The present invention relates to fuel cells; more particularly, to such fuel cells having a solid oxide electrolyte; and most particularly, to such a fuel cell wherein the permeation of oxygen ions to the anode is controlled by controlling the electrical resistance of the cell non-uniformly.
Fuel cells which generate electric current by controllably combining elemental hydrogen and oxygen are well known. In one form of such a fuel cell, an anodic layer and a cathodic layer are separated by an electrolyte formed of a ceramic solid oxide. Such a fuel cell is known in the art as a “solid oxide fuel cell” (SOFC). Either pure hydrogen or reformate is flowed along the outer surface of the anode and diffuses into the anode. Oxygen, typically from air, is flowed along the outer surface of the cathode and diffuses into the cathode. Each O2 molecule is split and reduced to two O−2 ions at the cathode/electrolyte interface. The oxygen ions diffuse through the electrolyte and combine the anode/electrolyte interface with four hydrogen ions to form two molecules water. The anode and the cathode are connected externally through the load to complete the circuit whereby four electrons are transferred from the anode to the cathode. When hydrogen is derived from “reformed” hydrocarbons, the “reformate” gas includes CO which is also converted to CO2 at the anode/electrolyte interface.
A single cell is capable of generating a relatively small voltage and wattage, typically about 0.7 volts and less than about 2 watts per cm2 of active area. Therefore, in practice it is usual to stack together in electrical series a plurality of cells. Because each anode and cathode must have a free space for passage of gas over its surface, the cells are separated by perimeter spacers which are vented to permit flow of gas to the anodes and cathodes as desired but which form seals on their axial surfaces to prevent gas leakage from the sides of the stack. Adjacent cells are connected electrically by “interconnect” elements in the stack, and the outer surfaces of the anodes and cathodes are electrically connected to their respective interconnects by electrical contacts disposed within the gas-flow space, typically by a metallic foam or a metallic mesh which is readily gas-permeable or by conductive filaments. The outermost, or end, interconnects of the stack define electrical terminals, or “current collectors,” connected across a load. For electrochemical reasons well known to those skilled in the art, an SOFC requires an elevated operating temperature, typically 750° C. or greater.
For steric reasons, fuel cells may be rectangular in plan view. Typically, gas flows into and out of the cells through a vertical manifold formed by aligned perforations near the edges of the components, the hydrogen flowing from its inlet manifold to its outlet manifold across the anodes in a first direction, and the oxygen flowing from its inlet manifold to its outlet manifold across the cathodes in a second direction.
An important limitation to improving power densities and increasing fuel utilization in a solid oxide fuel cell is localized fuel starvation in regions of the anode. The anode typically includes an active metal such as nickel (Ni). In local regions of the anode in which the concentration of hydrogen in the fuel being supplied is partially depleted, the partial pressure of O−2 can build up because the oxygen ion mobility is enabled by a completed circuit at each local segment of the overall cell and is independent of the hydrogen concentration present. O−2 which is not scavenged immediately by hydrogen or CO can attack and oxidize nickel in the anode.
What is needed is a means for preventing the formation of local areas of high oxygen ion concentration at the anode to protect the anode from corrosive attack.
It is a principal object of the present invention to prevent formation of a locally corrosive concentration of O−2 at the anode of a solid oxide fuel cell.
It is a further object of the present invention to improve the overall power output of a fuel cell stack.
Briefly described, a fuel cell in accordance with the invention has a non-uniform electrical resistivity over the flow area of the cell. Resistance is higher in areas of the cell having locally low levels of hydrogen than in areas having locally high levels of hydrogen. Since the rate of oxygen ion migration through the electrolyte is inversely proportional to the resistance of the circuit at any give point in the cell, the areal pattern of resistance is shaped in inverse proportion to the steady-state hydrogen concentration. Excess oxygen ion migration and buildup is suppressed in regions having low hydrogen concentration and is correspondingly increased in regions having a surfeit of hydrogen. Thus, destructive oxidation of the anode is prevented and a greater percentage of the hydrogen passed into the cell is consumed, thereby increasing electric output.
