CN115897246A - Radiation-proof deodorizing blanket and production process thereof - Google Patents

Abstract

The invention relates to the technical field of textile fabrics, and discloses a radiation-proof deodorizing blanket and a production process thereof. The radiation-proof deodorizing blanket is characterized in that a radiation-proof layer is arranged and is formed by weaving first yarns and core-spun fibers, the first yarns are formed by twisting silver-coated stainless steel fibers, the core-spun fibers are formed by winding kapron copper ion fibers on glass fibers, the stainless steel fibers are also called stainless steel superfine fibers, the stainless steel fibers have the characteristics of fineness and softening, and the stainless steel fibers have bright and bright metal luster and special functions of electric conduction, electromagnetic wave shielding and the like.

Description

Radiation-proof deodorizing blanket and production process thereof

Technical Field

The invention relates to the technical field of textile fabrics, in particular to a radiation-proof deodorizing blanket and a production process thereof.

Background

The blanket is a common bedding article, has a warm-keeping function and is thinner than a quilt. The raw materials are mainly animal fibers (such as wool, mohair, rabbit hair, cashmere, camel hair and yakwool) or chemical fibers such as acrylic fibers and viscose fibers, and also are prepared by blending animal fibers and chemical fibers. The woolen fabric with the plump plush on both surfaces has the plump plush on the surface, has the warm-keeping performance and can be used as ornaments such as bedspreads, wall blankets and the like. The carpet comprises three types of pure carpets, blended carpets and chemical fiber carpets according to the raw materials of the carpets, and the weaving invention comprises weaving, tufting, warp knitting, needling, stitch knitting and the like, wherein the carpet surface patterns comprise jacquard patterns, printing, plain colors, mandarin duck colors, roads, lattices and the like, and the carpet surface styles comprise pile surface types, pile type, smooth hair types, rolling ball types, water texture types and the like.

In the daily life of people, along with the continuous increase of electrical equipment and electronic equipment, people are more and more influenced by electromagnetic radiation, most blankets are woven by single fabric fibers, the functions are single, and the performances of radiation resistance, antibiosis, static electricity prevention and the like are all deficient, for example, chinese patent CN107488923A discloses a radiation-proof deodorizing blanket and a production process thereof, wherein the blanket comprises 65-80 wt% of wool, 13-30 wt% of polyester fiber and 2-10 wt% of viscose fiber; the production process of the blanket comprises the following steps: selecting raw materials; (2) spinning; (3) weaving; (4) finishing and shaping; and (5) warehousing the finished product. The stainless steel wire is added, so that the product has the advantages of lasting, efficient and environment-friendly demagnetization performance and good electromagnetic radiation prevention effect; in addition, the ultrafine powder active carbon is added into the dye, so that the product not only has lasting, efficient and environment-friendly deodorization performance, but also fully exerts the excellent characteristics of warmth retention, skin friendliness, softness, smoothness and glutinous performance of the wool, is soft and comfortable,

but the radiation-proof deodorant fabric has poor radiation-proof deodorant effect, cannot meet the requirements at the same time, and limits the further application of the protective fabric in special fields.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a radiation-proof deodorizing blanket and a production process thereof, and solves the problems that most fabrics are woven by single fabric fibers, the functions are single, and the performances such as radiation resistance, antibiosis, static electricity resistance and the like are all deficient.

(II) technical scheme

The invention provides the following technical scheme:

a radiation-proof deodorizing blanket and a production process thereof comprise the following production steps:

s1, preparing deodorizing liquid;

s2, soaking the fabric;

s3, rolling and drying;

and S4, trimming and storing.

Further, the S1 includes the following steps:

(2) Preparing materials, namely 5-7 parts of parachlorometaxylenol, 5-7 parts of nonionic polyacrylamide, 65-85 parts of ultrapure water, 10-15 parts of polyvinyl alcohol, 0.5-2 parts of 1-2 butanol, 1-1.5 parts of glycerol, 0.001-0.005 part of EDTA-2Na0.01-0.02 part of nano silver and nano zinc, 0.01-0.03 part of chlorphenesin, 0.05-0.1 part of spice and 1.5-2 parts of fucus extract;

