KR100539685B1 - Thermo-regulating micro-capsule having antibacterial and curing function and method for producing the same - Google Patents

Abstract

The present invention relates to a regenerative composite microcapsule having a natural antibacterial and healing function and a method of manufacturing the same, and to emulsifying a phase change material (PCM) to form an inner capsule and adding an initial melanin condensate to the capsule. Enclosing the capsule to form an outer portion of the capsule, adding a predetermined amount of silver nanoparticles to the polymer membrane on the outer surface of the capsule before the capsule is cured, and adding a crosslinking agent and a curing agent of the used polymer material. It consists of a process that terminates the reaction at room temperature, so that the microcapsules have a heat storage function, an antibacterial and a healing function at the same time, and when applied to a product, there is an advantage of being possible with one treatment unlike when the effect is obtained by each separate process. .

Microcapsules, phase change material, silver nanoparticles, heat storage, antibacterial

Description

Regenerative complex microcapsules with natural antibacterial and healing function and preparation method thereof {THERMO-REGULATING MICRO-CAPSULE HAVING ANTIBACTERIAL AND CURING FUNCTION AND METHOD FOR PRODUCING THE SAME}             

1 is a partial cross-sectional perspective view of a heat storage composite microcapsules coated with silver nanoparticles of the present invention.

Figure 2 is a particle analysis graph showing the size of the silver nanoparticles prepared by the present invention.

Figure 3 is a differential scanning sequence analysis graph of the heat storage microcapsules prepared by the present invention.

<Description of the symbols for the main parts of the drawings>

10: microcapsules 11: capsule inner layer

12: capsule outer layer 13: capsule epidermal layer

The present invention relates to a regenerative composite microcapsule having a natural antibacterial and healing function, and a method of manufacturing the same. More specifically, the regenerative composite is conventionally prepared by coating silver particles on the outer walls of various regenerative composite microcapsules in the form of ultrafine nanoparticles. In addition to the function of the microcapsules, the present invention relates to a heat-retaining composite microcapsule coated with silver nanoparticles capable of imparting unique natural antibacterial and healing functions, and a method of manufacturing the same.

Recently, as interest in regenerative functional materials has increased, attempts to apply microcapsules to various fields have been increasing. In addition, interest and importance in the field of nanoparticles are increasing day by day.

In general, as a method of improving the thermal insulation of the textile products, it is recognized only to use the thermal insulation effect by the insulation, but the more recently developed thermal insulation material has been proposed a more active method depending on the material used. Heat transfer related to the thermal insulation of textile products is basically conducted by conduction, convection and radiation. As a method of improving heat retention, the use of ultra-fine fabrics and hollow fiber is used to increase the content of air with low thermal conductivity, thereby reducing heat transfer due to conduction and convection or high heat reflectance on the surface of the fabric. Thermal insulation can be improved by applying a layer to reduce heat transfer by radiation.

In addition, in recent years, a method of improving heat retention by using far-infrared radiation ceramics has been developed in addition to a method of controlling heat transfer to improve heat retention. Far-infrared ceramics, which are generally applied to textile products, are opaque and have almost no light passing, and some reflect and some absorb and re-radiate.

In addition, the most frequent contact with the human body in the human living environment is fiber products. As the frequency of use of products increases, odors are generated by microorganisms or secretions of the human body, which causes discoloration, contamination and damage of textile products. It can also be a cause. For this reason, antimicrobial function is given to textile products to suppress the growth and proliferation of microorganisms to prevent infectious diseases, odor prevention, fiber contamination, discoloration and embrittlement prevention. In other words, this processing can be said to improve human health and sanitary living environment by improving the properties of microorganisms in textile products and suppressing the breeding and reproduction of bacteria and fungi on the fibers.

Commonly used antimicrobial processing methods include post-treatment methods that adhere to the surface of fibers or fabrics. Examples of the antimicrobial agents are inorganic metals, organometallics, quaternary ammonium salts, amphoteric and nonionic surfactants, and alcohols. , Nitrile series, iodine series, fluorine series and the like. In particular, almost all of the inorganic metal processing agents use silver (Ag). Silver has long been used as a natural antibiotic in the medical community, and its effects have been shown to be free of any side effects, comparable to synthetically manufactured phosphorus agents. In addition, since it completely absorbs and blocks harmful waves such as electromagnetic waves and water waves, it can improve health by providing an opportunity to easily encounter silver (Ag) in the surroundings.

