阅读说明：本技术 包括缝合线的远红外线辐射产品制造设备 (Far infrared ray radiation product manufacturing apparatus including suture thread ) 是由 林载钐 于 2020-05-28 设计创作，主要内容包括：本发明提供一种包括缝合线的远红外线辐射产品制造设备,包括：在内部空间配置被辐射物的高压封闭型腔室；在所述腔室内辐射远红外线的远红外线辐射部；调整所述腔室内的空气压力的空气压力调整部；所述远红外线辐射部包括：辐射远红外线的矿物粉末；在内部容纳所述矿物粉末并配置在所述腔室内侧的矿物粉末容纳器；配置在所述矿物粉末容纳器内部并且搅拌矿物粉末的搅拌叶片；及振荡高频波而使得高频波照射到所述矿物粉末容纳器内部的高频波振荡器,所述高频波振荡器将与所述矿物粉末的固有频率对应的范围的高频波照射到所述矿物粉末容纳器内部。(The present invention provides a far infrared ray radiation product manufacturing apparatus including a suture thread, comprising: a high-pressure closed chamber in which a radiation object is disposed in an internal space; a far infrared ray radiation part for radiating far infrared ray in the chamber; an air pressure adjusting unit for adjusting the air pressure in the chamber; the far infrared ray radiation part includes: mineral powder radiating far infrared rays; a mineral powder container configured inside the chamber and containing the mineral powder; a stirring blade disposed inside the mineral powder container and stirring mineral powder; and a high-frequency wave oscillator for oscillating a high-frequency wave to irradiate the inside of the mineral powder container with the high-frequency wave in a range corresponding to a natural frequency of the mineral powder.)

1. An apparatus for manufacturing far infrared ray radiation products, comprising:

a high-pressure closed chamber, an internal space of which is provided with an object to be irradiated;

a far infrared ray radiation part radiating far infrared rays in the chamber;

an air pressure adjusting portion that adjusts air pressure in the chamber,

the far infrared ray radiating section includes:

a mineral powder radiating far infrared rays;

a mineral powder container that contains the mineral powder therein and is disposed inside the chamber;

a stirring blade disposed inside the mineral powder container for stirring mineral powder; and

a high-frequency wave oscillator for oscillating a high-frequency wave to irradiate the inside of the mineral powder container with the high-frequency wave,

the high-frequency oscillator irradiates a high-frequency wave in a range corresponding to a natural frequency of the mineral powder into the mineral powder container.

2. The far infrared ray radiation product producing apparatus as set forth in claim 1,

the high-frequency wave oscillator has a wavelength ofOr evenAnd (3) a range.

3. The far infrared ray radiation product producing apparatus as set forth in claim 1,

the stirring blade is made of far infrared ray radiation mineral or ceramic material and rotates at 90rpm, 60rpm or 45 rpm.

4. The far infrared ray radiation product manufacturing apparatus as set forth in claim 1, further comprising:

a radiation-receiving object rotating section that rotates within the chamber and on which the radiation-receiving object is disposed;

the radiation-receiving object rotating section includes:

a circular guide groove formed on a bottom surface of the chamber;

a rotating roller moving along the guide groove;

a tray on which an object to be irradiated is loaded, the tray being disposed above the rotating rollers and moving along the rotating rollers so that the object to be irradiated rotates on the bottom surface of the chamber; and

a rotation motor that rotates the rotation roller.

5. The far infrared ray radiation product producing apparatus as set forth in claim 1,

the air pressure adjusting portion further includes:

a compressor pressurizing the interior of the chamber to 10 atmospheres; and

an air purification part including a radon filter for purifying air inside the chamber.

6. A far infrared ray radiation suture thread manufacturing apparatus, characterized by comprising:

a high-pressure closed chamber, an inner space of which is configured with a suture line;

a far infrared ray radiation part radiating far infrared rays in the chamber;

an air pressure adjusting portion that adjusts air pressure in the chamber,

the far infrared ray radiating section includes:

a mineral powder radiating far infrared rays;

a mineral powder container that contains the mineral powder therein and is disposed inside the chamber;

a stirring blade disposed inside the mineral powder container for stirring mineral powder; and

a high-frequency wave oscillator for oscillating a high-frequency wave to irradiate the inside of the mineral powder container with the high-frequency wave,

the high-frequency oscillator irradiates a high-frequency wave in a range corresponding to a natural frequency of the mineral powder into the mineral powder container.

7. The far infrared ray radiation suture thread producing apparatus as set forth in claim 6,

the suture is formed from a biodegradable polymeric material.

Technical Field

The present invention relates to a far infrared ray radiation product manufacturing apparatus including a suture thread.

