KR101327699B1 - Apparatus for manufacturing functional products radiating negative ions and infrared rays - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing functional products radiating negative ions and infrared rays. The apparatus comprises a chamber having an accommodation space, a high-frequency oscillator generating high frequency, a waveguide which connects to the high-frequency oscillator and extends to the inside of the chamber, a plate which is adjacent to the waveguide and has a constant area, mineral powder which is accommodated in the plate, a far infrared ray radiation part which is arranged on the top or side of the plate and radiates far infrared rays, and a door formed on the side of the far infrared ray radiation part. According to the configuration, an apparatus for manufacturing functional products radiating far infrared rays and anions from mineral powder arranged within the chamber can be provided.

Description

Apparatus for manufacturing functional products radiating negative ions and infrared rays

The present invention relates to an apparatus for producing a functional product that emits far infrared rays and anions.

Modern people live by wearing clothes made of fibers and eating or drinking beverages or food in paper, plastic, or ceramic containers.

Recently, functional fibers, papers, plastics, ceramics, and the like, which have added various functions in addition to the natural functions of such fibers, paper, plastics, ceramics, and the like, have been developed. For example, there are functional fibers having functions such as waterproofing, fragrance, and heat generation.

In this way, it is possible to make the human life more convenient and profitable by giving special function to the raw materials (fiber, paper, plastic, ceramic, glass, etc.) of the product closely related to the human life.

Far infrared rays mean long wavelengths among infrared rays. In general, light has a short wavelength and reflects well, and a long wavelength has a property of being absorbed well when it reaches an object. This heat action helps to eliminate the bacteria that cause various diseases and expands capillaries to help blood circulation and cell tissue production. In addition, far infrared rays are effective in preventing various adult diseases such as anti-aging, promoting metabolism, and chronic fatigue.

In addition, it has effects such as sweating, pain relief, heavy metal removal, sleep, deodorization, antibacterial, mold propagation prevention, dehumidification, and air purification, so that it can be used for housing and construction materials, kitchen utensils, textiles, beddings, medical devices, jjimjilbang. Is used in the field

On the other hand, the ion which has a negative charge in air | atmosphere is called anion. These negative ions are light and are very active because they can roam freely in the atmosphere. Drinking negative ions promotes cell metabolism, boosts vitality, clears blood, and is effective for nerve stabilization, fatigue recovery and appetite.

In this way, in addition to the natural functions of the raw materials of the product closely related to human life, by special treatment to the raw materials to have a special function, for example, the beneficial effect of far infrared rays or negative ions so that the raw materials can emit far infrared rays or negative ions. There is a need for a device to do this.

Republic of Korea Patent Application No. 10-2008-0059321

Accordingly, the present invention has been invented in view of the above circumstances, and is intended to manufacture functional products that emit far infrared rays and anions such that fibers, paper, plastic, ceramics, glass, etc., which are closely related to human life, may emit far infrared rays or anions. The purpose is to provide a device.

According to an aspect of the present invention for achieving the above object, an apparatus for producing a functional product that emits far infrared rays and negative ions, the chamber having a receiving space; A high frequency oscillator for generating a high frequency; A waveguide connected to the high frequency oscillator and extending into the chamber; A plate disposed adjacent said waveguide and having a constant volume; Mineral powder contained in the plate; A far infrared radiation unit disposed on the upper side or the side of the plate to emit far infrared rays; A door formed on the side of the chamber; .

In addition, a vacuum pump for sucking the inside of the chamber; A compressor for pressurizing the inside of the chamber; .

In addition, a vibrator for vibrating the plate; .

In addition, the mineral is at least one selected from magnesium, germanium, selenium, dolomite, illite, montmorillonite.

In addition, the mineral powder is nano-powdered to 100 to 800nm size.

In addition, the high frequency oscillator generates a high frequency in the range of 1 to 500 GHz.

In addition, the mineral powder is heat-treated at a temperature of 500 to 800 ℃.

In addition, a plurality of blowing fans disposed in the chamber; .

According to the present invention, it is possible to provide a device for manufacturing a functional product that emits far infrared rays and anions by allowing the product to absorb the far infrared rays and anions generated from the mineral powder disposed in the chamber.

1 is a diagram showing the configuration of an apparatus for producing a functional product that emits far infrared rays and anions according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a state in which anions are generated and absorbed by a product in the apparatus of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

1 is a diagram showing the configuration of an apparatus for producing a functional product that emits far infrared rays and anions according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a state in which anions are generated and absorbed by a product in the apparatus of FIG. 1.

The device (hereinafter, referred to as a device) for manufacturing a functional product that emits far infrared rays and anions of the present invention includes a product made of fiber, paper, plastic, ceramic, glass, etc. in a chamber and absorbs far infrared rays and anions in such products. To make functional products. Products absorbing far infrared rays and anions in the apparatus of the present invention become functional products capable of emitting far infrared rays and anions when used in daily life. Far infrared rays have the effect of antibacterial action, resonance action, odor, neutralization action to remove toxic, harmful substances, etc., anti-aging, promoting metabolism, increasing immunity. In addition, the enemy has the effects of sweating, pain relief, heavy metal removal, sleep, deodorization, antibacterial, mold growth prevention, dehumidification, air purification. Negative ions are known as vitamins of the air because they promote metabolism, boost vitality, clear blood, stabilize nerves, restore fatigue, and increase appetite.

