KR101599278B1 - Skin cooling handpiece - Google Patents

Abstract

One example of the skin cooling handpiece of the present invention is a lens barrel including a lens for receiving a laser from the outside and a lens barrel connected to the lens, A laser output unit including a lens shift dial for adjusting a spot size of the laser output by the generator, a solenoid valve for controlling the injection time of the cooling gas by receiving a cooling gas from the outside, A cooling gas injection shutter connected to the valve to irradiate the skin of the subject to be examined with the cooling gas, a first sensing unit for sensing an energy amount of the laser output from the laser generating unit, A second sensing unit for sensing a spot size of the laser through the first sensing unit and the second sensing unit, And a controller for controlling the operation of the solenoid valve and the cooling gas injection shutter in response to information sensed by each sensing unit, wherein the control unit controls the laser gas injection unit The opening and closing time of the solenoid valve is adjusted according to the magnitude of the energy of the laser gas and the degree of opening of the cooling gas injection shutter is adjusted according to the spot size of the laser sensed by the second sensing unit, , And controls the control of the cooling gas.

Description

Skin cooling handpiece {SKIN COOLING HANDPIECE}

The present invention relates to a skin cooling handpiece.

Laser treatment is done in a way that damages the tissue by laser thermal energy. Because the size or depth varies depending on the lesion, the spot size, laser energy, and laser wavelength of the laser are changed to treat the lesion. When the lesion is treated by changing the parameters of the laser treatment device as described above, the lesion is necrotized by heat energy. In this process, however, the secondary energy of the heat transferred to the skin causes thermal damage to the surrounding tissue.

Therefore, in order to solve the above problems, a laser is used to form a continuous or discontinuous pulse to reduce the side effect due to the ambient heat damage due to the secondary energy of the conducted heat. If the time it takes for the target tissue to send 50% of the heat to the surrounding area is called Thermal Relaxation Time (TRT), if the laser beam is delivered in a time shorter than the thermal relaxation time of the tissue, Which means that you do not have enough time to do so, which causes less thermal damage to the surroundings.

One of the methods of making the pulse train as described above is to apply a laser pulse to a treatment target region with a high peak power for a very short period of time, thereby causing a minimal secondary thermal damage to a surrounding region of the target tissue, Damage and evaporation.

However, the skin sensation is divided into five types, such as tactile sense, pressure angle, temperature angle, cooling, Such sensations are believed to correspond to receptors corresponding to each sensation in the skin.

During the laser treatment, the laser emits heat energy, and the heat energy primarily affects the temperature, especially the warmth, of the skin sensation. The warmth responds to the maximum at 48 to 55 degrees. When the temperature is above 44 ~ 45 degrees, which is the pre-warming phase, the excitement of the entrapment fiber is added to the pain. Therefore, laser thermal energy that radiates more than 100 degrees causes the skin to feel pain.

Therefore, it is possible to reduce thermal damage and pain by laser pulse method, but it is not a method that can be originally controlled.

Accordingly, in order to eliminate the residual pain due to the laser thermal energy as described above, the handpiece is equipped with a cooling device, and the skin is cooled to 3 to 10 degrees for a short time before the laser pulse enters the treatment target.

At this time, if the skin cooling temperature is less than 3 degrees, the moisture in the treatment area may be evaporated to damage the treatment area. If the skin cooling temperature is higher than 10 degrees, the skin temperature of the treatment area rises, Therefore, it is best to cool the skin between 3 and 10 degrees.

The skin cooling device can be largely divided into a contact type and a non-contact type, and a representative example of a method that is firstly used in a noncontact manner is a method of cooling the skin by cold air. In the above-mentioned cold wind method, in order to make cold wind, a bulky cold air device should be used and a warm-up time is required in order to make cool air of 10 degrees or less.

The contact type uses a crystal with a good temperature conductivity with a low refractive index such as sapphire, and uses a method of cooling the skin by directly contacting the skin with an electric cooling method such as TEC. The above-mentioned contact type method has a problem that secondary damage to the skin can be caused by the cooling contact.

SUMMARY OF THE INVENTION The present invention provides a skin cooling handpiece for changing a cooling gas injection state according to a laser output state.

