Reductant dosing unit compact side feed inlet port

What is claimed is: 1. An apparatus, comprising: an injector, including: an inlet port for transferring fluid to an inlet tube; an inner sleeve, the inner sleeve being part of the inlet port; an outer sleeve mounted to the inner sleeve, the outer sleeve being part of the inlet port; an inlet conduit partially disposed in the outer sleeve, the inlet conduit being part of the inlet port; a cavity formed at least partly by the outer sleeve; a volume reduction feature that is formed as part of the outer sleeve, wherein the volume reduction feature reduces the volume in the cavity; an upper wall formed as part of the outer sleeve, the volume reduction feature is formed as part of the upper wall of the outer sleeve; wherein fluid flows from the inlet conduit, into the cavity, and then into the inlet tube; wherein the volume reduction feature extends a majority of a distance between the inlet tube and an inner surface of a portion of the upper wall which does not form the volume reduction feature, wherein the volume reduction feature extends at least partly within the inner sleeve at a radial central portion thereof; wherein the inlet port is a side feed inlet port in which a longitudinal axis of the inlet conduit is orthogonal to a longitudinal axis of the injector; wherein fluid flows from the inlet conduit, through the outer sleeve and into the inlet tube; and wherein the volume reduction feature comprises a semi-spherical wall portion of the upper wall, a diameter of the semi-spherical wall portion extending a majority of a distance across an opening of the inlet tube. 2. The apparatus of claim 1 , further comprising: an aperture formed as part of the outer sleeve; wherein a portion of the inlet conduit is disposed in the aperture formed as part of the outer sleeve, and the inlet conduit is in fluid communication with the cavity. 3. The apparatus of claim 2 , further comprising: a flow path; wherein a portion of the inner sleeve obstructs a majority of the aperture, and the flow path is formed by the portion of the aperture that is unobstructed by the sleeve. 4. The apparatus of claim 1 , wherein the outer sleeve, the inner sleeve, and the inlet tube are all separate components that are formed using one selected from the group consisting of a stamping process and a forming process. 5. The apparatus of claim 3 , wherein a majority of the aperture is obstructed by the portion of the inner sleeve, the flow path being partly defined by a space between an outer surface of the inner sleeve and at least one of an inner surface of the outer sleeve and an end portion of the inlet conduit. 6. The apparatus of claim 1 , further comprising a seal member disposed between an outer surface of the inlet tube and an inner surface of the inner sleeve, wherein a radial axis of the seal member at a center thereof is offset from a longitudinal axis of the inlet conduit. 7. The apparatus of claim 1 , wherein the volume reduction feature reduces a volume of the cavity for receiving fluid by 20%. 8. The apparatus of claim 1 , wherein an upstream opening of the inlet tube, relative to a direction of fluid flow through the inlet tube, is disposed within an opening of the inner sleeve. 9. The apparatus of claim 1 , wherein the volume reduction feature does not directly contact the inner sleeve and does not directly contact the inlet tube. 10. An inlet port for an injector comprising: an inner sleeve mounted to an inlet tube of an injector; an outer sleeve, the inner sleeve partially disposed in the outer sleeve; a cavity formed as part of the outer sleeve, the inner sleeve partially disposed in the cavity; an aperture formed as part of the outer sleeve, the aperture in fluid communication with the cavity; an inlet conduit partially disposed in the aperture such that the inlet conduit is in fluid communication with the cavity; a volume reduction feature, wherein the volume reduction feature reduces the volume in the cavity and is formed as part of the outer sleeve; an upper wall formed as part of the outer sleeve, the volume reduction feature is formed as part of the upper wall of the outer sleeve; and a flow path, the inlet conduit in fluid communication with the cavity through the flow path; wherein the volume reduction feature extends a majority of a distance between the inlet tube and an inner surface of a portion of the upper wall which does not form the volume reduction feature, the volume reduction feature extending at least partly within the inner sleeve at a radial center portion of the inner sleeve; wherein a portion of the inner sleeve obstructs a majority of the aperture, and the flow path is formed by the portion of the aperture that is unobstructed by the inner sleeve; wherein fluid flows through the inlet conduit and into the cavity, and from the cavity into the inlet tube. 11. The inlet port of claim 10 , wherein the outer sleeve, the inner sleeve, and the inlet tube are all formed using one selected from the group consisting of a stamping process and a forming process. 12. The inlet port of claim 10 , wherein the volume reduction feature comprises a semi-spherical wall portion of the upper wall of the outer sleeve. 13. The inlet port of claim 10 , wherein the inlet port is a side feed inlet port. 14. The inlet port of claim 10 , wherein a longitudinal axis of the inlet conduit is orthogonal to a longitudinal axis of at least one of the inlet tube and the injector. 15. The inlet port of claim 10 , wherein the flow path is defined in part by a space between an outer surface of the inner sleeve and at least one of an inner surface of the outer sleeve and an end portion of the inlet conduit. 16. The inlet port of claim 12 , wherein a diameter of the semi-spherical wall portion of the upper wall of the outer sleeve is greater than a radius of an opening of the inner sleeve. 17. The inlet port of claim 12 , wherein an upstream opening of the inlet tube, relative to a direction of fluid flow through the inlet tube, is disposed within an opening of the inner sleeve. 18. The inlet port of claim 12 , wherein the volume reduction feature does not directly contact the inner sleeve and does not directly contact the inlet tube.