CN111938214A - Volcanic rock spontaneous heating socks and production process thereof - Google Patents

Abstract

The invention discloses a volcanic spontaneous heating sock which comprises the following components in percentage by weight: 2-4% of an antibacterial finishing agent, 4-8% of a discoloration-preventing auxiliary agent, 2-8% of a perfume auxiliary agent, 3-9% of a damp-clearing itching-relieving auxiliary agent, 9-13% of volcanic rock particles, 20-30% of wood pulp, 6-8% of polyvinyl alcohol fibers, 7-9% of polyvinyl chloride fibers, 6-10% of high-elasticity recovery elastic glue, 10-20% of elastic composite fibers, 10-14% of spandex fibers, 12-16% of polyester fibers, 9-15% of kapok fibers, 11-15% of cotton fibers, 9-11% of wheat straw fibers, 8-10% of castor fibers and 6-12% of antistatic polyester fibers. The invention has the technical effects of self-heating, dampness eliminating, itch eliminating, deodorizing and fragrance dispersing, and better mechanical performance.

Description

Volcanic rock spontaneous heating socks and production process thereof

Technical Field

The invention relates to the technical field of sock formulas and processes, in particular to a volcanic rock spontaneous heating sock and a production process thereof.

Background

The dress is a general term for the articles for decorating human body. Including apparel, shoes, hats, socks, gloves, scarves, ties, bags, umbrellas, hair accessories, and the like. Ancient people are used for covering up the shy, people have continuously improved knowledge of new things, and the materials and the styles of the clothes are various. Along with the improvement of living standard of people, the requirement on the comfort level of clothes is higher and higher, socks are socks, the length is 5 centimeters to the ankle longest, when the socks are worn, the socks cover the whole ankle, and most of the socks are made of cotton or nylon. Reducing foot and shoe friction; keep the feet warm; absorb the foot sweat. Socks are worn when wearing shoes that wrap the ankle of the entire leg, such as athletic shoes, boots, and leather shoes. The conventional socks have single functional effect, are easy to wear out due to friction with shoes, do not have the effect of self-heating in winter, and do not have the effects of dispelling dampness, relieving itching and deodorizing and dispersing fragrance, and the comfort level of the conventional socks also meets the required requirement.

Disclosure of Invention

The invention aims to provide volcanic self-heating socks and a production process thereof, and aims to solve the problems in the background art.

In order to realize the purpose, the invention provides the following technical scheme: the volcanic self-heating sock comprises the following components in percentage by weight: 2-4% of an antibacterial finishing agent, 4-8% of a discoloration-preventing auxiliary agent, 2-8% of a perfume auxiliary agent, 3-9% of a damp-clearing itching-relieving auxiliary agent, 9-13% of volcanic rock particles, 20-30% of wood pulp, 6-8% of polyvinyl alcohol fibers, 7-9% of polyvinyl chloride fibers, 6-10% of high-elasticity recovery elastic glue, 10-20% of elastic composite fibers, 10-14% of spandex fibers, 12-16% of polyester fibers, 9-15% of kapok fibers, 11-15% of cotton fibers, 9-11% of wheat straw fibers, 8-10% of castor fibers and 6-12% of antistatic polyester fibers.

Preferably, the antibacterial finishing agent comprises 15% of organic metal compound, 5% of liquorice, 3% of mint and 77% of water.

Preferably, the anti-decoloration auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, AES mate thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, cation agglomerate and water.

Preferably, the perfume auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

Preferably, the damp-clearing itch-relieving auxiliary agents comprise 40 g of dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

Preferably, the elastic gel with high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a coloring agent, a catalyst and a thickening agent.

Preferably, the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting manner.

