KR101670223B1 - Alopecia-healing comb using laser - Google Patents

Abstract

The laser hair removal treatment apparatus of the present invention comprises an inflow section for increasing the speed of air while decreasing the pressure of air when the air introduced into the narrowed cross section passes through the pipeline, a heat radiation line communicating with the inflow section and guiding the flow of air, , And a laser device which is sequentially provided on the heat dissipation line and is irradiated with a laser beam and the generated heat radiation temperature is cooled by an air flow.

Description

[0001] Alopecia-healing comb using laser [0002]

More particularly, the present invention relates to a laser hair loss treatment device, and more particularly, to a hair loss treatment device for a helmet, which is capable of cooling heat generated in a laser device when hair removal treatment is performed through a laser device, To a laser hair removal treatment apparatus.

The photo-chemical action of plants can be seen in carbon assimilation. It is known that light is irradiated to living organisms to produce ATP by its optical action, thereby activating the cells. In other words, the fact that the laser light is irradiated to a living body with a low energy not burning the living cells activates the physiological function of the living body and improves the natural healing power of the affected part. It has been well known in the medical field through its experience in laser surgery.

Recently, a low-level laser therapy (hereinafter referred to as LLLT) which treats various diseases actively using the above-mentioned action has been developed and started to be used in various disease fields.

The biochemical action of light depends on the wavelength of light, polarization, intensity, etc. Experiments have shown that light with an energy of about 100 mW is most effective for the human body in the range of 600 to 1000 μm.

Such light can be generated by using a He-Ne laser, a semiconductor laser, or a YAG laser. Particularly in terms of size and price, semiconductor lasers are advantageous, and GaAs (904 nm), GaAlAs (780-820-870 nm, InGaAlP 630-685 nm) are mainly developed and sold.

However, it has been reported that instead of these lasers, the emitted light of the LED can also be used, which is especially adopted in products with an emphasis on manufacturing cost.

Since the LED is not a coherent light such as a laser light, it can not focus the beam width to a certain degree and can generate light in the range of 600-1000 um, which is not polarized, and can secure a strength of about 100 mW / cm Almost the same effect as that of using a semiconductor laser can be obtained.

Currently, the most popular type of pain treatment is LLLT therapy, which was developed as a result of the fact that the professor of Canada's Canadian professor, Hee-Ne laser, investigated the acupuncture points in the form of laser acupuncture, .

Currently, it is confirmed that not only acupuncture but also direct irradiation to the affected part can obtain a very high effect to heal the disease as well as the pain, and the application field thereof is greatly expanded. In particular, LLLT is not only excellent for various chronic diseases known as conventional incontinence, but also has an inherently non-invasive (non-operative) and non-invasive treatment technique, has little pain and side effects for patients, There is an epoch-making advantage in that it is extremely low compared to traditional treatment methods.

However, the hair loss treatment apparatus developed based on LLLT has the following problems.

LLLT laser beam is applied to the inside of the helmet, and the laser beam is applied to the head of the patient with the helmet mounted on the head of the patient.

At this time, the circuit board of the LLLT is heated. However, due to the heat generation temperature, the helmet provided with the hair removal treatment apparatus for a long time can not be worn and the efficiency of the procedure is lowered.

In addition, there is a problem that the life of the LLLT is shortened by the heat generated in the LLLT and the luminescence is lowered.

Korea Registered Utility Model No. 20-0426924 (2006.09.13) Korean Patent Publication No. 2008-0025989 (Mar. 24, 2008)

In order to solve the above-mentioned problems, the laser hair loss treatment device of the present invention is provided with a heat dissipation line having a plurality of laser elements mounted on an inner surface of a helmet mounted on a head, So as to cool the heat generated in the circuit board of the laser device.

It is another object of the present invention to dissipate and cool heat generated in a laser device so as to prolong the lifetime of the laser device and to prevent degradation of luminescence.

According to an aspect of the present invention, there is provided an apparatus for laser hair removal comprising: an inflow section for increasing the speed of air while decreasing a pressure of air when passing through a pipeline having a narrow cross-sectional area; And a laser element which is sequentially disposed on the heat dissipation line and is irradiated with a laser beam and the heat radiation temperature generated is cooled by an air flow.

According to the present invention, the inflow portion includes an airflow generating means for generating airflow by rotating a wing through a driving force of a motor, and a pipe having an annular space in which the airflow generating means is mounted, And a main body means for increasing the air flow rate and wind speed by pulling backward airflow in an annular shape due to a difference in air pressure between the duct and the annular airflow.

