KR20050043804A - Nano silver coated pcm capsule composite material - Google Patents

Abstract

The present invention relates to a phase change composite composition mainly composed of silver-coated PCM (phase change material) nanocapsule, and has a phase change function as well as a fixing performance and antimicrobial activity, wash fastness, synthesis (sweat, Moisture) fastness, daylight fastness, anti-odor, far-infrared generation function, anion generation function, etc. have more excellent characteristics than the general PCM composition.

[Configuration]

A material a mixed with 35 to 65% by weight of a nano binder in a silver-coated PCM nanocapsules with a charged weight; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; It is characterized in that 0.1 to 25% by weight of nano clay [Clay (MMT)] is added to and mixed with the material a and material b in combination to complete a gel.

Description

Phase change composite composition composed mainly of silver nano coated PCM (phase change material) nano capsules {Nano silver coated PCM capsule composite material}

The present invention relates to a phase change composite composition mainly composed of silver-coated PCM (phase change material) nanocapsule, and has a phase change function as well as a fixing performance and antimicrobial activity, wash fastness, synthesis (sweat, Moisture) fastness, daylight fastness, anti-odor, far-infrared generation function, anion generation function, etc. have more excellent characteristics than the general PCM composition.

PCM (Phase Change Material) is an English abbreviation of phase change material and causes its own temperature change (about 10 ℃) through phase change according to the change of external temperature, which means endothermic and exothermic. In other words, the phase change material has a melting point and a freezing point, and when it enters the freezing point, it dissipates the stored heat and absorbs the surrounding heat when it enters the melting point. The phase change material dissipates heat at low temperatures and absorbs heat at high temperatures to protect any object or living body to which the phase change material is bound from severe temperature changes.

Therefore, in recent years, efforts have been made worldwide to apply phase change materials to various kinds of clothing, shoes, building materials, optics, and aerospace, including various textiles. Many experiments have been conducted to apply to uppers for shoes and fabrics for shoes.These fastening properties (binding fixation strength) of the phase change material nanocapsules are excellent, so that the fastness to washing and daylight fastness to the sweat and moisture are normal. There is a task that must be reached. In addition, at the same time, while focusing on the development of a phase change composite composition having excellent antibacterial and deodorizing ability and having far infrared ray generating function and negative ion generating function, however, the present situation has not been achieved.

On the other hand, a number of applications and registrations that have theoretically applied the general (silver is not nano-coated) phase-change nanocapsules in various fields has been made worldwide, in particular, the practicality of the phase-change nanocapsules are poor due to the poor fixing ability of the phase-change nanocapsules As the changeability of the changeable nanocapsules is poor, the ability of the additionally added material and the inherent function of the added material are also poor, and thus, such a product using a phase change composite composition has not appeared.

The present invention can improve the fixability of the PCM nanocapsules while using a new PCM nano-coated silver on the PCM nanocapsules to solve the problems and disadvantages of the conventional phase change composite composition described above, and various functions mentioned at the beginning This well exhibited silver was devised to provide a phase change composite composition mainly composed of nano-coated PCM (phase change material) nanocapsules.

A material a mixed with 35 to 65% by weight of a nano binder in a silver-coated PCM nanocapsules with a charged weight; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; It is characterized in that 0.1 to 25% by weight of nano clay [Clay (MMT)] is added and mixed with respect to the weight of the material a and the material b, which is completed in a gel shape.

In addition, the present invention is a material a is mixed with a nano binder of 35 to 65% by weight relative to the input weight of the silver-coated PCM nanocapsules; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; A material c mixed with 0.1 to 25% by weight of nano clay [Clay (MMT)] added to the combined weight of the material a and material b; 0.1-25 wt% of tormaline-based nano ceramics are added and mixed with the material a, material b, and material c, and the mixture is finished in a gel shape.

