CN100461501C - Polymer electrolye fuel cell and separator for polymer electrolyte fuel cell - Google Patents
Polymer electrolye fuel cell and separator for polymer electrolyte fuel cell Download PDFInfo
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- CN100461501C CN100461501C CNB2005101285146A CN200510128514A CN100461501C CN 100461501 C CN100461501 C CN 100461501C CN B2005101285146 A CNB2005101285146 A CN B2005101285146A CN 200510128514 A CN200510128514 A CN 200510128514A CN 100461501 C CN100461501 C CN 100461501C
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- fuel
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- supply
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Images
Classifications
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
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- Fuel Cell (AREA)
Abstract
The invention provides a clapboard used by a direct methanol, flat and polyelectrolyte fuel cell. The clapboard at the fuel supplying side of the direct methanol, flat and polyelectrolyte fuel cell directly adopts methanol aqueous solution as the fuel. The clapboard is characterized in that a plurality of plate-like components which supply the fuel to the electrolyte side used through holes of the fuel cell are arranged and deployed in a way of being approximately vertical to the surface thereof, and grooves used to supply the fuel as well as grooves used to connect the through holes are formed on the fuel supplying surfaces of the plate-like components.
Description
Technical field
The present invention relates to a plurality of unit cells are configured at equidirectional plane, be electrically connected between the unit cells of adjacency with regulation, the Electrolyte type fuel cell that above-mentioned a plurality of unit cells are connected in series.And then the battery that the present invention relates to act as a fuel directly utilizes the direct methanol type of methanol aqueous solution and is the polymer electrolyte fuel cells dividing plate of plane.
Background technology
Recently, from the viewpoint of the environment of preserving our planet, and, directly utilize hydrogen to act as a fuel to be viewpoints such as favourable, effciency of energy transfer height to set out, the desired value of fuel cell is sharply increased.
Up to the present, be used for the exploitation in universe and the exploitation of ocean, recently, carried out, carried out widely used possibility and increase as the power source that replaces automobile engine and the work of home-use Blast Furnace Top Gas Recovery Turbine Unit (TRT) aspect.
Fuel cell briefly, is fuel supplying (reducing agent) and oxygen or air (oxidant) continuously from a kind of outside, makes it to carry out the device that electrochemical reaction is extracted electric energy.Fuel cell is according to its working temperature, use the kind of fuel, and purposes etc. is classified, recently, usually, be divided into Solid Oxide Fuel Cell (SOFC) substantially mainly according to employed electrolytical kind, fused carbonate type fuel cell (MCFC), phosphoric acid type fuel cell (PAFC), polymer electrolyte fuel cells (PEFC), five kinds of alkaline aqueous solution type fuel cells (AFC) etc.
These fuel cells act as a fuel with the hydrogen by generations such as methane, but recently, the known direct methanol fuel cell (DMFC) that acts as a fuel and directly utilize methanol in water.
In this fuel cell, with two types electrode clamping polymeric membranes and then, the polymer electrolyte fuel cell that constitutes with these members of dividing plate clamping (below be also referred to as " polymer electrolyte fuel cells ", perhaps " PEFC ": Polymer Electrolyte FuelCell) very noticeable.
This PEFC disposes air pole (the oxygen utmost point) by the both sides at solid polymer membrane, and fuel electrodes electrode component unit batteries such as (the hydrogen utmost points) is with the both sides formation of this unit cells of separator for fuel battery clamping.
For example, structure as PEFC, can list following structure, be integrally formed fuel electrodes and air pole that the catalyst layer by thickness 10 μ m~20 μ m constitutes in the both sides of the polyelectrolyte of thickness 20 μ m~70 μ m, add the supporting layer (carbon tissue of porous matter as current-collecting member in the outside of catalyst layer, the porosity about 80%), and then, utilize dividing plate (space bar) clamping of the feed lines of reacting gass such as double as hydrogen or oxygen to constitute.
In above-mentioned PEFC,, they are isolated, and be necessary that the hydrogen ion (proton) that will generate is transported to the air pole side on fuel electrodes in order to make the not directly reaction of fuel (hydrogen) and oxidant (air).
In normal temperature (below the 100 ℃) fuel cell that work, proton move in solid polymer membrane down, the film (about thick 50 μ m) that has sulfonic perfluorocarbon sulfonic acid structure as ion-exchange group can be used as solid polymer membrane, compact battery can be made.
In this PEFC, its output performance is 1~3A/cm
2, each monocell of 0.6~2.1V/ obtains 2.1W/cm
2High output density.
In this PEFC, its structure is generally, and by in the both sides of solid polymer membrane, respectively a plurality of unit cells of configured electrodes is carried out lamination, makes the stack architecture (being called the PEFC heap) that strengthens its electromotive force according to required purpose.But, as the fuel cell of usefulness such as portable formula terminal, do not need too high electromotive force, require sometimes to make plane, thin as far as possible.
In addition, in PEFC, as dividing plate, usually, use forms the fuel gas supply tank that is supplied to an adjacent unit cells to use fuel gas on a face, form the dividing plate of the structure of the oxidant gas supply tank of using to another unit cells supply oxidant of adjacency on another face.Whereby, along separator face fuel supplying gas, oxidant gas.
As the PEFC dividing plate, known have, and graphite cake is cut out the dividing plate of groove, the moulding dividing plate of the carbon complex that carbon is mixed in resin, utilize etching etc. to carry out the metal separator of groove processing, the resin of corrosion resistance is covered the dividing plate of the surface element etc. of metal material.These dividing plates all form the fuel gas supply as required with groove and/or oxidant gas supply groove.
But, in the direct methanol fuel cell (DMFC) of direct use methanol aqueous solution that acts as a fuel, utilization has the fuel gas supply that fuel supplying gas uses and carries out the supply of fuel with the dividing plate of the above-mentioned prior art of groove, exists difference along with the position uneven problem that becomes.
Particularly, at direct methanol type, a plurality of unit cells alignment arrangements are become plane, under the situation of the plane that they in series are electrically connected, existing problems.
As mentioned above, in recent years, the possibility that is extensive use of fuel cell increases, in PEFC, except that general packed structures, needing electromotive force is not the fuel cell of thin form as far as possible of very high, plane yet. and then, in the PEFC of the direct plane of methanol type, can not fully eliminate because of the different fuel at position and supply uneven problem, require this is taken some countermeasures.
Summary of the invention
Therefore, the objective of the invention is, provide a kind of and have and to be arranged to the fuel cell of the structure that plane unit cells in series is electrically connected.
In addition, it is a kind of at direct methanol type and among the PEFC of plane that the present invention provides especially, can eliminate the fuel cell of the problem of the supply of fuel inhomogeneities that causes because of the position difference.
In order to reach such purpose, polymer electrolyte fuel cells of the present invention, its structure is, be configured to a plurality of unit cells plane at equidirectional, to in series be electrically connected between the unit cells of adjacency of regulation, in the Electrolyte type fuel cell that above-mentioned a plurality of unit cells are connected in series, for carry out aforementioned regulation in abutting connection with the electrical connection between the unit cells, between unit cells in the adjacency of aforementioned regulation, on the insulation division of the thickness that is roughly unit cells of constituent parts battery electric insulation, the through hole connecting portion is set at least, the filling vias connecting portion protrudes in the connecting portion.
Polymer electrolyte fuel cells of the present invention, with the part of a tabular polyelectrolyte membrane as the dielectric film that constitutes the constituent parts battery, be configured to plane along identical direction a plurality of unit cells, to in series be electrically connected between the unit cells of adjacency of regulation, in the polymer electrolyte fuel cells that aforementioned a plurality of unit cells are connected in series, for carry out aforementioned regulation in abutting connection with the electrical connection between the unit cells, on the polyelectrolyte membrane between the unit cells of the adjacency of aforementioned regulation, the through hole connecting portion is set at least, the filling vias connecting portion protrudes in the connecting portion.