The apparatus 100 includes a chamber 110, a high frequency oscillator 120, a waveguide 121, a plate 130, a vibrator 131, a mineral powder 135, a far infrared radiation unit 140, and a vacuum pump 150. , The compressor 160, the door 170, the blowing fan 180, and the like.

The chamber 110 has a receiving space in which various parts are accommodated, and provides a place where the product 20 can absorb far infrared rays and negative ions. The chamber 110 may have a cylindrical shape of cylindrical or polygonal shape. The door 110 is formed in the chamber 110 so that the product 20 can be withdrawn.

The high frequency oscillator 120 generates a high frequency to be irradiated into the chamber 110. The high frequency may have a frequency in the microwave to far infrared range. The high frequency generated by the high frequency oscillator 120 may have, for example, a range of 1 to 500 GHz.

The high frequency generated by the high frequency oscillator 120 may be moved into the chamber 110 through the waveguide 121. The waveguide 121 is connected to the high frequency oscillator 120 and extends into the chamber 110.

The plate 130 is disposed adjacent to the waveguide 121 and has a constant volume. The mineral powder 135 is accommodated in the plate 130. The vibrator 131 may be connected to the plate 130 to vibrate the plate 130. The plate 130 may be made of any one of glass, ceramic, and polypropylene that may absorb and emit far infrared rays.

The mineral powder 135 may be a material capable of absorbing and radiating far infrared rays and generating negative ions. Generally, the anion-generating minerals are minerals with high mineral content and are alkali materials containing a lot of metal ions. Mineral powder 135 is preferably nano-powdered to 100 to 800nm size. Mineral powder may be heat treated at a temperature of 500 to 800 ℃.

The mineral powder 135 may be selected from one or more of magnesium, germanium, selenium, dolomite, illite, and montmorillonite.

Magnesium is an alkaline earth metal belonging to group 2 of the periodic table. The element symbol is Mg, atomic number 12, and atomic weight 24.3050. Magnesium does not exist as a single element in nature but in the form of a salt combined with silicic acid, sulfuric acid or carbonic acid. Magnesium has a property of emitting a large amount of far infrared rays.

Germanium is a solid, light gray semimetal element, has the element symbol Ge, atomic number 32, and atomic weight 72.59, and belongs to group 4 in the periodic table. Germanium is mainly a by-product of zinc and copper, produced in the form of oxides, and is also slightly contained in coal. Germanium has a property of emitting a large amount of far-infrared rays, and facilitates absorption by lengthening wave energy of far-infrared rays.

Selenium has an atomic number of 34 and is a trace mineral and antioxidant that is essential for various functions in the body. The antioxidant activity of selenium enhances detoxification and immune function and reduces the damage of ultraviolet rays, X-rays, and radiation to prevent and treat cancer, liver disease, kidney disease and arthritis.

Dolomite is a trigonal mineral, formed by the dolomite of calcite, similar to calcite. Dolomite has a hardness of 3.5-4, specific gravity of 2.8-2.9, and is white, gray or pink, yellow, brown and green. Dolomite is transparent or translucent and has a glass luster, with crystals sometimes pearly. Dolomite has a property of emitting a large amount of far infrared rays.

Illite is a mica mineral belonging to the monoclinic system. The hardness of the illite is 1-2, the specific gravity is 2.6-2.9, and the streak color is white. Illite is composed of silica, iron, sodium, alumina, magnesium and the like. Illite has a property of emitting a large amount of far infrared rays, and functions to generate negative ions.

Montmorillonite is a monoclinic mineral that is a type of clay mineral. Montmorillonite has a hardness of 1-1.5, specific gravity of 2-1.5, white, gray, pink, blue, or green. Montmorillonite has the property of absorbing water and increasing its volume by 7 to 10 times, and has high ion exchangeability.

The far infrared radiation unit 140 is disposed on the upper portion of the plate 130 to emit far infrared rays. The far infrared radiation unit 140 receives power from the outside of the chamber 110 and emits light and heat of far infrared wavelengths. The far infrared radiation unit 140 may be disposed adjacent to the product 20 aligned on the support 101 to radiate far infrared rays directly to the product 20. The far infrared radiation unit 140 may be selected from lighting devices such as incandescent bulbs, halogen bulbs, and LED bulbs. The wavelength of far infrared rays may be 1-50 micrometers.

Far infrared rays radiated from the far infrared radiation unit 140 may be absorbed by the mineral powder 135. The mineral powder 135 absorbs far infrared rays and radiates far infrared rays into the chamber 110 again.

The interior of the chamber 110 may be changed to a high pressure state above the vacuum or atmospheric pressure, depending on the needs of the process. To this end, the device 100 may include a vacuum pump 150 for sucking the inside of the chamber 110 and a compressor 160 for pressurizing the inside of the chamber 110.

