Mask
Technical Field
The utility model relates to a health protection articles for use field, concretely relates to gauze mask with antibacterial skin care function adjusts temperature.
Background
The rapid development of industrial civilization has caused more and more environmental problems, such as global warming and air quality deterioration. Due to global warming, thawing of plateau glaciers and polar glaciers, many frozen ancient viruses and microorganisms are gradually released, and with the increasing decline of air quality, the viruses and microorganisms can cause a plurality of epidemic diseases, which is a great threat to more and more people on the earth.
With the increase of human safety awareness, people usually wear a mask to protect themselves in order to cope with the increasingly poor air quality and epidemic diseases. The existing masks in the market are full of various types of masks, and the types of the masks can be divided into a disposable half mask, a replaceable half mask and a full mask according to the national standard definition. Each mask, however, suffers from a number of deficiencies. The protective capability of a plurality of disposable masks is not enough, and the disposable using method causes great waste of material resources. The filtering efficiency of the masks KN90 and KN95 specified in the national standard needs to be respectively more than 90.0% and 95.0%, the requirement ensures effective interception of haze pollutants, but for most filter materials, the higher the filtering efficiency is, the larger the breathing resistance is, the more uncomfortable breathing of a wearer is, and the more serious the breathing uncomfortable breathing of the wearer is, and the skin problem is caused after the mask is used for a long time. At present, most masks do not have the temperature regulation capability, the bacteriostasis capability and the skin care capability, so that the mask has great theoretical significance and application value for endowing the traditional masks with the functions of temperature regulation, bacteriostasis and skin care.
The electrostatic spinning is to charge the high molecular solution or melt, place the charged solution or melt in a high-voltage electric field between a spinning nozzle and a receiving screen, overcome the surface tension of the high molecular solution or melt through electrostatic attraction, so that the spinning solution becomes a charged jet flow, moves in the electric field, and finally gathers on a metal reticular receiving screen to become a non-woven fabric-shaped fiber felt, and the high molecular solution or melt is solidified due to the evaporation of a solvent or the cooling of the melt, so that the nano-fiber non-woven fabric is formed. The filtering membrane prepared by the electrostatic spinning nano-fiber has the advantages of small diameter (generally dozens to hundreds of nanometers), high specific surface area, high filtering efficiency, low air resistance and the like. Compared with the conventional fiber filtering membrane, the filtering efficiency of the nanofiber filtering membrane with the same mass can be improved by 70%. The density of the traditional filtering membrane is reported to be 39g/m2The density of the PEO filtering membrane prepared by the electrostatic spinning technology can reach 3g/m2Can filter particles with the size of about 100 nm. In addition, it is shown that the smaller the diameter of the nanofiber, the higher the filtration efficiency, and the diameter distribution of the fiber is closely related to the filtration efficiency of the membrane. And currently most of PThe M2.5 mask adopts electret meltblown cloth to prepare an efficient filter layer, adopts a corona discharge mode to enable common meltblown cloth to have charges so as to improve the trapping and filtering of particles, and along with the enrichment of the particles and the change of temperature, the electret effect is obviously reduced, so that the protective capability of the mask is sharply reduced. The non-woven fabric prepared by electrostatic spinning has certain static electricity and good charge stability, so that an additional electret effect is not needed, and the operation is simple, convenient and fast.
The capsule is a tiny 'container' with a core-shell structure, is used for protecting or controlling release of capsule core substances, shielding odor and the like, realizes permanent solidification of the capsule core substances, and facilitates use, storage and transportation of the capsule core substances. The particle size can be classified into: nano capsules with the particle size of less than 1 mu m, microcapsules with the particle size of 1-1000 mu m and macrocapsules with the particle size of more than 1 mm. The composite material has wide application in the fields of aerospace, construction, environmental protection, textile and clothing, medical and health, electronic device cooling, military camouflage and the like.
In recent years, many patents have been made on the improvement of antibacterial ability of masks. The Chinese patent CN201610444058.4 takes the prepared Fe3+, N codoped titanium dioxide and biomass high polymer micro/nano fiber microporous membrane as a mask base material, and prepares the mask which can effectively block PM2.5 and has the effects of resisting bacteria and efficiently treating organic pollutants. Chinese patent CN201610012431.9 adopts nano silver particles as an antibacterial layer, and adopts an electro-spraying method to spray nano silver ions onto the spunbonded fabric of the non-woven fabric layer, so that the mask has a certain antibacterial ability, but the nano silver ion antibacterial agent is only attached to the surface of the mask, and does not form a chemical bond, and the combination is relatively unstable, and on the other hand, the nano silver ions have certain migration toxicity, which is not beneficial to human health in the using process. JP2016056481A discloses that organic acid cyanoacrylate polymer particles are added to the surface or inside of a fiber to provide the fiber with antibacterial ability, but the cyano group in the cyanoacrylate polymer has a certain toxicity, and the acrylic group has a certain peculiar smell to exert a certain influence on the human body. Japanese patent JP5885917B2 discloses that metal phthalocyanine and metal ammonia complex are loaded on the fiber, so that the fiber has certain antibacterial performance. The above patent methods are only used for preparing masks with a single bacteriostatic function, and masks with bacteriostatic function, temperature regulating function and skin care function are rarely reported.