According to such the present invention, can provide to have and to be arranged to the fuel cell of the structure that plane a plurality of unit cells in series are electrically connected.Promptly, by the insulation division with the thickness that roughly has unit cells of constituent parts battery electric insulation is set between the unit cells of the adjacency of stipulating, perhaps, by with the part of a tabular polyelectrolyte membrane as the electrolytic thin-membrane that constitutes the constituent parts battery, between unit cells, dispose polyelectrolyte membrane, with a plurality of unit cells point to same direction, be configured to plane, existing widely used through hole is connected, filling vias connects, and the protuberance interconnection technique is applied to the electrical connection of the series connection between unit cells.
In addition, dividing plate of the present invention, its structure is, in the dividing plate of the direct supply of fuel side that adopts the direct methanol type of methanol aqueous solution and use that acts as a fuel for the polymer electrolyte fuel cells of plane, have in the mode that is approximately perpendicular to its surperficial alignment arrangements and be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, on the surface of the fuel supplying of this tabular component, form supply of fuel with groove and with the groove that couples together between the through hole.
In addition, in plane PEFC, usually integral body is wrapped up, use aforementioned barriers between the tabular component and basket of contact, the through-hole section of tabular component, the supply of fuel groove, the groove between the connecting through hole constitutes the supply of fuel stream respectively.
In addition, dividing plate of the present invention, its structure is, in the dividing plate of the direct supply of fuel side of using the direct methanol type of methanol aqueous solution and using that acts as a fuel as the polymer electrolyte fuel cells of plane, have in the mode that is approximately perpendicular to its surperficial alignment arrangements and be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, and the cap that covers a face of this tabular component, with surface that the aforementioned cap of aforementioned tabular component contacts on form supply of fuel with the groove between groove and the connecting through hole, between the aforementioned tabular component and cap of contact, aforementioned through-hole, aforementioned supply of fuel groove, aforementioned grooves between the connecting through hole constitutes the supply of fuel stream respectively.
In addition, dividing plate of the present invention, its structure is, in the dividing plate of the direct supply of fuel side of using the direct methanol type of methanol aqueous solution and using that acts as a fuel as the polymer electrolyte fuel cells of plane, by be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses in the mode that is approximately perpendicular to its surperficial alignment arrangements, and the cap that covers a surface of this tabular component constitutes, on this cap and surface that aforementioned tabular component contacts, form the supply of fuel groove, and the groove between the connecting through hole, between the aforementioned tabular component and aforementioned cap of contact, the through-hole section of aforementioned tabular component, the supply of fuel groove of aforementioned cap, the groove between the connecting through hole constitutes the supply of fuel path respectively.
In addition, dividing plate of the present invention, its structure is that in aforementioned barriers, a plurality of supplies of fuel are connected on each through hole with the groove between groove or the connecting through hole.
In addition, dividing plate of the present invention, its structure is, in aforementioned barriers, tabular component is matrix with the metal, at least on the surface element of the aforementioned substrates of the electrolyte side that becomes fuel cell, the protective layer that configuration is made of the resin bed of acid resistance conductivity etc.
In addition; dividing plate of the present invention; its structure is; in aforementioned barriers; aforementioned protective layer is the electroplate liquid that utilizes the electric conducting material that is mixed with carbon particle, corrosion-resistant metal etc. in resin, and by electroplating film forming, being heating and curing then forms; or by electrolysis polymerization, be formed in the resin that constitutes by electroconductive polymer in order to improve the film that conductivity contains the state of dopant and form.
In addition, polymer electrolyte fuel cells of the present invention, its structure is, acting as a fuel the direct methanol type that directly utilizes methanol aqueous solution and in the polymer electrolyte fuel cells of plane, employing has in the mode that is approximately perpendicular to its surperficial alignment arrangements and is provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, on the surface of the fuel supplying of this tabular component, form the supply of fuel groove, and the dividing plate used of the polymer electrolyte fuel cells of the groove between the connecting through hole, via the through hole fuel supplying of this dividing plate.
In addition, polymer electrolyte fuel cells of the present invention, its structure is, acting as a fuel the direct methanol type that directly utilizes methanol aqueous solution and in the polymer electrolyte fuel cells of plane, employing has in the mode that is approximately perpendicular to its surperficial alignment arrangements and is provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, and the cap that covers a surface of this tabular component, with surface that the aforementioned cap of aforementioned tabular component contacts on form supply of fuel with the groove between groove and the connecting through hole, between the aforementioned tabular component and cap of contact, aforementioned through-hole, aforementioned supply of fuel groove, aforementioned grooves between the connecting through hole, constitute the polymer electrolyte fuel cells dividing plate of supply of fuel respectively, via the through hole of this dividing plate, fuel supplying with stream.
In addition, polymer electrolyte fuel cells of the present invention, its structure is, acting as a fuel the direct methanol type that directly utilizes methanol aqueous solution and in the polymer electrolyte fuel cells of plane, employing is by be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses in the mode that is approximately perpendicular to its surperficial alignment arrangements, and the cap that covers a surface of this tabular component constitutes, on this cap and surface that aforementioned tabular component contacts, form the supply of fuel groove, and the groove between the connecting through hole, between the aforementioned tabular component and aforementioned cap of contact, the through-hole section of aforementioned tabular component, the supply of fuel groove of aforementioned cap, groove between the connecting through hole, constitute the polymer electrolyte fuel cells dividing plate of supply of fuel respectively, via the through hole of this dividing plate, fuel supplying with path.
The dividing plate that the polymer electrolyte fuel cells of the plane of direct methanol type of the present invention is used by this structure, particularly, in direct PEFC methanol type, plane, can be eliminated the non-uniformity problem of the supply of fuel that causes because of the position difference.
That is,, can eliminate the non-uniformity problem that causes because of supply of fuel position difference by the groove between the connecting through hole is set.
Particularly, by at the groove that connects a plurality of (more than two) on each through hole, can further eliminate the supply of fuel non-uniformity problem that causes because of the position difference.
In addition, tabular component is matrix with the metal, and by the protective layer that configuration is made of the resin bed of acid resistance conductivity etc. on the surface element of the electrolyte side of the fuel cell that becomes matrix at least, making can practical structure.
Polymer electrolyte fuel cells of the present invention by said structure, particularly, in the plane PEFC of direct methanol type, can be eliminated the problem of the supply of fuel inhomogeneities that causes because of the position difference.
The simple declaration of accompanying drawing
Fig. 1, be the profile of first example of the form of implementation of polymer electrolyte fuel cells of the present invention.
Fig. 2, be the plane graph of polymer electrolyte fuel cells shown in Figure 1.
Fig. 3 (a)~Fig. 3 (d), be in first example with filled-type through hole connecting portion the flow chart making during as the connecting portion at the surperficial back side.
Fig. 4 (a)~Fig. 4 (d), be in first example, the flow chart making with filled-type path connecting portion during as the connecting portion at the surperficial back side.
Fig. 5 (a)~Fig. 5 (c), be in first example, the flow chart making when protruding connecting portion as the connecting portion at the surperficial back side.
Fig. 6, be the profile of second example of the form of implementation of polymer electrolyte fuel cells of the present invention.
Fig. 7, be the plane graph of polymer electrolyte fuel cells shown in Figure 6.
Fig. 8, be the profile of the 3rd example of the form of implementation of polymer electrolyte fuel cells of the present invention.
Fig. 9, be the plane graph of polymer electrolyte fuel cells shown in Figure 8.
Figure 10, be the profile of the plane polymer electrolyte fuel cells of direct methanol type of the present invention with first example of the form of implementation of dividing plate.