(2) Adding I-grade ultrapure water (the resistivity is more than or equal to 18M omega cm) into a reaction kettle, then adding parachlorometaxylenol, nonionic polyacrylamide and polyvinyl alcohol, starting stirring, gradually heating to 75-85 ℃, and stirring until the parachlorometaxylenol, the nonionic polyacrylamide and the polyvinyl alcohol are completely dissolved;

(3) Gradually adding butanol, 1-2 glycerol, EDTA-2Na and betaine every 5min, and controlling the temperature to be 75-85 ℃ to obtain a material A;

(4) Adding alkyl polydimethylsiloxane, octyl polymethylsiloxane and glycerol stearate into a reaction kettle, starting and stirring, heating to dissolve, adding vitamin E acetate, and controlling the temperature to be 75-85 ℃ to obtain a material B;

(5) Respectively adding the material A and the material B into a homogenizing emulsifying machine kettle, adding the material A and then adding the material B, carrying out high-speed homogenizing emulsification for 20-25 minutes by adopting a homogenizing emulsifying machine to ensure that the ingredient A phase and the ingredient B phase are fully emulsified and fused, and cooling to obtain a material C;

(6) Adding nano silver, nano zinc, chlorphenesin, spice and fucus extract into the material CN, and uniformly blending to obtain the deodorant solution.

Further, the S3 comprises the following steps of rolling the mixture at a roller pressure of 3-5bar, a speed of 15-17 m/min, overfeeding of 3-5% and a temperature of 140-150 ℃; baking: the temperature is 170-180 ℃, the vehicle speed is 12-15 m/min, and the overfeeding is 5-8%; rope washing: the speed of the vehicle is 280-300m/min, and the pressure of the roller is 1.2-1.5Bar.

The utility model provides a radiation protection type deodorization woollen blanket and production technology thereof, includes the base cloth layer, the last fixed surface of base cloth layer is connected with the cotton layer, the last fixed surface of cotton layer is connected with antibiotic layer, the last fixed surface on antibiotic layer is connected with the layer of protecting against radiation, the last fixed surface on the layer of protecting against radiation is connected with the wearing layer, the layer of protecting against radiation is woven by first yarn and covering fiber and is formed, first yarn is twisted together for the stainless steel fiber through silver-coated and forms, covering fiber is made on glass fiber for the winding of carplon copper ion fiber.

Preferably, the base cloth layer comprises a silk layer and a linen layer, and the linen layer is located between the silk layer and the cotton layer.

Preferably, the cotton cloth layer is formed by blending cotton fibers and modal fibers

Preferably, the antibacterial layer is woven by second yarns and bamboo charcoal fibers, and the second yarns are formed by spirally winding silver ion fibers and graphene fibers.

Preferably, the wear-resistant layer is woven by a plurality of elastic fabrics and polyester fabrics which are sequentially connected.

Preferably, the thickness ranges of the base cloth layer, the cotton cloth layer, the antibacterial layer, the radiation-proof layer and the wear-resistant layer are all 0.1-0.3mm.

(III) advantageous effects

Compared with the prior art, the invention provides a radiation-proof deodorizing blanket and a production process thereof, and the blanket has the following beneficial effects:

(1) When the radiation-proof deodorizing blanket is used, the radiation-proof layer is arranged and is formed by weaving first yarns and core-spun fibers, the first yarns are formed by twisting stainless steel fibers coated with silver, the core-spun fibers are formed by winding kapron copper ion fibers on glass fibers, the stainless steel fibers are also called stainless steel ultra-fine wires, and the stainless steel fibers are ultra-fine stainless steel wires. The radiation-proof fabric has the characteristics of fineness and softening, and the bright and bright metal luster and the special functions of electric conduction, electromagnetic wave shielding and the like of the stainless steel fiber, the radiation-proof performance of the stainless steel fiber is improved after the outer surface of the stainless steel fiber is coated with silver, the kapron copper ion fiber not only has the functions of strong and durable antibiosis, deodorization and self-cleaning, but also has good hydrophilicity and fabric comfortableness, the first yarn and the core-spun fiber are matched to form a metal net current to form a loop, and a reverse electromagnetic field is generated to play a role in radiation protection.

