CN106307639B - 3D printing elastic biological far-infrared anti-biotic deodorization underwear and preparation method thereof - Google Patents
3D printing elastic biological far-infrared anti-biotic deodorization underwear and preparation method thereof Download PDFInfo
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- CN106307639B CN106307639B CN201610650123.9A CN201610650123A CN106307639B CN 106307639 B CN106307639 B CN 106307639B CN 201610650123 A CN201610650123 A CN 201610650123A CN 106307639 B CN106307639 B CN 106307639B
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- A—HUMAN NECESSITIES
- A41—WEARING APPAREL
- A41B—SHIRTS; UNDERWEAR; BABY LINEN; HANDKERCHIEFS
- A41B17/00—Selection of special materials for underwear
-
- A—HUMAN NECESSITIES
- A41—WEARING APPAREL
- A41C—CORSETS; BRASSIERES
- A41C3/00—Brassieres
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- A—HUMAN NECESSITIES
- A41—WEARING APPAREL
- A41C—CORSETS; BRASSIERES
- A41C5/00—Machines, appliances, or methods for manufacturing corsets or brassieres
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- Engineering & Computer Science (AREA)
- Textile Engineering (AREA)
- Manufacturing & Machinery (AREA)
- Chemical & Material Sciences (AREA)
- Materials Engineering (AREA)
- Undergarments, Swaddling Clothes, Handkerchiefs Or Underwear Materials (AREA)
- Corsets Or Brassieres (AREA)
- Radiation-Therapy Devices (AREA)
- Pharmaceuticals Containing Other Organic And Inorganic Compounds (AREA)
Abstract
The present invention relates to a kind of underwears, and in particular to a kind of 3D printing elastic biological far-infrared anti-biotic deodorization underwear and preparation method thereof.Underwear is made up of 3D printing technique, including following raw material:Filmogen, the material that far infrared electromagnetic can be radiated and nano-antibacterial deodorizing material;The material that far infrared electromagnetic can be radiated is far infrared nano-ceramic powder;Nano-antibacterial deodorizing material is one or more in nano-silver ionic, nanometer copper ion, nanometer zinc ion, nano-titanium dioxide or nano-negative ion.The material wear ability of underwear of the present invention is good, can keep the shape of underwear, possesses the characteristic of health care, can generate activation histocyte, improve blood circulation and analgesia function, with antibiosis and deodorization effects, to people with biology friendly;The present invention also provides preparation methods.
Description
Technical field
The present invention relates to a kind of underwears, and in particular to a kind of 3D printing elastic biological far-infrared anti-biotic deodorization underwear and its system
Preparation Method.
Background technology
Underwear produces mainly based on weaving, dyeing, sizing, cutting, sewing at present, entire production process spillage of material
Greatly, high energy consumption, environmental pollution is serious, production environment is poor, serious manpower and materials, the differential functionalization of wasting is relatively difficult,
It is difficult to keep pace with the times, so being very high to the hope of the rapid shaping of underwear.Current and future, not with life water
Raising, the functionalization of underwear requires more and more urgent.The functionalization of underwear is required also higher and higher.
Invention content
In view of the deficiencies of the prior art, the object of the present invention is to provide a kind of 3D printing elastic biological far-infrared anti-biotic deodorizations
Underwear, material wear ability is good, can keep the shape of underwear, possesses the characteristic of health care, can generate activation histocyte, improves
Blood circulation and analgesia function, with antibiosis and deodorization effects, to people with biology friendly;The present invention also provides its preparation sides
Method.
3D printing elastic biological far-infrared anti-biotic deodorization underwear of the present invention, underwear are made up of 3D printing technique,
Including following raw material:Filmogen, the material that far infrared electromagnetic can be radiated and nano-antibacterial deodorizing material.
3D printing elastic biological far-infrared anti-biotic deodorization underwear of the present invention, includes the raw material of following weight fraction:
Filmogen 80-95%, the material 1-10% that far infrared electromagnetic can be radiated and nano-antibacterial deodorizing material 1-10%.