Disclosure of Invention
For solving the above-mentioned problem, to prior art not enough, the utility model provides a gauze mask that has antibacterial function, function and the skin care function of adjusting the temperature simultaneously. The in-process of preparing this utility model combines electrostatic spinning technique and microcapsule technique organically, makes this utility model frivolous soft and antibacterial property is excellent, temperature regulating property is stable, skin care function is showing when having certain mechanical properties, and is light comfortable when wearing, greatly reduced respiratory resistance and filtration performance excellent, great using value and wide market prospect have.
The utility model discloses the gauze mask of preparing contains gauze mask area, nose clip, gauze mask main part, and characterized by gauze mask main part structure is divided into hydrophobic top layer, intermediate level, antibacterial skin care nanofiber layer by outer to interior in proper order, and wherein the intermediate level comprises antibacterial nanofiber layer, support fibrous layer, the combination of temperature regulation nanofiber layer. The antibacterial nanofiber layer, the temperature-adjusting nanofiber layer and the antibacterial skin-care nanofiber layer are prepared and molded by adopting an electrostatic spinning technology, and are integrally connected with the hydrophobic surface layer and the supporting layer through ultrasonic welding, hot-pressing compounding or gluing.
The utility model discloses the concrete step of preparation gauze mask is as follows:
(1) preparing a bacteriostatic microcapsule dispersion liquid: adding 1-80 parts of bacteriostatic agent into 1-100 parts of dispersing agent, and stirring at a high speed of 5-90 ℃ for 3-120 min to form a microcapsule core material; dissolving 2-160 parts of antibacterial microcapsule wall material in a dispersing agent at 10-90 ℃, and uniformly stirring; dissolving 0.2-50 parts of surfactant in distilled water at 10-90 ℃, and uniformly stirring; mixing and stirring the three solutions uniformly, and carrying out shearing emulsification for 2-120 min at a shearing rate of 100-30000 rmp; and (3) homogenizing the sheared and emulsified mixed solution for 2-60 min at high pressure by a high-pressure homogenizer of 10-70 Mpa, transferring the mixed solution into a flask, reacting for 1-24 h at the temperature of 5-90 ℃, adjusting the pH value of the solution, and performing ultrasonic dispersion to prepare the antibacterial microcapsule dispersion liquid with the antibacterial function.
(2) Preparing a temperature-regulating microcapsule dispersion liquid: dissolving 2-240 parts of temperature-adjusting microcapsule wall material in a dispersing agent at 10-90 ℃, and uniformly stirring; adding 0.2-50 parts of surfactant and 1-80 parts of phase change material into the mixture, and then stirring the mixture at a high speed for 3-120 min at the temperature of 5-90 ℃; uniformly mixing and stirring the solution, and carrying out shearing emulsification for 2-120 min at a shearing rate of 100-30000 rmp; and then transferring the emulsion after shearing and emulsification into a flask to react for 1-24 h at the temperature of 5-190 ℃, adjusting the pH value of the solution, and performing ultrasonic dispersion to prepare the phase-change microcapsule dispersion liquid with the temperature adjusting function.
(3) Preparing a skin care microcapsule dispersion liquid: dissolving 2-240 parts of the skin-care microcapsule wall material in a dispersing agent at 10-90 ℃, and uniformly stirring; adding 0.2-50 parts of surfactant and 1-80 parts of skin care material into the mixture, and then stirring the mixture at a high speed for 3-120 min at the temperature of 5-90 ℃; uniformly mixing and stirring the solution, and carrying out shearing emulsification for 2-120 min at a shearing rate of 100-30000 rmp; and (3) homogenizing the sheared and emulsified mixed solution for 3-90 min at high pressure by a high-pressure homogenizer of 20-70 Mpa. And then transferring the emulsion after shearing and emulsification into a flask to react for 1-24 h at the temperature of 5-190 ℃, adjusting the pH value of the solution, and performing ultrasonic dispersion to prepare the skin-care microcapsule dispersion liquid with the skin-care function.
(4) Preparing a bacteriostatic nanofiber layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1) with spinning stock solution according to a certain proportion, and carrying out high-speed shearing emulsification, filtration and vacuum defoaming on the mixture, and then carrying out electrostatic spinning on the mixture to obtain the antibacterial nanofiber layer containing the antibacterial microcapsules.
(5) Preparing a temperature-adjusting nanofiber layer: and (3) mixing the temperature-regulating microcapsule dispersion liquid prepared in the step (2) with spinning stock solution according to a certain proportion, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning to obtain the temperature-regulating nanofiber layer containing the temperature-regulating microcapsules.
(6) Preparing a skin-care bacteriostatic nanofiber layer: and (3) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1), the skin care microcapsule dispersion liquid prepared in the step (3) and the spinning stock solution according to a certain proportion, and carrying out high-speed shearing emulsification, filtration and vacuum defoaming on the mixture, and then carrying out electrostatic spinning on the mixture to obtain the skin care antibacterial nanofiber layer containing the antibacterial microcapsules and the skin care microcapsules.
