CN111877009A

CN111877009A - Super-hydrophobic fiber with high air permeability

Info

Publication number: CN111877009A
Application number: CN202010637703.0A
Authority: CN
Inventors: 管伟
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-03-02
Filing date: 2019-03-02
Publication date: 2020-11-03
Also published as: CN109930384A; CN109930384B; CN111877008A

Abstract

The invention discloses a super-hydrophobic fiber with high air permeability, and belongs to the technical field of textiles. The method comprises the steps of firstly modifying cotton fibers by using a cationic modifier so that the surfaces of the cotton fibers have ammonium positive charges, secondly preparing a pretreated hollow microcapsule by using cholesterol modified glucan and polylactic acid, and depositing nano silicon dioxide in the pretreated hollow microcapsule in subsequent treatment so as to prepare a microcapsule, preparing the microcapsule and modified sodium lignosulfonate into a treating agent, and finally forming a super-hydrophobic protective layer on the cotton fibers in an ethanol solution with the volume fraction of 90%. The super-hydrophobic fiber prepared by the technical scheme of the invention has excellent super-hydrophobic performance while keeping good air permeability.

Description

Super-hydrophobic fiber with high air permeability

Technical Field

The invention discloses a super-hydrophobic fiber with high air permeability, and belongs to the technical field of textiles.

Background

By superhydrophobic material is meant a material having a contact angle with water of greater than 150 °. The super-hydrophobic material has hydrophobic property and self-cleaning capability of preventing fouling, water and dust, and has very wide application prospect in daily life and industrial and agricultural production, so the development of the preparation method of the super-hydrophobic material and the research of related properties become the focus of people's attention in recent years. Because the wettability of the solid material is mainly determined by the chemical composition and the surface micro-geometric structure, the preparation method of the super-hydrophobic material is mainly divided into two types, one is to modify low-surface-energy substances on the surface of a rough solid, such as materials containing fluorine and silicon elements; another type is the use of hydrophobic materials to build rough structures. Research has shown that even a smooth solid surface with the lowest surface free energy (6.7N/m) has a contact angle with water of only 119 degrees, so that the construction of a proper surface micro-geometry is the key for preparing the super-hydrophobic material. At present, the method for preparing a super-hydrophobic material with a micro-nano hierarchical structure mainly comprises the following steps: sol-gel method, template method, phase separation method, electrostatic spinning method, etching method, stretching method, etching method, self-assembly method, and the like.

Cellulose is a natural polymer with the most abundant natural reserves, can be quickly regenerated, and the annual regeneration quantity exceeds 1.0 multiplied by 10¹⁰And the cellulose also has the advantages of easy degradation, no pollution, easy modification and the like. Nowadays, cellulose and its derivatives have been widely used in the fields of plastics, textiles, paper, food, daily chemicals, medicine, construction and biology, etc., and may become the main raw materials of future world chemistry and chemical industry. The development of cellulose materials has important significance for improving ecological environment, changing human dietary structure, increasing energy, developing novel materials and the like.

At present, due to the work requirement of special industries, clothes with good waterproof and breathable performances are favored by people. The commonly used waterproof clothes are made of composite materials containing plastic or rubber components, and the air permeability is obviously reduced while the waterproof performance is ensured; however, the air permeability of the clothes made of organic synthetic polymer materials such as nylon is not good as that of the clothes made of pure cellulose fabrics. Therefore, a hydrophobic cellulose-based material is one of the most desirable materials, while ensuring breathability and water resistance.

However, most of the existing methods of superhydrophobic treatment are only applied to the surface of inorganic materials, the application amount on the surface of fibers is small, and when the method is applied to the surface of cotton fibers, the bonding force between a superhydrophobic interface layer and the cotton fibers is weak, so that the method cannot have long-term hydrophobic and breathable effects, and meanwhile, the degradation and regeneration performance of the cotton fibers subjected to superhydrophobic treatment are reduced, so that the designed and developed fibers with superhydrophobic surfaces and good breathability have wide market prospects.

