Fuel cell cathodes

Abstract

Methods of making fuel cell electrodes in which the pores of an electrically conductive metal substrate are filled with a slurry containing particles of the same or a different electrically conductive metal. The liquid phase of the slurry is removed, leaving the particles of conductive material in the pores of the substrate; and the conductive metal(s) making up the substrate and the metal particles supplied from the slurry are converted to oxide.

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates to fuel cells and, more specifically, to novel, improved fuel cell electrodes and to processes for making those electrodes.

BACKGROUND OF THE INVENTION

Fuel cells were invented in 1839 by Sir William Grove. A fuel cell is an electrochemical device which directly combines a fuel such as hydrogen and an oxidant such as oxygen to produce electricity and water. It has an anode and a cathode spanned by an electrolyte. Hydrogen is oxidized to hydrated protons on the anode with an accompanying release of electrons. At the cathode, oxygen reacts with protons to form water, consuming electrons in the process. Electrons flow from the anode to the cathode through an external load, and the circuit is completed by ionic current transport through the electrolyte.

Fuel cells do not pollute the environment. They operate quietly, and they have a potential efficiency of ca. 80 percent. Virtually any natural or synthetic fuel from which hydrogen can be extracted can be employed.

A variety of electrolytes have been proposed. These include: aqueous potassium hydroxide, concentrated phosphoric acid, fused alkali carbonates, and stabilized zirconium oxide. Molten carbonate fuel cell (MCFC) power plants are of particular interest. Like others, molten carbonate fuel cells produce electrical energy via electrochemical reaction between hydrogen and an oxidant. Fuels such as reformed natural gas, reformed naphtha, and gasified coal are used as a source of hydrogen. The oxidant is air mixed with the byproduct CO.sub.2 produced by the anode reaction. It is generally accepted that the electrochemical reactions taking place are as follows.

In the anode:

H.sub.2 +CO.sub.3.sup.2- .fwdarw.H.sub.2 O+CO.sub.2 +2e.fwdarw.(1) where e are the electrons that move from anode to cathode, producing an electrical current. The CO.sub.2 produced by the previous reaction is recovered and mixed with air and used as the oxidant in the cathode, where the reaction is: 1/2O.sub.2 +CO.sub.2 +2e.fwdarw.CO.sub.3.sup.2- ( 2) The carbonate ions (CO.sub.3.sup.2-) move through the electrolyte to the anode, completing the cycle.

Molten carbonate fuel cell components are thin, flat materials with a porosity and pore size distribution carefully tailored for proper electrolyte distribution by virtue of capillarity. The basic cell package typically consists of an anode, a cathode, current collectors, and an electrolyte structure composed of a matrix and an electrolyte retained in the matrix by capillarity. Because of cost, performance, and endurance considerations, the basic components of a MCFC fuel cell must be: easily manufactured by simple scalable techniques, stable in the fuel cell, and able to meet threshold performance levels.

Current molten carbonate fuel cells use nickel-based electrodes. The anode also contains hardening and strengthening agents such as chromium and aluminum that form lithium chromite and alumina or lithium aluminate during cell operation. State-of-the-art cathodes consist of a porous nickel plaque that is allowed to oxidize in-situ during cell operation in the presence of the molten alkali carbonate electrolyte to form an oxide semiconductor, known in the art as lithiated nickel oxide (LNO), which has the formula (Li.sub.x Ni.sub.(1-x) O).

The nickel plaque used as a cathode is sintered in a reducing environment at an elevated temperature to promote sintering, a step in which nickel particles bond to each other and develop strength. Upon oxidation, the sintering bonds are disrupted; and the cathode loses strength. Consequently, there is a present and continuing need for improved cathodes for fuel cells of the type currently employing nickel plaque cathodes.

SUMMARY OF THE INVENTION

It has now been found that the propensity of conventional, nickel plaque MCFC cathodes to lose strength under operating conditions can be significantly reduced by fiber reinforcment of the porous plaque. The reinforcement helps to distribute the load throughout the structure and prevents concentration of local stresses that would cause fracture. At the same time, the reinforcement can be incorporated in the cathode structure without any adverse effect on cell performance.

