Ceramic oxygen transport membrane array reactor and reforming method

What is claimed is: 1. An oxygen transport membrane panel for transferring radiant heat to a plurality of steam generators, the oxygen transport membrane panel comprising: a panel frame; and a plurality of oxygen transport membrane repeating units arranged in a tightly packed linear and co-planar orientation; wherein each oxygen transport membrane repeating unit comprises two or more oxygen transport membrane tubes coupled together configured to be in fluid communication with either a feed manifold or an exhaust manifold; wherein each oxygen transport membrane tube having a permeate side located on an interior surface of the tube and a retentate side located on an exterior surface of the oxygen transport membrane tube; wherein the plurality of oxygen transport membrane panels are configured to separate oxygen from an oxygen containing stream contacting the retentate side of the oxygen transport membrane tubes in cross-flow arrangement and react the permeated oxygen with a gas stream containing hydrogen fuel or hydrocarbon fuel introduced into the permeate side of the oxygen transport membrane tubes thereby producing radiant heat and a reaction product stream; wherein the plurality of steam generators are configured to produce steam from a source of feed water in the presence of the radiant heat from the oxygen transport membrane panels; and wherein the plurality of steam generators comprise a feed water, or feed steam manifold, a steam exhaust manifold, and a plurality of steam tubes disposed in a juxtaposed orientation with respect to the one or more the oxygen transport membrane tubes and the plurality of steam tubes in fluid communication with the feed water manifold and the steam collection manifold. 2. The oxygen transport membrane panel of claim 1 wherein said plurality of oxygen transport membrane repeating units are orientated within and supported by said panel frame. 3. The oxygen transport membrane panel of claim 2 wherein said plurality of oxygen transport membrane repeating units hang from said panel frame. 4. The oxygen transport membrane panel of claim 2 wherein the plurality of oxygen transport membrane tubes are arranged in a juxtaposed orientation. 5. The oxygen transport membrane panel of claim 4 wherein the plurality of oxygen transport membrane tubes are arranged in a serpentine orientation. 6. The oxygen transport membrane panel of claim 1 wherein the plurality of oxygen transport membrane tubes are arranged in a generally parallel orientation. 7. The oxygen transport membrane panel of claim 1 wherein the plurality of ceramic to ceramic coupling elements further comprise one or more ceramic linear connectors configured for fluidically coupling two adjacent oxygen transport membrane tubes in a linear orientation. 8. The oxygen transport membrane panel of claim 1 wherein the plurality of ceramic to ceramic coupling elements further comprise one or more ceramic U-shaped connectors configured for fluidically coupling two adjacent oxygen transport membrane tubes. 9. The oxygen transport membrane panel of claim 1 wherein the plurality of ceramic to ceramic coupling elements further comprise one or more ceramic M-shaped connectors configured for coupling three or more oxygen transport membrane tubes. 10. The oxygen transport membrane panel of claim 1 further comprising one or more isolation valve assemblies disposed between the first ceramic to metal coupling element and the feed manifold and/or between the second ceramic to metal coupling element and the exhaust manifold. 11. The oxygen transport membrane panel of claim 1 wherein said steam generators are configured to produce steam and/or supercritical steam from a source of feed water in the presence of the radiant heat from the oxygen transport membrane panels. 12. The oxygen transport membrane panel of claim 1 wherein each oxygen transport membrane tube is a composite material comprising a dense layer, a porous support and an intermediate porous layer located between the dense layer and the porous support, wherein said dense layer and the intermediate porous layer comprise a mixture of an ionic conductive material and an electrically conductive material effective in conducting oxygen ions and electrons. 13. An oxygen transport membrane array module comprising; a frame assembly one or more oxygen transport membrane panels according to claim 1 supported by said frame assembly, each panel comprising a plurality of oxygen transport membrane repeating units arranged in a tightly packed linear or co-planar orientation wherein each oxygen transport membrane repeating unit contains two or more oxygen transport membrane tubes coupled together at one end to form a multi-pass arrangement and the other end of the tubes configured to be in fluid communication with a fuel feed manifold and an exhaust manifold; and one or more steam generators, disposed in a juxtaposed orientation with respect to the one or more the oxygen transport membrane panels, wherein each steam generator comprises a plurality of steam tubes in fluid communication with a feed water manifold and a steam collection manifold. 14. The oxygen transport membrane array module of claim 13 wherein said plurality of steam tubes are arranged in an array separate and juxtaposed from the oxygen transport membrane panels. 15. An oxygen transport membrane based steam generating reactor for producing steam, said reactor comprising one or more oxygen transport membrane array modules in accordance with claim 13 . 16. The oxygen transport membrane based reactor of claim 15 wherein said one or more oxygen transport membrane array modules are housed in an insulated hot-air duct adjacent to a common feed water or feed steam drum arranged in a cooler zone and a common steam manifold or drum arranged in a separate zone apart from said cooler zone. 17. An oxygen transport membrane panel for transferring radiant heat to a process gas heater, the oxygen transport membrane panel comprising: a panel frame; and a plurality of oxygen transport membrane repeating units arranged in a tightly packed linear and co-planar orientation; wherein each oxygen transport membrane repeating unit comprises two or more oxygen transport membrane tubes coupled together at one end to form a multi-pass arrangement and the other end of the tubes configured to be in fluid communication with either a feed manifold or an exhaust manifold; wherein each oxygen transport membrane tube having a permeate side located on an interior surface of the tube and a retentate side located on an exterior surface of the oxygen transport membrane tube; wherein the plurality of oxygen transport membrane panels are configured to separate oxygen from an oxygen containing stream contacting the retentate side of the oxygen transport membrane tubes in cross-flow arrangement and react the permeated oxygen with a gas stream containing hydrogen fuel or hydrocarbon fuel introduced into the permeate side of the oxygen transport membrane tubes thereby producing radiant heat and a reaction product stream; wherein said plurality of process gas heaters are configured receive radiant heat from the oxygen transport membrane panels; and wherein the plurality of process gas heaters comprise a feed manifold, an exhaust manifold, and a plurality of process gas tubes disposed in a juxtaposed orientation with respect to the one or more the oxygen transport membrane tubes and the plurality of gas tubes in fluid communication with the feed manifold and the gas exhaust manifold. 18. An oxygen transport