Background

The infrared ray is one of the rays, and is an electron wave having a longer wavelength than the visible ray and a shorter wavelength than the microwave. The wavelength region has a range of 0.76 μm or even 1,000 μm. The far infrared ray is an electromagnetic wave that is farthest from a visible ray when an infrared ray region is made fine according to wavelength, that is, belongs to a range having the longest wavelength and the smallest oscillation frequency. Among the infrared rays, those having a wavelength of more than 4 μm are far infrared rays, which replace absorbed normal temperature with light energy of the far infrared rays and radiate the same. Frequencies between 20 terahertz and 300 gigahertz are generally distinguished as far infrared rays.

The far infrared ray is one of electronic waves, has a wavelength of 8-16 mu m most beneficial to a human body, and can permeate into a skin deep layer (4-5 cm) which is 80 times deeper than common heat energy to kill bacteria or cancer cells when being absorbed by the human body. The common hot compress patch can not pass through the skin fat layer, and the far infrared ray has longer wavelength and can permeate into the skin-fat layer-blood vessel-bone to improve the treatment effect. Far infrared rays are radiated to water and protein molecules constituting cells in the human body to cause the cells to actively move with minute oscillation resonance of 2,000 times per minute. The heat energy is generated in the process of cell activity to improve the body temperature, the micro blood vessels expand along with the improvement of the body temperature, and the blood circulation becomes active, so that the metabolism is strengthened, the tissue regenerative power is increased, and therefore the thrombus in the blood vessels can be decomposed, and the blood circulation is promoted. Since the blood becomes clear and the hydrogen ion concentration (pH) is increased, the ability to improve the body constitution from acidity to slightly alkalinity is enhanced, and since the relief effect possessed by it is helpful for mental health, it is also effective for relieving stress which is one of the causes of adult diseases.

Far infrared rays have effects of raising the temperature of subcutaneous layer, dilating blood capillary, promoting blood circulation, strengthening metabolism of blood and human body and other tissues, clearing blood disorder, enhancing tissue regeneration ability and antispasmodic ability, etc. to human body, and also have effects of inhibiting abnormal excitation of sensory nerve and regulating autonomic nerve function. Far infrared rays (far infrared rays) are used as a thermal wavelength, and far infrared rays radiated to the skin surface of a human body have almost the same oscillation wavelength as water in the human body, and can reach a part where ordinary heat energy cannot reach through resonance (resonance) or resonance (resonance) action.

Far infrared rays have 6 major effects on human bodies, such as warming, ripening, self-cleaning, wetting and drying, neutralization, resonance and the like. First, the warming action maintains the body temperature of the human body to an appropriate body temperature. It acts to warm the body temperature compared to the body surface. And plays a role in relieving muscle fatigue. The ripening action accelerates the growth of the human body. Has excellent analgesic effect and epithelialization effect on scald or burn, and has short healing time and no scar. The self-cleaning function optimizes blood circulation in human body and keeps balance of nutrition supply. The action of dry and wet maintains proper water in human body. The neutralizing effect promotes the excretion of metabolites in the human body and neutralizes the taste. Metabolites or harmful heavy metals, pesticides, harmful pigments accumulated in the body are excreted together with the surplus fat components to the outside of the body by the vigorous sweating. In particular, excess salt content, which is one of the causes of lifestyle-related diseases, is reduced. And can discharge impurities penetrating deep into skin, cosmetic dregs blocking sweat pores to weaken metabolism together with sweat, and can discharge excessive components of subcutaneous fat in sebaceous glands to regenerate glossy young skin. The resonance action decomposes various nutrients of the human body to maintain the balance of the nutrients.

Because of these effects, far infrared rays are widely used in various fields such as furniture, building materials for housing, fibers, bedding, and the like, and in various fields, for the radiation of far infrared rays, a method of coating, painting, or coloring with a material made of natural minerals having a far infrared ray radiation effect, or with powder of natural minerals having a far infrared ray radiation effect, or a method of making a member with powder of natural minerals having a far infrared ray radiation effect is used.

However, in far-infrared and negative-ion radiation products manufactured to have a far-infrared effect like a radon air bed event, there is a problem in that gas emitting radiation like radon is generated. Thus, it is required to prohibit the use of radioactive substances in products in close proximity to the body.

Therefore, a method of manufacturing a far infrared ray radiation product by transferring far infrared rays to an object to be irradiated under high pressure has been developed, but there is a problem that the far infrared ray radiation effect is weak and the duration is short. And there is a problem that a high pressure is applied to the container in order to transfer the far infrared ray, thereby causing damage to the irradiated object.

