KR101334702B1 - An optical apparatus for skin treatment and a method for controlling the optical apparatus - Google Patents

Abstract

The present invention relates to an optical device for treating skin and a control method thereof, comprising: a light irradiation unit for irradiating light generated from a light generation unit to a target position of the skin, and a cooling unit for cooling the skin surface by spraying a cooling gas to the target position. And a control unit controlling driving of the light irradiation unit and the cooling unit, wherein the control unit irradiates the first light to the target position, and the cooling unit injects the cooling gas to the target position. The optical irradiation apparatus and the control method thereof are characterized in that the light irradiation unit controls the light irradiation unit and the cooling unit to irradiate a second light to the target position.
According to the present invention, a sufficient amount of heat energy can be provided to the internal tissue of the skin without causing damage to the skin surface, thereby improving the effect of skin treatment. In addition, it is possible to minimize the phenomenon that the skin lesions temporarily disappear due to skin cooling, it is possible to increase the accuracy of the procedure.

Description

TECHNICAL APPARATUS AND A METHOD FOR SKIN TREATMENT AND A METHOD FOR CONTROLLING THE OPTICAL APPARATUS

The present invention relates to an optical device for treating skin and a control method thereof, and more particularly, to an optical device for treating skin and a control method thereof having a cooling system using a cooling gas.

Recently, a technique for treating the skin by applying light to the skin to modify or remove the state of the skin tissue has been widely applied. Accordingly, optical devices for treating skin using various types of electromagnetic waves, such as laser beams, flash lamps, RF radio frequency waves, microwaves, and ultrasounds, have been developed.

When the light is irradiated to the skin by using the optical device for treating the skin, light having a specific wavelength penetrates inward and is absorbed into various tissues such as collagen, hair follicle, and hemoglobin located inside the skin according to wavelength characteristics. The absorbed light is converted into thermal energy in the tissue, causing thermal damage to the tissue, thereby changing the state of the tissue.

At this time, the skin surface may be damaged by the heat energy generated during light irradiation, and it is common to cool the skin surface before or during light irradiation. For example, a method of cooling the skin by contacting the skin with a thermally conductive member that maintains a low temperature by a coolant or a thermoelectric element, or by cooling a skin by spraying a cryogenic cooling gas onto the skin is mainly used. Therefore, the internal tissue of the skin is treated while the surface of the skin is kept at a low temperature during light irradiation.

However, even when the treatment is performed in a state where the surface of the skin is cooled as in the prior art, there is a problem that damage is caused to the surface of the skin when irradiated with light at a predetermined size or more. Therefore, there is a limit in proceeding treatment by supplying sufficient heat energy to the skin tissue.

Furthermore, in the treatment of removing capillaries located on the surface of the skin, cooling the skin surface as in the prior art causes the capillaries to contract and disappear from the skin surface. As described above, in the case of some lesions, when the surface of the skin is cooled, the lesions disappear temporarily due to a sharp temperature drop. Therefore, it is difficult to treat the lesion by irradiating light at the correct position after cooling the skin.

In order to solve the above problems, the present invention is to provide an optical device for treating the skin and a method of controlling the same that can provide sufficient heat energy to the internal tissue of the skin without damaging the skin.

Furthermore, it is to provide an optical device for treating the skin and a method of controlling the same, which can minimize the phenomenon that the lesion temporarily disappears due to the temperature decrease of the skin during skin cooling.

An object of the present invention described above is a light irradiation unit for irradiating light generated by the light generating unit to a target position of the skin, a cooling unit for cooling the skin surface by spraying a cooling gas to the target position, and the light irradiation unit and the cooling unit And a control unit for controlling driving, wherein the light irradiation unit irradiates the first light to the target position, and after the cooling unit injects the cooling gas to the target position, the light irradiation unit supplies the second light. It can be achieved by the optical device for skin treatment, characterized in that for controlling the light irradiation unit and the cooling unit to irradiate to the target position.

At this time, the energy supplied to the unit area of the target position while irradiating the first light is less than the energy supplied to the unit area of the target position while irradiating the second light.

For example, the first light is irradiated with less output than the second light. Specifically, the light generating unit may include a light output adjusting unit that may adjust the output of the light, and the controller may be configured to control the light output adjusting unit to adjust the output of the first light and the second light.

