Fuel cell devices and fuel cell systems are provided. In certain embodiments, the fuel cell devices may include one or more active layers containing active cells that are connected electrically in series. In certain embodiments, the fuel cell devices include an elongate ceramic support structure the
Fuel cell devices and fuel cell systems are provided. In certain embodiments, the fuel cell devices may include one or more active layers containing active cells that are connected electrically in series. In certain embodiments, the fuel cell devices include an elongate ceramic support structure the length of which is the greatest dimension such that the coefficient of thermal expansion has only one dominant axis coextensive with the length. In certain embodiments, a reaction zone is positioned along a first portion of the length for heating to a reaction temperature, and at least one cold zone is positioned along a second portion of the length for operating below the reaction temperature. There are one or more gas passages, each having an associated anode or cathode.
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1. A fuel cell device comprising: a ceramic support structure having an interior structure defined by an exterior surface and having a reaction zone configured to be heated to an operating reaction temperature, and having at least a first active layer within the interior structure in the reaction zo
1. A fuel cell device comprising: a ceramic support structure having an interior structure defined by an exterior surface and having a reaction zone configured to be heated to an operating reaction temperature, and having at least a first active layer within the interior structure in the reaction zone, the first active layer comprising: a ceramic electrolyte layer,a plurality of spaced apart first electrodes positioned on a first side of the ceramic electrolyte layer, anda plurality of spaced apart second electrodes positioned on a second side of the ceramic electrolyte layer, wherein the first electrodes are opposite in polarity to the second electrodes, each being selected from anodes and cathodes, and wherein each one of the plurality of spaced apart first electrodes is in opposing relation to a respective one of the plurality of spaced apart second electrodes with the ceramic electrolyte layer therebetween, each opposing first and second electrode forming an active cell whereby a plurality of spaced apart active cells are positioned across the first active layer; anda plurality of conductive elements extending within the interior structure between the plurality of spaced apart active cells wherein each of the plurality of conductive elements physically contacts the first electrode of one active cell, extends through the ceramic electrolyte layer in the space adjacent the one active cell, and physically contacts the second electrode of the adjacent spaced apart active cell thereby connecting the plurality of active cells in series in the first active layer,the fuel cell device further comprising one or more additional active layers identical to and stacked upon the first active layer within the interior structure in spaced relation and with alternating polarity, wherein a first gas passage is positioned adjacent each plurality of spaced apart first electrodes and a second gas passage is positioned adjacent each plurality of spaced apart second electrodes thereby providing the spaced relation, wherein the plurality of spaced apart first electrodes of adjacent active layers are in opposing relation with the first gas passage shared therebetween, and the plurality of spaced apart second electrodes of adjacent active layers are in opposing relation with the second gas passage shared therebetween. 2. The fuel cell device of claim 1 further comprising a first electrical connector between each of the opposed plurality of spaced apart first electrodes of adjacent active layers and a second electrical connector between each of the opposed plurality of spaced apart second electrodes of adjacent active layers thereby connecting the first and additional active layers in parallel. 3. The fuel cell device of claim 2, wherein the first and second electrodes and the first and second electrical connectors are porous and the first and second conductive elements are non-porous. 4. The fuel cell device of claim 3, wherein each of the first electrical connectors comprise a portion of each of the opposed plurality of spaced apart first electrodes of adjacent active layers extending into the shared first gas passage and making physical contact therein, and wherein each of the second electrical connectors comprise a portion of each of the opposed plurality of spaced apart second electrodes of adjacent active layers extending into the shared second gas passage and making physical contact therein. 5. A fuel cell device comprising: a ceramic support structure having an interior structure defined by an exterior surface and having a reaction zone configured to be heated to an operating reaction temperature, and having at least a first active layer within the interior structure in the reaction zone, the first active layer comprising: a ceramic electrolyte layer,a plurality of spaced apart first electrodes positioned on a first side of the ceramic electrolyte layer, anda plurality of spaced apart second electrodes positioned on a second side of the ceramic electrolyte layer, wherein the first electrodes are opposite in polarity to the second electrodes, each being selected from anodes and cathodes, and wherein each one of the plurality of spaced apart first electrodes is in opposing relation to a respective one of the plurality of spaced apart second electrodes with the ceramic electrolyte layer therebetween, each opposing first and second electrode forming an active cell whereby a plurality of spaced apart active cells are positioned across the first active layer; anda plurality of conductive elements extending within the interior structure between the plurality of spaced apart active cells wherein each of the plurality of conductive elements physically contacts the first electrode of one active cell, extends through the ceramic electrolyte layer in the space adjacent the one active cell, and physically contacts the second electrode of the adjacent spaced apart active cell thereby connecting the plurality of active cells in series in the first active layer,wherein the ceramic support structure is an elongate spiral-rolled tubular structure having a length extending between a first end and a second end and having an outside rolled edge and an inside rolled edge, wherein the active cells in series in the first active layer are arranged in first and second portions, the first portion being adjacent the first end and the second portion being adjacent the second end, each portion comprising the active cells spaced apart between the outside rolled edge and the inside rolled edge, and wherein an electrical path for the active cells travels from the outside rolled edge inward along the first portion of active cells in spiral fashion to the inside rolled edge then outward along the second portion of active cells in spiral fashion to the outside rolled edge. 6. A fuel cell device comprising: a ceramic support structure having a reaction zone configured to be heated to an operating reaction temperature, and having at least a first active layer therein in the reaction zone, wherein the ceramic support structure is an elongate spiral-rolled tubular structure having a length extending between a first end and a second end and having an outside rolled edge and an inside rolled edge;a ceramic electrolyte layer in the first active layer;a plurality of spaced apart first electrodes in the first active layer positioned on a first side of the ceramic electrolyte layer;a plurality of spaced apart second