Preferably, the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to ensure that the main chain of the bamboo pulp fiber is mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

A volcanic rock spontaneous heating socks specifically comprises the following steps:

the method comprises the following steps: crushing volcanic rock particles by using a crusher, crushing the volcanic rock particles into powder, adding the powder into a thermocouple reaction kettle, continuously adding wood pulp, keeping the temperature at 30-50 ℃, and continuously stirring for 1-2 hours;

step two: respectively adding the antibacterial finishing agent, the anti-fading auxiliary agent, the perfume auxiliary agent and the dampness and itch removing auxiliary agent into the thermocouple reaction kettle in the step one, and continuously stirring to prepare mixed slurry;

step three: cutting the antistatic polyester fiber, the elastic composite fiber, the spandex fiber and the polyester fiber into short fibers, uniformly mixing, carrying out coarse carding and fine carding by a carding machine, and then carrying out drawing frame and fine winding to obtain a chemical fiber filament yarn A;

step four: cutting kapok fiber, cotton fiber, wheat straw fiber and castor fiber into short fibers, uniformly mixing, carrying out coarse carding and fine carding by a carding machine, and then carrying out drawing frame and fine complexing to obtain chemical fiber filaments B;

step five: placing the chemical fiber filament A prepared in the third step and the chemical fiber filament B prepared in the third step into the thermocouple reaction kettle in the first step at the same time, adding high-elasticity recovery degree elastic glue, continuously stirring for 1-2 hours, keeping the temperature at 20-30 ℃, taking out the chemical fiber filament A and the chemical fiber filament B, and drying the chemical fiber filament A and the chemical fiber filament B;

step six: twisting the chemical fiber filament B prepared in the fifth step outside the chemical fiber filament A into a coating yarn of the chemical fiber filament A by taking the chemical fiber filament A prepared in the fifth step as a core filament to prepare a composite yarn, and finally weaving the composite yarn into a sock by warp and weft;

step seven: adding into dye solution, rotating at room temperature for 15min, heating to 62 deg.C at a heating rate of 1.1 deg.C/min, maintaining for 10min, heating to 98 deg.C at a heating rate of 0.9 deg.C/min, maintaining for 30min, cooling to 52 deg.C at a cooling rate of 2.5 deg.C/min, draining, washing, fixing at 65 deg.C for 10min, washing, adding softening agent, treating at 40 deg.C for 30min, with the concentration of softening agent being 1.35%;

step eight: and (3) dehydrating the dyed socks, then shaping and preserving heat for 30s by using the sock connecting sleeve plate under the pressure of 0.1Mpa and the temperature of 100 ℃.

Preferably, the thermocouple reaction kettle is a thermocouple reaction kettle provided with a stirrer, a distillation column connected with a water-cooled condenser, a nitrogen inlet and a temperature regulator.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the volcanic self-heating socks and the production process thereof, volcanic particles are crushed by a crusher to be crushed into powder, the powder is added into a thermocouple reaction kettle, wood pulp is continuously added, volcanic particles are adhered to a chemical fiber filament A and a chemical fiber filament B which are woven in a warp-weft mode, then the chemical fiber filament A is used as a core wire, the chemical fiber filament B is twisted outside the chemical fiber filament A to be coated yarns of the chemical fiber filament A, composite yarns are prepared, and finally the composite yarns are woven in the warp-weft mode to be woven into socks, so that the socks have the self-heating effect from outside to inside.

2. The volcanic self-heating socks and the production process thereof are characterized in that an antibacterial finishing agent, an anti-discoloration aid, a spice aid and a dampness and itch removing aid are respectively added into a thermocouple reaction kettle in the first step, mixed slurry is continuously prepared by stirring, antibacterial, discoloration preventing, spice and dampness and itch removing aids are adhered to a chemical fiber filament A and a chemical fiber filament B which are woven in a warp and weft mode, then the chemical fiber filament A is used as a core filament, the chemical fiber filament B is twisted outside the chemical fiber filament A into a coated yarn of the chemical fiber filament A to prepare a composite yarn, finally the composite yarn is woven in a warp and weft mode to form the socks, and the prepared socks have the effects of dampness and itch removing, deodorization and fragrance dispersing and the effect of difficult discoloration.

