Method and composition for increasing the electrical and thermal conductivity of a textile article comprising the application of a composition comprising graphene and an inorganic pigment, so as to form a layer that consists of a thermal circuit for optimal management of heat and an electrical circuit for dissipation of the static electricity accumulated on the textile article.

An object of the present invention is to realize an environment-friendly manufacturing process for textile products that solves the problem of wastewater by using a solvent instead of conventionally used water in a sizing process and/or desizing process of textile products. According to an aspect of the present invention, there is provided a method for applying a sizing agent to a textile product, the method including: a step of sizing the textile product by bringing the textile product into contact with a fluid containing the sizing agent and supercritical carbon dioxide.

An object of the present invention is to realize an environment-friendly manufacturing process for textile products that solves the problem of wastewater by using a solvent instead of conventionally used water in a sizing process and/or desizing process of textile products. According to an aspect of the present invention, there is provided a method for applying a sizing agent to a textile product, the method including: a step of sizing the textile product by bringing the textile product into contact with a fluid containing the sizing agent and supercritical carbon dioxide.

A device for coating one or more yarns by a vapor deposition method, the device including a treatment chamber defining a first and a second treatment zone in which at least one yarn is to be coated by performing a vapor deposition method, the first and second zones being separated by a wall and the first zone surrounding the second zone, or being superposed on the second zone; a conveyor system to transport the at least one yarn through the first and second zones; a first injector device to inject a first treatment gas phase into the first zone and a first removal device configured to remove the residual first gas phase from the first zone; and a second injector device configured to inject a second treatment gas phase into the second zone, and a second removal device configured to remove the residual second gas phase from the second zone.

A device for coating one or more yarns by a vapor deposition method, the device including a treatment chamber defining a first and a second treatment zone in which at least one yarn is to be coated by performing a vapor deposition method, the first and second zones being separated by a wall and the first zone surrounding the second zone, or being superposed on the second zone; a conveyor system to transport the at least one yarn through the first and second zones; a first injector device to inject a first treatment gas phase into the first zone and a first removal device configured to remove the residual first gas phase from the first zone; and a second injector device configured to inject a second treatment gas phase into the second zone, and a second removal device configured to remove the residual second gas phase from the second zone.

A textile article includes a first fabric including a plurality of first carbon nanotubes coupled to the first fabric. The first carbon nanotubes of the plurality of first carbon nanotubes are metallic carbon nanotubes. A second fabric includes a plurality of second carbon nanotubes coupled to the second fabric. The second carbon nanotubes of the plurality of second carbon nanotubes are semiconductive carbon nanotubes. The first fabric is interconnected with the second fabric.

A textile article includes a first fabric including a plurality of first carbon nanotubes coupled to the first fabric. The first carbon nanotubes of the plurality of first carbon nanotubes are metallic carbon nanotubes. A second fabric includes a plurality of second carbon nanotubes coupled to the second fabric. The second carbon nanotubes of the plurality of second carbon nanotubes are semiconductive carbon nanotubes. The first fabric is interconnected with the second fabric.

The invention relates to a textile protective material, in particular providing protection against radioactive harmful and/or toxic substances and/or against biological harmful and/or toxic substances and/or against chemical harmful and/or toxic substances, preferably a textile adsorption filter material, and to a method for the production thereof. The textile protective material is suitable in particular for producing protective equipment and protective objects and filters and filter materials of all types.

An EM structure to emit a low frequency oscillating electromagnetic energy field has a nonpolar substrate, carbon fiber and an epoxy mixture to adhere the carbon fiber to a substrate, such as Kydex. The polarity changes from nonpolar to polar upon application of direct heat. When the EM structure is configured with two opposing sides that have the same flex modulus, the EM structure is reactive to external materials. The electromagnetic field changes the structure, or energy level, of the unprocessed material to a positive, reinforcing energy while processed foods remain in a negative, draining state.

An EM structure to emit a low frequency oscillating electromagnetic energy field has a nonpolar substrate, carbon fiber and an epoxy mixture to adhere the carbon fiber to a substrate, such as Kydex. The polarity changes from nonpolar to polar upon application of direct heat. When the EM structure is configured with two opposing sides that have the same flex modulus, the EM structure is reactive to external materials. The electromagnetic field changes the structure, or energy level, of the unprocessed material to a positive, reinforcing energy while processed foods remain in a negative, draining state.