In a first embodiment, the chemical composition of the anode or cathode itself is varied regionally to increase conductivity in regions of high hydrogen concentration and to decrease conductivity in hydrogen-poor regions.
In a second embodiment, the porosity of the cathode is varied to reduce or increase the permeability of oxygen through the cathode to coincide with the areas of low and high hydrogen concentrations.
In a third embodiment, the spatial density of conductive fibers extending between the anode and the interconnect or between the cathode and the interconnect is varied in direct proportion to the hydrogen concentration pattern in the cell.
In a fourth embodiment, the interconnects or current collectors are embossed in an areal pattern of protrusions to provide an areal pattern of contact points, resulting in a resistance gradient in accordance with the invention by providing an inverse conductivity gradient.
In a fifth embodiment, the anode surface or the mating interconnect surface is partially covered with dielectric material, as by a graded half-tone screen, or by thermal or plasma spraying, to provide an areal pattern of contact points, resulting in a resistance gradient between the areas of high hydrogen concentration and the areas of low hydrogen concentration.
In a sixth embodiment of the invention, the cathode or anode surface or the corresponding interconnect surface is covered with a wedge of dielectric material, the thickness of the layer being graded to provide a resistance gradient between the areas of high hydrogen concentration and the areas of low hydrogen concentration.
In a seventh embodiment of the invention, the thickness of the electrolyte element is varied to provide a resistance gradient between the areas of high hydrogen concentration and the areas of low hydrogen concentration.
These and other features and advantages of the invention will be more fully understood and appreciated from the following description of certain exemplary embodiments of the invention taken together with the accompanying drawings, in which:
a is a schematic cross-sectional view like that shown in
b is a schematic cross-sectional view like that shown in
c is a schematic cross-sectional view like that shown in
Referring to
Each fuel cell includes an electrolyte element 14 separating an anodic element 16 and a cathodic element 18. Each anode and cathode is in direct chemical contact with its respective surface of the electrolyte, and each anode and cathode has a respective free surface 20,22 forming one wall of a respective passageway 24,26 for flow of gas across the surface. Anode 16 of fuel cell B faces and is electrically connected to an interconnect 28 by filaments 30 extending across but not blocking passageway 24. Similarly, cathode 18 of fuel cell A faces and is electrically connected to interconnect 28 by filaments 30 extending across but not blocking passageway 26. Similarly, cathode 18 of fuel cell B faces and is electrically connected to a cathodic current collector 32 by filaments 30 extending across but not blocking passageway 26, and anode 16 of fuel cell A faces and is electrically connected to an anodic current collector 34 by filaments 30 extending across but not blocking passageway 24. Current collectors 32,34 may be connected across a load 35 in order that the fuel cell stack 10 performs electrical work. Passageways 24 are formed by anode spacers 36 between the perimeter of anode 16 and either interconnect 28 or anodic current collector 34. Passageways 26 are formed by cathode spacers 38 between the perimeter of electrolyte 14 and either interconnect 28 or cathodic current collector 32. Spacers 36,38 also serve to seal the perimeter of the stack against gas leakage and may be augmented by seals 37 (
Referring to
Preferably, the interconnect and the current collectors are formed of an alloy which is chemically and dimensionally stable at the elevated temperatures necessary for fuel cell operation, generally about 750° C. or higher, for example, Hastelloy. The electrolyte is formed of a ceramic oxide and preferably includes zirconia stabilized with yttrium oxide (yttria), known in the art as YSZ. The cathode is formed of, for example, porous lanthanum strontium manganate or lanthanum strontium iron, and the anode is formed, for example, of a mixture of nickel and YSZ.
