KR102062588B1 - Far infrared ray radiation suturing thread and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a far-infrared radiation suture and a method of manufacturing the same, the method of manufacturing a far-infrared radiation suture according to the present invention comprises the steps of disposing a cartridge into which the mineral raw material is injected into a high pressure tank; A second step in which a suture is disposed inside the high pressure tank; A third step of closing the inlet of the high pressure tank by an opening / closing door; A fourth step of the compressor applying pressure to the inside of the high pressure tank; And a fifth step in which the mineral raw material in the cartridge emits far infrared wave energy on the suture. And a sixth step of discharging the suture by opening the opening and closing door.

Description

Far infrared ray suture and its manufacturing method {FAR INFRARED RAY RADIATION SUTURING THREAD AND MANUFACTURING METHOD THEREOF}

Embodiments of the present invention relate to far-infrared radiation sutures and methods of making the same.

Several different approaches have been tried to give products specific functionality. The most common methods have been to incorporate or apply materials or additives that express the desired functionality into existing products or to incorporate a multi-layered structure.

However, the conventional methods and techniques can add the desired functionality to the original product, but at the same time, there is a possibility of causing a change in or lowering the inherent physical properties of the original product. .

Therefore, in reality, in order to satisfy both the functional provision and the minimization of the physical property change at the same time, the balance of the method of controlling the content of the functional additives within the appropriate range is balanced.

Far infrared rays are a kind of electromagnetic waves that appear on the longer wavelength side than visible light, and refers to radiation having particularly strong thermal action. The advantage of far infrared is that it shows resonance absorption and cardiac calendar. When far infrared rays are irradiated on a subject, if the frequency of the emitted far infrared rays coincides with the frequency of molecular movement of the subject, the molecules of the subject absorb far infrared wave energy, resulting in more intense molecular movement and so-called resonance absorption phenomenon. Will. When the resonance absorption phenomenon occurs, the movement between atoms rapidly becomes active, and most of the kinetic energy is changed to heat, and some of the kinetic energy is activated to activate the molecules.

The penetration of far infrared rays into the human body is the square root of the wavelength, and the far infrared rays with long wavelengths have greater penetration than near infrared rays with short wavelengths. It penetrates far-infrared deep into the body, activates molecules or atoms in the body, releases waste products in the body, and promotes metabolism by activating cells, so that the characteristics of these far-infrared rays are utilized for fatigue recovery and health rhythm maintenance. have. In addition, the characteristics of far-infrared rays are widely used to provide food packaging with freshness, deodorization, dehumidification, and air purification.

Meanwhile, a thread-embedding therapy for medically inserting a thread into a human body to strengthen muscles or to improve sagging or wrinkles of a skin has been developed and widely used.

The suture (silence room) inserted into the human body stimulates and pulls the tissues inside the human body, thereby strengthening muscles or improving sagging or wrinkles of the skin, and directly mixing mineral gemstones or powders with sutures or preparing them as a solution. If it is possible to impart the function of the far infrared rays without applying, then the sutures can provide various effects of the far infrared rays without changing the original characteristics of the sutures.

The present invention has been made to solve the above-described problem, the far-infrared radiation suture according to the present invention and the method for manufacturing the suture itself to emit far infrared rays, without including the minerals that emit far infrared in the suture, suture It is intended to provide a suture that emits far-infrared radiation without changing its natural properties.

In order to solve the above-described problem, the present invention is disposed in the door to open and close the entrance of the high-pressure tank, the cartridge is a mineral raw material is injected, the filter is installed on the surface of the far-infrared wave energy of the mineral raw material, the filter is the inlet Inserting and fixing the cartridge in the opening and closing door so as to face each other; Placing a suture in a conveyor belt type tray installed inside the high pressure tank from one side of the high pressure tank where the inlet is formed to the other side of the high pressure tank, and driving the tray to place the suture at a position corresponding to the cartridge; Closing the entrance through an opening and closing door; Applying pressure to the inside of the high pressure tank through a compressor connected to the high pressure tank; The mineral raw material in the cartridge radiates far-infrared wave energy on the suture, and the micro-vibration discharge plate installed in the high pressure tank emits a negative transition on the suture, and measures the internal pressure of the high pressure tank through a sensing unit installed in the high pressure tank. When the measured internal pressure of the high pressure tank exceeds the standard pressure, the pressure of the high pressure tank to the outside through the safety device installed in the high pressure tank to reduce the pressure; And opening the inlet through the opening and closing door and driving the tray to draw the suture through the inlet.

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According to an embodiment of the present invention, the far-infrared radiation suture and the method of manufacturing the same may enable the suture itself to emit far infrared rays, without including the material that emits far infrared rays, thereby emitting far-infrared rays without changing the original characteristics of the suture. A suture may be provided.