3. The volcanic self-heating socks and the production process thereof are characterized in that antistatic polyester fibers, elastic composite fibers, spandex fibers and polyester fibers are cut into short fibers, the short fibers are uniformly mixed, coarse carding and fine carding are carried out by a carding machine, and then chemical fiber filaments A are formed by drawing and fine winding; the method comprises the following steps of cutting kapok fiber, cotton fiber, wheat straw fiber and castor fiber into short fibers, uniformly mixing, carding in a carding machine to obtain coarse and fine carding, drawing and fine complexing to obtain chemical fiber filament A, twisting the chemical fiber filament B outside the chemical fiber filament A to obtain coated yarn of the chemical fiber filament A to obtain composite yarn, and finally weaving the composite yarn in a warp-weft manner to obtain the socks, wherein the elastic elasticity, hard object scratch resistance, water washing resistance, ageing resistance and wear resistance of the socks are improved.

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.

Example 1

The volcanic self-heating sock comprises the following components in percentage by weight: 2% of antibacterial finishing agent, 4% of anti-discoloration auxiliary agent, 2% of perfume auxiliary agent, 3% of damp-clearing and itch-relieving auxiliary agent, 9% of volcanic rock particles, 20% of wood pulp, 6% of polyvinyl alcohol fiber, 7% of polyvinyl chloride fiber, 6% of high-elasticity recovery degree elastic glue, 10% of elastic composite fiber, 10% of spandex fiber, 12% of polyester fiber, 9% of kapok fiber, 11% of cotton fiber, 9% of wheat straw fiber, 8% of castor fiber and 6% of anti-static polyester fiber.

In this embodiment, the antibacterial finishing agent includes 15% of organic metal compound, 5% of licorice, 3% of mint and 77% of water.

In this embodiment, the anti-decoloring auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, an AES partner thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, a cationic agglomerate, and water.

In the embodiment, the perfume auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

In the embodiment, the damp-clearing itch-relieving auxiliary agents comprise 40 g of dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

In this embodiment, the elastic gel with high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a colorant, a catalyst and a thickener.

In this embodiment, the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting manner.

In the embodiment, the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to enable the main chain of the bamboo pulp fiber to be mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

Example 2

The volcanic self-heating sock comprises the following components in percentage by weight: 4% of antibacterial finishing agent, 8% of anti-discoloration auxiliary agent, 8% of perfume auxiliary agent, 9% of damp-clearing and itch-relieving auxiliary agent, 13% of volcanic rock particles, 30% of wood pulp, 8% of polyvinyl alcohol fiber, 9% of polyvinyl chloride fiber, 10% of high-elasticity recovery degree elastic glue, 20% of elastic composite fiber, 14% of spandex fiber, 16% of polyester fiber, 15% of kapok fiber, 15% of cotton fiber, 11% of wheat straw fiber, 10% of castor fiber and 12% of anti-static polyester fiber.

In this embodiment, the antibacterial finishing agent includes 15% of organic metal compound, 5% of licorice, 3% of mint and 77% of water.

In this embodiment, the anti-decoloring auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, an AES partner thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, a cationic agglomerate, and water.

In the embodiment, the perfume auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

In the embodiment, the damp-clearing itch-relieving auxiliary agents comprise 40 g of dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

In this embodiment, the elastic gel with high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a colorant, a catalyst and a thickener.

In this embodiment, the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting manner.

In the embodiment, the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to enable the main chain of the bamboo pulp fiber to be mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

Example 3

The volcanic self-heating sock comprises the following components in percentage by weight: 3% of antibacterial finishing agent, 6% of anti-discoloration auxiliary agent, 5% of perfume auxiliary agent, 6% of damp-clearing and itch-relieving auxiliary agent, 11% of volcanic rock particles, 25% of wood pulp, 7% of polyvinyl alcohol fiber, 8% of polyvinyl chloride fiber, 8% of high-elasticity recovery degree elastic glue, 15% of elastic composite fiber, 12% of spandex fiber, 14% of polyester fiber, 12% of kapok fiber, 13% of cotton fiber, 10% of wheat straw fiber, 9% of castor fiber and 9% of anti-static polyester fiber.

