A method for processing natural or synthetic leather by using super-critical CO.sub.2. The leather can be dried leather, low grade leathers, thin leather, crust leathers, finished leathers, wet blue leathers, and tanned leather, as well as synthetic leather. In a second aspect the invention relates to leather obtained by said method, and in a third aspect to a stand-alone apparatus for performing said method.

Methods are directed to the use of a supercritical fluid for performing a dyeing of a material such that dye from a first material is used to dye a second material. A supercritical fluid is passed through a first material in a pressurized vessel. The supercritical fluid transports the dye from the first material to at least a second material causing a dye profile of the second material to change as a result of dye from the first material perfusing the second material.

Expanded, nanofiber structures are provided as well as methods of use thereof and methods of making.

Expanded, nanofiber structures are provided as well as methods of use thereof and methods of making.

Methods are directed to the use of a supercritical fluid for performing a dyeing of a material such that dye from a first material is used to dye a second material. A supercritical fluid is passed through a first material in a pressurized vessel. The supercritical fluid transports the dye from the first material to at least a second material causing a dye profile of the second material to change as a result of dye from the first material perfusing the second material.

An apparatus and process for disinfecting, and, optionally, sterilizing, fibers and non-woven materials produced from the fibers is disclosed, as well as processes for converting fibers into disinfected and/or sterilized non-woven materials. The process involves contacting the fibers and/or non-woven materials with high temperature steam, and then with UV light, which is preferably UV-C light, or another disinfectant process, such as ozone treatment. The process can also involve process steps such as blending fibers, applying fibers to an air card, subjecting the fibers to one or more carding steps, subjecting the carded fibers to non-woven process steps, and chemically treating the fibers and/or non-woven materials. The resulting non-woven materials can be used, for example, in personal care, baby care (including baby wipes), cosmetic applications, household cleaning, automotive, industrial cleaning applications, industrial uses, and the like.

A press-bonded body or a method for producing the same is provided, such that the press-bonded body is a press-bonded body of at least one of a base material selected from the group consisting of non-woven fabric, stretched porous film, and fiber. The base material contains a fluorine resin (except for polytetrafluoroethylene) having a —CF2- group content of 85% by mass or greater. Polytetrafluoroethylene fibrils bond fibers constitute the base material, and in relation to the entirety of the fibrils, the proportion of the number of fibrils that are oriented at an angle of 45° to 90° relative to the direction of the fibers constituting the base material is 50% or greater.

Methods are directed to the use of a supercritical fluid for finishing a target material with a finishing material. One or more variables selected from temperature, pressure, flow rate, and time are manipulated to increase efficiencies in the finishing process. As temperature or pressure are decreased causing a change in the density of a supercritical fluid carbon dioxide, which in turn causes a precipitation of dissolved material finish with the carbon dioxide, other variables are maintained above threshold values to increase the uptake of the material finish by the target material. This improvement reduces time by limiting cleaning processes of the system, saves materials used in the cleaning process, and saves energy used to achieve cycles of the process, in aspects.

An injecting assembly includes a nozzle that is formed with a mixture channel, a mixture opening communicating with the mixture channel, a shaper channel, and a shaper opening communicating with the shaper channel. A mixture of a precursor and a supercritical fluid (SCF) passes through the mixture channel. Waves of the mixture are periodically injected toward a surface of a substrate at the mixture opening. A stream of a shaping fluid flows through the shaper channel and is injected toward the substrate at the shaper opening. The stream of the shaping fluid confines the waves of the mixture. Molecules of the precursor penetrate into the substrate by impact of the wave fronts reaching the surface of the substrate. The molecules of the precursor can react with molecules of a material of the substrate to improve surface properties of the substrate.

An injecting assembly includes a nozzle that is formed with a mixture channel, a mixture opening communicating with the mixture channel, a shaper channel, and a shaper opening communicating with the shaper channel. A mixture of a precursor and a supercritical fluid (SCF) passes through the mixture channel. Waves of the mixture are periodically injected toward a surface of a substrate at the mixture opening. A stream of a shaping fluid flows through the shaper channel and is injected toward the substrate at the shaper opening. The stream of the shaping fluid confines the waves of the mixture. Molecules of the precursor penetrate into the substrate by impact of the wave fronts reaching the surface of the substrate. The molecules of the precursor can react with molecules of a material of the substrate to improve surface properties of the substrate.