Fuel igniter assembly having heat-dissipating element and methods of using same

What is claimed is: 1. A combustor for a gas turbine engine, said combustor comprising: a combustion chamber defined by an annular inner combustor liner and an annular outer combustor liner; a fuel igniter assembly coupled to said combustor and extending radially outward from the outer combustor liner, said fuel igniter assembly comprising an igniter housing configured to house a fuel igniter therein; a heat-dissipating element configured to be coupled to said igniter housing, said heat-dissipating element comprising a plurality of fins configured to dissipate heat from said fuel igniter assembly, wherein the plurality of fins are perpendicular to a hex nut disposed on the igniter housing; and a shroud that defines an airflow channel between igniter housing and the shroud, wherein the heat-dissipating element is included within the shroud. 2. A combustor in accordance with claim 1 , further comprising an ignition lead electrically coupled to said fuel igniter at a connection point within said igniter housing. 3. A combustor in accordance with claim 2 , wherein said heat-dissipating element is coupled to said igniter housing such that said heat-dissipating element at least partially surrounds the connection point between said ignition lead and said fuel igniter. 4. A combustor in accordance with claim 2 , wherein said ignition lead comprises an air cooled ignition lead. 5. A combustor in accordance with claim 2 , wherein said ignition lead is configured to supply an electrical voltage of at least about 15,000 volts to said fuel igniter. 6. A combustor in accordance with claim 2 , further comprising a dielectric member disposed between said igniter housing and said fuel igniter. 7. A combustor in accordance with claim 1 , wherein said heat-dissipating element is disposed along a portion of said igniter housing disposed radially outward from said outer combustor liner. 8. A fuel igniter assembly for use in a combustor, said fuel igniter assembly comprising: an igniter housing comprising an elongate body having a cavity defined therein; a fastener disposed on the igniter housing; a fuel igniter positioned within said cavity; an ignition lead electrically coupled to said fuel igniter at a connection point within said igniter housing; a heat-dissipating element coupled to said igniter housing such that said heat-dissipating element at least partially surrounds the connection point between said ignition lead and said fuel igniter, wherein the heat-dissipating element includes a plurality of fins configured to dissipate heat from said fuel igniter assembly, and said fins are located between the fastener and the combustor; and a shroud that defines an airflow channel between igniter housing and the shroud, wherein the heat-dissipating element is disposed within the shroud. 9. A fuel igniter assembly in accordance with claim 8 , wherein said heat-dissipating element comprises a body and the plurality of fins extend radially outward from said body. 10. A fuel igniter assembly in accordance with claim 8 , wherein said fins are oriented substantially parallel to an axial length of said fuel igniter assembly. 11. A fuel igniter assembly in accordance with claim 8 , wherein said fins are oriented substantially transverse to an axial length of said fuel igniter assembly. 12. A fuel igniter assembly in accordance with claim 8 , wherein said fins are oriented substantially parallel to one another. 13. A fuel igniter assembly in accordance with claim 8 , wherein said heat-dissipating element comprises between 20 and 40 fins. 14. A fuel igniter assembly in accordance with claim 8 , wherein said heat-dissipating element is coupled to said igniter housing by a press-fit connection. 15. A fuel igniter assembly in accordance with claim 8 , wherein said heat-dissipating element is constructed from at least one of stainless steel and a nickel-based superalloy. 16. A method of operating a gas turbine engine including a combustor and a compressor, the combustor including a fuel igniter assembly including an igniter housing, a fuel igniter positioned within the igniter housing, and a set of fins coupled to the igniter housing between the combustor, a shroud that at least partially encloses the set of fins and defines an airflow channel between the igniter housing and the shroud, and a nut disposed on the igniter housing, the method comprising: supplying an electrical voltage to the fuel igniter; directing an airflow through the shroud and across at least a subset of the fins to dissipate heat from the fuel igniter assembly; and coupling the fuel igniter to an air-cooled ignition lead wherein air is supplied through an air inlet and flows through a conduit and around the ignition lead, wherein directing the airflow across the subset of fins comprises directing air through the air inlet and along a longitudinal direction of the fins. 17. A method in accordance with claim 16 , wherein directing the airflow across the fins comprises channeling the airflow from the compressor to the fins such that air flows in a direction substantially parallel to the fins. 18. A method in accordance with claim 16 wherein supplying an electrical voltage to the fuel igniter comprises supplying an electrical voltage of at than about 15,000 volts.