JP7072018B2 - Manufacturing equipment for far-infrared radiation products including sutures - Google Patents

Description

The present invention relates to an apparatus for manufacturing a far-infrared radiation product including a suture.

Infrared light is a kind of light and is an electromagnetic wave having a wavelength longer than that of visible light and shorter than that of microwave. The wavelength range has a range of 0.76 μm to 1,000 μm. Far-infrared refers to an electromagnetic wave that corresponds to the range farthest from visible light when the infrared region is subdivided by wavelength, that is, the range having the longest wavelength and the lowest frequency. Among infrared rays, those having a wavelength of 4 μm or more are called far infrared rays, which absorb the temperature at room temperature and replace it with light energy called far infrared rays to radiate. As for the frequency, the frequency between 20 terahertz and 300 gigahertz is usually classified as far infrared rays.

Far-infrared rays, which are a type of electromagnetic waves, have a wavelength of 8 to 16 μm, which is the most beneficial wavelength for the human body, and when absorbed by the human body, they penetrate deep into the skin (4 to 5 cm), which is 80 times deeper than general heat. Not only kills pathogens (bacteria) and cancer cells (the temperature of the human body is 36.5 degrees, and pathogens such as cancer cells are killed by heat of 41 degrees or higher, but general wet cloth packs kill the skin fat layer. However, far infrared rays have a long wavelength and penetrate into the skin-fat layer-blood vessels-bone to enhance the therapeutic effect. In the case of electrical products, the temperature is too low and the therapeutic effect is low or high. There is a problem of killing normal cells too much.

Far-infrared rays are radiated to the water and protein molecules that make up cells in the human body, and resonate with minute vibrations about 2,000 times per minute to increase the activity of the cells. It acts to raise the body temperature while generating heat energy in the process of cell activity, but when the body temperature rises, the microvessels expand and blood circulation is activated, metabolism is strengthened, and the blood vessels while increasing the ability to regenerate the structure. It breaks down the blood war in the body and promotes blood circulation. Since the blood is clean, the hydrogen ion concentration (pH) is improved to strengthen the ability to improve the constitution from acidic to weakly alkaline, and the relaxing action that is useful for mental health is also effective in relieving the stress that is the cause of adult diseases. be.

The effects of far infrared rays on the human body include increasing the temperature of the subcutaneous layer, dilating microvessels, promoting blood circulation, strengthening the metabolism of blood and the human body and other occupations, eliminating blood disorders, and regenerating ability of the organization. It was revealed that it has an effect of suppressing abnormal excitement of sensory nerves and adjusting the function of autonomic nerves at the same time as it appears due to an increase in antispasmodic ability. Far infrared rays radiate to the surface of human skin at one thermal wavelength, and far infrared rays are almost similar to the vibration wavelength of water in the human body, and have resonance or vibration action. It has the characteristic that it reaches the part where general heat cannot reach.

Far-infrared rays have six effects on the human body, including thermal action, aging action, self-cleaning action, wetting action, neutralizing action, and resonance action. First, the thermal action keeps the human body temperature at an appropriate body temperature. It has the effect of warming the temperature inside the body rather than the body surface temperature (this property is applied as a method for eradicating cancer cells that are vulnerable to high temperatures). And it works to relieve fatigue of hardened muscles. The aging action promotes the growth of the human body. The labor and epithelializing effects of lacerations and burns are very strong, so the healing period is short and no scars remain. The self-cleaning action improves blood circulation in the human body and balances the nutritional supply. The wet and dry action keeps the human body in proper moisture. The neutralizing action promotes the excretion of waste products in the human body and neutralizes the odor. It excretes waste products, harmful heavy metals, pesticides, harmful pigments, etc. accumulated in the body due to vigorous sweating action together with excess fat. In particular, it reduces excess salt that causes lifestyle-related diseases. In addition, impurities that are deeply stained in the skin and cosmetic residues that block the sweat glands and weaken metabolism are excreted together with sweat, and the sebaceous glands are also excreted in excess of subcutaneous fat, resulting in shiny young skin. Play it. Resonance breaks down various nutrients in the human body to maintain nutritional balance.

It has such an effect and is used in various fields such as furniture, housing building materials, textiles, bedding, etc., but it is a natural mineral material that has a far-infrared radiation effect due to far-infrared radiation in various fields. , The material was coated, coated or painted with a powder of natural minerals with far-infrared radiation effect, or the parts were made with powder of natural minerals with far-infrared radiation effect.

