KR102036782B1 - Functional Material impregnated illite particle and Manufacturing method thereof - Google Patents

Abstract

The present invention relates to illite particles loaded with a functional material and a method of manufacturing the same, and more particularly, to a method for preparing illite particles loaded with a functional material on a physically treated illite and a bisabolol loaded as a functional material. Relates to light particles.
According to the present invention, when the illite is physically pretreated to support bisabolol, which is a functional material, the release behavior of bisabolol is excellent, and thus it can be easily used as a carrier.

Description

Functional material impregnated illite particles and manufacturing method thereof {Functional Material impregnated illite particle and Manufacturing method}

The present invention relates to illite particles loaded with a functional material and a method of manufacturing the same, and more particularly, to a method for producing illite particles loaded with a functional material on a physically treated illite and a bisabolol loaded as a functional material. Relates to light particles.

Yeongdong-gun, Chungcheongbuk-do has a large amount of illite, which is a non-expandable, octahedral and aluminum-rich mica-like mineral. Illite is also known for its excellent adsorption deodorization and decomposability for heavy metals and toxic gases, high far-infrared radiation and anion generation at room temperature, and antibacterial and antiviral properties. Such illite is currently mined and pulverized in mines and is used as sanitary ware, tiles, soil supplements, feed additives, etc., but its application range is simple, and it is an additive material for functionality, not a main raw material of products. The demand is very limited.

Illite collects materials in Yeongdong-gun by dividing them into four mining rights, and expands the utilization of materials by evaluating the supporting / discharging behavior of functional materials to identify characteristics and broaden the scope of application for each location. The present invention was approached for the purpose.

Accordingly, the present inventors have diligently researched to overcome the limitations of the conventional materials. As a result, when the bisabolol is supported on the physically treated illite, the present inventors have identified a new use of the illite as a carrier. Invented.

An object of the present invention is to provide a method for producing illite particles capable of supporting a functional material.

It is another object of the present invention to provide an illite particle loaded with a functional material having excellent release behavior of bisabolol as a functional material prepared according to the above-mentioned manufacturing method.

According to one aspect of the invention, the invention is

A) physical treatment in the illite; And

B) supporting a functional material on the physically treated illite; It provides a method for producing illite particles loaded with a functional material comprising a.

Illite (illite) is an excellent material having a variety of functions, currently used only as an additive material for a specific functionality in the field of simple materials, such as sanitary ware, tiles, hoisting aids, and is not used as the main raw material. Thus, the present inventors have completed the present invention in order to use the illite as a carrier of the functional material.

In the method for producing illite particles loaded with the functional material of the present invention, the illite of step A) is characterized in that it was taken from the Yeongdong region of North Chungcheong Province.

In the manufacturing method of the illite particles loaded with the functional material of the present invention, the step of physically treating the illite of step A) comprises mixing the illite and zirconia balls in a weight ratio of 1: 4, 24 at 200 rpm It is characterized by grinding in one direction for a time.

In the method for producing illite particles loaded with the functional material of the present invention, the physical treatment of step A) is characterized in that the elite is pulverized using a pot mill.

The port mill used in the present invention should select a ball and a port having a hardness higher than the hardness of the sample as a grinding device for grinding and mixing while placing and rotating a pot to be used on two rollers. When the pot is rotated, the ball inside the rolls down and causes collision or friction. As a result, the impact light and the friction force crush the illite into a uniform particle size. In the present invention, 10 pi was used as the zirconia ball.

In the method for producing illite particles loaded with the functional material of the present invention, the physically treated illite is characterized in that the average diameter of 1 to 5um.

According to one experimental example of the present invention, it was confirmed that the particle size of the illite treated physically has a size of 1um to 5um (see FIGS. 2 and 3). These results show that the particles of illite were produced in particle size to support the functional material as physically treated.

In the method for producing illite particles loaded with the functional material of the present invention, the physically treated illite is characterized in that a peak appears at 2θ = 27 ° or 2θ = 32 ° in XRD analysis.

According to an experimental example of the present invention, both the illite particles that were physically treated and the illite that were not physically treated showed the same peak (see FIG. 4). These results show that the physical treatment of the illite does not change the crystallinity that may occur during the grinding process, and there is no significant difference in the components of the illite mined at four mining companies.

In the method for producing illite particles loaded with the functional material of the present invention, the physically treated illite is characterized in that a peak appears at 1100 cm ^-1 when FT-IR measurement.

According to an experimental example of the present invention, it was confirmed that the Si-O peak (1100 cm ^-1 ) included in the illite was observed as a result of FT-IR measurement of the illite treated physically according to the present invention (see FIG. 5). ). These results show that the physical properties of the illite do not change.

In the method for producing illite particles loaded with the functional material of the present invention, the functional material of step B) may include any functional material used as a natural antibacterial agent, but is preferably bisabolol.

Bisabolol, which is naturally synthesized from candida trees and chamomile (Matricaria recutita) in Brazil, is known as a natural antimicrobial agent.

[Formula 1]

According to another aspect of the present invention, the present invention provides an illite particle loaded with a functional material prepared according to the production method of the present invention.

The illite particles loaded with the functional material of the present invention are characterized in that the functional material is released for 35 hours to 45 hours.

According to an experimental example of the present invention, as a result of confirming the release characteristics of the bisabolol in the illite particles loaded with bisabolol as a functional material, the initial release amount is continuously released up to about 27 hours, then up to 40 hours It was confirmed to be released (see FIG. 6). These results suggest that after the functional material is loaded into the illite, it can be used to develop sustained-release products, thereby maximizing the effect.

The present invention has excellent release behavior of bisabolol when physically pretreating illite to support bisabolol, which is a functional material, and thus can be easily used as a carrier.

