CN110735333A - Novel dyeing-color fixing method of micromolecular natural dye - Google Patents

Abstract

The invention belongs to the technical field of textile printing and dyeing, and particularly relates to a dyeing-color fixing method of a micromolecular natural dye. Because the micromolecule natural dye has low molecular weight and lacks groups combined with fibers, the micromolecule natural dye cannot be fixed on the fibers and only can float on the surface, and the micromolecule natural dye can fade after being simply soaped, so that direct dyeing cannot be realized. The method introduces soluble quantum dots into the dyeing bath of the micromolecular natural dye, utilizes the quantum dots to influence the dyeing process of the micromolecular natural dye, and changes the aggregation state of the dye, thereby improving the fixation of the dye on the fabric, reducing the color fading and further improving the color fastness of the dye on the fabric.

Description

Novel dyeing-color fixing method of micromolecular natural dye

Technical Field

The invention belongs to the technical field of textile printing and dyeing, relates to a dyeing method of natural dye, and particularly relates to a novel dyeing-color fixing method of micromolecular natural dye.

Background

Natural dyes have gained popularity in recent years due to their natural, environmentally friendly characteristics. However, natural plant dyes have poor affinity to fibers, are difficult to dye, have poor color fastness indexes, and are also important reasons for replacing natural dyes with synthetic dyes. The micromolecule natural dye can hardly be directly dyed on the fiber, and the mordant dyeing technology is mainly used, namely, the action mode of the micromolecule natural dye and the fiber is changed by utilizing metal ion complexation, so that the mordant dyeing of the natural dye is carried out. The mordant dyeing mode of natural dye can be divided into front mordant, back mordant and one-bath.

At present, as the ecological environment protection requirement, banning/limiting of heavy metal ions, a mordant with excellent properties such as chromium, copper and the like can not be/is limited to be used on textiles, so, technologists also improve the fastness of natural dyes on the textiles by adopting a non-banned metal as a mordant or developing a new method, for example, the natural dye dyeing process of cashmere fabrics is improved by adopting a mode of alum one-bath mordant dyeing and protein derivative addition in Chinese patent CN109235076A < >, a dyeing solution also comprises a protein derivative and a plurality of surfactants besides aluminum metal ions, 1, 6-hexanediol is added during dyeing, heat preservation is carried out for 40-60 min, the process steps are more, a method of firstly carrying out plasma treatment and then carrying out padding on a chitosan solution in the dyeing process is adopted to improve the dyeing fastness and the depth of the natural dyes and the textiles, a low-temperature plasma treatment instrument is not suitable for industrial push , CN108589334A is used for preparing natural dye, a method of 355635 is used for preparing natural dye, a method of carrying out surface dyeing by adopting a mixed plasma dyeing and padding into a natural dye solution is used for improving the dyeing fastness and deep dyeing of natural dye and deep dyeing of textiles, a method of a natural dye by adopting a mixed dyeing liquid ammonia-silicon substrate dyeing process for adding a high-based dyeing process for deep dyeing of a natural dye-3526 dyeing process for controlling a deep dyeing of a natural dye, a deep dyeing process of a natural dye, wherein the deep dyeing of a natural dye, a natural dye is not suitable for deep dyeing process of a natural dye, a deep dyeing process of a natural dye for improving a deep dyeing process of a deep dyeing polyvinyl pyrrolidone.

In recent years, rapid development of nanotechnology has seen two directions for its application in natural dyes, is in the direction of sensitized cells, such as patent CN103280325A "sensitized solar cells based on natural organic dyes and ZnO single crystal nanoarrays", secondly, organic dye molecules (ruthenium or osmium complexes) are doped in monodisperse silica nanospheres by using fluorescence effect for preparing fluorescent probes for marking, such as patent CN101457139A, which utilizes the photoelectric conversion effect of polypyrrole complexes of group viii metals, Zhu et al (Zhu L, Yin Y, Wang C F, et al. journal of materials Chemistry C,2013,1(32),4925.) carbon dot solutions synthesized from plant leaves are added to inkjet printers as inks to draw patterns, and imaging images can be clearly seen under ultraviolet rays, and also the fluorescence color rendering property of the carbon dot solutions can be used for dyeing fibers with ultra-small-sized quantum dots in small-molecule natural dyes to change their dyeing properties.