(2) When the radiation-proof deodorizing blanket is used, the second yarn is formed by weaving second yarns and bamboo charcoal fibers through the arranged antibacterial layer, the second yarns are formed by spirally winding silver ion fibers and graphene fibers, the bamboo charcoal fiber layer has natural antibacterial, bacteriostatic and bactericidal effects, a unique substance is arranged in the bamboo, the substance is named as 'bamboo quinone', has natural antibacterial, anti-mite, deodorizing and insect-proof functions, the silver ion fibers have the mildew-proof and deodorizing functions, the bacterium breeding can enable a body to generate odor, the silver ions on the surfaces of the silver ion fibers can quickly adsorb amonia and deteriorated protein on the silver ion fibers to reduce or eliminate the odor, the graphene fibers have excellent conductivity and play a role in preventing static electricity, the graphene fibers also have the characteristic of lasting bacteriostasis, and the radiation-proof deodorizing blanket is moisture-absorbing and breathable, is skin-friendly and comfortable to wear and can resist the invasion of ultraviolet rays, so that the antibacterial layer has the antibacterial, deodorizing and antistatic effects.

(3) When the radiation-proof deodorizing blanket is used, the cotton cloth layer is formed by blending cotton fibers and modal fibers, the modal fiber raw material is from natural wood, the modal fiber raw material can be naturally degraded after being used, the environment is not polluted, the modal fiber has good flexibility and excellent hygroscopicity, and the sweat absorption of the cotton cloth layer is improved; the wear-resistant layer is formed by weaving a plurality of elastic fabrics and the polyester fabrics which are sequentially connected, the elastic fabrics increase the stretch-resistant performance of the fabrics, the fabrics cannot be easily stretched and damaged, and the wear resistance of the fabrics is improved due to the arrangement of the polyester fabrics.

(4) When the radiation-proof deodorizing blanket is used, alkyl polydimethylsiloxane, octyl polymethylsiloxane, glyceryl stearate, vitamin E acetate, fucus extract and the like are taken to be compatible with each other, so that the cleaned skin is smooth and moist without damage. Meanwhile, the components are compatible with nano silver, nano zinc, chlorphenesin and the like, so that the product also has an antibacterial function;

(5) When the radiation-proof deodorizing blanket and the production process thereof are used, I-grade ultrapure water is adopted, the resistivity is more than or equal to 18M omega cm, and the water avoids the demulsification phenomenon of a system caused by metal particles; stainless steel and glass equipment are adopted in the production process, so that the existence of metal particles in a system is avoided, and the temperature in the production process is controlled, so that the stability of the system is solved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 shows a wear layer according to the invention.

In the figure: 1. a base cloth layer; 2. a cotton cloth layer; 3. an antibacterial layer; 4. a radiation-resistant layer; 5. a wear layer; 101. a silk layer; 102. a linen layer; 501. elastic cloth; 502. and (4) terylene cloth.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in 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.

Referring to fig. 1-2, a radiation-proof deodorizing blanket and a production process thereof includes the following steps:

s1, preparing deodorizing liquid;

s2, soaking the fabric;

s3, rolling and drying;

and S4, trimming and storing.

Further, the S1 includes the following steps:

(3) The preparation materials comprise 5 parts of parachlorometaxylenol, 5 parts of nonionic polyacrylamide, 65 parts of ultrapure water, 10 parts of polyvinyl alcohol, 0.5 part of 1-2 butanol, 1 part of glycerol, 0.001 part of EDTA-2Na0.001 part of nano silver and nano zinc, 0.01 part of chlorphenesin, 0.05 part of spice and 1.5 parts of fucus extract;

(2) Adding I-grade ultrapure water (the resistivity is more than or equal to 18M omega cm) into a reaction kettle, then adding parachlorometaxylenol, nonionic polyacrylamide and polyvinyl alcohol, starting stirring, gradually heating to 75 ℃, and stirring until the parachlorometaxylenol, the nonionic polyacrylamide and the polyvinyl alcohol are completely dissolved;

(3) Gradually adding butanol, 1-2 glycerol, EDTA-2Na and betaine every 5min, and controlling the temperature to be 75 ℃ to obtain a material A;

(4) Adding 3 parts of alkyl polydimethylsiloxane, 1.2 parts of octyl polymethylsiloxane and 4 parts of glycerol stearate into a reaction kettle, starting and stirring, heating to dissolve, adding vitamin E acetate, and controlling the temperature to be 75 ℃ to obtain a material B;

(5) Respectively adding the material A and the material B into a homogenizing and emulsifying machine kettle, adding the material A and then adding the material B, carrying out high-speed homogenizing and emulsifying for 20 minutes by adopting a homogenizing and emulsifying machine to fully emulsify and fuse the ingredient A phase and the ingredient B phase, and cooling to obtain a material C;

(6) Adding nano silver, nano zinc, chlorphenesin, 0.05 part of spice and fucus rudis extract into the material CN, and uniformly mixing to obtain the deodorant solution.