The objects, features, and advantages of the invention will be apparent to the reader from the foregoing and the appended claims and as the ensuing detailed description and discussion of the invention proceeds in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWING

The single FIGURE is a section through a fuel cell which may be provided with a fiber reinforced cathode embodying the principles of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to the drawing, the single FIGURE depicts a molten carbonate fuel cell 20 having an anode 22, a cathode 24, and an electrolyte matrix 26. Anode 22 is housed in anode flange 28 along with anode current collector 30 while cathode 24 is housed in cathode flange 32 along with cathode current collector 34.

Anode 22 may have a composition of Ni+Cr or Ni+Al. The Cr or the Al content can be 0.5 to 10 percent by weight.

The electrolyte matrix 26 is typically LiAlO.sub.2 with a nominal porosity of 45% to 70% and a mean pore size of 0.1 to 0.7 .mu.m. The porous LiAlO.sub.2 structure is impregnated with a mixture of Li.sub.2 CO.sub.3 and K.sub.2 CO.sub.3, usually the eutectic composition which is 62% by mole Li.sub.2 CO.sub.3 and 38% by mole K.sub.2 CO.sub.3. The electrolyte matrix prevents the mixing of the fuel and the oxidant supplied through the channels of the flanges 28 and 32, respectively. The perimeter of the electrolyte matrix seals against the raised edges of the flanges to prevent the fuel and the oxidant from leaking into the external atmosphere.

A typical fuel that is fed through the channels of the anode flange 28 is a humidified mixture of H.sub.2 and CO.sub.2, and a typical oxidant that is fed through the cathode flange 32 channels is a humidified mixture of air and CO.sub.2.

It is a salient feature of the present invention that the loss in strength of a conventional nickel fuel cell cathode attributable to the conversion of a continuous nickel phase to an agglomeration of NiO particles can be offset by fiber reinforcement. This makes it possible to relax the requirements for current collector 34 or to even altogether eliminate that component. In both cases, the integrity of the cell is significantly improved.

Fiber reinforced green structures which can be converted to NiO MCFC cathodes by in situ oxidation can be fabricated, in accord with the principles of the present invention, by impregnating an appropriate nickel mat reinforcement with a slurry of nickel powder to provide the surface area and porosity needed for efficient MCFC operation.

One satisfactory starting material, which contains fine nickel fibers suitable as reinforcements, is marketed by National Standard under the trade name FIBREX. As-received FIBREX mats, however, could not be used as a MCFC cathode. FIBREX has large, unacceptable, see-through pores and high porosity (85%-95%), which makes it unusable for MCFC cathodes; and it does not contain enough nickel powder to provide sufficient surface area for electrode reaction.

A slurry method is employed to impregnate the mat with nickel particles. This reduces porosity and increases the reaction surface area and thereby converts the FIBREX mat to a structure capable of functioning efficiently as a fuel cell cathode.

Typically, a slurry of nickel powder is cast onto a flat substrate by a doctor blade. The FIBREX mat is laid on the slurry, and the tape is allowed to dry. This results in the impregnation of nickel through approximately half of the mat thickness. After the tape drys, it is removed from the substrate.

A second nickel slurry is cast, and the unimpregnated side of the mat is laid on the nickel slurry. This results in the impregnation of the other side of the mat by the particulate nickel slurry. Thereafter, the tape and mat are dried; and the second tape is removed to complete the fabrication of the green cathode structure.

Additional details of a tape casting process which can be adapted to the casting of particulate metal tapes as just described are available in companion application Ser. No. 07/881,686.

Normally, a tape cast nickel cathode is sintered in a furnace at a temperature of 800.degree.-1100.degree. C. in a reducing atmosphere before it is assembled in a cell. The green electrode structures of the present invention have the advantage that they can be directly assembled in the cell without sintering, therefore costing less to process. After assembling the green structure in a cell such as that identified by reference character 20, the cell can be heated to its operating temperature of 600.degree.-700.degree. C. according to normal procedure.

Additional details of a MCFC cathode as disclosed herein appear in the working example which follows:

EXAMPLE I

A nickel mat having about 95% porosity and a fiber/powder ratio of 80/20 was impregnated as described above to produce a green, nickel, cathode structure with 84% porosity, a final fiber/powder ratio of 39/61, and a thickness of 30 mils. The green structure was converted in situ in the manner also discussed above to a fiber reinforced cathode in a 3 cm.sup.2 MCFC test cell.