(7) And (3) compounding and combining the antibacterial nanofiber layer, the temperature-regulating nanofiber layer and the skin-care antibacterial nanofiber layer prepared in the steps (4), (5) and (6), with the hydrophobic surface layer and the support layer, wherein the hydrophobic surface layer, the antibacterial nanofiber layer, the support layer, the temperature-regulating nanofiber layer and the antibacterial skin-care nanofiber layer are sequentially arranged from outside to inside, and the skin-care antibacterial nanofiber layer is positioned on the innermost layer contacting the skin.
(8) And (4) carrying out 3D cutting on the mask main body prepared in the step (7) according to the prior art, and connecting a mask belt and a nose clip.
The capsule wall material of the antibacterial microcapsule is at least one of chitosan, chitosan ammonium chloride, carboxymethyl chitosan, nano cellulose, methyl vitamin, hydroxymethyl cellulose, sodium carboxymethyl cellulose, cellulose nitrate, maltodextrin, cyclodextrin, corn syrup, starch, sucrose, lactose, pectin, sodium alginate, carrageenan, arabic gum, gelatin, soybean protein, hemoglobin, casein, whey protein, beeswax, paraffin, grease, liposome, polyurea, polyamide, polystyrene, amino resin, urea-formaldehyde resin, phenolic resin, epoxy resin, polyurethane, polyacrylate and polyvinyl alcohol.
The antibacterial microcapsule core material is at least one of nano silver, nano zinc, chlorhexidine gluconate, xanthorrhizol, ethyl vanillin, acylaniline, hinokitiol, imidazole, sorbic acid, vanillin, thiazoles, isothiazolinone derivatives, biguanidine, dodecyl ethoxy sulfobetaine and tetradecyl methyl dihydroxy ethyl ammonium bromide.
The capsule wall material of the temperature-regulating microcapsule is at least one of urea-formaldehyde resin, phenolic resin, melamine formaldehyde resin, methyl etherified melamine formaldehyde resin, butyl etherified melamine formaldehyde resin, polyurethane and prepolymer thereof, polymethyl methacrylate, chitosan, sodium alginate, cellulose acetate, gelatin and acacia.
The temperature-regulating microcapsule core material is at least one of paraffin, carboxylic acid, carboxylic ester, polyalcohol, n-alkyl alcohol, sugar alcohol and polyether.
The surfactant is any one or a mixture of any several of polyvinyl alcohol, polyvinylpyrrolidone, sorbitan oleate, an emulsifier OP10, fatty alcohol-polyoxyethylene ether sodium sulfate, a styrene maleic anhydride copolymer, fatty alcohol-polyoxyethylene ether, Turkey red oil, sodium alkyl benzene sulfonate, sodium dodecyl sulfate, propylene alginate, polyoxyethylene sorbitan monooleate, sodium alkyl sulfate or nekal in any ratio.
The phase transition temperature of the temperature-adjusting microcapsule is 25-40 ℃.
The capsule wall material of the skin-care microcapsule is at least one of chitosan, chitosan ammonium chloride, carboxymethyl chitosan, nano cellulose, polyvinyl alcohol, starch, maltodextrin, gelatin, Arabic gum, soybean protein and collagen.
The skin-care microcapsule core material is at least one of essential oil, vitamins, amino acids and proteins.
The particle size range of the capsule is 2 nm-20 mu m.
The solute in the spinning solution is at least one of cellulose acetate, nano-cellulose, cellulose polymer, cellulose acetate-butyrate, cellulose propionate, ethyl cellulose, methyl cellulose, carboxymethyl cellulose, hydroxyethyl cellulose, nitrocellulose, polyacrylonitrile, polyurethane, polystyrene, nylon 6, nylon 66, silk fibroin, fibrinogen, zein, soybean protein isolate, wheat protein, whey protein, gelatin, chitosan, dextran, hyaluronic acid, sodium alginate, soybean polysaccharide, pectin, xanthan gum, carrageenan and polyvinyl alcohol.
The solvent in the spinning solution is at least one of N, N-dimethylformamide, N-dimethylacetamide, acetone, formic acid, acetic acid, ethanol and distilled water.
The mass ratio of the microcapsule dispersion liquid to the spinning solution is 1: 9-7: 3.
The electrostatic spinning process parameters are as follows: the voltage is 10 KV-40 KV, the flow rate is 0.1 mL/h-10 mL/h, the receiving distance is 5 cm-30 cm, and the rotating speed of the receiving hub is 10 rpm-1000 rpm.
The hydrophobic surface layer is at least one of terylene, chinlon, spandex, polypropylene fiber, polyvinyl chloride fiber, acrylic fiber and spun-bonded non-woven fabric.
The supporting layer is at least one of terylene, chinlon, spandex, polypropylene fiber, polyvinyl chloride fiber, acrylic fiber, spun bond, viscose, silk, wool and cotton non-woven fabrics.
