초록 ▼

In a solid-oxide fuel cell system, a catalytic reformer unit provides reformate fuel for use by the cells in generating electricity. Both the reformer and the fuel cells require elevated temperatures for satisfactory operation. The reformer unit is provided with a combustion chamber and igniter ahe

In a solid-oxide fuel cell system, a catalytic reformer unit provides reformate fuel for use by the cells in generating electricity. Both the reformer and the fuel cells require elevated temperatures for satisfactory operation. The reformer unit is provided with a combustion chamber and igniter ahead of the catalytic reformer plates such that, during start-up, fuel/air mixture normally destined for reformation may be ignited in the combustion chamber to provide a hot combustion exhaust which is fed through the catalytic reformer and the anode reformate flow spaces to assist in rapidly bringing the fuel cell system to operating temperature.

대표청구항 ▼

What is claimed is: 1. A fuel cell system for generating electric power by combination of oxygen with reformate fuel, comprising: a) a plurality of individual fuel cells organized into at least one fuel cell stack assembly including a plurality of cathodes and anodes; b) a cover surrounding at leas

What is claimed is: 1. A fuel cell system for generating electric power by combination of oxygen with reformate fuel, comprising: a) a plurality of individual fuel cells organized into at least one fuel cell stack assembly including a plurality of cathodes and anodes; b) a cover surrounding at least a portion of said plurality of individual fuel cells, wherein a thermal jacket space is defined by said cover and said plurality of individual fuel cells: c) a reformer unit for combining pre-reformed hydrocarbon fuel and air into a fuel/air mixture and having catalytic elements in a reformer assembly for reforming said mixture to provide said reformate fuel to anode flow spaces in said stack assembly; d) a combustor chamber disposed within said reformer unit ahead of said catalytic surfaces and containing mixture-ignition means for controllably igniting said mixture to provide a hot combustor exhaust gas when temperatures in said fuel cell system are sub-optimal; and e) a manifold for conveying said exhaust gas from said fuel cell stack assembly to said thermal jacket space, wherein said exhaust gas passes from said combustor chamber through said reformer assembly, said fuel cell stack assembly, said manifold, and within said thermal jacket space to assist in elevating temperatures of said reformer and said fuel cell stack. 2. A fuel cell system in accordance with claim 1 further comprising a control system, and wherein timing of ignition of said fuel/air mixture in said combustor chamber is controlled by said control system. 3. A fuel cell system in accordance with claim 1 wherein said fuel cells are solid-oxide fuel cells. 4. A fuel cell system in accordance with claim 1 wherein said system is mounted on a vehicle. 5. A fuel cell system in accordance with claim 1 further comprising a heat exchanger in fluid communication with said manifold, wherein said heat exchanger is configured to transfer heat from said exhaust gas to incoming cathode air. 6. A fuel cell system in accordance with claim 4 wherein said vehicle is selected from the group consisting of car, truck, boat, and airplane. 7. A fuel cell system in accordance with claim 6 wherein said system is an auxiliary power unit for said vehicle. 8. A fuel cell system in accordance with claim 5 further comprising a tail gas combustor that burns said exhaust gas received from said fuel cell stack before being conveyed to said heat exchanger. 9. An automotive vehicle, comprising a fuel cell system for generating auxiliary power for said vehicle, said system including a plurality of individual fuel cells organized into at least one fuel cell stack assembly including a plurality of cathodes and anodes, a cover surrounding at least a portion of said plurality of individual fuel cells, wherein a thermal jacket space is defined by said cover and said plurality of individual fuel cells: a reformer unit for combining pre-reformed hydrocarbon fuel and air into a fuel/air mixture and having catalytic elements in a reformer assembly for reforming said mixture to provide said reformate fuel to anode flow spaces in said stack assembly; a combustor chamber disposed within said reformer unit ahead of said catalytic surfaces and containing mixture-ignition means for controllably igniting said mixture to provide a hot combustor exhaust gas when temperatures in said fuel cell system are sub-optimal; and a manifold for conveying said exhaust gas from said fuel cell stack assembly to said thermal jacket space, wherein said exhaust gas passes from said combustor chamber through said reformer assembly, said fuel cell stack assembly, said manifold, and within said thermal jacket space to assist in elevating temperatures of said reformer and said fuel cell stack. 10. An automotive vehicle in accordance with claim 9 further comprising a heat exchanger in fluid communication with said manifold, wherein said heat exchanger is configured to transfer heat from said exhaust gas to incoming cathode air. 11. An automotive vehicle in accordance with claim 10 further comprising a tail gas combustor that burns said exhaust gas received from said fuel cell stack before being conveyed to said heat exchanger.