On the other hand, when the content of silver (Ag) in the human body falls below the standard (0.0001%), it is known that the probability of disease increases.In order to contain a large amount of silver (Ag) in the body to increase the body's immunity, It is reported that a lot of vegetables that are rooted and eaten are not only sterilized by the cold virus by the silver ions emitted by Ag, but also by the silver ions penetrating the body to fight off germs.

In order to solve the above problems, an object of the present invention is to coat the silver particles on the outer wall of various heat storage composite microcapsules in the form of ultra-fine nanoparticles in addition to the function of the conventional heat storage composite microcapsules inherent in nature It is to provide a heat storage complex microcapsules and a method of manufacturing the same to provide antibacterial and healing functions.

According to the present invention, a method for preparing a heat storage composite microcapsule having a natural antibacterial and healing function according to the present invention comprises the steps of preparing a distribution solution of silver nanoparticles to form an inner layer of a capsule by initial emulsification of a phase change material. Step to form a capsule outer layer by enclosing the initial melamine condensate to the capsule inner layer, and before the capsule outer layer is cured by adding a certain amount of the distribution of silver nanoparticles fixed to the polymer membrane outside the capsule outer layer Forming a capsule epidermal layer, adding a crosslinking agent and a curing agent of the used polymer material to cure the capsule epidermal layer, and terminating the reaction by drying the filling solution containing the cured microcapsules at room temperature. Is done.

At this time, the method for preparing the silver nanoparticles distribution solution is prepared by first preparing a water-soluble polymer solution of styrene maleic anhydride and left at room temperature, and then passed through a filter to remove the granular tangled particles that may be generated in the mixing process In the step, adding the water-soluble polymer solution and the silver nitrate solution to the container, by gradually adding a drop of hydride solution to the mixed solution using a mixer at room temperature, slowly mixing, the hydride solution is completely added to room temperature In order to remove the unreacted hydrids after leaving in the step of adding a sodium hyper chloride solution, and mixing the solution at room temperature and then filtering in a stainless steel net.

In addition, the phase change material is characterized in that any one selected from a paraffinic hydrocarbon material having 13 to 28 carbon atoms, inorganic hydrates and molten salts thereof, and alcohols.

The inorganic hydrate is sodium sulfate decahydrate, sodium thiosulfate pentahydrate, sodium acetate trihydrate, dibasic sodium phosphate dihydrate, potassium fluoride tetrahydrate, potassium chloride hexahydrate, magnesium nitrate hexahydrate, ammonium nitrate eutectic mixture, sodium acetate 3 Any one selected from hydrate and urea eutectic mixtures.

In particular, the size of the silver nanoparticles is characterized in that the range within 10 ~ 300nm.

Hereinafter, the heat storage complex microcapsules having a natural antibacterial and healing function according to the present invention and a method of manufacturing the same will be described in detail.

In the case of foreign countries, various products including textile products are developed by applying microcapsules containing phase transfer substances. At the same time, in order to obtain a multifunctional product having antimicrobial and healing functions, the microcapsules are applied separately. Only through two or more processes). As a result, side effects such as an increase in manufacturing cost and uneven treatment of the product due to the prolongation of the process and a plurality of processes were obtained.

In the present invention, the microcapsules have a heat storage function depending on the type of phase transition material used as the inner material of the capsule when applied to an applied product, especially a textile product, that is, a thermal insulation function from extreme cold due to the variety of phase transition temperature or Silver nanoparticles are coated on the outside of the capsule with a cold function to maintain proper skin temperature from the rise or fall of body temperature due to extreme temperature and sweating during physical activity. By giving the unique antimicrobial, healing functions by inhibiting the bacterial culture and proliferation caused by sweating and various microorganisms of the human body can be used for the purpose of preventing odor, contamination of fibers, discoloration and mold growth.

The present invention imparts natural antimicrobial and healing functions inherent to silver in addition to the function of heat storage composite microcapsules. Especially, in consideration of application to the product, high temperature and pressure, Stability of microcapsules with time variation, stability of microcapsule outer wall that can withstand without being damaged by external pressure when applied to fiber or fabric surface, and micro-foaming conditions for high-temperature and high-pressure foaming when mixed in foam rubber or sponge Stability of capsules, solvents used in bonding textile products to other materials, for example toluene, methyl ethyl ketone (MEK), and so on.

In the present invention, various experiments have been conducted in order to obtain microcapsules with the highest stability in consideration of the above-mentioned points, and as a result, an optimal heat storage composite microcapsule is obtained.

