problem that occurred. In particular, oxygen pumps as such oxygen production apparatuses have been avoided in places such as hospitals that dislike noise.
[0007]
Further, the oxygen pump disclosed in Japanese Patent Publication No. 1-502993 uses a plate-like solid electrolyte, but has a honeycomb structure in a flow path for supplying concentrated oxygen gas and air. Therefore, it was difficult to manufacture an inexpensive oxygen pump because the formation of such a honeycomb structure component increased the cost. In addition, since this conventional oxygen pump is configured to supply power to the anode electrode and the cathode electrode in the honeycomb structure having a complicated structure, the construction of the configuration is very difficult.
[0008]
Furthermore, the oxygen pump disclosed in Japanese Patent Application Laid-Open No. 6-150945 has a small structure, but has the following problems. One of them is a configuration in which conductor portions are connected outside the laminate using a conductive paste in order to supply power to each of the anode electrode and the cathode electrode. In this connection method, since the conductor portion is thin, the conductor resistance immediately rises if it is damaged, and there is a risk of disconnection in an extreme case. In order to take out the concentrated oxygen, the oxygen take-out manifold is sealed to the oxygen pump. However, since the sealed portion becomes a high temperature during the pump operation, the sealed portion of the conventional oxygen pump is used. However, there was a concern about gas leakage and had a serious problem in terms of reliability.
[0009]
[Means for Solving the Problems]
    An object of the present invention is to solve the above problems and to provide a small and highly reliable oxygen pump.
  The oxygen pump of the present invention has different electrodesBoth sidesPlate-shaped solid electrolyte electrode plate formed onA sandwiched electrode plate for sandwiching an end of the solid electrolyte electrode plate and supplying power to the electrode;A solid electrolyte cell having:
  Gas separation / distribution plates disposed on both sides of the solid electrolyte electrode plate;
  The gas separation / distribution plate is disposed on one side, and has at least one laminate in which a heater plate serving as a heat source is laminated,
  The laminateThrough the outer periphery of each of the solid electrolyte cell, the gas separation / distribution plate, and the heater plate in the stacking direction.A plurality of gas supply and exhaust passages through which gas flows are formed.AndTwo systems are formed in which the gas supply / discharge passages do not communicate with each other., Different electrodes are arranged in the gas supply / exhaust passage of each system,
  A plurality of apertures penetrating in the stacking direction are formed at positions different from the formation positions of the gas supply / exhaust passages in the outer periphery of each of the solid electrolyte cell, the gas separation / distribution plate, and the heater plate. A plurality of rod-like bodies having electrical conductivity penetrating each of the opening portions, and each rod-like body supplies power to each of the electrodes on both the front and back surfaces of the solid electrolyte cell and the heater portion of the heater plate. Configured to supplying. The oxygen pump of the present invention configured as described above realizes a small and highly efficient oxygen pump because two gas supply / discharge passages that do not communicate with each other are formed in a stacked structure in which solid electrolyte cells are stacked. Therefore, it is superior in airtightness and can be downsized as compared with an oxygen pump retrofitted with a conventional manifold.
[0010]
Further, in the oxygen pump of the present invention, one gas supply / exhaust path of the two systems sends a gas flow to one electrode surface of the solid electrolyte electrode plate, and the other gas supply / exhaust path serves as the solid electrolyte electrode plate. You may comprise so that a gas flow may be sent to the other electrode surface.
Further, the oxygen pump of the present invention provides a gas flow direction on one electrode surface of the solid electrolyte electrode plate and a gas flow on the other electrode surface of the solid electrolyte electrode plate in two systems of gas supply / exhaust passages. The direction may be configured to flow in a perpendicular direction.
In the oxygen pump of the present invention, the heater plate is configured by sandwiching a resistor pattern formed of metal foil from both sides with a heat-resistant insulating member, and the heat-resistant insulating member is the resistance plate. It may be configured to have at least one or more openings exposing a part of the body pattern, and to have two or more openings serving as two systems of gas supply / exhaust passages in the outer peripheral portion of the heat-resistant insulating member. .
Further, in the oxygen pump of the present invention, a gas separation / distribution / heat insulating plate for keeping a temperature of the laminated body by diverting a gas to the outermost sides on both sides in the laminating direction of the laminated body or a laminated structure in which the laminated bodies are laminated. The metal plate having the gas supply / exhaust port may be laminated.
Moreover, in the oxygen pump of the present invention, in the laminated structure having a plurality of solid electrolyte cells, the electrodes of the solid electrolyte electrode plates arranged opposite to each other may be the same pole.
[0011]
  In the oxygen pump of the present invention,The sandwich electrode plate is in contact with an electrode formed on one surface of the solid electrolyte electrode plate by sandwiching one end of the solid electrolyte electrode plate and pressing with an elastic force. An electrode plate;
A second sandwiched electrode plate that sandwiches the other end of the solid electrolyte electrode plate and is in pressure contact with an elastic force to electrically contact an electrode formed on the other surface of the solid electrolyte electrode plate; The first sandwiched electrode plate and the second sandwiched electrode plate may be configured to supply power to different electrodes.. The oxygen pump configured as described above is configured to supply power to the electrode film by sandwiching the solid electrolyte electrode plate from both sides by the sandwiched electrode plate, and thus supplies power to each electrode in substantially the same plane. When the solid electrolyte cells are stacked, the clamping force does not work on the solid electrolyte electrode plate, so a material with low bending strength can be selected as the solid electrolyte electrode plate, resulting in an oxygen pump that is resistant to vibration and impact. .
[0012]
  In the oxygen pump of the present invention,SaidThe solid electrolyte electrode plate has a rectangular shape;The solid electrolyte electrode plateFront and backForm on both sidesThe different electrodes made of a film body, one electrode film being one end of the solid electrolyte electrode plateAnd is configured to be in electrical contact with the first sandwiched electrode plate.The other electrode membrane is the other end of the solid electrolyte electrode plateAnd may be configured to be in electrical contact with the second sandwiched electrode plate..
[0013]
  In the oxygen pump of the present invention,Each of the first sandwiched electrode plate and the second sandwiched electrode plateIs composed of at least two thin metal plates sandwiching both front and back surfaces of the end portion of the solid electrolyte electrode plate,
  Two sets of sandwiching at least two ends of the solid electrolyte electrode plateThe first sandwiched electrode plate and the second sandwiched electrode plateIn
  One set ofThe firstSurface of sandwich electrode plate~ sideThe thin metal plate is the surface of the solid electrolyte electrode plate~ sideThe electrode film is pressed andThe firstBack side of sandwich electrode plate~ sideThe metal thin plate is the back surface of the solid electrolyte electrode plate~ sideIs configured to press-contact the solid electrolyte electrode plate without contacting the electrode film,
  The other pairThe secondSurface of sandwich electrode plate~ sideThe thin metal plate is the surface of the solid electrolyte electrode plate~ sideThe solid electrolyte electrode plate without being in contact with the electrode film of the other set,The secondBack side of sandwich electrode plate~ sideThe metal thin plate is the back surface of the solid electrolyte electrode plate~ sideThe electrode film may be configured to be pressed.
[0014]
  Moreover, in the oxygen pump of the present invention, the solid electrolyte electrode plate includes a plurality of solid electrolyte substrates in which different electrodes are formed on both front and back surfaces, and
  A heat-resistant insulating substrate disposed such that the solid electrolyte substrate exposes the front and back electrodes; and
  A conductive pattern that is formed on each of the front and back surfaces of the heat-resistant insulating substrate and electrically connects the electrodes on the front and back surfaces of the solid electrolyte substrate; and
  The conductive pattern may be press-contacted by the sandwiched electrode plate to supply power to the electrodes on both the front and back surfaces of the solid electrolyte substrate..
[0015]
  In the oxygen pump of the present invention,The heat-resistant insulating substrate on which the conductive pattern is formed has a plurality of openings, the solid electrolyte substrate is disposed so as to close the plurality of openings and expose electrodes on both the front and back sides, and the front and back sides of the solid electrolyte substrate The electrodes on both sides and the conductive patternYou may connect so that the same surface may become the same electrode. In the oxygen pump of the present invention,The sandwiched electrode plate is in contact with the conductive pattern formed on one surface of the solid electrolyte electrode plate by sandwiching one end of the solid electrolyte electrode plate and pressing with an elastic force. A sandwich electrode plate;
A second sandwiched electrode plate sandwiching the other end of the solid electrolyte electrode plate and being in pressure contact with an elastic force to be in electrical contact with a conductive pattern formed on the other surface of the solid electrolyte electrode plate; The first sandwiching electrode plate and the second sandwiching electrode plate may supply power to the different electrodes.. In the oxygen pump of the present invention,One of the conductive patterns formed on the front and back surfaces of the solid electrolyte electrode plate is extended to one end of the solid electrolyte electrode plate and is in electrical contact with the first sandwich electrode plate The other is extended to the other end of the solid electrolyte electrode plate so as to be in electrical contact with the second sandwiched electrode plate.. In the oxygen pump of the present invention,Each of the first sandwiched electrode plate and the second sandwiched electrode plateIs composed of at least two thin metal plates sandwiching both front and back surfaces of the end portion of the solid electrolyte electrode plate,
  Two sets of sandwiching at least two ends of the solid electrolyte electrode plateThe first sandwiched electrode plate and the second sandwiched electrode plateIn
  One set ofThe firstThe thin metal plate on the surface side of the sandwiched electrode plate presses the conductor pattern on the surface side of the solid electrolyte electrode plate,The firstThe thin metal plate on the back side of the sandwich electrode plate is configured to press-contact the solid electrolyte electrode plate without contacting the conductive pattern on the back side of the solid electrolyte electrode plate,
  The other pairThe secondThe metal thin plate on the surface side of the sandwiched electrode plate is pressed against the solid electrolyte electrode plate without contacting the conductive pattern on the surface side of the solid electrolyte electrode plate, and the other setThe secondThe thin metal plate on the back side of the sandwich electrode plate may be configured to press-contact the conductive pattern on the back side of the solid electrolyte electrode plate.
[0016]
  In the oxygen pump of the present invention, the sandwiched electrode plate has a thermal expansion coefficient of 4 × 10.^-6~ 20x10^-6You may form with the metal material which exists in the range. In the oxygen pump of the present invention, the sandwich electrode plate may be composed of an iron alloy plate, a nickel alloy plate, a cobalt alloy plate, a nickel-cobalt alloy, or a stainless steel plate. In the oxygen pump of the present invention, a film of gold, silver, nickel, or aluminum may be formed on one surface or both surfaces of the sandwich electrode plate. In the oxygen pump of the present invention,In a laminated structure in which a plurality of the laminated bodies are laminated, the gas supply / discharge passage of one system passes through,Of solid electrolyte electrode plateon the other handGas flow in contact with the electrode membrane ofThrough the gas supply / discharge passage of the other system,The gas flow in contact with the other electrode membrane isFlow in parallel to the stacked electrode filmsIt may be configured. In the oxygen pump of the present invention,In a laminated structure in which a plurality of the laminated bodies are laminated, the gas supply / discharge passage of one system passes through,Of solid electrolyte electrode plateon the other handGas flow in contact with the electrode membrane ofThrough the gas supply / discharge passage of the other system,The gas flow in contact with the other electrode membrane isSequentially contact and flow in series with the stacked electrode filmsIt may be configured. In the oxygen pump of the present invention,In the laminated structure in which a plurality of the laminated bodies are laminated, the gas supply / discharge passage of one system passes through,Of solid electrolyte electrode plateon the other handGas flow in contact with the electrode membraneIs configured to flow in parallel with the stacked electrode films, and passes through the gas supply / discharge passage of the other system, and the solid electrolyte electrode plateGas flow in contact with the other electrode membraneAre in contact with the stacked electrode films and flow in series.It may be configured.
[0017]
  In the oxygen pump of the present invention,In a laminated structure in which a plurality of the laminated bodies are laminated,Of solid electrolyte electrode plateon the other handElectrode film orThe otherThe configuration is such that the direction of the gas flow in contact with the electrode film is switched so that each electrode film flows in parallel or in series.May. In the oxygen pump of the present invention,Of the laminated structureBy inserting a gas flow changing block into the opening serving as the supply / exhaust port of the gas supply / discharge path formed in the stacking direction, the gas flow can be changed to flow in parallel or in series with the stacked electrode films.May be configured as. In the oxygen pump of the present invention,SaidGas separation / distribution plate,SaidGas separation / distribution / heat insulation plate,as well asSaidThe thermal expansion coefficient of the heater plate material is 5 × 10^-6~ 15 × 10^-6You may comprise with the heat resistant and insulating material which exists in the range. In the oxygen pump of the present invention,SaidGas separation / distribution plate,SaidGas separation / distribution / heat insulation plate, andSaidThe heater plate may be formed of mica, a ceramic material, or a glass material. In the oxygen pump of the present invention,SaidIn the heater plate, the heater portion is formed by sandwiching a pattern formed of a thin plate-like iron alloy or nickel alloy between mica plates, the heater portion has a plurality of openings, and a portion outside the heater portion. A plurality of gas supply / discharge paths are formed independently of each other, and the outer periphery other than the gas supply / discharge pathsportionThe heater power may be supplied from the heater.
[0018]
  In the oxygen pump of the present invention,SaidThe rod-like body penetrating the laminated body or a laminated structure in which a plurality of the laminated bodies are stacked is made of screws having screws, and the material is formed of an iron alloy, a nickel alloy, a cobalt alloy, or stainless steel. Electrically connected to the electrode of the solid electrolyte cellSaidSandwiched electrode plate andSaidYou may comprise so that the terminal part of the heater part of a heater plate may be clamp | tightened by a fastening means, respectively. In the oxygen pump of the present invention,SaidThe metal plate disposed in the outermost layer of the laminated structure is formed of a rigid material made of an iron alloy plate, a nickel alloy plate, a cobalt alloy plate, a nickel-cobalt alloy, or a stainless steel plate. A gas supply port and a gas discharge port communicating with the gas supply / discharge path may be formed, and the metal plate may be fastened and fixed by the rod-shaped body. In the oxygen pump of the present invention,SaidThe solid electrolyte electrode plate is made of barium / cerium / gadolinium-based oxide ceramic material, barium / cerium / gadolinium / zirconium-based oxide material, or barium / cerium / gadolinium / aluminum-based oxide whose crystal structure is perovskite type. Also good. Furthermore, in the oxygen pump of the present invention,SaidConsists of at least one dense or porous heat-resistant material on one or both sides of the solid electrolyte electrode plateIt is good also as a structure which attached the spacer or reinforcing plate which was made.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of the oxygen pump of the present invention will be described with reference to the accompanying drawings.
[0020]
Example 1
FIG. 1 is a perspective view showing a configuration of an oxygen pump module which is a basic part of the oxygen pump according to the first embodiment of the present invention. The oxygen pump module in Example 1 has a laminated structure using a plate-like solid electrolyte. In the following description, a solid electrolyte electrode plate in which electrode films are formed on both front and back surfaces of the solid electrolyte plate is referred to as a solid electrolyte electrode plate. 2 is a perspective view of the solid electrolyte electrode plate in Example 1. FIG. FIG. 3 shows another configuration of the solid electrolyte electrode plate in Example 1, and is an exploded perspective view showing a configuration in which a circular solid electrolyte electrode plate is attached to an insulating substrate. FIG. 4 is a completed perspective view showing a state where the circular solid electrolyte electrode plate of FIG. 3 is attached to an insulating substrate. FIG. 5 is an exploded perspective view showing a part of the attachment structure of the sandwich electrode plate to the solid electrolyte electrode plate. FIG. 6 is a completed perspective view of FIG. 7 is a sectional view taken along line VII-VII in FIG. FIG. 8 is an exploded perspective view showing a solid electrolyte cell structure having another configuration according to the first embodiment. FIG. 9 is a perspective view showing a solid electrolyte cell structure of still another configuration in the first embodiment. FIG. 10 is a perspective view showing a gas separation / distribution plate in the first embodiment. FIG. 11 is an exploded perspective view showing the heater plate in the first embodiment. FIG. 12 is a cross-sectional view taken along line XII-XII in the main part of the oxygen pump module of Example 1 of FIG. 1 and shows the gas flow in the laminated structure. FIG. 13 is a perspective view illustrating an assembled state of the laminated structure of the oxygen pump module according to the first embodiment. FIG. 14 is a perspective view showing a completed state of the oxygen pump module. In all the drawings, the same reference numerals are given to components having the same function and configuration.
[0021]
Hereinafter, the configuration of the oxygen pump module according to the first embodiment of the present invention will be described with reference to the drawings.
First, FIG. 1 will be described. FIG. 1 is an exploded perspective view illustrating a part of a main part of the oxygen pump module according to the first embodiment. In the exploded perspective view of FIG. 1, the two solid electrolyte cells 10 and 11 that are the upper part of the laminated structure of the oxygen pump are shown exploded from the laminated structure. In the following description, one is called the upper solid electrolyte cell 10 and the other is called the lower solid electrolyte cell 11. In the upper solid electrolyte cell 10, the upper surface is a cathode electrode (−electrode) and the lower surface is an anode electrode (+ electrode). In the lower solid electrolyte cell 11, the upper surface is an anode electrode (+ electrode) and the lower surface is a cathode electrode (−electrode).
A solid electrolyte substrate 22 having a rectangular shape is provided in the upper solid electrolyte cell 10, and a cathode electrode film 20 is formed on the upper surface, and an anode electrode film (not shown) is formed on the lower surface. The lower solid electrolyte cell 11 is provided with a solid electrolyte substrate 19 having a rectangular shape. An anode electrode film 21 is formed on the upper surface, and a cathode electrode film (not shown) is formed on the lower surface. As described above, in the laminated structure of the oxygen pump module, the electrode films having opposite electrodes are formed on the front and back surfaces of the solid electrolyte substrates 19 and 22.
[0022]
Two sets of sandwiched electrode plates 23 and 24 are provided on the outer edge portion of the solid electrolyte substrate 22 of the upper solid electrolyte cell 10. One sandwiched electrode plate 23 is composed of two thin metal plates so as to sandwich two sides of the outer edge portion of the solid electrolyte substrate 22. The other sandwiched electrode plate 24 is composed of two thin metal plates so as to sandwich the other two sides of the outer edge portion of the solid electrolyte substrate 22.
The sandwiched electrode plate 23 is fixed to the solid electrolyte substrate 22 by spot welding the upper and lower sandwiched electrode plates 23 at several places so as to contact a part of the cathode electrode film 20 formed on the surface of the solid electrolyte substrate 22. It is a thing. In this way, when the two side portions of the solid electrolyte substrate 22 are sandwiched and fixed by the sandwiched electrode plate 23 which is the upper and lower two metal plates, the end of one sandwiched electrode plate is in contact with the cathode electrode film 20. However, the other sandwiched electrode plate is sandwiched and fixed without being in contact with the anode electrode film (the electrode formed on the lower surface of the solid electrolyte substrate 22).
On the other hand, the sandwiched electrode plate 24 is formed by spot welding the sandwiched electrode plates 24, which are two upper and lower metal plates, in contact with a part of the anode electrode film formed on the back surface of the solid electrolyte substrate 22 at several locations. It is fixed to the electrolyte substrate 22. Thus, when the two sides of the solid electrolyte substrate 22 are sandwiched and fixed by the two upper and lower sandwiched electrode plates 24, the end of one sandwiched electrode plate is formed on the anode electrode film (the lower surface of the solid electrolyte substrate 22). The other sandwiched electrode plate is sandwiched and fixed in a state where it is not in contact with the cathode electrode film 20. Details of the sandwiching structure formed by these sandwiching electrode plates 23 and 24 will be described later with reference to FIGS.