However, as in the radon bed case, far-infrared and anion-radiating products manufactured to have a far-infrared effect generated a gas that emits radiation such as radon, which became a problem. Therefore, it is required to prohibit the use of radioactive substances in body-adhesive products.

Therefore, a method has been developed in which far-infrared rays are transferred to an irradiated object at high pressure to produce a far-infrared radiation product, but there is a problem that the far-infrared radiation effect is insignificant and the duration is short. In addition, there is a problem that a high pressure is applied to the tank due to far-infrared transfer and the irradiated object is damaged.

Korean Registered Patent No. 10-141149

An object of the present invention is to provide an apparatus and a method for manufacturing a far-infrared radiation product capable of continuously producing a sufficient far-infrared radiation effect without damaging an irradiated object.

In order to achieve the above object, the present invention has a high-pressure closed chamber in which an object to be irradiated is arranged in an internal space in a far-infrared radiation product manufacturing apparatus, and a far-infrared ray radiating in the chamber. The far-infrared radiation unit includes an infrared radiation unit and an air pressure adjustment unit that adjusts the air pressure in the chamber, and the far-infrared radiation unit contains a mineral powder that radiates far-infrared rays and the mineral powder inside, and is arranged inside the chamber. A high frequency oscillator that oscillates a high frequency so that the inside of the mineral powder container is irradiated with a high frequency, and includes a stirring blade that is arranged inside the mineral powder container and stirs the mineral powder. The high-frequency oscillator provides a far-infrared radiation product manufacturing apparatus characterized by irradiating the inside of the mineral powder container with a high frequency in a range corresponding to the natural frequency of the mineral powder.

The high frequency oscillator is characterized in that the wavelength is in the range of 2400 to 2500 Å.

The stirring blade is made of a far-infrared radiation mineral or ceramic material and is characterized by rotating at 90, 60, or 45 rpm.

The object to be irradiated is arranged in the chamber and further includes a rotating portion to rotate the object to be irradiated, and the rotating portion to be irradiated includes a circular guide groove formed at the bottom of the chamber and a guide groove along the guide groove. A rotating roller that moves on the upper surface, a tray that is arranged on the upper side of the rotating roller and moves along the rotating roller to rotate the irradiated object at the bottom of the chamber, and the rotation. It is characterized by including a rotary motor that rotates a roller.

The air pressure adjusting unit further includes a compressor that pressurizes the inside of the chamber to 10 atm, and an air purification unit that includes a radon filter that purifies the air inside the chamber.

According to another embodiment of the present invention, in the far-infrared radiating suture manufacturing apparatus, a high-pressure closed chamber in which the suture is arranged in an internal space, a far-infrared radiating portion that radiates far-infrared in the chamber, and a far-infrared radiating portion. The far-infrared radiation unit includes an air pressure adjusting unit that adjusts the air pressure in the chamber, and the far-infrared radiation unit contains a mineral powder that radiates far-infrared rays, the mineral powder inside, and a mineral powder container arranged inside the chamber. The high frequency oscillator includes a stirring blade that is arranged inside the mineral powder container and agitates the mineral powder, and a high frequency oscillator that oscillates a high frequency so that the inside of the mineral powder container is irradiated with a high frequency. It is characterized by irradiating the inside of the mineral powder container with a high frequency in a range corresponding to the natural frequency of the mineral powder.

The suture is characterized by being a biodegradable polymer material.

According to the present invention configured as described above, it is possible to provide a suture manufacturing apparatus capable of continuously producing a sufficient far-infrared radiation effect without damaging the irradiated object by high pressure and high temperature.

It is a block diagram which showed schematic structure of the manufacturing apparatus of the far-infrared radiation product by an Example of this invention. It is a schematic road diagram which showed the manufacturing apparatus of the far-infrared radiation product by the Example of this invention. It is a measurement graph of the emissivity of the far-infrared radiation suture manufactured by the manufacturing apparatus of the far-infrared radiation product according to the embodiment of this invention. It is a measurement graph of the radiant energy of the far-infrared radiation suture manufactured by the manufacturing apparatus of the far-infrared radiation product according to the embodiment of the present invention.

Hereinafter, the present invention will be described in more detail through examples. These examples are merely for illustration purposes and are not construed as limiting the scope of the invention by these examples.