According to the present invention, a plurality of branch lines are formed in a state in which the heat dissipating line is connected to the inflow portion, a plurality of laser elements are sequentially arranged in the heat dissipating line, To be cooled by the air flow.

According to the present invention, air holes are formed on both sides of the circuit board of the plurality of laser elements, and external air is introduced into the heat dissipating holes by the air velocity of the air flowing through the heat dissipating lines.

According to the present invention, the inflow portion, the heat dissipation line, and the laser element are installed at the inner periphery of the helmet, and the inflow portion is disposed at the rear of the helmet, and the heat dissipation line is installed at the inner periphery of the helmet, And one side of the heat dissipation line is installed in front of the helmet, and a plurality of the laser elements are provided and sequentially installed in the heat dissipation line.

The laser hair removal treatment apparatus of the present invention as described above has an inlet portion for increasing the speed of the air while reducing the pressure of the air when the air introduced into the tube has a narrow cross section, And a plurality of laser devices mounted on the inner surface of the helmet mounted on the head, the laser device being composed of a laser device that is sequentially disposed on the heat dissipating line and is cooled by air flow, There is an effect of reducing the fatigue of the hair removal procedure by providing a heat dissipating line and flowing an air current having an improved wind speed and air volume on the inner circumference of the heat dissipating line to cool the heat generated in the circuit board of the laser device.

In addition, there is an effect that the reliability of the hair loss treatment device is improved by dissipating heat and cooling the heat generated by the laser device, thereby prolonging the life of the laser device and preventing the light emission from being lowered.

1 is a perspective view showing a mounting state of the laser hair loss hair treatment apparatus of the present invention.
2 is a cross-sectional view of the laser hair loss treatment device of the present invention.
3 is a bottom view of the laser hair loss treatment device of the present invention.
4 is an enlarged cross-sectional view of the laser hair loss treatment device of the present invention.
5 is an enlarged cross-sectional view illustrating an inflow section of the laser hair loss treatment apparatus of the present invention.

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

First, in the drawings, it is noted that the same components or parts are denoted by the same reference numerals as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

FIG. 3 is a bottom view of the laser hair removal therapy apparatus of the present invention, and FIG. 4 is a sectional view of the laser hair removal treatment apparatus of the present invention. FIG. 5 is an enlarged cross-sectional view illustrating an inflow section of the laser hair removal treatment apparatus of the present invention. FIG.

As shown in FIGS. 1 to 5, the laser hair loss treatment apparatus 10 of the present invention is installed on the inner peripheral edge of the inner side of the helmet 11.

The laser hair removal therapy apparatus 10 includes an inflow section 100, a heat dissipation line 300, and a laser device 320.

The inflow part 100, the heat dissipation line 300, and the laser device 320 are installed on the inner periphery of the helmet 11.

The inflow portion 100 is installed at the rear of the helmet 11 and the heat dissipation line 300 is installed at the inner periphery of the helmet 11 so that the other side of the heat dissipation line 300 is connected to the inflow portion 100 and one side of the heat dissipation line 300 is installed in front of the helmet 11 do.

The plurality of laser devices 320 are sequentially provided on the heat dissipation line 300 to irradiate laser light.

Specifically, the inflow portion 100 increases the speed of the air introduced into the interior of the inflow portion 100 while decreasing the pressure of the air as it passes through the narrow cross-sectional area.

The inflow unit 100 includes an airflow generating unit 110 for generating airflow by rotating the blades 112 through a driving force of a motor 111, a space 201 in which the airflow generating unit 110 is mounted, 210, and the pressure of the air passing through the narrow channel 202 is reduced at the inner circumference of the annulus 210 in the space 201, the velocity is increased while being discharged, and at the same time, the air pressure difference between the air- And a main body means 200 for attracting the airflow to increase the air flow rate and wind speed.

That is, the rotating blade 112 is rotated through the driving force of the motor 111 through the airflow generating means 110 to generate an air flow in the inner space 201 of the inflow section 100.

Thereafter, the air flow introduced into the space 201 of the inflow part 100 has improved air velocity and air volume through the body means 200.

The body means 200 enabling this is formed in the shape of a hollow aircraft wing 112 whose cross section has a hollow ring.

The air pushed up into the hollow body means 200 increases the flow rate due to the structural characteristics of the ring. The air pressure at the inside of the space 201 of the body means 200 is lowered as the air of this high speed is released through the narrow channel 202 inside the hollow ring.