In the above, the nano binder is selected from oily or aqueous acrylic binder, oily or aqueous polyurethane binder, oily or aqueous rubber binder or oily and aqueous latex binder. Clay is characterized in that it can be replaced with a layer silicate (Layer Silicate) or silica (Silica).

Hereinafter, the specific configuration and experimental examples of the present invention will be understood to be not limited to the following experimental examples.

First, the present invention provides two kinds of composite compositions, which are as described above, in which 35-65% by weight of a nano binder is added and mixed with a mixed material of silver-coated PCM nanocapsules; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; It provides a first composite composition characterized in that the nano clay (Clay (MMT)) of 0.1 to 25% by weight based on the combined weight of the material a and material b is added and mixed to complete the gel.

In addition, the present invention is a material a is mixed with a nano binder of 35 to 65% by weight relative to the input weight of the silver-coated PCM nanocapsules; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; A material c mixed with 0.1 to 25% by weight of nano clay [Clay (MMT)] added to the combined weight of the material a and material b; It provides a second composite composition, characterized in that 0.1 to 25% by weight of tormaline-based nano ceramics are added to and mixed with the material a, material b, and material c to form a gel.

In the first and second composite compositions, the nanobinder is selected from an oily or aqueous acrylic binder, an oily or aqueous polyurethane binder, an oily or aqueous rubber binder, or an oily or aqueous latex binder. In addition, the nano clay used to improve the fixing ability of the PCM nano capsules is characterized in that it can be replaced with a layer silicate (Layer Silicate) or silica (Silica). In addition, the tourmaline-based ceramic of the second composite composition allows the far infrared generation function and the anion generation function to be exerted to be exerted.

In the preparation of the composite composition of the present invention, it is necessary to add each material to a stirrer at room temperature and to stir at a high speed, so that a special device is not used, and the composition ratio of each material is very important. Material and composition ratio of the composite composition is determined by the inventors have been continuously experimented for several years, the main component of the silver-coated PCM nanocapsule (diameter: 8 ~ 13 μ ) is currently patented in Korea This invention completes this invention using the above-mentioned nano binder, a clay, and a tourmaline ceramic as an additional component. Here, it can be seen that the nano clay can be replaced with a layer silicate or silica, and the results of experiments by substituting clay in various experimental examples to be described later also revealed that the same results as using clay. .

On the other hand, PCM nanocapsules coated with silver, which is the main component of the present invention, have strong sterilization, antimicrobial, and odor removal effects, and are effective as they are. Compared to using silver-coated PCM nanocapsules, the silver-coated PCM nanocapsule is more economical in manufacturing, and the above-described functions of silver are more reliably exhibited. In addition to being excellent), experimental results were obtained that the fixing ability of the PCM nanocapsules was better (20% or more) and the phase change action was also better (20% or more). Therefore, it should be noted that there is a big difference between simply using a general PCM nanocapsules and silver powder and using the silver-coated PCM nanocapsules of the present invention.

Various experimental results using the composite composition of the present invention will be described below. The first composite composition and the second composite composition have almost the same functions and effects, but the far infrared ray generating function and the anion generating function have the second composite composition as the first composite. It should be noted in advance that the composition is increased by about 30% relative to the composition, and the far-infrared photographs presented below are based on the second composite composition. At the same time, the composite composition of the present invention uses the composite composition completed in the shape of a gel when a knife coating (or a multi coating, a release paper coating, a sticking thread coating) is applied to the fiber. In the case of using the impregnation method, the composite composition and water are mixed at a ratio of about 4: 1 to 5: 5.

First, in the composition ratio of the compositions of the present invention for the experiment, the first composite composition, a silver nano-coated PCM nanocapsules and a liquid nano binder is mixed in a ratio of 5: 5 to the weight and the weight of the base material 15 1% by weight of aroma microcapsule (herb) is mixed, and then 15% by weight of nano clay [Clay (MMT)] is added to the combined weight of these materials, mixed and stirred at a high speed to form a gel. The composite composition was prepared.

