Fuel cell systems with in-block reforming

We claim: 1. A system comprising: a fuel cell block comprising: a fuel cell stack comprising a plurality of solid oxide fuel cells, each solid oxide fuel cell comprising an anode, a cathode, and an electrolyte; an in-block fueling flowpath comprising a first and second fuel supply manifolds, a first and second fuel exhaust manifolds, and one or more fueling channels in fluid communication with said first and second fuel supply manifolds and each respective first and second said fuel exhaust manifold, wherein each anode is exposed to a fuel flowing in one or more of said fueling channels; and an in-block oxidizing flowpath comprising an oxidant supply manifold, an oxidant exhaust manifold, and one or more oxidizing channels in fluid communication with said oxidant supply manifold and said oxidant exhaust manifold, wherein each cathode is exposed to an oxidant flowing in one or more oxidizing channels; an out-of-block oxidant flowpath comprising: a cathode ejector having an oxidant supply input, an oxidant recycle input, and a combined oxidant output; an oxidant supply conduit in fluid communication with said cathode ejector oxidant supply input; an oxidant source in fluid communication with said oxidant supply conduit; an oxidant recycle conduit in fluid communication with said cathode ejector oxidant recycle input and said in-block oxidizing flowpath oxidant exhaust manifold; and a combined oxidant supply conduit in fluid communication with said cathode ejector combined oxidant output and said in-block oxidizing flowpath oxidant supply manifold; an out-of-block fuel flowpath comprising: a first anode ejector having a first fuel supply input, a first fuel recycle input, and a first combined fuel output; a second anode ejector having a second fuel supply input, a second fuel recycle input, and a second combined fuel output; a fuel supply conduit in fluid communication with each said first and second anode ejector fuel supply input; a source of fuel in fluid communication with said fuel supply conduit; a first and second fuel recycle conduits in fluid communication with each respective said first and second anode ejector fuel recycle input and each respective said first and second in-block fueling flowpath fuel exhaust manifold; a first and second combined fuel supply conduits in fluid communication with each respective said first and second anode ejector combined fuel output and said in-block fueling flowpath fuel supply manifold, wherein said out-of-block fuel flowpath and said in-block fueling flowpath are configured to effect a recycle ratio in the range of 4.5 to 15 of a mass of fuel flowing into each said first and second anode ejector fuel recycle input to a mass of fuel flowing into each said first and second anode ejector fuel supply input, and a first pre-reformer between the first anode ejector and the first fuel supply manifold and a second pre-reformer between the second anode ejector and the second fuel supply manifold, each first and second pre-reformer located in a flowpath provided by said out-of-block fuel flowpath combined fuel supply conduit, wherein at least one of said first and second pre-former is an adiabatic catalytic converter configured to remove higher hydrocarbons from the fuel; an out-of-block auxiliary flowpath comprising: an auxiliary ejector having an oxidant supply input, a fuel exhaust input, an oxidant exhaust input, a recycle input, and an output; an auxiliary ejector oxidant supply conduit in fluid communication with said auxiliary ejector oxidant supply input and said oxidant source; an auxiliary ejector fuel exhaust conduit in fluid communication with said auxiliary ejector fuel exhaust input and said in-block fueling flowpath fuel exhaust manifold; an auxiliary ejector oxidant exhaust conduit in fluid communication with said auxiliary ejector oxidant exhaust input and said in-block oxidizing flowpath oxidant exhaust manifold; an auxiliary exhaust conduit in fluid communication with said auxiliary ejector output; and an auxiliary ejector recycle conduit in fluid communication with said auxiliary ejector recycle input and said auxiliary exhaust conduit, and a recuperator located upstream of the cathode ejector and the auxiliary ejector, and functioning to transfer heat between a turbine exhaust and an oxidant supplied by a compressor. 2. The system of claim 1 wherein said out-of-block fuel flowpath and said in-block fueling flowpath are configured to effect a ratio in the range of 6 to 8 of a mass of fuel flowing into each said first and second anode ejector fuel recycle input to a mass of fuel flowing into each said first and second anode ejector fuel supply input. 3. The system of claim 2 wherein said out-of-block fuel flowpath and said in-block fueling flowpath are configured to effect a ratio of about 7.5 of a mass of fuel flowing into each said first and second anode ejector fuel recycle input to a mass of fuel flowing into each said first and second anode ejector fuel supply input. 4. The system of claim 1 wherein said out-of-block fuel flowpath and said in-block fueling flowpath are configured to effect a weight percent of methane in a fluid flowing into said in-block fueling flowpath fuel supply manifold of no greater than eleven percent. 5. The system of claim 1 further comprising a combustor in a flowpath provided by said auxiliary exhaust conduit. 6. The system of claim 5 further comprising a heat exchanger for transferring thermal energy between a fluid output of said combustor and a fluid flowing in said combined oxidant supply conduit. 7. The system of claim 5 further comprising a heat exchanger for transferring thermal energy between a fluid output of said combustor and a fluid flowing in said out-of-block oxidant flowpath oxidant supply conduit. 8. A system comprising: a fuel cell block comprising: a fuel cell stack comprising a first and a second segment, each segment comprising a plurality of solid oxide fuel cells, each solid oxide fuel cell comprising an anode, a cathode, and an electrolyte; a first in-block fueling flowpath comprising a first fuel supply manifold, a first fuel exhaust manifold, and one or more first fueling channels in fluid communication with said first fuel supply manifold and said first fuel exhaust manifold, wherein each anode in said first segment is exposed to a fuel flowing in one or more of said first fueling channels; a second in-block fueling flowpath comprising a second fuel supply manifold, a second fuel exhaust manifold, and one or more second fueling channels in fluid communication with said second fuel supply manifold and said second fuel exhaust manifold, wherein each anode in said second segment is exposed to a fuel flowing in one or more of said second fueling channels; and an in-block oxidizing flowpath comprising an oxidant supply manifold, an oxidant exhaust manifold, and one or more oxidizing channels in fluid communication with said oxidant supply manifold and said oxidant exhaust manifold, wherein each cathode in said first and second segments is exposed to an oxidant flowing in one or more oxidizing channels; an out-of-block oxidant flowpath comprising: a cathode ejector having an oxidant supply input, an oxidant recycle input, and a combined oxidant output; an oxidant supply conduit in fluid communication with said cathode ejector oxidant supply input; an oxidant source in fluid communication with said oxidant supply conduit; an oxidant recycle conduit in fluid communication with said cathode ejector oxidant recycle input and said in-block oxidizing flowpath oxidant exhaust manifold; and a combined oxidant supply conduit in fluid communication with said cathode ejector combined oxidant output and said in-block