FIG. 1 is a block diagram schematically showing the configuration of a far-infrared radiation product manufacturing apparatus according to an embodiment of the present invention, and FIG. 2 is a schematic view of a far-infrared radiation product manufacturing apparatus according to an embodiment of the present invention. It is a drawing shown in.

The far-infrared radiation product manufacturing apparatus 1000 manufactures a functional product that emits far-infrared rays by transferring the far-infrared rays to a product made of fiber, paper, plastic, ceramics, glass, or the like. As shown in the figure, the far-infrared radiation product manufacturing apparatus 1000 is manufactured in a chamber 100 in which the far-infrared radiation product is manufactured, a far-infrared radiation unit 200 that emits far-infrared rays in the chamber 100, and a far-infrared radiation product. The irradiated object rotating portion 300 in which the irradiated object is arranged and rotated, and the air pressure adjusting unit 400 for adjusting the air pressure in the chamber 100 are included.

The chamber 100 is provided with a space inside for accommodating an irradiated object to be manufactured into a far-infrared radiating product by receiving a transfer of far-infrared rays, and is used for high pressure to block direct contact with atmospheric air. The closed chamber 100 can be formed in a cylindrical shape. The chamber 100 is provided with a closed door 110 on one side or both sides of the chamber 100 so that the chamber 100 can be opened and closed while being closed tightly. Although not shown, in order to raise or lower the air pressure inside the chamber 100, a valve for shutting off air and entering and exiting air is installed in connection with the vacuum pump 410 and the compressor 420. The chamber 100 may be further fitted with a pressure safety check valve that is regulated to shut off excessive pressure inside the chamber.

The far-infrared radiation unit 200 stirs the far-infrared radiation mineral powder with a stirring blade and irradiates it with a high frequency so that the far-infrared rays are radiated into the chamber 100. The far-infrared ray emitting unit 200 is arranged inside a far-infrared ray radiating mineral powder 220, a mineral powder container 210 in which the far-infrared ray radiating mineral powder 220 is housed, and a mineral powder container 210, and is arranged inside the mineral powder. A stirring blade 230 that is connected to the stirring blade 230 and rotates the stirring blade 230, and a high frequency oscillator 240 that oscillates a high frequency so that the inside of the mineral powder container 210 is irradiated with a high frequency.

As the far-infrared radiation mineral, monazite, tourmaline, kiyoseki, jade, germanium, charcoal and the like are preferably used. Far-infrared radiation minerals are preferably used in powder form. The particle size of the far-infrared radiation mineral powder 220 is preferably 300 to 700 mesh. The far-infrared radiation mineral powder 220 preferably removes the metal after pulverizing the far-infrared radiation mineral.

The mineral powder container 210 is formed in the shape of a container in which the mineral powder is stored. It is preferable that the mineral powder container 210 is made of heat-resistant glass or ceramic material so that far infrared rays emitted from the mineral powder can be radiated into the chamber 100. The mineral container 210 is preferably made of far-infrared radiation ceramics. The mineral powder container 210 filled with the mineral powder is arranged in the center of the upper part of the chamber 100 so as to transfer far infrared rays evenly to the irradiated object 2000 placed on the tray 310 arranged below the inside of the chamber 100. become.

The stirring blade 230 is preferably made of a far-infrared radiation mineral material or ceramics containing a far-infrared radiation mineral. If the stirring blade 230 is made of far-infrared radiation minerals or ceramics, far-infrared radiation can be enhanced by friction between the stirring blade 230 and the mineral powder.

The stirring motor 250 rotates the stirring blade 230. The stirring motor 250 preferably uses 90, 60, 45 rpm. When it is 100 rpm or more or 30 rpm or less, there is a problem that the far-infrared radiation power of the final far-infrared radiation product is lowered.

The high frequency oscillator 240 oscillates a high frequency inside the mineral powder container 210 through a waveguide. Far infrared rays are radiated by mineral powder by high frequency. The high frequency oscillator 240 preferably oscillates a high frequency having a frequency corresponding to the natural frequency of the mineral powder. The high frequency oscillator 240 preferably oscillates a high frequency close to the natural frequency inside the mineral powder container 210. The high frequency preferably has a wavelength of 700 to 7000 Å. More preferably, the high frequency has a wavelength of 1800 to 2600 Å. Most preferably, the high frequency has a wavelength of 2400-2500 Å. When the high frequency wavelength is 2400 to 2500 Å, the far-infrared radiation power of the final manufactured far-infrared radiation product is the largest.