Wherein:
Filmogen is silica gel, gel, latex, TFEE, PLA, PVC or TPE.
The material that far infrared electromagnetic can be radiated is:Far infrared nano-ceramic powder.
Far infrared nano-ceramic powder is grouped as by the group of following weight fraction:Aluminium oxide 10-30%, silica 10-30%,
Titanium oxide 10-30%, magnesia 10-30% and zirconium oxide 10-30%.
The preparation method of far infrared nano-ceramic powder is:According to product formula weighing and burden, mixing, compression moulding or rolling
Dynamic molding, is then dried, sinter molding, through being crushed, roughly grinding, be finely ground to 10000-30000 mesh, is finally dried, airflow milling dispersion
Obtain far infrared nano-ceramic powder.
The far infrared that far infrared nano-ceramic powder preferred emission wavelength is 8~15 μm, normal spectral emissivity are excellent
Choosing reaches 85% or more.
As a kind of perferred technical scheme, the preparation method of far infrared nano-ceramic powder is:It weighs according to product formula
Dispensing is mixed by three-dimensional mixer, then compression moulding or rolling molding are dried, through shuttle kiln at 1000-1400 DEG C,
Heat preservation 1-10 hour, sinter molding, after through Raymond mill is broken reach 200-1000 mesh, ball mill is roughly ground, nanometer sand mill is thin
It is milled to 10000-30000 mesh, finally spray drying drying or baking oven drying, airflow milling disperse to obtain far infrared nano-ceramic powder.
Nano-antibacterial deodorizing material is nano-silver ionic, nanometer copper ion, nanometer zinc ion, nano-titanium dioxide or nanometer
It is one or more in anion;These nano-antibacterial deodorizing materials are due to biology friend good with antibiosis and deodorization effects, to people
The advantages that good property, can be applied to underwear preparation, but due to having high temperature or strong acid and strong base environment during producing fiber, have
Cannot add or due to technique limitation additive amount it is very few, effect is had a greatly reduced quality, the present invention using 3D printing molding avoid this
A little problems.
3D printing elastic biological far-infrared anti-biotic deodorization underwear of the present invention, further includes auxiliary agent, and auxiliary agent is nanometer stone
One or more in black alkene, anion nanometer powder, nanometer selenium powder or Chinese medicine preparation, Chinese medicine preparation can be wilsonii, thin
One or more of lotus, Chloranthus glaber etc.;The addition weight of auxiliary agent is preferably filmogen, can radiate far infrared electromagnetic
Material and the sum of nano-antibacterial deodorizing material three 0.1-5%.
3D printing elastic biological far-infrared anti-biotic deodorization underwear of the present invention, underwear can be lady's underwear, woman style
Shorts, skivvies, in men's style shorts or woman style brassiere.
The preparation method of 3D printing elastic biological far-infrared anti-biotic deodorization underwear of the present invention:Raw material is poured into stirring
Stirring and mixing, dispersion in tank, then it is fully ground dispersion, temperature of charge is no more than 40 DEG C, detects slurry, and it is 20- to make its viscosity
Then 3D printing system printing, heat-shaping or microwave molding is added in 70pa.s, degree of polymerization 1000-2000, control temperature is not
More than 160 DEG C, product after molding is removed into gas permeable material, washing drying, drying temperature is no more than 80 DEG C, and test package obtains
To product.
As a kind of perferred technical scheme, 3D printing elastic biological far-infrared anti-biotic deodorization underwear of the present invention
Preparation method:Raw material is poured into stirring and mixing in agitator tank, is fully ground point with high speed dispersor dispersion, again with nanometer sand mill
It dissipates, open cooling system, temperature of charge no more than 40 DEG C, the slurry processed detects the indexs such as viscosity, degree of polymerization, viscosity
Reach 20-70pa.s, the degree of polymerization reaches 1000-2000,3D printing system, printing speed, heat-shaping or microwave is then added
Molding, controlling temperature are no more than 160 DEG C, and washing, drying, drying temperature do not have to more than 80 DEG C, and test package obtains product.