Figure 11, be the diagram of the through hole of expression dividing plate shown in Figure 10.
Figure 12, be the profile of the plane polymer electrolyte fuel cells of direct methanol type of the present invention with second example of the form of implementation of dividing plate.
Figure 13, be the profile of the plane polymer electrolyte fuel cells of direct methanol type of the present invention with the 3rd example of the form of implementation of dividing plate.
Figure 14, be the diagram of the tabular component of expression configuration bulkhead through-hole shown in Figure 13.
Figure 15, be the diagram of expression dividing plate cap shown in Figure 13.
Figure 16, be the profile of first example of the form of implementation of polymer electrolyte fuel cells of the present invention.
Figure 17, be the plane graph of polymer electrolyte fuel cells shown in Figure 16.
Figure 18 (a)~(d) is the profile of manufacturing process of the connecting portion of expression polymer electrolyte fuel cells shown in Figure 17.
Figure 19, be the profile of second example of the form of implementation of expression polymer electrolyte fuel cells of the present invention.
Figure 20, be the profile of the 3rd example of the form of implementation of expression polymer electrolyte fuel cells of the present invention.
The optimised form that carries out an invention
Below, form of implementation of the present invention is described.
Form of implementation example based on Fig. 1~9 explanations polymer electrolyte fuel cells of the present invention.
In Fig. 1~9, the 10th, unit cells, the 11st, fuel electrodes side dividing plate (is also referred to as collector body, perhaps bipolar plates), the 12nd, air pole side dividing plate (being also referred to as collector body, perhaps bipolar plates), the 13rd, polyelectrolyte membrane, the 14th, insulation division, the 16th, through hole, the 20th, connecting portion, the 21st, connect distribution, the 22nd, surperficial back side connecting portion, 26, the 27th, distribution, the 31st, Copper Foil, the 33rd, coating, 35, the 36th, conductive paste, 41, the 42nd, Copper Foil, the 45th, protuberance, the 46th, contact site, the 50th, unit cells, the 51st, fuel electrodes side dividing plate (being also referred to as collector body, perhaps bipolar plates), the 52nd, air pole side dividing plate (is also referred to as collector body, perhaps bipolar plates), the 53rd, polyelectrolyte membrane, the 54th, insulation division, the 60th, connecting portion, the 61st, connect distribution, the 62nd, surperficial back side connecting portion, 66, the 67th, distribution, the 70th, unit cells, the 71st, fuel electrodes side dividing plate (is also referred to as collector body, perhaps bipolar plates), the 72nd, air side dividing plate (being also referred to as collector body, perhaps bipolar plates), the 73rd, polyelectrolyte membrane, 73A is tabular polyelectrolyte membrane, the 80th, and connecting portion, the 81st, connect distribution, the 82nd, surperficial back side connecting portion, 86, the 87th, distribution.
Wherein, Fig. 3~Fig. 5 is near the diagram the connecting portion 20 of Fig. 1.
In addition, Fig. 1 is the profile at the A1-A2 place of Fig. 2, and Fig. 6 is the profile at the B1-B2 place of Fig. 7, and Fig. 8 is the profile at the C1-C2 place of Fig. 9.
In addition, the A3 among Fig. 2, A4, the B3 among Fig. 7, B4, the C3 among Fig. 9, C4 are output terminal parts.
First example of the form of implementation of polymer electrolyte fuel cells of the present invention at first, is described based on Fig. 1, Fig. 2.
The high score of first example is in Electrolyte type fuel cell, as shown in Figures 1 and 2, be that a plurality of unit cells 10 alignment arrangements are become plane, they in series are electrically connected, the polymer electrolyte fuel cells of the voltage of exportable number (being 4 in Fig. 2) corresponding to unit cells.In addition, around individual unit cells 10, roughly identical with it insulation division 14 of thickness is set, integral body is made plane. promptly,, be arranged to unit cells 10 and insulation division 14 plane by unit cells being embedded in the cavern part of flat insulation division 14.
This example, the position between the unit cells of the adjacency of stipulating on the insulation division 14 with constituent parts battery 10 electric insulations, is provided with the surperficial back side connecting portion 22 of the connection usefulness of carrying out the surperficial back side of perforation.Simultaneously, (be also referred to as collector body via connecting the fuel electrodes side dividing plate that wiring part 21 should the back side, surface connecting portion 22 be connected to an adjacent unit cells, perhaps bipolar plates) 11 and the air pole side dividing plate of another unit cells (be also referred to as collector body, perhaps bipolar plates) on 12, will in series be electrically connected between the unit cells of adjacency.
In addition,, for the purpose of being easy to explanation, make in Fig. 2 that unit cells is 4 here, but also can be for more than 5.
As connecting portion 20, the through hole connecting portion, perhaps the filling vias connecting portion protrudes any one in the connecting portion, is arranged in the insulation division 14, can be used as existing wiring substrate The Application of Technology they are formed.
As the fuel electrodes side dividing plate 11 of unit cells 10, the material of air pole side dividing plate 12 preferably, adopts the aspects such as conductivity, intensity, corrosion resistance can be competently and the material good with the switching performance that is connected distribution 21.As these materials, use metal material usually, for example, adopt stainless steel, cold-rolled steel sheet, aluminium etc.Perhaps, as dividing plate 12, as basis material, adopt the dividing plate that on the surface of polyelectrolyte membrane side, disposes acid resistance and have the resin molding of conductivity with these metal materials.
Below, to an example of the manufacture method of this routine polymer electrolyte fuel cells, based on its handling process of Fig. 3 simple declaration.In this embodiment, be with the surperficial back side connecting portion 22 of connecting portion 20 situation as the through hole connecting portion of filled-type.
At first, have on two faces on the glass epoxy resin substrate (insulation division 14) of Copper Foil 31, forming the hole portion that unit cells is embedded, unit cells 10 is being embedded into (Fig. 3 (a)) in this hole portion with identical direction.
Secondly, utilize drill bit or laser, offer and form the through hole 16 (Fig. 3 (b)) that filled-type through hole connecting portion is used.
Secondly, after carrying out the decontamination processing and add catalyst handling, on interior whole, carry out chemical plating at the surface element that comprises through hole 16, and then, electroplate at chemical deposit.Whereby, with coating 33 filling vias 16, form surperficial back side connecting portion 22, with the conducting of the surperficial back side (Fig. 3 (c)).
As chemical plating, can suitably carry out chemical nickel plating, electroless copper.Chemical plating after utilizing catalyst to carry out activation processing, is carried out with the plating bath of stipulating. in addition,, carry out copper facing usually as plating.
Secondly, carry out resist plate-making on the whole surperficial back side, coating 33 etchings that will expose from resist form and connect distribution 21, remove resist, carry out clean as required, obtain this routine polymer electrolyte fuel cells (Fig. 3 (d)).
Etching solution is used for coating 33 optionally being etched into fuel agent side dividing plate 11, air pole side dividing plate 12 respectively.As this etching solution, can utilize iron chloride liquid etc., can consider the material of dividing plate and the etching speed of copper wiring, the decision etching condition.
In addition, here,, but be not limited thereto with coating 33 filling vias 16.For example, also can be to add large through-hole 16, the state behind the plating although form coating 33 on the internal face of through hole 16, still is in the common through hole connecting portion of the state of surperficial back side perforation.
Secondly, to an example of the manufacture method of this routine polymer electrolyte fuel cells, based on its handling process of Fig. 4 simple declaration.In this embodiment, be surperficial back side connecting portion 22 situations as the filling vias connecting portion with connecting portion 20.
At first, go up the hole portion that forms the unit cells embedding at glass epoxy resin substrate (insulation division 140), unit cells 10 is embedded this hole portion (Fig. 4 (a)) with identical direction, utilize drill bit or laser on insulation division 14, to offer and form the through hole 16 (Fig. 4 (b)) that filling vias portion uses.