Or, a focusing optical system installed on a traveling path of the light generated by the light generating unit to adjust an irradiation area of the light irradiated to the target position, wherein the controller is configured to irradiate the first light with a wider area than the second light. The focusing optical system can be controlled to be irradiated with an area. Here, the focusing optical system may include at least one optical member that is installed to be movable along the path of the light, and the optical member may be configured to adjust the irradiation area of the light while moving under the control of the controller.

Alternatively, the controller may control an irradiation time of the first light and the second light irradiated from the light irradiation unit, and control the first light to be irradiated for a shorter time than the second light. Specifically, at least one shutter is provided on an optical path, and the controller may be configured to control the irradiation time of the first light and the second light by opening and closing the shutter.

Further, the light generating unit includes a first resonator for generating the first light and a second resonator for generating the second light, wherein the first resonator generates light having a wavelength that is superior to skin penetration than the second resonator. Can be configured to As an example, the first resonator may be configured to generate light having a wavelength of 1064 nm, and the second resonator may be configured to generate light having a wavelength of 755 nm.

Here, the controller may control the cooling unit to spray the cooling gas after the light irradiation unit irradiates the first light and waits for 0 to 100 ms. The cooling unit may inject the cooling gas and control the light irradiation unit to irradiate the second light after waiting for 10 to 100 ms.

On the other hand, the object of the present invention, driving the light generating unit, irradiating the first light to the target position of the skin, injecting the cooling gas stored in the storage medium to the target position, predetermined after the cooling gas injection It may also be achieved by a method of controlling the optical device for treating skin, including the step of waiting for time and driving the light generating unit to irradiate a second light to the target position.

The energy supplied to the unit area of the target position in the step of irradiating the first light is controlled to be smaller than the energy supplied to the unit area of the target position in the step of irradiating the second light.

For example, the step of irradiating the first light is controlled to irradiate light having a smaller output than the step of irradiating the second light.

Alternatively, the method may further include a focusing optical system that adjusts an irradiation area of light generated by the light generating unit, and the irradiating the second light may include a narrower irradiation area than controlling the focused optical system to irradiate the first light. It may be controlled to irradiate the second light.

In addition to this, it is also possible to control the irradiation time of the first light to be shorter than the time for irradiating the second light.

The irradiating of the first light may include generating the first light by using the first resonator of the light generator, and irradiating the second light by using the second resonator of the light generator. The second resonator may generate light, and the first resonator may be configured to generate light having a wavelength superior to skin permeability than the second resonator. For example, the first resonator may generate light having a wavelength of 1064 nm, and the second resonator may generate light having a wavelength of 755 nm.

According to the present invention, a sufficient amount of heat energy can be provided to the internal tissue of the skin without causing damage to the skin surface, thereby improving the effect of skin treatment.

In addition, it is possible to minimize the phenomenon that the skin lesions temporarily disappear due to skin cooling, it is possible to increase the accuracy of the procedure.

1 is a view showing an optical device for treating skin according to an embodiment of the present invention,
2 is a view showing a connection relationship between the main body and the handpiece of FIG.
3 is a view showing the control content of the optical device for skin treatment of FIG.
4 to 6 are diagrams showing an example of the configuration of the first light and the second light in FIG.
FIG. 7 is a graph illustrating a change in temperature of skin when the optical device for treating skin is controlled in the order of FIG. 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following embodiments, an apparatus for treating skin using laser light will be described as an example. However, this is not limited to the scope of the present invention as a single embodiment, it is noted that the present invention can be applied using a variety of light sources other than laser.

1 is a view showing an optical device for treating skin according to an embodiment of the present invention, Figure 2 is a view showing a connection relationship between the main body and the handpiece of FIG. As shown in FIG. 1, the optical device for treating skin according to the present embodiment includes a main body 10, a handpiece 20, and a cable 30 connecting the same.

The main body 10 includes a power supply unit to receive power from the outside, and on the outer surface of the main body 10, a control panel 11 capable of manipulating the contents of the procedure and a display 12 capable of displaying the same to a user are provided. Is installed. In addition, the light generating unit 100 for generating light used in skin treatment is provided in the main body 10, and the cooling gas storage unit 310 in which the cooling gas for skin cooling is stored may also be installed in the main body 10. Can be.

On the other hand, the handpiece 20 is formed in a structure capable of overfishing so that the user can proceed with the procedure while changing the treatment position. The light irradiator 200 and the cooling gas injection unit 320 may be installed inside the handpiece 20 to irradiate light to the treatment position and inject the cooling gas. In addition, an outer surface of the handpiece 20 may be provided with a button-shaped operation unit 21 that allows the user to operate the drive of the handpiece 20.

