KR20060098710A - Sampling method of matter which releases far infrared ray, minus ion, plastic worked material, composite and food container thereof - Google Patents

Abstract

The present invention relates to far-infrared, anion-releasing material, in particular, by using an ionization method such as extracting anion material from the far-infrared, anion-releasing functional powder and adsorbing to a porous plastic processing material (foaming silicate), dispersion of the functional powder The present invention relates to a method of extracting far-infrared and anion-releasing materials having excellent transparency as well as allowing a large amount of far-infrared rays and anions to be released by overcoming limitations of performance and mixing, and plastic processing materials, compositions, and food containers using the same.

The present invention comprises the first step of dispersing far-infrared, anion-releasing functional powder in water and adding a phosphate to create an interlayer boundary to form a neutral pH; A second step of removing supernatant and floating impurities from the functional powder dispersion to obtain a supernatant; A third step of extracting an anionic substance in the form of a salt by adding an alkaline substance to the supernatant; And a fourth step of removing an extract from the extracted material to obtain an extract.

Far Infrared, Anion, Emission, Ionization, Extraction, Plastic, Food Container

Description

Extraction method of far-infrared and anion emitter and plastic processing material, composition and food container using same {SAMPLING METHOD OF MATTER WHICH RELEASES FAR INFRARED RAY, MINUS ION, PLASTIC WORKED MATERIAL, COMPOSITE AND FOOD CONTAINER THEREOF}

1 is a flow chart showing a method for extracting far-infrared, anion-emitting material according to the present invention;

Figure 2 is a flow chart showing the manufacturing process of the plastic material containing far-infrared, anion-emitting material according to the present invention.

The present invention relates to far-infrared, anion-releasing material, and more particularly to a method for extracting the far-infrared, anion-releasing material that can increase the dispersibility and mixing of the functional powder, and a plastic processing material, a composition and a food container using the same.

In recent years, as the standard of living has improved, the interest in the production of food containers that can prevent various diseases in advance, as well as the convenience of various food containers used indoors and the user's body or stored food, have.

In general, plastic food containers such as pots, rice bowls, tea cups, etc. are mostly molded products using a molding mold, and are classified into various types according to their materials.

Looking at products that are expensively traded due to the characteristics of the material, the main components are plastic solution and stone powder when forming products, and the pigments and hardeners of the desired color are added at the proper ratio.

On the other hand, functional powders such as ocher, jade, and tourmaline are known to emit far infrared rays and anions, and far infrared rays promote health by circulating blood and discharging wastes, and penetrate into food to prevent food from being deteriorated. There is.

In addition, the negative ions absorb and neutralize the cations released around the living environment from various pollutions, thereby preventing food from decaying and smoothing the body's metabolism.

For example, ocher is red with minerals composed of 40 to 80% quartz, 10 to 20% feldspar and mica, 5 to 35% carbonate mineral, and 2 to 4% silt. 60%, 8-12% alumina, 2-4% trivalent iron oxide, 0.8-1% divalent iron oxide, 4-16% calcium oxide, and 2-6% magnesium oxide.

It contains about 0.5% of titanium oxide, manganese oxide, and 10 ~ 15% of moisture, and in addition to the various minerals listed above, various kinds of microorganisms and enzymes, which are organic substances, are present together, and they absorb far infrared rays. It is known to have far-infrared radiation effect, room temperature and humidity control, antibacterial and deodorization, and heavy metal adsorption.

Therefore, in recent years, various attempts have been made to combine the benefits of various functional powders, such as loess, with basic daily necessities so as to be easily accessible in daily life.

Korean Patent Registration No. 2002-321290 discloses a plastic food container prepared by mixing 5 to 20% by weight of ocher in a plastic molding material, which is a method of using natural loess as it is.

However, since silica, calcium carbonate, and the like contained in functional powders such as ocher have a dense crystal structure, absorption of far-infrared rays is relatively low due to the low absorption of far-infrared rays.