Secondly, utilize silk screen printing etc. to be applied to conductive paste on the face of glass epoxy resin substrate with homogeneous thickness, to reduce pressure in the through hole 16 by the rear side that air-breathing utensil is configured in the glass epoxy resin substrate, conductive paste 35 is filled in the through hole 16 (Fig. 4 (c)).
Secondly, utilize print process printing conductive paste 36, form connection distribution 21, obtain this routine polymer electrolyte fuel cells (Fig. 4 (d)).
As conductive paste, can list silver-colored paste, copper paste, golden paste, palladium paste, palladium-Yin paste etc.
Secondly, to an example of the manufacture method of this routine polymer electrolyte fuel cells, based on its handling process of Fig. 5 simple declaration.In this embodiment, be as the situation of protruding connecting portion with the surperficial back side connecting portion 22 of connecting portion 20.
At first, utilize the hole portion of insulated substrate (insulation division 14) formation embedding unit cells such as glass epoxy resin substrate, unit cells 10 is embedded in this hole portion with identical direction.Secondly, prepare the Copper Foil 41 on a face of insulated substrate (insulation division 14), on another face, prepare to form the Copper Foil 42 (Fig. 5 (a)) of conductivity protuberance 45 in insulated substrate (insulation division 14) side.Copper Foil 41 and Copper Foil 42 are laminated to insulated substrate (insulation division 14) upward (Fig. 5 (b)).Utilize this lamination, protuberance 45 becomes and connects insulation division 14 and be connected to state on the Copper Foil 41.
In addition, when making protuberance, at the height that obtains protuberance simultaneously, cut its tip very sharp-pointed.
Secondly, carry out resist plate-making on the whole surperficial back side, the Copper Foil 41,42 that etching is exposed from resist forms connection distribution 21.Secondly, remove resist, carry out clean as required, obtain this routine polymer electrolyte fuel cells (Fig. 5 (c)).
The formation method of the connecting portion 20 of Fig. 3~shown in Figure 5 is an example, and the present invention is not limited thereto.
Like this, first example, by the insulation division 14 of the thickness that roughly having of individual unit cells electric insulation is identical with the thickness of unit cells is set between the unit cells of the adjacency of stipulating, as connecting portion 20, can adopt widely used through hole connecting portion in the prior art, the filling vias connecting portion protrudes connecting portion etc.In addition, the formation of connecting portion 20 to not influence of constituent parts, is that electricity is stable.
Secondly, second example of the form of implementation of polyelectrolyte type battery of the present invention be described based on Fig. 6, Fig. 7.
Second example, the same with first example, be that a plurality of unit cells 50 alignment arrangements are become plane, they in series are electrically connected the polymer electrolyte fuel cells of the voltage of exportable number (being 4 in Fig. 7) corresponding to unit cells.Simultaneously, on the part between the unit cells 50 that connecting portion 60 is set, be provided with, integral body made plane with the roughly the same insulation division 54 of its thickness.That is, its structure is, replaces the part of the polyelectrolyte membrane 53 between the unit cells of the adjacency that surperficial back side connecting portion 62 is set with insulation division 54.
Under the situation of second example, the both sides of a flat polyelectrolyte membrane 53, difference a plurality of (being 4 in Fig. 7) fuel electrodes side dividing plate 51, air pole side dividing plate 52, with the state configuration of separating. and then the fuel electrodes side dividing plate 51 of constituent parts battery 50 is with the size identical with air pole side dividing plate 52, subtend on identical position, the constituent parts battery is separated.
Because the direction of constituent parts battery 50 is identical, in series be electrically connected, so necessarily need surperficial back side connecting portion.
Situation under the situation of second example during also with first example is the same, between the unit cells of adjacency of regulation, will with the insulation division 54 of constituent parts battery 50 electric insulations on, the surperficial back side connecting portion 62 of connection usefulness perforation, that carry out the surperficial back side is set.Simultaneously, should the back side, surface connecting portion 62 the fuel electrodes side dividing plate 51 of an adjacent unit cells be connected with the air pole side dividing plate 52 of another unit cells, will be electrically connected between the adjacent unit cells via connecting distribution 61.
In addition, here, in order to be easy to explanation, the number that makes unit cells in Fig. 7 is 4, but also can be more than 5.
Under the situation of second example, each several part (material and structure) can adopt the part identical with first example.
In addition, the same with first example under second kind of situation, as connecting portion 60, the through hole connecting portion can be set in insulation division 54, perhaps filling vias connecting portion, it is any to protrude connecting portion.
In addition, comprise by the through hole connecting portion, perhaps filling vias connecting portion protrudes the formation at interior connecting portion 60 of surperficial back side connecting portion 62 that connecting portion etc. constitutes, can carry out with the same technology that illustrates under the situation with first example basically.
Under the situation of second example, equally, by regulation in abutting connection be provided with between the unit cells with constituent parts battery electric insulation roughly have a insulation division 54 with the unit cells same thickness, as connecting portion 60, the same with the situation of first example, can adopt widely used through hole connection in the prior art, filling vias connects, protuberance connection etc., and then, the formation of connecting portion 60 to the not influence of constituent parts battery, is that electricity is stable.
Secondly, the 3rd example of the form of implementation of polymer electrolyte fuel cells of the present invention be described based on Fig. 8, Fig. 9.
The 3rd example greater than part size, a tabular polyelectrolyte membrane 73A of a unit cells 70 dielectric film 73 as constituent parts battery 70, is configured to plane with identical direction a plurality of unit cells 70 size.Simultaneously, it is in series to be electrically connected between a kind of unit cells 70 of the adjacency that will stipulate, and a plurality of unit cells all are connected in series, and output is corresponding to the polymer electrolyte fuel cells of the voltage of the number (being 4 in Fig. 9) of unit cells 70.In this polymer electrolyte fuel cells,, on the polyelectrolyte membrane 73A between the unit cells in the adjacency of aforementioned regulation, surperficial back side connecting portion 82 is set for the electrical connection between the unit cells of the adjacency stipulated.
Under the situation of the 3rd example, equally, via connecting on the dividing plate 72 of air pole side that distribution 81 is connected to surperficial back side connecting portion 82 dividing plate 71 of fuel electrodes side of a unit cells 70 of adjacency and another unit cells 70, be electrically connected between the battery with adjacency.
In addition, here, for convenience of explanation, the number that makes unit cells in Fig. 9 is 4, but more than also can being.
Under the situation of the 3rd example, also the same with first example, second example, as connecting portion 80, on the polyelectrolyte membrane 73A between the unit cells of the adjacency of the regulation that is connected, through hole connecting portion or filling vias connecting portion are set, protrude connecting portion etc.
In addition, comprise, protrude the formation of surperficial back side connecting portion 82 that connecting portion etc. constitutes at interior connecting portion 80 by through hole connecting portion or filling vias connecting portion, basically can with the situation of first example under the substantially the same technology that illustrates carry out.
Under the situation of the 3rd example, with the part of a tabular polyelectrolyte membrane as the dielectric film that constitutes the constituent parts battery, polyelectrolyte membrane is configured between the unit cells, be configured to plane with identical direction a plurality of unit cells, so,, can adopt widely used through hole connection in the prior art as connecting portion 80, filling vias connects, and protrudes forms such as connecting portion.
In described in the above first example~3rd example, a plurality of unit cells are configured to plane, but, also can adopt the form of the state that the further multilayer of this structure is overlapping (storehouse shape).
In addition, in this case, output terminal part (A3 of Fig. 2, A4, the B3 of Fig. 7, B4, the C3 of Fig. 9 C4) along the connection of stack direction, can adopt the mode identical with existing stack architecture.