Prior art documents

Patent document

(patent document 1) Korean registered patent No. 10-1141149

Disclosure of Invention

Technical problem to be solved

The invention aims to provide a far infrared radiation product manufacturing device and a method, which can keep an object to be radiated undamaged and can continuously radiate sufficient far infrared rays.

Means for solving the problems

In order to achieve the above objects, the present invention provides a far infrared ray radiation product manufacturing apparatus,

a far infrared ray radiation product manufacturing apparatus,

the method comprises the following steps: a high-pressure closed chamber, an internal space of which is provided with an object to be irradiated;

a far infrared ray radiation part radiating far infrared rays in the chamber;

an air pressure adjusting portion that adjusts air pressure in the chamber,

the far infrared ray radiating section includes: a mineral powder radiating far infrared rays; a mineral powder container that contains the mineral powder therein and is disposed inside the chamber; a stirring blade disposed inside the mineral powder container for stirring mineral powder; and a high-frequency wave oscillator for oscillating a high-frequency wave to irradiate the inside of the mineral powder container with the high-frequency wave,

the high-frequency oscillator irradiates a high-frequency wave in a range corresponding to a natural frequency of the mineral powder into the mineral powder container.

The high-frequency wave oscillator has a wavelength ofOr evenThe ranges are characteristic.

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

The radiation-receiving object rotating part rotates in the chamber, and the radiation-receiving object rotating part is provided with the radiation-receiving object;

the radiation-receiving object rotating section includes:

a circular guide groove formed on the bottom surface of the chamber;

a rotating roller moving along the guide groove;

a tray on which an object to be irradiated is loaded, the tray being disposed above the rotating rollers and moving along the rotating rollers so that the object to be irradiated rotates on the bottom surface of the chamber; and

a rotation motor that rotates the rotation roller.

The air pressure adjusting portion further includes:

a compressor pressurizing the interior of the chamber to 10 atmospheres; and

an air purification part including a radon filter for purifying air inside the chamber.

In accordance with a further embodiment of the present invention,

a far infrared ray radiation suture thread producing apparatus comprising:

a high-pressure closed chamber, an inner space of which is configured with a suture line;

a far infrared ray radiation part radiating far infrared rays in the chamber;

an air pressure adjusting portion that adjusts air pressure in the chamber,

the far infrared ray radiating section includes: a mineral powder radiating far infrared rays; a mineral powder container that contains the mineral powder therein and is disposed inside the chamber; a stirring blade disposed inside the mineral powder container for stirring mineral powder; and a high-frequency wave oscillator for oscillating a high-frequency wave to irradiate the inside of the mineral powder container with the high-frequency wave,

the high-frequency oscillator irradiates a high-frequency wave in a range corresponding to a natural frequency of the mineral powder into the mineral powder container.

The suture is characterized by being formed of a biodegradable polymer material.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the above constitution, the present invention can provide a suture thread manufacturing apparatus which can continuously generate a sufficient far infrared radiation effect without damaging an object to be irradiated by high pressure and high temperature.

Drawings

FIG. 1 is a block diagram schematically showing the constitution of a far infrared radiation product manufacturing apparatus according to an embodiment of the present invention.

Fig. 2 is a schematic view showing a far infrared radiation product manufacturing apparatus according to an embodiment of the present invention.

Fig. 3 is a graph of emissivity measurement of a far infrared ray radiating suture thread manufactured by a far infrared ray radiating product manufacturing apparatus according to an embodiment of the present invention.

Fig. 4 is a graph of measuring radiant energy of a far infrared ray radiating suture thread manufactured by a far infrared ray radiating product manufacturing apparatus according to an embodiment of the present invention.

Detailed Description

The present invention will be described in more detail below with reference to examples. These examples are only for illustrating the present invention and should not be construed as limiting the scope of the present invention by these examples.

Fig. 1 is a block diagram schematically showing the constitution of a far infrared radiation product manufacturing apparatus according to an embodiment of the present invention, and fig. 2 is a diagram showing the far infrared radiation product manufacturing apparatus according to the embodiment of the present invention.

The far infrared ray radiation product manufacturing apparatus 1000 manufactures a product that radiates far infrared rays by transcribing far infrared rays on a product made of fiber, paper, plastic, ceramic, glass, or the like. As shown in the drawing, the far infrared radiation product manufacturing apparatus 1000 includes: a chamber 100 for manufacturing far infrared ray radiation products, a far infrared ray radiation part 200 for radiating far infrared rays into the chamber 100, a rotation part 300 for rotating an object to be radiated which is manufactured by the far infrared ray radiation products, and an air pressure adjusting part 400 for adjusting the air pressure in the chamber 100.