The underwear of 3D printing, entire underwear design embodies the meaning of private customization invariably, because from cup to shoulder belt again
3D scanning techniques are all used to hidden buckle of underwear.Made to carry out exclusive underwear design by the precise information of each women
Comfort level and plasticity reach ultimate attainment.Not only appearance is graceful for they, but also can ensure to agree with user's perfection.
In conclusion the present invention has the following advantages:
(1) present invention changes the mode of production of underwear using 3D printing technique, by the filmogen of 3D printing, Neng Goufang
The material and nano-antibacterial deodorizing material of injection far infrared electromagnetic are created instead of traditional textile material in customized
Clothing.Traditional sewing technology is not used during 3D printing, gives one clean appearance of underwear.In addition, the molding of 3D printing
Material is more resistant, can keep the shape of underwear.It is created that exquisite pattern, user can input ruler by computer using software
It is very little that customize, one's own underwear, production does not waste with the pattern liked.
(2) underwear flexibility ratio of the present invention, durability, smoothness are all well and good, and also very comfortable when skin contact.Using spy
The far infrared nano-ceramic powder of different technique research and development makes underwear possess the characteristic of health care, can generate activation histocyte, improves
Blood circulation and analgesia function, can preventing mammary gland hyperplasia disease generation, to disease itself also play the role of improve symptom, to body
It is beneficial to human body that body, which plays energy antibacterial and deodouring,.Far infrared has certain health-care effect to human body, promotes blood circulation, allows
Body keeps certain temperature.In addition to this, far infrared is also a kind of electromagnetic wave, thus human body can rapidly absorb it is this
Electromagnetic wave, the vibration of atom and molecule can be caused by going deep into electromagnetic wave into the human body, pass through resonant absorption, formed thermal response and promoted
Subcutaneous deep temperature rise, fine vascular expansion is set to promote blood circulation, the obstacle that extravasated blood etc. is harmed to metabolism is all clear
Except clean, so that tissue is brought back to life again, promotes ferment growth.Originally it is detained old waste in vivo and harmful substance, it can be with
Metabolism is excreted by sweat gland, and the cosmetics residue being present in pore, it will be able to need not penetrate kidney, directly from
Skin and sweat excrete together, can avoid the burden for increasing kidney.
(3) from the perspective of bodybuilding, 3D printing elastic biological far infrared antibody bacterium deodorization underwear plays the role of breast augmentation, makes
Women more bodybuilding.
(4) underwear of the present invention has many advantages, such as antibiosis and deodorization effects, has biological friendly to people.
(5) the present invention also provides preparation method, production process does not have waste material, exhaust gas, and environmentally friendly, at low cost, production is quickly.
Specific implementation mode
With reference to embodiment, the present invention will be further described.
Embodiment 1
A kind of 3D printing elastic biological far-infrared anti-biotic deodorization underwear, includes the raw material of following weight fraction:Filmogen
85%, the material 10% and nano-antibacterial deodorizing material 5% of far infrared electromagnetic can be radiated.
Filmogen is silica gel.
Nano-antibacterial deodorizing material is nano-silver ionic.
The material that far infrared electromagnetic can be radiated is:Far infrared nano-ceramic powder;Far infrared nano-ceramic powder by with
The group of lower weight fraction is grouped as:Aluminium oxide 20%, silica 20%, titanium oxide 30%, magnesia 10% and zirconium oxide 20%.
The preparation method of far infrared nano-ceramic powder is:According to product formula weighing and burden, mixed by three-dimensional mixer,
Compression moulding or roll molding, then dry, through shuttle kiln at 1250 DEG C, keep the temperature 6 hours, sinter molding, after covered through thunder
Gall it is broken reach 325 mesh, ball mill corase grinding, nanometer sand mill are finely ground to 10000-30000 mesh, finally spray drying drying or dry
Case is dried, and airflow milling disperses to obtain far infrared nano-ceramic powder.