[0023]
At the four corners of the upper solid electrolyte cell 10 constituted by the solid electrolyte substrate 22, the electrode films provided on both surfaces of the solid electrolyte substrate 22, and the sandwiched electrode plates 23, 24, openings 25 a, 25 b are provided. And 26a and 26b are formed at positions facing each other. The diameters of the apertures 25a and 25b on one diagonal are small, and the apertures 26a and 26b on the other diagonal are large. As shown in FIG. 1, the sandwiched electrode plates 23 and 24 forming the large apertures 26a and 26b have a structure separated on the center line of the apertures 26a and 26b (on the diagonal line of the solid electrolyte cell 10). is doing. Therefore, in the sandwiched electrode plates 23 and 24, the sandwiched electrode plate 23 in contact with the cathode electrode film 20 and the sandwiched electrode plate 24 in contact with the anode electrode film are assembled with a gap. And are electrically insulated from each other.
[0024]
The sandwiched electrode plates 23 and 24 are formed with gas passage openings serving as gas supply / discharge passages. The sandwiched electrode plate 23 is formed with a gas path opening 31a (in side) through which air enriched with oxygen flows and a gas path opening 30b (in side) through which air with reduced oxygen flows. The sandwiched electrode plate 24 is formed with a gas path opening 30a (out side) through which air with reduced oxygen flows and a gas path opening 31b (out side) through which air enriched with oxygen flows. Therefore, gas path openings 31a and 31b through which air to which oxygen is concentrated flow are formed in the vicinity of the outer peripheral portion of the solid electrolyte cell 10 on the upper side of the quadrangle, that is, in the vicinity of one opposing side, and the other is opposed to the other. In the vicinity of the sides, gas path openings 30a and 30b through which air in which oxygen is reduced flow are formed.
Gas separation / distribution plates 14, 15 are arranged and stacked above and below the solid electrolyte cell 10. In the gas separation / distribution plate 14, open gas passage portions 35 a and 35 b are formed at positions corresponding to the gas passage openings 30 a and 30 b of the solid electrolyte cell 10 where the air in which oxygen is reduced flows. These open gas passage portions 35a and 35b are included in a large opening formed in the central portion and are in communication. Therefore, the open gas passage portions 35a and 35b through which the air in which oxygen is reduced flow are substantially connected to the upper space of the cathode electrode film 20 formed on the upper surface of the solid electrolyte cell 10, and the air in which oxygen is reduced is gas. The separator / distribution plate 14 is configured to flow through a large opening formed in the central portion thereof.
In the gas separation / distribution plate 14, the gas passage opening through which the oxygen-concentrated air flows is rotated 90 ° in the horizontal plane with respect to the arrangement position of the open gas passage portions 35 a and 35 b through which the air in which oxygen decreases decreases. The parts 36a and 36b are formed to face each other. These gas path openings 36a and 36b are formed at positions corresponding to the gas path openings 31a (in side) and 31b (out side) of the solid electrolyte cell 10 through which air enriched with oxygen flows. Therefore, the gas path openings 36a and 36b through which the air enriched with oxygen flows are isolated from the upper space of the cathode electrode film 20 formed on the upper surface of the solid electrolyte cell 10, and each is formed by an independent through hole. It is configured.
[0025]
As shown in FIG. 1, a gas separation / distribution plate 15, a heater plate 17, and a gas separation / distribution plate 16 are disposed between the upper solid electrolyte cell 10 and the lower solid electrolyte cell 11. Has been. The gas separation / distribution plate 15, the heater plate 17, and the gas separation / distribution plate 16 have gas passage openings at positions corresponding to the gas passage openings 30 a (out side) and 30 b (in side) of the solid electrolyte cell 10. Through holes are formed as 47a and 47b so that air in which oxygen is reduced flows. Therefore, the open gas path portions 35 a and 35 b of the gas separation / distribution plate 14 communicating with the upper space of the cathode electrode film 20 of the solid electrolyte cell 10 are the gas separation / distribution plates 15, disposed below the solid electrolyte cell 10. The heater plate 17 and the gas separation / distribution plate 16 communicate with each through-hole formed independently in the vicinity of the outer peripheral portion. That is, the air in which oxygen is reduced is the gas path openings 42a and 42b of the gas separation / distribution plate 15, the gas path openings 45a and 45b of the heater plate 17, and the gas path opening 47a of the gas separation / distribution plate 16. , 47b. These through holes communicate with gas path openings 48a (out side) and 48b (in side) of the lower solid electrolyte cell 11.
[0026]
A gas separation / distribution plate 2 is disposed below the lower solid electrolyte cell 11, and open gas passage portions 40 a and 40 b in the gas separation / distribution plate 2 are formed on the lower surface of the solid electrolyte cell 11. It communicates with the space under the cathode electrode film (not shown). Therefore, the air that has passed through the gas passage openings 48 a and 48 b of the lower solid electrolyte cell 11 passes through the open gas passage portions 40 a and 40 b of the gas separation / distribution plate 2 and is formed on the lower surface of the solid electrolyte cell 11. It flows into the surface space of the cathode electrode film.
[0027]
In the gas separation / distribution plate 14 disposed on the upper side of the upper solid electrolyte cell 10, the gas path openings 36a and 36b through which air to which oxygen is concentrated flow are the above-described open gas path sections 35a through which air in which oxygen is reduced flows. , 35b. The gas passage openings 36a and 36b communicate with the open gas passage portions 41a and 41b of the gas separation / distribution plate 15 disposed at the lower part of the solid electrolyte cell 10, and the solid passages are provided via the open gas passage portions 41a and 41b. It communicates with a space in contact with the anode electrode film surface on the lower surface of the electrolyte cell 10. Further, the gas passage openings 36a and 36b communicate with the open gas passage portions 50a and 50b of the gas separation / distribution plate 16, and the upper surface of the lower solid electrolyte cell 11 is connected via the open gas passage portions 50a and 50b. It communicates with the space in contact with the anode electrode film surface.
[0028]
As described above, the structural difference between the gas separation / distribution plate 14 and the gas separation / distribution plate 15 disposed above and below the solid electrolyte cell 10 is that the gas separation / distribution plate 14 is independent of the central opening. The arrangement position of the passage openings 36a and 36b and the arrangement position of the gas passage openings 42a and 42b independent from the opening of the central portion of the gas separation / distribution plate 15 are rotated by 90 ° on the horizontal plane. . This positional relationship is common to the gas separation / distribution plates arranged above and below all the solid electrolyte cells. In FIG. 1, the laminated body block 18 disposed below the lower solid electrolyte cell 11 is configured in the same manner as described above, and the description thereof is omitted. In the laminated body block 18 shown in FIG. 1, two gas separation / distribution plates 2, 3, a solid electrolyte cell 12, a gas separation / distribution plate 32, and a heater are disposed below the lower solid electrolyte cell 11. The plate 33, the gas separation / distribution plate 34, the solid electrolyte cell 13, and the gas separation / distribution plate 4 are arranged in order.
[0029]
As described above, in a structure in which a plurality of solid electrolyte cells are stacked, the opposing surfaces of the solid electrolyte cells arranged to face each other are stacked with the same pole. By adopting such a configuration, in the gas supply / discharge passage formed in the vicinity of the four sides of the substantially rectangular solid electrolyte cell, the in- and out-side flow paths of the air to which oxygen is concentrated, and the oxygen 2 systems of gas supply / exhaust passages can be formed.
In addition, by configuring as described above, it becomes possible to connect anode electrode films and cathode electrode films of a plurality of solid electrolyte cells with two metal conductors in a power supply method described later, and a compact oxygen pump Modules can be realized.
[0030]
In the oxygen pump of Example 1 according to the present invention, a heater plate is provided in the laminate. In the oxygen pump module of the first embodiment shown in FIG. 1, the heater plate indicated by reference numeral 17 is provided between the gas separation / distribution plates 15 and 16.
The heater plate 17 has a plurality of openings 43 formed at the center thereof, and a plurality of heater portions 44 made of metal resistance foil are disposed in the openings 43. Four independent gas path openings 45a, 45b, 46a, 46b are formed in the vicinity of the outer periphery of the four pieces of the heater plate 17, respectively. These gas passage openings 45a, 45b, 46a, 46b are located at positions on the vertical lines corresponding to the gas passage openings of the solid electrolyte cell, the gas passage openings of the gas separation / distribution plate, and the open gas passages in the laminate. It is formed, and it is formed so that the gas supply / discharge path on the vertical line communicates.
[0031]
Furthermore, openings 51a, 51b, 52a, 52b are formed at the four corners of the heater plate 17, and the two openings 51a, 51b on one diagonal line are connected to the heat pattern of the heater section 44 as a heat source. The exposed terminals are exposed. An external power supply is connected to these terminal portions to supply power. The other two openings 52a and 52b on the diagonal line are configured so that a power supply line to the cathode electrode film and the anode electrode film formed on the solid electrolyte cell 10 passes therethrough. Therefore, the arrangement positions of the openings 51a and 51b of the heater plate 17 are rotated 90 degrees in the horizontal plane with respect to the arrangement positions of the openings 25a and 25b of the solid electrolyte cell 10 to which the power supply line is connected. That is, in the substantially square heater plate 17, the openings 52a and 52b are formed at the corners on the other diagonal line with respect to the openings 51a and 51b formed at the corner on one diagonal line. A metal rod for supplying power to the cathode electrode film and the anode electrode film of the solid electrolyte cell 10 passes through these openings 52a and 52b. The openings 26a, 26b and 53a, 53b formed in the corners of the upper solid electrolyte cell 10 and the lower solid electrolyte cell 11 are conductors for supplying electric power to the heater portion 44 of the heater plate 17. A certain metal rod is inserted, and in order to electrically insulate the metal rod from contact with the solid electrolyte cell 10 and the solid electrolyte cell 11, the respective openings 26a, 26b and 53a, 53b are Largely formed.
[0032]
Next, the power supply structure to the cathode electrode film and anode electrode film of the solid electrolyte cell (including the solid electrolyte cells 12 and 13 in the laminate block 18) and the heater portion 44 of the heater plate 17 in Example 1 will be described. To do.
The solid electrolyte cells 10, 11, 12, 13 of the oxygen pump module shown in FIG. 1 and all the solid electrolyte cells in the oxygen pump of Example 1 are sandwiched between sandwiched electrode plates composed of two upper and lower metal plates. It is. In these sandwiched electrode plates, small openings are formed in portions corresponding to the two corners on the diagonal line of each solid electrolyte cell. The small opening in the vertical direction in each solid electrolyte cell stacked in the vertical direction has its center formed in a straight line.
In FIG. 1, since the cathode electrode film 20 is formed on the upper surface of the solid electrolyte cell 10, the metal rod inserted into and connected to the opening 25a of the solid electrolyte cell 10 is a cathode electrode. The metal rod inserted and connected to 25b is an anode pole. Therefore, in Example 1, the power supply to the cathode electrode film is performed as follows.
[0033]
In FIG. 1, the metal rod that is screwed and connected to the external power source (−pole) is a large opening 55 a in the gas separation / distribution plate 14 → a small opening 25 a in the solid electrolyte cell 10 → a gas separation / distribution plate 15. → large opening 52a in the heater plate 17 → large opening in the gas separation / distribution plate 16 (not shown) → small opening 56a in the solid electrolyte cell 11 → gas separation / distribution plate 2 (lamination) The body block 18) is inserted in the order of openings (not shown) → (each hole in the laminated body block 18). This metal rod is fastened and fixed by a nut as a fastening means at the opening 25a of the solid electrolyte cell 10 and the opening 56a of the solid electrolyte cell 11. In addition, nuts for fixing the metal rods are accommodated in the large openings of the gas separation / distribution plates 14 and 16.
[0034]
Similarly, power supply to the anode electrode film is performed as follows. The metal rod that is screwed and connected to the external power source (+ pole) is a large opening 55b in the gas separation / distribution plate 14 → a small opening 25b in the solid electrolyte cell 10 → an opening 54b in the gas separation / distribution plate 15 → Large opening 52b in the heater plate 17 → large opening 57b in the gas separation / distribution plate 16 → small opening 56b in the solid electrolyte cell 11 → opening 58b in the gas separation / distribution plate 2 (laminate block 18) → (lamination) Each hole in the body block 18) is inserted in this order. This metal rod is fastened and fixed with a nut at the opening 25 b of the solid electrolyte cell 10 and the opening 56 b of the solid electrolyte cell 11. Note that nuts for fixing the metal rods are accommodated in the large openings of the gas separation / distribution plates 14 and 16.
Each metal bar provided as described above is inserted so as to protrude to both upper and lower ends of the laminated body, and a nut is attached to the metal bar led out under the laminated body and is fastened and fixed. Moreover, each external lead wire is attached to the upper part of each metal bar, and electric power is supplied.
[0035]
The power supply to the heater plate 17 in the oxygen pump module in Example 1 has the same structure as the power supply to the electrode film of the solid electrolyte cell described above.
Electric power is supplied by passing a metal rod threaded through the heater terminals formed in the openings 51a and 51b of the heater plate 17 through the openings of the laminate. That is, power supply metal bars are respectively inserted into the openings 71 a and 71 b of the gas separation / distribution plate 14, and are fastened by nuts at the bottom of the laminated body block 18. In addition, the metal rod is also tightened by the nut in the heater terminals of the openings 51a and 51b of the heater plate 17, and the metal rod and the heater terminal are electrically connected. An external lead wire is attached to the upper part of the metal bar to supply power.
[0036]
Since the oxygen pump module of Example 1 has the above-described power supply structure, openings that communicate with the inside of the laminate are formed at the four corners of the laminate having a rectangular shape. By inserting a metal rod into the electrode, power can be easily supplied to each electrode of the solid electrolyte cell and each electrode of the heater plate. The power supply connection structure according to the first embodiment is a system in which a metal rod and a metal terminal are physically tightened and fixed. Therefore, by using the power supply method in Example 1, there is a concern of vibration and impact or breakage due to a difference in thermal expansion between materials used compared to a conventional method of connecting using a conductive paste or the like. No reliable power supply connection can be provided.
[0037]
Next, the air flow in the laminated body of the oxygen pump module of Example 1 will be described.
As shown in FIG. 1, the gas is inserted in the direction of the arrow 72b (upward direction in FIG. 1) with respect to the stack of oxygen pump modules. The gas passes through the gas path opening 30b of the solid electrolyte cell 10 and is diverted onto the cathode surface of the cathode electrode film 20, and enters the gas path opening 30a formed at the opposite position, and the direction of the arrow 72a (see FIG. 1 downward) and discharged. The gas flow indicated by the arrows 72b and 72a is a gas flow in which oxygen decreases, and is a gas flow with less oxygen.
On the other hand, with respect to the anode electrode film (not shown) of the solid electrolyte cell 10, a gas is inserted in the direction of the arrow 73 a (downward in FIG. 1) with respect to the stacked body of the oxygen pump module. The gas passage opening 31a passes through the gas passage opening 31a, is divided on the surface of the anode electrode film, enters the gas passage opening 31b formed at the opposite position, flows in the direction of the arrow 73b (upward in FIG. 1), and is discharged. Is done. The gas flow indicated by the arrows 73a and 73b is a gas flow in which oxygen is concentrated, and is a gas flow rich in oxygen.
[0038]
In addition, in Example 1, although demonstrated in the example which comprised the exit of the gas in which oxygen decreased and the exit of the gas in which oxygen was concentrated in the opposite direction, the present invention is limited to such a configuration. Instead, it is possible to provide each outlet in the same direction. Moreover, in Example 1, although the example which made the opening part used as a gas supply / exhaust path one opening was demonstrated, even if it comprises as several opening, the function does not change at all.
[0039]
Next, the detailed structure of the solid electrolyte cell in Example 1 is demonstrated using FIGS. FIG. 2 is a perspective view of a substantially square solid electrolyte electrode plate 91 in the solid electrolyte cell 10. The solid electrolyte electrode plate 91 is formed on the solid electrolyte substrate 22 and one surface (surface) of the solid electrolyte substrate 22. The substantially square cathode electrode film 20 and the substantially square anode electrode film 92 formed on the other surface. As shown in FIG. 2, the cathode electrode film 20 has two adjacent sides (two sides on the back side in FIG. 2) formed from the vicinity of the end of the solid electrolyte substrate 22, and the two opposite sides (see FIG. 2). 2 on the front side in FIG. 2 is formed with a wide interval from the end of the solid electrolyte substrate 22.
Further, in the solid electrolyte cell 10, the anode electrode film 92 formed on the other surface (back surface) is formed from the vicinity of the end portion of the solid electrolyte substrate 22 on the near side opposite to the cathode electrode film 20 described above. The two sides on the back side are formed with a wide interval from the end of the solid electrolyte substrate 22. That is, the cathode electrode film 20 and the anode electrode film 92 formed on both surfaces of the solid electrolyte substrate 22 are disposed so as to have an inverted positional relationship.
[0040]
The material of the solid electrolyte substrate 22 used in Example 1 and the manufacturing method thereof are as follows. (1) The material of the solid electrolyte is BaCe_0.35Zr_0.5Gd_0.15O_3-αEach material is weighed so as to become, and an organic solvent is added and mixed for 24 hours by a ball mill.
(2) After mixing in (1), it is dried and calcined in an air atmosphere at 1300 ° C. after molding.
(3) After calcination of (2), add organic solvent, plasticizer and dispersant, grind and mix for 48 hours in a ball mill, and then form a sheet on a silicone-treated PET film by the doctor blade method and dry To do.
(4) After drying in (3), a plurality of the sheets are stacked and heated while being pressed, integrated, and then cut into a required size.
(5) After cutting in (4), place on a porous setter, remove the binder in an air atmosphere in an electric furnace at 500 ° C., and finally calcinate at 1650 ° C. in an air atmosphere in an electric furnace for 10 hours to obtain a thin perovskite Type barium-cerium-gadolinium-zirconium-based oxide solid electrolyte substrate was prepared.
[0041]
On both sides of the solid electrolyte substrate (70 × 70 × 0.5 mmt) manufactured as described above, gold paste, for example, gold paste TR-1301 manufactured by Tanaka Kikinzoku Co., Ltd. on both sides at the position shown in FIG. It was formed by a screen printing method and baked at 850 ° C. for 10 minutes in an air atmosphere to obtain an anode electrode film or a cathode electrode film. The electrode material is not limited to the above gold paste, and platinum paste or the like can be used. Further, if the gold paste is not made of fine gold powder but is made into a paste form using an organic gold compound, a thin conductive film can be formed and the material cost can be reduced.
[0042]
Next, a solid electrolyte electrode plate having another configuration will be described with reference to FIGS. In the solid electrolyte electrode plate shown in FIG. 2 described above, a solid electrolyte cell is configured by using a rectangular solid electrolyte substrate as it is, but the solid electrolyte electrode plate described in FIGS. 3 and 4 is a small size solid electrolyte substrate. This is an example in which a solid electrolyte electrode plate is configured by using.
In FIG. 3, a plurality of solid electrolyte electrode plates are manufactured by forming cathode electrode films 93a to 93e on the surfaces of circular solid electrolyte substrates 92a to 92e and an anode electrode film (not shown) on the other surface by screen printing. To do. The material used as the electrode of this solid electrolyte electrode plate is a gold paste TR-1301 from Tanaka Kikinzoku Metal Sales Co., Ltd. The gold paste was printed by a screen printing method, dried, and fired at 850 ° C.
[0043]
Openings 95a to 95e having a diameter slightly smaller than the outer diameter size of the solid electrolyte substrates 92a to 92e are formed in the insulating ceramic substrate 94. A paste containing silver-palladium powder, for example, Ag / Pd paste TR-4848 from Tanaka Kikinzoku Co., Ltd. was printed on both surfaces of the ceramic substrate 94 and fired to form a conductor pattern 97. Further, around the openings 95a to 95e of the ceramic substrate 94, the thermal expansion coefficient is 5 to 15 × 10.^-6Paste containing a glass material in the range of, for example, glass paste PLS-3179 (thermal expansion coefficient; 10 × 10 10) of Nippon Electric Glass Co., Ltd.^-6) Was formed by a screen printing method. A disc-shaped solid electrolyte electrode plate on which a cathode electrode film and an anode electrode film are formed is brought into close contact with the openings 95a to 95e, and is fired in this state, so that the solid electrolyte substrates 92a to 92e are made of glass 96a to 96e. To the ceramic substrate 94.
