Steam reformer bypass line and flow controller

We claim: 1. A reformer unit for a fuel cell system comprising: a reforming section configured to reform a hydrocarbon-containing fuel, said reforming section having an inlet adapted for fluid communication with a source of hydrocarbon-containing fuel, and an outlet adapted for fluid communication with an anode inlet of a fuel cell stack; a heat exchanging section configured to heat a fluid flowing in the reforming section, said heat exchanging section having an inlet adapted for fluid communication with an exhaust of a cathode of a fuel cell stack, and an outlet adapted for fluid communication with an inlet of a cathode of the fuel cell stack, said heat exchanging section being in thermal communication with said reforming section to effect heat transfer between a fluid flowing through said heat exchanger section and a fluid flowing through said reforming section; and a bypass section configured to provide a bypassing flowpath for a hydrocarbon-containing fuel around said reforming section, said bypass section having an inlet in fluid communication with said reforming section inlet, an outlet in fluid communication with said reforming section outlet, and a variable orifice flow controller positioned in the bypassing flowpath, wherein said variable orifice flow controller comprises: an upstream connector having a cylindrical tubular portion defining a conduit in fluid communication with the bypassing flowpath for receiving fluid flowing within the flowpath, and a frusto-conical portion defining a plurality of conduits in fluid communication with the conduit defined by said cylindrical tubular portion; a downstream connector defining a frusto-conical cavity for receiving the frusto-conical portion of said upstream connector in a selected radial alignment, said downstream connector further defining a plurality of conduits in fluid communication with said cavity; and an interconnector for providing a fluid-tight connection when said frusto-conical portion of said upstream connector is received within the cavity defined by said downstream connector, wherein an amount of fluid communication between the plurality of conduits defined by said downstream connector and the plurality of conduits defined by the frusto-conical portion of said upstream connector is selected by the radial alignment therebetween when in a fluid-tight connection. 2. The reformer unit of claim 1 wherein said heat exchanging section is in thermal communication with said bypass section to effect heat transfer between a fluid flowing through said heat exchanger section and a fluid flowing through said bypass section. 3. The reformer unit of claim 1 wherein each of the frusto-conical portion of said upstream connector and said downstream connector define a pair of opposing arcuate conduits. 4. The reformer unit of claim 1 wherein said variable orifice flow controller further comprises: a disc defining the plurality of conduits, said disc being adjacent to a face of the frusto-conical portion of said upstream connector in the selected radial alignment so that the plurality of conduits defined by said disc are in fluid communication with the plurality of conduits defined by the frusto-conical portion of said upstream connector and the conduit defined by said downstream connector. 5. The reformer unit of claim 4 wherein each of the frusto-conical portion of said upstream connector and said disc define a pair of opposing arcuate conduits. 6. The reformer unit of claim 1 , wherein said reforming unit is a steam reformer. 7. The reformer unit of claim 1 , wherein said reforming section comprises a Group VIII metal. 8. The reforming unit of claim 7 , wherein said reforming section further comprises an element selected from the group comprising Groups IIa-VIIa, Groups Ib-Vb, lanthanide and actinide series elements. 9. The reforming unit of claim 1 further comprising a second heat exchanging section having an inlet adapted for fluid communication with an exhaust of the fuel cell system and an outlet adapted for fluid communication with an inlet of the fuel cell system, said second heat exchanging section being in thermal communication with said bypass section to effect heat transfer between a fluid flowing through said heat exchanger section and a fluid flowing through said bypass section. 10. The reforming unit of claim 1 , wherein said bypass section comprises a ceramic coating. 11. A variable orifice flow controller for controlling the flow of a high temperature fluid, said controller comprising: an upstream connector having a cylindrical tubular portion defining a conduit in fluid communication with a bypassing flowpath, and a frusto-conical portion defining a plurality of conduits in fluid communication with the conduit defined by said cylindrical tubular portion; a downstream connector defining a frusto-conical cavity for receiving the frusto-conical portion of said upstream connector in a selected radial alignment, said downstream connector further defining a plurality of conduits in fluid communication with said cavity; and an interconnector for providing a fluid-tight connection when said frusto-conical portion of said upstream connector is received within the cavity defined by said downstream connector, wherein an amount of fluid communication between the plurality of conduits defined by said downstream connector and the plurality of conduits defined by the frusto-conical portion of said upstream connector is selected by the radial alignment therebetween when in a fluid-tight connection, wherein the controller is positioned in the bypass section of a reformer system, the reformer system comprising a reforming section, a heat exchanging section configured to heat a fluid flowing in the reforming section, and the bypass section configured to provide the bypassing flowpath around said reforming section. 12. The flow controller of claim 11 wherein each of the frusto-conical portion of said upstream connector and said downstream connector define a pair of opposing arcuate conduits. 13. The flow controller of claim 11 forming a fluid-tight connection for a fluid having a temperature of at least 650 degrees Celsius. 14. The flow controller of claim 11 , wherein said downstream connector comprises one or more notches adapted to operably receive a tab affixed to said upstream connector, said one or more notches and tab configured to prevent relative rotation between said upstream and downstream connectors. 15. The flow controller of claim 11 , wherein the radial alignment between the plurality of conduits defined by said downstream connector and the plurality of conduits defined by the frusto-conical portion of said upstream connector is maintained by a compression fit between said upstream and downstream connectors when in a fluid-tight connection. 16. A variable orifice flow controller for controlling the flow of a high temperature gas, said controller comprising: an upstream connector having a cylindrical tubular portion defining a conduit in fluid communication with a bypassing flowpath, and a frusto-conical portion defining a plurality of conduits in fluid communication with the conduit defined by said cylindrical tubular portion; a downstream connector defining a frusto-conical cavity for receiving the frusto-conical portion of said upstream connector, said downstream connector further defining a conduit in fluid communication with said cavity; a disc defining a plurality of conduits, said disc being adjacent to a face of the frusto-conical portion of said upstream connector in a selected radial alignment so that the pluralit