The chamber 100 is provided with a space for receiving an object to be irradiated, which is to be transferred with far infrared rays and then manufactured into a far infrared ray radiation product, and may be formed in a cylindrical shape as a high pressure closed chamber 100 blocking direct contact with atmospheric air. A closing door 110 that can close the chamber 100 and can be opened and closed is provided at one side surface or both side surfaces of the chamber 100. Although not shown, a valve is connected to the vacuum pump 410 and the compressor 420 to block or introduce air in order to increase or decrease the air pressure inside the chamber 100. The chamber 100 may also be provided with a pressure safety check valve that may be adjusted in order to block excessive pressure inside the chamber.

The far infrared radiation part 200 stirs the far infrared radiation mineral powder with the stirring blade and irradiates high frequency waves, thereby radiating far infrared rays to the inside of the chamber 100. The far infrared ray radiating part 200 includes: a powder 220 of far infrared ray radiating minerals radiating far infrared rays, a mineral powder container 210 containing the powder 220 of far infrared ray radiating minerals therein, a stirring blade 230 disposed inside the mineral powder container 210 for stirring mineral powder, a stirring motor 250 connected to the stirring blade 230 and rotating the stirring blade 230, and a high frequency wave oscillator 240 oscillating a high frequency wave to irradiate the high frequency wave to the inside of the mineral powder container 210.

The far infrared ray radiating mineral is preferably monazite, tourmaline, melilite, melissite, jade, germanium, charcoal, etc. The far infrared radiating mineral is preferably in the form of powder. The particle size of the powder 220 of far infrared ray radiating minerals is preferably 300 to 700 mesh. The powder 220 of the far infrared ray radiating minerals is preferably a powder obtained by pulverizing the far infrared ray radiating minerals and then removing the metals.

The mineral powder container 210 is formed in the shape of a container containing mineral powder. The mineral powder receptacle 210 is preferably formed of a pyrex or ceramic material so that far infrared rays radiated from the mineral powder are radiated to the inside of the chamber 100. The mineral container 210 is preferably made of far infrared radiation ceramic. The mineral powder container 210 filled with mineral powder is disposed at the center of the upper portion of the chamber 100, and uniformly transfers far infrared rays to the object to be irradiated 2000 placed on the tray 310 disposed below the inside of the chamber 100.

The agitating blade 230 is preferably formed of a far infrared radiating mineral material or a ceramic including a far infrared radiating mineral. The use of far infrared radiation minerals or ceramics for the agitating blade 230 can enhance far infrared radiation by friction between the agitating blade 230 and the minerals.

The stirring motor 250 rotates the stirring blade 230. The stirring motor 250 is preferably used at 90, 60, 45 rpm. The case of more than 100rpm or less than 30rpm may have a problem that the far infrared ray radiation power of the final far infrared ray radiation product is lowered.

The high-frequency wave oscillator 240 oscillates a high-frequency wave through the waveguide toward the inside of the mineral powder container 210. The high frequency wave causes the mineral powder to radiate far infrared rays. The high-frequency wave oscillator 240 preferably oscillates a high-frequency wave having a frequency corresponding to a natural frequency (natural frequency) of the mineral powder. The high-frequency wave oscillator 240 oscillates a high-frequency wave having a frequency close to the natural frequency toward the inside of the mineral powder container 210. The wavelength of the high-frequency wave is preferablyOr evenThe wavelength of the high frequency wave is more preferablyOr evenThe wavelength of the high frequency wave is most preferablyOr evenA high frequency wave having a wavelength ofOr evenWhen the product is used, the far infrared radiation strength of the finally manufactured far infrared radiation product is strongest.

The irradiation target rotating part 300 rotates in the chamber 100, and the irradiation target is disposed thereon. The irradiation target rotating unit 300 includes: a tray 310 on which the object 2000 to be irradiated is placed, a rotary roller 320 which is placed on the bottom surface so that the tray 310 rotates at the lower portion inside the chamber 300, and a rotary motor 330 which rotates the rotary roller 320. The bottom surface of the chamber 300 is formed with a circular guide groove. The rotating roller (320) is located at a position movable along the guide groove. The tray 310 is disposed above the rotary rollers 320, the radiation object 2000 is disposed on the upper surface of the tray 310, the rotary rollers 320 are rotated along the guide grooves by the driving of the rotary motor 330, and the tray 310 disposed above the rotary rollers 320 is rotated along with the rotary rollers 320. The irradiated object 2000 rotates with the rotation of the tray 310, and the far infrared rays are uniformly transferred to the entire irradiated object 2000.