1 is a block diagram of an apparatus for manufacturing far-infrared radiation product according to an embodiment of the present invention.
2 is a flowchart illustrating a method of manufacturing a far infrared ray radiated product according to an embodiment of the present invention.
2 to 6 are views for explaining in detail the apparatus and method for manufacturing a far-infrared radiation product according to an embodiment of the present invention.
7 is a view for explaining the result of the stapling procedure using the far-infrared radiation suture according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention. However, in describing the embodiments, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, the size of each component in the drawings may be exaggerated for description, it does not mean the size that is actually applied.

1 is a block diagram of an apparatus for manufacturing a far infrared ray radiated product according to an embodiment of the present invention, and FIG. 2 is a flowchart illustrating a method for manufacturing a far infrared ray radiated product according to an embodiment of the present invention.

In addition, Figures 3 to 6 is a view for explaining in detail the apparatus and method for manufacturing a far infrared radiation product according to an embodiment of the present invention, Figure 7 is a far-infrared radiation suture according to an embodiment of the present invention It is a figure for demonstrating the result of an open-air process.

Hereinafter, an apparatus for manufacturing a far-infrared radiation product according to an embodiment of the present invention will be described with reference to FIGS. 1 to 7.

As shown in FIG. 1, the apparatus for manufacturing a far-infrared radiation product according to an embodiment of the present invention includes a high pressure tank 110, an opening and closing door 120, a cartridge 140, a compressor 150, and a micro vibration discharge plate 160. And a safety device 170.

First, the cartridge 140 into which the mineral raw material is input is disposed in the high pressure tank 110 (S210).

As shown in Figure 3, the high-pressure tank 110 is composed of a cylindrical pressure vessel configured to withstand high pressure of 10kg / ㎠ or more, including an opening and closing door 120 for entering and exiting the suture 130, the present invention It may be configured to further include a control unit 101 for the control of the manufacturing apparatus of the far-infrared radiation product according to an embodiment of the.

As shown in FIG. 4, the opening and closing door 120 is coupled to the side of the high pressure tank 110 to open and close the inlet of the high pressure tank 110, and the high pressure tank 110 and the opening and closing door 120 are in contact with each other by 10 kg /. A configuration for improving the sealing property is applied to withstand high pressure of 2 cm 2 or more.

The cartridge 140 is a place where the mineral raw material is input, so that the far-infrared wave energy of the mineral raw material is radiated to the suture.

More specifically, the cartridge 140 is inserted and fixed in the opening and closing door 120, the suture 130 may be disposed in a position corresponding to the cartridge 140 in the high pressure tank (110).

In addition, the cartridge 140 may be configured to include a filter 141 through which the far-infrared wave energy of the mineral raw material is transmitted on the surface.

On the other hand, the mineral material introduced into the cartridge 140 is jade, jade, tourmaline, loess, biotite, raw ore, bamboo charcoal, Uranite, guineastone, obsidian, ganbanite, photonite, lava gemstone, quartz, monzoite, One or more minerals selected from the group consisting of gneiss, rhyolite tuff, strontium, vanadium, zirconium, cerium, neodymium, lanthanum, barium, rubidium, cesium and gallium are powdered into fine particles of 6.5 μm or less.

In addition, the mineral raw material according to the present invention can increase the far-infrared radiation efficiency by using jade or jade powder, the mineral raw material preferably has a particle size of 6.5 to 1.3㎛ as mineral powder.

The cartridge 140 may be made of a material capable of withstanding electromagnetic waves and high pressure so that far infrared rays may be transmitted from the mineral raw material contained therein without loss and irradiated to the suture, and the mineral raw material may be formed on the surface of the cartridge 140. The filter 141 may be installed to transmit the far-infrared wave energy.

In addition, one side of the cartridge 140 includes an electromagnetic radiation unit for emitting microwaves in the 2.45 GHz frequency band to the suture 130, it is possible to increase the radiation efficiency of far infrared rays by irradiating the microwaves.

After that, the suture 130 to be processed in the far infrared is disposed inside the high pressure tank 110 (S220).

At this time, the tray 131 in which the suture is placed on the bottom surface of the high-pressure tank 110 may be disposed to easily enter and exit the suture 130.

Thereafter, the inlet of the high pressure tank is closed by the opening and closing door (S230), and the compressor 150 applies pressure to the inside of the high pressure tank 110 (S240).

Compressor 150 shown in Figure 5 is connected to the inside of the high-pressure tank 110, the pressurized fresh air filtered through the program can be gradually applied to the pressure up to 10kg / ㎠ by program, in this case the compressor 150 ) May apply a pressure of 20 to 30 atm inside the high pressure tank (110).

Then, the mineral raw material in the cartridge emits far infrared wave energy on the suture (S250).

At this time, the micro-vibration discharge plate 160 shown in Figure 6 radiates a negative transition in the interior of the high-pressure tank 110, the far infrared ray of the mineral raw material is effectively activated by the negative transition to irradiate the suture 130 You can do that.

Far-infrared rays are electromagnetic waves corresponding to the wavelength range of 0.76 to 1,000 μm, which is the longest wavelength and the lowest frequency when the infrared region is subdivided according to the wavelength. In the far-infrared wavelength band, intrinsic absorption of all living bodies made of organic compounds 4-15 micrometers which is a wavelength band is included.

