A capillary tube bundle sub-assembly for use in an extracorporeal heat exchanger includes a continuous capillary tubing wound about a core to define a plurality of capillary layers each including a plurality of capillary segments. The capillary segments each define opposing terminal ends adjacent op
A capillary tube bundle sub-assembly for use in an extracorporeal heat exchanger includes a continuous capillary tubing wound about a core to define a plurality of capillary layers each including a plurality of capillary segments. The capillary segments each define opposing terminal ends adjacent opposing ends of the core. The capillary segments of each layer are circumferentially aligned relative to an axis of the core, with each successive layer being radially outward of an immediately preceding layer. The capillary segments are non-parallel with the axis, spiraling partially about the axis in extension between the opposing terminal ends. Each capillary segment forms less than one complete revolution (i.e., winds less than 360°). The segments within each layer are substantially parallel with one another; however, an orientation of the segments differs from layer-to-layer such as by pitch or angle.
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1. A capillary tube bundle sub-assembly for use in an extracorporeal blood circuit heat exchanger, the capillary tube bundle sub-assembly comprising: a substrate core defining a cylindrical outer surface having a central longitudinal axis, a first core end, a second core end opposite the first core
1. A capillary tube bundle sub-assembly for use in an extracorporeal blood circuit heat exchanger, the capillary tube bundle sub-assembly comprising: a substrate core defining a cylindrical outer surface having a central longitudinal axis, a first core end, a second core end opposite the first core end, and a length between the opposing core ends in a direction of the central axis; andat least one continuous fluid impermeable capillary tubing wound about the outer surface to define a plurality of layers each including a plurality of capillary segments traversing a majority of the core length from a first terminal end adjacent the first core end to an opposing second terminal end adjacent the second core end, the capillary segments of each layer being substantially circumferentially aligned relative to the central axis, wherein each successive layer is radially outward of an immediately preceding layer;wherein the plurality of layers includes a first layer disposed against the outer surface, and further wherein the continuous capillary tubing is entirely longitudinally between the first and second core ends in forming the capillary segments of the first layer;wherein an entirety of each of the capillary segments is non-parallel with the central axis;and further wherein each of the capillary segments spirals partially about the central axis in extension from the corresponding first terminal end to the corresponding second terminal end by less than 360°. 2. The bundle sub-assembly of claim 1, wherein the capillary tubing is formed of a thermally conductive material. 3. The bundle sub-assembly of claim 1, wherein the capillary tubing has an outer diameter in the range of 0.010-0.050 inch and an inner diameter in the range of 0.005-0.03 inch. 4. The bundle sub-assembly of claim 1, wherein the plurality of layers further includes a second layer, the second layer being disposed against the first layer opposite the outer surface, and further wherein an orientation of each of the capillary segments of the first layer relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end differs from an orientation of each of the capillary segments of the second layer relative to the central axis. 5. The bundle sub-assembly of claim 4, wherein the capillary segments of the first layer have a pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, and the capillary segments of the second layer have a second pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, the first pitch direction being opposite the second pitch direction. 6. The bundle sub-assembly of claim 5, wherein the capillary segments of the first layer are arranged at a right hand pitch and the capillary segments of the second layer are arranged at a left hand pitch. 7. The bundle sub-assembly of claim 5, wherein the plurality of layers further includes a third layer disposed against the second layer opposite the first layer, and further wherein the capillary segments of the third layer each have a pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, the pitch direction of the third layer being identical to the first pitch direction. 8. The bundle sub-assembly of claim 4, wherein the capillary segments of the first and second layers each define an angle relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end, the angle of the capillary segments of a first layer differing from the angle of the capillary segments of the second layer. 9. The bundle sub-assembly of claim 8, wherein the plurality of layers further includes a third layer disposed against the second layer opposite the first layer, and further wherein the capillary segments of the third layer each define an angle relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end, the angle of the capillary segments of the third layer differing from the angle of the capillary segments of the first and second layers. 10. The bundle sub-assembly of claim 4, wherein the capillary segments of the first layer are substantially parallel with one another in extension from the corresponding first terminal end to the corresponding second terminal end. 11. The bundle sub-assembly of claim 1, wherein the bundle sub-assembly is characterized by the absence of a thread interconnecting each of the capillary segments within the first layer. 12. The bundle sub-assembly of claim 1, wherein the bundle sub-assembly includes a plurality of continuous capillary tubings wound about the outer surface, the plurality of capillary tubings combining to define the layers. 13. The bundle sub-assembly of claim 1, wherein the layers define a radially variable packing fraction. 14. A capillary tube bundle sub-assembly for use in an extracorporeal blood circuit heat exchanger, the capillary tube bundle sub-assembly comprising: a substrate core defining a cylindrical outer surface having a central longitudinal axis, a first core end, a second core end opposite the first core end, and a length between the opposing core ends in a direction of the central axis; andat least one continuous fluid impermeable capillary tubing wound about the outer surface to define a plurality of layers each including a plurality of capillary segments traversing a majority of the core length from a first terminal end adjacent the first core end to an opposing second terminal end adjacent the second core end, the capillary segments of each layer being substantially circumferentially aligned relative to the central axis, wherein each successive layer is radially outward of an immediately preceding layer;wherein an entirety of each of the capillary segments is non-parallel with the central axis;and further wherein each of the capillary segments spirals partially about the central axis in extension from the corresponding first terminal end to the corresponding second terminal end by less than 360°,wherein the plurality of layers includes a first layer disposed against the outer surface, the first layer including a first capillary segment immediately circumferentially adjacent a second capillary segment, and further wherein the wound continuous capillary tubing forms a single turnaround adjacent one of the first and second core ends that directly connects the first and second capillary segments. 