Disclosure of Invention

The invention aims to provide novel dyeing-color fixing methods of micromolecular natural dyes, and the dye uptake and the dye fastness of the micromolecular natural dyes can be improved by the methods.

The micromolecule natural dye has low molecular weight and small molecules, is lack of groups combined with fibers, cannot be fixed on the fibers, only can float on the fibers, and can fade by simple soaping, so that direct dyeing cannot be realized. Testing K/S values of the dyed fabrics/fibers before and after soaping by using a computer testing color matching instrument, and calculating the retention rate N of the K/S values by using a formula (1)_K/SBy N_K/STo characterize the fading of the fabric/fiber during dyeing.

The water-soluble quantum dots are kinds of nanometer-scale particles, which can be divided into carbon quantum dots and silicon-carbon quantum dots according to the source, the size is less than 10nm, the active groups (amino, hydroxyl, carboxyl and the like) point to the water phase, and a stable solution can be formed in water.

The technical scheme adopted for solving the technical problems is that water-soluble quantum dots (carbon quantum dots and silicon-carbon quantum dots) are introduced into a dyeing bath of micromolecular natural dye, the micromolecular natural dye is influenced to be dyed by the water-soluble quantum dots, and the aggregation state of the dye is changed, so that the fixation of the dye on the fabric is improved, the fading is reduced, and the color fastness of the dye on the fabric is improved.

The dyeing-fixing method provided by the invention can be used for treating the water-soluble quantum dots and the micromolecular natural dye in one bath; the fabric/fiber can be treated by adopting water-soluble quantum dots, and then dyed by micromolecular natural dye; the method can be that the micromolecule natural dye firstly dyes the fabric/fiber, and then the dyed fiber is treated by the water-soluble quantum dots.

The specific method and the formula are as follows:

① the one-bath method comprises adding the water-soluble quantum dot solution into the micromolecular natural dye solution, mixing, preparing dye solution, and dyeing the fabric/fiber.

The dyeing formula is as follows: the bath ratio is 1: 10-50; dyeing temperature is 40-80 ℃; dyeing time is 5-60 min; soaping, washing and drying to obtain a dyeing sample.

② the pretreatment method comprises treating the fabric/fiber with water soluble quantum dot solution, and dyeing with micromolecular natural dye.

The pretreatment formula comprises: the bath ratio is 1: 10-50; the treatment temperature is 20-30 ℃; the treatment time is 1-5 min; and (5) wringing.

The dyeing formula comprises the following components: the bath ratio is 1: 10-50; dyeing temperature is 40-80 ℃; dyeing time is 5-60 min; soaping, washing and drying to obtain a dyeing sample.

③ post-treatment method, which comprises dyeing with micromolecular natural dye, and treating the dyed fabric/fiber with water-soluble quantum dot solution.

The dyeing formula comprises the following components: the bath ratio is 1: 10-50; dyeing temperature is 40-80 ℃; dyeing time is 5-60 min; and (5) wringing.

The post-treatment formula comprises: the bath ratio is 1: 10-50; the treatment temperature is 20-30 ℃; the treatment time is 1-5 min; soaping, washing and drying to obtain a dyeing sample.

Compares the K/S retention rate N after soaping in the dyeing process in the three methods_K/SWherein the one-bath dyeing is N_K/SGreater than 80%, andthe color of the front and the back has no obvious change. Pretreatment dyeing N_K/SMore than 70 percent, and the color and luster before and after the color and luster are not obviously changed. Method of post-dyeing treatment N_K/SMore than 50 percent, and the color changes from front to back.

The method of the invention selects one-bath dyeing preferentially, the water-soluble quantum dot solution is added into the micromolecule natural dye solution, and the mixture is mixed evenly to prepare dye liquor for dyeing the fabrics/fibers.