In this embodiment, the antibacterial finishing agent includes 15% of organic metal compound, 5% of licorice, 3% of mint and 77% of water.

In this embodiment, the anti-decoloring auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, an AES partner thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, a cationic agglomerate, and water.

In the embodiment, the perfume auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

In the embodiment, the damp-clearing itch-relieving auxiliary agents comprise 40 g of dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

In this embodiment, the elastic gel with high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a colorant, a catalyst and a thickener.

In this embodiment, the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting manner.

In the embodiment, the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to enable the main chain of the bamboo pulp fiber to be mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

Example 4

The volcanic self-heating sock comprises the following components in percentage by weight: 3% of antibacterial finishing agent, 6% of anti-discoloration auxiliary agent, 5% of perfume auxiliary agent, 6% of damp-clearing and itch-relieving auxiliary agent, 25% of wood pulp, 7% of polyvinyl alcohol fiber, 8% of polyvinyl chloride fiber, 8% of high-elasticity recovery degree elastic glue, 15% of elastic composite fiber, 12% of spandex fiber, 14% of polyester fiber, 12% of kapok fiber, 13% of cotton fiber, 10% of wheat straw fiber, 9% of castor fiber and 9% of anti-static polyester fiber.

In this embodiment, the antibacterial finishing agent includes 15% of organic metal compound, 5% of licorice, 3% of mint and 77% of water.

In this embodiment, the anti-decoloring auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, an AES partner thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, a cationic agglomerate, and water.

In the embodiment, the perfume auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

In the embodiment, the damp-clearing itch-relieving auxiliary agents comprise 40 g of dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

In this embodiment, the elastic gel with high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a colorant, a catalyst and a thickener.

In this embodiment, the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting manner.

In the embodiment, the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to enable the main chain of the bamboo pulp fiber to be mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

Example 5

The volcanic self-heating sock comprises the following components in percentage by weight: 11% of volcanic rock particles, 25% of wood pulp, 7% of polyvinyl alcohol fiber, 8% of polyvinyl chloride fiber, 8% of high-elasticity recovery degree elastic glue, 15% of elastic composite fiber, 12% of spandex fiber, 14% of polyester fiber, 12% of kapok fiber, 13% of cotton fiber, 10% of wheat straw fiber, 9% of castor fiber and 9% of antistatic polyester fiber.

In this embodiment, the antibacterial finishing agent includes 15% of organic metal compound, 5% of licorice, 3% of mint and 77% of water.

In this embodiment, the anti-decoloring auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, an AES partner thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, a cationic agglomerate, and water.

In the embodiment, the perfume auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

In the embodiment, the damp-clearing itch-relieving auxiliary agents comprise 40 g of dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

In this embodiment, the elastic gel with high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a colorant, a catalyst and a thickener.

In this embodiment, the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting manner.

In the embodiment, the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to enable the main chain of the bamboo pulp fiber to be mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

A volcanic rock spontaneous heating socks specifically comprises the following steps:

the method comprises the following steps: crushing volcanic rock particles by using a crusher, crushing the volcanic rock particles into powder, adding the powder into a thermocouple reaction kettle, continuously adding wood pulp, keeping the temperature at 30-50 ℃, and continuously stirring for 1-2 hours;

step two: respectively adding the antibacterial finishing agent, the anti-fading auxiliary agent, the perfume auxiliary agent and the dampness and itch removing auxiliary agent into the thermocouple reaction kettle in the step one, and continuously stirring to prepare mixed slurry;

step three: cutting the antistatic polyester fiber, the elastic composite fiber, the spandex fiber and the polyester fiber into short fibers, uniformly mixing, carrying out coarse carding and fine carding by a carding machine, and then carrying out drawing frame and fine winding to obtain a chemical fiber filament yarn A;

step four: cutting kapok fiber, cotton fiber, wheat straw fiber and castor fiber into short fibers, uniformly mixing, carrying out coarse carding and fine carding by a carding machine, and then carrying out drawing frame and fine complexing to obtain chemical fiber filaments B;