The prepared antibacterial nanofiber layer, the temperature-adjusting nanofiber layer and the skin-protecting antibacterial nanofiber layer can be compounded with the hydrophobic surface layer and the supporting layer according to actual needs in multiple layers, so that masks with different layers can be prepared in a combined mode, and the mask is suitable for multiple fields. The hydrophobic surface layer can isolate the penetration of liquid such as spray, body fluid and the like, and the supporting layer provides certain mechanical strength for the mask main body. Because the nanofiber layer thickness that electrostatic spinning prepared is thinner, even multilayer nanofiber layer and hydrophobic top layer, supporting layer combination are superimposed and are constituteed the gauze mask together, can not appear great breathing resistance when wearing yet, and the temperature regulating effect of phase transition microcapsule in the gauze mask in addition can the effective control temperature in the gauze mask, very big reduction the sense of suffocating. In addition, the pore diameter of the nanofiber layer prepared by electrostatic spinning is smaller and about 10 nm-20 microns, most of particulate matters and bacteria and viruses can be prevented and isolated, and the antibacterial microcapsules in the electrostatic spinning can kill the bacteria and viruses intercepted by the antibacterial microcapsules, so that the mask can be repeatedly utilized; the skin care substance in the skin care microcapsule can be gradually released to the facial skin when the mask is worn, so that the effect of moistening the skin is achieved, and the facial skin can still keep healthy even if the mask is worn for a long time.
Drawings
The present invention will be further explained with reference to the accompanying drawings.
Fig. 1 is a schematic cross-sectional structure of a mask body prepared in example 1.
In the figure, 1 is a hydrophobic surface layer, 2 is an intermediate layer, and 3 is a skin-care bacteriostatic nanofiber layer.
The hydrophobic surface layer 1 is at least one of terylene, chinlon, spandex, polypropylene fiber, polyvinyl chloride fiber, acrylic fiber and spun-bonded non-woven fabric.
The middle layer 2 is formed by combining a bacteriostatic nanofiber layer, a supporting fiber layer and a temperature-adjusting nanofiber layer, and at least one layer is formed by each layer.
The supporting fiber layer is at least one of terylene, chinlon, spandex, polypropylene fiber, polyvinyl chloride fiber, acrylic fiber, spun bond, viscose, silk, wool and cotton non-woven fabrics.
The skin-care bacteriostatic nanofiber layer 3 is positioned on the innermost layer contacting the skin.
Detailed Description
The structure and the manufacturing method of the present invention will be further described by the following specific examples, but the present invention is not limited to these examples.
Example 1:
the preparation method and the structure of the mask are connected as follows:
(1) preparing a bacteriostatic microcapsule dispersion liquid: adding 40 parts of bacteriostatic agent thiazole into 50 parts of dispersing agent ether, and stirring at a high speed at 47 ℃ for 60min to form a microcapsule core material; dissolving 90 parts of antibacterial microcapsule wall material chitosan quaternary ammonium salt in a dispersant aqueous solution at 50 ℃, and uniformly stirring; dissolving 25 parts of surfactant sodium dodecyl sulfate in distilled water at 50 ℃, and uniformly stirring; mixing and stirring the three solutions uniformly, and carrying out shearing emulsification for 60min at the shearing rate of 15000 rmp; homogenizing the sheared and emulsified mixed solution for 30min at high pressure by a high-pressure homogenizer of 40Mpa, then transferring the mixed solution into a flask to react for 12h at the temperature of 50 ℃, adjusting the pH value of the solution to 4.5, and performing ultrasonic dispersion for 20min to prepare the antibacterial microcapsule dispersion liquid with the antibacterial function.
(2) Preparing a temperature-regulating microcapsule dispersion liquid: dissolving 120 parts of temperature-regulating microcapsule capsule wall material gelatin in 50 ℃ dispersing agent water, and uniformly stirring; adding 25 parts of surfactant OP10 and 40 parts of phase change material octadecane, and stirring at 55 ℃ for 60 min; mixing and stirring the solution uniformly, and carrying out shearing emulsification for 60min at the shearing rate of 15000 rmp; and then transferring the emulsion after shearing and emulsification into a flask to react for 12 hours at the temperature of 50 ℃, adjusting the pH value of the solution to 8.5, and performing ultrasonic dispersion for 20 minutes to prepare the phase-change microcapsule dispersion liquid with the temperature adjusting function.
(3) Preparing a skin care microcapsule dispersion liquid: dissolving 120 parts of a skin-care microcapsule wall material Arabic gum in a dispersing agent at 50 ℃, and uniformly stirring; adding 25 parts of fatty alcohol-polyoxyethylene ether as surfactant and 40 parts of calendula oil as skin care material, and stirring at 60 deg.C for 60 min; mixing and stirring the solution uniformly, and carrying out shearing emulsification for 60min at the shearing rate of 15000 rmp; homogenizing the sheared and emulsified mixed solution for 50min at high pressure by a high-pressure homogenizer of 45 Mpa. And then transferring the emulsion after shearing and emulsification into a flask to react for 12 hours at the temperature of 70 ℃, adjusting the pH value of the solution to 7, and performing ultrasonic dispersion for 15 minutes to prepare the skin-care microcapsule dispersion liquid with the skin-care function.
(4) Preparing a bacteriostatic nanofiber layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1) with a spinning solution (5% of cellulose acetate as a solute, 5% of waterborne polyurethane and water as a solvent) according to a ratio of 5: 5, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning (the electrostatic spinning process parameters are 20KV, the flow rate is 5mL/h, the receiving distance is 19cm, and the rotating speed of a receiving hub is 500rpm) to obtain the antibacterial nanofiber layer containing the antibacterial microcapsules.