The dyeing formula is as follows: the bath ratio is 1: 10-50; dyeing temperature is 40-80 ℃; dyeing time is 5-60 min; soaping, washing and drying to obtain a dyeing sample.

The quantum dot solution provided by the invention is a water-soluble quantum dot solution, the solubility of the quantum dot solution in water is good, and the size of the quantum dot is less than 10 nm. The carbon quantum dot solution or the silicon-carbon quantum dot solution can be used.

The carbon quantum dot solution provided by the invention is prepared by the following specific steps: mixing sodium citrate or sodium ascorbate with an alkaline agent, reacting at 150-200 ℃ for 1-5h, cooling to room temperature, purifying, performing ultrafiltration, and adding deionized water to dilute by 0-50 times according to volume.

Wherein the alkaline agent is sodium hydroxide, ammonium bicarbonate or urea. The molar ratio of the alkaline agent to the sodium citrate or the sodium ascorbate is 1:20-30

The silicon-carbon quantum dot solution provided by the invention is prepared by the following specific steps: hydrolyzing the silane coupling agent in water at 50-60 ℃ for 20-50 min, then adding a reducing agent, stirring for 30-50 min, and adding deionized water to dilute by 0-50 times according to volume.

The molar ratio of the silane coupling agent to the reducing agent is 50-20: 1, the involved silane coupling agent is or a mixture of more than two of KH550 (gamma-aminopropyltriethoxysilane), KH560 (gamma-glycidoxypropyltrimethoxysilane) and KH570 (gamma-methacryloxypropyltrimethoxysilane), and the involved reducing agent is of ascorbic acid, sodium ascorbate, citric acid and sodium citrate.

The molecular weight of the micromolecular natural dye is less than 500, and the micromolecular natural dye lacks a group directly dyed with fabrics/fibers in the structure and can be complexed through a metal mediumThe obtained stable color is difficult to dye on the fabric/fiber directly, and the direct dyeing is shown as the floating color, and the K/S value retention rate N of the dyed soap washed fabric/fiber_K/SLess than 20%, and discoloration was severe.

The micromolecule natural dye provided by the invention is derived from natural plant extracts and can be types of sappan wood extracts (mainly containing hematoxylin and hematoxylin oxide), madder extracts (mainly containing alizarin), honeysuckle extracts (mainly containing luteolin) and tea extracts (mainly containing catechin).

The invention has the beneficial effects that:

(1) the micromolecular natural dye can be dyed on the fabric/fiber without using metal medium ions, and the K/S retention rate N is_K/SHigher and more stable color and luster obtained by dyeing.

(2) The chemicals related in the scheme provided by the invention only contain carbon, silicon and oxygen elements or sodium elements, and are ecological and environment-friendly.

(3) The dyeing-color fixing process operation in the scheme provided by the invention is similar to that of a metal mordant dyeing method, additional equipment and process are not required, workers are not required to be trained, and the method is convenient for .

Detailed Description

The invention is further described in with reference to specific examples, it being understood that these examples are intended to illustrate the invention and are not intended to limit the scope of the invention in any way.

Example 1

Silicon carbon quantum dot solution 1

The molar ratio of KH550 to ascorbic acid is 50: 1. Hydrolyzing silane coupling agent KH550 (industrial product) in deionized water at 50 deg.C for 20min, adding reducing agent ascorbic acid, and stirring for 30 min. Preparing the silicon-carbon quantum dot solution 1, wherein the particle size of the quantum dot is 2.2 +/-0.4 nm.

Silicon carbon quantum dot solution 2

The molar ratio of KH560 to sodium ascorbate was 42: 1. Hydrolyzing silane coupling agent KH560 (industrial product) in 55 deg.C water for 50min, adding reducing agent sodium ascorbate, stirring for 50min, adding deionized water to dilute the solution to 20 times of original volume to obtain silicon-carbon quantum dot solution 2 with quantum dot particle size of 1.8 + -0.4 nm.