electrodes in the first active layer positioned on a second side of the ceramic electrolyte layer, wherein the first electrodes are opposite in polarity to the second electrodes, each being selected from anodes and cathodes, and wherein each one of the plurality of spaced apart first electrodes is in opposing relation to a respective one of the plurality of spaced apart second electrodes with the ceramic electrolyte layer therebetween, each opposing first and second electrode forming an active cell whereby a plurality of spaced apart active cells are positioned across the first active layer;a plurality of conductive elements extending between the plurality of spaced apart active cells wherein each of the plurality of conductive elements physically contacts the first electrode of one active cell, extends through the ceramic electrolyte layer in the space adjacent the one active cell, and physically contacts the second electrode of the adjacent spaced apart active cell thereby connecting the plurality of active cells in series in the first active layer, wherein the active cells in series in the first active layer are arranged in first and second portions, the first portion being adjacent the first end and the second portion being adjacent the second end, each portion comprising the active cells spaced apart between the outside rolled edge and the inside rolled edge, and wherein an electrical path for the active cells travels from the outside rolled edge inward along the first portion of active cells in spiral fashion to the inside rolled edge then outward along the second portion of active cells in spiral fashion to the outside rolled edge;a plurality of first gas passages extending from the first end along the length to a first exhaust passage adjacent the second end, the first gas passages each feeding a first gas through the first end to the first electrode of an active cell in each of the first and second portions, and the first exhaust passage extending from the first gas passage adjacent the inside rolled edge to the outside rolled edge to exhaust the first gas; anda plurality of second gas passages extending from the second end along the length to a second exhaust passage adjacent the first end, the second gas passages each feeding a second gas through the second end to the second electrode of an active cell in each of the first and second portions, and the second exhaust passage extending from the second gas passage adjacent the inside rolled edge to the outside rolled edge to exhaust the second gas. 7. A fuel cell device comprising: a ceramic support structure having an interior structure defined by an exterior surface and having a reaction zone configured to be heated to an operating reaction temperature, and having at least a first active layer within the interior structure in the reaction zone, the first active layer comprising: a ceramic electrolyte layer,a plurality of spaced apart first electrodes positioned on a first side of the ceramic electrolyte layer, anda plurality of spaced apart second electrodes positioned on a second side of the ceramic electrolyte layer, wherein the first electrodes are opposite in polarity to the second electrodes, each being selected from anodes and cathodes, and wherein each one of the plurality of spaced apart first electrodes is in opposing relation to a respective one of the plurality of spaced apart second electrodes with the ceramic electrolyte layer therebetween, each opposing first and second electrode forming an active cell whereby a plurality of spaced apart active cells are positioned across the first active layer; anda plurality of conductive elements extending within the interior structure between the plurality of spaced apart active cells wherein each of the plurality of conductive elements physically contacts the first electrode of one active cell, extends through the ceramic electrolyte layer in the space adjacent the one active cell, and physically contacts the second electrode of the adjacent spaced apart active cell thereby connecting the plurality of active cells in series in the first active layer,wherein the ceramic support structure is an elongate spiral-rolled tubular structure having a length extending between a first end and a second end and having an outside rolled edge and an inside rolled edge, wherein the active cells in series in the first active layer extend between the outside and inside rolled edges and are spaced apart between the first and second ends, and wherein an electrical path for the active cells travels from the first end to the second end. 8. The fuel cell device of claim 7 further comprising a first conductive end portion integral with the first end of the ceramic support structure and a second conductive end portion integral with the second end of the ceramic support structure, wherein the electrical path further extends to the first and second conductive end portions. 9. A fuel cell device comprising: a ceramic support structure having a reaction zone configured to be heated to an operating reaction temperature, and having at least a first active layer therein in the reaction zone, wherein the ceramic support structure is an elongate spiral-rolled tubular structure having a length extending between a first end and a second end and having an outside rolled edge and an inside rolled edge;a ceramic electrolyte layer in the first active layer;a plurality of spaced apart first electrodes in the first active layer positioned on a first side of the ceramic electrolyte layer;a plurality of spaced apart second electrodes in the first active layer positioned on a second side of the ceramic electrolyte layer, wherein the first electrodes are opposite in polarity to the second electrodes, each being selected from anodes and cathodes, and wherein each one of the plurality of spaced apart first electrodes is in opposing relation to a respective one of the plurality of spaced apart second electrodes with the ceramic electrolyte layer therebetween, each opposing first and second electrode forming an active cell whereby a plurality of spaced apart active cells are positioned across the first active layer;a plurality of conductive elements extending between the plurality of spaced apart active cells wherein each of the plurality of conductive elements physically contacts the first electrode of one active cell, extends through the ceramic electrolyte layer in the space adjacent the one active cell, and physically contacts the second electrode of the adjacent spaced apart active cell thereby connecting the plurality of active cells in series in the first active layer, wherein the active cells in series in the first active layer extend between the outside and inside rolled edges and are spaced apart between the first and second ends, and wherein an electrical path for the active cells travels from the first end to the second end;a first entrance passage extending from the first end adjacent the inner rolled edge along the length to adjacent the second end and a plurality of first gas passages extending from the first entrance passage to the outside rolled edge, the first entrance passage feeding a first gas to the first gas passages, and the first gas passages each feeding the first gas to the first electrode of a respective active cell and to exhaust at the outside rolled edge; anda second entrance passage extending from the second end adjacent the inner rolled edge along the length to adjacent the first end and a plurality of second gas passages extending from the second entrance passage to the outside rolled edge, the second entrance passage feeding a second gas to the second gas passages, and the second gas passages each feeding the second gas to the second electrode of a respective active cell and to exhaust at the outside rolled edge.
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