(5) Preparing a temperature-adjusting nanofiber layer: and (3) mixing the temperature-regulating microcapsule dispersion liquid prepared in the step (2) with a spinning solution (5% of cellulose acetate as a solute, 5% of waterborne polyurethane and water as a solvent) according to a ratio of 5: 5, and performing high-speed shearing emulsification, filtration and vacuum defoaming on the mixture, and then performing electrostatic spinning (the electrostatic spinning process parameters are 22KV, the flow rate is 6mL/h, the receiving distance is 17cm, and the rotating speed of a receiving hub is 460rpm) to obtain the temperature-regulating nanofiber layer containing the temperature-regulating microcapsules.
(6) Preparing a skin-care nanofiber antibacterial layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1), the skin-care microcapsule dispersion liquid prepared in the step (3) and a spinning solution (the solute is 5% of cellulose acetate, 5% of waterborne polyurethane and the solvent is water) according to the mass ratio of 2: 4, and carrying out high-speed shearing emulsification, filtration and vacuum defoaming on the mixture, and then carrying out electrostatic spinning (the electrostatic spinning process parameters are that the voltage is 25KV, the flow rate is 8mL/h, the receiving distance is 15cm and the rotating speed of a receiving hub is 390rpm) on the mixture to prepare the skin-care antibacterial nanofiber layer containing the antibacterial microcapsules and the skin-care microcapsules.
(7) Combining 2 layers of the bacteriostatic nanofiber layer, the temperature-regulating nanofiber layer and the skin-protecting bacteriostatic nanofiber layer prepared in the steps (4), (5) and (6) with a hydrophobic surface layer spun-bonded nonwoven fabric and a supporting layer polypropylene nonwoven fabric for use, wherein the combination mode is that the spun-bonded nonwoven fabric 1 layer, the bacteriostatic nanofiber layer 2 layer, the polypropylene nonwoven fabric 1 layer, the temperature-regulating nanofiber layer 2 layer and the bacteriostatic skin-protecting nanofiber layer 2 layer are sequentially arranged from outside to inside, and the skin-protecting bacteriostatic nanofiber layer is positioned on the innermost layer contacting the skin; the layers are then bonded together by ultrasonic welding to produce the outlet hood body.
(8) And (4) carrying out 3D cutting on the mask main body prepared in the step (7) according to the prior art, and connecting a mask belt and a nose clip.
The cross-sectional view of the main structure of the mask manufactured in this embodiment is shown in fig. 1, and the hydrophobic surface layer 1 is 1 layer of spun-bonded nonwoven fabric; the middle layer 2 consists of 2 bacteriostatic nanofiber layers, 1 polypropylene non-woven fabric supporting layer and 2 temperature-regulating nanofiber layers; the skin-protecting bacteriostatic nanofiber layer 3 is positioned on the innermost layer contacting the skin and consists of 2 layers of bacteriostatic skin-protecting nanofibers prepared by electrostatic spinning; the layers are then bonded together by ultrasonic welding.
Example 2:
the preparation method and the structure of the mask are connected as follows:
(1) preparing a bacteriostatic microcapsule dispersion liquid: adding 80 parts of bacteriostatic agent acylaniline into 100 parts of dispersing agent, and stirring at a high speed for 120min at 90 ℃ to form a microcapsule core material; 160 parts of antibacterial microcapsule wall material carboxymethyl chitosan is dissolved in a dispersant at 90 ℃, and is stirred uniformly; dissolving 50 parts of sorbitan oleate serving as a surfactant in distilled water at 90 ℃, and uniformly stirring; mixing and stirring the three solutions uniformly, and carrying out shearing emulsification for 120min at the shearing rate of 30000 rmp; homogenizing the sheared and emulsified mixed solution for 60min at high pressure by a high-pressure homogenizer of 70Mpa, then transferring the mixed solution into a flask to react for 24h at the temperature of 190 ℃, adjusting the pH value of the solution to 7.5, and dispersing the solution for 30min by ultrasound to prepare the antibacterial microcapsule dispersion liquid with the antibacterial function.
(2) Preparing a temperature-regulating microcapsule dispersion liquid: dissolving 240 parts of temperature-regulating microcapsule capsule wall material phenolic resin in a dispersant at 90 ℃, and uniformly stirring; adding 50 parts of surfactant styrene maleic anhydride and 80 parts of phase change material n-hexadecane, and stirring at 90 deg.C for 120 min; mixing and stirring the solution evenly, and carrying out shearing emulsification for 120min at the shearing rate of 30000 rmp; and then transferring the emulsion after shearing and emulsification into a flask to react for 24 hours at the temperature of 90 ℃, adjusting the pH of the solution to 5.5, and performing ultrasonic dispersion for 30 minutes to prepare the phase-change microcapsule dispersion liquid with the temperature adjusting function.
(3) Preparing a skin care microcapsule dispersion liquid: dissolving 240 parts of gelatin serving as a capsule wall material of the skin-care microcapsule in 90 ℃ dispersing agent water, and uniformly stirring; adding 50 parts of surfactant sodium dodecyl sulfate and 80 parts of skin care material vitamin E, and stirring at 90 deg.C for 120 min; mixing and stirring the solution evenly, and carrying out shearing emulsification for 120min at the shearing rate of 30000 rmp; homogenizing the sheared and emulsified mixed solution for 90min at high pressure by a high-pressure homogenizer of 70 Mpa. And then transferring the emulsion after shearing and emulsification into a flask to react for 24 hours at the temperature of 90 ℃, adjusting the pH value of the solution to be 5.6, and preparing the skin-care microcapsule dispersion liquid with the skin-care function after ultrasonic dispersion.