step five: placing the chemical fiber filament A prepared in the third step and the chemical fiber filament B prepared in the third step into the thermocouple reaction kettle in the first step at the same time, adding high-elasticity recovery degree elastic glue, continuously stirring for 1-2 hours, keeping the temperature at 20-30 ℃, taking out the chemical fiber filament A and the chemical fiber filament B, and drying the chemical fiber filament A and the chemical fiber filament B;

step six: twisting the chemical fiber filament B prepared in the fifth step outside the chemical fiber filament A into a coating yarn of the chemical fiber filament A by taking the chemical fiber filament A prepared in the fifth step as a core filament to prepare a composite yarn, and finally weaving the composite yarn into a sock by warp and weft;

step seven: adding into dye solution, rotating at room temperature for 15min, heating to 62 deg.C at a heating rate of 1.1 deg.C/min, maintaining for 10min, heating to 98 deg.C at a heating rate of 0.9 deg.C/min, maintaining for 30min, cooling to 52 deg.C at a cooling rate of 2.5 deg.C/min, draining, washing, fixing at 65 deg.C for 10min, washing, adding softening agent, treating at 40 deg.C for 30min, with the concentration of softening agent being 1.35%;

step eight: and (3) dehydrating the dyed socks, then shaping and preserving heat for 30s by using the sock connecting sleeve plate under the pressure of 0.1Mpa and the temperature of 100 ℃.

In this example, the thermocouple reactor was a thermocouple reactor equipped with a stirrer, a distillation column connected to a water-cooled condenser, a nitrogen inlet, and a temperature regulator.

Experiment one: the test of natural heat temperature was conducted for the socks prepared in example 1, example 2, example 3, example 4 and example 5 and the socks of the prior art, the samples to be tested were placed in the same environment, and the temperature of each sample to be tested was measured by a temperature measuring device at regular time every day, and the test data are shown in the following table:

the experimental results are as follows: the self-heating temperatures of the socks prepared in example 1, example 2 and example 3 were equal and significantly higher than those of the socks prepared in example 4 and example 5 and the socks of the prior art.

Experiment two: tests of elasticity, hard scratch resistance, washing resistance, aging resistance and abrasion resistance were carried out on the socks prepared in example 1, in example 2, in example 3, in example 4 and in example 5 and on the socks of the prior art,

(1) the elasticity is good: abrasion resistance > 800N;

(2) the wear resistance is good: abrasion resistance is less than 150mm³；

(3) Good washing resistance: the knee pad rubber is washed by water at 40 ℃ for 5 times, each time is 80 minutes, and the test is continuously carried out for 3 months, so that the knee pad rubber has no damage, falling, peeling or rotting;

(4) the aging resistance is good: after the test is continuously carried out for 3 months for 1 time in 40 minutes, the knee pad rubber has no crack phenomenon and no aging phenomenon;

(5) hard object scratch resistance: the knee pad rubber is subjected to scratch resistance test by adopting a conventional means, and is scratched for more than hundred times without scratches and damage.

The experimental data are shown in the following table:

the experimental results are as follows: the elasticity, scuff resistance, wash resistance, aging resistance and abrasion resistance of the socks prepared for example 1, for example 2, for example 3, for example 4 and for example 5 are significantly higher than those of the socks of the prior art.

Experiment three: tests for the damp and itch repellent, deodorant fragrance and fade resistance days duration were conducted for example 1, for example 2, for example 3, for example 4, for the socks prepared in example 5 and for the socks of the prior art, as shown in the following table:

the experimental results are as follows: the damp-clearing, itching-relieving, deodorizing, fragrance-dissipating and fade-resistant properties of example 1, example 2, example 3 and the socks prepared in example 4 were significantly higher than those of the socks prepared in example 5 and the socks of the prior art.

