Swirling flow-blurring atomizer

What is claimed is: 1 . An atomizer configured to atomize liquids passed therethrough, the atomizer comprising: an endcap comprising an annular wall extending longitudinally along an axial centerline of the atomizer from an upstream end to a downstream end with respect to a flow of fuel through the atomizer and a planar wall that extends radially inward from the downstream end of the annular wall to an opening; a nozzle situated within the endcap; and a plurality of swirl vanes, wherein a first end radially outward end of each swirl vane in the plurality of swirl vanes contacts a radially inward surface of the annular wall, wherein each swirl vane in the plurality of swirl vanes extends radially inward from the radially inward surface of the annular wall towards the axial centerline of the atomizer and terminates at a radially inward end, wherein a downstream end of each swirl vane contacts an upstream surface of the planar wall wherein each swirl vane extends axially upstream from the upstream surface of the planar wall and terminates at an upstream end, and the radially inward end of each swirl vane in the plurality of swirl vanes and the upstream end of each swirl vane of the plurality of swirl vanes do not contact any surface, wherein the plurality of swirl vanes are set at a non-zero angle of incidence to the endcap, wherein the endcap extends farther radially inward from the annular wall than the swirl vanes extend radially inward from the annular wall, wherein the endcap defines an inner fluid chamber between a fluid inlet and the nozzle, wherein flow from the inlet to the nozzle is at least partially directed through passageways between the plurality of swirl vanes, and wherein the flow is imparted with swirling motion due to a tangential momentum imposed by the plurality of swirl vanes. 2 . The atomizer of claim 1 , wherein the nozzle is centered with respect to the endcap. 3 . The atomizer of claim 1 , wherein the angle of incidence is 32 degrees. 4 . The atomizer of claim 1 , wherein the plurality of swirl vanes extend radially inward from the radially inward inner surface of the annular wall at a 30 degree angle. 5 . The atomizer of claim 1 , wherein the tangential momentum is configured to increase a mixing between a plume sprayed from the endcap and air surrounding the plume. 6 . An atomizer, comprising: an endcap comprising an annular wall extending longitudinally along an axial centerline of the atomizer from an upstream end to a downstream end with respect to a flow of liquid through the atomizer and a planar wall that extends radially inward from the downstream end of the annular wall to an opening; a spray nozzle situated within the endcap, wherein the spray nozzle is configured to pass the liquid through the spray nozzle; and a plurality of swirl vanes, wherein a radially outward end of each swirl vane in the plurality of swirl vanes contacts a radially inward surface of the annular wall, wherein each swirl vane in the plurality of swirl vanes extends radially inward from the radially inward surface of the annular wall towards the axial centerline of the atomizer and terminates at a radially inward end, wherein a downstream end of each swirl vane contacts an upstream surface of the planar wall, wherein each swirl vane extends axially upstream from the upstream surface of the planar wall and terminates at an upstream end, and the radially inward end of each swirl vane in the plurality of swirl vanes and the upstream end of each swirl vane of the plurality of swirl vanes do not contact any surface, wherein the plurality of swirl vanes are configured to define a plurality of swirled passages, wherein the endcap extends farther radially inward from the annular wall than the swirl vanes extend radially inward from the annular wall, wherein the plurality of swirled passages are configured to impart a swirling motion to gas passing through the plurality of swirled passages, and wherein the plurality of swirl vanes and the spray nozzle are configured to mix the liquid with the gas, thereby atomizing the liquid. 7 . The atomizer of claim 6 , wherein the plurality of swirl vanes comprise 8 swirl vanes. 8 . The atomizer of claim 6 , wherein the plurality of swirl vanes extend radially inward from the radially inward inner surface of the annular wall at a 30 degree angle. 9 . The atomizer of claim 6 , wherein the plurality of swirl vanes are configured to impose a tangential momentum on the gas passing through the plurality of swirled passages. 10 . The atomizer of claim 6 , wherein the plurality of swirl vanes are configured to impose a tangential momentum on the gas, and wherein the tangential momentum is configured to increase a mixing between a plume sprayed from the endcap and air surrounding the plume. 11 . The atomizer of claim 6 , wherein the nozzle is centered with respect to the endcap. 12 . An atomizer, comprising: an endcap comprising an annular wall extending longitudinally along an axial centerline of the atomizer from an upstream end to a downstream end with respect to a flow of liquid through the atomizer and a planar wall that extends radially inward from the downstream end of the annular wall to an opening; a spray nozzle situated within the endcap, wherein the spray nozzle is configured to pass the liquid through the spray nozzle; and a plurality of swirl vanes, wherein a radially outward end of each swirl vane in the plurality of swirl vanes contacts a radially inward surface of the annular wall, wherein each swirl vane in the plurality of swirl vanes extends radially inward from the radially inward surface of the annular wall towards the axial centerline of the atomizer and terminates at a radially inward end, wherein a downstream end of each swirl vane contacts an upstream surface of the planar wall, wherein each swirl vane extends axially upstream from the upstream surface of the planar wall and terminates at an upstream end, and the radially inward end of each swirl vane in the plurality of swirl vanes and the upstream end of each swirl vane of the plurality of swirl vanes do not contact any surface, wherein the plurality of swirl vanes are configured to define a plurality of swirled passages, wherein the endcap extends farther radially inward from the annular wall than the swirl vanes extend radially inward from the annular wall, wherein the plurality of swirled passages are configured to impart a swirling motion to gas passing through the plurality of swirled passages, and wherein the plurality of swirl vanes and the spray nozzle are configured to mix the liquid with the gas, thereby atomizing the liquid, wherein the plurality of swirl vanes are configured to impose a tangential momentum on the gas passing through the plurality of swirled passages, and wherein the tangential momentum is configured to increase a mixing between a plume sprayed from the endcap and air surrounding the plume, wherein the nozzle is centered with respect to the endcap. 13 . The atomizer of claim 12 , wherein the plurality of swirl vanes comprise 8 swirl vanes. 14 . The atomizer of claim 12 , wherein the plurality of swirl vanes extend radially inward from the radially inward inner surface of the annular wall at a 30 degree angle. 15 . The atomizer of claim 12 , wherein the plurality of swirl vanes are set at a non-zero angle of incidence to the endcap. 16 . The atomizer of claim 12 , wherein the angle of incidence is 32 degrees.