Disclosure of Invention

Aiming at the problems that the traditional knitted fiber is not durable enough in hydrophobic property, not high in air permeability and not good in super-hydrophobic property after super-hydrophobic treatment, the super-hydrophobic fiber with high air permeability and the processing method thereof are provided.

In order to achieve the purpose, the invention provides the following technical scheme:

the super-hydrophobic fiber with high air permeability is characterized by mainly comprising the following raw material components in parts by weight: 60-70 parts of cotton fibers, 15-30 parts of cationization reagent and 5-12 parts of initiator, wherein after the cotton fibers are subjected to cationic modification, the surface activity of the cotton fibers is higher, the reaction activity is enhanced, but the hydrophobic property of the modified cotton fibers is obviously reduced.

The super-hydrophobic fiber with high air permeability is characterized by further comprising the following components in parts by weight: 20-28 parts of treating agent, wherein a nano mastoid structure can be formed on the surface of the cationized cotton fiber by adding the treating agent, and a hydrophobic layer can be formed on the surface of the fiber by forming the nano mastoid structure, so that the contact angle between water and the cotton fiber is improved, the adhesive force of water molecules on the surface of the fiber is reduced, and the super-hydrophobic property of the cotton fiber is improved.

Preferably, the cationization reagent is any one of methacryloyloxyethyl trimethyl ammonium chloride or dimethyl diallyl ammonium chloride, and the initiator is prepared by mixing sodium bisulfate and potassium sulfite according to a mass ratio of 1: 1, the cationization reagent can enable the surface of the fiber to form positive charges, so that the combination of the cotton fiber and the treatment agent in the subsequent treatment is facilitated, and molecular chains can be formed on the surface of the fiber, so that the combination of the treatment agent is further facilitated.

As optimization, the treating agent contains microcapsules and modified sodium lignin sulfonate, the microcapsules are composed of cholesterol modified glucan, polylactic acid and silicon dioxide, the modified sodium lignin sulfonate is sodium lignin sulfonate modified by halogenated hydrocarbon, the microcapsules are of a hollow structure and can adsorb nano silicon dioxide formed by hydrolyzing tetraethoxysilane in the preparation process, so that when the treating agent is adsorbed on the surface of a fiber, finer nano particles can be adsorbed on the surface of the fiber, the super-hydrophobic performance of the product is further improved, and the microcapsules are fixed by a three-dimensional network of the modified sodium lignin sulfonate, so that the product has long-acting super-hydrophobic performance; after the sodium lignosulfonate is modified, a hydrophobic molecular chain is grafted at the molecular chain end of the sodium lignosulfonate, and after the sodium lignosulfonate is combined with the pre-modified cotton fiber, the hydrophobic molecular chain can be spread on the surface of the fiber, so that the super-hydrophobic property of the product is further improved.

Preferably, the super-hydrophobic fiber comprises the following components in parts by weight: 65 parts of cotton fiber, 15 parts of cationization reagent, 5 parts of initiator and 28 parts of treating agent, under the condition, the utilization rate of the treating agent can be maximized, and the waste is reduced.

As an optimization, the processing method of the super-hydrophobic fiber specifically comprises the following steps:

(1) mixing cotton fibers with an initiator, adding water and a cationization reagent, stirring and reacting under the nitrogen atmosphere, filtering and drying;

(2) mixing cholesterol modified glucan and polylactic acid, adding dimethyl sulfoxide, stirring for reaction, dialyzing, and freeze-drying;

(3) mixing the substance obtained in the step (2) with ethyl orthosilicate, adding water, ethanol and ammonia water, stirring for reaction, filtering and drying;

(4) mixing sodium lignosulfonate with water, adjusting the pH value, adding potassium iodide, a halogenated hydrocarbon solution and the substance obtained in the step (3), stirring for reaction, extracting, filtering, and performing rotary evaporation and concentration;

(5) mixing the fiber obtained in the step (1) with a coagulating bath, adding the concentrate obtained in the step (4), and stirring for reaction;

(6) filtering and drying the substance obtained in the step (5);

(7) and (4) performing index analysis on the product obtained in the step (6).