15. The bundle sub-assembly of claim 14, wherein the plurality of layers further includes a second layer, the second layer being disposed against the first layer opposite the outer surface, and further wherein an orientation of each of the capillary segments of the first layer relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end differs from an orientation of each of the capillary segments of the second layer relative to the central axis. 16. The bundle sub-assembly of claim 15, wherein the capillary segments of the first layer have a pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, and the capillary segments of the second layer have a second pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, the first pitch direction being opposite the second pitch direction. 17. The bundle sub-assembly of claim 16, wherein the capillary segments of the first layer are arranged at a right hand pitch and the capillary segments of the second layer are arranged at a left hand pitch. 18. The bundle sub-assembly of claim 16, wherein the plurality of layers further includes a third layer disposed against the second layer opposite the first layer, and further wherein the capillary segments of the third layer each have a pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, the pitch direction of the third layer being identical to the first pitch direction. 19. The bundle sub-assembly of claim 15, wherein the capillary segments of the first and second layers each define an angle relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end, the angle of the capillary segments of a first layer differing from the angle of the capillary segments of the second layer. 20. The bundle sub-assembly of claim 19, wherein the plurality of layers further includes a third layer disposed against the second layer opposite the first layer, and further wherein the capillary segments of the third layer each define an angle relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end, the angle of the capillary segments of the third layer differing from the angle of the capillary segments of the first and second layers. 21. The bundle sub-assembly of claim 15, wherein the capillary segments of the first layer are substantially parallel with one another in extension from the corresponding first terminal end to the corresponding second terminal end. 22. A capillary tube bundle sub-assembly for use in an extracorporeal blood circuit heat exchanger, the capillary tube bundle sub-assembly comprising: a substrate core defining a cylindrical outer surface having a central longitudinal axis, a first core end, a second core end opposite the first core end, and a length between the opposing core ends in a direction of the central axis; andat least one continuous fluid impermeable capillary tubing wound about the outer surface to define a plurality of layers each including a plurality of capillary segments traversing a majority of the core length from a first terminal end adjacent the first core end to an opposing second terminal end adjacent the second core end, the capillary segments of each layer being substantially circumferentially aligned relative to the central axis, wherein each successive layer is radially outward of an immediately preceding layer;wherein an entirety of each of the capillary segments is non-parallel with the central axis;and further wherein each of the capillary segments spirals partially about the central axis in extension from the corresponding first terminal end to the corresponding second terminal end by less than 360°,wherein the plurality of layers includes a first layer disposed against the outer surface, the first layer including a first capillary segment immediately circumferentially adjacent a second capillary segment, and further wherein the second terminal end of the first capillary segment is commonly shared with the second terminal end of the second capillary segment. 23. The bundle sub-assembly of claim 22, wherein the plurality of layers further includes a second layer, the second layer being disposed against the first layer opposite the outer surface, and further wherein an orientation of each of the capillary segments of the first layer relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end differs from an orientation of each of the capillary segments of the second layer relative to the central axis. 24. The bundle sub-assembly of claim 23, wherein the capillary segments of the first layer have a pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, and the capillary segments of the second layer have a second pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, the first pitch direction being opposite the second pitch direction. 25. The bundle sub-assembly of claim 24, wherein the capillary segments of the first layer are arranged at a right hand pitch and the capillary segments of the second layer are arranged at a left hand pitch. 26. The bundle sub-assembly of claim 24, wherein the plurality of layers further includes a third layer disposed against the second layer opposite the first layer, and further wherein the capillary segments of the third layer each have a pitch direction in extension from the corresponding first terminal end to the corresponding second terminal end, the pitch direction of the third layer being identical to the first pitch direction. 27. The bundle sub-assembly of claim 23, wherein the capillary segments of the first and second layers each define an angle relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end, the angle of the capillary segments of a first layer differing from the angle of the capillary segments of the second layer. 28. The bundle sub-assembly of claim 27, wherein the plurality of layers further includes a third layer disposed against the second layer opposite the first layer, and further wherein the capillary segments of the third layer each define an angle relative to the central axis in extension from the corresponding first terminal end to the corresponding second terminal end, the angle of the capillary segments of the third layer differing from the angle of the capillary segments of the first and second layers. 29. The bundle sub-assembly of claim 23, wherein the capillary segments of the first layer are substantially parallel with one another in extension from the corresponding first terminal end to the corresponding second terminal end.
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