1 is a view showing the illite mining mining and Yeolite collected from the Yeongdong region of Chungcheongbuk-do.
2 is a view of observing the change in particle shape of the illite before and after grinding using SEM.
3 is a result of measuring the particle size of the illite before and after grinding using a particle size analyzer.
4 shows the results of XRD measurement on the illite before and after grinding.
5 shows the FT-IR results for the illite before and after grinding.
Figure 6 shows the results of measuring the release characteristics of bisabolol in the ilsaborol-supported illite.

Hereinafter, the present invention will be described in more detail with reference to Examples. Since these examples are only for illustrating the present invention, the scope of the present invention is not to be construed as being limited by these examples.

Example 1 Physical Pretreatment of Illite

In the present invention, the illite is physically pretreated in order to support the bisabolol, which is a functional substance, in the illite particles.

The illite was collected from four mining rights in Yeongdong-gun, Chungcheongbuk-do, and the experiment was performed by marking the illite collected from each mining group as MY-325, YY-325, OY-325 and DY-325.

Specifically, the illite and zirconia ball in dry conditions are prepared by mixing in a weight ratio of 1: 4. Then, grinding is performed in one direction at 200 rpm for 24 hours, which is performed by a pot mill.

The pot mill is a grinding equipment that grinds and mixes while putting a pot to be used on two rollers while rotating and selecting a ball and a port having a hardness higher than the hardness of the sample to be crushed. 10 pies were used as zirconia balls.

When the pot rotates, the ball inside the rolls falls and causes collision or friction to disperse. As a result, the illite is crushed to an average diameter of 1 μm or less by the impact force and the friction force, and thus the particle size is uniform.

Experimental Example

Experimental Example 1 SEM Observation

The illite before the physical achievement and the forms of MY-325, YY-325, OY-325 and DY-325 physically treated in Example 1 were observed using SEM, and the results are shown in FIG. 3. .

As a result, as can be seen in Figure 3, the particles have a non-uniform size before grinding, but after the grinding can be confirmed to have a uniform size of about 5 μm or less. Even when the particle size was small, the size of the material appeared to be large on the SEM image due to the aggregation of the ceramic material.

Experimental Example 2 Particle Size Measurement

The illite before the physical achievement and the particle size of MY-325, YY-325, OY-325 and DY-325 physically treated in Example 1 were observed using a particle size analyzer, and the results are shown in FIG. Indicated.

As a result, as can be seen in Figure 3, it was confirmed that the four illite before grinding has a size of as small as 14.51 μm to as large as 45.74 μm. On the contrary, in the case of the four illite of Example 1 which had been physically treated, it was confirmed that the particle size had a size of 691.8 nm to 960.7 nm, and thus the particle size was reduced.

Experimental Example 3 XRD Measurement

XRD analysis was performed on the illite before physical treatment and MY-325, YY-325, OY-325 and DY-325 physically pretreated in Example 1, and the apparatus used was Rigaku 2311-B (room temperature ~ 1400 ℃ in vacuum (10-³torr); heating element in He gas: Pt wire; thermocouple: R-type. The analysis results are shown in FIG. 4.

As a result, as can be seen in Figure 4, the change in crystallinity that can occur during the grinding process according to the particle size was not observed, it can be seen that the components of the illite mined from the four mining companies are not significantly different.

These results suggest that the application of materials will not be limited because the light veins of the illite are connected in one, so there is no other specificity.

Experimental Example 4 FT-IR Measurement

FT-IR analysis was performed to confirm the material composition of Example 1, and the apparatus used was JASCO V-460 FT / IR Spectrometer (Wavelength Range: 650∼4000nm; using Miracle Single reflectance ATR; Resolution: 4cm- 1; Scantimes: 30times). The results are shown in FIG.

In FIG. 5, it can be seen that the Si-O peak included in the illite appears at 1100 cm ⁻¹ .

Experimental Example 5 Confirmation of Bisabolol Release Characteristics

Emission efficiency of the pulverized illite collected after sampling in the four mining companies prepared in Example 1 confirmed the release behavior of bisabolol in solution in pH 7.4, PBS.

Bisabolol, a functional substance, was supported by applying pressure to the illite to confirm the release behavior of bisabolol.

The amount of bisabolol used in the release behavior was 0.01 g and 20 mL of PBS solution was used.

As a result, as can be seen in Figure 6, the release characteristics showed a tendency that the initial release is a continuous release up to about 27 hours, and almost no release after 40 hours.

This tendency was confirmed that if used in the development of sustained-release products after loading functional materials, it would show a sustained release behavior.

Claims (8)

A) physical treatment in the illite; And
B) supporting a functional material on the physically treated illite; In the manufacturing method of the illite particles loaded with a functional material comprising a,
The step of physically treating the illite of step A) comprises mixing the illite and zirconia balls in a weight ratio of 1: 4 and grinding in one direction at 200 rpm for 24 hours,
The physically treated illite has an average diameter of 1 to 5 um,
The functional material of the step B) is characterized in that the bisabolol, functional material-supported manufacturing method of the illite particles.
delete delete The method of claim 1,
The physically treated illite is a peak at 2θ = 27 ° or 2θ = 32 ° in XRD analysis.
Method for producing illite particles loaded with a functional material.
The method of claim 1,
The physically treated illite is a peak at 1100 cm ^-1 when measured by FT-IR
Method for producing illite particles loaded with a functional material.
delete An illite particle loaded with a functional material prepared according to any one of claims 1, 4 and 5.
The method of claim 7, wherein
The release time of the functional material in the illite particles loaded with the functional material is 35 hours to 45 hours
Illite particles loaded with functional materials.

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