As shown in FIG. 1, the schematic structure of the functional microcapsules 10 of the present invention is formed in a spherical shape, in which the capsule inner layer 11 contains a heat storage material including a phase transfer material (PCM), and an outer capsule layer. 12 is formed into a spherical shape surrounding the capsule inner layer 11 by containing a polymer material.

In addition, by coating ultrafine silver nanoparticles on the polymer material of the capsule outer layer 12, the silver nanoparticles are evenly distributed in the capsule outer layer 12 of the heat storage composite microcapsule 10 to form the capsule epidermal layer 13.

In this way, the silver nanoparticles distributed in the capsule epidermal layer 13 exhibit additional functions of natural silver sterilization and immunity enhancement by surface treatment of silver nanoparticles in addition to the unique heat storage function of the heat storage composite microcapsules 10. do.

Thousands of known materials can be used as the phase change material that can be used in the present invention, but representative examples include paraffinic hydrocarbon materials having 13 to 28 carbon atoms, various inorganic hydrates, molten salts thereof and alcohols. The phase transition temperature according to the carbon number of the alcohol hydrocarbon is shown in Table 1 below.

Various inorganic hydrates or molten salts include sodium sulfate decahydrate, sodium thiosulfate pentahydrate, sodium acetate trihydrate, dibasic sodium phosphate 12 hydrate, potassium fluoride tetrahydrate, potassium chloride hexahydrate, eutectic mixture of magnesium nitrate hexahydrate and ammonium nitrate and acetic acid Sodium trihydrate and urea eutectic mixtures.

[Table 1] Typical Alcohol Hydrocarbons and Phase Transition Temperatures According to Carbon Number

Hydrocarbon substance Carbon number Phase transition temperature (℃) 1-Nonanol 9 -8 to -6 1-Decanol 10 7 1-Undecanol 11 11 1-Dodecanol 12 24 to 27 1-Tridecanol 13 32.5 to 33.5 1-Tetradecanol 14 38-40 1-Pentadecanol 15 45 to 46 1-Hexadecanol 16 50-55 1-Heptadecanol 17 56 to 58 1-Octadecanol 18 60 to 61 1-Nonadecanol 19 60 to 61 1-Eicosanol 20 64 to 66

Meanwhile, in order to manufacture the heat storage composite microcapsules 10 coated with the silver nanoparticles as described above, first, a solution containing silver nanoparticles coated on the outer capsule layer 12 to form the capsule epidermal layer 13 is formed. It should be manufactured as follows.

[constitutional formula]

First, in Example 1, a water-soluble polymer 4% solution of styrene maleic anhydride having the above chemical structural formula was first prepared and left at room temperature for 3 to 5 hours, and then passed through a 2.0 μm filter to generate impurities and mixing process. Remove any granular tangled particles.

In addition, 500 g of a water-soluble polymer solution prepared in advance in a 1000 ml container and 50 to 100 ml of 0.1 mol silver nitrate solution were added and mixed by using a mixer at room temperature, and 150 to 200 ml of 0.1 mol hydrazine solution in the mixed solution. Mix slowly by dropping drops.

In addition, 0.1 mol hydride solution is completely added and then left at room temperature for 24 hours, and then 200 to 250 ml of 0.1 mol sodium hyperchloride solution is added to remove unreacted hydride.

Thereafter, the solution is mixed at room temperature for at least 5 hours, and then filtered through a 300 mesh stainless steel mesh to obtain a distribution of granular silver nanoparticles, and the size of the prepared silver nanoparticles is measured by a particle size analyzer. You can check using.

Figure 2 is a graph showing the particle size distribution of the silver nanoparticles prepared by the method of Example 1 It is preferable that the size of the silver nanoparticles are distributed in a large range from 90 to 120nm and maintained within a range of 10 to 300nm, more preferred It can be seen that the range is 20-100 nm which is within 50% of the average size.

On the other hand, in Example 2 to prepare a microcapsule 10 coated with silver nanoparticles of the present invention coated with a silver nanoparticles distribution solution as in Example 1.

First, using the above-mentioned phase transition material as the containing material to the initial emulsification to form the capsule inner layer (11), to which the initial melamine condensate is added to surround the capsule inner layer 11 to encapsulate the outer layer ( 12).

In addition, before the capsule outer layer 12 is cured, a certain amount of the silver nanoparticles prepared in Example 1 is added to the film outer layer so as to be fixed to the polymer membrane outside the capsule outer layer 12.