The invention has the beneficial effects that: according to the volcanic self-heating socks and the production process thereof, volcanic particles are crushed by a crusher to be crushed into powder, the powder is added into a thermocouple reaction kettle, wood pulp is continuously added, volcanic particles are adhered to a chemical fiber filament A and a chemical fiber filament B which are woven in a warp-weft mode, then the chemical fiber filament A is used as a core wire, the chemical fiber filament B is twisted outside the chemical fiber filament A to be coated yarns of the chemical fiber filament A to be prepared into composite yarns, and finally the composite yarns are woven in the warp-weft mode to be woven into socks, so that the socks have the self-heating effect from outside to inside. The volcanic self-heating socks and the production process thereof are characterized in that an antibacterial finishing agent, an anti-discoloration aid, a spice aid and a dampness and itch removing aid are respectively added into a thermocouple reaction kettle in the first step, mixed slurry is continuously prepared by stirring, antibacterial, discoloration preventing, spice and dampness and itch removing aids are adhered to a chemical fiber filament A and a chemical fiber filament B which are woven in a warp and weft mode, then the chemical fiber filament A is used as a core filament, the chemical fiber filament B is twisted outside the chemical fiber filament A into a coated yarn of the chemical fiber filament A to prepare a composite yarn, finally the composite yarn is woven in a warp and weft mode to form the socks, and the prepared socks have the effects of dampness and itch removing, deodorization and fragrance dispersing and the effect of difficult discoloration. The volcanic self-heating socks and the production process thereof are characterized in that antistatic polyester fibers, elastic composite fibers, spandex fibers and polyester fibers are cut into short fibers, the short fibers are uniformly mixed, coarse carding and fine carding are carried out by a carding machine, and then chemical fiber filaments A are formed by drawing and fine winding; the method comprises the following steps of cutting kapok fiber, cotton fiber, wheat straw fiber and castor fiber into short fibers, uniformly mixing, carding in a carding machine to obtain coarse and fine carding, drawing and fine complexing to obtain chemical fiber filament A, twisting the chemical fiber filament B outside the chemical fiber filament A to obtain coated yarn of the chemical fiber filament A to obtain composite yarn, and finally weaving the composite yarn in a warp-weft manner to obtain the socks, wherein the elastic elasticity, hard object scratch resistance, water washing resistance, ageing resistance and wear resistance of the socks are improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. A volcanic rock spontaneous heating socks which characterized in that: comprises the following components in percentage by weight: 2-4% of an antibacterial finishing agent, 4-8% of a discoloration-preventing auxiliary agent, 2-8% of a perfume auxiliary agent, 3-9% of a damp-clearing itching-relieving auxiliary agent, 9-13% of volcanic rock particles, 20-30% of wood pulp, 6-8% of polyvinyl alcohol fibers, 7-9% of polyvinyl chloride fibers, 6-10% of high-elasticity recovery elastic glue, 10-20% of elastic composite fibers, 10-14% of spandex fibers, 12-16% of polyester fibers, 9-15% of kapok fibers, 11-15% of cotton fibers, 9-11% of wheat straw fibers, 8-10% of castor fibers and 6-12% of antistatic polyester fibers.

2. The volcanic rock spontaneous heating socks of claim 1, wherein: the antibacterial finishing agent comprises 15% of organic metal compound, 5% of liquorice, 3% of mint and 77% of water.

3. The volcanic rock spontaneous heating socks of claim 1, wherein: the anti-decoloration auxiliary agent is prepared by mixing AES, starch transaminase, dimethyl phenyl acetate, AES mate thickener, polyethylene glycol, ramination, sodium octadecyl benzene sulfonate, sodium oleate, cation agglomerate and water.

4. The volcanic rock spontaneous heating socks of claim 1, wherein: the spice auxiliary agent comprises 20 g of folium artemisiae argyi, 20 g of thin lotus, 15 g of wrinkled gianthyssop herb, 15 g of asarum, 15 g of dried orange peel, 20 g of chrysanthemum, 20 g of jasmine, 15 g of honeysuckle, 15 g of hosta plantaginea, 20 g of rose, 20 g of fragrant rose and 10 g of evening primrose.