Secondly, the example of the form of implementation of dividing plate that the high-molecular electrolyte fuel battery of direct methanol type of the present invention, plane is used and high-molecular electrolyte fuel battery is described based on Figure 10~Figure 20.
In Figure 10~Figure 20,100A, 100B, 100C is a dividing plate, 110,110a is a tabular component, the 111st, through-hole section, the 112nd, groove, 112a are the supply of fuel grooves, 120,120a is a cap, the 122nd, and groove, the 130th, unit cells, the 132nd, air pole side dividing plate, the 133rd, polyelectrolyte membrane, the 134th, insulation division, the 136th, through hole, the 140th, connecting portion, the 141st, connect distribution, the 142nd, surperficial back side connecting portion, 146, the 147th, distribution, the 151st, Copper Foil, the 153rd, coating, the 160th, unit cells, the 162nd, air pole side dividing plate, the 163rd, polyelectrolyte membrane, the 164th, insulation division, the 170th, connecting portion, the 171st, connect distribution, the 172nd, surperficial back side connecting portion, the 180th, unit cells, the 182nd, air pole side dividing plate, the 183rd, polyelectrolyte membrane, 183A are tabular polyelectrolyte membranes, the 190th, and connecting portion, the 191st, connect distribution, the 192nd, surperficial back side connecting portion.
Figure 11 is a diagram of seeing A1, A2 side from the chain-dotted line of Figure 10, and Figure 16 is the profile at the B1-B2 place of Figure 17.Among Figure 17, B3, B4 are output terminal parts.
In addition, Figure 18 is near the diagram the connecting portion 140 of Figure 16.
First example of the form of implementation of the dividing plate that the high-molecular electrolyte fuel battery of the plane of direct methanol type of the present invention is used at first, is described based on Figure 10.
First example is to act as a fuel the direct methanol type that directly uses methanol in water and the dividing plate of the supply of fuel side used as the high-molecular electrolyte fuel battery of plane.As shown in figure 10, dividing plate 100A generally perpendicularly arranges with its surface on tabular component 110 a plurality of through holes 111 of using to the electrolyte side of fuel cell supply of fuel is set, and, on the surface of fuel supplying, form supply of fuel groove 112a, the groove 112 between the connecting through hole.
In the case of this example, at the state that constitutes battery, surround the formation face side contacts of the supply of fuel of whole basket (not shown) and tabular component 110 with the groove 112 between groove 112a, the connecting through hole.Whereby, between the tabular component 110 and basket of contact, the through hole 111 of tabular component 110, supply of fuel groove 112a, the groove 112 between the connecting through hole constitutes the supply of fuel stream respectively.
The material of tabular component 110, in order to tolerate the use of fuel, as long as have acid resistance, conductivity can obtain enough intensity, has no particular limits.
The metallic matrix of tabular component 110, by utilizing machining, the etching and processing of photoetching technique is processed into the shape of regulation.
In addition, as on the surface element of the matrix that constitutes by metal, disposing acid resistance and having the method for the resin molding of conductivity, can list use with carbon particle, electric conducting materials such as the metal of corrosion resistance are mixed into the electroplate liquid in the resin, utilize to electroplate and form film, the method that is heating and curing then perhaps, is formed on the method etc. of the film of the state that contains the alloy that improves conductivity in the resin that electroconductive polymer constitutes by electrolysis polymerization.
Electroplate, form the electroplate liquid that resin molding is used as electroplating, use has the various anionic properties of plating property or the synthetic macromolecule resin of cationic, and the state that is dispersed with electric conducting material in electroplate liquid is electroplated.
In addition, utilizing the resin of electroplating the resin molding that forms originally not have conductivity on one's body, but owing under the state that conductive material is mixed in the resin, form film, so, show conductivity as resin.
As employed anionic property macromolecule resin, can use following resin individually or by these resin combination are used as mixture, these resins comprise: acrylic resin, mylar, the maleic acid oleoresin, polybutadiene, epoxy resin, polyamide, polyimide resin etc.
And then, also can also use crosslinkable resins such as melamine resin, phenolic resins, urethane resin together simultaneously with above-mentioned anionic property synthetic resin.
In addition, as employed cationic synthetic macromolecule resin, can use following resin separately or they are carried out combination in any and constitute the mixture use, described resin is an acrylic resin, epoxy resin, urethane resin, polybutadiene, polyamide, polyimide resin etc.And then, also can be with mylar, crosslinkable resin and above-mentioned cationic synthetic macromolecule resin while and usefulness such as urethane resin.
In addition, for giving above-mentioned macromolecule resin with caking property, can add rosin system as required, terpenic series, Petropols etc. are given close-burning resin.
Above-mentioned macromolecule resin is utilizing the neutralization of alkaline matter or acidic materials to be dissolvable in water state in the water, perhaps uses in the state power supply plating of aqueous dispersion.That is, use trimethylamine, diethylamine, dimethylethanolamine, amines such as diisopropanolamine (DIPA), ammonia, inorganic bases such as caustic potash with the moon from neutralizing in the property synthetic macromolecule resin.Use acetic acid, formic acid, propionic acid, acid such as lactic acid neutralizes the cationic synthetic macromolecule resin.Simultaneously, the macromolecule resin that is neutralized, can be dissolved in the water in water dispersible or lysotype, uses under the state of dilute with water.
Under with the situation that electroplate to form resin molding, as the electric conducting material that is mixed in the resin, can list carbon particle, the metal of corrosion resistance etc., as long as but the resin bed that can obtain to have acid resistance and conductivity be not limited thereto.
Electrolysis polymerization is immersed in electrode basically to contain to switch in the electrolyte of aromatic compound as monomer and carries out, and the method for utilizing electrochemical oxidation or reductive polymerization is well-known method, omits its detailed description here.
Utilize electrolysis polymerization, can directly electroconductive polymer be synthesized film like, but in this example, be formed on the state that contains the dopant that improves conductivity in the resin of electrolysis polymerization.
Like this, in the resin of electrolysis polymerization, in order to make and then contain the state of the dopant that improves conductivity, can adopt when electrolysis polymerization, contain the electrochemical doping of dopant, perhaps, behind the electrolysis polymerization, the electroconductive resin (macromolecule) that utilizes electrolysis polymerization to form is immersed in the dopant liquid itself, perhaps, is immersed in the methods such as liquid phase doping in the solution that contains dopant molecule.
In addition, this dopant with negative electrode and anode in short circuit, or adds reverse voltage after polymerization, can break away from or neutralize, and then control voltage reversibly mixes, goes to mix and the concentration of controlled doping agent.
In the dopant that when forming the resin molding that adopts electrolysis polymerization, uses, dopant as the doping type that provides electronics, can list alkali metal, alkyl phosphate ions etc. are subjected to the principal mode dopant as what capture electronics, can list halogen, lewis acid (Lweis acid), Bronsted acid, transition metal halide, organic acid etc.
Secondly, based on Figure 12 second example of the plane polymer electrolyte fuel cells of direct methanol type of the present invention with the form of implementation of dividing plate is described.
Second example, also the same with first example, be the dividing plate of the supply of fuel side that the polymer electrolyte fuel cells of the direct methanol type that directly uses methanol aqueous solution and plane uses of acting as a fuel.This dividing plate 100B also uses the tabular component 110 the same with first example.Dividing plate 100B, by the tabular component 110 that forms the groove 112 between through hole 111, supply of fuel groove 112a, the connecting through hole, and the cap 120 on the surface of the groove 112a of covering tabular component 110 and groove 112 constitutes.Simultaneously, tabular component 110 contacts with cap 120, between this tabular component 110 and cap 120, and through hole 111, supply of fuel groove 112a, the groove 112 between the connecting through hole forms the supply of fuel stream respectively.