In the oxygen pump of the present invention, as an insulating substrate that can be used, the thermal expansion coefficient of the solid electrolyte material used in the present invention is 10 to 12 × 10 6.^-6Therefore, materials having a thermal expansion coefficient before and after that can be used. Specifically, the thermal expansion coefficient is 5 to 15 × 10.^-6In this range, a dense material having insulating properties can be used. As such a condition, there are various ceramic materials, for example, 94 to 96% alumina, steatite, forsterite, and glass (including crystallized glass) materials.
[0044]
FIG. 4 is a perspective view showing a completed state of the solid electrolyte electrode plate 91A shown in FIG. As shown in FIG. 4, in order to connect the cathode electrode films of the solid electrolyte substrates 92a to 9e to the conductor pattern 97, for example, a paste 98 containing silver-palladium powder in the connecting portion (the aforementioned Ag / Pd paste TR-4848). And the same were applied and fired for connection. The anode electrode films on the back surfaces of the solid electrolyte substrates 92a to 9e were similarly connected. In this way, a solid electrolyte electrode plate 91A having a plurality of solid electrolyte substrates 92a to 92e was formed.
As shown in FIG. 4, the rectangular conductor pattern 97 in the ceramic substrate 94 has two adjacent sides (the back side in FIG. 4) formed from the vicinity of the end of the ceramic substrate 94. The other two opposite sides (front side in FIG. 4) of the pattern 97 are formed with a large gap from the end of the ceramic substrate 94.
[0045]
Similarly to the positional relationship between the cathode electrode film 20 and the anode electrode film 92 in the solid electrolyte substrate 22 shown in FIG. 2, the conductor pattern on the back surface of the ceramic substrate 94 is a position inverted from the conductor pattern 97 on the surface. It is formed to become. That is, when the solid electrolyte electrode plate 91A is seen through from the surface, the conductor pattern 97 on the surface has two adjacent sides on the back side close to the end of the ceramic substrate 94, and the conductor pattern on the back surface is Two adjacent sides on the front side are formed close to the end of the ceramic substrate 94.
As the conductor material of the conductor pattern, Ag-based paste, Ag / Pt-based paste, and Al-based paste can be used in the same manner as the Ag-Pd-based paste, in addition to the aforementioned Ag-Pd-based paste. In addition to glass-based materials, materials used for bonding solid electrolyte substrates include materials formed from sol-gel, and bonding agents containing colloidal inorganic materials, such as Aron Ceramics manufactured by Toa Gosei Co., Ltd., for the same purpose. Is possible. In particular, it is important to select a material having a thermal expansion coefficient from room temperature to 500 ° C. close to that of the solid electrolyte material.
[0046]
In the example shown in FIGS. 3 and 4, the solid electrolyte electrode plate having the circular solid electrolyte substrate has been described. However, the present invention is not limited to the circular shape, and is a rectangular or polygonal solid. Of course, there is no problem even if an electrolyte substrate is used. In particular, the ability of the oxygen pump to concentrate or take out oxygen is proportional to the total area of the solid electrolyte substrate, so that the square or rectangular shape is more efficient in a rectangular laminate.
[0047]
Next, a method for attaching a sandwich electrode plate, which is a thin metal plate, to the solid electrolyte electrode plate using the various solid electrolyte electrode plates produced by the above-described manufacturing method and the configuration thereof will be described with reference to FIG. In FIG. 5, only one pole of the sandwiched electrode plate 23 is shown to make the drawing easier to see, and the other sandwiched electrode electrode 24 (FIG. 1) is omitted. In the following description using FIG. 5, the case where the solid electrolyte electrode plate 91 shown in FIG. 2 is used will be described. However, the solid electrolyte electrode plate 91A shown in FIG. The description is omitted. In the following description, description will be made based on the solid electrolyte cell 10 on the upper side of FIG.
[0048]
As described with reference to FIG. 2, the cathode electrode film 20 is formed on the surface of the solid electrolyte substrate 22, and the electrode pattern on the back side of the cathode electrode film 20 is almost close to the end of the solid electrolyte substrate 22. Is formed. On the other hand, there is a wide gap between the end of the electrode pattern of the cathode electrode film 20 on the two opposite front sides and the end of the solid electrolyte substrate 22.
In the electrode pattern of the cathode electrode film 20 arranged as described above, the two sides formed from the vicinity of the end of the solid electrolyte substrate 22 are sandwiched from above and below by two L-shaped sandwiched electrode plates 101 and 102. It is attached. These sandwiched electrode plates 101 and 102 are spot-welded and joined at several places.
[0049]
As shown in FIG. 5, the L-shaped sandwiched electrode plates 101 and 102 are formed with stepped portions 107, 109 and 108, 110 on the inside thereof, and sandwich the solid electrolyte substrate 22 disposed therebetween. It is configured to be able to. Therefore, when the two sandwiched electrode plates 101 and 102 are joined by spot welding, the respective stepped portions 107, 109 and 108, 110 are molded so as to press the surface of the solid electrolyte substrate 22. That is, both the sandwiched electrode plates 101 and 102 sandwich the solid electrolyte substrate 22 and are joined by spot welding so that the stepped portions 107 and 109 of the sandwiched electrode plate 101 press the cathode electrode film 20 on the solid electrolyte substrate. To do. As a result, the stepped portions 107 and 109 are electrically connected to the cathode electrode film 20 formed on the solid electrolyte substrate 22, and there is an electrically good connection state between the sandwiched electrode plate 101 and the cathode electrode film 20. It is formed.
[0050]
On the other hand, in the step portions 108 and 110 of the sandwiched electrode plate 102 attached to the back surface of the solid electrolyte substrate 22, the anode electrode film formed on the back surface of the solid electrolyte substrate 22 has a wide interval from the end portion of the solid electrolyte substrate 22. Therefore, even if it is pressed against the solid electrolyte substrate 22, it does not come into contact with the electrode pattern of the anode electrode film 92. Therefore, the sandwiched electrode plate 102 and the anode electrode film are electrically insulated.
As described above, even when the two sandwiched electrode plates 101 and 102 are spot-welded with the solid electrolyte substrate 22 sandwiched, the sandwiched electrode plates 101 and 102 are electrically connected only to the cathode electrode film 20. The structure is not connected to the anode electrode.
The two sandwiching electrode plates 24 on the near side, which are omitted in FIG. 5, are structurally the same as the sandwiching electrode plates 101 and 102 described above, but their connection destinations are different. When the front-side sandwiched electrode plate 24 is spot welded with the solid electrolyte substrate 22 sandwiched therebetween, the front-side sandwiched electrode plate 24 is opposite to the back-side sandwiched electrode plates 101 and 102. The stepped portion is insulated from the cathode electrode film 20 and is only electrically connected to the anode electrode film formed on the back surface of the solid electrolyte substrate 22.
[0051]
The sandwiched electrode plates 101 and 102 fixed by sandwiching the solid electrolyte substrate by spot welding are electrically insulated from the sandwiched electrode plate 24 on the near side (not shown in FIG. 5). The end portions 111a and 111b of the electrode plates 101 and 102 are disposed so as to have a gap with the sandwiched electrode plate 24 on the near side. Further, in the pair of sandwiching electrode plates 101 and 102, when the openings 103a and 105a of the sandwiching electrode plate 101 serving as a gas supply / discharge path and the openings 103b and 105b of the sandwiching electrode plate 102 are joined by spot welding. Are arranged at the same position.
Further, in the pair of sandwiching electrode plates 101 and 102, the opening 25a formed in one sandwiching electrode plate 101 and the opening (not shown) formed in the other sandwiching electrode plate 102 are located at the positions. Are arranged and welded to match. A metal rod for power supply is inserted into the opening 25a. Note that the front side sandwiching electrode plate 24 has the same structure as that of the rear side sandwiching electrode plate 23.
[0052]
As described above, in the oxygen pump module of Example 1, power is supplied to the anode electrode film and the cathode electrode film by the two sets of sandwiched electrode plates attached to the solid electrolyte cell in substantially the same plane. It has a possible structure.
In addition, since the perovskite-type barium-cerium-gadolinium-zirconium-based oxide solid electrolyte material used in Example 1 is a material that is driven at a temperature of 400 to 500 ° C., extreme oxidation does not occur at a temperature in this temperature range. If the metal parts in contact with the anode electrode film and the cathode electrode film formed on both surfaces of the solid electrolyte substrate are materials that do not deteriorate the spring property even when operated at the above temperature for a long time, the sandwiched electrode plate Can be used. The sandwiched electrode plate used in the oxygen pump of Example 1 is a material that retains the spring property at 600 ° C. or lower. If the driving temperature (practical ion conductivity) is 600 ° C. or less other than the solid electrolyte material used in the oxygen pump of Example 1, the connection method of the present invention can be applied regardless of the type of the solid electrolyte material. is there.
[0053]
FIG. 6 is a completed perspective view of the solid electrolyte cell 10 shown in FIG. In the solid electrolyte cell 10 of FIG. 6, two sets of sandwiched electrode plates 23 and 24 are fixed to the ends of the four sides of the rectangular solid electrolyte substrate 22, and one of the sandwiched electrode plates 23 has a cathode. An electrode film 20 is connected, and an anode electrode film is connected to the other sandwiched electrode plate 24. In the solid electrolyte cell 10 to which the sandwiched electrode plates 23 and 24 are attached, gas passage openings 31a, 31b, 30a, and 30b are formed on the outer peripheral portion thereof, and the diagonal lines at the four corners of the solid electrolyte cell 10 are formed. Small openings 25a and 25b and large openings 26a and 26b are formed. A metal rod for supplying power to the cathode electrode and the anode electrode is inserted into the small openings 25a and 25b and electrically connected thereto. On the other hand, the large openings 26a and 26b are through holes into which a metal rod for supplying power to the heater portion 44 of the heater plate 17 is inserted, and are formed large so as not to contact the metal rod for power supply.
As shown in FIG. 6, the gaps 121 and 122 formed by the two sandwiched electrode plates 23 and 24 are attached at an optimum interval so that the cathode electrode and the anode electrode are not short-circuited. In FIG. 6, the hatched portions 123 a, 123 b, 124 a, 124 b shown by fine hatching in the vicinity of the four corners of the electrode are provided with a heat resistant inorganic system in order to prevent the generation of an air flow directly flowing between the front and back of the solid electrolyte substrate 22. Adhesive is applied and cured.
[0054]
The heat-resistant inorganic adhesive used as described above in the present invention does not change at a high temperature (room temperature to about 500 ° C.), and maintains the adhesive force and airtightness, and the thermal expansion coefficient of the cured material. 5-15x10^-6  It is sufficient if the material is within the range. Specifically, heat-resistant inorganic adhesive Aron ceramic (main component is zirconia / silica, silica, alumina) of Toa Synthetic Chemical Industry Co., Ltd., various metal alkoxides (Si, Useful are heat-resistant inorganic adhesives using Ti, Zr, Al, etc., such as SIM # 500 series and Al2O3-SiO2-based, Al2O3-SiO2-Na2O-based adhesives manufactured by NICHIAS.
In order to maintain the airtightness as described above, the present invention is not limited to the use of the heat-resistant inorganic adhesive as described in Example 1, but a flexible heat-resistant material. There is no problem even if a material that is sealed with a sealant or a method for maintaining airtightness is used.
[0055]
7 is a cross-sectional view taken along the line VII-VII in FIG. 6 in order to explain the structure of the solid electrolyte cell 10 of Example 1 more clearly. As shown in FIG. 7, the cathode electrode film 20 and the anode electrode film 92 are formed on both surfaces of the solid electrolyte substrate 22, and the sandwiched electrode plates 101, 102, and 132 are formed on two sides of the solid electrolyte substrate 22 symmetrically. , 133 are disposed in a sandwiched state. In FIG. 7, the stepped portion 107 of the sandwiched electrode plate 101 on the upper right side presses the end of the cathode electrode film 20. On the other hand, the stepped portion 108 of the sandwiched electrode plate 102 on the lower right side is disposed with a gap from the anode electrode film 92 and is directly press-contacted to the solid electrolyte substrate 22.
The step portion 130 of the sandwiched electrode plate 132 shown on the upper left side in the solid electrolyte cell 10 of FIG. 7 is in direct pressure contact with the solid electrolyte substrate 22 and is disposed with a gap from the cathode electrode film 20. On the other hand, the step portion 131 of the sandwiched electrode plate 133 on the lower left side presses the end portion of the anode electrode film 92.
[0056]
As described above, in the solid electrolyte cell 10 of Example 1, the sandwiched electrode plates are respectively attached to the cathode electrode film 20 and the anode electrode film 92 formed on both surfaces of the solid electrolyte substrate 22 in substantially the same plane. It is joined to each electrode film without short-circuiting. The sandwiched electrode plate joining method by sandwiching the sandwiched electrode plate described in Example 1 according to the present invention does not generate microcracks in the joined portion even during long-time operation, and maintains an excellent joined state for a long period of time. can do.
In the conventional joining method using precious metal paste etc., in the case of an oxygen pump using a solid electrolyte cell where a large temperature difference always occurs, microcracks occur at the joint when operated for a long time even with a slight difference in thermal expansion coefficient, There is a problem that the joint portion eventually breaks. However, the sandwiched electrode plate joining method in the present invention solves the problems in the conventional joining method as described above, and the joining state of the joining portion is reliably maintained without breaking for a long time.
[0057]
As described above, the electrode connection structure of the oxygen pump in the present invention is a structure in which the solid electrolyte substrate is press-contacted using the spring property of the material of the sandwiched electrode plate. Therefore, even if there is a difference in thermal expansion coefficient between the solid electrolyte substrate and the sandwiched electrode plate, the joining portion between the solid electrolyte substrate and the sandwiched electrode plate is shifted or slipped due to the spring property of the sandwiched electrode plate. Therefore, it is possible to overcome and overcome the difference in thermal expansion between each other. As a result, the bonded portion between the solid electrolyte substrate and the sandwiched electrode plate in the oxygen pump of the present invention ensures a stable and stable bonded state for a long period of time.
Since the barium-cerium-gadolinium-based oxide, barium-cerium-gadolinium-zirconium-based oxide, or barium-cerium-gadolinium-aluminum-based oxide used in the present invention has a driving temperature of 500 ° C. or less, A joining method according to the present invention, that is, a joining method using metal springiness can be applied. In addition, since the conventional zirconium oxide-based oxide requires a temperature of 800 ° C. or higher, by using a metal material exhibiting spring property even in the temperature range, the joining method of the present invention can immediately perform this zirconium oxide-based oxidation. Of course, it can also be applied to objects.
[0058]
The joining structure of the sandwiched electrode plate with respect to the solid electrolyte electrode plate shown in FIG. 4 is exactly the same as that shown in FIGS.
In the joining method of the solid electrolyte electrode plate and the sandwiched electrode plate in Example 1, the sandwiched electrode plate has a structure that can move at the press contact portion with respect to the solid electrolyte electrode plate in addition to the above-described effects. Further, the twisting or warping due to the difference in the thermal expansion coefficient between the materials to be used, or the stress such as compression or tension being applied to the solid electrolyte electrode plate can be alleviated by the sliding of the pressure contact portion. As a result, the oxygen pump according to the present invention has an excellent effect that even a thin solid electrolyte electrode plate can be easily assembled and can be used for a long time without being damaged.
[0059]
In Example 1, the bonding structure using a pair of sandwiched electrode plates on two adjacent sides of the solid electrolyte electrode plate has been described. However, the present invention is not limited to such a configuration of the present invention. A junction structure may be used. An example thereof will be described with reference to FIG.
FIG. 8 is a perspective view showing the structure of another solid electrolyte cell in Example 1. FIG. In FIG. 8, one electrode film 140 is formed on the surface of the solid electrolyte substrate 22, and the other electrode film 141 is formed on the back surface by the materials and printing methods described above. However, in the electrode film 140 on the surface of FIG. 8, the far left side is formed to a position near the end of the solid electrolyte substrate 22. On the other hand, the right side on the front side of the electrode film 140 is formed with a wide gap from the end of the solid electrolyte 22.
[0060]
As shown in FIG. 8, two upper and lower sandwiched electrode plates 143a and 143b are attached to the left side of the back side of the solid electrolyte substrate 22 so that the right side on the front side is sandwiched between the upper and lower two sandwiched electrode plates 144a and 144a. 144b is attached so that it may pinch | interpose. Steps 145a, 145b and 146a, 146b are formed on the sandwiched electrode plates 143a, 143b and 144a, 144b as described above with reference to FIG. These stepped portions 145a, 145b and 146a, 146b sandwich the back left side and the front right side of the solid electrolyte substrate 22, and are fixed by spot welding at a plurality of locations of each sandwiched electrode plate 143a, 143b and 144a, 144b. Is done. At this time, the stepped portion 145a of the sandwiched electrode plate 143a on the surface on the far left side is in electrical contact with one electrode film 140, and the stepped portion 146b of the sandwiched electrode plate 144b on the back surface on the right side on the near side is the other electrode. Electrical contact is made with the membrane 141. Further, at this time, the stepped portion 145b of the sandwiched electrode plate 143b on the back surface on the left side on the back side is fixed in a state of being in direct contact with the solid electrolyte substrate 22, and the stepped portion 146a of the sandwiched electrode plate 144a on the surface on the right side on the near side is solid. The electrode substrate 22 is fixed in direct contact with the electrolyte substrate 22. That is, the sandwiched electrode plate 143b on the back surface on the left side on the back side is not in contact with the electrode film 141 on the back surface, and the sandwiched electrode plate 146a on the surface on the right side on the near side is not in contact with the electrode film 140 on the surface.
[0061]
In the solid electrolyte cell shown in FIG. 8, the sandwiching plates 142a, 142b and 147a, 147b having substantially the same structure as the sandwiching electrode plates 143a, 143b and 144a, 144b described above are the right side on the back side of the solid electrolyte substrate 22. And the end of the left side on the near side are sandwiched and fixed to each other by welding. The sandwich plates 142a, 142b and 147a, 147b are intended to hold the solid electrolyte substrate 22, and are not electrically connected to the electrode films 140, 141.
The aforementioned sandwiched electrode plates 143a, 143b and 144a, 144b are formed with openings 152a, 152b and 153a, 153b, respectively, for the same purpose as the gas passage openings 30b and 30a shown in FIG. . In addition, openings 150a and 150b are formed in the sandwiching plates 142a and 142b and 147a and 147b, respectively, for the same purpose as the gas passage openings 31a and 31b shown in FIG.
Further, mica plates 155a, 155b, 155c, and 155d are attached to the four corners of the solid electrolyte cell of FIG. 8, sandwiching electrode plates 143a, 143b and 144a, 144b, and sandwiching plates 142a, 142b and 147a, The gap with 147b is filled. As described with reference to FIG. 6, an inorganic adhesive is applied between the sandwiched electrode plates and the gap between the sandwiched plates, and the airtightness of the gap is ensured.
[0062]
In the description of the solid electrolyte cell shown in FIG. 8, the connection structure to the external power source is omitted, but it is the same as the connection structure of the embodiment shown in FIG. 1, and the sandwiched electrode plates 143a, 143b and Openings are formed at appropriate positions of 144a and 144b, and a metal rod for power supply is inserted and electrically connected.
In the above description, the sandwiched electrode plates 143a, 143b and 144a, 144b have been described with respect to the shape of a dimension that is substantially equal to the length of one side of the rectangular solid electrolyte substrate 22, but the sandwiched electrode plate is one side of the solid electrolyte substrate. Even if the size is smaller than the length of the electrode film, that is, the structure is connected to a part of the electrode film, it has the function of the present invention without any problem. This was confirmed by the present inventors through experiments. As an extreme method, even if the electrode film is pressed by using a metal wire having spring property and oxidation resistance even at a high temperature as the sandwich electrode plate, it is exactly the same as that of the connection structure described in the first embodiment. The effect can be demonstrated.
In the solid electrolyte cell shown in FIG. 8, there is no problem even if the sandwiching plates 142a, 142b and 147a, 147b intended to hold the solid electrolyte substrate 22 are omitted. However, when the sandwiching plate is omitted, an airtight structure at that portion is necessary. By comprising in this way, the use area of a metal material decreases and material reduction is attained.
