Compact augmented permeation system (CAPS) assemblies and related systems and methods

What is claimed is: 1. A compact augmented permeation system (CAPS) assembly, comprising: a housing defining an interior cavity, the housing further defining a gas inlet for receiving gas within the interior cavity and a gas outlet for expelling the gas from the interior cavity; and a solid, continuous gas-permeable membrane positioned within the housing and defining a system boundary across the interior cavity such that gas received within the interior cavity via the gas inlet permeates through the gas-permeable membrane before being expelled from the interior cavity via the gas outlet, the gas-permeable membrane including an inner surface and an opposed outer surface; wherein the inner surface of the gas-permeable membrane has a non-planar configuration as the gas-permeable membrane extends across the interior cavity defined by the housing. 2. The CAPS assembly of claim 1 , wherein the interior cavity extends within the housing in an axial direction along a longitudinal axis of the CAPS assembly and in a radial direction outwardly from the longitudinal axis, wherein the inner surface of the gas-permeable membrane is oriented in both the axial direction and the radial direction as the inner surface extends between the longitudinal axis and an inner surface of the housing. 3. The CAPS assembly of claim 1 , wherein the inner surface of the gas-permeable membrane has a greater surface area than a radial cross-sectional area of the interior cavity. 4. The CAPS assembly of claim 1 , further comprising at least one support structure positioned within the housing, the at least one support structure being configured to support the gas-permeable membrane in the non-planar configuration. 5. The CAPS assembly of claim 4 , wherein the at least one support structure defines a support surface that contacts the gas-permeable membrane, the support surface having a non-planar configuration that matches the non-planar configuration of the gas-permeable membrane. 6. The CAPS assembly of claim 4 , wherein the at least one support structure comprises a lower support structure and an upper support structure, the gas-permeable membrane being positioned between the upper and lower support structures with at least a portion of the inner surface of the gas-permeable membrane contacting the lower support structure. 7. The CAPS assembly of claim 6 , wherein the upper and lower support structures define mirrored three-dimensional geometries. 8. The CAPS assembly of claim 1 , wherein the gas-permeable membrane is configured to allow the gas to flow around a portion of the gas-permeable membrane without permeating therethrough when a fluid pressure of the gas exceeds a given threshold. 9. The CAPS assembly of claim 1 , wherein at least a portion of the gas-permeable membrane is movable relative to the housing between a sealed position, at which the gas-permeable membrane defines the system boundary, and a venting position, at which the gas is allowed to flow around a portion of the gas-permeable membrane without permeating therethrough. 10. The CAPS assembly of claim 1 , wherein at least a portion of an outer perimeter of the housing is threaded. 11. The CAPS assembly of claim 1 , further comprising a heat-generating component configured to heat the gas-permeable membrane. 12. A material storage system including the CAPS assembly of claim 1 , the material storage system further comprising a storage container, the CAPS assembly configured to be removably coupled to the storage container to allow the CAPS assembly to be transitioned between installed and uninstalled states relative to the storage container. 13. The material storage system of claim 12 , wherein the storage container is configured to contain hazardous materials that generate the gas and wherein the storage container further defines an opening within which the CAPS assembly is configured to be installed, the CAPS assembly configured to be sealed against an adjacent surface of the storage container such that the CAPS assembly seals the opening while still allowing the gas to be expelled from the storage container via permeation through the gas-permeable membrane. 14. The material storage system of claim 13 , wherein the opening comprises a threaded opening and wherein the housing is at least partially threaded such that the housing is configured to be threaded into the threaded opening to removably couple the CAPS assembly to the storage container. 15. A material storage system, comprising: a storage container defining an opening; and a compact augmented permeation system (CAPS) assembly configured to be installed relative to the opening of the storage container, the CAPS assembly comprising: a housing defining an interior cavity, the housing further defining a gas inlet for receiving gas within the interior cavity and a gas outlet for expelling the gas from the interior cavity; and a gas-permeable membrane positioned within the housing and defining a system boundary across the interior cavity such that gas received within the interior cavity via the gas inlet permeates through the gas-permeable membrane before being expelled from the interior cavity via the gas outlet; wherein the housing is configured to be removably coupled to the storage container to allow the CAPS assembly to be transitioned between installed and uninstalled states relative to the storage container; wherein the storage container is configured to contain hazardous materials that generate the gas and wherein the CAPS assembly is configured to be sealed against an adjacent surface of the storage container such that the CAPS assembly seals the opening while still allowing the gas to be expelled from the storage container via permeation through the gas-permeable membrane; and wherein the opening comprises a threaded opening and wherein the housing is at least partially threaded such that the housing is configured to be threaded into the threaded opening to removably couple the CAPS assembly to the storage container. 16. A compact augmented permeation system (CAPS) assembly, comprising: a housing defining an interior cavity, the housing further defining a gas inlet for receiving gas within the interior cavity and a gas outlet for expelling the gas from the interior cavity; and a gas-permeable membrane positioned within the housing and defining a system boundary across the interior cavity such that gas received within the interior cavity via the gas inlet permeates through the gas-permeable membrane before being expelled from the interior cavity via the gas outlet, the gas-permeable membrane including an inner surface and an opposed outer surface; wherein the inner surface of the gas-permeable membrane has a non-planar configuration as the gas-permeable membrane extends across the interior cavity defined by the housing; and wherein at least a portion of an outer perimeter of the housing is threaded. 17. The material storage system of claim 15 , wherein: the gas-permeable membrane of the CAPS assembly includes an inner surface and an opposed outer surface; and the inner surface of the gas-permeable membrane has a non-planar configuration as the gas-permeable membrane extends across the interior cavity defined by the housing. 18. The material storage system of claim 17 , wherein the inner surface of the gas-permeable membrane has a greater surface area than a radial cross-sectional area of the interior cavity. 19. The material storage system of claim 17 , wherein the CAPS assembly further comprises at least one support structure positi