Process for making a fabric label (1) containing one piece of unique electronically-readable information; characterized by comprising the following steps: providing a fabric bolt made of a material mainly comprising synthetic fibers at least in the weft, generating at least one array of m×n cells, being n the number of rows and m the number of columns; generating at least one first sequence of variable information (3); associating the variable information (3) to the cells of the previous array in compliance with a predetermined logic; inserting, by the use of an image assembler, the graphic form that can be associated with each of said variable information (3) into a cell of a graphics array (5) with size m×n; printing said array (5) of images on a first medium (8) through a digital printing process; transferring said print, by heating, through a process named sublimation on said bolt (7) to generate a second medium (9) of fabric comprising said array (5); storing in a database the variable information (3) printed on each label (1), taking care of tuning the column m and the row n on which every information has been positioned; cutting the second medium (9) of fabric in m ribbons or labels rows (12) having size adapted to be wound on bobbins (13) that are wide as wide the single cell is.

Process for making a fabric label (1) containing one piece of unique electronically-readable information; characterized by comprising the following steps: providing a fabric bolt made of a material mainly comprising synthetic fibers at least in the weft, generating at least one array of m×n cells, being n the number of rows and m the number of columns; generating at least one first sequence of variable information (3); associating the variable information (3) to the cells of the previous array in compliance with a predetermined logic; inserting, by the use of an image assembler, the graphic form that can be associated with each of said variable information (3) into a cell of a graphics array (5) with size m×n; printing said array (5) of images on a first medium (8) through a digital printing process; transferring said print, by heating, through a process named sublimation on said bolt (7) to generate a second medium (9) of fabric comprising said array (5); storing in a database the variable information (3) printed on each label (1), taking care of tuning the column m and the row n on which every information has been positioned; cutting the second medium (9) of fabric in m ribbons or labels rows (12) having size adapted to be wound on bobbins (13) that are wide as wide the single cell is.

The present disclosure provides dye compounds for use in dyeing textiles.

A composition with advantages for textile fibers is disclosed. The composition is a melt of polyester precursors selected from the group consisting of terephthalic acid, dimethyl terephthalate, ethylene glycol, sebacic acid in an amount sufficient to give filaments and fibers made from the melt a dye receptivity similar to cotton at atmospheric pressure; pentaerythritol in an amount sufficient to give pill resistance to yarns blended of cotton with fibers made from the melt, and polyethylene glycol in an amount sufficient to give the melt the elasticity necessary to produce extruded filament from the melt. In an exemplary embodiment, the copolymer melt includes between about 4 and 6 percent sebacic acid, between about 500 and 800 ppm pentaerythritol, and between about 3.5 and 3.9 percent polyethylene glycol, with less than 2 percent DEG, at an intrinsic viscosity of between about 0.640 and 0.690 dl/g, and at a temperature of between about 268° C. and 271° C., with the proportional amounts being based on the amount of polymerized copolymer.

A composition with advantages for textile fibers is disclosed. The composition is a melt of polyester precursors selected from the group consisting of terephthalic acid, dimethyl terephthalate, ethylene glycol, sebacic acid in an amount sufficient to give filaments and fibers made from the melt a dye receptivity similar to cotton at atmospheric pressure; pentaerythritol in an amount sufficient to give pill resistance to yarns blended of cotton with fibers made from the melt, and polyethylene glycol in an amount sufficient to give the melt the elasticity necessary to produce extruded filament from the melt. In an exemplary embodiment, the copolymer melt includes between about 4 and 6 percent sebacic acid, between about 500 and 800 ppm pentaerythritol, and between about 3.5 and 3.9 percent polyethylene glycol, with less than 2 percent DEG, at an intrinsic viscosity of between about 0.640 and 0.690 dl/g, and at a temperature of between about 268° C. and 271° C., with the proportional amounts being based on the amount of polymerized copolymer.

An aqueous ink jet ink composition contains an organic solvent with an SP value of 9.5 to 10.5, resin particles, a plasticizer, and water. With respect to the amount of the aqueous ink jet ink composition, 1.0% by mass to 10.0% by mass of the organic solvent is contained.

This invention relates to a functional textile manufacturing system. This system uses weaving equipment, dyeing and finishing equipment, shaping equipment, evaporation equipment, lamination equipment, roll adhesion equipment and printing equipment for production. Weaving equipment, dyeing and finishing equipment and shaping equipment are used for weaving, dyeing, washing and shaping to process low-cost polyester fibers into shaped fabric. Then, the evaporation equipment is used to evaporate a metal onto a plane release film to form a metal evaporation release film, and the lamination equipment, roll adhesion equipment and printing equipment are used to laminate the shaped fabric and the metal evaporation release film and to adhere a printed layer on the functional thin film. Such a manufacturing system can produce laundry resistant unconventional material antimicrobial protective fabric that features special temperature control, antimicrobial, waterproof, breathable, scratch resistant properties, as well as comfortable feeling.

This invention relates to a functional textile manufacturing system. This system uses weaving equipment, dyeing and finishing equipment, shaping equipment, evaporation equipment, lamination equipment, roll adhesion equipment and printing equipment for production. Weaving equipment, dyeing and finishing equipment and shaping equipment are used for weaving, dyeing, washing and shaping to process low-cost polyester fibers into shaped fabric. Then, the evaporation equipment is used to evaporate a metal onto a plane release film to form a metal evaporation release film, and the lamination equipment, roll adhesion equipment and printing equipment are used to laminate the shaped fabric and the metal evaporation release film and to adhere a printed layer on the functional thin film. Such a manufacturing system can produce laundry resistant unconventional material antimicrobial protective fabric that features special temperature control, antimicrobial, waterproof, breathable, scratch resistant properties, as well as comfortable feeling.

A moisture-sensed shrinking ink applied to a digital printing process for fabric has a viscosity between 2.5 cP and 10.0 cP and a surface tension between 22 dyne/cm and 32 dyne/cm, in which the moisture-sensed shrinking ink includes 15 parts by weight to 35 parts by weight of a moisture-sensed shrinking resin and 65 parts by weight to 85 parts by weight of water.

Disclosed is a leather-like sheet having a lightness L* of 35 or less, and including a fiber structure including fiber dyed with a dye composition including C.I. Basic Blue 3 and at least one blue cationic dye other than C.I. Basic Blue 3, and an elastic polymer contained in internal voids of the fiber structure, or the fiber structure. Also disclosed is a leather-like sheet having a lightness L* of 35 or less, and including a fiber structure including fiber dyed with an azo-based blue cationic dye, and an elastic polymer contained in internal voids of the fiber structure, wherein the leather-like sheet or the fiber structure has a color difference (ΔE), determined when treated for 48 hours under moist and hot conditions of 80° C. and a moisture of 90%, of ΔE≤2. or the fiber structure.