The present disclosure relates to fibrous structures including active agents and having a graphic printed thereon. In some embodiments, a nonwoven web may include a fibrous structure comprising filaments. In turn, the filaments may include filament forming material, and an active agent releasable from the filaments when exposed to conditions of intended use. In addition, a graphic may be printed directly onto the fibrous structure.

A method of preparing a cleaning wipe having a high sustainable polymer content is provided. The cleaning wipe includes a fibrous layer having fibers of a melt spinnable sustainable polymer; and an abrasive layer having meltblown fibers of a melt spinnable sustainable polymer. The abrasive layer defining an outer surface of the cleaning wipe, and includes a plurality of abrasive structures formed thereon in which the abrasive structures are formed from conglomerated fibers, meltblown shot, fibers having average diameters greater than 4 micrometers and fibers having a tortuous geometry. The melt spinnable sustainable polymer content of the cleaning wipe is at least 50 weight % by weight of the cleaning wipe. A method of preparing the cleaning wipe is also provided.

A method of preparing a cleaning wipe having a high sustainable polymer content is provided. The cleaning wipe includes a fibrous layer having fibers of a melt spinnable sustainable polymer; and an abrasive layer having meltblown fibers of a melt spinnable sustainable polymer. The abrasive layer defining an outer surface of the cleaning wipe, and includes a plurality of abrasive structures formed thereon in which the abrasive structures are formed from conglomerated fibers, meltblown shot, fibers having average diameters greater than 4 micrometers and fibers having a tortuous geometry. The melt spinnable sustainable polymer content of the cleaning wipe is at least 50 weight % by weight of the cleaning wipe. A method of preparing the cleaning wipe is also provided.

A packaging for sterile packaging application includes: a single layer nonwoven fabric obtained from a nonwoven, the nonwoven including meltblown polymer fibers having an average fiber diameter between 2 μm to 10 μm and a standard deviation of the fiber diameter of at least 100%. The nonwoven is thermally bonded.

A method for producing a nonwoven for shielding electromagnetic radiation in a terahertz (THz) range includes: providing a first metal alloy adapted to shield electromagnetic radiation; providing a polymer material; providing a second metal alloy which differs from the first metal alloy; producing polymer fibers with filled fiber cores by evaporating the first metal alloy and mixing the first metal alloy molecules with the polymer material; coating at least a part of a surface of the polymer fibers with the second metal alloy; producing the nonwoven by randomly and irregularly arranging the coated polymer fibers with filled fiber cores in a three spatial dimensional directions, or producing the nonwoven by randomly and irregularly arranging the polymer fibers with filled fiber cores in the three spatial dimensional directions and coating at least a part of a surface of the nonwoven with the second metal alloy.

A method for producing a nonwoven for shielding electromagnetic radiation in a terahertz (THz) range includes: providing a first metal alloy adapted to shield electromagnetic radiation; providing a polymer material; providing a second metal alloy which differs from the first metal alloy; producing polymer fibers with filled fiber cores by evaporating the first metal alloy and mixing the first metal alloy molecules with the polymer material; coating at least a part of a surface of the polymer fibers with the second metal alloy; producing the nonwoven by randomly and irregularly arranging the coated polymer fibers with filled fiber cores in a three spatial dimensional directions, or producing the nonwoven by randomly and irregularly arranging the polymer fibers with filled fiber cores in the three spatial dimensional directions and coating at least a part of a surface of the nonwoven with the second metal alloy.

The present disclosure relates to a spunbond nonwoven fabric for a base fabric for tile carpet which not only has excellent spinnability during the production of nonwoven fabric and improves tensile strength and tensile elongation, and has the effect of recycling waste such as polyester plastic, by using recycled polyester with optimized intrinsic viscosity, crystallization temperature, and number of foreign matters as a raw material, and a tile carpet using the same.

The present disclosure relates to a spunbond nonwoven fabric for a base fabric for tile carpet which not only has excellent spinnability during the production of nonwoven fabric and improves tensile strength and tensile elongation, and has the effect of recycling waste such as polyester plastic, by using recycled polyester with optimized intrinsic viscosity, crystallization temperature, and number of foreign matters as a raw material, and a tile carpet using the same.

A fiber having a surface region and an interior region includes a polymer comprising at least one of a vinyl acetate moiety or a vinyl alcohol moiety, the fiber having a transverse cross-section including the interior region comprising the polymer having a first degree of hydrolysis and the surface region comprising the polymer having a second degree of hydrolysis greater than the first degree of hydrolysis.

A nonwoven biofabric comprises a web comprising (a) biodegradable polymeric melt blown fibers, and (b) a plurality of particles enmeshed in the biodegradable polymeric meltblown fibers.