The present disclosure is directed to an oil-infused bacterial nanocellulose (BNC) material including a porous body comprising a three-dimensional network of bacterial nanocellulose fibers defining a plurality of interconnected pores; and, an oil infused within the plurality of pores. The present disclosure additionally describes a method of preparing an oil-infused BNC material that includes fermenting bacteria to form a porous body of bacterial nanocellulose fibers having a three-dimensional network defining a plurality of interconnected pores; mechanically pressing the porous body; dehydrating the porous body; and infusing the porous body with an oil infusion fluid including an oil so as to entrap the oil in the pores of the porous body forming an oil-infused BNC material.

The present invention relates to a method for the production of highly absorbent polysaccharide fibers which contain a mixture of cellulose and (1.fwdarw.3)-glucan as a fiber-forming substance, as well as to the highly absorbent fibers made thereby, and to their use.

The present invention relates to a method for the production of highly absorbent polysaccharide fibers which contain a mixture of cellulose and (1.fwdarw.3)-glucan as a fiber-forming substance, as well as to the highly absorbent fibers made thereby, and to their use.

The present invention relates to a method for the production of polysaccharide fibers which, as a fiber-forming substance, comprise a mixture of cellulose and (1.fwdarw.3)-glucan, as well as to the fibers made thereof and to their use.

The present invention relates to a method for the production of polysaccharide fibers which, as a fiber-forming substance, comprise a mixture of cellulose and (1.fwdarw.3)-glucan, as well as to the fibers made thereof and to their use.

A viscose fiber comprises a fiber body including a regenerated cellulosic material and a plurality of microcapsules dispersed in the regenerated cellulosic material. The regenerated cellulosic material is derived from an organic plant material and the plurality of microcapsules containing a phase change material has a transition temperature in the range of 0 C. to 100 C., the phase change material providing thermal regulation based on at least one of absorption and release of latent heat at the transition temperature.

A viscose fiber comprises a fiber body including a regenerated cellulosic material and a plurality of microcapsules dispersed in the regenerated cellulosic material. The regenerated cellulosic material is derived from an organic plant material and the plurality of microcapsules containing a phase change material has a transition temperature in the range of 0 C. to 100 C., the phase change material providing thermal regulation based on at least one of absorption and release of latent heat at the transition temperature.

The present invention relates to a direct dissolving process for the production of polysaccharide fibers which contain (1.fwdarw.3)-glucan as a fiber-forming substance, with aqueous sodium hydroxide solution as a solvent, as well as to the fibers made thereby, and to their use.

The present invention relates to a direct dissolving process for the production of polysaccharide fibers which contain (1.fwdarw.3)-glucan as a fiber-forming substance, with aqueous sodium hydroxide solution as a solvent, as well as to the fibers made thereby, and to their use.

This application describes a method of preparation of a natural graphene cellulose blended meltblown nonwoven fabric, which comprises using a graphite powder as a raw material for preparing a graphene solution, adding the graphene solution to a slurry formed by mixing and dissolving a wood pulp with N-methylmorpholine N-oxide (NMMO), removing the water content thereof to form a spinning dope, and then directly preparing the natural graphene cellulose blended meltblown nonwoven fabric by a meltblown process. The present method does not require a highly toxic hydrazine hydrate solution. Further, by increasing the adding ratio of the graphene solution in the manufacturing process, control of the antistatic properties and thermal transferring function can be achieved, and thereby various requirements of different consumers can be satisfied. Besides, the fabric can decompose naturally after being used, and thus the product is harmless, natural, and environmentally friendly.