Plates and plate assemblies for noise attenuators and other devices and methods making the same

What is claimed is: 1. A disc-shaped plate for a noise attenuator, the disc-shaped plate comprising: a plurality of sector-shaped plates, the plurality of sector-shaped plates having openings defining flow paths, each of the plurality of sector-shaped plates having a first radial edge forming a first mating feature and a second radial edge forming a second mating feature that is complementary to the first mating feature such that, when the plurality of sector-shaped plates are arranged together, the first mating feature of each of the plurality of sector-shaped plates mates with the second mating feature of an adjacent one of the plurality of sector-shaped plates, and, when the plurality of sector-shaped plates are arranged together, a portion of each of the plurality of sector-shaped plates overlaps in an axial direction with an adjacent one of the plurality of sector-shaped plates. 2. The disc-shaped plate of claim 1 , wherein each of the plurality of sector-shaped plates is the same shape and size. 3. The disc-shaped plate of claim 1 , wherein each of the plurality of sector-shaped plates is constructed via layers of fused material. 4. The disc-shaped plate of claim 1 , wherein the plurality of sector-shaped plates includes a first sector-shaped plate, the first sector-shaped plate including: a first wall forming a first side of the first sector-shaped plate, the first wall having a first plurality of openings; a second wall forming a second side of the first sector-shaped plate, the second wall having a second plurality of openings; and an internal lattice structure between the first wall and the second wall. 5. The disc-shaped plate of claim 1 , wherein the plurality of sector-shaped plates are not coupled by fasteners. 6. A disc-shaped plate for a noise attenuator, the disc-shaped plate comprising: a plurality of sector-shaped plates, the plurality of sector-shaped plates having openings defining flow paths, the openings being tear-drop shaped, each of the plurality of sector-shaped plates having a first radial edge forming a first mating feature and a second radial edge forming a second mating feature that is complementary to the first mating feature such that, when the plurality of sector-shaped plates are arranged together, the first mating feature of each of the plurality of sector-shaped plates mates with the second mating feature of an adjacent one of the plurality of sector-shaped plates. 7. A disc-shaped plate for a noise attenuator, the disc-shaped plate comprising: a plurality of sector-shaped plates, the plurality of sector-shaped plates having openings defining flow paths, each of the plurality of sector-shaped plates having a first radial edge forming a first mating feature and a second radial edge forming a second mating feature that is complementary to the first mating feature such that, when the plurality of sector-shaped plates are arranged together, the first mating feature of each of the plurality of sector-shaped plates mates with the second mating feature of an adjacent one of the plurality of sector-shaped plates, wherein the plurality of sector-shaped plates includes a first sector-shaped plate, the first sector-shaped plate including: a first wall forming a first side of the first sector-shaped plate, the first wall having a first plurality of openings; a second wall forming a second side of the first sector-shaped plate, the second wall having a second plurality of openings; and an internal lattice structure between the first wall and the second wall, wherein the internal lattice structure forms a third plurality of openings. 8. The disc-shaped plate of claim 7 , wherein one of the third plurality of openings fluidly connects a first set of the first plurality of openings in the first wall and a second set of the second plurality of openings in the second wall. 9. The disc-shaped plate of claim 7 , wherein the third plurality of openings are diamond shaped. 10. A noise attenuator comprising: a body defining a fluid passageway between an inlet and an outlet; and a disc-shaped plate disposed in the fluid passageway, the disc-shaped plate having a plurality of openings forming flow paths for reducing noise of fluid flowing in the fluid passageway, the disc-shaped plate formed by a plurality of sector-shaped plates having mating features such that, when the plurality of sector-shaped plates are arranged together, a portion of each of the plurality of sector-shaped plates overlaps in an axial direction with an adjacent one of the plurality of sector-shaped plates. 11. The noise attenuator of claim 10 , wherein the disc-shaped plate is disposed in the fluid passageway at or near the outlet. 12. The noise attenuator of claim 11 , wherein an outer peripheral region of the disc-shaped plate is configured to be clamped between an outlet flange of the body and an inlet flange of a downstream pipe. 13. The noise attenuator of claim 10 , wherein the plurality of sector-shaped plates are not coupled by fasteners. 14. The noise attenuator of claim 10 , further including additional plates disposed in the fluid passageway upstream of the disc-shaped plate. 15. The noise attenuator of claim 10 , wherein the openings are tear-drop shaped. 16. A method comprising: printing, via a three-dimensional (3D) printer, a plurality of sector-shaped plates, the plurality of sector-shaped plates having openings defining flow paths, each of the plurality of sector-shaped plates having a first radial edge forming a first mating feature and a second radial edge forming a second mating feature that is complementary to the first mating feature such that, when the plurality of sector-shaped plates are arranged together, the first mating feature of each of the plurality of sector-shaped plates mates with the second mating feature of an adjacent one of the plurality of sector-shaped plates, and, when the plurality of sector-shaped plates are arranged together, a portion of each of the plurality of sector-shaped plates overlaps in an axial direction with an adjacent one of the plurality of sector-shaped plates. 17. The method of claim 16 , wherein the plurality of sector-shaped plates are printed by the 3D printer during a same print batch. 18. The method of claim 16 , further including assembling the plurality of sector-shaped plates to form a disc-shaped plate. 19. The method of claim 18 , further including coupling the disc-shaped plate to a fluid body such that the disc-shaped plate is disposed in a fluid passageway of the fluid body. 20. The method of claim 19 , wherein an outer peripheral region of the disc-shaped plate is clamped between the fluid body and a downstream pipe.