As optimization, the processing method of the super-hydrophobic fiber mainly comprises the following steps:

(1) mixing 60-70 parts of cotton fibers and 6-12 parts of an initiator in a reaction kettle, adding 15-30 parts of a cationization reagent into the reaction kettle, stirring and reacting for 3-6 hours under the conditions of a nitrogen atmosphere, a temperature of 50-80 ℃ and a rotating speed of 300-320 r/min, filtering and drying;

(2) mixing the cholesterol modified glucan and the polylactic acid according to a mass ratio of 1.0: 1.0-1.0: 1.2, adding dimethyl sulfoxide 200-300 times of the weight of the cholesterol modified glucan into the mixture of the cholesterol modified glucan and the polylactic acid, stirring and dissolving, dialyzing for 30-60 hours by using a dialysis bag with the molecular weight of 1400, and freeze-drying;

(3) mixing the substance obtained in the step (2) and tetraethoxysilane according to the mass ratio of 1: 3-1: 4, mixing, adding absolute ethyl alcohol with the mass being 4-5 times that of the substance obtained in the step (2) into a mixture of the substance obtained in the step (2) and ethyl orthosilicate, adding water with the mass being 1-2 times that of the substance obtained in the step (2) and ammonia water with the mass being 2-6 times that of the substance obtained in the step (2), stirring and reacting for 10-12 hours at the temperature of 30-40 ℃ and the rotating speed of 300-320 r/min, filtering and drying;

(4) mixing sodium lignosulfonate and water according to a mass ratio of 1: 5-1: 10, mixing, and adjusting the pH value of the mixture of sodium lignosulfonate and water to 11-12 to obtain a sodium lignosulfonate solution; mixing sodium lignosulfonate solution and potassium iodide according to a mass ratio of 100: 1-180: 1, adding a halogenated hydrocarbon solution which is 0.2-0.3 time of the mass of the sodium lignosulfonate solution and a substance which is 0.1-0.2 time of the mass of the sodium lignosulfonate solution and is obtained in the step (3) into a mixture of the sodium lignosulfonate solution and potassium iodide, stirring and reacting for 5-6 hours under the conditions that the pH is 10-11, the temperature is 50-80 ℃, and the rotating speed is 300-350 r/min, extracting with petroleum ether, filtering, removing an organic phase to obtain an aqueous phase mixture, and carrying out rotary evaporation and concentration on the aqueous phase mixture under the conditions that the temperature is 60-80 ℃, the rotating speed is 120-150 r/min, and the pressure is 500-600 kPa until the water content is 0.1-0.2%;

(5) mixing the fiber obtained in the step (1) with 20-28 parts of the substance obtained in the step (4), adding the mixture into a coagulating bath with the mass being 20-30 times that of the fiber obtained in the step (1), and stirring and reacting at the temperature of 30-50 ℃ and the rotating speed of 150-200 r/min for 8-10 h;

(6) filtering the substance obtained in the step (5), drying for 1-2 hours at the temperature of 60-80 ℃, and removing the redundant coagulating bath;

(7) and (4) performing index analysis on the product obtained in the step (6), namely testing the contact angle of the super-hydrophobic fiber, the contact angle after friction and air permeability.

Preferably, the cholesterol modified glucan obtained in the step (2) is prepared by mixing cholesterol and pyridine according to a mass ratio of 1: 32, adding succinic anhydride with the mass being 1 time of that of the cholesterol, stirring for reaction, then carrying out reduced pressure distillation to obtain a pretreated cholesterol mixture, and mixing the pretreated cholesterol mixture with an ethanol solution with the mass fraction of 90% according to the mass ratio of 1: 10 mixing, filtering to obtain filtrate, recrystallizing the filtrate in ice water, and filtering to obtain cholesterol-succinate; mixing cholesterol-succinate and thionyl chloride according to a molar ratio of 1: 10, adding trichloromethane with the mole number of 20-40 times that of the cholesterol-succinate, stirring for reaction, performing rotary evaporation and concentration to obtain cholesterol-succinate acyl chloride, and mixing the cholesterol-succinate acyl chloride and the trichloromethane according to the mass ratio of 1: 8, mixing to obtain a cholesterol-succinate acyl chloride solution, and mixing dextran and dimethyl sulfoxide according to a mass ratio of 1: 30, adding triethylamine with the mass of 0.1 time of that of the glucan, stirring and mixing to obtain a glucan solution, mixing the glucan solution with the cholesterol-succinate acyl chloride solution according to the volume ratio of 15: 1, stirring for reaction, and freeze-drying to obtain the cholesterol modified glucan, wherein the cholesterol modified glucan is used as a forming material of the microcapsule, so that the forming of the microcapsule is facilitated, and the used material is degradable, so that the recycling and utilization of the super-hydrophobic fiber are not influenced.