[0063]
FIG. 9 is a perspective view showing the structure of still another solid electrolyte cell in Example 1. FIG. The shape of the solid electrolyte substrate 160 shown in FIG. 9 is different from that described above, and gas path openings 161a, 161b, 161c, 161d and a metal rod for connection to an external power source are inserted in the periphery of the solid electrolyte substrate 160 itself. Openings 162a, 162b, 163a, 163b are formed. In addition, an electrode film 165 (the back surface is omitted in FIG. 9) is formed at the central portion of the solid electrolyte substrate 160 by the above-described materials and printing method.
The sandwiched electrode plates 101 and 102 having the same structure as the sandwiched electrode plates 101 and 102 shown in FIG. 5 are fixed to two adjacent sides of the rectangular solid electrolyte substrate 160 so as to be sandwiched from above and below. . Further, stepped portions 107 and 109 are formed in the sandwiched electrode plates 101 and 102, and these stepped portions 107 and 109 are fixed so as to contact the end portion of the electrode film 165. Note that the step portions 108 and 110 of the back-side sandwiched electrode plate 102 are not in contact with the back-side electrode film. The reason that only one sandwiched electrode plate can be in contact with the electrode film in this manner is that the arrangement of the electrode films formed on both surfaces of the solid electrolyte substrate is different on both surfaces as in the above-described embodiment. In FIG. 9, the sandwiched electrode plate fixed to the front side has the same structure as the sandwiched electrode plates 101 and 102 on the back side, and therefore illustration and description thereof are omitted. Further, in FIG. 9, the details of the other configurations are the same as those described in FIG.
[0064]
In the structure of the solid electrolyte cell shown in FIG. 9, since the upper and lower sides are isolated by the solid electrolyte substrate 160, gas tightness between both surfaces of the solid electrolyte substrate 160 is ensured. The structure shown in FIG. 9 is a very effective structure particularly for an oxygen pump that places importance on airtightness (when high-purity oxygen is required). Note that the arrangement of the electrode film, the connection between the electrode film and the sandwiched electrode film, and the like in FIG. The solid electrolyte substrate 160 shown in FIG. 9 was produced by a green sheet method.
[0065]
Next, the gas separation / distribution plate in Example 1 according to the oxygen pump of the present invention will be described with reference to FIG. FIG. 10 is a perspective view showing the gas separation / distribution plate 14 in the oxygen pump module of the first embodiment.
In the gas separation / distribution plate 14 having a rectangular shape (horizontal cross section is substantially square), independent gas path openings 36a and 36b are formed in the vicinity of two opposing sides, and in the vicinity of the other two sides, Open gas passage portions 35a and 35b are formed at the placement positions of the gas passage openings 36a and 36b and at the placement positions rotated 90 ° in the horizontal plane. These open gas passage portions 35a and 35b are included in a large opening formed in the central portion of the gas separation / distribution plate 14, as shown in FIG. Further, openings 55a, 55b, 71a, 71b are formed at the four corners of the gas separation / distribution plate 14, and the two openings 55a, 55b and 71a, 71b on the opposing line have the same size. In the openings 55a and 55b having large diameters, nuts that are fastening means for fixing a metal rod for supplying electric power to the connection portion of the solid electrolyte cell 10 disposed below the holes 55a and 55b are disposed. Similarly, the gas separation / distribution plate 14 disposed on the heater plate 17 is formed with openings 27a and 27b having a large diameter, and the terminal portions of the heater plate 17 are formed in the openings 27a and 27b. And a nut for connecting the metal rod to each other. These large apertures are formed slightly larger than the size of the nut so that the nut can be accommodated.
[0066]
The gas separation / distribution plate used in the present invention has a high flatness made of a rigid, heat-resistant material, and serves to securely hold the solid electrolyte cells laminated together with the gas separation / distribution plate in a planar state. Have. If the gas separation / distribution plate is flexible or has low flatness, the solid electrolyte cell may be distorted and the solid electrolyte substrate of the solid electrolyte cell may be damaged.
[0067]
Next, the heater plate in Example 1 according to the oxygen pump of the present invention will be described in detail with reference to FIG. FIG. 11 is a perspective view showing the heater plate 17 in the oxygen pump of the first embodiment.
The heater part 44 which is a metal resistance foil which is a heating element of the heater plate 17 in the first embodiment is a stainless steel metal foil, for example, a stainless steel (Fe—Cr—Al type) plate thickness of Nippon Metal Industry Co., Ltd. It is formed using a material of 50 to 70 μm. As shown in FIG. 11, the heater portion 44 has a zigzag pattern, and this zigzag pattern is formed by an etching method, a laser processing method, a press molding method, or the like. Terminal portions 181 and 182 having openings 183a and 183b are formed at the center portions of both ends of the heater portion 44, respectively. Both surfaces of the heater portion 44 are sandwiched between mica plates 171 and 172 formed of a substantially square mica plate material, and the heater plate 17 is formed. In the vicinity of each side of these mica plates 171 and 172, gas passage openings 171a to 171d and 172a to 172d serving as gas supply / discharge passages are formed. Also, four openings 173a to 173d or openings 174a to 174d are formed in the central portion of each mica plate 171 or 172. The zigzag pattern of the heater unit 44 is configured to be disposed inside the gas path openings 171a to 171d and 172a to 172d serving as gas supply / discharge paths.
[0068]
In the mica plates 171 and 172, openings 178a, 178b and 180a, 180b are formed in one diagonal corner (left and right corners in FIG. 11). In these openings 178a, 178b, 180a, 180b, the center points of the openings 178a and 180a, or 178b and 180b are perpendicular to the center points of the openings 183a and 183b of the terminal part 181 or 182 of the heater part 44, respectively. It is made to be on the line.
The openings 178a and 178b in the mica plate 171 (the left and right openings in the mica plate 171 in FIG. 11) have a large diameter. This is because nuts for fastening the metal rod for power supply to the terminal portions 181 and 182 are accommodated in the openings 178a and 178b.
In the mica plate 171, openings 175 a and 176 a on the other diagonal line (openings on the back side and the near side of the mica plate 171 in FIG. 11) are through holes into which a metal rod for power supply of the solid electrolyte cell is inserted. is there.
[0069]
The heater plate 17 of Example 1 configured as described above has a thin shape with high flatness, and a main member is formed of a member having heat resistance. Further, it is made of a material that does not break even if the peripheral portion of the heater plate 17 is screwed, and is an optimal heating element for heating the solid electrolyte electrode plate of the oxygen pump of the present invention. In the oxygen pump of the present invention, the material of the heater plate is flat as long as it is heat resistant and does not break even if the peripheral part is screwed. It is not limited to.
[0070]
Next, the gas flow in the oxygen pump module of Example 1 according to the present invention will be described with reference to FIG. FIG. 12 is a cross-sectional view showing a gas flow in a laminated structure in which a predetermined number of solid electrolyte cells, gas separation / distribution plates, and heater plates of the oxygen pump module are laminated. The main components of the oxygen pump module shown in FIG. The cross-sectional structure by the XII-XII line in a part is shown. In FIG. 12, the same number is attached | subjected to the thing of the same function and structure as the drawing mentioned above.
[0071]
As described above with reference to FIG. 1, the gas passing over the surface of the cathode electrode film 20 of the solid electrolyte cell 10 is a gas in which oxygen decreases. In FIG. 12, this gas flow is indicated by arrows 72a and 72b. Is shown. The laminated body shown in FIG. 12 has a structure in which gas separation / distribution / heat retaining plates 185a and 185b and metal plates 186a and 186b are further attached to the outermost layer of the laminated body shown in FIG. The gas separation / distribution / heat retaining plates 185a and 185b guide the flow of gas and have a heat retaining function in the laminated structure. The outermost metal plates 186a and 186b in the laminated structure are provided to fasten the laminated body disposed between them and to maintain airtightness between the respective layers. The metal plates 186a and 186b used in Example 1 may be any material having oxidation resistance, and may have a thermal expansion coefficient close to that of the solid electrolyte material to be used. For example, in Example 1, the thermal expansion coefficient of the solid electrolyte is 10 to 12 × 10.^-6Therefore, the range before and after that, that is, 4 to 20 × 10^-6If it is within the range, there is no problem. The inventor has confirmed the range of the expansion coefficient by experiments. As a specific material of the metal plates 186a and 186b, stainless steel, nickel alloy, cobalt alloy, nickel-cobalt alloy, iron alloy or the like is optimal.
[0072]
In FIG. 12, the gas flowing toward the cathode electrode flows in the direction of the arrow 72ba on the left side and is divided toward the cathode electrode surface of each solid electrolyte cell by the four gas separation / distribution plates 14, 2, 3, and 4. The The diverted gas passes on the surface of the cathode electrode surface of each solid electrolyte cell, and flows out in the direction of the right arrow 72a while taking oxygen.
On the other hand, the gas enriched with oxygen flows into the laminated structure and flows in a direction perpendicular to the paper surface, and in the gas separation / distribution plates 15, 16, 32, 34, the anode electrode surfaces 188, 189, Passing over the surfaces of 193 and 194, oxygen enriched gas flows out of this stack.
In the laminated structure of FIG. 12, the gas flow has been described as flowing in from the lower part and flowing out to the lower part, but the present invention is not limited to such a structure, and the inflow direction and the outflow direction are in the upper part. Or in any direction below.
[0073]
Next, the structure of the laminated structure in the oxygen pump of Example 1 according to the present invention will be described in more detail with reference to FIG. FIG. 13 is a perspective view showing the structure of the laminated structure in the oxygen pump of Example 1. FIG.
In FIG. 13, the portion denoted by reference numeral 201 is the laminated body shown in FIG. In addition, metal plates 203a and 203b are provided outside the gas separation / distribution / heat insulating plates 202a and 202b for fastening the laminated structure.
Openings 204a and 204b on both sides provided in the vicinity of two opposing sides of the upper gas separation / distribution / heat insulating plate 202a are gas supply / discharge passages. On the other hand, the lower gas separation / distribution / heat retaining plate 202b is supplied with gas at the positions where the openings 204a and 204b of the upper gas separation / distribution / heat retaining plate 202a are disposed and disposed at a position rotated 90 ° in the horizontal plane. A path (not shown) is formed.
[0074]
As shown in FIG. 13, the upper metal plate 203a has notches 205a, 205b, 205c, and 205d formed at its four corners, and a metal for supplying power to the anode electrode, the cathode electrode, and the heating element. It is comprised so that it may not contact with the terminal attached to a stick | rod and its metal stick | rod. Similarly, the lower metal plate 203b has notches 206a, 206c, and 206d (in FIG. 13, one notch is not shown because of the drawing) at the four corners. A plurality of holes 207 are formed in the vicinity of the edges of the metal plates 203a and 203b, and serve as screw insertion holes for screwing the upper and lower metal plates 203a and 203b.
Although omitted in FIG. 13, in order to further increase the airtightness between the respective layers, a gasket having heat resistance and flexibility is arranged between the respective layers, and the metal plates 203a and 203b are tightened. Yes. In addition, if it is comprised with the material by which a certain amount of airtightness is hold | maintained, it is also possible to comprise without inserting a gasket.
[0075]
FIG. 14 is a perspective view showing an appearance of the oxygen pump according to the first embodiment of the present invention.
In FIG. 14, screws 211a and 211b provided on the diagonal line on the back side and the near side pass through the laminated structure (202a, 201, 202b), and the anode of each solid electrolyte cell in the laminated structure. It is electrically connected to the electrode and the cathode electrode. These screws 211a and 211b have lead wire connection terminals 213a and 213b attached at the upper part thereof, and are tightened by nuts at the lower part thereof.
Further, in FIG. 14, screws 212a and 212b provided on the right and left diagonal lines pass through the laminated structure (202a, 201, 202b), and the heater pattern of the heater plate is formed inside the laminated structure. It is electrically connected to the connected terminal part. These screws 212a and 212b have lead wire connection terminals 214a and 214b attached at the upper part thereof, and are tightened by nuts at the lower part thereof.
[0076]
In FIG. 14, washers 216 are respectively attached to a plurality of screws 215 attached to the upper metal plate 203a, and the screws 215 pass through the laminated structural body (202a, 201, 202b), and at the lower part thereof. The nuts are tightened to integrate the stacked structural bodies (202a, 201, 202b).
In FIG. 14, an arrow 73a indicates a gas introduction part for gas in which oxygen is concentrated, and an arrow 73b indicates an outlet for gas in which oxygen is concentrated. In the configuration of the oxygen pump shown in FIG. 14, the gas enriched with oxygen is an example of a configuration in which the gas is taken out from the upper side of the laminated structure, but, of course, any configuration in which both gases flow in and out on one side. Can be manufactured without problems.
In the first embodiment, the oxygen pump module has been described. The oxygen pump module is a basic component of the oxygen pump, and is the oxygen pump itself. The same applies to the following embodiments.
The oxygen pump according to the first embodiment of the present invention has a structure having a gas supply / discharge path and a power supply line in a small stack structure, and is very compact.
[0077]
Example 2
Next, an oxygen pump module according to Example 2 of the present invention will be described with reference to FIGS. The oxygen pump module of Example 2 has substantially the same configuration in which the solid electrolyte cell, gas separation / distribution plate, heater plate, and the like in the oxygen pump module of Example 1 described above are stacked. The direction of the gas flow inside is changed. In the oxygen pump module described with reference to FIGS. 1 to 14, a structure in which a gas flow in which oxygen is concentrated and a gas flow in which oxygen is reduced flows in the same direction on each surface of a plurality of solid electrolyte cells (parallel system) ) Explained. The oxygen pump module shown in FIG. 15 has both oxygen enriched gas and oxygen depleted gas staggered on each side of the solid electrolyte cell, i.e., the gas is different on the surface of each solid electrolyte cell. It has a structure that flows in order in the direction (series system). The structure of this oxygen pump in series will be described below.
The majority of the configuration of the oxygen pump module of the second embodiment shown in FIG. 15 is the same as that of the first embodiment shown in FIG. 1, but the solid electrolyte cell, gas separation / distribution plate, heater The positions of the gas passage openings that form the gas supply / discharge passages in the plate or the like are different.
[0078]
First, the gas flow 219 flowing from the upper part of the laminated structure will be described.
As shown in FIG. 15, in the gas separation / distribution plate 223 arranged in the uppermost layer, the open gas path portions 231a and 231b are included in an opening portion formed in the central portion thereof. Thereby, the gas that has flowed in from the upper part of the stacked structure flows along the upper surface of the solid electrolyte cell 221 through the open gas path portion 231a.
The gas flowing along the upper surface of the solid electrolyte cell 221 flows through a gas path opening 232a formed in the vicinity of one side of the solid electrolyte cell 221 (in the vicinity of the right-hand side in FIG. 15). In the solid electrolyte cell 221, an opening serving as a gas supply / discharge path is not formed at a position facing the gas path opening 232a.
In the gas separation / distribution plate 224 disposed immediately below the solid electrolyte cell 221, an independent gas path opening 233a is formed in the vicinity of one side (near the right side in FIG. 15). An opening serving as a gas supply / discharge path is not formed at a position facing the gas path opening 233a.
[0079]
In the heater plate 227 arranged immediately below the gas separation / distribution plate 224, a gas path opening 234a is formed independently in the vicinity of one side thereof (in the vicinity of the right side on the front side in FIG. 15). In this case, an opening serving as a gas supply / discharge path is not formed.
In the gas separation / distribution plate 225 arranged immediately below the heater plate 227, a gas path opening 235a is independently formed in the vicinity of one side thereof (in the vicinity of the right front side in FIG. 15), and the opposing position. In this case, an opening serving as a gas supply / discharge path is not formed.
[0080]
In the solid electrolyte cell 222 disposed immediately below the gas separation / distribution plate 225, a gas path opening 236a is independently formed in the vicinity of one side (near the right side in FIG. 15). An opening serving as a gas supply / discharge path is not formed at a position facing the gas supply / discharge path opening 236a.
The gas separation / distribution plate 226 disposed immediately below the solid electrolyte cell 222 has an open gas passage portion 237a serving as a gas supply / discharge passage in the vicinity of the two opposing sides (near the front right side and the back left side in FIG. 15). , 237b are included in the opening of the central portion. Therefore, the open gas path portions 237a and 237b facing each other are in communication with each other.
[0081]
In the laminated structure constructed and laminated as described above, when the gas flows in from the open gas passage portion 231a of the uppermost gas separation / distribution plate 223, the gas is produced only through the route indicated by the gas flow 219 in FIG. In the laminated structure, the gas always flows in one path in order from the top (hereinafter referred to as a series system).
Further, the gas flow 220 flowing from the lower side of the laminated structure shown in FIG. 15 is configured to flow in the direction rotated by 90 ° in the direction of the gas flow 219 and the horizontal plane in each layer. As shown in FIG. 15, the gas flow 220 flowing inside the stacked structure is also configured in a series system so that the gas always flows in one path from the bottom in the stacked structure.
[0082]
The gas passage opening 238a in the gas separation / distribution plate 223 is independently formed only in the vicinity of one side (near the right back side in FIG. 15). A gas path opening 232b is formed in the vicinity of one side of the solid electrolyte cell 221 (in the vicinity of the far right side in FIG. 15), and an opening serving as a gas supply / discharge path is formed at a position facing the gas path opening 232b. The part is not formed. In the heater plate 227, gas passage openings 234b are formed in the vicinity of two opposing sides (the vicinity of the front left side and the back right side in FIG. 15). A gas path opening 236b is formed in the vicinity of one side of the solid electrolyte cell 222 (in the vicinity of the left side on the front side in FIG. 15), and an opening serving as a gas supply / discharge path is located at a position facing the gas path opening 236b. The part is not formed. Further, the gas separation / distribution plate 226 disposed immediately below the solid electrolyte cell 222 has a gas path opening 237b in the vicinity of one side thereof (in the vicinity of the left side in front of FIG. 15). An opening serving as a gas supply / discharge path is not formed at a position facing the gas path opening 237b.
[0083]
As described above, by changing the position of the gas supply / discharge path formed in the vicinity of the outer peripheral portion of each layer, it is possible to easily change the direction of the gas flow flowing through the stacked structure to the parallel system or the serial system. .
When the gas flow is a serial stacked structure, the gas inflow side and the outflow side are opposite to each other in the stacked structure. However, in the parallel stacked structure, the gas inflow side and the outflow side can be freely designed to be the same side or the opposite side.
[0084]
FIG. 16 is a perspective view showing the overall configuration of the oxygen pump module in the second embodiment. The oxygen pump module shown in FIG. 16 includes gas separation / distribution / heat insulation plates 241a, 241b and upper metal plate 243a having two gas supply / discharge ports 244, 245 above and below the stacked structure shown in FIG. A lower metal plate 243b having two gas supply / exhaust ports 246 (the other gas supply / exhaust port is not shown) is provided. The upper and lower gas separation / distribution / heat insulation plates 241a and 241b determine the direction of gas flow, and also function as heat insulation in the solid electrolyte cell and for the metal plates 243a and 243b attached up and down. Openings 242a and 242b formed in the upper gas separation / distribution / heat insulating plate 241a are formed so as to be at the same positions as the gas path openings 238a and 231a of the gas separation / distribution plate 223. Similarly, the opening formed in the lower gas separation / distribution / heat retaining plate 241b is formed to be in the same position as the gas path opening of the gas separation / distribution plate thereabove.
[0085]
17 is a cross-sectional view taken along line XVII-XVII in the oxygen pump module of FIG.
As shown in FIG. 17, the gas flowing in from the gas supply / exhaust port 245 at the top of the oxygen pump module is, as shown in the gas flow 219, the upper space 251 of the solid electrolyte electrode plate 261, two solid electrolyte substrates 262. It flows continuously through a space 252 surrounded by H.263 and a space 253 on the lower surface of the solid electrolyte plate 264, and flows out from the lower gas supply / exhaust port 246.
The other gas flow 220 (FIG. 16) (not shown) flows in a direction perpendicular to the paper surface, and includes spaces 254 and 255 surrounded by the two solid electrolyte plates 261 and 262 (including the space where the heater plate 265a is disposed). , And continuously flow through spaces 256 and 257 (including the space for arranging the heater plate 265b) surrounded by the two solid electrolyte plates 263 and 264.