The preparation method of the 3D printing elastic biological far-infrared anti-biotic deodorization underwear:Raw material is poured into stir in agitator tank and is mixed
With, with high speed dispersor dispersion, again with nanometer sand mill be fully ground dispersion, open cooling system, temperature of charge no more than
40 DEG C, detection phosphoric acid is 50pa.s, the degree of polymerization 1500, is then added 3D printing system, printing speed, heat-shaping or
Microwave is molded, and controlling temperature is no more than 160 DEG C, and washing, drying, drying temperature do not have to more than 80 DEG C, test package.
Embodiment 2
A kind of 3D printing elastic biological far-infrared anti-biotic deodorization underwear, includes the raw material of following weight fraction:Filmogen
95%, the material 2% and nano-antibacterial deodorizing material 3% of far infrared electromagnetic can be radiated;Further include auxiliary agent, auxiliary agent is to receive
Rice graphene;The addition weight of auxiliary agent is filmogen, can radiate the material and nano-antibacterial deodorizing of far infrared electromagnetic
The 2% of the sum of material three.
Filmogen is latex.
Nano-antibacterial deodorizing material is nanometer copper ion and nanometer zinc ion is 1 by weight:1 mixing.
The material that far infrared electromagnetic can be radiated is:Far infrared nano-ceramic powder, far infrared nano-ceramic powder by with
The group of lower weight fraction is grouped as:Aluminium oxide 30%, silica 10%, titanium oxide 30%, magnesia 20% and zirconium oxide 10%.
The preparation method of far infrared nano-ceramic powder is:According to product formula weighing and burden, mixed by three-dimensional mixer,
Compression moulding or roll molding, then dry, through shuttle kiln at 1350 DEG C, keep the temperature 3 hours, sinter molding, after covered through thunder
Gall it is broken reach 400 mesh, ball mill corase grinding, nanometer sand mill are finely ground to 10000-30000 mesh, finally spray drying drying or dry
Case is dried, and airflow milling disperses to obtain far infrared nano-ceramic powder.
The preparation method of the 3D printing elastic biological far-infrared anti-biotic deodorization underwear:Raw material is poured into stir in agitator tank and is mixed
With, with high speed dispersor dispersion, again with nanometer sand mill be fully ground dispersion, open cooling system, temperature of charge no more than
40 DEG C, detection phosphoric acid is 60pa.s, the degree of polymerization 2000, is then added 3D printing system, printing speed, heat-shaping or
Microwave is molded, and controlling temperature is no more than 160 DEG C, and washing, drying, drying temperature do not have to more than 80 DEG C, test package.
Embodiment 3
A kind of 3D printing elastic biological far-infrared anti-biotic deodorization underwear, includes the raw material of following weight fraction:Filmogen
80%, far-infrared electromagnetic wave material 10% and nano-antibacterial deodorizing material 10% can be radiated;Further include auxiliary agent, auxiliary agent is to receive
The weight ratios mixing such as rice graphene, nanometer selenium powder and anion nanometer powder;The addition weight of auxiliary agent is filmogen, Neng Goufang
The material of injection far infrared electromagnetic and the 4% of the sum of nano-antibacterial deodorizing material three.
Filmogen is TPE.
Nano-antibacterial deodorizing material is the mixing of the weight ratios such as nanometer zinc ion, nano-titanium dioxide and nano-negative ion.
The material that far infrared electromagnetic can be radiated is:Far infrared nano-ceramic powder, far infrared nano-ceramic powder by with
The group of lower weight fraction is grouped as:Aluminium oxide 25%, silica 15%, titanium oxide 15%, magnesia 15% and zirconium oxide 30%.