The cell performance was quite acceptable. It yielded a cell potential of 855 mV at 160 mA/cm.sup.2 using an oxidant of 30 CO.sub.2 /70 air humidified at room temperature and a fuel of 75 H.sub.2 /25 CO.sub.2 humidified at 60.degree. C.

Many modifications may be made without exceeding the scope of the invention. For example, pore matching of the cathode with other active MCFC components can be employed to optimize the performance of an endless variety of MCFC's with cathodes embodying the principles of the present invention. Also, the reinforcement can be in the form of loose fibers, screen, expanded metal, and other materials with construction elements in a form having a large length-to-diameter ratio; and the reinforcement material can be based on cobalt, silver, copper, iron, aluminum or their stable products in the cathode environment. The present embodiment is therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims

1. A method of making a fuel cell electrode possessing structural integrity after being operated at high temperatures for extended periods of time, said method comprising the steps of:

filling the pores of a porous, fibrous, electrically conductive, metal substrate with a slurry containing particles of the same or a different electrically conductive metal;

so removing the liquid phase of the slurry as to leave the particles of electrically conductive metal in the pores of the metal substrate; and

converting the conductive metal or metals to oxides;

the pores of the substrate being filled with the slurry by: casting the slurry onto a surface in a tape of controlled thickness, placing one side of the substrate on the cast surface, and thereafter drying and then removing the tape.

2. A method as defined in claim 1 in which:

it is a first portion of said slurry that is cast onto a surface to provide said tape of controlled thickness and a second portion of the slurry is cast onto a surface to provide a second tape which is also of controlled thickness;

the substrate is placed on the second tape with the opposite, unimpregnated side of the substrate in contact with the second tape; and

the second tape is then dried and removed.

3. A method as defined in claim 1 in which the substrate comprises elemental cobalt, nickel, silver, copper or a form of one of those elements which is stable at an elevated temperature.

4. A method as defined in claim 1 in which the substrate is composed of elements having a large length-to-diameter ratio.

5. A method as defined in claim 4 in which the substrate is composed of loose fibers or a mat or screen or is fabricated from expanded metal.

6. A method as defined in claim 1 in which the substrate is a porous mat composed of nickel fibers and nickel powder.

7. A method as defined in claim 6 in which the electrically conductive metal in the slurry is elemental nickel in powder form.

8. A method as defined in claim 1 in which the metal(s) of the substrate and the particles are converted to oxides by heating the cathode in situ in a fuel cell and in a reducing temperature.

9. A method of making a fuel cell electrode possessing structural integrity after being operated at high temperatures for extended periods of time, said method comprising the steps of:

filling the pores of a porous, fibrous, electrically conductive, metal substrate with a slurry containing particles of the same or a different electrically conductive metal;

so removing the liquid phase of the slurry as to leave the particles of electrically conductive metal in the pores of the metal substrate; and

converting the conductive metal or metals to oxides;

the metal(s) of the substrate and the particles being converted to oxides by heating the cathode in situ in a fuel cell and in a reducing temperature.

10. A method as defined in claim 9 in which the pores of the substrate are filled with the slurry by:

casting the slurry onto a surface in a tape of controlled thickness;

placing one side of the substrate on the cast surface; and

thereafter drying and then removing the tape.

11. A method as defined in claim 10 in which:

it is a first portion of said slurry that is cast onto a surface to provide said tape of controlled thickness and a second portion of the slurry is cast onto a surface to provide a second tape which is also of controlled thickness;

the substrate is placed on the second tape with the opposite, unimpregnated side of the substrate in contact with the second tape; and

the second tape is then dried and removed.

12. A method as defined in claim 9 in which the substrate comprises elemental cobalt, nickel, silver, copper or a form of one of those elements which is stable at an elevated temperature.

13. A method as defined in claim 9 in which the substrate is composed of elements having a large length-to-diameter ratio.

14. A method as defined in claim 12 in which the substrate is composed of loose fibers or a mat or screen or is fabricated from expanded metal.

15. A method as defined in claim 9 in which the substrate is a porous mat composed of nickel fibers and nickel powder.

16. A method as defined in claim 14 in which the electrically conductive metal in the slurry is elemental nickel in powder form.