[0086]
According to the configuration of the oxygen pump module of the second embodiment configured as described above, the gas flows continuously through the surface of each solid electrolyte plate sequentially in one path, and flows out from the gas supply / discharge port. Therefore, a gas containing concentrated oxygen or reduced oxygen can be reliably taken out.
[0087]
FIG. 18 is a cross-sectional view illustrating another configuration of the oxygen pump module according to the second embodiment. The oxygen pump module shown in FIG. 18 has a structure in which the gas flow can be switched to a serial system (FIG. 18 (a)) or a parallel system (FIG. 18 (b)). It is.
The oxygen pump module shown in FIG. 18 is configured so that openings formed in the vicinity of two opposing sides of each layer communicate vertically. In FIG. 18, a space that communicates vertically (hereinafter referred to as a communication space) is indicated by reference numeral 283.
[0088]
As shown in FIG. 18 (b), when the gas flow is parallel in the oxygen pump module, the gas flowing in from the gas supply / exhaust port 271 passes through the communication space 283, and the anode electrode film of each solid electrolyte cell or The gas flows in parallel in the same direction so as to be in contact with the surface of the cathode electrode film, and flows out from the gas supply / discharge port 272. In this way, in order to change the direction of the gas flow flowing in the parallel system to the gas flow in the serial system, the gas flow changing blocks 273a and 274a are mounted in the communication space 283 as shown in FIG. By mounting the gas flow changing blocks 273a and 274a in the communication space 283 in this way, a part of the gas supply / discharge path in the parallel system is closed, and the gas is supplied to each anode electrode film or each cathode electrode film of each solid electrolyte cell. The gas flows in a different direction for each stack and becomes a serial gas flow. The serial type gas flow changing blocks 273a and 274a and the parallel type gas flow changing blocks 273b and 274b mounted in the communication space 283 shown in FIG. 18 are made of a heat-resistant insulating material, and are connected to the communication space. It is formed so as to be fitted to 283.
[0089]
FIG. 19 is a perspective view showing one gas flow changing block 273a for forming a serial gas flow. In FIG. 19, a groove portion 283 is formed in an intermediate portion of the gas flow changing block 273a, and this groove portion 283 is a portion through which the gas at the communicating portion passes. The dimensions of the gas flow changing block are dimensions that can be securely inserted and fitted into the communication space 283 of the oxygen pump module (in FIG. 1, the space formed by the gas passage opening 36a of the gas separation / distribution plate 14). . In FIG. 19, the dimensions of the width 281 and the length 282 in the gas flow changing block 273a are formed slightly smaller than the dimensions of the gas path opening portion serving as the gas supply / discharge path of each layer in the laminated structure.
The embodiments shown in FIGS. 18 and 19 show one method for changing the direction of gas flow, and the present invention is not limited to such a configuration.
[0090]
As described above, by using the gas flow change block configured as shown in FIG. 18 and FIG. 19, the gas supply / discharge path of the oxygen pump module can be changed, and the serial type gas flow and the parallel type gas flow can be changed. An oxygen pump that can be generated can be provided. The oxygen pump configured in this way can be used to change the direction of gas flow simply by inserting a gas flow changing block having a desired shape into the communication space (gas supply / exhaust passage) of the laminated structure. A laminated oxygen pump according to the purpose can be easily provided.
[0091]
Example 3
Next, an oxygen pump according to a third embodiment of the present invention will be described with reference to FIGS. Example 3 relates to an oxygen pump module configured by stacking four layers of solid electrolyte cells each having two solid electrolyte electrode plates. In the oxygen pump module of the third embodiment, the functions of the solid electrolyte cell, the gas separation / distribution plate and the heater plate described in the oxygen pump module of the first embodiment are substantially the same. Configured. Therefore, in the description of the oxygen pump module according to the third embodiment, differences from the above-described embodiment will be described.
[0092]
FIG. 20 is an exploded perspective view showing a laminated structure of the oxygen pump module according to the third embodiment. FIG. 21 is a perspective view of a solid electrolyte cell in Example 3, FIG. 22 is a perspective view of a gas separation / distribution plate in Example 3, and FIG. 23 is an exploded perspective view of a heater plate in Example 3. FIG. 24 is a perspective view showing an assembly process of the laminated structure, and FIG. 25 is a perspective view showing a completed state of the oxygen pump module of the third embodiment.
[0093]
In FIG. 20, two solid electrolyte electrode plates 307, 308, 387, and 388 are arranged in parallel in each solid electrolyte cell 304 and 305, respectively. On the upper side of the upper solid electrolyte cell 304, a gas separation / distribution plate 301 is disposed, and two sets of opposed open gas path portions 335a, 335b and 335c, 335d are formed. The open gas path portions 335a, 335b and 335c, 335d of each set are included in large openings formed independently in the left and right central portions, and communicate with each other.
A gas separation / distribution plate 302 is disposed below the solid electrolyte cell 304. The open gas path portions 335a, 335b and 335c, 335d of the upper gas separation / distribution plate 301 are arranged in a horizontal plane. Open gas passage portions 341a and 341b are formed at positions opposite to each other on the right side and the front left side in FIG. 20. These open gas passage portions 341a and 341b communicate with each other at the central portion. It is contained in one large opening formed.
[0094]
Below the gas separation / distribution plate 302, a heater plate 306 in which two heater portions are connected in series and arranged in parallel is arranged. Under the heater plate 306, a gas separation / distribution plate 303 having substantially the same configuration as the gas separation / distribution plate 302 described above (however, a nut for connecting and fixing the solid electrolyte cell 305 is disposed). Only the hole 303a is different in size from the opening 302a), the solid electrolyte cell 305, and the gas separation / distribution plate 310 having substantially the same configuration as the gas separation / distribution plate 301 arranged in the uppermost layer (however, the opening 310a is different in size from the opening 318 of the gas separation / distribution plate 301) and is laminated.
Laminated structure (gas separation / distribution plate 301-solid electrolyte cell 304-gas separation / distribution plate 302-heater plate 306-gas separation / distribution plate 303-solid electrolyte cell 305-gas separation / distribution configured as described above. The plate 310) is considered as one laminated block, and a laminated structure of the oxygen pump module of Example 3 is configured by stacking a plurality of laminated blocks.
[0095]
In the laminated structure shown in FIG. 20, in the upper solid electrolyte cell 304, the electrodes on the same surface of the solid electrolyte electrode plates 307 and 308 arranged in parallel, for example, the electrode on the upper surface side in FIG. It is. Further, in the solid electrolyte cells 304 and 305 arranged above and below, the electrodes on the opposing surfaces are arranged so as to have the same polarity. That is, the anode electrode is disposed so that the anode electrode faces the cathode electrode, and the cathode electrode faces the cathode electrode.
In the solid electrolyte cells 304 and 305, two sandwiched electrode plates that press-contact the anode electrode film or the cathode electrode film formed on both surfaces of the solid electrolyte electrode plate are sandwiched from above and below at the periphery of the solid electrolyte electrode plate. It is fixed. A plurality of apertures 311, 312, 313 and 314, 315, 316 are formed in these sandwiched electrode plates. These openings 311, 312, 313 and 314, 315, 316 serve as connection terminals for power supply, the openings 311, 312, 314, 315 have the same pole, and the openings 313, 316 have the opposite poles. Configured to be connected.
[0096]
On the line connecting the center lines of the apertures 311 and 314 in the upper and lower solid electrolyte cells 304 and 305, at the corresponding positions of the respective substrates (for example, the gas separation / distribution plates 301, 302, and 303 and the heater plate 306) of the laminated structure. The formed opening (319 or the like) is disposed. Similarly, an opening (317 or the like) formed at a position corresponding to each substrate of the laminated structure is disposed on a line connecting the center lines of the openings 312 and 315. Further, openings (318, 302a, 306a, 303a, 310a, etc.) formed at positions corresponding to the respective substrates of the laminated structure are arranged on a line connecting the center lines of the openings 313, 316. It should be noted that the lower laminated structure other than that described above has the same structure, and a description thereof will be omitted.
[0097]
A metal rod as a power supply conductor for the solid electrolyte cell is inserted into each of the openings 311 and 314 and the openings 312 and 315 in the upper and lower solid electrolyte cells 304 and 305 arranged as described above. And an external power source is supplied to each. Note that the metal rods inserted into the openings 311 and 314 and the openings 312 and 315 are the same electrode. Further, metal rods of different electrodes are inserted into the openings 313 and 316, and external power is supplied.
At the four corners of the heater plate 306, openings 321 and 322 are formed at two positions (the back corner and the left end corner in FIG. 20) different from the positions at which the openings 311 and 312 of the solid electrolyte cell 304 are formed. Openings 321 in the heater plate 306 (openings formed in two corners on the back side in FIG. 20) are arranged on the same vertical line of the openings 323 in the upper gas separation / distribution plate 301, and are similarly opened. The hole 322 (left end corner in FIG. 20) is disposed on the same vertical line of the opening 324 of the gas separation / distribution plate 301. A metal rod is inserted into these openings 321 and 322 and is electrically connected. Electric power from an external power source is supplied to the heater plate 306 by this metal rod. In the solid electrolyte cells 304 and 305, the opening into which the metal bar for supplying power to the heater plate 306 is inserted is formed large so as not to contact the metal bar.
[0098]
As shown in FIG. 20, in the solid electrolyte cells 304 and 305, in the vicinity of the two short sides facing each other (near the two sides on the far right side and the near left side in FIG. 20), there is a gas passage opening 323a in the peripheral part of the sandwiched electrode plate. , 323b, 324a, 324b. In these gas path openings 323a, 323b, 324a, 324b, the gas path openings 323a, 324a and 323b, 324b on the far right side and the left side on the near side communicate with each other, and in FIG. 20, the gas flows from top to bottom. It is comprised so that it may flow in, and each is the same gas supply / discharge path.
In addition, gas passage openings 326 and 327 communicating with each other are formed in the central portions of the solid electrolyte cells 304 and 305, which serve as outflow passages from the bottom to the top of the inflowing gas.
[0099]
Further, in the solid electrolyte cell 304, two gas path openings 330a to 330d are formed in the vicinity of the two long sides facing each other (near the two long sides on the front right side and the back left side in FIG. 20). Further, in the solid electrolyte cell 305, two gas path openings 331a to 331d are formed in the vicinity of the two long sides facing each other (near the two long sides on the front right side and the back left side in FIG. 20), Each is arranged on the same vertical line in the vertical direction with the gas passage openings 330a to 330d. Thus, the gas path openings (330a-331a, 330b-331b, 330c-331c, and 330d-331d) formed on the same vertical line are in communication. The gas supply / exhaust path of the gas flow constituted by the gas path openings 330a to 330d and 331a to 331d is the gas path openings 323a, 323b, 326, 324a, 324b, and 327 formed between the back right side and the front left side. A gas supply / exhaust path with a different gas flow is formed. These two gas supply / discharge paths have a structure that is isolated from each other.
[0100]
As shown in FIG. 20, two sets of open gas passages 335a and 335b, 335c and 335d in the gas separation / distribution plate 301 arranged on the upper side of the solid electrolyte cell 304 are large openings formed on the left and right respectively. It is included and has a communication structure. The gas separation / distribution plate 301 has three gas passage openings 336a, 336b, and 337 that are formed independently of each other, and are also isolated and independent from two large openings formed on the left and right. .
Unlike the gas separation / distribution plate 301 described above, the gas separation / distribution plate 302 disposed below the solid electrolyte cell 304 has open gas path portions 341a and 341b formed in the vicinity of two opposing short sides at the central portion. It is contained in one large opening formed and is in communication. Further, in the gas separation / distribution plate 302, the gas path openings 342a, 342b (see FIG. 22), 342c, 342d formed in the vicinity of two opposing long sides are independent from each other and formed in the central portion. Isolated from large openings. Therefore, in the gas separation / distribution plates 301 and 302 arranged in contact with the upper and lower surfaces of the solid electrolyte cell 304, the arrangement relationship of whether the gas supply / exhaust passage communicates with a large opening formed therebetween or is independent. This is the same in the arrangement direction rotated 90 ° in the horizontal plane. This positional relationship is the same in the upper and lower gas separation / distribution plates with respect to other solid electrolyte cells. In addition, the gas path openings in the gas separation / distribution plates 302 and 303 disposed between the two solid electrolyte cells 304 and 305 are formed on the same vertical line and are in communication.
The above configuration is the same in the other blocks.
[0101]
Next, the gas flow in the oxygen pump module of Example 3 will be described. Although the oxygen pump of the third embodiment has a parallel gas flow configuration, it can be configured as a serial gas flow by using a gas flow change block that switches the direction of the gas flow as in the second embodiment. Is possible. Hereinafter, the parallel gas flow will be described.
Of the gas enriched in oxygen or the gas depleted in oxygen, one gas flows in from the bottom and flows through the gas supply / exhaust passage as shown by the white arrows 348a and 349a, and makes a U-turn at the top. . The U-turned gas at the upper part flows downward in the gas supply / discharge path as shown by gas flows 348b and 349b indicated by white arrows.
The other gas flows from the upper part of both sides as shown by the slanted arrows 345a and 345b, flows through the gas supply / discharge passage, and makes a U-turn on the lower side. The gas that has made a U-turn on the lower side flows out of the oxygen pump module as a gas flow 346 that flows upward through a gas supply / discharge passage formed in the center as indicated by the hatched arrow.
The inflow direction and outflow direction of the gas flow are not limited to the directions shown in FIG. 20 and can be freely selected.
[0102]
Also, changing the gas flow parallel system to the serial system as described above can be easily changed by installing a gas flow changing block having a desired shape as shown in FIG. Is possible.
In the oxygen pump module of Example 3, an example of a configuration in which two solid electrolyte plates are incorporated in one solid electrolyte cell has been described, but when a larger amount of concentrated oxygen is required, a plurality of solid electrolyte plates are used. This can be handled by incorporating the electrolyte plate into one solid electrolyte cell to form a laminated structure. With this configuration, the oxygen pump of the present invention can discharge a large amount of concentrated oxygen, and can provide a compact and large-capacity oxygen pump.
Moreover, by mounting a plurality of solid electrolytes in one solid electrolyte cell, the required area in all the laminates is reduced, and parts such as a power supply metal plate arranged in the solid electrolyte cell The number of points is reduced, the number of work steps is reduced, and the cost can be greatly reduced. In addition, solid electrolyte cells equipped with multiple solid electrolytes have less heat dissipating than solid electrolyte cells equipped with single-leaf solid electrolytes. It is possible to save energy of the heater for heating provided in the housing.
[0103]
Although the oxygen pump of Example 3 has been described with reference to FIG. 20, details of individual constituent substrates will be described below with reference to the drawings.
FIG. 21 is a perspective view showing the solid electrolyte cell 304 in the third embodiment. In FIG. 21, electrode films are formed on both surfaces of solid electrolyte substrates 351 and 352 of solid electrolyte electrode plates 307 and 308 provided on the left and right sides, and reference numerals 353 and 354 are formed on one surface of the solid electrolyte substrates 351 and 352. It is the electrode film of the same pole made.
Each electrode film is formed by the material and method described in the first embodiment. The electrode patterns of the electrode films 353 and 354 are arranged so as to be offset toward the adjacent two sides (short sides) of the left and right solid electrolyte substrates 351 and 352, and on the opposite two sides that are both ends in the longitudinal direction. A portion where no electrode pattern exists is formed. Further, similarly to the above-described embodiments, the electrode patterns on the back surface of the solid electrolyte substrates 351 and 352 are formed so as to be reversed from the arrangement on the front surface.
[0104]
In the solid electrolyte cell 304 shown in FIG. 21, three sandwiched electrode plates 355, 356a, and 356b are provided so as to surround the solid electrolyte electrode plates 307 and 308. The central sandwiched electrode plate 355 has a T shape, and the sandwiched electrode plates 356a and 356b on both sides have an L shape. Each sandwiched electrode plate 355, 356a, 356b is composed of two upper and lower plates having the same shape as described in the first embodiment, and is fixed so as to sandwich the solid electrolyte electrode plates 307, 308 from above and below. The
In FIG. 21, the T-shaped sandwiched electrode plate 355 is in electrical contact with the electrode film 353 formed on the surface of the solid electrolyte electrode plate 307 with stepped portions 357 and 358 formed on the sandwiched electrode plate 355. It is pressed to do. Further, the other step portions 359 and 360 formed on the sandwiched electrode plate 355 are in pressure contact with the electrode film 354 formed on the surface of the solid electrolyte electrode plate 307, respectively. That is, the T-shaped sandwiched electrode plate 355 is electrically connected to the two electrode films 353 and 354 arranged on the left and right. The T-shaped sandwiched electrode plate 355 is not in contact with the electrode film formed on the back surface.
In FIG. 21, the L-shaped sandwiched electrode plate 356a disposed on the right side is in electrical contact with the electrode film formed on the back surface of the solid electrolyte 307, and the L-shaped sandwiched electrode plate 356a is disposed on the front left side. The sandwiched electrode plate 356b is in electrical contact with the electrode film formed on the back surface of the solid electrolyte plate 308. That is, the T-shaped sandwiching electrode plate 355 is connected to one electrode, and the L-shaped sandwiching electrode plates 356a and 356b are connected to the other electrode.
[0105]
In Example 3, the sandwiching electrode plates 355, 356a, 356b are each composed of two upper and lower plates, and the sandwiching structure for sandwiching and fixing the solid electrolyte electrode plates 307, 308 from above and below is sandwiched electrode plates 355, 356a. , 356b, and the electrical connection method using the spring property, and since this electrical connection method has been described in detail in the first embodiment, it is omitted here.
Electric power is supplied to the electrode films 353 and 354 of the solid electrolyte electrode plates 307 and 308 by a metal rod connected to an opening 313 formed in the sandwiched electrode plate 355, and supply to the electrode films on the back surface is sandwiched. This is performed by metal bars connected to the apertures 311 and 312 formed in the electrode plates 356a and 356b.
The T-shaped sandwiched electrode plate 355 and the L-shaped sandwiched electrode plates 356a and 356b are formed with gaps 361a, 361b, 362a, and 362b at their opposing ends, and are electrically insulated from each other. Has been.
[0106]
In addition, in order to ensure gas tightness in the laminated structure, the vicinity of the four corners 365a, 365b, 365c, 365d and 366a, 366b, 366c, 366d of the solid electrolyte electrode plates 307, 308, which are portions where gas may leak. The adhesive composed of the inorganic material described in the first embodiment is applied to isolate the front and back sides.
In the third embodiment, the solid electrolyte cell 304 having the two solid electrolyte electrode plates 307 and 308 has been described. However, more solid electrolyte electrode plates are arranged in the solid electrolyte cell to increase the amount of gas supply. It is possible.
In the third embodiment, the connection between the sandwiched electrode plate and the electrode film has been described as being performed on two adjacent L-shaped sides. However, this connection may be performed on one side, and further, There is no problem even if only one part is connected. The power supply to the electrode film can also be performed by connection with a metal wire. However, as described above, the metal wire to be used must be made of a material capable of sandwiching the solid electrolyte electrode plate by generating a spring property by performing heat treatment specific to the metal.
[0107]
FIG. 22 is a perspective view showing two types of gas separation / distribution plates 301 and 302 in the third embodiment. In the upper gas separation / distribution plate 301, the open gas passage portions 335a, 335b and 335c, 335d, which are gas supply / discharge passages formed in the vicinity of the side in the longitudinal direction, are included in large openings on the left and right sides, and are in communication with each other. It is. When the gas flows through the communicating opening, the gas is configured to come into contact with the electrode film surface of the solid electrolyte electrode plate.
On the other hand, in the lower gas separation / distribution plate 302, a position rotated by 90 ° in the horizontal plane with the open gas path portions 335a, 335b and 335c, 335d of the upper gas separation / distribution plate 301, that is, a direction perpendicular to the longitudinal direction. Open gas path portions 341a and 341b are formed at positions in the vicinity of the short side, and these open gas path portions 341a and 341b are included in a large opening formed in the central portion and are in communication. When the gas flows through the communication opening, the gas contacts the surfaces of the two electrode films.
