Provided is an absorbent material and a method of making an absorbent material. The absorbent material comprises a blend of a super-absorbent first type of gel-forming fiber with a second type of gel-forming fiber, wherein the super-absorbent first type of gel-forming fiber is formed from a super-absorbent polymer. Such absorbent materials are useful in the manufacture of absorbent articles such as wound dressings.

Provided is an absorbent material and a method of making an absorbent material. The absorbent material comprises a blend of a super-absorbent first type of gel-forming fiber with a second type of gel-forming fiber, wherein the super-absorbent first type of gel-forming fiber is formed from a super-absorbent polymer. Such absorbent materials are useful in the manufacture of absorbent articles such as wound dressings.

A process for using recycled waste cotton material to produce a textile product is provided. The process can include collecting different categories of waste cotton material from a variety of textile formation processes. The process can also include selecting specific categories of waste cotton material to be blended together depending on the textile product to be produced. In the process, sequence of cleaning, opening and blending processing steps can be selected to be used in making a yarn depending on the textile product to be produced. The selected specific categories of waste cotton material can be cleaned, opened and blended into blended cotton fibers. The blended cotton fibers can then be processed into the textile product to be produced. Thus, a textile product can be provided that includes yarn that can have at least three different categories of waste cotton material that are from textile formation processes.

Disclosed are fibers comprising one or more branded fibers which exhibit surface markings in a repeated pattern along the length of the branded fibers. The branded fibers can be incorporated into yarns or fiber bands to represent supply chain information of the yarns, fiber bands, and/or articles made from the yards or fiber bands. In a specific example, branded fibers can be incorporated into an acetate tow band The branded fibers can be recovered from a cigarette filter, the repeated pattern decoded, and supply chain information associated with the acetate tow used to make the cigarette filter, such as manufacturer, customer, ship to location, and even the acetate tow bale, can be obtained.

In one aspect, a textile machine for processing and/or transporting fiber material includes at least one processing unit configured to process and/or transport fiber material and at least one sensor unit configured to detect soiling on and/or at the at least one processing unit and/or damage to the at least one processing unit. The textile machine also includes at least one display unit configured to display the soiling on and/or the damage to the at least one processing unit.

In one aspect, a textile machine for processing and/or transporting fiber material includes at least one processing unit configured to process and/or transport fiber material and at least one sensor unit configured to detect soiling on and/or at the at least one processing unit and/or damage to the at least one processing unit. The textile machine also includes at least one display unit configured to display the soiling on and/or the damage to the at least one processing unit.

A method for producing a filling material comprising goose and/or duck down and vegetable kapok fibres comprises feeding vegetable kapok fibre to a mixing chamber (16), separating elementary kapok filaments (210) unbound from each other from the vegetable kapok fibre in the mixing chamber (16) by directing jets and/or blades of a pressurized fluid against the vegetable kapok fibre, feeding goose and/or duck down to the mixing chamber (16) and incorporating elementary kapok filaments (210) unbound from each other into the flakes (101) of goose and/or duck down (100) by mixing the elementary kapok filaments (210) and the goose and/or duck down in the mixing chamber (16) by means of said jets and/or blades of pressurized fluid fed for example by suitably oriented nozzles (33).

A method for producing a filling material comprising goose and/or duck down and vegetable kapok fibres comprises feeding vegetable kapok fibre to a mixing chamber (16), separating elementary kapok filaments (210) unbound from each other from the vegetable kapok fibre in the mixing chamber (16) by directing jets and/or blades of a pressurized fluid against the vegetable kapok fibre, feeding goose and/or duck down to the mixing chamber (16) and incorporating elementary kapok filaments (210) unbound from each other into the flakes (101) of goose and/or duck down (100) by mixing the elementary kapok filaments (210) and the goose and/or duck down in the mixing chamber (16) by means of said jets and/or blades of pressurized fluid fed for example by suitably oriented nozzles (33).

A fireproof material used for a lithium battery module and a method for producing the same are provided. The fireproof material has a stacked structure formed by stacking multiple layers of mesh structures. Each layer of the mesh structures includes a plurality of first fibers and a plurality of second fibers. The first fibers are oxidized fibers, and the second fibers are silicate fibers. Each layer of the mesh structures is formed by interweaving the plurality of first fibers and the plurality of second fibers. The multiple layers of the mesh structures of the fireproof material have a stacked layer number of between 5 layers and 20 layers and a stacked layer thickness of between 0.3 mm and 5 mm. The fireproof material has a density of between 0.05 g/cm.sup.3 and 2 g/cm.sup.3 and a thermal conductivity of between 0.01 W/(m.Math.K) and 0.8 W/(m.Math.K).

A fireproof material used for a lithium battery module and a method for producing the same are provided. The fireproof material has a stacked structure formed by stacking multiple layers of mesh structures. Each layer of the mesh structures includes a plurality of first fibers and a plurality of second fibers. The first fibers are oxidized fibers, and the second fibers are silicate fibers. Each layer of the mesh structures is formed by interweaving the plurality of first fibers and the plurality of second fibers. The multiple layers of the mesh structures of the fireproof material have a stacked layer number of between 5 layers and 20 layers and a stacked layer thickness of between 0.3 mm and 5 mm. The fireproof material has a density of between 0.05 g/cm.sup.3 and 2 g/cm.sup.3 and a thermal conductivity of between 0.01 W/(m.Math.K) and 0.8 W/(m.Math.K).