The irradiated object rotating portion 300 rotates with the irradiated object arranged in the chamber 100. The irradiated object rotating portion 300 is a rotation that rotates a tray 310 on which the irradiated object 2000 is arranged on the upper surface, a rotating roller 320 on the bottom surface such that the tray 310 rotates at the lower part inside the chamber 300, and a rotating roller 320. Includes motor 330. A circular guide groove is formed at the bottom of the chamber 300. The rotary roller 320 is movably located along the guide groove. The tray 310 is arranged on the upper surface of the rotary roller 320, and the irradiated object 2000 is arranged on the upper surface of the tray 310. The drive of the rotary motor 330 causes the rotary roller 320 to rotate along the guide groove, and the tray 310 arranged above the rotary roller 320 rotates along the guide groove. The irradiated object 2000 is rotated by the rotation of the tray 310, and far infrared rays are evenly transferred to the entire irradiated object 2000.

The air pressure adjusting unit 400 adjusts the air pressure in the chamber 100. The air pressure adjusting unit 400 includes a vacuum pump 410, a compressor 420, and an air purifying unit 450. The air pressure adjusting unit 400 pressurizes the inside of the chamber 100 to 10 atm or reduces the pressure to atmospheric pressure by using the vacuum pump 410 and the compressor 420. When the pressure is reduced, the internal air is purified through the air purification unit 450. The air purification unit 450 includes a radioactive substance adsorption filter such as a radon filter, purifies the air inside the chamber contaminated by the radioactive substance generated by the mineral powder, and contaminates the air generated during the manufacture of far-infrared radiation products. It is possible to prevent the user from being exposed to the air. The air pressure adjusting unit 400 pressurizes the pressure inside the chamber 100 to 10 atm when the far-infrared radiation unit 200 is driven, drives the far-infrared radiation unit 200 under 10 atm, and the far-infrared rays are transferred to the irradiated object 2000. To do so.

The far-infrared radiation product manufacturing apparatus according to the embodiment of the present invention further includes a temperature control unit so that the far-infrared ray is transferred at 50 ° C. The temperature control unit prevents the irradiated object 2000 from being damaged by the temperature rise generated by the internal pressurization, and maintains about 50 ° C. to improve the transfer efficiency of far infrared rays.

The method for manufacturing a far-infrared radiation product by the far-infrared radiation product manufacturing apparatus 1000 according to the embodiment of the present invention configured as described above is as follows.

The mineral powder container 210 is filled with the mineral powder 220, the irradiated object 2000 such as a suture is placed on the tray 310, and the tray 310 is placed on the rotating roller 320. The door 110 of the chamber 100 is closed, and the air pressure adjusting unit 400 is driven to boost the air pressure inside the chamber 100 to 10 atm. The rotary motor 330 is rotated to rotate the tray 310 on which the irradiated object 2000 is arranged. The stirring motor 250 is driven and the stirring blade 230 is rotated at 90, 60, 45 rpm inside the mineral powder container 210 filled with the mineral powder 220. A high frequency oscillator 240 is driven to oscillate a high frequency in the natural frequency band of the mineral powder inside the mineral powder container 210. The high frequency oscillator 240 causes a high frequency having a wavelength of 2400 to 2500 Å to be radiated inside the mineral powder container 210. By driving the far-infrared ray emitting unit 200, the transfer of far-infrared rays is advanced to the irradiated object 2000. When the transfer of far infrared rays is completed, the air pressure adjusting unit 400 is driven to purify the air inside the chamber 100 through the air purifying unit 450 and then removed, and the pressure inside the chamber 100 is adjusted to the atmospheric pressure. .. The door 110 is opened and the irradiated object 2000 whose far-infrared transfer is completed by the far-infrared radiation product is taken out.

The irradiated object 2000 for manufacturing a far-infrared radiation product includes a product made of fiber, plastic, ceramics, paper, glass and the like. In particular, the irradiated object 2000 includes sutures. Suture refers to surgical thread. Sutures include PGA sutures and PDO sutures. Sutures include degradable sutures that are broken down and absorbed by the body after being introduced into the human body assembly. The suture is characterized by being a biodegradable polymer material. The suture can consist of a suture thread on the fiber and a needle with a point. It is preferable that the suture is sterilized and packaged and then subjected to far-infrared transfer treatment in the chamber 100.