In addition, the far-infrared radiation substance contained in the functional powder is a metal and mineral component contained in a very small amount, and when mixing a large amount of the functional powder in plastic to obtain the desired far infrared, anion release effect, the blendability and dispersibility of the functional powder It was a problem.

Due to such dispersibility and mixing problems of the functional powder it was bound to limit the amount of the functional powder to a small amount, and therefore it was difficult to expect to maximize the far-infrared, anion release effect of the food container.

The present invention has been made in order to solve the problems of the prior art as described above, after removing the high-purity silica, calcium carbonate, and the like, the amount of far-infrared radiation contained in the functional powder in advance to remove it contained in the interlayer of the functional powder It is an object of the present invention to provide a method for extracting far-infrared and anion emitters that ionically separates only anion materials.

In addition, since the functional powder is not directly added to the plastic (chip), the amount of the functional powder added is reduced, and the far-infrared and anion-releasing material adsorbed by increasing the dispersibility and mixing properties of the inorganic components of the functional powder in the plastic is contained. It is an object to provide plastic processing materials.

On the other hand, another object of the present invention to provide a plastic composition and a food container containing far-infrared, anion-releasing material excellent in the far infrared, anion release effect using the plastic processing material.

Far infrared, anion emitting material extraction method of the present invention for achieving the above object

A first step of dispersing far-infrared and anion-releasing functional powder in water and adding a phosphate to generate an interlayer boundary to neutralize the pH;

A second step of removing supernatant and floating impurities from the functional powder dispersion to obtain a supernatant;

A third step of extracting an anionic substance in the form of a salt by adding an alkaline substance to the supernatant; And

And a fourth step of obtaining an extract by removing the eutectic content from the extracted material.

In addition, the far-infrared, anion-emitting functional powder is selected from ocher, jade, gold, silver, tourmaline, yangyang, ganban stone, giant stone, shells, burlap, green tea, eochocho, pine needles, ginseng, thorny oak, oak and licorice It is characterized in that the powder of the species or more, the phosphate added in the first step is characterized in that NaH ₃ CO ₃ , the alkaline material added in the third step is characterized in that the NaCl or Na ₂ CO ₃ .

In addition, the plastic processing material containing the far-infrared, anion-emitting material of the present invention is characterized by adsorbing the far-infrared, anion-emitting material extracted by the extraction methods to the cationic component of the porous plastic processing material having a cationic component. do.

This comprises the steps of adding, stirring and dispersing the porous plastic processing material having a cationic component into the far-infrared, anion-releasing material extract;

Filtering, settling or centrifuging the dispersion to remove the supernatant;

Vacuum-drying the porous plastic processing material adsorbed the far-infrared and anion-emitting material in the step; And

It is characterized in that it is prepared by heating the porous plastic processing raw material to 500 ~ 600 ℃ to strengthen the ionic bonds to fix the far infrared, anion emitting material.

And, the porous plastic processing material having the cationic component is characterized in that the foam silicate, and further comprising the step of powdering by a ball mill grinder after the step of fixing the far-infrared, anion-emitting material.

On the other hand, the plastic composition containing the far-infrared, anion-emitting material of the present invention is characterized in that the plastic containing 1 to 15% by weight of the plastic processing material containing the far-infrared, anion-emitting material, plasticizer, colorant, CaCO _{3 It} is characterized in that it further comprises one or more additives selected from T _i O ₂ and silver nanoparticles.

In addition, the plastic food container containing the far-infrared, anion-releasing material of the present invention is characterized in that the plastic composition and the synthetic resin is produced by mixing and pelletizing after molding in a certain ratio, pellets made of the plastic compositions And it is characterized by consisting of 1 to 15% by weight of the master batch and 85 to 99% by weight of the synthetic resin.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart showing a method for extracting far infrared rays and anion emitting materials according to the present invention, and FIG. 2 is a flowchart showing a manufacturing process of a plastic processing material containing far infrared rays and anion emitting materials according to the present invention.

As shown, the method for extracting far-infrared and anion-releasing material of the present invention is a first step of dispersing far-infrared, anion-releasing functional powder (such as ocher) in water and adding a phosphate to create an interlayer boundary to form a neutral pH. (S100).