Preferably, the halogenated hydrocarbon solution in the step (4) is prepared by mixing 1, 6-dibromohexane and absolute ethyl alcohol in a mass ratio of 3: 1, mixing to obtain a halogenated hydrocarbon solution.

As an optimization, the coagulating bath in the step (5) is prepared by mixing ethanol and water in a volume ratio of 9: 1, mixing to obtain the coagulating bath.

Compared with the prior art, the invention has the beneficial effects that: (1) the invention adds the microcapsule when preparing the super-hydrophobic fiber, firstly, the microcapsule has a nano structure, can be embedded in a three-dimensional network structure of the modified sodium lignosulfonate in the preparation process of the treating agent, and is adsorbed on the surface of the cotton fiber together with the treating agent, and a nano mastoid structure is formed on the surface of the cotton fiber, so that the surface of the fiber has excellent super-hydrophobic performance, secondly, the microcapsule is a hollow structure, and can adsorb nano silicon dioxide formed by hydrolyzing tetraethoxysilane in the preparation process, so that when the treating agent is adsorbed on the surface of the fiber, finer nano particles can be adsorbed on the surface of the fiber, so that the super-hydrophobic performance of the product is further improved, and the microcapsule is fixed by the three-dimensional network of the modified sodium lignosulfonate, so that the product has long-acting super-hydrophobic performance; moreover, alkali treatment is needed in the preparation process of the treating agent, so that part of silicon dioxide in the microcapsule can be etched, and a porous structure is formed in the microcapsule, so that the air permeability of the product is improved;

(2) according to the invention, when the super-hydrophobic fiber is prepared, the cotton fiber is pre-modified and then treated by the treating agent, on one hand, after the pre-modification treatment is carried out on the cotton fiber, the surface of the cotton fiber is provided with positive charges, so that after the cotton fiber is mixed with the treating agent, ammonium radicals on the surface of the cotton fiber can react with a sulfonate on the surface of modified sodium lignosulfonate in the treating agent, so that firm combination is formed, and further the product has long-acting super-hydrophobic performance, and on the other hand, after the sodium lignosulfonate in the treating agent is modified, a hydrophobic molecular chain is grafted at the end of a sodium lignosulfonate molecular chain, and after the sodium lignosulfonate is combined with the pre-modified cotton fiber, the hydrophobic molecular chain can be spread on the surface of the fiber, so that the.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

To illustrate the method of the present invention more clearly, the following examples are given, and the test methods for each index of the superhydrophobic fiber produced in the following examples are as follows:

hydrophobicity: the contact angles of the super-hydrophobic fiber obtained in each example and the comparative example product are measured respectively;

long-lasting property: after the super-hydrophobic fiber obtained in each example and a comparative product are respectively rubbed by a YG502 type fuzzing and pilling tester for 800 revolutions, the contact angle is measured;

air permeability: the superhydrophobic fibers from each example and the comparative product were tested according to GB/T5453.

Example 1:

a super-hydrophobic fiber with high air permeability mainly comprises the following components in parts by weight: 65 parts of cotton fiber, 15 parts of methacryloyloxyethyl trimethyl ammonium chloride, 5 parts of initiator and 28 parts of treating agent.

