Cell structures for use in heat exchangers, and methods of producing the same

What is claimed is: 1. A cell structure for use in a heat exchanger, the cell structure comprising: a hub, defined as a central chamber having an inner surface and an outer surface; and a number (n) of tubes, where n is three or more, each tube having a first end, a second end, an inner surface, and an outer surface; and wherein, the n tubes are configured such that (i) each first end comprises an opening integrally joined at the hub, (ii) each second end extends away from the hub, (iii) the inner surface of each tube and the inner surface of the hub form a smooth, continuous, structure inner surface, (iv) the outer surface of each tube and the outer surface of the hub form a smooth, continuous structure outer surface, and (v) there are no other openings into the hub or the n tubes; and an impermeable partition extending across the central chamber of the hub, integrally joined along its perimeter to the central chamber inner surface, dividing the central chamber into a first sub-chamber and a second sub-chamber, the partition preventing fluid communication between the first sub-chamber and the second sub-chamber; and wherein a first tube, the first sub-chamber, and a second tube comprise a first flow-path; and a third tube, the second sub-chamber, and a fourth tube comprise a second flow-path; and wherein the first flow-path and the second flow-path are in fluid isolation from each other. 2. The cell structure of claim 1 , wherein n is four. 3. The cell structure of claim 2 , wherein each tube of the four tubes integrally joined at the hub forms a substantially 109 degree angle from every other of the tubes integrally joined at the hub. 4. The cell structure of claim 3 , wherein substantially is plus or minus five percent. 5. The cell structure of claim 4 , wherein: the structure inner surface is impermeable; and the structure outer surface is impermeable. 6. The cell structure of claim 5 , wherein a material comprising the structure inner surface is different from a material comprising the structure outer surface. 7. The cell structure of claim 6 , wherein a second end of a tube is is integrally joined to a vessel wall. 8. The cell structure of claim 7 , wherein: each of the n tubes has a same cross sectional area as each other, defined as a tube cross section; the hub has a cross sectional area, defined as a hub cross section; and the hub cross section is larger than the tube cross section. 9. The cell structure of claim 8 , wherein: the n tubes have a tube thickness; the hub has a hub thickness; and the tube thickness and hub thickness are not equal. 10. A lattice structure for use in a heat exchanger, the lattice structure comprising: a plurality of hubs, each defined as a central chamber having an inner surface and an outer surface; and a plurality of tubes, each tube having an inner surface and an outer surface; each hub of the plurality of hubs directly connected to at least three of the plurality of tubes, such that, for each of the at least three tubes connected to the hub, (i) the inner surface of each tube and the inner surface of the hub form a smooth, continuous, structure inner surface, (ii) the outer surface of each tube and the outer surface of the hub form a smooth, continuous structure outer surface, (iii) there are no other openings into the hub or the tubes, and (iv) for each hub, each tube of the at least three tubes connected thereto is oriented at a substantially 109 degree angle from each other tube of the at least three tubes; and wherein tubes and hubs are interconnected to define (i) a repeating shape, (ii) an inner flow path comprising structure inner surfaces, and (iii) an outer flow path comprising structure; and a vessel wall, to which some of the plurality of tubes are integrally joined. 11. The lattice structure of claim 10 , wherein: the lattice structure defines a volume; and the volume is substantially enclosed in a radial direction by the vessel wall. 12. The lattice structure of claim 11 , wherein: the volume is bisected by a vessel wall that prevents fluid communication between a first section of the volume and a second section of the volume. 13. The lattice structure of claim 12 , wherein: the structure inner surfaces are non-permeable; and the structure outer surfaces are non-permeable. 14. The lattice structure of claim 13 , wherein a material comprising the structure inner surfaces is different from a material comprising the structure outer surfaces. 15. The lattice structure of claim 14 , further comprising: a partition extending across a central chamber of at least one hub, seamlessly joined along its perimeter to the structure inner surface, dividing the central chamber into a first sub-chamber and a second sub-chamber, the partition preventing fluid communication between the first sub-chamber and second sub-chamber. 16. The lattice structure of claim 15 , wherein at least one tube is is mechanically coupled to the vessel wall.