In the first step (S100) of the extraction method, it is preferable to disperse functional powders such as ocher in a ratio of about 40 to 100 g in 1 L of water, and the dispersion is performed in a conventional mixing vessel equipped with a stirrer.

At this time, in order to enhance the interlayer swelling effect of the functional powder particles, the pH is neutralized by adding phosphate, for example, NaH ₃ PO ₄ (Sodium Phosphate).

In addition, a second step (S200) of obtaining a supernatant by removing the co-content and suspended impurities from the functional powder dispersion.

In the second step (S200) to remove the powder and the like from the functional powder dispersion, which can be carried out by filtration, sedimentation, centrifugation or other known conventional methods.

For example, the functional powder dispersion can be held for 24 hours to settle the solids and separate only the supernatant. At this time, the floating impurities other than the solid content can be easily removed by a known method such as sieving.

Next, an alkaline substance is added to the supernatant, followed by a third step (S300) of extracting an anionic substance in the form of a salt.

In the third step (S300), by adding and stirring an alkaline material such as NaCl, Na ₂ CO ₃ to the supernatant separated in the second step (S200), anion substances present in the supernatant are extracted in the form of salt.

Finally, a fourth step (S400) of removing the content from the extracted material to obtain an extract.

In the fourth step (S400) it is removed in the same manner as the second step (S200) to obtain a final high purity extract liquid.

And, the plastic processing material containing the far-infrared, anion-releasing material of the present invention is prepared by adsorbing the material extracted by the above extraction methods to the cationic component of the porous plastic processing material having a cationic component.

For example, by using a plastic processing material prepared by ion adsorption (dying) the extracted material in the cationic component of the foamed silicate formed pores, the mixing and dispersibility of the conventional functional powder directly into the plastic Poor problem can be solved.

Looking specifically at this adsorption process, a porous plastic processing raw material (foaming silicate) having a cationic component (Site) to the far-infrared, anion-releasing material extract is subjected to a step (S100 ') of stirring.

For example, 75 g of foamed silicate is first introduced into an adsorption column having a capacity of about 1 L and a length of about 40 cm, and then injected with 400 ml of a functional powder aqueous solution (30 wt% of solids), and adsorbed for 4 to 5 hours.

And, the step of removing the supernatant by filtration, sedimentation or centrifugation of the dispersion (S200 ') and vacuum drying the porous plastic processing material (foaming silicate) adsorbed far-infrared, anion-emitting material in the step (S300') Go through.

Far-infrared and anion emitters contained in the functional powders have anionic properties, and plastic processing materials used as carriers of these materials have cationic properties, and can be adsorbed very easily and firmly by mutual ion bonding.

Finally, by heating the porous plastic processing raw material to 500 ~ 600 ℃ to strengthen the ionic bonds to fix the far infrared, anion emitting material (S400 ') and the powdering step by the ball mill grinder (400 ~ 500 mesh) (S500 The manufacturing is completed by passing through ').

That is, when the adsorption is completed, open the valve at the bottom of the adsorption column to remove the filtrate, and separate only the solid content, and the foam silicate slurry in which the functional material is adsorbed (incorporated) is put into the dryer and dried, and finally the ball mill grinder (400-500 mesh) Finely pulverized into) to complete the plastic processing material.

Foam silicates show high absorption energy of 800 ~ 400λ ^-1 when irradiated with infrared rays when forming into a film form, and also have excellent radiation energy. Better anion dissipation effect can be obtained than using materials.

In addition, the plastic composition containing the far-infrared, anion-emitting material of the present invention comprises 1 to 15% by weight of the plastic processing material containing the far-infrared, anion-emitting material in the plastic.

At this time, it may further include at least one additive selected from a plasticizer, a colorant, CaCO _3, T _i O ₂ and silver nanoparticles. In particular, when silver nanoparticles are added, antimicrobial activity becomes further excellent.