Then, the cable 30 connects the handpiece 20 and the main body 10. An optical fiber 31 forming an optical path from the light generating unit 100 to the light irradiation unit 200, a cooling passage 32 forming a path through which cooling gas flows, and various signals can be transmitted therein. It may be configured to include a signal line 33.

Hereinafter, with reference to FIG. 2 to be described in more detail the connection relationship between the components of the main body 10 and the handpiece 20.

As shown in FIG. 2, the light generator 100 includes at least one resonator 110 or 120. Each of the resonators 110 and 120 is provided with laser media 111 and 121, and optical members such as total reflection mirrors 112 and 122, shutters 141 and partial reflection mirrors 113 and 123 at both ends of the laser media. Is installed. Accordingly, the light oscillated from the laser medium by an excitation medium such as a flash lamp (not shown) is amplified while reciprocating inside the resonators 110 and 120 to form laser light.

The light generator 100 of the present exemplary embodiment includes a first resonator 110 and a second resonator 120, and each of the resonators 110 and 120 includes a laser medium for generating light having different wavelengths. do. In addition, optical members such as a shutter 141 for selectively opening and closing the optical path and a splitter 142 for transmitting or reflecting light according to wavelength characteristics are disposed to selectively provide light having two different wavelengths. Can be.

However, in the present embodiment, the light generating unit 100 is configured using two resonators 110 and 120, but this is only an example, and it is also possible to configure the light generating unit using one or three or more resonators. Do. In addition, in the present embodiment, a configuration in which a solid state laser is generated using a flash lamp as an excitation medium has been described. In addition, various configurations that can generate a gas laser or a semiconductor laser may be applied.

Meanwhile, one end of the light generator 100 is connected to the light emitter 200 of the handpiece 20 by a light transmission medium such as the optical fiber 31. Therefore, the light generated by the light generating unit 100 is provided to the light irradiation unit 200 of the handpiece 20 along the light path formed by the optical fiber 31. The light irradiation unit 200 includes a focusing optical system 210 made of a plurality of optical members such as a lens 211. Therefore, the light discharged to the end of the optical fiber 31 can be focused and irradiated to the treatment site.

On the other hand, the cooling unit 300 for cooling the skin during the procedure is configured to include a cooling gas storage unit 310 for storing the cooling gas and a cooling gas injection unit 320 for injecting the cooling gas to the skin. As shown in FIG. 2, the cooling gas storage unit 310 is installed in the main body 10, and the cooling gas injection unit 320 is installed in the handpiece 20, so that the cooling flow path 32 of the cable 30 is located. ) Can be connected.

In the present embodiment, the cooling gas may use HFC-134a as an example by using a cryogen gas vaporized at room temperature. The cooling gas is stored in the cooling gas storage 310 in a high pressure liquefied state. The cooling gas storage unit 310 is configured as a container structure in which a predetermined amount of cooling gas is stored, and may be detachably installed on the outside of the main body 10 so that the cooling gas may be easily replaced (see FIG. 1). .

The cooling gas storage unit 310 is connected to the cooling passage inside the body 10 when coupled to the body 10. In addition, an opening / closing member such as a solenoid valve may be provided on the cooling channel, and the cooling gas may be supplied or blocked to the cooling gas injection part 320 according to the operation of the opening / closing member. Meanwhile, a temperature adjusting member such as a heater (not shown) capable of controlling the temperature of the cooling gas storage 310 may be installed at a portion where the cooling gas storage 310 is installed. Therefore, condensation on the surface of the cooling gas storage unit can be prevented by controlling the temperature of the surface of the storage unit 310 by using the temperature adjusting member. Furthermore, the pressure inside the cooling gas storage unit 310 is increased to increase the pressure of the cooling gas. The injection pressure can be adjusted.

As such, the cooling gas provided from the cooling gas storage unit 310 is provided to the handpiece 20 through the cooling channel 32, and the treatment position of the skin through the cooling gas injection unit 320 of the handpiece 20. Is sprayed on. However, in the present exemplary embodiment, the cooling gas storage unit 310 is configured as a disposable container detachably installed on the main body 10, but the present invention is not limited thereto. In addition, the cooling gas storage unit 310 may be installed in the main body to be configured to fill the cooling gas, and the cooling gas storage unit 310 may be directly connected to the handpiece 20 instead of the main body 10. It is also possible to configure for installation.

