Air separation module with increased permeate area

The invention claimed is: 1. A method for removing oxygen from engine bleed air, the method comprising: feeding fluid into an air separation module, wherein the air separation module comprises: a casing; a plurality of fibers located within the casing; a fiber membrane defining an exterior of each of the plurality of fibers; at least one perforated canister is inserted between the plurality of fibers, wherein the at least one perforated canister includes a cross-sectional profile configured to maximize a surface area of the at least one perforated canister with respect to a number of the plurality of fibers in the air separation module; forcing the fluid down the length of the plurality of fibers; permeating a first portion of the fluid through the fiber membrane to create a permeated fluid; collecting a portion of the permeated fluid into the at least one perforated canister; expelling the permeated fluid from the casing; and removing any non-permeated fluid from the casing through an outlet located on an end of the casing. 2. The method of claim 1 , wherein the perforated canister includes perforations, the perforations configured to maximize an amount of collected permeated gas with respect to the number of the plurality of fibers in the air separation module. 3. The method of claim 2 , further comprising: introducing the nitrogen-enriched gas into a fuel tank to reduce an oxygen concentration below a level necessary for combustion. 4. The method of claim 1 , wherein the fluid is bleed air from a compressor. 5. The method of claim 4 , wherein the fluid is compressed RAM air. 6. The method of claim 1 , wherein the at least one perforated canister includes a plurality of perforated canisters that contain cross-sectional profiles configured to maximize a surface area of the plurality of perforated canisters with respect to a volume in the air separation module. 7. A method for removing oxygen from engine bleed air, the method comprising: feeding fluid into an air separation module, wherein the air separation module comprises: a casing; a plurality of fibers located within the casing; a fiber membrane defining an exterior of each of the plurality of fibers; a plurality of perforated canisters is inserted between the plurality of fibers, wherein the plurality of perforated canisters contain cross-sectional profiles configured to maximize a surface area of the plurality of perforated canisters with respect to a volume in the air separation module; forcing the fluid down the length of the plurality of fibers; permeating a first portion of the fluid through the fiber membrane to create a permeated fluid; collecting a portion of the permeated fluid into the at least one perforated canister; expelling the permeated fluid from the casing; and removing any non-permeated fluid from the casing through an outlet located on an end of the casing. 8. The method of claim 7 , wherein each of the perforated canisters includes perforations, the perforations configured to maximize an amount of collected permeated gas with respect to the number of the plurality of fibers in the air separation module. 9. The method of claim 8 , further comprising: introducing the nitrogen-enriched gas into a fuel tank to reduce an oxygen concentration below a level necessary for combustion. 10. The method of claim 7 , wherein the fluid is bleed air from a compressor. 11. The method of claim 7 , wherein the fluid is compressed RAM air.