(4) Preparing a bacteriostatic nanofiber layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1) with a spinning solution (the solute is 7% of nano-cellulose, the solute is 3% of polyacrylonitrile, and the solvent is acetic acid) according to a ratio of 7: 3, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning (the voltage is 40KV, the flow rate is 10mL/h, the receiving distance is 30cm, and the rotating speed of a receiving hub is 1000rpm) to prepare the antibacterial nanofiber layer containing the antibacterial microcapsules.
(5) Preparing a temperature-adjusting nanofiber layer: and (3) mixing the temperature-regulating microcapsule dispersion liquid prepared in the step (2) with a spinning solution (the solute is 7% of nano-cellulose, the solute is 3% of polyacrylonitrile, and the solvent is acetic acid) according to a ratio of 7: 3, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning (the voltage is 38KV, the flow rate is 8mL/h, the receiving distance is 28cm, and the rotating speed of a receiving hub is 900rpm) to prepare the temperature-regulating nanofiber layer containing the temperature-regulating microcapsules.
(6) Preparing a skin-care bacteriostatic nanofiber layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1), the skin-care microcapsule dispersion liquid prepared in the step (3) and a spinning solution (with the solute being 7% of nano-cellulose, 3% of polyacrylonitrile and the solvent being acetic acid) according to a ratio of 2: 3: 5, carrying out high-speed shearing emulsification, filtration and vacuum defoaming, and then carrying out electrostatic spinning (with the voltage being 40KV, the flow rate being 9mL/h, the receiving distance being 27cm and the rotation speed of a receiving hub being 950rpm) to prepare the skin-care antibacterial nanofiber layer containing the antibacterial microcapsules and the skin-care microcapsules.
(7) Combining the 20 antibacterial nanofiber layers, the temperature-regulating nanofiber layer and the skin-protecting antibacterial nanofiber layer prepared in the steps (4), (5) and (6) with the hydrophobic surface layer polyester non-woven fabric and the supporting layer polyamide non-woven fabric for use, wherein the combination mode comprises 2 layers of the polyester non-woven fabric, 20 layers of the antibacterial nanofiber layer, 1 layer of the polyamide non-woven fabric, 20 layers of the temperature-regulating nanofiber layer and 20 layers of the antibacterial skin-protecting nanofiber layer in sequence from outside to inside, and the skin-protecting antibacterial nanofiber layer is positioned on the innermost layer contacting the skin; the layers are then bonded together by means of adhesive bonding to produce the outlet housing body.
(8) And (4) carrying out 3D cutting on the mask main body prepared in the step (7) according to the prior art, and connecting a mask belt and a nose clip.
The mask body structure produced in this example is as follows: the hydrophobic surface layer 1 is 2 layers of polyester non-woven fabrics; the middle layer 2 consists of 20 bacteriostatic nanofiber layers, 1 nylon non-woven fabric support layer and 20 temperature-regulating nanofiber layers; the skin-care bacteriostatic nanofiber layer 3 is positioned on the innermost layer contacting the skin and consists of 20 layers of bacteriostatic skin-care nanofibers prepared by electrostatic spinning; the layers are then bonded together by means of adhesive bonding.
Example 3:
the preparation method and the structure of the mask are connected as follows:
(1) preparing a bacteriostatic microcapsule dispersion liquid: adding 1 part of bacteriostatic isothiazolone into 1 part of dispersant, and stirring at a high speed of 5 ℃ for 3min to form a microcapsule core material; dissolving 2 parts of antibacterial microcapsule wall material carboxymethyl chitosan in 10 parts of dispersing agent, and uniformly stirring; dissolving 0.2 part of surfactant polyvinylpyrrolidone in distilled water at 10 ℃, and uniformly stirring; mixing and stirring the three solutions uniformly, and carrying out shearing emulsification for 2min at a shearing rate of 1000 rmp; homogenizing the sheared and emulsified mixed solution for 2min at high pressure by a high-pressure homogenizer of 10Mpa, transferring the mixed solution into a flask, reacting for 1h at the temperature of 5 ℃, adjusting the pH value of the solution to 6.5, and performing ultrasonic dispersion for 10min to prepare the antibacterial microcapsule dispersion liquid with the antibacterial function.
(2) Preparing a temperature-regulating microcapsule dispersion liquid: dissolving 2 parts of temperature-regulating microcapsule capsule wall material urea-formaldehyde resin in a 10 ℃ dispersing agent, and uniformly stirring; adding 0.2 part of surfactant propylene alginate and 1 part of phase-change material octadecyl acrylate into the solution, and stirring at 5 deg.C for 3 min; mixing the above solutions, stirring, and shearing and emulsifying at a shear rate of 100rmp for 2 min; and then transferring the emulsion after shearing and emulsification into a flask to react for 1h at the temperature of 5 ℃, adjusting the pH of the solution to 7.5, and performing ultrasonic dispersion for 10min to prepare the phase-change microcapsule dispersion liquid with the temperature adjusting function.