On the other hand, the optical device for skin treatment according to the present invention includes a control unit 400 for controlling each component. The control unit 400 performs operations of each component such as the light generator 100, the light emitter 200, and the cooling unit 300 according to contents input by the user through the control panel 11 or stored in its own memory. Can be controlled. Various conditions can be performed by the control of the control unit 400, and the following is a detailed description of the content of the optical device for treating skin according to the present invention.

3 is a view showing the control content of the optical device for skin treatment according to the present invention.

As described above, the optical device for treating the skin has been irradiated with light while the skin is cooled to prevent thermal damage to the skin surface. However, even when the surface of the skin is cooled, there is a limit in increasing the output of light, and thus sufficient amount of thermal energy cannot be provided to the internal tissue of the skin.

Therefore, the optical device for treating skin according to the present invention precedes the step of irradiating the first light to the target position of the skin before cooling the skin surface (S10). In this way, when the first light is irradiated to the skin maintaining the normal body temperature, the skin is preheated to a temperature higher than the normal temperature.

 In general, preheating the skin in a thermally conductive manner in which a hot object is in contact with the skin may be considered, but in this case, the amount of thermal energy provided to the inside of the skin may decrease linearly as it is deeper from the skin surface. On the contrary, when the skin is preheated by the light irradiation method as in the present embodiment, since the absorption characteristics for each material are different depending on the wavelength of the light, it is possible to preheat the skin deep to the desired position by providing thermal energy to a desired position inside the skin. Do.

As such, when the target position of the skin is preheated by the irradiation of the first light, the cooling unit 300 is driven to inject the cooling gas (S20). At this time, the injected cooling gas intensively cools the skin surface by the heat of vaporization while vaporizing from the skin surface. Therefore, compared to cooling the skin by thermally contacting a low temperature object to the skin surface, the temperature of the skin surface is instantaneously cooled to a cryogenic state of minus 10 ° C. or less, and the internal tissues of the skin absorb the heat energy provided during the first light irradiation. You can keep it.

When the surface of the skin is sufficiently cooled by the above step, the second light is irradiated to the target position (S30). In this case, the second light may provide thermal energy to the internal tissue of the skin through the cooled skin. However, as described above, even when the skin is cooled, there is a limit in increasing the output of the second light. However, according to the present invention, since the internal tissue of the skin has the heat energy supplied during the first light irradiation, a sufficient amount of heat energy necessary for the treatment of the skin together with the heat energy supplied during the second light irradiation is provided. Can be provided as

In addition, in the related art, some lesions temporarily disappear upon cooling of the skin, such as when blood vessels contract and disappear from the skin surface during cooling of the skin. However, according to the present invention, since the cooling is performed on the surface of the skin while the skin is preheated, the internal tissue of the skin can maintain a temperature higher than the normal body temperature, so that some lesions temporarily disappear due to skin cooling. It can be minimized.

As described above, in the optical device for treating skin according to the present invention, the control unit 400 controls the light generator 100, the light emitter 200, and the cooling unit 300 to irradiate the first light (S10). The spraying of the cooling gas (S20) and the irradiation of the second light (S30) may be sequentially performed.

However, the step of irradiating the second light (S30) is performed in a state of cooling the skin surface, whereas the step of irradiating the first light (S10) proceeds without cooling the surface of the skin, If light provides too much heat, it can damage the skin surface.

Thus, the amount of energy provided by the first light to the unit area of the skin while the first light is irradiated is less than the amount of energy provided by the second light to the unit area of the skin while the second light is irradiated. It is preferable to irradiate 1 light and 2nd light. Therefore, it is possible to provide energy such that no burn occurs on the surface of the skin maintaining the normal temperature during the first light irradiation, and to provide a sufficient amount of thermal energy required for skin treatment during the second light irradiation. . The step of irradiating the first light and the step of irradiating the second light may be variously implemented by differently adjusting the output of the irradiated light, the irradiated area of the light or the irradiation time of the light, and the like, which will be described in detail below. do.