Silicon carbon quantum dot solution 3

The molar ratio of the silane coupling agent KH570 to the citric acid was 35: 1. Hydrolyzing silane coupling agent KH570 (industrial product) in 60 deg.C water for 30min, adding reducing agent citric acid, stirring for 40min, and adding deionized water to dilute the solution to 31 times of original volume. Preparing the silicon-carbon quantum dot solution 3, wherein the particle size of the quantum dot is 1.5 +/-0.4 nm.

Silicon carbon quantum dot solution 4

The molar ratio is as follows: KH 570: KH 560: sodium citrate 10:10: 1. Hydrolyzing silane coupling agent KH570 (industrial product) in water at 57 deg.C for 39min, adding reducing agent sodium citrate, stirring for 35min, adding deionized water to dilute the solution to 51 times of the original volume, wherein the particle size of the quantum dot is 2.6 + -0.4 nm.

Carbon quantum dots 1

Mixing sodium citrate and ammonium bicarbonate, reacting at 150 ℃ for 5h, cooling to room temperature, purifying, ultrafiltering by using a dialysis bag, and adding deionized water to dilute to 11 times of the original volume. The molar ratio is as follows: sodium citrate: ammonium bicarbonate 30: 1. The quantum dot particle size is less than 10 nm.

Carbon quantum dots 2

Mixing sodium citrate and ammonium bicarbonate, reacting at 200 ℃ for 1h, cooling to room temperature, purifying, performing ultrafiltration by using an ultrafiltration membrane, and adding deionized water to dilute to 26 times of the original volume. The molar ratio is as follows: sodium citrate: ammonium bicarbonate 20: 1. The particle size of the quantum dots is less than 10 nm.

Example 2

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: two pieces of real silk woven fabric

Adding the silicon-carbon quantum dot solution 1 (the quantum dot stock solution prepared in example 1) into a hematoxylin dye solution, mixing uniformly to prepare a dye solution, and dyeing the fabric.

The dyeing formula is as follows:

the concentration of the hematoxylin dye is 0.5g/L, the concentration of the silicon-carbon quantum dots is 0.5g/L, and the bath ratio is 1: 10; the dyeing temperature is 40 ℃; dyeing for 10min to obtain two fabrics 1 and 2.

Drying the fabric 1, measuring the K/S value of 1.4014, and determining the color characteristic value: l64.23, a 19.55, b 17.78;

soaping, washing and drying the fabric 2, measuring the K/S value of the fabric to be 1.364, and measuring the color characteristic value: l64.47, a 19.18, b 17.59.

Retention ratio of K/S N after washing with dyeing soap_K/S97% and no change in color before and after.

Comparative example 1

Direct dyeing with small molecular natural dye (without silicon carbon quantum dots and other substances)

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: two pieces of real silk woven fabric

The dyeing formula is as follows:

the concentration of the hematoxylin dye is 0.5g/L, and the bath ratio is 1: 10; the dyeing temperature is 40 ℃; dyeing for 10min to obtain two fabrics 3 and 4.

Drying the fabric 3, measuring the K/S value of 1.4961, and determining the color characteristic value: l76.49, a 11.66, b 37.98;

soaping, washing and drying the fabric 4, measuring the K/S value of the fabric to be 0.1905, and measuring the color characteristic value: l82.64, a 6.17, b 6.71.

Retention ratio of K/S N after washing with dyeing soap_K/S13 percent and the color change before and after the color change is obvious.

Comparative example 2

Dyeing with small molecular natural dye coupling agent (adding coupling agent KH550)

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: two pieces of real silk woven fabric

The dyeing formula is as follows:

the concentration of the hematoxylin dye is 0.5g/L, the coupling agent KH5500.5g/L and the bath ratio is 1: 10; the dyeing temperature is 40 ℃; dyeing for 10min to obtain two fabrics 5 and 6 with colored film on the surface.

Drying the fabric 5, carrying out color spot, measuring the K/S value of 1.9866, and carrying out color characteristic value: l54.8, a 20.42, b 9.39;

6 soaping, washing, drying, having color spots and uneven color distribution, measuring the K/S value of 1.1665, and obtaining the color characteristic value: l64.52, a 23.22, b 9.66.