In the case of this example, cap 120 for example, can be the β stainless sheet steel, but as the material of cap 120, as long as can tolerate the use of fuel, has the intensity of regulation, does not have specific restriction.For example, under the situation that is used to be electrically connected, can use sheet metals such as stainless steel, cold-rolled steel sheet, aluminium.
Secondly, the 3rd example of the form of implementation of the dividing plate that the polymer electrolyte fuel cells of the plane of direct methanol type of the present invention is used be described based on Figure 13~Figure 15.
The dividing plate 100C of the 3rd example, the same with second example, by arrangement the tabular component 110a of the through-hole section 111 of a plurality of and its Surface Vertical is set, and cap 120a constitutes.In lid dividing plate 100C, on the face of the cap 120a that contacts with tabular component 110a, supply of fuel groove 122a is set, and the groove between the connecting through hole 122.Simultaneously, contact with cap 120a by tabular component 110a, between tabular component 110a and cap 120a, the supply of fuel groove 122a of the through-hole section 111 of tabular component 110a and cap 120, groove 122 between the connecting through hole forms the supply of fuel stream respectively.
In addition, the processing of cap 120a is if matrix is a metal, usually, carry out machining, etching and processing, if the words of resin, carry out injection molded, extrusion molding, transfer feed is shaped, calendaring molding, compression molding, general forming process such as cast molding, and machining such as cutting etc.
Secondly, first example of the form of implementation of the polymer electrolyte fuel cells of the present invention that utilizes dividing plate of the present invention is described based on Figure 16, Figure 17.
This example is to use the polymer electrolyte fuel cells of plane of direct methanol type of the dividing plate 100B of second example shown in Figure 12.
This polymer electrolyte fuel cells, be a kind ofly a plurality of unit cells 130 alignment arrangements to be become plane they in series are electrically connected, the polymer electrolyte fuel cells of the voltage of (being 4 in Figure 17) of exportable number corresponding to unit cells. simultaneously, around constituent parts battery 130, the roughly the same insulation division 134 of thickness with it is set, integral body is made plane.That is,, be arranged to unit cells 130 and insulation division 134 plane by unit cells 130 being embedded into the portion of digging out of flat insulation division 134.In addition, on insulation division 134 between the unit cells of the adjacency of stipulating,, surperficial back side connecting portion 142 perforation, that carry out its surperficial back side connection usefulness is set with constituent parts battery electric insulation.Simultaneously,, this back side, surface connecting portion 142 is connected on the dividing plate 132 of air pole side of the dividing plate 100B of fuel electrodes side of a unit cells of adjacency and another unit cells, will in series be electrically connected between the unit cells of adjacency via connecting distribution 141.
In addition, here, in order to be easy to explanation, the number that makes unit cells on Figure 17 is 4, but also can be more than 5.
134 of insulation divisions are made of insulant, also can be the structures that part contains conductive object.As the material of insulation division 134 usefulness, usually, use baseplate material, for example, use glass epoxy resin, polyimides etc.
As connecting portion 140, the through hole connecting portion is set in insulation division 134, perhaps, the filling vias connecting portion protrudes in the connecting portion anyly, but they also can be used as existing wiring substrate The Application of Technology and form.
As the material of the dividing plate 132 of the air pole side of unit cells 130, preferably, in conductivity, intensity, use can be competent in aspects such as corrosion resistance, and good with the switching performance that is connected distribution 141.As their material, usually, adopt metal material, for example, use stainless steel, cold-rolled steel sheet, aluminium etc.
Below, based on Figure 18, an example to the manufacture method of this routine polymer electrolyte fuel cells illustrates its handling process simply.In this embodiment, utilize the surperficial back side connecting portion 142 of the through hole connecting portion of filled-type as connecting portion 140.
At first, have on two faces on the glass epoxy resin substrate (insulation division 134) of Copper Foil 151, forming the hole portion that unit cells embeds, unit cells 130 is being embedded (Figure 18 (a)) in this hole portion with identical direction.
Secondly, utilize drill bit or laser, offer and form the through hole 136 (Figure 18 (b)) that filled-type through hole connecting portion is used.
Secondly, after carrying out decontamination processing and additional catalyst processing, on interior whole, carry out chemical plating at the surface element that comprises through hole 136, and then, at the enterprising electroplating of chemical deposit.Whereby, with coating 153 filling vias 136, form surperficial back side connecting portion 142, the surperficial back side is switched on (Figure 18 (c)).
As chemical plating, can suitably carry out chemical nickel plating, electroless copper.Chemical plating is carried out in the plating bath of regulation after carrying out activation processing with catalyst.In addition, as plating, usually, carry out copper facing.
Secondly, carry out resist plate-making on the whole surperficial back side, the coating 153 that etching is exposed from resist forms connection distribution 141, removes resist, carries out clean as required, obtains this routine polymer electrolyte fuel cells (Figure 18 (d)).
Etching solution can be with the dividing plate 132 of the dividing plate 100B of fuel electrodes side and the air pole side etching solution of etching coating 153 optionally distinctively in addition.As this etching solution, can utilize iron chloride liquid etc., consider the material of dividing plate and the etching speed of copper wiring, the decision etching condition.
In addition, here,, but be not limited thereto with coating 153 filling vias 136.For example, also can add large through-hole 136, on the internal face of through hole 136, form coating 153 although make, the state behind the plating, the surperficial back side still is in the common through hole connecting portion of breakthrough status.
The formation method of connecting portion 140 shown in Figure 180 is an example, is not limited thereto.
In addition, like this, by between the unit cells of the adjacency of stipulating, the insulation division 134 that the thickness of constituent parts battery electric insulation is roughly identical with unit cells being set, as connecting portion 140, except that the through hole connection of existing extensive employing, can also adopt filling vias to connect, protrude connecting portion etc.In addition, the formation of connecting portion 140 is that electricity is stable to the not influence of constituent parts battery.
Secondly, second example of the form of implementation of polymer electrolyte fuel cells of the present invention be described based on Figure 19.
The molecule Electrolyte type fuel cell of second example shown in Figure 19 adopts the dividing plate 100B of second example shown in Figure 12.In this second example, the same with the polymer electrolyte fuel cells of first example, be that a plurality of unit cells 160 alignment arrangements are become plane, they in series are electrically connected, the polymer electrolyte fuel cells of the voltage of exportable number (for example, 4) corresponding to unit cells.Simultaneously, the insulation division 164 of thickness roughly the same with it is set on the part between the unit cells 160 that connecting portion 170 is set, integral body is made plane. promptly, its structure is, replaces the part of the polyelectrolyte membrane 163 between the unit cells of the adjacency that surperficial back side connecting portion 172 is set with insulation division 164.
In this case, respectively in the both sides of the polyelectrolyte membrane 163 of a plane tabular, the dividing plate 100B of the fuel electrodes side of a plurality of (for example 4) and air pole side dividing plate 162 are with the state configuration of separating respectively.And then the dividing plate 100B of the fuel electrodes side of constituent parts battery 160, air pole side dividing plate 162 sizes are identical, face mutually in identical position, and the constituent parts battery is separated.
In the case of this example, between the unit cells of adjacency of regulation with the insulation division 164 of constituent parts battery 160 electric insulations on situation with the polymer electrolyte fuel cells of first example the same, the surperficial back side connecting portion 172 of the connection usefulness of carrying out the surperficial back side of perforation is set.Simultaneously,, this back side, surface connecting portion 172 is connected on the dividing plate 162 of air pole side of the dividing plate 100B of fuel electrodes side of a unit cells of adjacency and another unit cells, is electrically connected between the unit cells with adjacency via connecting distribution 171.
In addition, here, in order to be easy to explanation, make that the unit cells number is 4, but also can be more than 5.
