Method of liquid resin infusion of a composite preform

Having thus described various embodiments of the invention, what is claimed as new and desired to be protected by Letters Patent includes the following: 1. A method of infusing composite material with liquid resin to form a composite part, the method comprising: placing a flow media into a recess formed into a surface of a rigid tool, wherein the recess is selectively fluidly coupled with a resin reservoir having liquid resin therein; placing a caul sheet into the recess, thereby sandwiching the flow media between the caul sheet and the rigid tool, wherein the caul sheet has a plurality of holes or perforations formed therein or is made of a porous material; placing composite material over the caul sheet; placing an impermeable membrane over the composite material; sealing the impermeable membrane to the rigid tool around a periphery of the composite material; applying a pressure differential sufficient to compress the impermeable membrane toward the composite material and the rigid tool by vacuuming air or atmosphere out from between the impermeable membrane and the rigid tool; and opening a connection between the resin reservoir and the recess, such that the liquid resin is pulled from the resin reservoir, through the flow media, through the caul sheet, and throughout the composite material by vacuum. 2. The method of claim 1 , further comprising placing the caul sheet into a first recessed portion of the recess and placing the flow media into a second recessed portion of the recess, wherein the first recessed portion extends a first depth from the surface of the rigid tool and the second recessed portion is formed inward of the first recessed portion and extends a second depth from the surface of the rigid tool. 3. The method of claim 1 , further comprising placing a peel ply over the caul sheet between the caul sheet and the composite material. 4. The method of claim 1 , wherein the composite material overlaps an edge at which the surface of the rigid tool meets the recess, such that an outer portion of the composite material rests on the surface of the rigid tool and an inner portion of the composite material rests on the caul sheet. 5. The method of claim 1 , wherein the composite material comprises a composite skin and at least one composite stringer, wherein the impermeable membrane has at least one vacuum port aligned with the at least one stringer, wherein the step of applying the pressure differential comprises vacuuming air or atmosphere out through the vacuum port from between the impermeable membrane and the rigid tool. 6. The method of claim 1 , further comprising placing rigid tooling components onto the composite material and placing the impermeable membrane over the rigid tooling components and the composite material. 7. The method of claim 6 , wherein an outer mold line (OML) surface of the composite part is formed by the rigid tool and the caul sheet and an inner mold line (IML) surface of the composite part is formed by rigid tooling components and the impermeable membrane. 8. A method of infusing composite material with liquid resin to form a composite part having an inner mold line (IML) surface and an outer mold line (OML) surface opposite the IML surface, the method comprising: placing a flow media into a recess formed into a surface of a rigid tool, wherein the recess is fluidly coupled with a resin reservoir having liquid resin therein, wherein the recess is two-tiered, having a first recessed portion extending a first depth from the surface of the rigid tool and a second recessed portion, inward of the first recessed portion and having an area less than or equal to the first recessed portion, that extends a second depth from the surface of the rigid tool, wherein the placing of the flow media into the recess comprises placing the flow media into the second recessed portion; placing a caul sheet into the first recessed portion, thereby sandwiching the flow media between the caul sheet and the rigid tool, wherein the caul sheet has a plurality of holes or perforations formed therein and rests on a ledge extending between the first recessed portion and the second recessed portion; placing composite material over the caul sheet; placing a flexible impermeable membrane over the composite material; sealing the impermeable membrane to the rigid tool around a periphery of the composite material; and vacuuming air or atmosphere from between the impermeable membrane and the rigid tool by an amount sufficient to compress the impermeable membrane toward the composite material and the rigid tool, such that the liquid resin is pulled from the resin reservoir, through the flow media, through the holes or perforations of the caul sheet, and throughout the composite material toward the vacuum port. 9. The method of claim 8 , further comprising placing a peel ply over the caul sheet between the caul sheet and the composite material. 10. The method of claim 8 , wherein the composite material comprises a composite skin and at least one composite stringer. 11. The method of claim 10 , further comprising aligning the at least one vacuum port with the at least one composite stringer. 12. The method of claim 10 , further comprising supporting the composite stringer with rigid stringer tooling components and placing the impermeable membrane over the rigid stringer tooling components and the composite material. 13. The method of claim 12 , wherein the OML surface of the composite part is formed by the rigid tool and the caul sheet and the IML surface of the composite part is formed by rigid stringer tooling components and the impermeable membrane. 14. An assembly for infusing composite material with liquid resin to form a composite part having a complex geometry including an inner mold line (IML) surface and an outer mold line (OML) surface opposite the IML surface, the composite material comprising a composite skin and at least one composite stringer, and the assembly comprising: a rigid tool comprising a mold surface having a two-tiered recess formed therein including a first recessed portion and a second recessed portion, wherein the second recessed portion is formed inward of the first recessed portion and has a greater depth from the surface of the rigid tool than a depth of the first recessed portion, wherein the two-tiered recess is configured to be fluidly coupled with a resin reservoir having liquid resin therein; a flow media placed within the second recessed portion of the two-tiered recess of the tool; a caul sheet placed within the first recessed portion of the two-tiered recess of the tool, such that the flow media is sandwiched between the caul sheet and the tool, wherein the caul sheet has a plurality of holes or perforations formed therein, wherein a surface of the caul sheet corresponds with the OML surface of the composite part to be formed thereon; a flexible impermeable membrane wherein the impermeable membrane is placed over the two-tiered recess, the flow media, the caul sheet, and the composite material and sealed to the rigid tool, cooperatively forming a pocket with the rigid tool around a periphery of the two-tiered recess; and a vacuum port formed through at least one of the impermeable membrane and the rigid tool, wherein vacuuming air or atmosphere through the vacuum port from between the impermeable membrane and the rigid tool compresses the impermeable membrane toward the composite material and the rigid tool, such that the liquid resin is pulled from the resin reservoir, through the flow media, through the holes or perforations of the caul sheet, and throughout the composite material toward the v