Integrated fuel cell block with a revised fuel cell cycle for in block reforming fuel cells

We claim: 1. A fuel cell system comprising: a fuel cell stack comprising at least one fuel cell, each fuel cell comprising an anode, a cathode, and an electrolyte; a reformer comprising cold-side channels and hot-side channels; a source of fuel; an anode loop for supplying fuel and reformate to the anode of each fuel cell, said anode loop comprising: a fuel inlet manifold in said fuel cell stack configured to supply fuel and reformate to the anode of each fuel cell; a fuel exhaust manifold configured to receive unused fuel from the anode of each fuel cell; an anode ejector configured to receive fuel from said fuel source and said fuel exhaust manifold; a pre-reformer configured to remove higher hydrocarbons from said fuel from said fuel source and said fuel exhaust manifold; the cold-side channels of said reformer configured to receive fuel from said anode ejector; a bypass line configured to bypass a portion of fuel exhausted by said anode ejector around said cold-side channels of said reformer; wherein said fuel ducting between said anode ejector and said pre-reformer is treated to prevent carbon formation; a source of oxidant; a compressor configured to receive oxidant from said oxidant source; a cathode loop for supplying oxidant to the cathode of each fuel cell, said cathode loop comprising: an oxidant inlet manifold in said fuel cell stack configured to supply oxidant to the cathode of each fuel cell; an oxidant exhaust manifold in said fuel cell stack configured to receive unused oxidant from each cathode of said fuel cells; a cathode ejector configured to receive oxidant from said oxidant source and said oxidant exhaust manifold and configured to supply oxidant to said oxidant inlet manifold; a catalytic start combustor unit between said oxidant inlet manifold and said oxidant exhaust manifold; wherein a portion of the oxidant exhausted from said oxidant exhaust manifold of said fuel cell stack passes through the hot-side channels of said reformer; a heat exchanger comprising hot-side and cold-side channels located upstream of said cathode ejector, wherein oxidant from said source of oxidant passes through said cold-side channels and an auxiliary loop for combusting a portion of the unused fuel from said fuel exhaust manifold and said portion of the unused oxidant from said oxidant exhaust manifold, said auxiliary loop comprising: an auxiliary ejector configured to receive said portion of the unused oxidant from the hot-side channels of said reformer, a portion of the oxidant from said source of oxidant, and a portion of the unused fuel from said fuel exhaust manifold; a combustor configured to combust the exhaust from said auxiliary ejector; and the hot-side channels of said heat exchanger configured to receive the combusted exhaust from said combustor; and a turbine configured to receive the exhaust from said combustor.