In FIG. 3, the suture thread package is placed in the far-infrared radiation product manufacturing apparatus configured as described above, and the far-infrared radiation sutures manufactured through the far-infrared transfer process are radiated one week after the manufacture. It is a graph which measured the rate, and FIG. 4 is a measurement graph of radiant energy. As shown in the figure, it can be confirmed that the far-infrared radiation effect continues even after one week has passed.

Further, if the far-infrared radiation product manufacturing apparatus configured as described above is used, even if the suture made of the biodegradable polymer material in the package state is placed on the irradiated object 2000 and far-infrared transfer is performed, the package is packaged. It can be confirmed that neither the suture nor the polymer is damaged, and the suture exerts a sufficient far-infrared radiation effect without directly coating or containing the far-infrared radiation mineral.

According to the far-infrared radiation product manufacturing apparatus according to the embodiment of the present invention configured as described above, a product having sufficient far-infrared radiation efficiency is produced through frequency adjustment of the high-frequency oscillator without applying a high voltage close to 20 atm. It will be possible. Further, if the chamber is pressurized to a high pressure, the temperature inside the chamber rises, and there is a problem that the biodegradable suture thread made of the biodegradable polymer is damaged. However, according to the present invention, the high pressure is applied. Even if it is not added, the far-infrared radiation efficiency and the far-infrared radiation energy can be fully exhibited, and the product can measure the far-infrared radiation effect for a long period of 3 months or more.

Claims (7)

In the manufacturing equipment for far-infrared radiation products
A high-pressure closed chamber in which the object to be irradiated is placed in the internal space,
A far-infrared ray emitting part that radiates far-infrared rays in the chamber,
An air pressure adjusting unit that adjusts the air pressure in the chamber ,
Includes a temperature control unit that maintains the temperature inside the chamber at a predetermined temperature .
The far-infrared emitting unit is arranged inside the mineral powder having an adjusted particle size for radiating far-infrared, a mineral powder container in which the mineral powder is housed and arranged inside the chamber, and the mineral powder container. , A stirring blade that stirs the mineral powder, and a high frequency oscillator that oscillates the high frequency so that the inside of the mineral powder container is irradiated with the high frequency.
The high-frequency oscillator is an apparatus for manufacturing a far-infrared radiation product, which irradiates the mineral powder inside the mineral powder container with a high frequency in a range corresponding to the natural frequency of the mineral powder. The far-infrared radiation product manufacturing apparatus according to claim 1, wherein the high-frequency oscillator has a wavelength in the range of 2400 to 2500 Å. The far-infrared radiation product manufacturing apparatus according to claim 1, wherein the stirring blade is made of a far-infrared radiation mineral or ceramic material and rotates at 90, 60, or 45 rpm. The object to be irradiated is arranged in the chamber, and further includes a rotating portion of the object to be irradiated to rotate.
The irradiated object rotating portion is
A circular guide groove formed at the bottom of the chamber,
A rotating roller that moves along the guide groove,
A tray in which the irradiated object is loaded on the upper surface, is arranged on the upper surface of the rotating roller, moves along the rotating roller, and rotates the irradiated object at the bottom of the chamber.
The far-infrared radiation product manufacturing apparatus according to claim 1, further comprising a rotary motor for rotating the rotary roller. The air pressure adjusting unit is
A compressor that pressurizes the inside of the chamber to 10 atm, and
The far-infrared radiation product manufacturing apparatus according to claim 1, further comprising an air purification unit including a radon filter that purifies the air inside the chamber. In the far-infrared radiation suture manufacturing equipment
A high-pressure closed chamber in which the far-infrared radiation suture is placed in the internal space,
A far-infrared ray emitting part that radiates far-infrared rays in the chamber,
An air pressure adjusting unit that adjusts the air pressure in the chamber ,
Includes a temperature control unit that maintains the temperature inside the chamber at a predetermined temperature .
The far-infrared emitting unit is arranged inside the mineral powder having an adjusted particle size for radiating far-infrared, a mineral powder container in which the mineral powder is housed and arranged inside the chamber, and the mineral powder container. , A stirring blade that stirs the mineral powder, and a high frequency oscillator that oscillates the high frequency so that the inside of the mineral powder container is irradiated with the high frequency.
The high-frequency oscillator is an apparatus for producing far-infrared radiation sutures, which irradiates the mineral powder inside the mineral powder container with a high frequency in a range corresponding to the natural frequency of the mineral powder. The device for producing a far-infrared radiation suture according to claim 6 , wherein the far-infrared radiation suture is made of a biodegradable polymer material.

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