After curing the capsule epidermal layer 13 by adding a cross-linking agent and a curing agent of the polymer material used, the silver nanoparticles of the present invention by terminating the reaction by drying the filling solution containing the cured microcapsules 10 at room temperature Coated regenerative composite microcapsules 10 are prepared.

On the other hand, according to the KS K0693: 2001 method, the result of measuring the antimicrobial power of the functional nanocapsules (10) coated with the silver nanoparticles of the present invention as a result, in the case of the microcapsules 10 containing silver in the capsule epidermal layer (13) Significant antimicrobial activity was seen.

That is, the microcapsule solution prepared in Example 2 was made into a solution of 0.5% 1,000ml, 50g of test cloth (cotton) was added thereto, stirred for 10 minutes, and the test cloth was taken out to dry and then tested for antibacterial activity.

In addition, after washing the test cloth completed as described above 15 times in the laundry tester, as a result of the test of the antimicrobial power as described above by the laundry fastness test was also found that there is no degradation of the antimicrobial power. Table 2 below is an antimicrobial result table of the heat storage composite microcapsules coated with silver nanoparticles prepared in the present invention.

TABLE 2

Test species (preservation number) Staphylococcus aureus (ATCC 6538P) Klebsiella pneumoniae (ATCC 4352) Bacterial concentration (pcs / ml) 1.0 X 10 ⁵ 1.0 X 10 ⁵ Growth value (F) 4.1 3.5 Ma 3.8 3.9 Mb 7.9 7.4 Mc 2.6 2.8 Bacteriostatic activity (S) 5.3 4.6 Sterilization Activity (L) 1.2 1.1 Reduction rate (%) 99.9 99.9 Nonionic Water Soluble Polymer Polyoxyethylene sorbitan monorate 0.05%

In addition, FIG. 3 is n-Octadecane used as a phase change material as a result of the differential scanning calorimetry (DSC) analysis of the manufactured heat storage composite microcapsules, and Perkin Elmer DSC7 was used for the analysis. The analysis showed a heat capacity of 82.29 J / g near 28 ° C, the phase transition temperature of the material used.

As described above, the method for producing a regenerative composite microcapsule having a natural antibacterial and healing function according to the present invention is a conventional regenerative composite micro coating by coating silver particles on the outer walls of various regenerative composite microcapsules in the form of ultrafine nanoparticles. In addition to the function of the capsule can be provided with the effect that can be given inherent natural antibacterial and healing functions and sterilization and immunity enhancement function.

On the other hand, while the above has been described with reference to the preferred embodiments of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention described in the claims below It will be understood that modifications and changes can be made.

Claims (5)

delete Preparing a distribution solution of silver nanoparticles, Initial emulsification of the phase change material to form an inner capsule layer, Forming an outer capsule layer by enclosing the initial melamine condensate on the inner capsule layer, Forming a capsule epidermal layer by adding a predetermined amount of silver nanoparticles to the polymer membrane outside the capsule outer layer before the outer capsule layer is cured; Curing the capsule epidermal layer by adding a crosslinking agent and a curing agent of a used polymer material; and Comprising a step of terminating the reaction by drying the filling solution containing the cured microcapsules at room temperature, Preparing a distribution solution of the silver nanoparticles Preparing a water-soluble polymer solution of styrene maleic anhydride, leaving it at room temperature, and passing through a filter to remove granular tangled particles that may be generated during the mixing process; Injecting the water-soluble polymer solution and silver nitrate solution into the container, Mixing slowly using a mixer at room temperature while dropping the hydridine solution into the mixed solution, Adding a hydride solution completely and leaving it at room temperature, and then adding sodium hyperchloride solution to remove unreacted hydrides; and Method for producing a regenerative composite microcapsule comprising the step of filtering the solution at room temperature and then filtering in a stainless steel net. delete The method of claim 2, The phase change material is a paraffinic hydrocarbon material having 13 to 28 carbon atoms, an inorganic hydrate and a molten salt thereof, and a method for producing a regenerative composite microcapsule, characterized in that the alcohol. The method of claim 4, wherein The inorganic hydrate is sodium sulfate decahydrate, sodium thiosulfate pentahydrate, sodium acetate trihydrate, dibasic sodium phosphate 12 hydrate, potassium fluoride tetrahydrate, potassium chloride hexahydrate, magnesium nitrate hexahydrate, eutectic mixture of ammonium nitrate, sodium acetate trihydrate, and Method for producing a regenerative composite microcapsule, characterized in that any one selected from the urea eutectic mixture.

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