Further, the S3 comprises the following steps of controlling the roller pressure to be 3bar, the vehicle speed to be 15 m/min, the overfeeding to be 3 percent and the temperature to be 140 ℃; baking: the temperature is 170 ℃, the vehicle speed is 12 m/min, and the overfeeding is 5 percent; rope washing: the vehicle speed is 280m/min, and the roller pressure is 1.2Bar.

The radiation-proof deodorizing blanket comprises a base cloth layer 1, wherein a cotton cloth layer 2 is fixedly connected to the upper surface of the base cloth layer 1, an antibacterial layer 3 is fixedly connected to the upper surface of the cotton cloth layer 2, a radiation-proof layer 4 is fixedly connected to the upper surface of the antibacterial layer 3, a wear-resistant layer 5 is fixedly connected to the upper surface of the radiation-proof layer 4, the radiation-proof layer 4 is woven by first yarns and core-spun fibers, the first yarns are formed by twisting silver-coated stainless steel fibers, the core-spun fibers are made by winding kaplan copper ion fibers on glass fibers, the stainless steel fibers are also called stainless steel ultra-fine wires, and the stainless steel fibers are ultrafine stainless steel wires. The radiation-proof fabric has the characteristics of fineness and softening, and the bright and bright metal luster and the special functions of electric conduction, electromagnetic wave shielding and the like of the stainless steel fiber, the radiation-proof performance of the stainless steel fiber is improved after the outer surface of the stainless steel fiber is coated with silver, the kapron copper ion fiber not only has the functions of strong and durable antibiosis, deodorization and self-cleaning, but also has good hydrophilicity and fabric comfortableness, the first yarn and the core-spun fiber are matched to form a metal net current to form a loop, and a reverse electromagnetic field is generated to play a role in radiation protection.

Further, the base fabric layer 1 comprises a silk layer 101 and a linen layer 102, and the linen layer 102 is located between the silk layer 101 and the cotton layer 2, so that the air permeability of the base fabric layer 1 is improved, and the base fabric layer 1 has good comfort.

Furthermore, the cotton cloth layer 2 is formed by blending cotton fibers and modal fibers, the modal fiber raw material is from natural wood, the modal fiber raw material can be naturally degraded after being used, the environment is not polluted, the modal fibers have good flexibility and excellent hygroscopicity, and the sweat absorption performance of the cotton cloth layer is improved

Further, the antibacterial layer 3 is formed by weaving second yarns and bamboo charcoal fibers, the second yarns are formed by spirally winding silver ion fibers and graphene fibers, the bamboo charcoal fiber layer has natural antibacterial, bacteriostatic and bactericidal effects, a unique substance is arranged in bamboo, the substance is named as 'bamboo quinone', the substance has natural antibacterial, anti-mite, deodorant and insect-proof functions, the silver ion fibers have a mould-proof and deodorizing function, bacteria breeding can enable a body to generate odor, silver ions on the surface of the silver ion fibers 202 can quickly adsorb amonia and deteriorated protein to reduce or eliminate the odor, the graphene fibers have excellent conductivity and play a role in static electricity prevention, and have the characteristics of lasting bacteriostasis, moisture absorption and ventilation like cotton, skin-friendly and comfortable wearing and can resist ultraviolet invasion, so that the antibacterial layer 3 has antibacterial, deodorant and antistatic effects.

Further, the wear-resistant layer 5 is woven by a plurality of elastic fabrics 501 and terylene fabrics 502 which are sequentially connected, the elastic fabrics 501 increase the tensile resistance of the fabrics, so that the fabrics cannot be easily stretched and damaged, and the terylene fabrics 502 improve the wear resistance of the fabrics.