(3) Preparing a skin care microcapsule dispersion liquid: dissolving 2 parts of skin-care microcapsule wall material maltodextrin in a dispersing agent at 10 ℃, and uniformly stirring; adding 0.2 part of surfactant sodium alcohol ether sulfate and 1 part of skin care material lemon essential oil, and stirring at 5 deg.C for 3 min; mixing the above solutions, stirring, and shearing and emulsifying at a shear rate of 100rmp for 2 min; homogenizing the sheared and emulsified mixed solution for 3min at high pressure by a high-pressure homogenizer of 20 Mpa. And then transferring the emulsion after shearing and emulsification into a flask to react for 1h at the temperature of 5 ℃, adjusting the pH of the solution to 5.0, and performing ultrasonic dispersion for 10min to prepare the skin-care microcapsule dispersion liquid with the skin-care function.
(4) Preparing a bacteriostatic nanofiber layer: mixing the antibacterial microcapsule dispersion liquid prepared in the step (1) with a spinning solution (solute is 5% of nano-cellulose, 5% of silk fibroin, and solvent is acetic acid) according to a ratio of 1: 9, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning (voltage is 10KV, flow rate is 0.1mL/h, receiving distance is 5cm, and rotating speed of a receiving hub is 10rpm) to prepare the antibacterial nanofiber layer containing the antibacterial microcapsules.
(5) Preparing a temperature-adjusting nanofiber layer: and (3) mixing the temperature-regulating microcapsule dispersion liquid prepared in the step (2) with a spinning solution (the solute is 5% of nano-cellulose, the solute is 5% of silk fibroin, and the solvent is acetic acid) according to a ratio of 1: 9, and carrying out high-speed shearing emulsification, filtration and vacuum defoaming on the mixture, and then carrying out electrostatic spinning (the voltage is 10KV, the flow rate is 0.1mL/h, the receiving distance is 5cm, and the rotating speed of a receiving hub is 10rpm) on the mixture to prepare the temperature-regulating nano-fiber layer containing the temperature-regulating microcapsules.
(6) Preparing a skin-care bacteriostatic nanofiber layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1), the skin-care microcapsule dispersion liquid prepared in the step (3) and a spinning solution (the solute is 5% of nano-cellulose, 5% of silk fibroin and the solvent is acetic acid) according to a ratio of 3: 4, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning (the voltage is 10KV, the flow rate is 0.1mL/h, the receiving distance is 5cm, and the rotating speed of a receiving hub is 10rpm) to prepare the skin-care antibacterial nanofiber layer containing the antibacterial microcapsules and the skin-care microcapsules.
(7) Combining 10 layers of the bacteriostatic nanofiber layer, the temperature-regulating nanofiber layer and the skin-care bacteriostatic nanofiber layer prepared in the steps (4), (5) and (6) with a hydrophobic surface layer spandex non-woven fabric and a supporting layer cotton non-woven fabric for use, wherein the combination mode comprises 2 layers of spandex non-woven fabric, 10 layers of bacteriostatic nanofiber layer, 1 layer of cotton non-woven fabric, 10 layers of temperature-regulating nanofiber layer and 10 layers of bacteriostatic skin-care nanofiber layer from outside to inside in sequence, and the skin-care bacteriostatic nanofiber layer is positioned on the innermost layer contacting with the skin; the layers are then bonded together using a hot press to produce the outlet cover body.
(8) And (4) carrying out 3D cutting on the mask main body prepared in the step (7) according to the prior art, and connecting a mask belt and a nose clip.
The mask body structure produced in this example is as follows: the hydrophobic surface layer 1 is 2 layers of spandex non-woven fabrics; the middle layer 2 consists of 10 bacteriostatic nanofiber layers, 1 cotton non-woven fabric supporting layer and 10 temperature-regulating nanofiber layers; the skin-protecting bacteriostatic nanofiber layer 3 is positioned on the innermost layer contacting the skin and consists of 10 layers of bacteriostatic skin-protecting nanofibers prepared by electrostatic spinning; the layers are then bonded together by means of a hot press.
Example 4:
the preparation method and the structure of the mask are connected as follows:
(1) preparing a bacteriostatic microcapsule dispersion liquid: adding 25 parts of bacteriostatic agent tetradecyl methyl dihydroxyethyl ammonium bromide into 30 parts of dispersing agent, and stirring at a high speed at 27 ℃ for 40min to form a microcapsule core material; dissolving 50 parts of antibacterial microcapsule wall material chitosan in a dispersant at 30 ℃, and uniformly stirring; dissolving 15 parts of surfactant sodium dodecyl sulfate in distilled water at 30 ℃, and uniformly stirring; mixing the three solutions, stirring uniformly, and performing shearing emulsification at a shearing rate of 10000rmp for 40 min; homogenizing the sheared and emulsified mixed solution for 20min at high pressure by a high-pressure homogenizer of 20Mpa, transferring the mixed solution into a flask, reacting for 8h at the temperature of 30 ℃, adjusting the pH value of the solution to 4.5, and performing ultrasonic dispersion for 20min to prepare the antibacterial microcapsule dispersion liquid with the antibacterial function.
