Heat exchanger with integrated subcooler

What is claimed is: 1. A heat exchanger assembly comprising: a heat exchanger including a plurality of tubes, each having an inlet end and an outlet end; an inlet header configured to receive a cooling fluid along a flow direction and to distribute the cooling fluid to the inlet ends of the plurality of tubes; and an outlet header including an outer shell and defining an outlet chamber, the outlet header attached to the outlet ends of the tubes, the outlet chamber configured to receive cooling fluid discharged from the outlet ends of the plurality of tubes such that cooling fluid flows from the tubes directly into the outlet header; a supply conduit for supplying the cooling fluid to the inlet header, the supply conduit including a conduit portion extending through the outlet header, and the supply conduit routed completely external to the heat exchanger for a distance extending from the outlet header where the supply conduit exits the outlet header to the inlet header in the flow direction; and an expansion valve coupled to the supply conduit between an outlet of the conduit portion and the inlet header in the flow direction. 2. The cooling assembly of claim 1 , wherein the outer shell substantially encloses the conduit portion. 3. The cooling assembly of claim 2 , wherein the conduit portion is substantially coaxial with the outlet header. 4. The cooling assembly of claim 2 , wherein the outlet header further includes an outlet chamber tube at least partially defining the outlet chamber, and wherein the conduit portion is at least partially defined by an annular space between the outer shell and the outlet chamber tube. 5. The cooling assembly of claim 4 , wherein a surface of the conduit portion defines helical grooves. 6. The cooling assembly of claim 1 , wherein a surface of the outer shell defines helical grooves. 7. The cooling assembly of claim 1 , wherein the conduit portion is defined by a tubular member disposed within the outer shell. 8. The cooling assembly of claim 7 , wherein a surface of the tubular member defines helical grooves. 9. The cooling assembly of claim 7 , wherein a surface of the tubular member defines surface-area increasing features. 10. The cooling assembly of claim 1 , wherein the expansion valve receives the cooling fluid from the supply conduit and is disposed upstream of the inlet header. 11. The cooling assembly of claim 10 , wherein the expansion valve receives subcooled liquid refrigerant from the supply conduit. 12. A method of operating a heat exchanger assembly, the method comprising: providing a heat exchanger including an inlet header, an outlet header, and a plurality of tubes, each of the plurality of tubes having an inlet end and an outlet end; attaching the outlet ends of the tubes to the outlet header; supplying a cooling fluid along a flow direction to the inlet ends through the inlet header; passing the cooling fluid through each of the plurality of tubes from the inlet end to the outlet end; receiving the cooling fluid directly from the outlet ends in an outlet header such that the cooling fluid flows from the tubes directly into the outlet header; routing a conduit portion of a supply conduit through the outlet header; and routing the supply conduit completely external to the heat exchanger for a distance extending from an outlet of the conduit portion where the supply conduit exits the outlet header to the inlet header in the flow direction, the supply conduit supplying cooling fluid to the inlet header after passing through the conduit portion and an expansion valve coupled between the outlet of the conduit portion and the inlet header in the flow direction. 13. The method of claim 12 , wherein the act of routing the conduit portion of the supply conduit through the outlet header includes routing the conduit portion of the supply conduit between an outer shell and an outlet chamber tube of the outlet header. 14. The method of claim 12 , further comprising subcooling the cooling fluid in the portion of the supply conduit routed through the outlet header. 15. The method of claim 12 , further comprising supplying the cooling fluid to the expansion valve upstream of the inlet header. 16. The method of claim 15 , wherein the cooling fluid is supplied to the expansion valve as a subcooled liquid. 17. A heat exchanger assembly comprising: a heat exchanger including a plurality of tubes, each of the of tubes extending from an inlet end to an outlet end; an inlet header configured to receive a refrigerant and to distribute the refrigerant to the inlet ends of the of tubes; an outlet header attached to the outlet ends of the second set of tubes; and a liquid to suction heat exchanger including: a suction header at least partially defined by the outlet header and receiving vapor refrigerant discharged directly from the outlet ends of the tubes, and a liquid conduit fluidly and physically connected to the inlet header upstream of the inlet header, the liquid conduit thermally coupled to the at least portion of the suction header defined by the outlet header for heat transfer between liquid refrigerant in the liquid conduit and vapor refrigerant in the suction header, wherein the liquid conduit is routed completely external to the plurality of tubes from where the liquid conduit exits the suction header to where the liquid conduit is connected to the inlet header. 18. The cooling assembly of claim 17 , wherein the liquid to suction heat exchanger includes an outer shell. 19. The cooling assembly of claim 18 , wherein the outer shell at least partially defines the liquid conduit. 20. The cooling assembly of claim 18 , wherein the outer shell at least partially defines the suction header.