Furthermore, the thickness ranges of the base cloth layer 1, the cotton cloth layer 2, the antibacterial layer 3, the radiation-proof layer 4 and the wear-resistant layer 5 are all 0.1-0.3mm, so that the condition that the use is influenced due to the overlarge thickness of the cloth is avoided.

Embodiment 2, a radiation-proof deodorizing blanket and a production process thereof, comprising the following production steps:

s1, preparing deodorizing liquid;

s2, soaking the fabric;

s3, rolling and drying;

and S4, trimming and storing.

Further, the S1 includes the following steps:

(4) The preparation materials comprise 6 parts of parachlorometaxylenol, 6 parts of nonionic polyacrylamide, 75 parts of ultrapure water, 13 parts of polyvinyl alcohol, 1.2 parts of 1-2 butanol, 1.3 parts of glycerol, 0.003 part of EDTA-2Na0.003 part of nano-silver and nano-zinc, 0.02 part of chlorphenesin, 0.08 part of spice and 1.7 parts of fucus extract;

(2) Adding I-grade ultrapure water (the resistivity is more than or equal to 18M omega cm) into a reaction kettle, then adding parachlorometaxylenol, nonionic polyacrylamide and polyvinyl alcohol, starting stirring, gradually heating to 75-85 ℃, and stirring until the parachlorometaxylenol, the nonionic polyacrylamide and the polyvinyl alcohol are completely dissolved;

(3) Gradually adding butanol, 1-2 glycerol, EDTA-2Na and betaine every 5min, and controlling the temperature to be 75-85 ℃ to obtain a material A;

(4) Adding alkyl polydimethylsiloxane, octyl polymethylsiloxane and glycerol stearate into a reaction kettle, starting and stirring, heating to dissolve, adding vitamin E acetate, and controlling the temperature to be 75-85 ℃ to obtain a material B;

(5) Respectively adding the material A and the material B into a homogenizing and emulsifying machine kettle, adding the material A and then adding the material B, carrying out high-speed homogenizing and emulsifying for 23 minutes by adopting a homogenizing and emulsifying machine to fully emulsify and fuse the ingredient A phase and the ingredient B phase, and cooling to obtain a material C;

(6) Adding nano silver, nano zinc, chlorphenesin, spice and fucus extract into the material CN, and uniformly blending to obtain the deodorant solution.

Further, the S3 comprises the following steps of roller pressure of 4bar, vehicle speed of 16 m/min, overfeed of 4% and temperature of 144 ℃; baking: the temperature is 175 ℃, the vehicle speed is 13 m/min, and the overfeeding is 6 percent; rope washing: the vehicle speed is 289m/min, and the roller pressure is 1.4Bar.

Embodiment 3, a radiation-proof deodorizing blanket and a production process thereof, comprising the following production steps:

s1, preparing deodorizing liquid;

s2, soaking the fabric;

s3, rolling and drying;

and S4, trimming and storing.

Further, the S1 includes the following steps:

(5) The preparation materials comprise 7 parts of parachlorometaxylenol, 7 parts of nonionic polyacrylamide, 85 parts of ultrapure water, 15 parts of polyvinyl alcohol, 2 parts of 1-2 butanol, 1.5 parts of glycerol, 0.005 part of EDTA-2Na0.005 part of nano silver and nano zinc, 0.03 part of chlorphenesin, 0.1 part of spice and 2 parts of fucus extract;

(2) Adding I-grade ultrapure water (the resistivity is more than or equal to 18M omega cm) into a reaction kettle, then adding parachlorometaxylenol, nonionic polyacrylamide and polyvinyl alcohol, starting stirring, gradually heating to 75-85 ℃, and stirring until the parachlorometaxylenol, the nonionic polyacrylamide and the polyvinyl alcohol are completely dissolved;

(3) Gradually adding butanol, 2-propanetriol, EDTA-2Na and betaine every 5min, and controlling the temperature to be 85 ℃ to obtain a material A;

(4) Adding alkyl polydimethylsiloxane, octyl polymethylsiloxane and glycerol stearate into a reaction kettle, starting and stirring, heating to dissolve, adding vitamin E acetate, and controlling the temperature to be 85 ℃ to obtain a material B;

(5) Respectively adding the material A and the material B into a homogenizing and emulsifying machine kettle, adding the material A and then adding the material B, carrying out high-speed homogenizing and emulsifying for 25 minutes by adopting a homogenizing and emulsifying machine to fully emulsify and fuse the ingredient A phase and the ingredient B phase, and cooling to obtain a material C;

(6) Adding nano silver, nano zinc, chlorphenesin, spice and fucus extract into the material CN, and uniformly blending to obtain the deodorant solution.