Comparative example 2'

Micromolecular natural dye chitosan dyeing

Preparing a chitosan solution (with glacial acetic acid as a solvent) with the mass percentage concentration of 1 percent

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: two pieces of real silk woven fabric

Adding the chitosan solution into the hematoxylin dye solution, mixing uniformly to prepare dye solution, and dyeing the fabric.

The dyeing formula is as follows:

the concentration of the hematoxylin dye is 0.5g/L, the concentration of the chitosan is 0.5g/L, and the bath ratio is 1: 10; the dyeing temperature is 40 ℃; dyeing for 10min to obtain two fabrics 7 and 8.

Drying the fabric 7, measuring the K/S value of 2.037, and determining the color characteristic value: l66.95, a 8.96, b 29.57;

soaping, washing and drying the fabric 8, measuring the K/S value of the fabric to be 1.0032, and measuring the color characteristic value: l80.72, a 7.12, b 21.75.

Retention ratio of K/S N after washing with dyeing soap_K/S49 percent and more obvious color change before and after.

Example 3

Small molecule natural dyes: radix Rubiae extract (alizarin as main ingredient)

Fabric: two pieces of wool knitted fabric

The carbon quantum dot solution 1 (the diluted quantum dot solution in example 1) is used for treating wool fabric, and then the wool fabric is added into the madder dye solution for dyeing.

The pretreatment formula comprises: the concentration of the carbon quantum dots is 1g/L, and the bath ratio is 1: 10; the treatment temperature is 20 ℃; the treatment time is 1 min; and (5) wringing.

The dyeing formula comprises the following components: the concentration of the madder dye is 1g/L, and the bath ratio is 1: 20; the dyeing temperature is 50 ℃; dyeing time is 30 min; two pieces of fabric 9, 10 are obtained.

Drying the fabric 9, measuring the K/S value of 1.8763, and determining the color characteristic value: l61.42, a 18.48, b 22.27;

soaping, washing and drying the fabric 10, measuring the K/S value of the fabric to be 1.4264, and measuring the color characteristic value: l63.07, a 15.04, b 18.42.

Retention ratio of K/S N after washing with dyeing soap_K/S76% and no obvious change in color before and after.

Comparative example 3

Small molecule natural dyes: radix Rubiae extract (alizarin as main ingredient)

Fabric: two pieces of wool knitted fabric

The dyeing formula without adding carbon quantum dots is as follows:

the concentration of the madder dye is 1g/L, and the bath ratio is 1: 20; the dyeing temperature is 50 ℃; dyeing for 30min to obtain two fabrics 11 and 12.

Drying the fabric 11, measuring the K/S value of 1.5442, and determining the color characteristic value: l74.18, a 12.46, b 30.53;

soaping, washing and drying the fabric 12, measuring the K/S value of the fabric to be 0.2007, and measuring the color characteristic value: l70.32, a 14.50, b 23.41.

Retention ratio of K/S N after washing with dyeing soap_K/S13 percent and the color change before and after the color change is obvious.

Example 4

Small molecule natural dyes: flos Lonicerae extract (luteolin as main ingredient)

Fabric: two wool tops

Wool tops were treated with the honeysuckle dye and then treated with carbon quantum dot solution 2 (diluted quantum dot solution from example 1).

The dyeing formula comprises the following components: 2g/L of honeysuckle dye, and the bath ratio is 1: 50; the dyeing temperature is 80 ℃; dyeing time is 30 min; and (5) wringing.

The post-treatment formula comprises: the concentration of the carbon quantum dots 2 is 2g/L, and the bath ratio is 1: 50; the treatment temperature is 30 ℃; the treatment time is 5 min; two wool tops 13, 14 are obtained.

Drying the wool tops 13, measuring the K/S value of the wool tops to be 2.3028, and determining the color characteristic value: l81.49, a 0.66, b 13.98;

soaping the wool top 14, washing with water, drying, measuring the K/S value of 1.2205, and measuring the color characteristic value: l82.31, a 0.73, b 13.79.