As shown in FIG. 20, the upper and lower sides of the solid electrolyte cell are sandwiched between gas separation / distribution plates 301 and 302, and further, the gas separation / distribution plates 301 and 302 are stacked, and the heater plate 306 is sandwiched between the two solid electrolyte cells. By stacking in the same manner, an oxygen pump module having a plurality of solid electrolyte cells can be manufactured.
[0108]
FIG. 23 is an exploded perspective view showing details of the heater plate 306 in the third embodiment. In FIG. 23, the heater portion 361 is formed of a metal thin film and has two heat generation pattern portions in a zigzag state. The two heat generating pattern portions are configured to have a high temperature. Openings 362a and 362b are formed at both ends of the heater portion 361, and terminal portions 363 and 364 having these openings 362a and 362b are continuously provided. The heater plate 306 is configured such that the heat generation pattern of the heater portion 361 is sandwiched from above and below by heat-resistant insulating substrates 365a and 365b.
The heat-resistant insulating substrates 365a and 365b are formed with a plurality of openings 366 at positions corresponding to the heating element pattern portions so that heat from the heater portion 361 is directly radiated to the solid electrolyte plate. Improvements are being made.
[0109]
Openings 367a to 367f and 368 and 369a to 369f and 370, which are independent for the gas supply / discharge paths, are formed in the outer peripheral portions of the heat-resistant insulating substrates 365a and 365b.
As the material of the heater part 361, a stainless steel metal thin film, particularly a stainless steel material containing aluminum is effective. In other words, since aluminum forms an oxide at a high temperature and the oxide is in a stable state, it has a function of suppressing the progress of oxidation of the resistance foil, and a heating element portion having a small resistance value variation even when used for a long time. realizable. Further, according to the experiment by the inventors, the thickness of the resistor in the heater portion 361 is preferably 30 μm to 200 μm, and particularly the thickness of 50 μm to 100 μm was optimal as the resistor of the oxygen pump of the present invention. .
[0110]
FIG. 24 is an exploded perspective view showing a state during the assembly of the oxygen pump module in the third embodiment. In FIG. 24, the portion of the laminated body indicated by reference numeral 375 is the laminated structure shown in FIG. In the oxygen pump module shown in FIG. 24, gas separation / distribution / heat insulation plates 376 and 377 are disposed above and below the laminated structure 375, and metal plates 378 and 379 are disposed outside thereof.
As shown in FIG. 24, the gases 390a and 390b flowing into the oxygen pump enter through openings on both sides of the upper metal plate 378 and pass through openings 391a and 391b on both sides of the gas separation / distribution / heat insulation plate 376. And flows downward in the oxygen pump. Then, the gas rebounded from the inner surface of the lower gas separation / distribution / heat insulation plate 377 on the opposite side (back surface side) passes through the opening 392 in the center of the gas separation / distribution / heat insulation plate 376 and the upper metal plate. It flows out from the opening 393 at the center of 378.
[0111]
No opening is formed at the position (short side position) of the lower gas separation / distribution / heat insulating plate 377 opposite to the openings 391a and 391b (short side position) of the upper gas separation / distribution / heat insulating board 376. In addition, openings through which gas flows are formed on both sides of a position (long side position) rotated 90 ° on a horizontal plane. The gas flow at this time is indicated by reference numerals 395a and 395d. In FIG. 24, a gas flow passing through the opening is similarly generated downward at positions facing the gas flows 395a and 395d (near the long side position).
The gas separation / distribution / heat insulating plates 376 and 377 have a heat insulating function for keeping the inside of the oxygen pump warm and preventing the outer metal plates 378 and 379 from becoming high temperature.
The upper metal plate 378 has five notches 397a, 397b, 397c, 397d, and 398 formed at the four corners and the central portion thereof, and the lower metal plate 379 similarly includes five notches at the four corners and the central portion. Two notches (in FIG. 24, these notches are denoted by reference numerals 401a, 401c, 401d, and 402, and the notch on the far right side is omitted for the sake of illustration). These cutouts are provided with electrode terminals of each solid electrolyte electrode plate and connection terminals for supplying electric power to the heater parts of each heater plate, and are formed for electrical insulation from these connection terminals. ing.
[0112]
FIG. 25 is a perspective view showing a completed state as the oxygen pump module of the third embodiment. In FIG. 25, screws 411 and 412 provided at two corners are electrically connected to one electrode film formed on each solid electrolyte electrode plate, and a screw 413 provided at the center portion is connected to the other electrode film. Is electrically connected. Further, screws 414 and 415 provided at the other two corners of the oxygen pump module are electrically connected to the terminal portions of the heater portions of the respective heater plates.
As shown in FIG. 25, connection terminals 416, 417, 418, 419, and 420 for connecting lead wires are attached to the screws 411, 412, 413, 414, and 415, respectively. The screw shown in FIG. 25 penetrates to the lower end of the laminated structure of the oxygen pump module, and is fastened and fixed by a nut at the lower part.
The oxygen pump of Example 3 is an oxygen pump module in which two solid electrolyte electrode plates are incorporated in parallel in a solid electrolyte cell, and four solid electrolyte cells configured in this way are used. Therefore, the capacity is twice that of the oxygen pump module of the first embodiment.
Note that the metal plate and screw material used in Example 3 are the materials described in Example 1 above, and the metal plate is subjected to a surface treatment, thereby providing a more reliable oxygen pump module. Can be provided.
[0113]
In the oxygen pump module described in the first to third embodiments of the present invention, a rigid metal plate is disposed on the outermost layer on both sides of the laminated structure, and penetrates the laminated structure including the metal plate. The oxygen pump has a structure in which it is fastened and fixed by a screw that does not cause a gas leak with no gap between the laminated substrates of the laminated structure. In particular, since a mica plate is used for the laminated substrate of the laminated structure, the mica plate is pressed with flexibility, so that a laminated oxygen pump module without gas leakage can be provided. In order to further improve confidentiality, there is flexibility between the laminated substrates, and if an electrically insulating gasket is inserted, a further excellent effect can be obtained.
[0114]
Example 4
Next, an oxygen pump module according to Embodiment 4 of the present invention will be described with reference to FIGS. Example 4 relates to a breakage prevention mechanism for a thin solid electrolyte plate having a small bending strength. In the oxygen pump module of the fourth embodiment, the functions of the solid electrolyte cell, the gas separation / distribution plate, and the heater plate described in the oxygen pump module of the first embodiment are substantially the same, and these substrates are laminated. Configured. Therefore, in the description of the oxygen pump module according to the fourth embodiment, differences from the above-described embodiment will be described.
[0115]
As shown in FIG. 26, in Example 4, an electrode film 434 formed on the surface of a square solid electrolyte electrode plate 433 having a side length of 70 mm × 70 mm and a thickness of 0.5 mm is formed on the back surface. A spacer 435 having a diameter of 10 mm is joined to a substantially central portion of the electrode film (not shown). The spacers 435 have substantially the same dimensions (heights) between the spacers 435 and other stacked substrates that are arranged above and below the solid electrolyte electrode plate 433 and stacked.
As an insulating material that can be used in the oxygen pump of the present invention, the thermal expansion coefficient of the solid electrolyte substrate is 10 to 12 × 10 6 as described in Example 1 above.^-6Therefore, materials having a thermal expansion coefficient before and after that can be used. Specifically, the thermal expansion coefficient is 5 to 15 × 10.^-6It is within the range of this, and the material which has insulation can be used. Therefore, the material of the spacer 435 has a thermal expansion coefficient of 5 to 15 × 10.^-6The material is not limited as long as the material is within the range. Specific materials for the spacer 435 include insulating materials such as 94 to 96% alumina, steatite, forsterite, and glass (including crystallized glass), or metal materials having a thermal expansion coefficient within the above-described range. Can be used. Each material may be dense, but more preferably a porous material.
In Example 4, the bonding of the spacers 435 was performed using various inorganic adhesives such as the various conductor pastes, glass pastes, and the above-described Aron ceramics described in Example 1 above.
[0116]
In addition, although the shape of the spacer 435 in Example 4 was demonstrated with the column shape, in this invention, it is not limited to a column shape, For example, various shapes, such as a square pole and a barrel shape, can be used.
Further, the number of the spacers 435 in Example 4 has been described in the example in which one is provided in the central portion of the solid electrolyte electrode plate 433. However, a plurality of spacers 435 may be provided to pursue more certainty. The number may be determined according to the dimensions of the electrode plate.
As described above, by providing the spacers on both sides of the solid electrolyte electrode plate as shown in FIG. 26, even if excessive vibration or impact is applied to the oxygen pump, the vibration is absorbed by the spacer and the solid electrolyte is absorbed. It is possible to prevent the electrode plate from being damaged.
The spacer in the present invention is not limited to a cylinder or a prism, and a rectangular porous plate having a size substantially equal to the electrode of the solid electrolyte electrode plate is more preferable. As the material, for example, zirconia foam material of Mitsubishi Materials Corporation, foam metal material of the company, etc. are suitable.
[0117]
FIG. 27 is a perspective view for explaining another damage prevention mechanism of the solid electrolyte electrode plate 433 in the fourth embodiment.
In FIG. 27, reinforcing materials 437 and 438 made of a material having a high bending strength are attached to both surfaces of the solid electrolyte electrode plate 433. In FIG. 27, the reinforcing material is attached to both sides, but a configuration in which the reinforcing material is attached to only one side is also possible.
As the reinforcing materials 437 and 438, 94 to 96% alumina, crystallized glass, or the aforementioned nickel alloy, cobalt alloy, nickel-cobalt alloy, iron alloy, or the like is optimal. According to the inventor's experiment, the dimensions of the reinforcing members 437 and 438 were preferably 5 mm width and 0.635 to 1 mm thickness for the ceramic material, and 5 mm width and 0.3 to 0.5 mm thickness for the metal material. In particular, in the case of a metal material, it was more effective when processed into an L shape.
The mounting locations of the reinforcing members 437 and 438 were applied to the entire length of the substrate exposed on the center line of the solid electrolyte electrode plate, and a cross shape orthogonal to the front and back of the solid electrolyte electrode plate was effective. In the case of one side, the reinforcing material was applied to the entire length of the substrate exposed on the center line of the central portion of the solid electrolyte electrode plate. The attachment angle of the reinforcing material may be a direction parallel or orthogonal to each side of the rectangular solid electrolyte cell, or an oblique direction having an angle of 45 degrees.
According to the oxygen pump of Example 4 configured as described above, the solid electrolyte electrode plate is prevented from being damaged even when excessive vibration or impact is applied, and a highly reliable oxygen pump is provided. be able to.
[0118]
As described above, the oxygen pump of the present invention has a laminated structure in which a plurality of solid electrolyte electrode plates are laminated, and a heater plate is disposed between the laminated substrates in the laminated structure. The oxygen pump of the present invention configured as described above operates at a relatively low temperature, and can generate a relatively high concentration of oxygen without generating dangerous byproducts. In particular, the oxygen pump of the present invention is used as an oxygen concentrator in a place such as a hospital where noise is hated, as an oxygen remover in an apparatus that hates oxygen in food storage such as a refrigerator, etc. It can be effectively used as an oxygen replenishing device, or as a device used in other places where a gas having a high oxygen concentration is required or on the contrary, a place requiring a gas having a low oxygen concentration.
[0119]
In the present invention, the material of the gas separation / distribution plate, gas separation / distribution / heat insulation plate, or heater plate is not limited as long as it has heat resistance and electrical insulation. For example, for ceramic materials, there is a large temperature difference between the temperature near the anode electrode film surface and the cathode electrode surface and the temperature at the outer peripheral portion, so that materials with extremely large thermal expansion coefficients may be destroyed due to temperature differences within the material. It cannot be used because there is. However, the thermal expansion coefficient is 5 × 10^-6~ 15 × 10^-6A material in the range of, for example, mullite (3Al2O3 · 2SiO2) thermal expansion coefficient; 5 × 10^-6Or steatite (MgO.SiO2) coefficient of thermal expansion; 7-9 × 10^―6Or forsterite (2MgO.SiO2) coefficient of thermal expansion; 9 to 11 × 10^-6Or alumina (92-96Al2O3) coefficient of thermal expansion; 7-8 × 10^-6Or mica material, coefficient of thermal expansion; 10-12 × 10^-6Or other glass or ceramic materials with a thermal expansion coefficient of 5-15 × 10^-6A material within the range can be used as the optimum material. Particularly preferred is a mica material. Mica material is an effective material because it is strong in bending force, heat resistant, and excellent in electrical insulation.
[0120]
Moreover, since the material of the metal rod which has the screw for electric power supply, and the nut for clamp | tightening is used in a high temperature oxidation atmosphere, it is restrict | limited to the material which has the outstanding oxidation resistance. For example, as the material, stainless steel, nickel alloy, cobalt alloy, nickel-cobalt alloy, iron alloy, or the like, which is the same material as the metal plate that is the outermost layer of the laminated structure described above, is effective. Particularly preferably, nickel such as Hastelloy, Inconel, Incoloy, and Invar, cobalt-based alloy, nickel-cobalt alloy, etc., which have excellent oxidation resistance and a small thermal expansion coefficient, are effective. Also, since it is used in a high-temperature oxidizing atmosphere, the surface of the metal bar or nut is covered with a material that is difficult to oxidize such as platinum, gold, silver, aluminum, nickel, palladium, etc. Reliability can be greatly increased.
[0121]
Moreover, as a material of the sandwiched electrode plate sandwiching the solid electrolyte electrode plate or the metal plate that is the sandwiched plate, it can be used in a high temperature oxidizing atmosphere, and in addition, it is springy even at a high temperature state, that is, an anode electrode film and a cathode electrode film. There is a demand for a material that does not deteriorate the force of pressing. Metal materials that can withstand such use include nickel alloys such as Hastelloy X (Fe; 18%, Cr; 22%, Mo; 9%, Ni; Balance) thermal expansion coefficient of Mitsubishi Materials Corp .; 14.7 × 10^-6And MA750 (Fe; 7%, Cr; 15%, Al; 0.7%, Ni; Balance) thermal expansion coefficient; 14 × 10^-6And MA263 (Co; 20%, Cr; 20%, Mo; 5.9%, Al; 0.5%) coefficient of thermal expansion; 13.3 × 10^-6A material referred to as Inconel, or a cobalt alloy, for example, Haynes Alloy No. 25 (Ni; 10%, Cr; 20%, W; 15%, Co; Balance), a thermal expansion coefficient of Mitsubishi Materials Corporation; 13.9 × 10^-6Etc., iron alloys such as MA800H (Ni; 32.5%, Cr; 21%, Al; 0.5%) of Mitsubishi Materials Corp. 16.6 × 10^-6MA155N (Ni; 20%, Co; 20%, Cr; 21%, Mo; 3%, W; 2.5%) 15.6 × 10^-6Or a nickel-cobalt alloy, for example, 42 invar ((Ni + co); 41 to 43%, Mo; 0.9 to 1.3%, Fe; Balance) thermal expansion coefficient; 4.5-6 × 10^-6Of low thermal expansion coefficient, or stainless steel, such as SUS310S (Ni; 19-22%, Cr; 24-26%, Fe; Balance), thermal expansion coefficient; 16.9 × 10^-6The material was optimal. In addition, said content is a value when weight% and a thermal expansion coefficient are normal temperature-500 degreeC. That is, when heat treatment is performed under the heat treatment conditions peculiar to each material, it exhibits a spring property at a normal temperature to 600 ° C., has electrical conductivity, and has a thermal expansion coefficient of 4 × 10 4 in the above temperature range.^-6~ 20x10^-6As long as it is a material within the range, any material can be used as the material of the metal plate of the present invention without being limited to the above materials.
[0122]
The thickness of the sandwiched electrode plate sandwiching the solid electrolyte electrode plate or the metal plate that is the sandwiched plate may be 0.1 mm to 0.5 mm, and preferably 0.15 mm to 0.3 mm. If the thickness of the metal plate is less than the above range, the spring pressure is too small and an unstable element occurs in the electrical contact. Conversely, if the thickness is thicker than the above range, the spring pressure is too strong and the two upper and lower metal plates are welded together. The solid electrolyte electrode plate may be damaged, and in the worst case, the solid electrolyte electrode plate may be damaged.
By constituting the sandwich electrode plate and the sandwich plate with the above materials, the difference in expansion and contraction of the material due to the difference in thermal expansion coefficient from the solid electrolyte electrode plate is small, and the expansion and contraction is the same as that of the sandwich electrode plate. It can absorb by the slip in the contact part between the solid electrolyte electrode plates. This was confirmed by the inventors through experiments.
[0123]
As described above, the material of the sandwiched electrode plate needs to be used after being subjected to a heat treatment specific to each material in order to have a spring property at a high temperature. Particularly preferred are nickel and cobalt alloys such as Hastelloy, Inconel, Incoloy, and Invar, which have excellent oxidation resistance, have a thermal expansion coefficient close to that of the solid electrolyte plate material, and are less likely to deteriorate even at high temperatures. It is. In addition, since the sandwiched electrode plate is used in a high-temperature oxidizing atmosphere, platinum, gold, silver, aluminum, nickel, palladium, or other material that is difficult to oxidize on the entire surface of the sandwiched electrode plate or a part of the necessary part As a result, the reliability of the electrical connection portion is greatly improved. Particularly preferably, gold plating is effective as the covering material. According to the inventor's experiment, in the case of gold plating, the thickness of the plating was about 0.5 to 1.0 μm, and the function of a sufficient antioxidant film was shown.
In the above-described first embodiment, the example in which the heater plate is provided in the laminated structure has been described. However, an oxygen pump that does not require a heater plate is provided by preheating the gas flowing into the laminated structure. Is possible.
[0124]
Further, in the above-described embodiment according to the present invention, the structure of the oxygen pump using the square solid electrolyte electrode plate has been described. However, the power is supplied by sandwiching the solid electrolyte electrode plate with the sandwich electrode plate. Is applied, the shape of the solid electrolyte electrode plate is not limited to a square, and for example, it can be applied to a rectangle and other polygons without any problems.
Further, in the above-described embodiment according to the present invention, the oxygen pump in which four solid electrolyte cells are stacked has been described. However, the present invention is not limited to such a configuration, and even one solid electrolyte cell is used. Needless to say, the present invention can be applied to the case of five or more sheets.
[0125]
Furthermore, in the above-described embodiment according to the present invention, the electrical connection structure by the contact between the sandwiched electrode plate and the solid electrolyte electrode plate has been described, but the metal film having spring property is used to press-contact the electrode film. A connecting method is also possible, and if the airtightness at the connecting portion of the metal wire is ensured, it can be put into practical use immediately.
Further, in the above-described embodiment according to the present invention, the structure in which the electrical connection for supplying power to the anode electrode film and the cathode electrode film of the solid electrolyte cell is performed at the four corners of the laminated structure has been described. The present invention is not limited to the four corners, and can be realized immediately by partially changing the position of the gas flow path in other parts.
[0126]
Further, in the above-described embodiment according to the present invention, the method of supplying power by electrically connecting at two locations of the solid electrolyte cell has been described, but the present invention is based on such a power supply method by connecting at two locations. For example, if a three-point connection method is used, two places are connected so that the entire solid electrolyte can be energized, and the remaining one place is connected to a part of the solid electrolyte. It is possible to realize an oxygen pump that can drive a solid electrolyte cell of this type or that can drive only some of the solid electrolyte cells. By comprising in this way, it becomes possible to provide the oxygen pump which can select the capability of an oxygen pump.
Further, in the above-described embodiment according to the present invention, the oxygen pump in which the electrode surface of the solid electrolyte cell is in the horizontal direction has been described. However, the inventor has confirmed through experiments that there is no problem in any direction. .