According to an aspect of the present invention, a skin cooling handpiece includes a lens barrel including a lens for receiving a laser from the outside, and a lens barrel connected to the lens, A laser output part including a lens shift dial for adjusting a spot size of the laser output from the laser generator, a solenoid valve for controlling the injection time of the cooling gas by receiving a cooling gas from the outside, A cooling gas injection shutter connected to the solenoid valve for irradiating the skin of the subject to be examined with the cooling gas, a first sensing unit for sensing an energy amount of the laser output from the laser generation unit, A second sensing unit for sensing a spot size of the laser through the first sensing unit and the second sensing unit, And a controller for controlling the operation of the solenoid valve and the cooling gas injection shutter in response to information sensed by each sensing unit, the control unit being connected to the second sensing unit, The controller controls the opening / closing time of the solenoid valve according to the magnitude of the energy of the laser, adjusts the opening degree of the cooling gas injection shutter according to the spot size of the laser sensed by the second sensing unit, The control of the cooling gas is controlled.

The laser output unit further includes a skin contact supporting part formed below the output end of the lens barrel, wherein the laser output part is formed as a support for preventing the hand from shaking when the laser is irradiated while being kept at a distance from the skin of the subject.

According to this aspect, the skin cooling handpiece according to an embodiment of the present invention has an effect of providing a skin cooling handpiece that changes the state of cooling gas injection according to the laser output state.

1 is a perspective view illustrating a structure of a skin cooling handpiece according to an embodiment of the present invention.
2 is a block diagram illustrating a system for controlling a cooling gas injection unit according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

Hereinafter, a skin cooling handpiece according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1, in an embodiment of the present invention, a skin cooling handpiece includes a lens (not shown) receiving a laser output from a laser generator (not shown) A lens barrel 11 including a lens barrel 11 and a lens moving dial 12 for adjusting the lens position inside the lens barrel 11 and a solenoid A valve (solenoid valve) 21, and a cooling gas spraying part 20 connected to the solenoid valve 21 and including a cooling gas spraying shutter 22 for irradiating the skin with cooling gas.

The laser output unit 10 includes a skin contact support unit 13 formed as a support for preventing hand shake when irradiating a laser beam at a distance from the skin of the subject to be examined, And further below the front end (A) of the lens barrel (11), which is a side from which one laser is output.

The lens barrel 11 has a side to which the lens moving dial 12 is connected as a rear end B of the lens barrel 11 and a side where the laser passes through the lens barrel 11 as a front end A. [

The laser generating unit is connected to the lens moving dial 12 located at the rear end B of the lens barrel 11 and outputs the laser having the predetermined energy to the inside in the direction of the rear end B of the lens barrel 11.

When the laser generating unit outputs a laser to treat the skin of the subject to be examined with a laser, the laser generating unit transmits the laser to the lens inside the lens barrel 11 through the lens moving dial 12.

The lens barrel 11 is formed in a cylindrical shape in which the lens is moved from one circular side to another circular side.

As described above, the lens barrel 11

The lens barrel 11 moves between the front end and the rear end of the lens through the rotation operation of the lens moving dial 12 positioned at the rear end of the lens barrel 11. [

The lens inside the lens barrel 11 moves from the front end A to the rear end B to adjust the spot size of the laser transmitted from the laser generating portion at the rear end B of the lens barrel 11 .

The laser output unit 10 configured as described above outputs a laser to the skin of the subject (patient) requiring laser treatment. In order to prevent damage other than the treatment caused by the temperature of the laser in the laser treatment, 10) at the same time as the irradiation of the cooling gas suitable for the output power of the laser and the spot size of the laser.

 2, the cooling gas spraying unit 20 includes a first sensing unit 110 for sensing the amount of energy of the laser output from the laser output unit 10, The second sensing unit 120 senses the position of the first sensing unit 110 and receives information sensed by the first sensing unit 110 and the second sensing unit 120 to control the solenoid valve 21 and the cooling gas injection shutter 22 To control unnecessary damage by the laser and to control the injection of cooling gas to calm the pain during laser treatment with the skin cooling handpiece.

The first sensing unit 110 is connected to the laser generating unit, and when the user starts laser irradiation using the skin cooling handpiece, the laser generating unit sets the energy of the laser to command the output, do.

The first sensing unit 110 transmits the received energy amount to the controller 200.

When the user moves the position of the lens in the lens barrel 11 by operating the lens shift dial 12 to adjust the spot size of the laser for treatment, the second sensor 120 detects the position of the moved lens Detection.