Retention ratio of K/S N after washing with dyeing soap_K/S53 percent, and the color of the front and the back is not obviously changed.

Comparative example 4

Small molecule natural dyes: flos Lonicerae extract (luteolin as main ingredient)

Fabric: two wool tops

The dyeing formula without adding carbon quantum dots is as follows:

the concentration of the honeysuckle dye is 2g/L, and the bath ratio is 1: 50; the dyeing temperature is 80 ℃; dyeing time is 30 min; two pieces of fabric 15, 16 are obtained.

Drying the fabric 15, measuring the K/S value of 1.7961, and determining the color characteristic value: l76.56, a 2.71, b 15.36;

washing 16 fabrics with soap, washing with water, drying, measuring the K/S value of 0.2905, and measuring the color characteristic value: l72.31, a 0.54, b 14.12.

Retention ratio of K/S N after washing with dyeing soap_K/S16 percent and the color change before and after the color change is obvious.

Example 5

Small molecule natural dyes: tea extract (catechin as main ingredient)

Fabric: two parts of silk yarn

Adding the silicon-carbon quantum dot solution 2 (the diluted quantum dot solution in the embodiment 1) into the tea dye solution, mixing uniformly to prepare a dye solution, and dyeing the real silk yarns.

The dyeing formula is as follows:

the concentration of the tea dye is 3g/L, the concentration of the silicon-carbon quantum dots is 2g/L, and the bath ratio is 1: 50; the dyeing temperature is 80 ℃; dyeing time is 40min, and two parts of yarns 17 and 18 are obtained.

Drying the yarn 17, measuring the K/S value of 3.1015, and determining the color characteristic value: l55.06, a 18.87, b 6.1;

soaping the yarn 18, washing with water, drying, measuring the K/S value of 2.9770, and measuring the color characteristic value: l55.47, a 19.18, b 6.59.

Retention ratio of K/S N after washing with dyeing soap_K/S96% and no change in color before and after.

Comparative example 5

Small molecule natural dyes: tea extract (catechin as main ingredient)

Fabric: two parts of silk yarn

The dyeing formula is as follows without adding silicon-carbon quantum dots:

the concentration of the tea dye is 3g/L, and the bath ratio is 1: 50; the dyeing temperature is 80 ℃; dyeing time 40min, two yarns 19, 20 are obtained.

Drying the yarn 19, measuring the K/S value of 2.8437, and determining the color characteristic value: l53.76, a 16.33, b 7.80;

and (3) soaping, washing and drying the yarn 20, measuring the K/S value of the yarn to be 0.2559, and measuring the color characteristic value: l40.91, a 7.42, b 7.55.

Retention ratio of K/S N after washing with dyeing soap_K/S9 percent and more obvious color change before and after.

Example 6

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: weaving two pieces of silk and wool blended machine

Adding the silicon-carbon quantum dot solution 3 (the diluted quantum dot solution in the embodiment 1) into the hematoxylin dye solution, mixing uniformly to prepare dye solution, and dyeing the fabric.

The dyeing formula is as follows:

the concentration of the hematoxylin dye is 0.5g/L, the concentration of the silicon-carbon quantum dots is 3g/L, and the bath ratio is 1: 30; the dyeing temperature is 60 ℃; dyeing for 5min to obtain two fabrics 21 and 22.

Drying the fabric 21, measuring the K/S value of 2.1014, and determining the color characteristic value: l75.05, a 14.27, b 16.97;

soaping the fabric 22, washing with water, drying, measuring the K/S value of 2.0173, and measuring the color characteristic value: l74.71, a 15.56, b 16.39.

Retention ratio of K/S N after washing with dyeing soap_K/S96% and no change in color before and after.

Comparative example 6

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: weaving two pieces of silk and wool blended machine

The dyeing formula is as follows without adding silicon-carbon quantum dot solution:

the concentration of the hematoxylin dye is 0.5g/L, and the bath ratio is 1: 30; the dyeing temperature is 60 ℃; dyeing time is 5min, and two fabrics 23 and 24 are obtained.

