The present invention provides a post-fabrication modification approach for the fabrication of colored and chromic materials and sensors using plasma surface modification to covalently bind the coloring agent to the substrate, thus avoiding leaching of the dye. Advantageously, in said methods, said coloring agent is a dye or pigment linked to a radical sensitive functional group, such as an alkenyl or alkynyl functional group, and is applied to the substrate prior to the gas plasma treatment. The methods envisaged herein are generic in nature, which allow the covalent immobilization of various dyes on different materials. The covalently coated materials after plasma surface modification, particularly the covalently coated chromic materials and sensors, can be used in many different applications, such as protective textile and wound dressing applications.

The present invention provides a post-fabrication modification approach for the fabrication of colored and chromic materials and sensors using plasma surface modification to covalently bind the coloring agent to the substrate, thus avoiding leaching of the dye. Advantageously, in said methods, said coloring agent is a dye or pigment linked to a radical sensitive functional group, such as an alkenyl or alkynyl functional group, and is applied to the substrate prior to the gas plasma treatment. The methods envisaged herein are generic in nature, which allow the covalent immobilization of various dyes on different materials. The covalently coated materials after plasma surface modification, particularly the covalently coated chromic materials and sensors, can be used in many different applications, such as protective textile and wound dressing applications.

The present invention provides a post-fabrication modification approach for the fabrication of colored and chromic materials and sensors using plasma surface modification to covalently bind the coloring agent to the substrate, thus avoiding leaching of the dye. Advantageously, in said methods, said coloring agent is a dye or pigment linked to a radical sensitive functional group, such as an alkenyl or alkynyl functional group, and is applied to the substrate prior to the gas plasma treatment. The methods envisaged herein are generic in nature, which allow the covalent immobilization of various dyes on different materials. The covalently coated materials after plasma surface modification, particularly the covalently coated chromic materials and sensors, can be used in many different applications, such as protective textile and wound dressing applications.

The present invention provides a post-fabrication modification approach for the fabrication of colored and chromic materials and sensors using plasma surface modification to covalently bind the coloring agent to the substrate, thus avoiding leaching of the dye. Advantageously, in said methods, said coloring agent is a dye or pigment linked to a radical sensitive functional group, such as an alkenyl or alkynyl functional group, and is applied to the substrate prior to the gas plasma treatment. The methods envisaged herein are generic in nature, which allow the covalent immobilization of various dyes on different materials. The covalently coated materials after plasma surface modification, particularly the covalently coated chromic materials and sensors, can be used in many different applications, such as protective textile and wound dressing applications.

A method for producing durable fluffy and soft loop fabric having embedded weft floats, including: 1) yarn selection; 2) winding; 3) warping; 4) sizing; 5) weaving; and 6) dyeing and finishing. During the weaving process, low-twist or zero-twist yarns or filament long floats are embedded into loops. During the dyeing and finishing process, due to weft-wise shrinkage, the embedded weft floats shrink and expand, thereby supporting the loops upright without lodging. In addition, the fluffy zero-twist yarns and interlaced yarn floats form a stacked stereoscopic structure with other weft yarns fixedly connected to the loops, thereby facilitating the extension of the loops and enlarging moisture diffusion surfaces of the loops during baking and air-drying processes to create a rapid drying condition for towels. Therefore, a loop fabric which has a special style and a fluffy and soft hand feeling and is still fluffy and soft after being washed is obtained.

A method for producing durable fluffy and soft loop fabric having embedded weft floats, including: 1) yarn selection; 2) winding; 3) warping; 4) sizing; 5) weaving; and 6) dyeing and finishing. During the weaving process, low-twist or zero-twist yarns or filament long floats are embedded into loops. During the dyeing and finishing process, due to weft-wise shrinkage, the embedded weft floats shrink and expand, thereby supporting the loops upright without lodging. In addition, the fluffy zero-twist yarns and interlaced yarn floats form a stacked stereoscopic structure with other weft yarns fixedly connected to the loops, thereby facilitating the extension of the loops and enlarging moisture diffusion surfaces of the loops during baking and air-drying processes to create a rapid drying condition for towels. Therefore, a loop fabric which has a special style and a fluffy and soft hand feeling and is still fluffy and soft after being washed is obtained.

A method and an integrated system for dyeing synthetic, natural, and blended textiles in the form of fabrics, yarns, and garments are provided. The integrated system includes a first pressurizing pump for pressurizing liquefied CO.sub.2 to supercritical CO.sub.2 (Sc—CO.sub.2); a second pressurizing pump for pressurizing CO.sub.2 to liquefied CO.sub.2; a liquefied CO.sub.2 storage vessel for storing the liquefied CO.sub.2 and the separated liquefied CO.sub.2 from the one or more cyclone separators; a heater for heating the Sc—CO.sub.2; a dyestuff vessel for mixing a dyestuff and the Sc—CO.sub.2 to obtain Sc—CO.sub.2-mixed dyestuff; a dyeing vessel for dyeing the textile by circulating the Sc—CO.sub.2 and the Sc—CO.sub.2-mixed dyestuff between the dyeing vessel and the dyestuff vessel; and one or more cyclone separators for removing the dyestuff from the Sc—CO.sub.2-mixed dyestuff to obtain separated liquefied CO.sub.2.

A textile printing ink jet ink composition set includes a textile printing ink jet ink composition having a hue angle ∠h° within a range of 260° or more and 310° or less and a chroma C* of 45 or less, which are specified in the CIELAB color space, on a textile printing product after textile printing; and a textile printing ink jet ink composition having a hue angle ∠h° within a range of 15° or more and 80° or less and a chroma C* of 65 or less, which are specified in the CIELAB color space, on a textile printing product after textile printing.

The disclosure provides a method of continuous dyeing with reactive dyes in wet conditions, the method including: 1) adding fabric to a mixture of a dye liquor and an alkali through a one-bath-one-step method; 2) immersing the fabric pretreated in 1) in a padding liquor with an air film horizontal pad dyeing machine; 3) preheating the fabric after being treated in 2) at a temperature of 50-90° C.; and 4) rolling and batching the fabric after being treated in 3) at a temperature of 10-70° C. for 2-72 hours.

The disclosure provides a method of continuous dyeing with reactive dyes in wet conditions, the method including: 1) adding fabric to a mixture of a dye liquor and an alkali through a one-bath-one-step method; 2) immersing the fabric pretreated in 1) in a padding liquor with an air film horizontal pad dyeing machine; 3) preheating the fabric after being treated in 2) at a temperature of 50-90° C.; and 4) rolling and batching the fabric after being treated in 3) at a temperature of 10-70° C. for 2-72 hours.