Next, silver-coated PCM nanocapsules and liquid nanobinders are mixed at a ratio of 6: 4 to weight, and 10% by weight of aroma microcapsules (herbs) are added to the weight of the base material, followed by mixing. 20% by weight of nano clay [Clay (MMT)] was added to the combined weight, and 20% by weight tormaline-based nano ceramics were added to the combined weight of these materials and mixed, followed by stirring and gel formation at high speed. Experiment 2 composite composition was prepared.

The first photomicrograph is applied to the Marymesh fabric through the impregnation method, the second photomicrograph is applied to the ordinary socks, and the third photomicrograph is applied to the conventional arm band, and the Marymesh The fourth micrograph is applied to the fabric by the coating method, and the fifth photomicrograph is applied to the merry mesh fabric by the multi-coating method, and the experiment 1 and 2 composite compositions showed the same picture. As shown in these micrographs, it can be seen that the nanocapsules made of the composite composition of the present invention are fixed in a large amount to the fiber, which is due to the excellent fixing ability of the nanoclay as described above and is compared with the general PCM composite composition. As described above, the fixability of about 20% is improved.

Hereinafter, the first, second, third, fourth, fifth micrographs are shown.

First Micrograph

[Second micrograph]

[Third Micrograph]

[Fourth Micrograph]

[Fifth Micrograph]

Next, a table showing the results of experiments of the phase change action of the composite composition using the silver-coated PCM nanocapsules of the present invention and the composition using a general PCM nanocapsules.

TABLE 1

TABLE 2

Table 1 is a result table of the present inventors directly wear and test the temperature change and humidity change after applying the composite composition using the PCM of the present invention to the upper and insoles for shoes by the impregnation method or coating method to make sneakers, 2 is a result table of the present inventors directly wearing the composite composition using a PCM impregnation method or coating method to the upper and insoles for shoes to make the sneakers and then tested the temperature change and humidity change. Here, only the results of the bridge bridge will be described for the change of temperature and humidity of the toe part, and the arch part of the sole can be easily seen by looking at the table, so the comparison result according to the temperature and humidity change of the arch part will not be described.

To explain this in detail, when the user wears the present invention and the comparative product at room temperature and runs on the treadmill, the internal temperature of the sneaker is measured after 5 minutes elapsed. 15 minutes after wearing the present invention was 24.65 ℃ but the comparative product was 28.72 ℃, 30 minutes after wearing the present invention was 31.08 ℃, but the comparative product was 38.55 ℃. On the other hand, when the stationary state was maintained without running in the state of wearing sneakers, the temperature of the toe part after 30 minutes of the present invention was 30.41 ℃, but the comparative product was 40.25 ℃.

As described above, it was found that the present invention and the comparative product were clearly different from each other, but the present invention was found to be very excellent.

Next, when wearing the present invention and the comparative product and running on a treadmill at room temperature, after 5 minutes, the internal humidity of the sneakers was measured. After 15 minutes, the invention was 82.62%, but the comparative product was 84.50%. After 30 minutes, the invention was 88.62%, but the comparative product was 97.65%. On the other hand, when the stationary state was maintained without running in the state wearing the sneakers, the humidity of the present invention was 86.97% after 5 minutes, but the comparative product was 91.80%.

As described above, it was found that the present invention and the comparative product were clearly different from each other, but the present invention was found to be very excellent.

Next, referring to the following [Table 3], the fiber to which the composite composition of the present invention is applied can be seen that the washing fastness is the best level as 5, and the friction fastness is also the best state as 5, and the composite including daylight fastness (Sweat, Moisture) Color fastness was also found to be very good as 4 to 5 for acidity and alkalinity. This is a copy of the test result certificate issued by the Korea Apparel Testing Institute to the inventors on August 26, 2004. As a result of requesting one point of the knitted fabric (top), the laundry fastness, friction fastness and overall fastness are the best. It has been proved to be in very good condition because of the reason that the nanoclays of the present invention allow silver to excel in the ability of the nanocoated PCM nanocapsules to fibers.