Thereby, the air around the body means 200 is guided into the annulus 210 to create a strong air flow through the annulus 210. The amount of air passing through the annulus 210 is greater than the amount of air sucked down through the motor 111.

As a result, as the pressure of the air passing through the narrow channel 202 decreases, the speed is increased and the air is discharged. At the same time, the airflow pressure difference between the duct 202 and the annular shape 210 causes the airflow to be attracted to the annular shape 210, do.

The air velocity and the air flow rate for the air stream of the improved air are supplied to the heat dissipating line 300 through the inlet 100 as described above.

The radiating line 300 is installed on the inner circumference of the inner side of the helmet 11 to guide the flow of air.

A plurality of branch tubes 310 are formed in the heat dissipation line 300 in a state of being connected to the inflow section 100, and a plurality of laser elements 320 are sequentially installed in the heat dissipation line 300.

Further, the circuit board 321 of the laser device 320 is positioned at the inner periphery of the heat radiation line 300 and cooled by the air flow.

That is, the plurality of branch pipes 310 are formed in the hollow so that the air flow generated in the inflow portion 100 flows.

At this time, when the laser device 320 is installed in the branch pipe 310, the circuit board 321 is positioned at the inner periphery of the branch pipe 310.

The air flowing to the branch pipe 310 through the cooling air circulates the circuit board 321 to be heated.

At this time, the branch duct 310 forms heat dissipation holes 311 on both sides of the circuit board 321 of the plurality of laser devices 320, and allows the outside air to flow into the heat dissipating holes 311 by the air velocity of the air flowing through the heat dissipating lines 300.

That is, the air heated in the space 201 between the inner periphery of the inner rim and the head of the practitioner flows into the separation line through the radiating hole 311 to lower the temperature of the air inside the helmet 11.

Accordingly, the temperature of the space 201 inside the helmet 11 is lowered, thereby reducing the fatigue of the operation of the practitioner.

Further, a radiating line 300 having a plurality of laser devices 320 mounted on the inner surface of the helmet 11 mounted on the operator's head, and an air flow having an improved air velocity and an air flow is flowed to the inner circumference of the radiating line 300, The heat generated by the circuit board 321 is cooled to dissipate and cool the heat generated by the laser device 320, thereby prolonging the life of the laser device 320 and preventing the light emission from being lowered, thereby improving the reliability of the hair loss treatment device have.

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 or scope of the inventions. It will be clear to those who have knowledge of.

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 or scope of the inventions. It will be clear to those who have knowledge of.

10: laser hair loss treatment device 11: helmet
100: inlet portion 110: airflow generating means
111: motor 112: wing
200: main body means 201: space
202: channel 210: annular
300: heat dissipation line 310: branch tube
311: air vent 320: laser element
321: circuit board

Claims (5)

An inflow portion for increasing the speed of the air while reducing the pressure of the air when the air flows into the narrow cross-sectional area,
A heat dissipation line communicating with the inflow portion and guiding the flow of air,
And a laser device which is sequentially disposed on the heat dissipation line and is irradiated with a laser beam, and the generated heat radiation temperature is cooled by an air flow.
The method according to claim 1,
Wherein:
An airflow generating means for generating airflow by rotating the blades through the driving force of the motor,
Wherein the space in which the airflow generating means is mounted is annular and the speed of the air passing through the inner circumference of the annular inner circumference of the space is decreased while the speed of the air is reduced, And a main body means for pulling the backward airflow in an annular shape by the airflow and increasing the air flow rate and wind speed.
The method according to claim 1,
The heat-
A plurality of branch passages are formed in a state of being connected to the inflow portion,
A plurality of laser elements are sequentially arranged in the heat dissipation line
Wherein the circuit board of the laser device is positioned at the inner periphery of the heat radiation line and cooled by the air flow.
The method of claim 3,
Wherein a plurality of laser elements are provided on both sides of the circuit board with air holes to allow external air to flow into the heat dissipation holes by the velocity of the air flowing through the heat dissipating lines.
The method according to claim 1,
The inflow portion, the heat dissipating line, and the laser device are installed at the inner periphery of the helmet,
The inflow portion is installed at the rear of the helmet,
Wherein the heat dissipating line is installed at the inner periphery of the helmet, the other side of the heat dissipating line is connected to the inlet, the one side of the heat dissipating line is installed in front of the helmet,
Wherein a plurality of the laser elements are provided and sequentially installed on the heat dissipation line.

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