Further, the S3 comprises the following steps of roller pressure of 5bar, vehicle speed of 17 m/min, overfeed of 5% and temperature of 150 ℃; baking: the temperature is 180 ℃, the vehicle speed is 15 m/min, and the overfeeding is 8 percent; rope washing: the vehicle speed is 300m/min, and the roller pressure is 1.5Bar.

To sum up, when the radiation-proof deodorizing blanket and the production process thereof are used, the radiation-proof layer 4 is formed by weaving first yarns and core-spun fibers, the first yarns are formed by twisting silver-coated stainless steel fibers, the core-spun fibers are made by winding kapron copper ion fibers on glass fibers, the stainless steel fibers are also called as stainless steel ultra-fine wires, and the stainless steel fibers are ultra-fine stainless steel wires. The radiation-proof fabric has the characteristics of fineness and softening, and also has the bright and bright metallic luster and special functions of electric conduction, electromagnetic wave shielding and the like of the stainless steel fiber, the radiation-proof performance of the stainless steel fiber is improved after the outer surface of the stainless steel fiber is coated with silver, the kapron copper ion fiber not only has strong and durable antibacterial, deodorizing and self-cleaning functions, but also has good hydrophilicity and fabric comfort, and the first yarn and the core-spun fiber are matched to form a metal net current to form a loop to generate a reverse electromagnetic field to play a role in radiation protection.

When the radiation-proof deodorizing blanket is used, the second yarn is formed by weaving second yarns and bamboo charcoal fibers through the arranged antibacterial layer 3, the second yarns are formed by spirally winding silver ion fibers and graphene fibers, the bamboo charcoal fiber layer has natural antibacterial, bacteriostatic and bactericidal effects, a unique substance is arranged in the bamboo, the substance is named as 'bamboo quinone', has natural antibacterial, anti-mite, deodorizing and insect-proof functions, the silver ion fibers have the mildew-proof and deodorizing functions, the bacterium breeding can enable a body to generate odor, silver ions on the surface of the silver ion fibers 202 can quickly adsorb amonia and deteriorated protein on the silver ions to reduce or eliminate the odor, the graphene fibers have excellent conductivity and play a role in preventing static electricity, and the graphene fibers also have the characteristic of lasting bacteriostasis, are moisture-absorbing and breathable, are skin-friendly and comfortable to wear and can resist invasion of odor ultraviolet rays, so that the antibacterial layer 3 has the antibacterial, deodorizing and anti-static effects.

When the radiation-proof deodorizing blanket and the production process thereof are used, the cotton cloth layer 2 is formed by blending cotton fibers and modal fibers, the modal fiber raw material is from natural wood, the modal fiber raw material can be naturally degraded after being used, the environment is not polluted, and the modal fiber has good flexibility and excellent hygroscopicity, so that the sweat absorption of the cotton cloth layer is improved; the wear-resistant layer 5 is formed by weaving a plurality of elastic fabrics 501 and terylene fabrics 502 which are sequentially connected, the elastic fabrics 501 increase the tensile resistance of the fabrics, the fabrics cannot be easily stretched and damaged, and the terylene fabrics 502 improve the wear resistance of the fabrics

It should be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, invention, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, invention, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a" \8230; "does not exclude the presence of additional like elements in a process, invention, article, or apparatus that comprises the element.

The standard parts used in the present application document can be purchased from the market, and can be customized according to the description of the specification and the accompanying drawings, the specific connection mode of each part adopts the conventional means matured in the prior art, the machines, the parts and the equipment adopt the conventional types in the prior art, the circuit connection adopts the conventional connection mode in the prior art, no specific description is provided here, meanwhile, the electric elements appearing in the specification are electrically connected with the external main controller and the mains supply, the peripheral controller mentioned in the specification can play a control role for the electric elements mentioned in the specification, and the peripheral controller is the conventional known equipment.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The radiation-proof deodorizing blanket is characterized by comprising the following production steps:

s1, preparing deodorizing liquid;

s2, soaking the fabric;

s3, rolling and drying;

and S4, trimming and storing.