Drying the fabric 23, measuring the K/S value of 1.9481, and determining the color characteristic value: l73.61, a 16.92, b 15.34;

soaping the fabric 24, washing with water, drying, measuring the K/S value of 0.2013, and measuring the color characteristic value: l54.24, a 15.63, b 17.90.

Retention ratio of K/S N after washing with dyeing soap_K/S10 percent and the color change before and after the color change is obvious.

Example 7

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: two blocks of true silk skein

Adding the silicon-carbon quantum dot solution 4 (the diluted quantum dot solution in the embodiment 1) into the hematoxylin dye solution, mixing uniformly to prepare dye solution, and dyeing the skein.

The dyeing formula is as follows:

the concentration of the hematoxylin dye is 1g/L, the concentration of the silicon-carbon quantum dots is 5g/L, and the bath ratio is 1: 50; the dyeing temperature is 80 ℃; dyeing time is 60min, and two skeins 25 and 26 are obtained.

And (3) drying the skein 25, measuring the K/S value of the skein to be 1.6981, and determining the color characteristic value: l71.15, a 8.27, b 31.89;

soaping the skein 26, washing, drying, measuring the K/S value of 1.4436, and measuring the color characteristic value: l71.22, a 7.93, b 26.03.

Retention ratio of K/S N after washing with dyeing soap_K/S85% and no change in color before and after.

Comparative example 7

Small molecule natural dyes: lignum sappan extract (hematoxylin and hematoxylin oxide as main ingredients)

Fabric: two blocks of true silk skein

The dyeing formula is as follows without adding silicon-carbon quantum dot solution:

the concentration of the hematoxylin dye is 1g/L, and the bath ratio is 1: 50; the dyeing temperature is 80 ℃; dyeing time is 60min, and two skeins 27 and 28 are obtained.

Drying the fabric 27, measuring the K/S value of 1.1986, and determining the color characteristic value: l62.59, a 20.63, b 11.71;

soaping, washing and drying the fabric 28, measuring the K/S value of the fabric to be 0.1979, and measuring the color characteristic value: l43.35, a 25.30, b 10.06.

Retention ratio of K/S N after washing with dyeing soap_K/S16 percent and the color change before and after the color change is obvious.

The color comparison data for the specific examples and comparative examples are shown in table 1.

TABLE 1K/S values and color characterization values for dyed fabrics

Experimental results show that the method provided by the invention greatly improves the dyeing effect of the micromolecule natural dye on the fabric/fiber, and the K/S retention rate N is maintained after the dyeing soap washing_K/SHigher and more stable color and luster obtained by dyeing. In the comparative example, the small-molecule natural dye was directly dyed (without any other auxiliary agent), and the K/S retention rate N was maintained after the dyeing soap washing_K/SThe color is low, the color is almost faded after dyeing and soaping, and the color is unstable; when the coupling agent is adopted as the auxiliary agent for dyeing in the comparative example, the coupling agent is hydrolyzed violently in water to form a membranous color block which is adsorbed on the surface of the fabric, so that the dyeing is uneven, color spots are formed, and the dyeing is not suitable for dyeing application; comparative example K/S Retention ratio N after washing of dyeing soap when dyeing was carried out using chitosan as an auxiliary agent_K/SLower, the color changes. The novel dyeing-color fixing method of the micromolecule natural dye provided by the invention has good dyeing effect on fabrics and good application prospect.

Claims (11)

1. The novel dyeing-color fixing method of the micromolecule natural dye is characterized by comprising the following steps: the water-soluble quantum dots are introduced into a dyeing bath of the micromolecular natural dye, and the dyeing process of the micromolecular natural dye is influenced by the water-soluble quantum dots.

2. The novel dyeing-fixing method of natural small-molecule dyes according to claim 1, characterized in that it is: the water-soluble quantum dots and the micromolecular natural dye are treated and dyed in the same bath, or the water-soluble quantum dots are firstly adopted to treat the fabric/fiber and then dyed with the micromolecular natural dye, or the water-soluble quantum dots are adopted to treat the dyed fabric/fiber after the micromolecular natural dye dyes the fabric/fiber.