A plurality of blowing fans 180 may be disposed in the chamber 110. The blowing fan 180 activates the flow of negative ions in the chamber 110 to allow the negative ions to be absorbed into the product 20 well.

Hereinafter, a method of manufacturing the product 20 that emits far infrared rays and negative ions using the apparatus 100 according to the embodiment of the present invention will be described.

First, the door 170 is opened and the product 20 is aligned in the chamber 110. The product 20 may be a garment, a wrapping paper, a container, or the like having a material of fiber, paper, plastic, ceramic, glass, or the like. At this time, the product 20 can be aligned on the support 101 by entering the chamber 110 on the tray 10 to raise the tray 10 on the support 101. The product 20 is disposed on the tray 10 to be spaced apart in a zigzag form without overlapping each other, so as to absorb far infrared rays and negative ions as much as possible. In the figure, the product 20 represents a container, but the product 20 may be various objects such as clothing, wrapping paper, and the like.

Next, the high frequency generated by the high frequency oscillator 120 moves along the waveguide 121 and is irradiated into the chamber 110. At this time, the high frequency may have a frequency in the range of 1 to 500 GHz.

These high frequencies are irradiated with the mineral powder 135 contained in the plate 130, so that negative ions can be generated from the mineral powder 135. The material of the plate 130 may be made of any one of glass, ceramic, and polypropylene, which may absorb high frequency well. At this time, the vibrator 131 vibrates the plate 130 so that the mineral powders 135 rub against each other to more actively generate negative ions.

The far infrared radiation unit 140 irradiates the far infrared rays with the mineral powder 135 placed on the plate 130 to allow the mineral powder 135 to absorb the far infrared rays. The interior of the chamber 110 may be maintained at 50 to 80 ℃ for radiation and absorption of far infrared rays.

The mineral powder 135 may be nano-powdered to a size of 100 to 800 nm and easily heat-treated at a temperature of 500 to 800 ° C. to facilitate absorption of far infrared rays. The mineral powder 135 absorbing light and heat again radiates far infrared rays into the chamber 110 so that such far infrared rays can be absorbed into the product 20. The mineral powder 135 that absorbs heat may be more active in generating anions. Far infrared radiation unit 140 is also located in the portion adjacent to the product 20 so that the far infrared ray can be directly absorbed by the product (20).

While the far infrared rays and negative ions are generated, the pressure inside the chamber 110 may be adjusted to a high pressure above the negative pressure or the atmospheric pressure by the vacuum pump 150 or the compressor 160 as necessary.

The blowing fan 180 may be operated so that negative ions generated from the mineral powder 135 may be evenly distributed in the chamber 110 and absorbed well in the product 20.

As such, the product 20 that absorbs far infrared rays and negative ions in the chamber 110 may emit negative ions and emit far infrared rays at a predetermined temperature or more when used in daily life. Such a product 20 becomes a functional product having the efficacy of far infrared rays and anions as it is.

As described above, the device 100 according to an embodiment of the present invention allows the product 20 arranged in the chamber 110 to absorb far infrared rays and negative ions so that when such product 20 is used in real life, far infrared rays are used. It becomes a functional product that radiates anions and anions.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

10 tray
20: Product
100: apparatus for manufacturing functional products
101: support
110: chamber
120: high frequency oscillator
121: waveguide
130: plate
131: vibrator
135: mineral powder
140: far infrared radiation unit
150: Vacuum pump
160: Compressor
170: door
180: blower fan

Claims (8)

delete delete A device for producing a functional product that emits far infrared rays and anions,
A chamber having a receiving space;
A high frequency oscillator for generating a high frequency;
A waveguide connected to the high frequency oscillator and extending into the chamber;
A plate disposed adjacent said waveguide and having a constant volume;
Mineral powder contained in the plate;
A far infrared radiation unit disposed on the upper side or the side of the plate to emit far infrared rays;
A door formed on the side of the chamber;
A vacuum pump for sucking inside the chamber;
A compressor for pressurizing the inside of the chamber;
A vibrator for vibrating the plate;
Apparatus for producing a functional product that emits far infrared rays and anions comprising a. The method of claim 3,
The mineral is an apparatus for producing a functional product that emits far infrared rays and anions selected from at least one selected from magnesium, germanium, selenium, dolomite, illite, montmorillonite. 5. The method of claim 4,
The mineral powder is a device for producing a functional product that emits far infrared rays and anions are nano-powdered to 100 to 800nm size. 5. The method of claim 4,
The high frequency oscillator is a device for manufacturing a functional product that emits far infrared rays and negative ions generating high frequencies in the range of 1 to 500 GHz. 7. The method according to any one of claims 3 to 6,
The mineral powder is a device for producing a functional product that emits far infrared rays and anions are heat-treated at a temperature of 500 to 800 ℃. 7. The method according to any one of claims 3 to 6,
A plurality of blowing fans disposed in the chamber;
Apparatus for producing a functional product that emits far infrared rays and negative ions further comprising.

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