Air separation modules and methods of making air separation modules

What is claimed is: 1. An air separation module, comprising: a canister with a plenum portion connecting an inlet portion to an outlet portion and extending circumferentially about a canister axis, the plenum portion having a plenum diameter that is larger than a canister diameter defined by the inlet portion and the outlet portion of the canister; a separator arranged within the canister and axially spanning the plenum portion of the canister, the separator configured to separate air received at the inlet end portion into a nitrogen-enriched air flow and an oxygen-enriched air flow; and a perforated plate seated within the plenum portion and fluidly coupling the separator to an oxygen-enriched air outlet port defined by the plenum portion, wherein the perforated plate has a snap-fit major dimension that is smaller than the plenum diameter to radially support a portion of the separator axially spanning the plenum portion of the canister; wherein the perforated plate has a split annulus body with a plate end and a clip end, the plate end slidably disposed within the clip end of the split annulus body. 2. The air separation module of claim 1 , wherein the perforated plate has a perforated portion with a plurality of perforations extending therethrough. 3. The air separation module of claim 2 , wherein the perforated plate has a flange portion extending radially outward from the perforated portion of the perforated plate. 4. The air separation module of claim 3 , wherein the flange portion is a first flange portion and the perforated plate has a second flange portion, wherein the perforated portion connects the first flange portion to the second flange portion. 5. The air separation module of claim 3 , wherein the perforated portion of the perforated plate is radially spaced from an interior surface of the plenum portion by the flange portion of the perforated plate, the interior surface and the perforated portion defining a plenum therebetween. 6. The air separation module of claim 1 , wherein the perforated plate extends circumferentially about the separator and abuts a radially outer surface of the separator. 7. The air separation module of claim 1 , wherein the plate end of the split annulus body has a plate member extending circumferentially therefrom. 8. The air separation module of claim 1 , wherein the clip end of the split annulus body has a radially inner clip member and a radially outer clip member extending circumferentially from the clip end of the split annulus body. 9. The air separation module of claim 1 , wherein the inlet portion of the canister is arranged radially inward of the plenum portion of the canister, wherein the outlet portion of the canister is arranged radially inward of the plenum portion of the canister. 10. The air separation module of claim 1 , further comprising: an inlet end cap fixed to the inlet portion of the canister; and an outlet end cap fixed to the outlet portion of the canister, wherein the separator is enclosed within the inlet end cap, the outlet end cap, and the canister. 11. The air separation module of claim 1 , wherein the snap-fit major dimension of the perforated plate is substantially equivalent to the canister diameter. 12. The air separation module of claim 1 , wherein the perforated plate and the plenum portion define a plenum therebetween, the plenum extending circumferentially about the perforated plate, wherein the perforated plate has a compressed major dimension and a relaxed major dimension, the relaxed major dimension larger than the snap-fit major dimension, the compressed major dimension smaller than the snap-fit major dimension. 13. A nitrogen generation system, comprising: an air separation module as recited in claim 1 , wherein the perforated plate has a perforated portion with a plurality of perforations extending therethrough; an ozone converter fluidly coupled to the separator; an oxygen sensor fluidly coupled to the ozone converter by separator; and a flow control valve fluidly coupled to the ozone converter by the separator. 14. The nitrogen generation system of claim 13 , wherein the perforated plate extends circumferentially about the separator, wherein the perforated plate abuts a radially outer surface of the separator, the nitrogen generation system further comprising: a compressed air source fluidly coupled to the air separation module; and a fuel tank fluidly coupled to the compressed air source by the air separation module. 15. The nitrogen generation system of claim 13 , wherein the plate end is adjacent the clip end when the perforated plate is compressed, and wherein the plate end is spaced apart from the clip end when the perforated plate is relaxed. 16. An air separation module, comprising: a canister with a plenum portion connecting an inlet portion to an outlet portion and extending circumferentially about a canister axis, the plenum portion having a plenum diameter that is larger than a canister diameter defined by the inlet portion and the outlet portion of the canister; a separator arranged within the canister and axially spanning the plenum portion of the canister, the separator configured to separate air received at the inlet end portion into a nitrogen-enriched air flow and an oxygen-enriched air flow; and a perforated plate seated within the plenum portion and fluidly coupling the separator to an oxygen-enriched air outlet port defined by the plenum portion, wherein the perforated plate has a snap-fit major dimension that is smaller than the plenum diameter to radially support a portion of the separator axially spanning the plenum portion of the canister; wherein the perforated plate comprises: a first annular segment with a plate end; and a second annular segment with a clip end, wherein the plate end of the first annular segment is slidably received within the clip end of the second annular segment. 17. The air separation module of claim 16 , wherein the first annular segment has a clip end, wherein the second annular segment has a plate end, and wherein the plate end of the second annular segment is slidably received within the clip end of the first annular segment. 18. The air separation module of claim 16 , wherein the first annular segment and the second annular segment cooperate to circumferentially span the plenum portion of the canister. 19. A nitrogen generation system, comprising: an air separation module as recited in claim 16 , wherein the perforated plate has a perforated portion with a plurality of perforations extending therethrough; an ozone converter fluidly coupled to the separator; an oxygen sensor fluidly coupled to the ozone converter by separator; and a flow control valve fluidly coupled to the ozone converter by the separator. 20. A method of making an air separation module, comprising: at a canister with a plenum portion connecting an inlet portion to an outlet portion and extending circumferentially about a canister axis, the plenum portion having a plenum diameter larger than a canister diameter defined by the inlet portion and the outlet portion of the canister, compressing a perforated plate such that the perforated plate has a compressed major dimension smaller than the canister diameter; seating the perforated plate within the plenum portion of the canister by relaxing the compressed perforated plate, the perforated plate having a snap-fit major dimension that is smaller than the plenum diameter once relaxed; and arranging a separator configured to separate air rec