[0127]
Further, in the above-described embodiments according to the present invention, the gas supply / discharge channel structure in which the anode electrode or the cathode electrode is sealed has been described. However, the present invention is not limited to the sealed structure, and for example, the oxygen concentration When low air is required, the gas supply / discharge path on the anode electrode side can be structured to communicate with the space outside the laminated structure, and when high oxygen concentration air is required, the cathode electrode The gas supply / discharge passage on the side can be structured to communicate with the space outside the laminated structure. By comprising in this way, the gas supply pump for sending air becomes unnecessary, and it becomes possible to fully comprise an oxygen pump with a small capacity blower.
[0128]
In the above-described embodiments, the oxygen pump is mainly described. However, when the oxygen pump is actually used, it is preferable to connect the oxygen pump to a heat exchanger. A heat exchanger is connected to the oxygen pump, the high temperature gas flowing out from the oxygen pump is led to the heat exchanger, and the gas flowing into the oxygen pump is warmed in the heat exchanger, thereby preventing the temperature drop of the solid electrolyte cell. As a result, it is possible to improve the oxygen concentration or oxygen removal capability, reduce the burden on the heater section, and achieve an energy saving effect. There are no restrictions on the heat exchanger used here, either an aluminum honeycomb structure constructed by alternately changing the angle at the same angle, or a type in which radiating fins with high thermal conductivity are attached to a thermally conductive tube A general heat exchanger can be used.
The oxygen pump of the present invention is a thin plate of perovskite Ba-Ce-Gd-O-based oxide, Ba-Ce-Gd-Zr-O-based oxide, or Ba-Ce-Gd-Al-O-based oxide ceramics. Although the oxygen pump using the solid electrolyte has been described, the present invention is not limited to the above composition, and it is of course possible to configure the oxygen pump of the present invention using a solid electrolyte of another composition. That is, the present invention can be applied to an oxygen pump using any solid electrolyte as long as the driving temperature of the solid electrolyte is within a limit that can maintain the spring property of the sandwiched electrode plate to be used.
[0129]
As described above, since the structure of the present invention has a structure in which solid electrolyte cells are stacked, a small and highly efficient oxygen pump module can be realized, and a gas supply / exhaust path is built in the oxygen pump module. It is more airtight and can be downsized compared to the conventional method of retrofitting a manifold.
[0130]
According to the configuration of the present invention, the gas supply / exhaust passage for the two gas flows is formed in the solid electrolyte cell, and the gas separation / distribution plates arranged on both sides of the solid electrolyte cell are provided, This is an oxygen pump capable of isolating the gas stream enriched from the gas stream from which oxygen has been removed with a simple configuration. In particular, the present invention is effective as an apparatus for concentrating or removing oxygen in the air. According to the present invention, since the solid electrolyte cell and the gas separation / distribution plate are thin plate-like, the oxygen pump module can be produced in a compact manner even if the solid electrolyte cell and the gas separation / distribution plate are constituted by a plurality of laminated structures.
[0131]
The oxygen pump of the present invention is a stacked oxygen pump and incorporates a heater plate. In an oxygen pump, oxygen receives electrons at the interface between the solid electrolyte and the cathode electrode, and O₂-In the reaction that becomes an ion, moves inside the solid electrolyte, emits electrons at the interface between the solid electrolyte and the anode electrode, and becomes oxygen gas, the conductivity of the solid electrolyte is important. In yttrium-stabilized zirconia, which is a general solid electrolyte, Unless it is heated to 800 ° C. or higher, a practical oxygen pump cannot be produced. That is, even if an oxygen pump module is manufactured, how to heat the solid electrolyte in the oxygen pump module to the operating temperature is the key to practical use. In particular, it was a big problem when the purpose was to provide a small and portable oxygen pump module. In the oxygen pump of the present invention, since the plate-shaped heater plate is disposed in the vicinity of the solid electrolyte cell and in parallel with the solid electrolyte cell, the solid electrolyte can be easily heated to the operating temperature. In particular, in the oxygen pump of the present invention using the barium-cerium-gadolinium-based oxide, which is a novel solid electrolyte, a practical operating temperature is achieved when heated to about 400 ° C., so the object of the present invention is sufficiently achieved by the configuration of the present invention. be able to.
[0132]
In the oxygen pump according to the present invention, the solid electrolyte electrode plate and the solid electrolyte electrode plate are separated from each other, the two gas flows are separated, and the gas separation / distribution plate and the heater plate for preventing gas leakage are all sheets. Gas supply / discharge passages are formed in each outer peripheral portion by independent openings or openings communicating as open gas passages, and gas or air inflow passages, oxygen-concentrated or removed gas Or the compact oxygen pump which integrated the outflow path for discharging | emitting air can be provided.
[0133]
In the oxygen pump of the present invention, since the same poles are arranged facing each other in a state where a plurality of solid electrolyte electrode plates are laminated, a space portion connected to the gas supply / discharge path can be used in common. For this reason, the number of gas distribution / separation plates used is the minimum number, and the configuration is compact. In addition, since a method of supplying power to the electrode film using a sandwiched electrode plate is used, if the same poles face each other, a metal rod is penetrated in a stacked state and the sandwiched electrode plate is connected to it. By this method, electric power can be supplied to all anode electrode films and cathode electrode films.
[0134]
Since the oxygen pump of the present invention is formed by shifting the positions of the electrode films formed on both surfaces of the solid electrolyte electrode plate, the configuration is such that the solid electrolyte electrode plate is sandwiched between the two sandwiched electrode plates to supply electric power. It is possible. That is, one sandwiched electrode plate is in contact with the end of the electrode film, but the other sandwiched electrode plate can be in a state of not contacting the electrode film. As a result, electric power can be supplied to each of the anode electrode film and the cathode electrode film in an insulated state in the same plane of the solid electrolyte electrode plate.
[0135]
Since the oxygen pump of the present invention can be configured as a solid electrolyte plate by attaching a small-area circular or rectangular solid electrolyte electrode plate to an insulating substrate, the production of the solid electrolyte electrode plate is easy. That is, a highly difficult technique is required to produce a flat solid electrolyte electrode plate having a large area. Furthermore, for the purpose of operating the solid electrolyte at a lower temperature, it is common to make the plate thickness thin to increase the conductivity, and in fact, it is used by reducing the plate thickness to about 0.5 mm. . In order to make it thinner, a method of forming a solid electrolyte membrane of several tens of μm on a porous support substrate having electron conductivity has also been adopted. However, a solid electrolyte plate having a large area can be formed without using a support substrate. Although it is difficult to manufacture, a large substrate can be easily manufactured by using a configuration in which a plurality of solid electrolyte plates having a small area are arranged as in the present invention. Of course, it is also possible to apply what formed the thin solid electrolyte in the electron conductive porous support body to this invention.
[0136]
The oxygen pump of the present invention is configured to supply power to the anode electrode film or the cathode electrode film by sandwiching two sandwiched electrode plates from both sides, and the positions of the conductor film patterns on both sides of the solid electrolyte substrate are different. Since the conductor film pattern is formed with a wide interval from the end portion and the back surface having a narrow interval from the end portion, even if the conductive film pattern is sandwiched between the sandwiched electrode plates, the conductor is connected to the sandwiched electrode plate on the wide side. Therefore, it is possible to realize a configuration in which power is supplied to the anode electrode and the cathode electrode in the same plane. In the present invention, since a material having a high bending strength can be selected as the heat resistant insulating substrate, a solid electrolyte cell resistant to vibration and impact can be realized.
[0137]
The oxygen pump according to the present invention has an opening for gas supply / discharge passage formed on the outer periphery of the solid electrolyte substrate itself, and an anode electrode and a cathode electrode which are shifted from each other are formed on both surfaces of the central portion. It has a structure in which the electrolyte substrate is pressed from both sides with a sandwich electrode plate. According to this configuration, since the solid electrolyte electrode is disposed between the two sandwiched electrode plates that are in pressure contact with each other, the oxygen-concentrating side and the oxygen-extracting side can be completely isolated, and the oxygen pump has high airtightness. Can provide.
[0138]
The oxygen pump according to the present invention is an anode electrode film or cathode electrode in which one end of one sandwiched electrode plate of two sandwiched electrode plates that retains a spring property even at a high temperature is formed on one surface of a solid electrolyte electrode plate A structure in which one end of the other sandwiched electrode plate is sandwiched and connected so as to be in contact with the membrane, and is sandwiched and attached so as to be in contact with the cathode electrode film or the anode electrode film formed on the other surface of the solid electrolyte electrode plate. is there. According to this configuration, the electrical connection state is maintained by the pressure contact of the sandwiched electrode plate having a spring property even at a high temperature, and the connection portion does not come off due to the difference in the thermal expansion coefficient of the material. The difference in thermal expansion is absorbed by the displacement of the contact portion to maintain contact, and a state in which there is almost no internal stress in the connection portion can be realized. In addition, according to the present invention, both sandwiched electrode plates are joined by spot welding, and since the connection is a physical method, an assembly method using a mechanical method is realized, which can greatly contribute to a reduction in manufacturing cost.
[0139]
In the oxygen pump of the present invention, the sandwiched electrode plates attached to both ends of the opposite sides of the solid electrolyte electrode plate can be connected to the electrode films on both sides of the solid electrolyte electrode plate while maintaining electrical insulation, A highly reliable structure in which the anode electrode and the cathode electrode are not short-circuited can be realized.
[0140]
In the oxygen pump of the present invention, the sandwich electrode plate for power supply has a thermal expansion coefficient of 4 × 10.^-6~ 20x10^-6The solid electrolyte cell using the metal material in the range is used. The power supply method of the present invention is a structure that uses the spring property of a metal plate and keeps electrical contact by pressing with the spring force, so even if there is a difference in thermal expansion coefficient between materials, it slips at the contact part, so the connection state Will not come off. The greatest advantage of this is that it can be used in the present invention basically without any major problems as long as it is a material having oxidation resistance at room temperature to 500 ° C. and retention of spring properties, and there is a wide range of material selection. It can be taken. As described above, the range of the thermal expansion coefficient of the metal material that can be used in the present invention is 4 × 10.^-6~ 20x10^-6  Any material can be used without any problem as long as it has a heat resistance within the range of the above and maintains a spring property at a high temperature. For materials with a coefficient of thermal expansion greater than or less than that, the difference in thermal expansion from other materials to be laminated becomes too large, and repeated heating and cooling will cause deformation stress in the oxygen pump module itself, resulting in gaps in the laminate. It adversely affects gas tightness. However, when the sandwiched electrode plate is configured to contact from above and below with a small metal plate or metal wire, a metal material having a wider thermal expansion coefficient can be used.
[0141]
The oxygen pump of the present invention is a solid electrolyte cell in which the power supply metal plate is formed of an iron alloy plate, a nickel alloy plate, a cobalt alloy plate, a nickel-cobalt alloy, or a stainless steel plate. As a result of examination by the inventor within the range of a desired thermal expansion coefficient and taking into consideration oxidation resistance, spring retention, etc., it has been found that the alloy material is optimal. Further, in the present invention, the sandwiched electrode plate has a smaller thermal expansion coefficient than other metal plates and uses less progress of oxidation even in a high-temperature oxygen atmosphere, thereby realizing a highly reliable power supply means. it can. Further, the sandwiched electrode plate can maintain a spring property at a high temperature by forming a metal thin plate in a desired environment and subjecting the metal material to a heat treatment at an optimum temperature. By forming the sandwiched electrode plate using such a metal material, the contact pressure of the contact portion does not deteriorate, in other words, the electrical connection state can be maintained satisfactorily.
[0142]
The oxygen pump of the present invention is a solid electrolyte cell in which a gold, silver, nickel, or aluminum film is formed on the entire surface or a part of one surface or both surfaces of a power supply metal plate. Since the metal plate for power supply forms a metal film that is difficult to oxidize on the surface of the thin metal plate, it can provide a highly reliable device that does not increase the electrical resistance of the contact portion even in a high-temperature oxidizing atmosphere, In particular, the inventors have confirmed that a gold plating film having a thickness of 0.5 μm or more can be used stably.
[0143]
In the oxygen pump of the present invention, the gas flow that flows on the oxygen concentration side and the oxygen removal side in the stack can be configured to be introduced in parallel or in series to each solid electrolyte cell. When a low-temperature gas is introduced by a plurality of solid electrolyte cells, the temperature of each solid electrolyte cell is lowered in the same manner, so that the temperature control of each solid electrolyte is easy. In addition, the inflow side (in side) or outflow side (out side) of the oxygen enrichment side and the oxygen removal side can be freely selected to be attached to the same side or the opposite side. When designing the device, the design becomes easy.
[0144]
In the oxygen pump of the present invention, when the gas is flowed in a series system, the gas sequentially flows through each solid electrolyte cell, so that concentrated oxygen or reduced oxygen can be taken out reliably. In the parallel system, if the same amount of gas is distributed or recovered to each solid electrolyte cell, the gas supply / exhaust channel opening area and the area ratio of the opening flowing into the solid electrolyte cell must be selected appropriately. A large amount of gas flows only into the solid electrolyte cell, imbalance occurs and 100% generated oxygen cannot be taken out, and the solid electrolyte cell into which a large amount of gas flows is further cooled, so that the capacity of the solid electrolyte decreases.
[0145]
The oxygen pump of the present invention can constitute a combined system of a parallel gas flow and a serial gas flow by flowing either one of the gas flows in parallel and the other in series. It has an intermediate characteristic between the system and the series system, and if a series system is introduced on the required gas inflow side, performance close to the series system can be obtained.
[0146]
The oxygen pump of the present invention can be configured to switch the gas flow to a parallel system or a serial system, and can easily change the inflow direction and the outflow direction of the gas flow. As a result, the gas outflow direction of the oxygen concentrator or oxygen remover using the oxygen pump of the present invention can be changed, and the design of the apparatus becomes easy.
The oxygen pump of the present invention has a structure in which the gas flow can be easily changed to a parallel system or a serial system by inserting a heat-resistant plate having substantially the same shape as the gas channel opening. is doing.
[0147]
The oxygen pump of the present invention has a thermal expansion coefficient of 5 × 10 5 for the gas separation / distribution plate, gas separation / distribution / heat insulation plate, and heater plate material.^-6~ 15 × 10^-6It is formed using a heat-resistant and insulating material within the range. As described above, the thermal expansion coefficient of the solid electrolyte material used for the oxygen pump of the present invention is 10 to 12 × 10.^-6Therefore, the inventor has confirmed that if a heat-resistant insulating material having a thermal expansion coefficient is used, it functions as an oxygen pump without any problem even if thermal shock is frequently applied. If the thermal expansion coefficient is smaller or larger than the above range, excessive stress is generated in the solid electrolyte, and in the worst case, the solid electrolyte plate may be damaged.
[0148]
In the oxygen pump of the present invention, the gas separation / distribution plate, the gas separation / distribution / heat insulation plate, and the heater plate are formed using mica or / or a ceramic material and / or a glass material. The thermal expansion coefficient between room temperature and 500 ° C. is 11 × 10 for mica material^-6The majority of ceramic materials are within the aforementioned coefficient of thermal expansion and can be used. Among them, particularly excellent materials were mica, 90 to 95% alumina, forsterite and steatite. In particular, the mica plate can be fastened with a screw through a rigid metal plate from above and below, and an oxygen pump structure with less gas leakage can be easily constructed.
[0149]
In general, an oxygen pump using a solid electrolyte needs to be heated to a temperature at which the solid electrolyte can be driven by a heater plate, that is, ion conduction occurs, and the temperature is determined by the material of the solid electrolyte. A zirconia-based material stabilized with yttrium that is generally used has a temperature of 800 ° C. or higher. The solid electrolyte used for the oxygen pump of the present invention is a material that exhibits sufficient ion conductivity at a temperature lower than that of a conventional zirconia-based material, and a heating temperature of 300 ° C. to 500 ° C. is sufficient. Therefore, in the present invention, the heater plate has a structure in which a patterned metal resistance foil is sandwiched between mica plates, and has a gas supply / exhaust passage on its outer peripheral portion, and is configured to supply power from another position on the outer peripheral portion. It is possible to realize a compact oxygen pump with a built-in heater by stacking together with the aforementioned solid electrolyte constituent cells. However, the present invention is not limited to the mica plate as the material of the heater plate, and any material within the above-described range of the thermal expansion coefficient and having heat resistance insulation can be used. However, in particular, the excellent material was mica board.
[0150]
In the oxygen pump of the present invention, the anode and cathode electrodes of each solid electrolyte and the heater terminals of the heater plate are passed through the laminate from four sides or four corners of the laminate having a rectangular shape and through a metal rod-like body. Therefore, a very compact and highly reliable power supply structure can be realized. In the present invention, since all the materials for supplying power are made of a metal material, it is possible to realize a connection structure that is easy to assemble and has high reliability.
[0151]
In the oxygen pump of the present invention, a rod-like body made of an electrically conductive material is inserted through the laminate, and each terminal portion of the power supply metal plate connected to the solid electrolyte and the heater portion is a nut. As a result of being tightened and connected, a reliable electrical connection is guaranteed. Further, according to the present invention, since the rod-shaped body is made of an iron alloy, nickel alloy, cobalt alloy, or stainless steel, the thermal expansion coefficient is close to that of the material used for the laminated body. It is possible to realize an oxygen pump that does not cause thermal distortion of the entire pump and does not leak gas from the interface of the stacked portions. In particular, by using a screw or nut that is coated with gold, silver, nickel, or aluminum, the electrical resistance of the connecting portion does not increase, and a stable connection can be guaranteed over a long period of time.
[0152]
In the oxygen pump of the present invention, the outermost gas supply / discharge metal plate of the oxygen pump is formed of a rigid material made of an iron alloy plate, a nickel alloy plate, a cobalt alloy plate, a nickel-cobalt alloy, or a stainless steel plate. The gas supply port and the discharge port are arranged at positions where the gas supply / exhaust port metal plates are disposed on both surfaces of the outermost layer of the laminate and communicate with the gas supply / discharge passage of the laminate at both ends of the gas supply / discharge port metal plate. Is formed. Since the oxygen pump configured in this way has a structure in which the laminate is fastened with a rigid metal plate from above and below, the gas at the interface of the laminate does not leak, and the gas supply / exhaust metal plate does not leak gas. Since the inflow port and the discharge port are formed, the oxygen-enriched gas or the reduced gas can be easily taken out simply by connecting a heat-resistant pipe or the like. In the present invention, since the material used as the gas supply / exhaust metal plate approximates the thermal expansion coefficient of the ceramic material or solid electrolyte material, internal stress due to thermal strain is unlikely to accumulate between the materials, and A highly reliable oxygen pump with little body deformation can be provided.
[0153]
In the oxygen pump of the present invention, the solid electrolyte has a perovskite-type barium / cerium / gadolinium-based oxide ceramic material, barium / cerium / gadolinium / zirconium-based oxide material, or barium / cerium / gadolinium / aluminum-based material. It is made of oxide. Since the solid electrolyte material used in the oxygen pump of the present invention has a temperature at which the solid electrolyte is driven, that is, a temperature at which ion conduction occurs, is 300 ° C. or higher, the sandwiched connection method with a sandwiched electrode plate in the present invention, a mica plate, etc. It becomes usable and a compact oxygen pump can be realized.
[0154]
In the oxygen pump of the present invention, at least one spacer or reinforcing plate is attached to one side or both sides of the solid electrolyte electrode plate, so that the vibration or impact of the solid electrolyte electrode plate is absorbed and destroyed. Can be prevented. The spacer used here was attached so as to have a desired interval with the gas separation / distribution / heat insulation plate, heater plate, or other solid electrolyte electrode plate contacting both surfaces of the solid electrolyte electrode plate when laminated. Is. One or more spacers may be provided on both surfaces of the solid electrolyte electrode plate. The reinforcing material has a structure in which a reinforcing material is attached to one side or both sides of a solid electrolyte electrode plate. In the oxygen pump of the present invention configured as described above, even if vibration or impact is applied to the solid electrolyte electrode plate, the spacer or the reinforcing material suppresses the vibration of the solid electrolyte electrode plate, thereby preventing the destruction of the solid electrolyte electrode plate. Can do.
[0155]
【The invention's effect】
As is apparent from the detailed description of the embodiments, the present invention has the following effects.