First, in the step S10 of irradiating the first light and the step S30 of irradiating the second light, the output of the light irradiated through the light irradiator 200 may be differently controlled. Here, the light output may be controlled in various ways. For example, the light output may be controlled by adjusting the amount of current supplied from the light generator 100 to the flash lamp that excites the laser medium. Accordingly, the controller controls the light generator 100 to irradiate the first light at step S10 to irradiate the first light with a relatively small output (for example, 20W, see a in FIG. 4). In the step S30 of irradiating the second light, the second light may be irradiated with a larger output (for example, 100W, see b of FIG. 4) when the first light is irradiated. When the first light and the second light have the same wavelength and irradiate with the same irradiation area for the same time, the first light having a relatively small output can provide a smaller amount of thermal energy to the skin surface than the second light. .

In addition, the amount of energy transmitted to the skin in the step S10 of irradiating the first light and the step S30 of irradiating the second light may be controlled by adjusting the area to which the light is irradiated in each step. In this embodiment, as shown in FIG. 5, the light irradiation unit 200 of the handpiece 20 includes a focusing optical system 210 for focusing and irradiating light transmitted from an optical fiber. The focusing optical system 210 may include at least one optical member such as the lens 211, and may control the size of an area to which light is irradiated by changing the position of the optical member constituting the focusing optical system 210. At this time, the light having the same wavelength and irradiated with the same output for the same time, the larger the irradiation area, the less energy is supplied per unit area. Therefore, in the step S10 of irradiating the first light, the amount of thermal energy supplied per unit area to the target position can be reduced by irradiating the light with a larger irradiation area than in the step S30 of irradiating the second light (FIG. 5). In this case, as the first light is irradiated with a large irradiation area, the effect of supplying thermal energy to a deep position in the skin can also be seen.

In addition to this, it is also possible to control the amount of heat energy delivered to the skin by adjusting the time the light is irradiated. The shorter the light irradiation time, the less the amount of heat energy applied to the skin. Therefore, by controlling the time for irradiating the first light shorter than the time for irradiating the second light, it is possible to prevent the phenomenon that thermal damage occurs during the preheating process.

As such, the controller differently controls at least one condition of the light output, the irradiation area, and the irradiation time during the first and second light irradiations, so that the first light irradiation preheats the skin tissue without damaging the surface of the skin and the second light. When irradiated with light, the cooled skin provides sufficient heat energy.

At this time, the treatment for the skin lesion is mainly progressed by the second light, the first light mainly serves to preheat the internal tissue of the skin rather than directly treating the skin. Here, although the light of the same wavelength may be used as the first light and the second light, it is preferable to use light having different wavelengths in consideration of the function of the first light and the second light in each step.

The light generator of this embodiment includes a first resonator 110 for generating first light and a second resonator 120 for generating second light (see FIG. 2). Here, the second resonator 120 is configured to generate light of a wavelength effective for the skin lesion to be treated. In addition, the first resonator 110 may be configured to generate light having a wavelength that is excellent in skin permeability compared to the second resonator 120, and thus may increase the preheating effect of the skin when the first light is irradiated. As an example, the first resonator 110 includes a yttrium aluminum garnate with neodymium (Nd: YAG) medium, and the second resonator 120 is configured to include a chrysoberyl crystal with Chromium medium. Therefore, during the first light irradiation, the skin is preheated by irradiating light having a wavelength of 1064 nm having excellent skin permeability generated from the first resonator 110 (see a of FIG. 6), and during the second light irradiation, the second resonator ( Light of 755 nm wavelength generated from 120 may be irradiated to treat skin lesions (see FIG. 6B).

As described above, the optical device for treating skin according to the present invention irradiates the first light for preheating the skin under the control of the control unit 400, sprays the cooling gas, and then supplies the second light for treating the skin lesion. It works to investigate. In this case, the user may instruct driving to the control unit 400 through the control panel 11 or the control unit 21. When the user's instruction is input, the control unit 400 sequentially performs the above three steps as a set of operations. Proceed to

7 is a graph illustrating a change in temperature of the skin when the optical device for treating skin is controlled in the order of FIG. 3, and FIG. 7 b illustrates a temperature of the skin surface, and FIG. The temperature is shown. Hereinafter, the temperature change of the skin surface and the internal tissue during skin treatment using the present embodiment will be described with reference to FIG. 7.

First, the first light having a wavelength of 1064 nm to the target position of the skin maintaining the normal temperature is t ₁ Investigate for time. At this time, it is preferable to set the irradiation area and the irradiation time according to the light output so that the temperature of the surface of the skin during the first light irradiation can be prevented from rising above 50 ° C. Specifically, the first light may be irradiated with an irradiation area of 50 mm ² or more for a time ranging from 1 ms to 1 s.