In the case of this example, each several part (material and structure) can be the same with the situation of the high molecular fuel battery of first example.
Secondly, the 3rd example of the form of implementation of polymer electrolyte fuel cells of the present invention be described based on Figure 20.
The polymer electrolyte fuel cells of the 3rd example as shown in figure 20, adopt this polymer electrolyte fuel cells of dividing plate 100B. of second example shown in Figure 12, with the part of size greater than a tabular polyelectrolyte membrane 183A of the size of a unit cells 180, as the dielectric film 183 of constituent parts battery 180, be configured to plane with identical direction a plurality of unit cells 180.It is in series to be electrically connected between a kind of unit cells 180 of the adjacency that will stipulate, and a plurality of unit cells all are connected in series, the polymer electrolyte fuel cells of exportable voltage corresponding to unit cells number (for example 4).In this polymer electrolyte fuel cells,, on the polyelectrolyte membrane 183A between the unit cells in the adjacency of regulation, surperficial back side connecting portion 192 is set for the electrical connection between the unit cells of the adjacency stipulated.
In this example, via connecting distribution 191, this back side, surface connecting portion 192 is connected on the dividing plate 182 of air pole side of the dividing plate 100B of fuel electrodes side of a unit cells 180 of adjacency and another unit cells 180, is electrically connected between the unit cells with adjacency.
In addition, here, in order to be easy to explanation, make that the unit cells number is 4, but also can be more than 5.
In this case, as connecting portion 190, on the polyelectrolyte membrane 183A between the unit cells of the adjacency of the regulation that connects the through hole connecting portion is set, perhaps the filling vias connecting portion protrudes connecting portion etc.
In above-mentioned example, enumerated the situation of the dividing plate 100B that uses second example shown in Figure 12, but similarly, the also suitable dividing plate 100A that uses first example shown in Figure 10, the dividing plate 100C of the 3rd example shown in Figure 13 can obtain the plane polymer electrolyte fuel cells of direct methanol type.
Industrial utilizability
As mentioned above, according to polymer electrolyte fuel cells of the present invention, be plane Be suitable for the fuel cell of thin form, in addition, dividing plate of the present invention is used for direct methanol type And be the polymer electrolyte fuel cells of plane, be suitable for equably fuel supplying, Use the polymer electrolyte fuel cells of this dividing plate, also be suitable for plane, thin The fuel cell of form.
Claims (13)
1. the dividing plate used of the plane polymer electrolyte fuel cells of a direct methanol type, in the dividing plate of the direct supply of fuel side that adopts the direct methanol type of methanol aqueous solution and use that acts as a fuel for the polymer electrolyte fuel cells of plane, it is characterized by
Have in the mode that is approximately perpendicular to its surperficial alignment arrangements and be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, on the surface of the fuel supplying of this tabular component, form supply of fuel with groove with the groove that couples together between the through hole, on each through hole, be connected with a plurality of supplies of fuel with groove or with the groove that couples together between the through hole.
2. the dividing plate that polymer electrolyte fuel cells as claimed in claim 1 is used; it is characterized by; aforementioned tabular component is matrix with the metal, at least on the surface element of the aforementioned substrates of the electrolyte side that becomes fuel cell, and the protective layer that configuration is made of the resin bed of acid resistance, conductivity.
3. the dividing plate that polymer electrolyte fuel cells as claimed in claim 2 is used; it is characterized by; aforementioned protective layer is to utilize to be mixed with carbon particle in resin; the electroplate liquid of the electric conducting material of the metal of corrosion resistance; by electroplating film forming; be heating and curing then and form; perhaps; the electrolyte that contains dopant by utilization carries out electrolysis polymerization; being formed in the film that contains the state of the dopant that improves conductivity in the resin that electroconductive polymer constitutes forms; perhaps; the resin impregnation that will be made of the electroconductive polymer that electrolysis polymerization forms is at the solution of dopant or contain in the solution of dopant molecule, and the film that constitutes the state that contains the dopant that improves conductivity forms.
4. the dividing plate used of the plane polymer electrolyte fuel cells of a direct methanol type, in the dividing plate of the direct supply of fuel side of using the direct methanol type of methanol aqueous solution and using that acts as a fuel as the polymer electrolyte fuel cells of plane, it is characterized by
Have in the mode that is approximately perpendicular to its surperficial alignment arrangements and be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, and the cap that covers a surface of this tabular component, on the surface of the aforementioned tabular component that contacts with aforementioned cap, form supply of fuel with groove with the groove that couples together between the through hole, between the aforementioned tabular component and cap of contact, aforementioned through-hole, aforementioned supply of fuel constitutes the supply of fuel stream with groove with the aforementioned grooves that couples together between the through hole, be connected with a plurality of supply of fuel grooves on each through hole or with through hole between the groove that couples together.
5. the dividing plate that polymer electrolyte fuel cells as claimed in claim 4 is used; it is characterized by; aforementioned tabular component is matrix with the metal, at least on the surface element of the aforementioned substrates of the electrolyte side that becomes fuel cell, and the protective layer that configuration is made of the resin bed of acid resistance, conductivity.
6. the dividing plate that polymer electrolyte fuel cells as claimed in claim 4 is used; it is characterized by; aforementioned protective layer is to utilize to be mixed with carbon particle in resin; the electroplate liquid of the electric conducting material of the metal of corrosion resistance; by electroplating film forming; be heating and curing then and form; perhaps; the electrolyte that contains dopant by utilization carries out electrolysis polymerization; being formed in the film that contains the state of the dopant that improves conductivity in the resin that electroconductive polymer constitutes forms; perhaps; the resin impregnation that will be made of the electroconductive polymer that electrolysis polymerization forms is at the solution of dopant or contain in the solution of dopant molecule, and the film that constitutes the state that contains the dopant that improves conductivity forms.
7. the dividing plate used of the plane polymer electrolyte fuel cells of a direct methanol type, in the dividing plate of the direct supply of fuel side of using the direct methanol type of methanol aqueous solution and using that acts as a fuel as the polymer electrolyte fuel cells of plane, it is characterized by
Have in the mode that is approximately perpendicular to its surperficial alignment arrangements and be provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, and the cap that covers a surface of this tabular component constitutes, on the surface of the aforementioned cap that contacts with aforementioned plate-shaped member, form supply of fuel with groove with the groove that couples together between the through hole, between the aforementioned tabular component and aforementioned cap of contact, the through-hole section of aforementioned tabular component, the supply of fuel of aforementioned cap constitute the supply of fuel path with groove with the groove that couples together between the through hole.
8. the dividing plate that polymer electrolyte fuel cells as claimed in claim 7 is used is characterized by, and is being connected with a plurality of supplies of fuel on each through hole with groove or the groove that couples together between with through hole.
9. the dividing plate that polymer electrolyte fuel cells as claimed in claim 7 is used; it is characterized by; aforementioned tabular component is matrix with the metal, at least on the surface element of the aforementioned substrates of the electrolyte side that becomes fuel cell, and the protective layer that configuration is made of the resin bed of acid resistance, conductivity.
10. the dividing plate that polymer electrolyte fuel cells as claimed in claim 7 is used; it is characterized by; aforementioned protective layer is to utilize to be mixed with carbon particle in resin; the electroplate liquid of the electric conducting material of corrosion-resistant metal; by electroplating film forming; be heating and curing then and form; or carry out electrolysis polymerization by the electrolyte that utilization contains dopant; being formed in the film that contains the state of the dopant that improves conductivity in the resin that is made of electroconductive polymer forms; perhaps; the resin impregnation that will be made of the electroconductive polymer that electrolysis polymerization forms is at the solution of dopant or contain in the solution of dopant molecule, and the film that constitutes the state that contains the dopant that improves conductivity forms.
