A fabricating method of a heat-insulating and UV-resistant fabric includes the following steps. A melt-spinning step is performed on a raw material to form a plurality of fibers, in which the raw material includes a near-infrared reflecting masterbatch, the near-infrared reflecting masterbatch includes a near-infrared reflecting dye, and when a content of the fibers is 100 wt %, a content of the near-infrared reflecting dye is 0.5 wt % to 1.0 wt %. The fibers are weaved to form the heat-insulating and UV-resistant fabric. A post-processing dyeing step is performed on the heat-insulating and UV-resistant fabric.

A fabricating method of a heat-insulating and UV-resistant fabric includes the following steps. A melt-spinning step is performed on a raw material to form a plurality of fibers, in which the raw material includes a near-infrared reflecting masterbatch, the near-infrared reflecting masterbatch includes a near-infrared reflecting dye, and when a content of the fibers is 100 wt %, a content of the near-infrared reflecting dye is 0.5 wt % to 1.0 wt %. The fibers are weaved to form the heat-insulating and UV-resistant fabric. A post-processing dyeing step is performed on the heat-insulating and UV-resistant fabric.

A cooling material is provided. The cooling material can include a yarn having a defined denier of less than or equal to approximately 90 denier, wherein the yarn can comprise a cooling additive disposed on or in a polymer. In some embodiments, the yarn can be at least one of a warp or a weft of a woven fabric. A method can comprise receiving a cooling material, wherein the cooling material comprises: a polymer and a cooling additive, wherein the cooling additive is disposed on or in the polymer; and processing the cooling material by employing a non-weaving technique to create a non-woven fabric. In some embodiments, the non-weaving technique is one of a meltblown process, a spunbond process, or a multi-denier process.

A textile article that includes a shawl that includes functional features.

In one aspect, the disclosure relates to cooling films comprising a substrate and one or more cooling materials deposited on the substrate. The disclosed cooling films can be used to prepare the disclosed cooling masterbatch materials. The disclosed cooling masterbatch materials can be used to prepare disclosed cooling yarns. The one or more cooling materials deposited on the substrate of a disclosed cooling film, dispersed in a disclosed cooling masterbatch material, or in disclosed cooling yarn are nano-sized particles. In still further aspects, the present disclosure pertains to a fabric comprising a disclosed cooling yarn. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

In one aspect, the disclosure relates to cooling films comprising a substrate and one or more cooling materials deposited on the substrate. The disclosed cooling films can be used to prepare the disclosed cooling masterbatch materials. The disclosed cooling masterbatch materials can be used to prepare disclosed cooling yarns. The one or more cooling materials deposited on the substrate of a disclosed cooling film, dispersed in a disclosed cooling masterbatch material, or in disclosed cooling yarn are nano-sized particles. In still further aspects, the present disclosure pertains to a fabric comprising a disclosed cooling yarn. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

Compositions of matter, methods, and systems for producing fibers, yarns, and fabrics with enhanced thermoregulation properties are provided. The composition may be created from a cellulose solution derived from natural sources, into which nano-sized phase change materials and high-specific heat minerals are incorporated. These additives form a mesoporous structure within the fiber, enabling the capture and retention of the nanomaterials. The method involves spinning this composite solution into yarn, which can be blended with additional fibers to produce a bespoke yarn. This yarn can then be knitted or woven into fabrics that maintain thermoregulation.

Compositions of matter, methods, and systems for producing fibers, yarns, and fabrics with enhanced thermoregulation properties are provided. The composition may be created from a cellulose solution derived from natural sources, into which nano-sized phase change materials and high-specific heat minerals are incorporated. These additives form a mesoporous structure within the fiber, enabling the capture and retention of the nanomaterials. The method involves spinning this composite solution into yarn, which can be blended with additional fibers to produce a bespoke yarn. This yarn can then be knitted or woven into fabrics that maintain thermoregulation.

A thermoelectric module includes two insulating substrates supporting a plurality of thermoelectric fingers. Each thermoelectric finger has alternating strips of n-type doped material and p-type doped material, wherein adjacent n-type doped strips and p-type doped strips are separated by and electrically coupled to conductive regions. The thermoelectric fingers run in a first direction and are spaced apart from each other. A plurality of holes in the insulating substrates are disposed between adjacent thermoelectric fingers, and area aligned with each other. A length of fabric yarn woven is in and out of substantially aligned holes in each substantially aligned set of holes.

A thermoelectric module includes two insulating substrates supporting a plurality of thermoelectric fingers. Each thermoelectric finger has alternating strips of n-type doped material and p-type doped material, wherein adjacent n-type doped strips and p-type doped strips are separated by and electrically coupled to conductive regions. The thermoelectric fingers run in a first direction and are spaced apart from each other. A plurality of holes in the insulating substrates are disposed between adjacent thermoelectric fingers, and area aligned with each other. A length of fabric yarn woven is in and out of substantially aligned holes in each substantially aligned set of holes.