3. The novel dyeing-fixing method of natural small-molecule dyes according to claim 2, characterized in that it is specifically as follows:

① the one-bath method comprises adding water-soluble quantum dot solution into micromolecular natural dye solution, mixing to obtain dye solution, dyeing fabric/fiber, wherein the dyeing formula is that the bath ratio is 1: 10-50, the dyeing temperature is 40-80 ℃, the dyeing time is 5-60 min, soaping, washing, and drying to obtain a dyeing sample;

or ②, a pretreatment method comprises the steps of firstly treating the fabric/fiber with a water-soluble quantum dot solution, and then dyeing with a small molecular natural dye, wherein the pretreatment formula comprises the steps of bath ratio of 1: 10-50, treatment temperature of 20-30 ℃, treatment time of 1-5 min, wringing, the dyeing formula comprises the steps of bath ratio of 1: 10-50, dyeing temperature of 40-80 ℃, dyeing time of 5-60 min, soaping, washing with water, and drying to obtain a dyeing sample;

or ③ post-treatment method, which comprises the steps of dyeing with micromolecule natural dye, treating the dyed fabric/fiber with water-soluble quantum dot solution, wringing out the fabric/fiber with the dyeing formula of bath ratio of 1: 10-50, dyeing temperature of 40-80 ℃, dyeing time of 5-60 min, and post-treatment formula of bath ratio of 1: 10-50, treatment temperature of 20-30 ℃, treatment time of 1-5 min, soaping, washing with water, and drying to obtain a dyed sample.

4. The novel dye-fixing method of natural small molecule dyes according to claim 1, characterized in that the water-soluble quantum dots are less than 10nm in size.

5. The novel dyeing-fixing method of small-molecule natural dyes according to claim 1, characterized in that the water-soluble quantum dots are water-soluble carbon quantum dots or water-soluble silicon-carbon quantum dots.

6. The novel dyeing-fixing method of the small-molecule natural dye according to claim 5, wherein the preparation method of the carbon quantum dots comprises the steps of mixing sodium citrate or sodium ascorbate with an alkaline agent, reacting at 150-200 ℃ for 1-5 hours, cooling to room temperature, purifying, performing ultrafiltration, adding deionized water to dilute by 0-50 times according to volume, wherein the alkaline agent is of sodium hydroxide, ammonium bicarbonate and urea, and the molar ratio of the alkaline agent to the sodium citrate or sodium ascorbate is 1: 20-30.

7. The novel dyeing-fixing method of the small-molecule natural dye according to claim 5, characterized in that the preparation method of the silicon-carbon quantum dots comprises the following steps: hydrolyzing the silane coupling agent in water at 50-60 ℃ for 20-50 min, then adding a reducing agent, stirring for 30-50 min, and adding deionized water to dilute by 0-50 times according to volume.

8. The novel dyeing-color fixing method of the small-molecule natural dye according to claim 7, characterized in that the molar ratio of the silane coupling agent to the reducing agent is 50-20: 1, the silane coupling agent is or a mixture of more than two of gamma-aminopropyltriethoxysilane (KH550), gamma-glycidoxypropyltrimethoxysilane (KH560) or gamma-methacryloxypropyltrimethoxysilane (KH570), and the reducing agent is of ascorbic acid, sodium ascorbate, citric acid and sodium citrate.

9. The novel dyeing-fixing method of small-molecule natural dye according to claim 1, characterized in that the small-molecule natural dye has molecular weight less than 500 and lacks a group for direct dyeing with fabric/fiber in structure.

10. The novel dyeing-fixing method of small-molecule natural dyes according to claim 1, characterized in that the small-molecule natural dyes are derived from natural plant extracts, in particular kinds of sappan wood extract, madder extract, honeysuckle extract or tea extract.

11. The novel dyeing-fixing method of natural small-molecule dyes according to claim 2, characterized in that the fabrics/fibers are of real silk, wool, mixed silk-wool blend and mixed silk-wool.