A transparent soluble polyimide resin was dissolved in N,N-dimethyacetamide, and a sample solution whose concentration was 10 weight percent was produced. This sample solution is put in a container CNT which is attached to an apparatus shown in FIG. 1, whereby a nanofiber structure was produced. The produced polyimide nanofiber structure acquired the excellent water resistance, air permeability and moisture permeability while maintaining the physical properties inherent in a polyimide, such as high heat resistance and insulation. Further, when a nanofiber structure is produced in a similar manner from a different polyimide resin, the nanofiber structure maintains excellent adhesiveness.

A dispersible, nonwoven multistrata wipe material is provided that is stable in a wetting liquid and flushable in use. More particularly, multilayered structures including, but not limited to, two, three, or four layers are provided to form the dispersible nonwoven wipe material. The layers contain combinations of cellulosic and noncellulosic fibers, and optionally a binder or additive.

Methods and systems are provided for a process to generate a nonwoven textile. In one example, the nonwoven textile may have layered, zonal properties resulting from entangling of two or more types of staple fibers through a merging region between the layers of staple fibers while maintaining distinct zones, each zone comprising a type of staple fiber. Furthermore, the process may include embedding a filament layer into the nonwoven textile via a continuous assembly line.

Methods and systems are provided for a process to generate a nonwoven textile. In one example, the nonwoven textile may have layered, zonal properties resulting from entangling of two or more types of staple fibers through a merging region between the layers of staple fibers while maintaining distinct zones, each zone comprising a type of staple fiber. Furthermore, the process may include embedding a filament layer into the nonwoven textile via a continuous assembly line.