The second sensing unit 120 is connected to the lens movement dial 12 and receives a lens movement command signal from the operation of the lens movement dial 12 to determine the position of the lens. The position of the lens itself is judged by the resistance value of the connected variable resistor. In addition, the second sensing unit 120 may be connected to the lens barrel 11 to detect the position of the lens by sensing the inside of the lens barrel 11.

When the first and second sensing units 110 and 120 sense the energy of the laser and the position of the lens, the sensed information is transmitted to the control unit 200.

The control unit 200 controls the opening time of the solenoid valve 21 according to the amount of laser energy received from the first sensing unit 110 to control the amount of cooling gas to be injected. For example, when the output laser beam is output with a high energy amount, a large amount of cooling gas is required accordingly. Therefore, the solenoid valve 21 is opened longer than the laser beam having a small energy amount, .

In addition, the controller 200 controls the opening degree of the cooling gas injection shutter 22 according to the position of the lens received from the second sensing unit 120.

This operation is performed to adjust the spot size of the cooling gas injected according to the spot size of the laser because the spot size of the laser output from the laser output unit 10 changes according to the position of the lens.

When the spot size of the laser output to the skin of the subject is maximized by the movement of the lens, the cooling gas injection shutter 22 is opened to the maximum to increase the spot size of the injected cooling gas.

Further, when the spot size of the laser output to the skin of the subject is minimized by the movement of the lens, the cooling gas spraying shutter 22 is opened to the minimum to make the spot size of the sprayed cooling gas small.

The cooling gas injection shutter 22 is configured such that the shutter is closed and opened around the center and the center point of the position where the laser is output to the skin of the subject and the cooling gas injected from the cooling gas injection shutter 22 are formed on the skin of the subject When the open position of the cooling gas injection shutter 22 is changed according to the variation of the laser spot size by adjusting the center point of the position, the center point does not change and the accuracy of the injection is enhanced.

FIG. 1 is a structural view of a skin cooling handpiece according to the present invention, in which a laser produced by a laser generator is transmitted to the rear end of a lens barrel 11 by a laser delivery device.

When the user changes the lens movement dial 12, the lens in the lens barrel 11 moves and the spot size of the laser is changed.

The laser beam having the spot size changed is irradiated to the skin of the patient through the lens barrel 11 and the skin contact support 13.

In this case, the solenoid valve 21 is controlled by the control unit 200 so that the cooling gas is delivered to the output terminal of the solenoid valve 21.

The cooling gas output from the solenoid valve 21 is controlled by the control unit 200 and transmitted to the patient's skin through the open cooling gas injection shutter 22. [

As described above, according to the present invention, the inclination angle of the injection angle is controlled according to the spot size of the output laser, the injection range of the cooling gas is controlled, and the amount of the cooling gas injected according to the energy level of the laser is controlled, Thereby efficiently controlling the amount of heat transferred to the user when the eigens are irradiated. This reduces the risk of burn or pain of the user and increases the satisfaction of the user.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: laser output part 11: lens barrel
12: Lens shift dial 13: Skin contact support
20: Cooling gas injection part 21: Solenoid valve
22: cooling gas injection shutter 110: first sensing unit
120: second sensing unit 200:

Claims (2)

A lens barrel including a lens for receiving a laser from the outside, and a spot size of the laser output from the laser generator, which is connected to the lens and changes the position of the lens in the barrel, A laser output portion including a lens shift dial for adjusting
A solenoid valve connected to the solenoid valve for controlling the injection time of the cooling gas to receive the cooling gas from the outside, a cooling gas spray shutter connected to the solenoid valve for spraying the cooling gas onto the skin of the subject to be examined, A second sensing unit connected to the lens and sensing a spot size of the laser through the position of the lens, and a second sensing unit coupled to the first sensing unit and the second sensing unit, And a controller for controlling the operation of the solenoid valve and the cooling gas injection shutter in response to information sensed by each sensing unit,
And a cooling gas distributing portion
And,
The control unit adjusts the opening / closing time of the solenoid valve according to the magnitude of energy of the laser sensed by the first sensing unit, and adjusts the opening degree of the cooling gas injection shutter according to the spot size of the laser sensed by the second sensing unit To control the control of the cooling gas when the lesion of the subject is treated with the laser
Skin cooling handpiece. The method of claim 1,
Wherein the laser output unit further comprises a skin contact supporting part formed below the output end of the lens barrel, the support part being formed as a support for preventing the hand from shaking when irradiating the laser light while being kept at a distance from the skin of the subject.

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