The air pressure adjusting part 400 adjusts the air pressure within 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 part 400 reduces the pressure inside the chamber 100 to 10 atm or atmospheric pressure using the vacuum pump 410 and the compressor 420. The inside air is purified by the air purifying part 450 at the time of decompression. The air cleaning part 450 includes a filter for absorbing a radioactive substance, such as a radon filter, thereby cleaning the air inside the chamber contaminated by the radioactive substance generated in the mineral powder, thereby preventing the user from being exposed to the contaminated air generated when the far infrared radiation product is manufactured. When the far infrared radiation part 200 is driven, the air pressure adjusting part 400 pressurizes the air pressure inside the chamber 100 to 10 air pressures, thereby driving the far infrared radiation part 200 under 10 air pressures to transfer the far infrared rays to the irradiated object 2000.

The far infrared ray radiation product manufacturing apparatus according to the embodiment of the present invention additionally includes a temperature adjustment part so that the far infrared ray is transcribed at 50 ℃. The temperature adjusting part prevents the radiation object 2000 from being damaged when the temperature rises due to internal pressurization, and maintains the temperature of about 50 ℃ to improve the far infrared ray transfer efficiency.

A manufacturing method of 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 mineral powder 220, the radiation object 2000 such as a suture thread is disposed on the tray 310, and the tray 310 is disposed on the stirring blade 320. The door 110 for closing the chamber 100 drives the air pressure adjusting unit 400 to increase the air pressure inside the chamber 100 to 10 atm. The tray 310 on which the object 2000 to be irradiated is disposed is rotated by rotating the rotation motor 330. The stirring motor 250 is driven so that the stirring blade 230 rotates at 90, 60, 45rpm inside the mineral powder container 210 containing the mineral powder 220. The high-frequency wave oscillator 240 is driven to oscillate a high-frequency wave corresponding to the natural oscillation frequency of the mineral powder into the mineral powder container 210. The high-frequency wave oscillator 240 makes the wavelength beOr evenIs radiated to the inside of the mineral powder container 210. The far infrared ray is transferred to the object 2000 by driving the far infrared ray radiation section 200. After the transfer of the far infrared rays is completed, the air pressure adjusting unit 400 is driven to remove the air inside the chamber 100 after the air is purified by the air purifying unit 450, and the air pressure inside the chamber 100 is adjusted to the atmospheric pressure. The door 110 is opened and the irradiated object 2000 which has been completed with the far infrared ray transfer by the far infrared ray radiating product is taken out.

The irradiated object 2000 for manufacturing the far infrared ray irradiation product may include products made of fiber, plastic, ceramic, paper, glass, etc. In particular, the irradiated object 2000 includes a suture thread. Suture thread refers to surgical thread. Sutures include PGA sutures and PDO sutures. The suture includes a degradable suture which is decomposed after being introduced into a human tissue and absorbed by a body. The suture is formed from a Biodegradable (Biodegradable) polymer material. The suture may be comprised of a suture thread having a fiber shape and a sharp pointed (point) needle. The suture thread is preferably subjected to far infrared ray transfer treatment in the chamber 100 in a state of being packaged after the sterilization treatment.

Fig. 3 is a graph showing that a suture thread package is arranged in the far infrared ray radiation product manufacturing apparatus constructed as described above, a far infrared ray radiation suture thread is manufactured through a far infrared ray transfer process, and then the radiant ratio is measured after one week, and fig. 4 is a radiant energy measurement graph. As shown in the figure, it was confirmed that the far infrared ray radiation effect continued after one week.

In addition, with the apparatus for manufacturing far infrared ray radiation products configured as described above, even if the suture thread of biodegradable polymer material in a packaged state is disposed on the object to be irradiated 2000 and the far infrared ray transfer is performed, it can be confirmed that the suture thread can sufficiently exhibit the far infrared ray radiation effect without damaging the package and the polymer material, even if the direct far infrared ray radiation mineral is not included or applied.

According to the far infrared radiation product manufacturing apparatus according to the embodiment of the present invention configured as described, a product having sufficient far infrared radiation efficiency can be produced by adjusting the frequency of the high frequency wave oscillating part even if a high pressure of approximately 20 atmospheres is not applied. Further, when the chamber is pressurized to a high pressure, the temperature inside the chamber rises, and thus there occurs a problem that the biodegradable suture thread made of the biodegradable polymer material is damaged, but according to the present invention, the far infrared ray radiation efficiency and the far infrared ray radiation energy can be sufficiently exerted even if the high pressure is not applied, and the product can measure the effect of the far infrared ray radiation effect for 3 months or more.