Systems and methods for cooling an imaging system

The invention claimed is: 1. A manifold assembly for an imaging system, comprising: an intake manifold and a return manifold formed by a plurality of unitary sections, the intake manifold and the return manifold positioned adjacent to each other and separated by a shared wall; and a plurality of nozzles, with each nozzle of the plurality of nozzles formed integrally with a corresponding section of the plurality of unitary sections, wherein a first section of the plurality of unitary sections is integrally formed with a drain outlet as a single piece, the drain outlet in fluidic communication with one of the intake manifold or the return manifold and adapted to flow coolant out of the manifold assembly via gravity. 2. The manifold assembly of claim 1 , wherein the intake manifold and the return manifold are each centered on a same, central axis of the manifold assembly, with the intake manifold, the return manifold, and the shared wall encircling the central axis. 3. The manifold assembly of claim 1 , wherein the intake manifold includes an annular intake passage formed by a plurality of arcuate intake passages, the return manifold includes an annular return passage formed by a plurality of arcuate return passages, and the shared wall comprises a plurality of arcuate walls. 4. The manifold assembly of claim 3 , wherein each arcuate intake passage of the plurality of arcuate intake passages, each arcuate return passage of the plurality of arcuate return passages, and each arcuate wall of the plurality of arcuate walls is formed by a corresponding section of the plurality of unitary sections. 5. The manifold assembly of claim 4 , wherein one or more arcuate walls of the plurality of arcuate walls forms a reservoir having a thermally insulating material disposed therein, the thermally insulating material having a lower thermal conductivity than a material of the one or more arcuate walls. 6. The manifold assembly of claim 4 , wherein each section of the plurality of unitary sections includes exactly one arcuate intake passage of the plurality of arcuate intake passages and exactly one arcuate return passage of the plurality of arcuate return passages. 7. The manifold assembly of claim 3 , wherein the shared wall fluidly isolates the annular intake passage from the annular return passage. 8. The manifold assembly of claim 3 , wherein the plurality of nozzles includes a plurality of intake nozzles and a plurality of return nozzles, the plurality of intake nozzles formed with the annular intake passage and in fluidic communication with the annular intake passage, and the plurality of return nozzles formed with the annular return passage and in fluidic communication with the annular return passage. 9. The manifold assembly of claim 1 , wherein each section of the plurality of unitary sections includes an end coupled to a corresponding, adjacent section of the plurality of unitary sections. 10. The manifold assembly of claim 1 , wherein the plurality of nozzles includes a plurality of nozzle sets, with each nozzle set of the plurality of nozzle sets including an intake nozzle and a return nozzle. 11. The manifold assembly of claim 10 , wherein each nozzle set of the plurality of nozzle sets is in fluidic communication with a corresponding detector assembly of a plurality of detector assemblies of the imaging system. 12. The manifold assembly of claim 1 , wherein a first section of the plurality of unitary sections is integrally formed with a mounting bracket as a single piece, the mounting bracket adapted to couple the manifold assembly to the imaging system. 13. The manifold assembly of claim 1 , wherein the intake manifold includes an intake inlet and the return manifold includes a return outlet, the intake inlet and the return outlet formed by one or more sections of the plurality of unitary sections. 14. A method, comprising: forming a plurality of separate, unitary sections of a manifold assembly for a positron emission tomography (PET) system via an additive manufacturing process, with each unitary section including an intake passage, a return passage, a plurality of nozzles, and a shared wall separating the intake passage from the return passage; and coupling the plurality of unitary sections together to form an intake manifold and a return manifold of the manifold assembly. 15. The method of claim 14 , wherein coupling the plurality of unitary sections together to form the intake manifold and the return manifold includes only fitting an end of each section of the plurality of unitary sections into a corresponding end of a corresponding, adjacent section of the plurality of adjacent sections. 16. The method of claim 14 , wherein coupling the plurality of unitary sections together to form the intake manifold and the return manifold includes only fusing an end of each section of the plurality of unitary sections with a corresponding end of a corresponding, adjacent section of the plurality of unitary sections, and does not include any other fusing or coupling of any section of the plurality of unitary sections to any other section of the plurality of unitary sections. 17. The method of claim 14 , wherein the additive manufacturing process comprises 3D printing, and wherein forming the plurality of separate, unitary sections of the manifold assembly via the additive manufacturing process includes forming the intake passage, the return passage, the plurality of nozzles, and the shared wall of each unitary section of the plurality of unitary sections entirely of a same material, and with the intake passage, the return passage, and the plurality of nozzles having a same wall thickness. 18. A positron emission tomography (PET) system, comprising: a plurality of photodetector assemblies positioned in an annular array encircling a bore of the PET system; and a manifold assembly including an annular coolant intake passage and an annular coolant return passage comprised of a plurality of unitary, arcuate sections, with each arcuate section of the plurality of arcuate sections formed integrally with a plurality of nozzles as a single piece via a 3D printing manufacturing process, the plurality of nozzles fluidly coupling the annular coolant intake passage and the annular coolant return passage to the plurality of photodetector assemblies. 19. The PET system of claim 18 , wherein one or more arcuate sections of the plurality of arcuate sections further comprises a mounting bracket or a drain outlet formed integrally with the one or more arcuate sections via the 3D printing manufacturing process, and wherein each arcuate section of the plurality of arcuate sections includes a wall separating the annular coolant intake passage from the annular coolant return passage and forming inner surfaces of each of the annular coolant intake passage and the annular coolant return passage, the wall formed via the 3D printing manufacturing process.