A processing method of super-hydrophobic fiber with high air permeability mainly comprises the following steps:

(1) mixing 65 parts of cotton fibers and 5 parts of an initiator in a reaction kettle, adding 15 parts of a cationization reagent into the reaction kettle, stirring and reacting at the temperature of 60 ℃ and the rotating speed of 320r/min in a nitrogen atmosphere for 6 hours, filtering and drying;

(2) mixing the cholesterol modified glucan and the polylactic acid according to a mass ratio of 1.0: 1.2, adding dimethyl sulfoxide with the mass of 250 times of that of the cholesterol modified glucan into the mixture of the cholesterol modified glucan and the polylactic acid, stirring and dissolving, dialyzing for 50 hours by using a dialysis bag with the molecular weight of 1400, and freeze-drying;

(3) mixing the substance obtained in the step (2) and tetraethoxysilane according to the mass ratio of 1: 4, mixing, adding absolute ethyl alcohol of which the mass is 5 times that of the substance obtained in the step (2) into a mixture of the substance obtained in the step (2) and ethyl orthosilicate, adding water of which the mass is 2 times that of the substance obtained in the step (2) and ammonia water of which the mass is 4 times that of the substance obtained in the step (2), stirring and reacting for 10 hours at the temperature of 35 ℃ and the rotating speed of 300r/min, filtering and drying;

(4) mixing sodium lignosulfonate and water according to a mass ratio of 1: 8, mixing, and adjusting the pH value of the mixture of the sodium lignosulfonate and the water to 11 to obtain a sodium lignosulfonate solution; mixing sodium lignosulfonate solution and potassium iodide according to a mass ratio of 150: 1, adding a halogenated hydrocarbon solution with the mass of 0.2 time of that of the sodium lignosulfonate solution and a substance obtained in the step (3) with the mass of 0.2 time of that of the sodium lignosulfonate solution into a mixture of the sodium lignosulfonate solution and potassium iodide, stirring and reacting for 6 hours under the conditions of pH 11, temperature of 60 ℃ and rotation speed of 320r/min, extracting with petroleum ether, filtering, removing an organic phase, and performing rotary evaporation and concentration under the conditions of temperature of 70 ℃, rotation speed of 150r/min and pressure of 600kPa until the water content is 0.2%;

(5) mixing the fiber obtained in the step (1) with 28 parts of the substance obtained in the step (4), adding the mixture into a coagulating bath with the mass 30 times that of the fiber obtained in the step (1), and stirring and reacting at the temperature of 40 ℃ and the rotating speed of 180r/min for 9 hours;

(6) filtering the substance obtained in the step (5), drying for 2h at the temperature of 80 ℃, and removing the redundant coagulating bath;

(7) and (4) performing index analysis on the product obtained in the step (6).

Preferably, the cholesterol modified glucan obtained in the step (2) is prepared by mixing cholesterol and pyridine according to a mass ratio of 1: 32, adding succinic anhydride with the mass being 1 time of that of the cholesterol, stirring for reaction, then carrying out reduced pressure distillation to obtain a pretreated cholesterol mixture, and mixing the pretreated cholesterol mixture with an ethanol solution with the mass fraction of 90% according to the mass ratio of 1: 10 mixing, filtering to obtain filtrate, recrystallizing the filtrate in ice water, and filtering to obtain cholesterol-succinate; mixing cholesterol-succinate and thionyl chloride according to a molar ratio of 1: 10, adding trichloromethane with the mole number 30 times that of the cholesterol-succinate, stirring for reaction, performing rotary evaporation and concentration to obtain cholesterol-succinate acyl chloride, and mixing the cholesterol-succinate acyl chloride and the trichloromethane according to the mass ratio of 1: 8, mixing to obtain a cholesterol-succinate acyl chloride solution, and mixing dextran and dimethyl sulfoxide according to a mass ratio of 1: 30, adding triethylamine with the mass of 0.1 time of that of the glucan, stirring and mixing to obtain a glucan solution, mixing the glucan solution with the cholesterol-succinate acyl chloride solution according to the volume ratio of 15: 1, stirring, reacting, and freeze-drying to obtain the cholesterol modified glucan.

Example 2:

a super-hydrophobic fiber with high air permeability mainly comprises the following components in parts by weight: 65 parts of cotton fiber, 15 parts of dimethyl diallyl ammonium chloride, 5 parts of initiator and 28 parts of treating agent.

