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The present invention is directed to systems and processes of operating molten carbonate fuel cell systems. A process for operating the molten carbonate fuel cell includes providing a hydrogen-containing stream comprising molecular hydrogen from a high temperature hydrogen-separation device to a mol

The present invention is directed to systems and processes of operating molten carbonate fuel cell systems. A process for operating the molten carbonate fuel cell includes providing a hydrogen-containing stream comprising molecular hydrogen from a high temperature hydrogen-separation device to a molten carbonate fuel cell, wherein the high temperature hydrogen-separation device comprises one or more high temperature hydrogen-separating membranes; mixing at least a portion of hydrocarbons to be provided to, or provided to, a first reformer with anode exhaust from the molten carbonate fuel cell; at least partially reforming some of the hydrocarbons in the first reformer to produce a steam reforming feed; and providing the steam reforming feed to a second reformer, wherein the second reformer comprises the high temperature hydrogen-separation device or the second reformer is operatively coupled to the high temperature hydrogen-separation device, and the high temperature hydrogen-separation device is configured to produce at least a portion of the stream comprising molecular hydrogen provided to the molten carbonate fuel cell.

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1. A process of operating a molten carbonate fuel cell having an anode side and a cathode side, the process comprises: introducing into the anode side of the molten carbonate fuel cell a hydrogen-containing stream, comprising molecular hydrogen, yielded from a high temperature hydrogen-separation de

1. A process of operating a molten carbonate fuel cell having an anode side and a cathode side, the process comprises: introducing into the anode side of the molten carbonate fuel cell a hydrogen-containing stream, comprising molecular hydrogen, yielded from a high temperature hydrogen-separation device for separating hydrogen from a gas stream having a temperature of at least 250° C., wherein the high temperature hydrogen-separation device comprises one or more high temperature hydrogen-separating membranes, and yielding an anode exhaust and a cathode exhaust from the molten carbonate fuel cell;mixing hydrocarbons with the anode exhaust to provide a mixture of anode exhaust and hydrocarbons; and at least partially reforming some of the hydrocarbons thereof in a first reformer to produce a steam reforming feed; andproviding the steam reforming feed to a second reformer, wherein the second reformer is operatively coupled to the high temperature hydrogen-separation device such that the high temperature hydrogen-separation device is configured to produce the hydrogen-containing stream and a hydrogen-depleted stream comprising gaseous hydrocarbon and a carbon oxide. 2. The process of claim 1, wherein a mole fraction of the molecular hydrogen in the hydrogen-containing stream from the high temperature hydrogen-separation device is at least about 0.6. 3. The process of claim 1, further comprising controlling a flow rate of the hydrogen-containing stream to the molten carbonate fuel cell such that a molar ratio of water to molecular hydrogen in the anode exhaust stream is at most 1.0. 4. The process of claim 1, further comprising the steps of: contacting the hydrogen-depleted stream and an oxidant with a partial oxidation catalyst to produce a hot effluent stream, comprising carbon dioxide; and providing at least a portion of heat from the hot effluent stream to the first reformer while exchanging heat from the hot effluent stream with the mixture, and thereafter providing the hot exhaust stream to the cathode side of the molten carbonate fuel cell. 5. The process of claim 1, wherein the hydrocarbons mixed with the anode exhaust have a carbon number of at least 4. 6. The process of claim 1, further comprising mixing the hydrogen-containing stream from the high temperature hydrogen-separation device with an oxidant and generating electricity from the molten carbonate fuel cell at an electrical power density of at least 0.1 W/cm2. 7. A molten carbonate fuel cell system, comprising: a molten carbonate fuel cell having an anode side and a cathode side;a first reformer coupled to the molten carbonate fuel cell, the first reformer configured to receive hydrocarbons and an anode exhaust from the anode side of the molten carbonate fuel cell, and-being further configured to allow the anode exhaust to mix with the hydrocarbons to produce a hydrogen-containing steam reforming feed;a second reformer coupled to the first reformer, wherein the second reformer is configured to receive the hydrogen-containing steam reforming feed from the first reformer; and,a high temperature hydrogen-separation device for separating hydrogen from a gas stream having a temperature of at least 250° C. that is operatively connected to the second reformer, wherein the high temperature hydrogen-separation device comprises one or more high temperature hydrogen-separating membranes and is configured to provide a hydrogen-containing stream to the anode side of the molten carbonate fuel cell. 8. A fuel cell hydrogen-separation apparatus comprising: a first reformer defining a first reforming zone having a first reforming catalyst, wherein the first reformer is configured to receive hydrocarbons and a fuel cell anode exhaust, and wherein the first reformer dispenses a first reformed stream;a reformer-separator defining a second reforming zone, operatively connected to the first reformer for receiving the first reformed stream within the second reforming zone having a second reformer catalyst;an catalytic partial oxidation reformer operatively connected to the reformer-separator for receiving a reformed product gas from the reformer-separator and for partially oxidizing the reformed product gas to produce an effluent stream; and,a hydrogen separator positioned within the second reforming zone, wherein the hydrogen separator has a membrane providing for the separation of hydrogen from the second reforming zone. 9. The fuel cell hydrogen-separation apparatus of claim 8, wherein the second reforming zone is configured to perform at least one of a reforming reaction and a water-gas shift reaction on the first reformed stream. 10. The fuel cell hydrogen-separation apparatus of claim 8, wherein the first reforming catalyst comprises at least one of a metal and a substrate, wherein the metal is one of a Group VIII transition metal and the substrate is selected from the group consisting of α-alumina and zirconia. 11. The fuel cell hydrogen-separation apparatus of claim 8, wherein the second reforming catalyst comprises at least one of a metal and a substrate, wherein the metal is selected from the group consisting of Group VIII transition metals and the substrate contains an element selected from the group consisting of a Group III element and a Group IV element. 12. The fuel cell hydrogen-separation apparatus of claim 8, wherein the membrane is a tubular membrane. 13. A method comprising: a) providing a fuel cell having a cathode and an anode, wherein the anode receives a hydrogen-containing stream to yield an anode exhaust, and the cathode receives carbon dioxide and oxygen to yield a cathode exhaust;b) combining a stream of hydrocarbons with the anode exhaust to create a hydrocarbon-enriched anode exhaust;c) reforming within a first reforming zone the hydrocarbon-enriched anode exhaust to yield a reformed stream comprising hydrogen;d) reforming the reformed stream within a second reforming zone of a reformer-separator while separating hydrogen from the second reforming zone to yield the hydrogen-containing stream and a hydrogen-depleted stream;e) oxidizing the hydrogen-depleted stream in an oxidizing unit to yield a fuel stream; and,f) supplying the fuel stream to the anode of the fuel cell. 14. The method of claim 13, wherein a reaction selected from the group consisting of a reforming reaction and a water-gas shift reaction occurs within the reformer-separator. 15. The method of claim 13, wherein the reformer-separator comprises a hydrogen-selective permeable membrane located within the second reforming zone having catalysts and positioned such that the reformed stream contacts the hydrogen-selective permeable membrane allowing for passage of hydrogen therethrough to yield the hydrogen-containing stream. 16. The method of claim 13, wherein the hydrogen-depleted stream comprises compounds selected from the group consisting of a carbon oxide and a gaseous hydrocarbon. 17. The method of claim 13, wherein the oxidizing unit is a partial catalytic oxidation reformer.