Referring to
Known approaches to remedying this problem involve either using pressure gradients to cause the flow to be more uniform and/or providing aerodynamically improved entry and exit manifolding to expand and contract the flow smoothly. The former approach is undesirable because it results in reduced system efficiency due to pressure increase in the fuel flow, and the latter approach is undesirable because it requires very substantial increase in the size and shape of the stack to accommodate the smoothing manifolds.
The problem may be remedied in accordance with the present invention by any of a number of physical and/or chemical configurations as described below, all of which act to prevent the buildup of unacceptably high O−2 ion concentrations and to promote additional consumption of hydrogen by areally varying or grading the electrical resistance of the cell.
In a first embodiment, the chemical composition of either the cathode or the anode itself is varied regionally to increase or decrease local conductivity. The cathode comprises, for example, a chemical composition of lanthanum strontium manganate of lanthanum strontium iron. In the embodiment, the atomic proportion of lanthanum to strontium in the composition is varied across the cathode non-uniformly so that the atomic proportion is increased in regions of the cathode where high concentrations of hydrogen are found to exist. For example, in areas of high hydrogen concentration where greater conductivity is desired, the atomic proportion of lathanum to strontium may by 80% to 20%, respectively, while in areas of low concentration, the proportion would be reversed. The chemical composition of the anode can also be varied. The anode comprises a mixture of a conductive material, for example, nickel, and a dielectric material, for example YSZ. The nickel percentage is varied non-uniformly to provide more nickel, and hence greater conductivity, in regions of high hydrogen concentration and less nickel, and hence lesser conductivity, in hydrogen-poor regions.
In a second embodiment 50 referring to
In a third embodiment 55, referring to
In a fourth embodiment 60, referring to
In a fifth embodiment 65, referring to
In a sixth embodiment 70, 70′ of a fuel cell in accordance with the invention, referring to
Typically, the thickness of the electrolyte element is approximately 1 micron. In a seventh embodiment, the thickness of the electrolyte element is varied regionally to increase or decrease local conductivity. Where areas of low hydrogen concentration exists, the electrolyte is made thicker to decrease conductivity, and vice versa. The proper thickness gradient for a given fuel cell stack are readily determinable without undue experimentation.
Techniques for forming the dielectric deposits on the anodes, cathodes, interconnects, and current collectors, for varying the thickness of the electrolyte element, for forming protrusions on the interconnects and current collectors, and for varying the nickel content of the anodes, or the atomic proportions of the lanthanum and strontium of the cathode in the embodiments just recited are well within the skill of one skilled in the art of fuel cell manufacture; therefore, such techniques need not be recited here.
Also, in the embodiments shown herein, the cathode element has been described as comprising lanthanum strontium manganate or lanthanum strontium iron. It is understood that the cathode element can be comprised of other chemical compositions known in the art to which the composition can be varied to impart a localized affect on the conductivity of the cathode.
While the invention has been described by reference to various specific embodiments, it should be understood that numerous changes may be made within the spirit and scope of the inventive concepts described. Accordingly, it is intended that the invention not be limited to the described embodiments, but will have full scope defined by the language of the following claims.
Number | Name | Date | Kind |
---|---|---|---|
6230494 | Botti et al. | May 2001 | B1 |
6423896 | Keegan | Jul 2002 | B1 |
6485852 | Miller et al. | Nov 2002 | B1 |
6500574 | Keegan | Dec 2002 | B1 |
6509113 | Keegan | Jan 2003 | B1 |
6551734 | Simpkins et al. | Apr 2003 | B1 |
6562496 | Faville et al. | May 2003 | B1 |
6608463 | Kelly et al. | Aug 2003 | B1 |
6609582 | Botti et al. | Aug 2003 | B1 |
6613468 | Simpkins et al. | Sep 2003 | B1 |
6613469 | Keegan | Sep 2003 | B1 |
6620535 | Mukerjee et al. | Sep 2003 | B1 |
20020098400 | Mieney et al. | Jul 2002 | A1 |
Number | Date | Country | |
---|---|---|---|
20030077496 A1 | Apr 2003 | US |