(1) mixing 65 parts of cotton fibers and 5 parts of initiator in a reaction kettle, adding 15 parts of dimethyl diallyl ammonium chloride into the reaction kettle, stirring and reacting at the temperature of 60 ℃ and the rotating speed of 320r/min in a nitrogen atmosphere for 6 hours, filtering and drying;

(7) and (4) performing index analysis on the product obtained in the step (6).

Example 3:

(3) mixing sodium lignosulfonate and water according to a mass ratio of 1: 8, mixing, and adjusting the pH value of the mixture of the sodium lignosulfonate and the water to 11 to obtain a sodium lignosulfonate solution; mixing sodium lignosulfonate solution and potassium iodide according to a mass ratio of 150: 1, adding a halogenated hydrocarbon solution with the mass of 0.2 time of that of the sodium lignosulfonate solution and a substance obtained in the step (2) with the mass of 0.2 time of that of the sodium lignosulfonate solution into a mixture of the sodium lignosulfonate solution and potassium iodide, stirring and reacting for 6 hours under the conditions of pH 11, temperature of 60 ℃ and rotation speed of 320r/min, extracting with petroleum ether, filtering, removing an organic phase, and performing rotary evaporation and concentration under the conditions of temperature of 70 ℃, rotation speed of 150r/min and pressure of 600kPa until the water content is 0.2%;

(4) mixing the fiber obtained in the step (1) with 28 parts of the substance obtained in the step (3), adding the mixture into a coagulating bath with the mass 30 times that of the fiber obtained in the step (1), and stirring and reacting at the temperature of 40 ℃ and the rotating speed of 180r/min for 9 hours;

(5) filtering the substance obtained in the step (4), drying for 2h at the temperature of 80 ℃, and removing the redundant coagulating bath;

(6) and (4) performing index analysis on the product obtained in the step (6).

Preferably, the halogenated hydrocarbon solution in the step (3) is prepared by mixing 1, 6-dibromohexane and absolute ethyl alcohol in a mass ratio of 3: 1, mixing to obtain a halogenated hydrocarbon solution.

As an optimization, the coagulating bath in the step (4) is prepared by mixing ethanol and water in a volume ratio of 9: 1, mixing to obtain the coagulating bath.

Example 4:

(1) mixing 65 parts of cotton fibers and 5 parts of an initiator in a reaction kettle, adding 15 parts of a cationization reagent into the reaction kettle, stirring and reacting for 6 hours in a nitrogen atmosphere at the temperature of 60 ℃ and the rotating speed of 320r/min, filtering and drying;

(2) mixing sodium lignosulfonate and water according to a mass ratio of 1: 8, mixing, and adjusting the pH value of the mixture of the sodium lignosulfonate and the water to 11 to obtain a sodium lignosulfonate solution; mixing sodium lignosulfonate solution and potassium iodide according to a mass ratio of 150: 1, adding a halogenated hydrocarbon solution with the mass of 0.2 time that of the sodium lignosulfonate solution into a mixture of the sodium lignosulfonate solution and potassium iodide, stirring and reacting for 6 hours at the temperature of 60 ℃ and the rotating speed of 320r/min, extracting with petroleum ether, filtering, removing an organic phase, and performing rotary evaporation and concentration at the temperature of 70 ℃, the rotating speed of 150r/min and the pressure of 600kPa until the water content is 0.2%;

(3) mixing the fiber obtained in the step (1) with 28 parts of the substance obtained in the step (2), adding the mixture into a coagulating bath with the mass 30 times that of the fiber obtained in the step (1), and stirring and reacting at the temperature of 40 ℃ and the rotating speed of 180r/min for 9 hours;

(4) filtering the substance obtained in the step (3), drying for 2h at the temperature of 80 ℃, and removing the redundant coagulating bath;

(5) and (4) performing index analysis on the product obtained in the step (4).

Preferably, the halogenated hydrocarbon solution in the step (2) is prepared by mixing 1, 6-dibromohexane and absolute ethyl alcohol in a mass ratio of 3: 1, mixing to obtain a halogenated hydrocarbon solution.