Far infrared rays are radiated to the water and protein molecules that make up the cells in the human body and resonate with minute vibration about 2,000 times a minute to make the activity of the cells vigorous. In the process of cell activity, heat energy is generated, which increases body temperature.As the body temperature increases, microvascularization expands and blood circulation is activated, and the metabolism is strengthened, and tissue regeneration power increases to break down blood clots in blood vessels and promote blood circulation. It is possible to enhance the biological activity of the organism by causing a biological activity (Biological Activity) or by cutting off the water cluster (Water Cluster).

On the other hand, the sensing unit 180 may be configured to include a temperature sensor and a pressure sensor for measuring the temperature and pressure inside the high pressure tank 110, the safety device 170 is a standard air pressure of the internal pressure of the high pressure tank (110). If exceeded, the pressure may be released to the outside, or after the far-infrared treatment is completed, the pressure may be reduced to within 1 kg / cm 2 atmospheric pressure.

Thereafter, opening and closing the door 120 to discharge the suture 130 (S260).

TABLE 1

TABLE 2

Table 1 describes the test results of the far-infrared emissivity and far-infrared radiation energy of the suture before the far-infrared treatment, and in Table 2, the test results of the far-infrared emissivity and far-infrared radiation energy of the far-infrared radiation suture treated with the far-infrared treatment according to an embodiment of the present invention. It is described.

Referring to Table 1 and Table 2, far-infrared radiation suture treated with far-infrared radiation according to an embodiment of the present invention, it can be confirmed that the far-infrared emissivity and far-infrared radiation energy increased compared to the suture before the far-infrared treatment.

7 to 13 are views for explaining the results of the stapling procedure using the far-infrared radiation suture according to an embodiment of the present invention.

More specifically, Figure 7 is a picture of the neck of a patient who has undergone a barley surgery using a suture according to an embodiment of the present invention, the suture refers to a thread that can be inserted into the skin for medical or cosmetic purposes.

Referring to FIG. 7, the A side was used for far-end treatment using a far-infrared radiation suture, and the B side was used for general-line suture.

As in the A side, when using the far-infrared radiation suture was performed by the stapling procedure, the swelling of the affected area was markedly reduced, and the lifting effect was also excellent. At this time, the lifting is to pull or pull up the skin by the suture, the lifting is performed by the protrusions, knots or clasps included in the suture may have the effect of physically improving or removing the wrinkles of the skin surface.

8 is an infrared photograph of the upper body before the procedure of the far infrared radiation suture according to an embodiment of the present invention, Figure 9 is an infrared photograph of the upper body after the procedure of the far infrared radiation suture according to an embodiment of the present invention.

10 is an infrared photograph of the whole body before the procedure of the far infrared radiation suture according to an embodiment of the present invention, Figure 11 is an infrared photograph of the whole body after the procedure of the far infrared radiation suture according to an embodiment of the present invention.

Compared with the infrared photograph of the whole body before the procedure of the far infrared radiation suture of FIGS. 8 and 10, referring to the infrared photograph after the procedure of the far infrared radiation suture of FIG. 9 and FIG. 11, the far infrared radiation It can be seen that the body temperature rises by promoting metabolism through activation of cells of the subject by far infrared rays from the suture.

In the detailed description of the invention as described above, specific embodiments have been described. However, many modifications are possible without departing from the scope of the invention. The technical spirit of the present invention should not be limited to the above-described embodiments of the present invention, but should be determined not only by the claims, but also by those equivalent to the claims.

110: high pressure tank
120: opening and closing door
130: suture
140: cartridge
141: filter
150: compressor
160: fine vibration discharge plate
170: safety device
180: detector

Claims (7)

A cartridge in which a mineral raw material is input and a filter on which a far infrared wave energy of the mineral raw material is transmitted is disposed on a surface of the cartridge, and the cartridge is disposed in an opening / closing door that opens and closes the inlet of the high pressure tank, and the cartridge is opened so that the filter faces the inlet. Inserting and fixing in the chamber;
The suture is disposed in a tray of a conveyor belt type installed inside the high pressure tank toward the other side of the high pressure tank from one side of the high pressure tank in which the inlet is formed, and drives the tray to correspond to the suture to the cartridge. Placing in position;
Closing the entrance through the opening and closing door;
Applying pressure to the inside of the high pressure tank through a compressor connected to the high pressure tank;
The mineral raw material in the cartridge radiates far-infrared wave energy on the suture, and the micro-vibration discharge plate installed in the high pressure tank radiates a negative transition on the suture, but through a sensing unit installed in the high pressure tank of the high pressure tank. Measuring an internal pressure, and when the measured internal air pressure of the high pressure tank exceeds a reference air pressure, depressurizing and discharging the pressure of the high pressure tank to the outside through a safety device installed in the high pressure tank; And
Opening the inlet through the opening and closing door, driving the tray to draw the suture through the inlet;
Far infrared ray suture manufacturing method comprising a.
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