11. polymer electrolyte fuel cells, in polymer electrolyte fuel cells the act as a fuel direct methanol type that directly adopts methanol aqueous solution and plane, that form by the dividing plate clamping polyelectrolyte of the dividing plate of supply of fuel side and air pole side, it is characterized by
The dividing plate of supply side acts as a fuel, employing has in the mode that is approximately perpendicular to its surperficial alignment arrangements and is provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, on the surface of the fuel supplying of this tabular component, form supply of fuel with groove with the groove that couples together between with through hole, on each through hole, be connected with a plurality of supplies of fuel with groove or dividing plate that the polymer electrolyte fuel cells that the groove that couples together between the through hole forms is used, via the through hole fuel supplying of this dividing plate.
12. polymer electrolyte fuel cells, in polymer electrolyte fuel cells the act as a fuel direct methanol type that directly utilizes methanol aqueous solution and plane, that form by the dividing plate clamping polyelectrolyte of the dividing plate of supply of fuel side and air pole side, it is characterized by
The dividing plate of supply side acts as a fuel, employing has in the mode that is approximately perpendicular to its surperficial alignment arrangements and is provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, and the cap that covers a surface of this tabular component, on the surface of the aforementioned tabular component that contacts with aforementioned cap, form supply of fuel with groove with the groove that couples together between the through hole, between the aforementioned tabular component and cap of contact, aforementioned through-hole, aforementioned supply of fuel constitutes the supply of fuel stream with groove with the aforementioned grooves that couples together between the through hole, on each through hole, be connected with a plurality of supplies of fuel with groove or polymer electrolyte fuel cells dividing plate that the groove that couples together between the through hole is formed, via the through hole fuel supplying of this dividing plate.
13. polymer electrolyte fuel cells, in polymer electrolyte fuel cells the act as a fuel direct methanol type that directly utilizes methanol aqueous solution and plane, that form by the dividing plate clamping polyelectrolyte of the dividing plate of supply of fuel side and air pole side, it is characterized by
The dividing plate of supply side acts as a fuel, employing has in the mode that is approximately perpendicular to its surperficial alignment arrangements and is provided with a plurality of tabular components of supply of fuel being given the through hole that the electrolyte side of fuel cell uses, and the cap that covers a surface of this tabular component constitutes, on the surface of the aforementioned cap that contacts with aforementioned plate-shaped member, form supply of fuel with groove with the groove that couples together between the through hole, between the aforementioned tabular component and aforementioned cap of contact, the through-hole section of aforementioned tabular component, the supply of fuel of aforementioned cap constitutes the polymer electrolyte fuel cells dividing plate of supply of fuel with path with groove with the groove that couples together between the through hole, via the through hole fuel supplying of this dividing plate.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP399963/2001 | 2001-12-28 | ||
| JP2001399862A JP2003197225A (en) | 2001-12-28 | 2001-12-28 | High polymer electrolyte fuel cell |
| JP399862/2001 | 2001-12-28 |
Related Parent Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CNB028056671A Division CN100367553C (en) | 2001-12-28 | 2002-12-26 | Polyelectrolyte type fuel cell and separator for polyelectrolyte type fuel cell |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN1783542A CN1783542A (en) | 2006-06-07 |
| CN100461501C true CN100461501C (en) | 2009-02-11 |
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| Application Number | Title | Priority Date | Filing Date |
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| CNB2005101285146A Expired - Fee Related CN100461501C (en) | 2001-12-28 | 2002-12-26 | Polymer electrolye fuel cell and separator for polymer electrolyte fuel cell |
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| Country | Link |
|---|---|
| JP (1) | JP2003197225A (en) |
| CN (1) | CN100461501C (en) |
Families Citing this family (24)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP3575477B2 (en) * | 2002-06-07 | 2004-10-13 | 日本電気株式会社 | Fuel cell |
| JP3693039B2 (en) * | 2002-06-07 | 2005-09-07 | 日本電気株式会社 | Liquid fuel supply type fuel cell |
| JP4042526B2 (en) | 2002-10-22 | 2008-02-06 | 株式会社日立製作所 | Sheet electrolyte membrane electrode assembly and fuel cell using the same |
| US7638219B2 (en) * | 2003-03-07 | 2009-12-29 | Honda Motor Co., Ltd. | Fuel cell without Z-like connection plates and the method producing the same |
| TWI251954B (en) * | 2003-07-29 | 2006-03-21 | Ind Tech Res Inst | Flat fuel cell assembly and fabrication thereof |
| JP4405196B2 (en) | 2003-08-22 | 2010-01-27 | 新光電気工業株式会社 | Solid electrolyte fuel cell |
| JP4674789B2 (en) * | 2004-03-31 | 2011-04-20 | 実 梅田 | Membrane electrode element manufacturing method, membrane electrode element and fuel cell |
| KR100760132B1 (en) * | 2005-02-28 | 2007-09-18 | 산요덴키가부시키가이샤 | Composite membrane and fuel cell using composite membrane |
| EP1727228A1 (en) * | 2005-05-24 | 2006-11-29 | Samsung SDI Co., Ltd. | Monopolar membrane-electrode assembly |
| JPWO2006126346A1 (en) * | 2005-05-25 | 2008-12-25 | コニカミノルタホールディングス株式会社 | PROTON CONDUCTIVE ELECTROLYTE MEMBRANE, MANUFACTURING METHOD THEREOF, AND SOLID POLYMER TYPE FUEL CELL USING THE PROTON CONDUCTIVE ELECTROLYTE MEMBRANE |
| JP4996061B2 (en) * | 2005-05-26 | 2012-08-08 | 株式会社東芝 | Polymer electrolyte fuel cell |
| KR100738061B1 (en) | 2006-05-16 | 2007-07-10 | 삼성에스디아이 주식회사 | Monopolar Membrane Electrode Assembly |
| JP5130692B2 (en) | 2006-10-27 | 2013-01-30 | ソニー株式会社 | Electrochemical device and manufacturing method thereof |
| JP5111869B2 (en) * | 2007-01-18 | 2013-01-09 | 三菱マテリアル株式会社 | Fuel cell |
| JP5183080B2 (en) | 2007-02-27 | 2013-04-17 | 三洋電機株式会社 | Fuel cell |
| JP2008293757A (en) * | 2007-05-23 | 2008-12-04 | Sanyo Electric Co Ltd | Fuel cell |
| JP5047122B2 (en) * | 2008-10-22 | 2012-10-10 | 実 梅田 | Membrane electrode element manufacturing method, membrane electrode element and fuel cell |
| JP5362406B2 (en) * | 2009-03-25 | 2013-12-11 | 三洋電機株式会社 | Fuel cell |
| CN102254857B (en) * | 2010-05-18 | 2015-11-25 | 异基因开发有限责任公司 | Semiconductor technology and structure |
| JP5617491B2 (en) * | 2010-09-29 | 2014-11-05 | 大日本印刷株式会社 | Membrane-electrode assembly intermediate, and membrane-electrode assembly intermediate, membrane-electrode assembly, and method for producing polymer electrolyte fuel cell |
| JP2014102876A (en) * | 2011-02-28 | 2014-06-05 | Sanyo Electric Co Ltd | Fuel cell |
| WO2012124326A1 (en) * | 2011-03-14 | 2012-09-20 | 三洋電機株式会社 | Fuel cell, and fuel cell manufacturing method |
| WO2013073271A1 (en) * | 2011-11-14 | 2013-05-23 | シャープ株式会社 | Electricity generating device |
| JP2013058500A (en) * | 2012-12-27 | 2013-03-28 | Sanyo Electric Co Ltd | Fuel cell |
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| CN1783542A (en) | 2006-06-07 |
| JP2003197225A (en) | 2003-07-11 |
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