Preferably, the coagulating bath in the step (3) is prepared by mixing ethanol and water in a volume ratio of 9: 1, mixing to obtain the coagulating bath.

Comparative example 1:

a super-hydrophobic fiber with high air permeability mainly comprises the following components in parts by weight: 65 parts of cotton fiber, 15 parts of methacryloyloxyethyl trimethyl ammonium chloride and 5 parts of initiator.

(2) and (3) performing index analysis on the product obtained in the step (1).

Effect example 1:

table 1 below gives index analysis results of the superhydrophobic fiber processing methods using examples 1-4 of the present invention and comparative example 1.

TABLE 1

As can be seen from table 1: compared with a comparative example, the product prepared by the invention has excellent super-hydrophobic performance, and still has good air permeability after being treated, and the product obtained by comparing example 4 with the comparative example can find that the surface cationized cotton fiber has better hydrophobicity without reaching the super-hydrophobic performance by adding the halohydrocarbon modified sodium lignosulfonate; comparing example 4 with example 3, the added halohydrocarbon modified sodium lignosulfonate and silica-free microcapsule can form a better hydrophobic layer on the surface of cationized cotton fiber, so that the hydrophobic property of the fiber is closer to the super-hydrophobic grade, comparing example 3 with example 2, the treated fiber can show super-hydrophobic property when fine nano-silica is added into the microcapsule, and comparing the contact angle with the contact angle data after 800 times of friction in table 1, the treated fiber has better service performance, even after multiple times of friction, the product still has super-hydrophobic property, which shows that the bonding force between the super-hydrophobic layer and the fiber is better after the super-hydrophobic treatment of the fiber, comparing example 1 with example 2, different cationization agents are added to treat the cotton fiber, the contact angle of the cotton fiber after the super-hydrophobic treatment is not greatly influenced.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein, and any reference thereto is therefore intended to be embraced therein.

Claims

1. A super-hydrophobic fiber with high air permeability is characterized in that: the adhesive mainly comprises the following components in parts by weight: 65 parts of cotton fiber, 15 parts of methacryloyloxyethyl trimethyl ammonium chloride, 5 parts of initiator and 28 parts of treating agent;

the processing method of the super-hydrophobic fiber with high air permeability comprises the following steps:

(7) performing index analysis on the product obtained in the step (6);

the cholesterol modified glucan obtained in the step (2) is prepared by mixing cholesterol and pyridine according to a mass ratio of 1: 32, adding succinic anhydride with the mass being 1 time of that of the cholesterol, stirring for reaction, then carrying out reduced pressure distillation to obtain a pretreated cholesterol mixture, and mixing the pretreated cholesterol mixture with an ethanol solution with the mass fraction of 90% according to the mass ratio of 1: 10 mixing, filtering to obtain filtrate, recrystallizing the filtrate in ice water, and filtering to obtain cholesterol-succinate; mixing cholesterol-succinate and thionyl chloride according to a molar ratio of 1: 10, adding trichloromethane with the mole number 30 times that of the cholesterol-succinate, stirring for reaction, performing rotary evaporation and concentration to obtain cholesterol-succinate acyl chloride, and mixing the cholesterol-succinate acyl chloride and the trichloromethane according to the mass ratio of 1: 8, mixing to obtain a cholesterol-succinate acyl chloride solution, and mixing dextran and dimethyl sulfoxide according to a mass ratio of 1: 30, adding triethylamine with the mass of 0.1 time of that of the glucan, stirring and mixing to obtain a glucan solution, mixing the glucan solution with the cholesterol-succinate acyl chloride solution according to the volume ratio of 15: 1, mixing, stirring for reaction, and freeze-drying to obtain cholesterol modified glucan;

the halogenated hydrocarbon solution in the step (4) is prepared by mixing 1, 6-dibromohexane and absolute ethyl alcohol according to a mass ratio of 3: 1, mixing to obtain a halogenated hydrocarbon solution;

and (5) the coagulating bath is prepared by mixing ethanol and water according to the volume ratio of 9: 1, mixing to obtain the coagulating bath.