In the oxygen pump of the present invention, as described in the above-described embodiments, the electrodes are connected to the electrode films formed on both surfaces of the solid electrolyte electrode plate. The metal plate has a structure in which the tip of the metal plate is brought into pressure contact with the electrode film of the solid electrolyte electrode plate by utilizing the spring property of the metal plate having a chemical property. Since the oxygen pump using a solid electrolyte ceramic plate is configured to drive the oxygen pump at a high temperature, select a material with a thermal expansion coefficient close to the material used for the oxygen pump, and it can be broken or electrically contacted by thermal strain. It is necessary to prevent defects. In the oxygen pump of the present invention, since the electrode connection structure is configured to press-contact the electrode surface using the spring property of the metal plate, even if there is a difference in thermal expansion between the materials of each component, The difference in thermal expansion is absorbed by the shift in the contact portion. As a result, according to the oxygen pump of the present invention, since distortion in each component can be alleviated, breakdown or poor contact may occur at the connection portion between the electrode film portion of the solid electrolyte cell and the power supply portion. In addition, an oxygen pump having a highly reliable electrode connection structure can be provided.
[0156]
Further, the oxygen pump of the present invention includes a Ba-Ce-Gd-O-based oxide, a Ba-Ce-Gd-Zr-O-based oxide, or a Ba-Ce-Gd-Al-O-based oxide ceramic plate. Therefore, the oxygen pump can be driven at a temperature of 500 ° C. or lower. As a result, in the oxygen pump of the present invention, the electrode connection structure described in the embodiments can be used, and a highly reliable oxygen pump can be provided.
In the oxygen pump of the present invention, a solid electrolyte electrode plate is sandwiched by sandwiched electrode plates to form a single solid electrolyte cell, and gas separation / distribution plates and heater plates are arranged above and below the solid electrolyte cell. Since the substrates are stacked, a very compact oxygen pump can be provided.
[0157]
Furthermore, in the oxygen pump of the present invention, a gas supply / discharge path is formed in the outer peripheral portion of each substrate of the solid electrolyte cell, gas separation / distribution plate, and heater plate, and oxygen is concentrated in these gas supply / discharge paths. Each of the air and the air in which oxygen is reduced flows independently and is supplied to the electrode surface of the solid electrolyte cell. Therefore, the oxygen pump of the present invention eliminates the need for the gas supply / exhaust passage manifold portion used in conventional oxygen pumps, and thus has the advantage of reducing the number of attachment joints and facilitating the construction of an airtight structure.
[0158]
Furthermore, in the oxygen pump of the present invention, since the sandwiched electrode plate is connected to the electrode films on both sides of the solid electrolyte cell, the sandwiched electrode plate other than the connection portion between the sandwiched electrode plate and the electrode film is used. The outer peripheral part can be used as a part for supplying power, and the structure of the oxygen pump is a laminated structure, so a metal rod is inserted in the lamination direction into the laminated body and sandwiched between the metal rods By fixing the electrode plate, it is possible to easily supply power, and it is possible to provide a compact oxygen pump with a simple configuration.
[0159]
Furthermore, in the oxygen pump of the present invention, as the material of the sandwich electrode plate which is a metal plate, stainless steel, Ni-Mo-Cr-Fe-W alloy hastelloy, Ni (Ni-Co) -CrFe alloy inconel or Ni Nickel alloys such as incoloy of (Co) -Fe-Cr alloy and invar of Ni-Co-Fe alloy, and iron-based alloys such as cobalt alloy, Fe-NiCr alloy and Fe-Ni-Co-Cr alloy are used. As a result, the sandwiched electrode plate according to the present invention has excellent oxidation resistance and a thermal expansion coefficient close to that of the solid electrolyte ceramic plate. Therefore, in the present invention, the sandwiched electrode plate, the solid electrolyte cell, The reliability of the connection state between is greatly improved. In particular, nickel and cobalt alloys such as Hastelloy, Inconel, Incoloy, and Invar are effective as the material for the sandwich electrode plate. In addition, since the surface of the sandwiched electrode plate according to the present invention is provided with an oxidation resistant coating such as platinum, nickel, silver, gold, aluminum, palladium, etc., the reliability of the connecting portion is further improved.
[0160]
Furthermore, the oxygen pump of the present invention has an electrode connection structure in which the end portion of the solid electrolyte cell is sandwiched by sandwiching electrode plates as described in detail in the embodiments, and is a stacked structure in which a plurality of substrates are stacked. Therefore, a large-capacity oxygen pump can be configured in a compact manner by arranging a plurality of solid electrolyte plates juxtaposed on one solid electrolyte cell and stacking the solid electrolyte cells configured as such.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view showing an oxygen pump according to a first embodiment of the present invention.
FIG. 2 is a perspective view of a solid electrolyte plate in the oxygen pump of Example 1 according to the present invention.
FIG. 3 is an exploded perspective view showing another configuration of the solid electrolyte plate in the oxygen pump according to the first embodiment of the present invention.
4 is a perspective view showing a completed state of the solid electrolyte plate of FIG. 3. FIG.
FIG. 5 is an exploded perspective view showing a joining structure of a sandwiched electrode plate in Example 1 according to the present invention.
FIG. 6 is a perspective view showing a solid electrolyte cell in Example 1 according to the present invention.
7 is a cross-sectional view of the solid electrolyte cell of FIG. 6 taken along line VII-VII.
8 is an exploded perspective view showing another structure of the solid electrolyte cell in Example 1 according to the present invention. FIG.
FIG. 9 is an exploded perspective view showing still another structure of the solid electrolyte cell according to the first embodiment of the present invention.
FIG. 10 is a perspective view showing a gas separation / distribution plate in Embodiment 1 according to the present invention.
FIG. 11 is an exploded perspective view showing a configuration of a heater plate in Example 1 according to the present invention.
FIG. 12 is a cross-sectional view showing a laminated structure of the oxygen pump according to the first embodiment of the present invention.
FIG. 13 is an exploded perspective view showing an assembled state of the oxygen pump according to the first embodiment of the present invention.
FIG. 14 is a perspective view showing a completed state of the oxygen pump according to the first embodiment of the present invention.
FIG. 15 is an exploded perspective view showing an oxygen pump according to a second embodiment of the present invention.
FIG. 16 is an exploded perspective view showing an assembled state of the oxygen pump according to the second embodiment of the present invention.
FIG. 17 is a cross-sectional view showing a laminated structure in an oxygen pump of Example 2 according to the present invention.
FIG. 18 is a cross-sectional view showing another laminated structure in the oxygen pump according to the second embodiment of the present invention.
FIG. 19 is a perspective view showing a gas flow changing block for switching the gas flow used in the oxygen pump shown in FIG. 18;
FIG. 20 is an exploded perspective view showing the oxygen pump according to the third embodiment of the present invention.
FIG. 21 is a perspective view showing a solid electrolyte cell in an oxygen pump of Example 3 according to the present invention.
FIG. 22 is a perspective view of a gas separation / distribution plate in the oxygen pump according to the third embodiment of the present invention.
FIG. 23 is a perspective view showing a heater plate in the oxygen pump according to the third embodiment of the present invention.
FIG. 24 is an exploded perspective view showing an assembled state of the oxygen pump according to the third embodiment of the present invention.
FIG. 25 is a perspective view showing a completed state of the oxygen pump according to the third embodiment of the present invention.
FIG. 26 is a perspective view showing a solid electrolyte cell in an oxygen pump of Example 4 according to the present invention.
FIG. 27 is a perspective view showing another solid electrolyte cell in the oxygen pump of Example 4 according to the present invention.
FIG. 28 is an exploded perspective view showing a conventional oxygen pump.
[Explanation of symbols]
10, 11, 12, 13 Solid electrolyte cell
17 Heater plate
14, 15, 16 Gas separation / distribution plate
22, 92 Solid electrolyte substrate
20, 21, 92 Electrode film
44 Heater
23, 24 sandwiched electrode plate

Claims (29)

A solid electrolyte cell having a plate-like solid electrolyte electrode plate in which different electrodes are formed on both front and back surfaces , and a sandwiched electrode plate for sandwiching an end of the solid electrolyte electrode plate to supply power to the electrode ;
Gas separation / distribution plates disposed on both sides of the solid electrolyte electrode plate;
The gas separation / distribution plate is disposed on one side, and has at least one laminate in which a heater plate serving as a heat source is laminated,
The solid electrolyte cell in the stack, the gas separation and distribution plate, and a plurality of gas supply and exhaust passage gas flows through the respective outer peripheral portion of the heater plate in the stacking direction is formed, the gas Two systems are formed in which the supply / discharge paths do not communicate with each other, and different electrodes are arranged on the gas supply / discharge paths of each system,
A plurality of apertures penetrating in the stacking direction are formed at positions different from the formation positions of the gas supply / discharge passages in the outer peripheral portions of the solid electrolyte cell, the gas separation / distribution plate, and the heater plate. A plurality of rod-like bodies having electrical conductivity penetrating each of the opening portions, and each rod-like body supplies power to each of the electrodes on both the front and back surfaces of the solid electrolyte cell and the heater portion of the heater plate. An oxygen pump configured to supply .   One of the two gas supply / discharge passages sends a gas flow to one electrode surface of the solid electrolyte electrode plate, and the other gas supply / discharge passage sends a gas flow to the other electrode surface of the solid electrolyte electrode plate. The oxygen pump according to claim 1, wherein the oxygen pump is configured as described above.   In a two-system gas supply / discharge path, the gas flow direction on one electrode surface of the solid electrolyte electrode plate and the gas flow direction on the other electrode surface of the solid electrolyte electrode plate flow in a perpendicular direction The oxygen pump according to claim 2, wherein the oxygen pump is provided. The heater plate is configured by sandwiching a resistor pattern formed of a metal foil from both sides with a heat resistant insulating member, and the heat resistant insulating member exposes a part of the resistor pattern. 4. The apparatus according to claim 1, further comprising at least one opening and having two or more openings serving as two systems of gas supply / exhaust passages in an outer peripheral portion of the heat-resistant insulating member. The oxygen pump according to item.   Gas separation / distribution / heat insulation plate for keeping gas by distributing gas to the outermost sides on both sides in the lamination direction of the laminate or a laminate structure in which a plurality of the laminates are laminated, and a metal plate having a gas supply / exhaust port The oxygen pump according to any one of claims 1 to 4, wherein and are laminated.   6. The oxygen pump according to claim 5, wherein in a laminated structure having a plurality of solid electrolyte cells, the electrodes of the solid electrolyte electrode plates arranged opposite to each other have the same pole. The sandwich electrode plate is in contact with an electrode formed on one surface of the solid electrolyte electrode plate by sandwiching one end of the solid electrolyte electrode plate and pressing with an elastic force. An electrode plate;
A second sandwiched electrode plate that sandwiches the other end of the solid electrolyte electrode plate and is in pressure contact with an elastic force to make electrical contact with an electrode formed on the other surface of the solid electrolyte electrode plate; The first sandwiching electrode plate and the second sandwiching electrode plate are configured to supply electric power to different electrodes, respectively. Oxygen pump. The solid electrolyte electrode plate has a rectangular shape, different electrodes formed on both the front and back surfaces of the solid electrolyte electrode plate are constituted by a film body, and one electrode film extends to one end of the solid electrolyte electrode plate. And is configured to be in electrical contact with the first sandwiched electrode plate , the other electrode film extending to the other end of the solid electrolyte electrode plate, and the second sandwiched electrode plate The oxygen pump according to claim 7, wherein the oxygen pump is configured to be in electrical contact . Each of the first sandwiched electrode plate and the second sandwiched electrode plate is composed of at least two metal thin plates sandwiching both front and back surfaces of the end portion of the solid electrolyte electrode plate,
In the two sets of the first sandwiched electrode plate and the second sandwiched electrode plate sandwiching at least two ends of the solid electrolyte electrode plate ,
Surface side of the sheet metal of one set of the first clamping electrode plate is pressed against the surface of the electrode film of the solid electrolyte electrode plates, the back side of the of the one set the first clamping electrode plate The metal thin plate is configured to press-contact the solid electrolyte electrode plate without contacting the electrode film on the back surface side of the solid electrolyte electrode plate,
It was pressed against the solid electrolyte electrode plate without the other set of the front surface of the sheet metal of the second clamping electrode plate in contact with the surface side of the electrode film of the solid electrolyte electrode plate, wherein the said other set The oxygen pump according to claim 7 , wherein a metal thin plate on the back side of the second sandwich electrode plate is configured to press-contact an electrode film on the back side of the solid electrolyte electrode plate. The solid electrolyte electrode plate is a plurality of solid electrolyte substrates in which different electrodes are formed on both front and back surfaces, and
A heat-resistant insulating substrate disposed such that the solid electrolyte substrate exposes the front and back electrodes; and
A conductive pattern that is formed on each of the front and back surfaces of the heat-resistant insulating substrate and electrically connects the electrodes on the front and back surfaces of the solid electrolyte substrate; and
2. The oxygen pump according to claim 1, wherein the conductive pattern is press-contacted by the sandwiched electrode plate and power is supplied to each electrode on both the front and back surfaces of the solid electrolyte substrate . The heat-resistant insulating substrate on which the conductive pattern is formed has a plurality of openings, the solid electrolyte substrate is disposed so as to close the plurality of openings and expose electrodes on both the front and back sides, and the front and back sides of the solid electrolyte substrate 11. The oxygen pump according to claim 10 , wherein the electrodes on both sides and the conductive pattern are connected such that the same surface is the same electrode. The sandwiched electrode plate is in contact with the conductive pattern formed on one surface of the solid electrolyte electrode plate by sandwiching one end of the solid electrolyte electrode plate and pressing with an elastic force. A sandwich electrode plate;
A second sandwiched electrode plate sandwiching the other end of the solid electrolyte electrode plate and being in pressure contact with an elastic force to be in electrical contact with a conductive pattern formed on the other surface of the solid electrolyte electrode plate; The oxygen pump according to claim 11, wherein each of the first sandwiched electrode plate and the second sandwiched electrode plate is configured to supply power to the different electrodes . One of the conductive patterns formed on the front and back surfaces of the solid electrolyte electrode plate is extended to one end of the solid electrolyte electrode plate and is in electrical contact with the first sandwich electrode plate 13. The oxygen according to claim 12 , wherein the other is extended to the other end of the solid electrolyte electrode plate and is in electrical contact with the second sandwich electrode plate. pump. Each of the first sandwiched electrode plate and the second sandwiched electrode plate is composed of at least two metal thin plates sandwiching both front and back surfaces of the end portion of the solid electrolyte electrode plate,
In the two sets of the first sandwiched electrode plate and the second sandwiched electrode plate sandwiching at least two ends of the solid electrolyte electrode plate ,
Surface side of the sheet metal of one set of the first clamping electrode plate is pressed against the surface of the conductor pattern of the solid electrolyte electrode plates, the back side of the of the one set the first clamping electrode plate The metal thin plate is configured to press-contact the solid electrolyte electrode plate without contacting the conductive pattern on the back surface side of the solid electrolyte electrode plate,
Was pressed against the solid electrolyte electrode plate without surface side of the sheet metal of the other set of said second clamping electrode plate is in contact with the conductive pattern on the surface side of the solid electrolyte electrode plate, wherein the said other set The oxygen pump according to claim 12 , wherein the thin metal plate on the back surface side of the second sandwich electrode plate is configured to press-contact the conductive pattern on the back surface side of the solid electrolyte electrode plate. 15. The sandwiched electrode plate is formed of a metal material having a thermal expansion coefficient in a range of 4 × 10 ^{−6 to} 20 × 10 ^−6. 15 . Oxygen pump. The oxygen pump according to any one of claims 1 to 14 , wherein the sandwiched electrode plate is made of an iron alloy plate, a nickel alloy plate, a cobalt alloy plate, a nickel-cobalt alloy, or a stainless steel plate. The oxygen pump according to any one of claims 1 to 14 , wherein a film of gold, silver, nickel, or aluminum is formed on one surface or both surfaces of the sandwich electrode plate. In the laminated structure in which a plurality of the laminated bodies are laminated, the gas flow passing through the gas supply / discharge passage of one system and contacting one electrode film of the solid electrolyte electrode plate, and the gas supply / discharge of the other system 18. The gas flow passing through a path and contacting the other electrode film of the solid electrolyte electrode plate is configured to flow in parallel to the stacked electrode films. 18 . The oxygen pump according to claim 1. In the laminated structure in which a plurality of the laminated bodies are laminated, the gas flow passing through the gas supply / discharge passage of one system and contacting one electrode film of the solid electrolyte electrode plate, and the gas supply / discharge of the other system as the road, the gas stream in contact with the other electrode layer of said solid electrolyte electrode plate, according to claim 1, characterized in that it is configured to flow sequentially contact in series with stacked the electrode film The oxygen pump according to any one of 17 . In the laminated structure in which a plurality of the laminated bodies are laminated , a gas flow that passes through a gas supply / discharge path of one system and contacts one electrode film of the solid electrolyte electrode plate is applied to the laminated electrode films. The gas flow that is configured to flow in parallel and passes through the gas supply / discharge passage of the other system and contacts the other electrode film of the solid electrolyte electrode plate sequentially contacts the stacked electrode films. The oxygen pump according to any one of claims 1 to 17 , wherein the oxygen pump is configured to flow in series . In the laminated structure of the laminate are stacked, by switching the direction of gas flow in contact with one electrode film or other electrode film of the solid electrolyte electrode plates, so that each of the electrode films flowing in parallel or in series The oxygen pump according to claim 1 , wherein the oxygen pump has a switching structure. By inserting a gas flow changing block into an opening serving as a supply / exhaust port of the gas supply / discharge path formed in the stacking direction of the stacked structure, the gas flow is parallel or serial with respect to the stacked electrode films. The oxygen pump according to claim 21 , wherein the oxygen pump has a structure that can be changed to flow. The gas separation and distribution plate, said gas separation, distribution, insulation board, and the thermal expansion coefficient of the material of the heater plate, heat resistance and insulating material in the range of ⁵ × 10 ^-6 ~15 × 10 -6 The oxygen pump according to claim 5 , wherein The gas separation and distribution plate, said gas separation, distribution, insulation board, and the oxygen pump according to claim 5, wherein the heater plate, wherein mica, ceramic materials, or that it is formed of a glass material. In the heater plate, the heater portion is formed by sandwiching a pattern formed of a thin plate-like iron alloy or nickel alloy between mica plates, the heater portion has a plurality of openings, and a portion outside the heater portion are respectively formed a plurality of gas supply and exhaust passage are each independently in claim 1 to 24 power for the heater from an outer peripheral portion other than the gas supply and exhaust passage and having a structure to be supplied The oxygen pump according to any one of the above. The rod-like body that penetrates the laminated body or a laminated structure in which a plurality of the laminated bodies are stacked is made of screws having screws, and the material is formed of an iron alloy, a nickel alloy, a cobalt alloy, or stainless steel. cage, claim 1, wherein a terminal portion of the heater portion of the solid electrolyte the clamping electrode plates are electrically connected to the electrodes of the cell and the heater plate is adapted to be clamped in each fastening means The oxygen pump according to any one of 1 to 25 . The metal plate disposed in the outermost layer of the laminated structure is formed of a rigid material made of an iron alloy plate, a nickel alloy plate, a cobalt alloy plate, a nickel-cobalt alloy, or a stainless steel plate, and the metal plate 6. The oxygen according to claim 5 , wherein a gas supply port and a gas discharge port communicating with the gas supply / discharge passage are formed, and the metal plate is fastened and fixed by the rod-shaped body. pump. The solid electrolyte electrode plate is formed of a perovskite-type barium / cerium / gadolinium-based oxide ceramic material, barium / cerium / gadolinium / zirconium-based oxide material, or barium / cerium / gadolinium / aluminum-based oxide. The oxygen pump according to any one of claims 1 to 27, wherein: 29. The structure according to claim 1, wherein a spacer or a reinforcing plate made of at least one dense or porous heat-resistant material is attached to one side or both sides of the solid electrolyte electrode plate . The oxygen pump according to any one of the above.

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