Next, Table 4 shows the Staphylococcus aureus and Klebsiella feumoniae strains on the fiber to which the composite composition of the present invention was applied (test pieces were 5 cm in width and length, respectively). Inoculation of Klebsiella pneumoniae) at the same concentration as shown in the table shows that the bacteriostatic activity is excellent, and the sixth micrograph and the seventh micrograph show that it supports the bar nano silver coating component of the present invention. This is because it played a major role.

TABLE 3

TABLE 4

[Sixth Micrograph]

7th Micrograph

Next, referring to Table 5 and the first thermographic photograph and the first thermographic photograph, this is the result of applying the second composite composition of the present invention to a fiber and performing a thermal infrared thermography. This is a copy of the test report issued to the inventor of October 23, 2011. Looking at this, it can be seen that excellent far-infrared ray is emitted from the garment to which the present invention is applied as compared to the general garment.

Subsequently, the following Tables 6 and 7 show that the present invention was applied to the Korea Apparel Testing and Research Institute for the nonwoven fabric having a width of 298 mm and a length of 211 mm. This is a test report and a graph of ion water measurement, which was issued on November 30, 2004. In view of this, the fiber or clothing to which the present invention was applied showed that the number of ions generated in A4 size was on average 98, which is almost the same as the number of ions detected in a pleasant natural environment (field, trail, garden, etc.). This is due to the overall action of the silver, ceramics and clay of the present invention, but the nano-ceramic of the present invention has a more important action.

TABLE 5

[1st thermography photo]

[Second Thermographic Picture]

TABLE 6

TABLE 7

As described above, the present invention is based on the newly produced silver-coated PCM (phase-change material) nanocapsules as a main component, and nanoclay and nano ceramics (torumaline-based) are selected as a new additive composition to provide a conventional general PCM capsule. As well as the poor phase change function derived from the phase change composition composed as a main ingredient, the adhesion performance decreases and the antibacterial activity decreases, the wash fastness decreases, the comprehensive fastness (sweat and moisture) fastness falls, the daylight fastness falls, and the anti-odor falls, It has a useful effect of remarkably improving the small far-infrared generation function and the small negative ion generation function, and has the characteristics that can be immediately applied to the production of various practical products.

Claims (4)

A material a mixed with 35 to 65% by weight of a nano binder in a silver-coated PCM nanocapsules with a charged weight; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; Nano-coated PCM (phase change material) nanocapsule silver-coated, characterized in that 0.1 to 25% by weight of nano clay [Clay (MMT)] is added and mixed with respect to the weight of the material a and the material b to be mixed. Phase change composite composition containing A material a mixed with 35 to 65% by weight of a nano binder in a silver-coated PCM nanocapsules with a charged weight; A material b in which 0.1 to 25% by weight of aroma microcapsules are added and mixed with respect to the weight of the material a; A material c mixed with 0.1 to 25% by weight of nano clay [Clay (MMT)] added to the combined weight of the material a and material b; Silver-coated PCM (phase change material), characterized in that 0.1 to 25% by weight of tormaline-based nano ceramics are added and mixed with the material a, material b, and material c, and mixed to form a gel. ) Phase change composite composition based on nanocapsules. The nanobinder according to claim 1 or 2, wherein the nanobinder is selected from an oily or aqueous acrylic binder, an oily or aqueous polyurethane binder, an oily or aqueous rubber binder, or an oily or aqueous latex binder. A phase change composite composition mainly composed of silver-coated nanoparticles coated PCM (phase change material) nanocapsule. The phase based on silver nano-coated PCM (phase change material) nanocapsules according to claim 1 or 2, characterized in that the nanoclay can be replaced with a layer silicate or silica. Metabolic complex composition.