5. The volcanic rock spontaneous heating socks of claim 1, wherein: 40 g of damp-clearing itch-relieving auxiliary agent dandelion, 30 g of sappan wood, 20 g of poria cocos, 20 g of alum, 30 g of vine, 20 g of divaricate saposhnikovia root and 20 g of radix stephaniae tetrandrae.

6. The volcanic rock spontaneous heating socks of claim 1, wherein: the elastic rubber with the high elastic recovery degree is prepared from hydroxyl silicone oil, a cross-linking agent, a hydrocarbon solvent, a coloring agent, a catalyst and a thickening agent.

7. The volcanic rock spontaneous heating socks of claim 1, wherein: the antistatic polyester fiber is prepared by weaving conductive fibers into coral velvet in a tatting mode.

8. The volcanic rock spontaneous heating socks of claim 1, wherein: the preparation method of the conductive fiber comprises the steps of adopting bamboo pulp fiber, manufacturing the conductive fiber by utilizing the conductive property of carbon black, carbonizing the bamboo pulp fiber, and heating and carbonizing the bamboo pulp fiber at the temperature of 200-280 ℃ in inert atmosphere to ensure that the main chain of the bamboo pulp fiber is mainly carbon atoms, so that the carbonized fiber with good inherent fiber density and tensile strength and conductive property is obtained.

9. A production process of volcanic spontaneous heating socks is characterized in that: the method specifically comprises the following steps:

the method comprises the following steps: crushing volcanic rock particles by using a crusher, crushing the volcanic rock particles into powder, adding the powder into a thermocouple reaction kettle, continuously adding wood pulp, keeping the temperature at 30-50 ℃, and continuously stirring for 1-2 hours;

step two: respectively adding the antibacterial finishing agent, the anti-fading auxiliary agent, the perfume auxiliary agent and the dampness and itch removing auxiliary agent into the thermocouple reaction kettle in the step one, and continuously stirring to prepare mixed slurry;

step three: cutting the antistatic polyester fiber, the elastic composite fiber, the spandex fiber and the polyester fiber into short fibers, uniformly mixing, carrying out coarse carding and fine carding by a carding machine, and then carrying out drawing frame and fine winding to obtain a chemical fiber filament yarn A;

step four: cutting kapok fiber, cotton fiber, wheat straw fiber and castor fiber into short fibers, uniformly mixing, carrying out coarse carding and fine carding by a carding machine, and then carrying out drawing frame and fine complexing to obtain chemical fiber filaments B;

step five: placing the chemical fiber filament A prepared in the third step and the chemical fiber filament B prepared in the third step into the thermocouple reaction kettle in the first step at the same time, adding high-elasticity recovery degree elastic glue, continuously stirring for 1-2 hours, keeping the temperature at 20-30 ℃, taking out the chemical fiber filament A and the chemical fiber filament B, and drying the chemical fiber filament A and the chemical fiber filament B;

step six: twisting the chemical fiber filament B prepared in the fifth step outside the chemical fiber filament A into a coating yarn of the chemical fiber filament A by taking the chemical fiber filament A prepared in the fifth step as a core filament to prepare a composite yarn, and finally weaving the composite yarn into a sock by warp and weft;

step seven: adding into dye solution, rotating at room temperature for 15min, heating to 62 deg.C at a heating rate of 1.1 deg.C/min, maintaining for 10min, heating to 98 deg.C at a heating rate of 0.9 deg.C/min, maintaining for 30min, cooling to 52 deg.C at a cooling rate of 2.5 deg.C/min, draining, washing, fixing at 65 deg.C for 10min, washing, adding softening agent, treating at 40 deg.C for 30min, with the concentration of softening agent being 1.35%;

step eight: and (3) dehydrating the dyed socks, then shaping and preserving heat for 30s by using the sock connecting sleeve plate under the pressure of 0.1Mpa and the temperature of 100 ℃.

10. The production process of the volcanic spontaneous heating socks as claimed in claim 9, wherein the production process comprises the following steps: the thermocouple reaction kettle is provided with a stirrer, a distillation column connected with a water-cooled condenser, a nitrogen inlet and a thermocouple reaction kettle connected with a temperature regulator.