That is, it contains 1 to 15% by weight of plastic processing materials adsorbing far-infrared and anion-releasing materials to plastics such as PP, PE, PET, ABS, and other suitable plastic processing materials such as plasticizers and colorants, if necessary. It is prepared by blending it further.

On the other hand, the plastic food container containing the far-infrared, anion-releasing material of the present invention is produced by mixing the plastic composition (foaming silicate) and synthetic resin (PP, PE, ABS, PC, PS, etc.) at a predetermined ratio, pelletized and molded Or it is composed of 1-15% by weight of the pellet and the masterbatch and 85-99% by weight of the synthetic resin prepared from the plastic composition, and is produced by a method such as extrusion, injection.

Foamed silicates used as plastic processing raw materials play a role as a stiffener for synthetic resins, and have excellent mixing properties with synthetic resins, and as crystals grow around silicates, they act as nucleating agents to further improve the transparency of plastic containers. .

The far-infrared, anion-releasing material extraction method and plastic processing materials, compositions and food containers using the same of the present invention configured as described above increase the dispersibility and blendability of the anion powder in the functional powder to release a large amount of far-infrared and anion, as well as transparency and The antibacterial effect also shows excellent useful effects.

Claims (12)

A first step of dispersing far-infrared and anion-releasing functional powder in water and adding a phosphate to generate an interlayer boundary to neutralize the pH; A second step of removing supernatant and floating impurities from the functional powder dispersion to obtain a supernatant; A third step of extracting an anionic substance in the form of a salt by adding an alkaline substance to the supernatant; And Far-infrared, anion-emitting material extraction method comprising the step of obtaining an extract by removing the content from the extracted material. The method of claim 1, The far-infrared, anion-releasing functional powder is one or more powders selected from ocher, jade, gold, silver, tourmaline, yangyang, ganban stone, giant stone, shells, burlap, green tea, eochocho, pine needles, ginseng, thorny oak, oak and licorice Far infrared, anion emitting material extraction method characterized in that. The method according to claim 1 or 2, The phosphate added in the first step is NaH ₃ CO ₃ Far infrared, anion emitting material extraction method. The method of claim 3, wherein The alkaline material added in the third step is NaCl or Na ₂ CO ₃ Far infrared, anion emitting material extraction method.  Plastic processing material containing far-infrared and anion-releasing material, characterized in that the cationic component of the porous plastic processing material having a cationic component is adsorbed the far-infrared and anion-emitting material extracted by the extraction method of claim 1 or 4. . The method of claim 5, Adding, stirring, and dispersing a porous plastic processing material having a cationic component into the far-infrared anion extractant; Filtering, settling or centrifuging the dispersion to remove the supernatant; Vacuum-drying the porous plastic processing material adsorbed the far-infrared and anion-emitting material in the step; And A plastic processing material containing far-infrared and anion-emitting material, characterized in that it is manufactured by heating the porous plastic processing raw material to 500 ~ 600 ℃ to strengthen the ionic bond to fix the far-infrared, anion-emitting material. The method according to claim 5 or 6, The porous plastic processing material having the cationic component is a plastic silicate containing far-infrared, anion-emitting material, characterized in that the foam silicate. The method of claim 6, The far-infrared, anion-emitting plastic processing material containing the far-infrared, anion-emitting material, characterized in that further comprising the step of powdering by a ball mill after the step of fixing the anion-emitting material. The plastic composition containing far-infrared and anion-emitting material, characterized in that 1 to 15% by weight of the plastic processing material containing the far-infrared, anion-emitting material of claim 5 or 8 in the plastic. The method of claim 9, Plastic composition containing far-infrared, anion-emitting material, characterized in that it further comprises at least one additive selected from a plasticizer, a colorant, CaCO _3, T _i O ₂ and silver nanoparticles. A plastic food container containing far-infrared and anion-releasing material, characterized in that the plastic composition and the synthetic resin of claim 9 or 10 in a predetermined ratio to be pelletized. A plastic food container containing far-infrared and anion-releasing material, comprising 1 to 15% by weight of a pellet and a master batch made of the plastic composition of claim 9 or 10 and 85 to 99% by weight of a synthetic resin.

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