As above, as the first light is irradiated, the surface temperature of the target position gradually increases (see FIG. 7B), and the temperature of the internal tissue of the skin also gradually warms up (see FIG. 7C).

On the other hand, even when the irradiation of the first light is finished, the temperature of the skin surface and the internal tissue of the skin continuously rises for a predetermined time and then falls. Therefore, it is possible to maintain the standby state for t2 hours until the temperature of the skin sufficiently rises after the first light irradiation. At this time, the standby state may be maintained at 100 ms or less, and may be set to proceed to the next step without proceeding with the standby state at the user's discretion.

As described above, when the target position of the skin is preheated by the first light irradiation, a cooling gas is injected to the target position to cool the skin surface. The cooling gas injection time t ₃ may be controlled in a range of 10 ms to 300 ms.

In this case, as shown in Fig. 7, the surface of the skin at the target position is rapidly cooled below minus 10 DEG C by cooling gas injection (see a in Fig. 7). In contrast, the internal tissue of the skin is not significantly affected by the cooling gas injection and remains preheated to a temperature higher than normal temperature (see b of FIG. 7).

When the cooling gas is injected, after having a waiting time t ₄ for 10ms to 100ms, the second light is irradiated to the target position. As described above, the second light has a wavelength of 755 nm and can set light output, irradiation time and irradiation area according to the skin lesion.

The second light irradiation causes thermal energy to be provided to the skin surface and the tissue inside the skin at the target location to increase the temperature. At this time, the inside of the target position is additionally supplied with thermal energy in a state of being preheated by the first light, and thus rises to a higher temperature than in the prior art.

As such, since the present invention cools the surface of the skin in the state of preheating the target position by irradiating light and proceeds the treatment through secondary light irradiation, it is desirable to provide sufficient heat energy for treatment without damaging the surface of the skin. It is possible.

However, in the present embodiment, a configuration in which the first light irradiation step, the cooling gas injection step, and the second light irradiation step are controlled to operate as a set has been described as an example, but the present invention is not limited thereto. In addition, it is also possible to repeat the step of spraying the cooling gas and irradiating light again after the second light irradiation several times, and by modifying the detailed order according to the lesion, various treatments such as hair removal or skin vascular treatment Applicable to the field.

Claims (13)

A light irradiation unit for irradiating light generated by the light generation unit to a target position of the skin;
A cooling unit cooling the surface of the skin by injecting a cooling gas to the target position; And,
And a control unit controlling driving of the light irradiation unit and the cooling unit.
The control unit is configured to irradiate the first light to the target position by the light irradiation unit, the cooling unit to inject the cooling gas to the target position, and then emit the second light to the target position by the light irradiation unit. And controlling the cooling unit,
The energy supplied per unit area of the target position during the irradiation of the first light is less than the energy supplied per unit area of the target position during the irradiation of the second light. The method of claim 1,
And the first light and the second light differ in at least one of light output, light irradiation time, light irradiation area, and wavelength of light. 3. The method according to claim 1 or 2,
And the first light is irradiated with less power than the second light. 3. The method according to claim 1 or 2,
And a focusing optical system installed on a traveling path of the light generated by the light generating unit to adjust an irradiation area of the light irradiated to the target position, wherein the control unit has a larger irradiation area than that of the second light. Optical device for skin treatment, characterized in that for controlling the focusing optical system to be irradiated. 5. The method of claim 4,
The focusing optical system includes at least one optical member that is installed to be movable along a path of light, and the optical member adjusts an irradiation area of light while moving under the control of the controller. . 3. The method according to claim 1 or 2,
And the control unit controls the irradiation time of the first light and the second light in the light irradiation unit, and controls the first light to be irradiated for a shorter time than the second light. The method according to claim 6,
At least one shutter is provided on a path through which the light generated by the light generator travels, and the controller controls the irradiation time of the first light and the second light by opening and closing the shutter. Optical device. 3. The method according to claim 1 or 2,
The control unit is characterized in that the light irradiation unit irradiates the first light, and after waiting for 0 ~ 100ms, the cooling unit for controlling the optical device, characterized in that the control to spray the cooling gas. 3. The method according to claim 1 or 2,
The control unit is an optical device for skin treatment, characterized in that the cooling unit injects the cooling gas, and waits for 10 ~ 100ms and the light irradiation unit to irradiate the second light. delete delete delete delete

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