(2) Preparing a temperature-regulating microcapsule dispersion liquid: 70 parts of temperature-regulating microcapsule capsule wall material amino resin is dissolved in a dispersant at 30 ℃ and is stirred uniformly; adding 15 parts of surfactant SMA and 25 parts of phase-change material acrylate into the mixture, and then stirring the mixture at a high speed for 40min at the temperature of 30 ℃; mixing the above solutions, stirring, and shearing and emulsifying at a shear rate of 10000rmp for 40 min; and then transferring the emulsion after shearing and emulsification into a flask to react for 8 hours at the temperature of 30 ℃, adjusting the pH of the solution to be 7.5, and preparing the phase-change microcapsule dispersion liquid with the temperature adjusting function after ultrasonic dispersion.
(3) Preparing a skin care microcapsule dispersion liquid: dissolving 70 parts of a mixture of arabic gum and gelatin which are capsule wall materials of the skin-care microcapsules in a dispersing agent at 30 ℃, and uniformly stirring; adding 15 parts of surfactant zipper powder and 25 parts of skin care material rose essential oil, and stirring at high speed at 30 deg.C for 40 min; mixing the above solutions, stirring, and shearing and emulsifying at a shear rate of 10000rmp for 40 min; homogenizing the sheared and emulsified mixed solution for 30min at high pressure by a high-pressure homogenizer of 25 Mpa. And then transferring the emulsion after shearing and emulsification into a flask to react for 9 hours at the temperature of 30 ℃, adjusting the pH of the solution to 5.5, and performing ultrasonic dispersion for 20 minutes to prepare the skin-care microcapsule dispersion liquid with the skin-care function.
(4) Preparing a bacteriostatic nanofiber layer: mixing the antibacterial microcapsule dispersion liquid (6% of ethyl cellulose as solute, 4% of chitosan and formic acid as solvent) prepared in the step (1) with spinning solution according to a ratio of 6: 4, and performing high-speed shearing emulsification, filtration and vacuum defoamation, and then performing electrostatic spinning (with the voltage of 26KV, the flow rate of 5mL/h, the receiving distance of 15cm and the rotation speed of a receiving hub of 555rpm) to prepare the antibacterial nanofiber layer containing the antibacterial microcapsules.
(5) Preparing a temperature-adjusting nanofiber layer: and (3) mixing the temperature-regulating microcapsule dispersion liquid prepared in the step (2) with a spinning solution (6% of ethyl cellulose as a solute, 4% of chitosan as a solvent and formic acid) according to a ratio of 6: 4, and performing high-speed shearing emulsification, filtration and vacuum defoaming on the mixture, and then performing electrostatic spinning (29 KV voltage, 6mL/h of flow rate, 16cm of receiving distance and 625rpm of receiving hub) to obtain the temperature-regulating nanofiber layer containing the temperature-regulating microcapsules.
(6) Preparing a skin-care bacteriostatic nanofiber layer: and (2) mixing the antibacterial microcapsule dispersion liquid prepared in the step (1), the skin-care microcapsule dispersion liquid prepared in the step (3) and a spinning solution (the solute is 6% of ethyl cellulose, 4% of chitosan and the solvent is formic acid) according to the ratio of 2: 5: 3, and performing high-speed shearing emulsification, filtration and vacuum defoaming, and then performing electrostatic spinning (the voltage is 22KV, the flow rate is 7mL/h, the receiving distance is 17cm, and the rotating speed of a receiving hub is 750rpm) to prepare the skin-care antibacterial nanofiber layer containing the antibacterial microcapsules and the skin-care microcapsules.
(7) Combining 50 layers of the bacteriostatic nanofiber layer, the temperature-regulating nanofiber layer and the skin-care bacteriostatic nanofiber layer prepared in the steps (4), (5) and (6) with a hydrophobic surface layer polyester non-woven fabric and a supporting layer non-woven fabric for use, wherein the combining mode is that 1 layer of a polyvinyl chloride fiber non-woven fabric, 20 layers of the bacteriostatic nanofiber layer, 2 layers of an acrylic non-woven fabric, 50 layers of the temperature-regulating nanofiber layer and 30 layers of the bacteriostatic skin-care nanofiber layer are sequentially arranged from outside to inside, and the skin-care bacteriostatic nanofiber layer is positioned on the innermost layer contacting with the skin; the layers are then bonded together using a hot press to produce the outlet cover body.
(8) And (4) carrying out 3D cutting on the mask main body prepared in the step (7) according to the prior art, and connecting a mask belt and a nose clip.
The mask body structure produced in this example is as follows: the hydrophobic surface layer 1 is 1 layer of polyvinyl chloride fiber non-woven fabric; the middle layer 2 consists of 20 bacteriostatic nanofiber layers, 2 acrylic non-woven fabric support layers and 50 temperature-regulating nanofiber layers; the skin-care bacteriostatic nanofiber layer 3 is positioned on the innermost layer contacting the skin and consists of 30 layers of bacteriostatic skin-care nanofibers prepared by electrostatic spinning; the layers are then bonded together by means of a hot press.
The mask is simple in structure, can be implemented in various modes, is stable in bacteriostatic performance, temperature adjusting performance and skin care performance, is excellent in mechanical property, has a wide application prospect, and is suitable for industrial application. The mask has good antibacterial ability, temperature regulating ability and skin care ability while maintaining good protection function, and is safe to use and wide in application.
The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.