초록 ▼

A solid oxide fuel cell generator (10) contains stacks of hollow axially elongated fuel cells (36) having an open top end (37), an oxidant inlet plenum (52), a feed fuel plenum (11), a combustion chamber (94) for combusting reacted oxidant/spent fuel; and, optionally, a fuel recirculation chamber (1

A solid oxide fuel cell generator (10) contains stacks of hollow axially elongated fuel cells (36) having an open top end (37), an oxidant inlet plenum (52), a feed fuel plenum (11), a combustion chamber (94) for combusting reacted oxidant/spent fuel; and, optionally, a fuel recirculation chamber (106) below the combustion chamber (94), where the fuel recirculation chamber (94) is in part defined by semi-porous fuel cell positioning gasket (108), all within an outer generator enclosure (8), wherein the fuel cell gasket (108) has a laminate structure comprising at least a compliant fibrous mat support layer and a strong, yet flexible woven layer, which may contain catalytic particles facing the combustion chamber, where the catalyst, if used, is effective to further oxidize exhaust fuel and protect the open top end (37) of the fuel cells.

대표청구항 ▼

What is claimed is: 1. A solid oxide fuel cell generator comprising: (1) stacks of hollow, axially elongated fuel cells, arranged in bundle stacks, each cell having at least one open top above an electrochemically active portion, which can react and operate on feed oxidant gas and feed hydrogen fue

What is claimed is: 1. A solid oxide fuel cell generator comprising: (1) stacks of hollow, axially elongated fuel cells, arranged in bundle stacks, each cell having at least one open top above an electrochemically active portion, which can react and operate on feed oxidant gas and feed hydrogen fuel gas to generate electricity; (2) an oxidant inlet plenum supporting oxidant feed tubes; (3) a feed fuel inlet plenum; (4) a combustion chamber for receiving and combusting reacted oxidant/spent fuel gases, located above the electrochemically active portion of the fuel cells and below the oxidant inlet plenum and containing the at least one open top of the fuel cells, said at least one open top being subject to localized burning, where the combustion chamber is defined by the oxidant inlet plenum, and a fuel cell positioning gasket, which gasket allows permeation of spent fuel gas into the combustion chamber; and (5) a fuel recirculation chamber, below the combustion chamber, said fuel recirculation chamber defined at least by the fuel cell positioning gasket; all surrounded by insulation and all within an outer generator enclosure, where the oxidant feed tubes have an open end in the oxidant inlet plenum and which oxidant feed tubes pass through the combustion chamber and into the at least one open fuel cell top within the combustion chamber, where the fuel cell positioning gasket closely gaskets the fuel cells while concurrently controlling the flow rate of the spent fuel gas electrochemically consumed, and controls gas flow into the combustion chamber by providing a pressure drop across the positioning gasket of from about 0.25 inches of water to 2.0 inches of water, where the fuel cell positioning gasket contains alumina and up to 40 wt. % silica and has a flexible laminate structure comprising at least a compliant fibrous mat layer and a flexible, woven layer facing the combustion chamber, where said woven layer is a nickel containing catalytic layer which promotes flameless combustion in the combustion chamber and provides a region where hydrogen fuel combustion would preferably occur, and where said gasket woven layer of the fuel cell positioning gasket protects the at least one open top of the fuel cells from localized burning of hydrogen, and the fuel cell positioning gasket is flexible and complies to accommodate variable cell bundle pitch. 2. The fuel cell generator of claim 1, wherein a lower fuel cell positioning board consisting essentially of a single layer of porous, low density alumina defines the bottom of the fuel recirculation chamber. 3. The fuel cell generator of claim 1, wherein the fuel cell positioning gasket mat support and woven layer are cemented, stitched or sewn together. 4. The fuel cell generator of claim 1, wherein the fuel cells fit tightly through perforations in the fuel cell positioning gasket, the feed oxidant is air, and the fuel cell positioning gasket is soft and compliant yet closely gaskets the fuel cells so that exhaust spent fuel permeation into the combustion chamber is controlled, and where materials used for the gasket have porosities of 90-99 vol. % allowing gas to diffuse evenly through it. 5. The fuel cell generator of claim 1, wherein the laminate structure of the gasket also contains a woven un-catalyzed layer facing the fuel recirculation chamber, where the gasket is flexible even in the initial state, allowing ease of installation over bundle rows. 6. The fuel cell generator of claim 1, wherein the gasket has perforations there through to accommodate the fuel cells, and also flow holes to allow gas diffusion. 7. The fuel cell generator of claim 1, wherein the gasket is of a sewn pillow configuration.