2. The radiation-proof deodorizing blanket and the production process thereof according to claim 1 are characterized in that: the S1 comprises the following steps:

(1) Preparing materials, namely 5-7 parts of parachlorometaxylenol, 5-7 parts of nonionic polyacrylamide, 65-85 parts of ultrapure water, 10-15 parts of polyvinyl alcohol, 0.5-2 parts of 1-2 butanol, 1-1.5 parts of glycerol, 0.001-0.005 part of EDTA-2Na0.01-0.02 part of nano silver and nano zinc, 0.01-0.03 part of chlorphenesin, 0.05-0.1 part of spice and 1.5-2 parts of fucus extract;

(2) Adding I-grade ultrapure water (the resistivity is more than or equal to 18M omega cm) into a reaction kettle, then adding parachlorometaxylenol, nonionic polyacrylamide and polyvinyl alcohol, starting stirring, gradually heating to 75-85 ℃, and stirring until the parachlorometaxylenol, the nonionic polyacrylamide and the polyvinyl alcohol are completely dissolved;

(3) Gradually adding butanol, 1-2 glycerol, EDTA-2Na and betaine every 5min, and controlling the temperature to be 75-85 ℃ to obtain a material A;

(4) Adding alkyl polydimethylsiloxane, octyl polymethylsiloxane and 4-6 parts of glycerol stearate into a reaction kettle, starting and stirring, heating to dissolve, adding vitamin E acetate, and controlling the temperature to be 75-85 ℃ to obtain a material B;

(5) Respectively adding the material A and the material B into a homogenizing emulsifying machine kettle, adding the material A and then adding the material B, carrying out high-speed homogenizing emulsification for 20-25 minutes by adopting a homogenizing emulsifying machine to ensure that the ingredient A phase and the ingredient B phase are fully emulsified and fused, and cooling to obtain a material C;

(6) Adding nano silver, nano zinc, chlorphenesin, spice and fucus extract into the material CN, and uniformly blending to obtain the deodorant solution.

3. The radiation-proof deodorizing blanket and the production process thereof according to claim 1, characterized in that: s3, in the following steps, the roller pressure is 3-5bar, the speed is 15-17 m/min, the overfeeding is 3-5%, and the temperature is 140-150 ℃; baking: the temperature is 170-180 ℃, the vehicle speed is 12-15 m/min, and the overfeeding is 5-8%; rope washing: the speed of the vehicle is 280-300m/min, and the pressure of the roller is 1.2-1.5Bar.

4. The utility model provides a radiation protection type deodorization woollen blanket, includes base cloth layer (1), its characterized in that: the upper surface fixedly connected with cotton layer (2) of base cloth layer (1), the last fixed surface of cotton layer (2) is connected with antibiotic layer (3), the last fixed surface of antibiotic layer (3) is connected with protects layer (4) against radiation, the last fixed surface of protecting against radiation layer (4) is connected with wearing layer (5), it forms by first yarn and core-spun fiber weaving to protect against radiation layer (4), first yarn forms for twisting together through silver-coated stainless steel fiber, the core-spun fiber is made on glass fiber for the winding of kapron copper ion fiber.

5. The radiation protection type deodorizing blanket according to claim 1, wherein: the base cloth layer (1) comprises a silk layer (101) and a linen layer (102), and the linen layer (102) is located between the silk layer (101) and the cotton cloth layer (2).

6. The radiation protection type deodorizing blanket according to claim 4, wherein: the cotton cloth layer (2) is formed by blending cotton fibers and modal fibers.

7. The radiation protection type deodorizing blanket according to claim 4, wherein: the antibacterial layer (3) is formed by weaving second yarns and bamboo charcoal fibers, and the second yarns are formed by spirally winding silver ion fibers and graphene fibers.

8. The radiation protection type deodorizing blanket according to claim 4, wherein: the wear-resistant layer (5) is formed by weaving a plurality of elastic fabrics (501) and terylene fabrics (502) which are sequentially connected.

9. The radiation protection type deodorizing blanket according to claim 4, wherein: the thickness ranges of the base cloth layer (1), the cotton cloth layer (2), the antibacterial layer (3), the radiation-proof layer (4) and the wear-resistant layer (5) are all 0.1-0.3mm.

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