The preparation method of far infrared nano-ceramic powder is:According to product formula weighing and burden, mixed by three-dimensional mixer,
Compression moulding or roll molding, then dry, through shuttle kiln at 1100 DEG C, keep the temperature 9 hours, sinter molding, after covered through thunder
Gall it is broken reach 500 mesh, ball mill corase grinding, nanometer sand mill are finely ground to 10000-30000 mesh, finally spray drying drying or dry
Case is dried, and airflow milling disperses to obtain far infrared nano-ceramic powder.
The preparation method of the 3D printing elastic biological far-infrared anti-biotic deodorization underwear:Raw material is poured into stir in agitator tank and is mixed
With, with high speed dispersor dispersion, again with nanometer sand mill be fully ground dispersion, open cooling system, temperature of charge no more than
40 DEG C, detection phosphoric acid is 30pa.s, the degree of polymerization 1000, is then added 3D printing system, printing speed, heat-shaping or
Microwave is molded, and controlling temperature is no more than 160 DEG C, and washing, drying, drying temperature do not have to more than 80 DEG C, test package.
Claims (4)
1. a kind of 3D printing elastic biological far-infrared anti-biotic deodorization underwear, it is characterised in that:Underwear is made up of 3D printing technique,
Including following raw material:Filmogen, the material that far infrared electromagnetic can be radiated and nano-antibacterial deodorizing material;
The material that far infrared electromagnetic can be radiated is:Far infrared nano-ceramic powder;
Far infrared nano-ceramic powder is the far infrared that launch wavelength is 8~15 μm, normal spectral emissivity reach 85% with
On;
Far infrared nano-ceramic powder is grouped as by the group of following weight fraction:Aluminium oxide 10-30%, silica 10-30%, titanium oxide
10-30%, magnesia 10-30% and zirconium oxide 10-30%;
The preparation method of far infrared nano-ceramic powder is:According to product formula weighing and burden, mixing, compression moulding or roll at
Then type is dried, sinter molding, through being crushed, roughly grinding, be finely ground to 10000-30000 mesh, is finally dried, airflow milling disperses to obtain
Far infrared nano-ceramic powder;
Include the raw material of following weight fraction:Filmogen 80-95%, the material 1-10% that far infrared electromagnetic can be radiated and
Nano-antibacterial deodorizing material 1-10%;
Raw material is poured into stirring and mixing in agitator tank, dispersion, then is fully ground dispersion, temperature of charge is no more than 40 DEG C, detection material
Slurry, makes its viscosity be 20-70pa.s, degree of polymerization 1000-2000, and 3D printing system printing, heat-shaping or micro- is then added
Wave is molded, and control temperature is no more than 160 DEG C, and washing, drying, drying temperature are no more than 80 DEG C, and test package obtains product.
2. 3D printing elastic biological far-infrared anti-biotic deodorization underwear according to claim 1, it is characterised in that:Filmogen
For silica gel, gel, latex, PTFE, PLA, PVC or TPE.
3. 3D printing elastic biological far-infrared anti-biotic deodorization underwear according to claim 1, it is characterised in that:Nano-antibacterial
Deodoring materials be nano-silver ionic, nanometer copper ion, nanometer zinc ion, nano-titanium dioxide or one kind in nano-negative ion or
It is a variety of.
4. 3D printing elastic biological far-infrared anti-biotic deodorization underwear according to claim 1, it is characterised in that:Further include helping
Agent, auxiliary agent are one or more in nano-graphene, anion nanometer powder, nanometer selenium powder or Chinese medicine preparation.
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CN107021724A (en) * | 2017-04-10 | 2017-08-08 | 深圳市米兰达生物科技有限公司 | A kind of graphene far infrared ceramic powder silica gel material |
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CN108552629A (en) * | 2018-05-13 | 2018-09-21 | 腾飞科技股份有限公司 | The preparation process of 3D printing brassiere |
CN109537087A (en) * | 2018-08-14 | 2019-03-29 | 岑锴林 | Far-infrared functional master batch, far-infrared polyester fiber and preparation method, application |
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