Extracorporeal blood circuit reservoir with angled venous inlet luer port

What is claimed is: 1. An extracorporeal blood circuit reservoir device comprising: a housing defining a main chamber; an exit port fluidly connected to the main chamber; a venous inlet sub-assembly mounted to the housing and including: a downtube forming a primary lumen extending between and open at opposing inlet and outlet ends, the downtube defining an inlet section adjacent the inlet end and an outlet section adjacent the outlet end, a first luer port connector body extending from the inlet section and forming a passageway open to the primary lumen at a flow opening, wherein the port connector body is arranged relative to the inlet section such that a flow path of fluid flow from the passageway into the primary lumen merges with a flow path of fluid flow along the primary lumen at an angle of less than 90°; wherein the venous inlet sub-assembly is arranged to locate the inlet section and the port connector body outside of the housing and the outlet section within the housing; and a venous filter maintained within the housing fluidly between the outlet end and the exit port. 2. The reservoir device of claim 1 , wherein an extension angle defined at an intersection of an axial centerline of the passageway with a central axis of the primary lumen is less than 90°. 3. The reservoir device of claim 2 , wherein the extension angle is in the range of 1°-85°. 4. The reservoir device of claim 2 , wherein the axial centerline is linear along an entire length of the port connector body. 5. The reservoir device of claim 2 , wherein the axial centerline is non-linear along a length of the port connector body. 6. The reservoir device of claim 1 , further comprising a luer lock assembled to the port connector body. 7. The reservoir device of claim 1 , wherein the venous inlet sub-assembly further includes: a second luer port connector body extending from the inlet section and forming a passageway; wherein the second port connector body is arranged relative to the inlet section such that a flow path of fluid flow from the passageway of the second port connector body into the primary lumen merges with a flow path of fluid flow along the primary lumen at an angle less than 90°. 8. The reservoir device of claim 7 , wherein the passageway of each of the port connector bodies defines an axial centerline, and further wherein an intersection of each of the axial centerlines with a central axis of the primary lumen forms an extension angle of less than 90°. 9. The reservoir device of claim 7 , wherein the second port connector body is circumferentially spaced from the first port connector body. 10. The reservoir device of claim 7 , wherein the first port connector body is longitudinally aligned with the second port connector body. 11. The reservoir device of claim 7 , wherein the venous inlet assembly further includes a sampling port body extending from the inlet section and fluidly open to the primary lumen. 12. The reservoir device of claim 1 , further comprising: a bowl disposed within the housing and forming a floor surface arranged to receive fluid flow from the downtube outlet end; wherein the floor surface defines a curvature adapted to tangentially transition the fluid flow from a central region of the floor surface to a radially outward region of the floor surface. 13. The reservoir device of claim 1 , further comprising: a cardiotomy inlet assembly mounted to the housing and defining a cardiotomy inlet and a cardiotomy outlet; and a cardiotomy filter disposed within the housing fluidly between the cardiotomy outlet and the exit port. 14. The reservoir device of claim 13 , wherein the venous filter and the cardiotomy filter are arranged to guide fluid flow into the main chamber. 15. The reservoir device of claim 1 , wherein arrangement of the first port connector body relative to the downtube is configured such that at a port flow rate of less than 500 mL/minute through the passageway, fluid flow from the first port connector body does not induce turbulent flow into fluid flowing through the primary lumen. 16. An extracorporeal blood circuit comprising: a venous cannula for cannulation to a patient and receiving venous blood; a reservoir device including: a housing defining a main chamber, an exit port fluidly connected to the main chamber, a venous inlet sub-assembly mounted to the housing and including: a downtube forming a primary lumen extending between an opening at opposing inlet and outlet ends, the downtube defining an inlet section adjacent the inlet end and an outlet section adjacent the outlet end, a luer port connector body extending from the inlet section and forming a passageway open to the primary lumen, a venous filter maintained within the housing fluidly between the outlet end and the exit port; wherein the venous cannula is fluidly connected to the inlet end of the downtube; an arterial filter device including a purge port, wherein the arterial filter device is fluidly connected to the exit port downstream of the reservoir device, and further wherein the purge port is fluidly connected to the port connector body; and an arterial cannula for cannulation to a patient downstream of the arterial filter; wherein a primary venous flow path is established from the venous cannula and through the downtube, and a secondary flow path is established from the purge port and through the first port connector body, and further wherein the secondary flow path merges with the primary venous flow path within the inlet section at an angle less than 90°. 17. The circuit of claim 16 , wherein an extension angle defined at an intersection of an axial centerline of the passageway with a central axis of the primary lumen is less than 90°. 18. A method of collecting and treating extracorporeal blood of a patient during surgical procedure, the method comprising: directing venous source blood from the patient into an inlet end of a downtube having an outlet end; directing secondary source blood into the downtube via a luer port connector body at a location upstream of the outlet end, including the secondary source blood flow merging with the venous source blood flow at an angle of less than 90°; dispensing a combination of the venous source blood and the secondary source blood from the outlet end into a reservoir chamber; and guiding the combination blood through a venous filter within the chamber. 19. The method of claim 18 , further comprising: directing blood from the reservoir to an arterial filler; directing blood from the arterial filter back to the patient; and purging a partial flow of blood from the arterial filter to the downtube as the secondary source blood. 20. The method of claim 18 , wherein an arrangement of the connector port body relative to the downtube is configured such that at a secondary source blood flow rate of less than 500 mL/minute through the luer port connector body, the secondary source blood flow does not induce turbulent flow into the primary venous source blood flow.