KR20190062869A - The laser handpiece with two type of cooling device - Google Patents

Abstract

The present invention relates to a laser handpiece having a cooling device of two types, capable of obtaining an appropriate skin cooling effect, which comprises: a laser output device for adjusting a spot size of a laser; a contact cooling device for cooling skin of a subject heated by the irradiated laser; and a spray cooling device for spraying cooling gas to cool the skin of the subject.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a laser handpiece having two types of cooling devices,

The present invention relates to a laser handpiece equipped with two cooling apparatuses of a contact type and an injection type.

In recent years, techniques for treating skin by modifying or removing the state of skin tissue by irradiating light to the skin have been widely applied, and laser beams, flash lamps, RF radio waves, microwaves microwave, and ultrasound have been developed.

When the light is irradiated to the skin, the light penetrates into the inside of the skin while the light having a specific wavelength is absorbed into various tissues such as collagen, hair follicle and hemoglobin located inside the skin according to the wavelength characteristic, It transforms into thermal energy and causes thermal damage to the tissue to change the state of the tissue.

At this time, the skin treatment apparatus may cause damage to the surface of the skin due to heat energy generated during light irradiation, and it is common to cool the surface of the skin before light irradiation or during light irradiation.

A system for treating skin by irradiating light may cause thermal damage to the skin if excessive heat is accumulated on the skin according to the light irradiation of the light. Therefore, in order to prevent such thermal damage, That is, techniques for cooling the skin have been developed.

This technique of cooling the skin includes a method of spraying cooled air on the skin, a method of cooling the skin by contacting a cooling device having an endothermic function, a method of spraying the refrigerant, and a method of spraying the refrigerant. Fourth, And the like.

However, the above-mentioned various methods have the following problems.

In the method of spraying the cooled air onto the skin, a separate procedure assistant must hold the tube and shoot the cold air at the treatment site, which may interfere with the operation of the practitioner. If the cold air is directed toward the nose of the patient, And the like.

The method of cooling the skin by bringing the cooling device into contact may be difficult to manufacture depending on the structure of the handpiece tip, and there is a problem that the cooling effect is limited even if it is possible.

In addition, the method of sprinkling the refrigerant or the method of using the ice pack has problems such as wearing statues or changing the ice pack frequently, and the effect is also limited.

Korean Patent Laid-Open Publication No. 10-2015-0062305, entitled "Medical Laser Irradiation Unit with Skin Cooling System" (published on Jun. 08, 2015, Applicant: Wonek Co., Ltd.) And the cooling gas is sprayed onto the skin of the subject to be examined.

However, the above-described prior art discloses a technical structure in which the contact cooling method and the spray cooling method are used in a simple parallel manner, and does not disclose a technical structure and function for enhancing the skin cooling efficiency using the two cooling methods.

Patent Document (KOKAI) No. 10-2015-0062305 entitled "Medical Laser Irradiation Unit Having a Skin Cooling System" (Published on Jun. 08, 2015, Wonek Co., Ltd.)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a cooling method and a spray cooling method for cooling a laser irradiation site, respectively, The purpose is to provide.

The present invention has been made in view of the above problems, and it is an object of the present invention to provide an apparatus and method for controlling the same.

According to an aspect of the present invention, there is provided a method of controlling the position of a plurality of lenses provided along a laser irradiation path in a lens barrel, A laser output device for adjusting a spot size; A contact window is provided which is coupled with the output terminal of the laser output device so as to be in contact with the skin of the subject to be examined so that the laser output device is supported and fixed on the subject to be examined and transmitted to the contact window using a thermoelectric element A contact cooling device for absorbing heat to cool the skin of the subject to be heated which is heated by the irradiated laser; And a spray cooling device coupled to a side of the laser output device for spraying a cooling gas onto the skin of the subject to be heated which is heated by the irradiated laser to cool the skin of the subject to be examined, The cooling device is selectively used to be used.

The contact cooling apparatus includes a contact window provided in a material having a high thermal conductivity to contact the skin of the subject to be examined, a thermoelectric element in which the cooling surface absorbs heat of the contact window in contact with the contact window, And a water jacket for dissipating heat of the thermoelectric element in contact with the surface of the cooling jacket, wherein the jet cooling apparatus includes a solenoid valve for controlling a jetting time of the cooling gas, a jetting range of the cooling gas jetted in connection with the solenoid valve, An output amount sensor connected to the laser generation device and measuring the energy amount of the laser output, and a controller for determining a position of the lens by calculating the spot size of the laser, And a T-sensor, which is measured from the output amount sensor and the spot recognition sensor, It may further include; cooling control device including the configuration of a control unit for controlling the opening degree of the opening and closing angle and injection time, the injection nozzle of the intake amount of heat, the solenoid valve of the thermal element in accordance with the output amount and the spot size.

Further, the contact cooling apparatus may be arranged such that the contact window is provided in a circular or symmetrical polygonal shape around the irradiation path of the laser, and the thermoelectric element is provided at one side in the width direction of the contact window, Wherein the contact window forms an asymmetric endothermic structure around a laser irradiation path and the cooling control device calculates an asymmetric endothermic structure of the contact window based on an amount of heat absorbed by the thermoelectric element, The opening and closing time of the solenoid valve, the degree of opening and closing of the injection nozzle, and the injection angle on the basis of the asymmetric heat absorbing structure of the solenoid valve, so that the asymmetric heat absorbing structure can be formed into a symmetric heat absorbing structure.

The cooling control device can increase the output amount for cooling the injection cooling device by the delay time of the response speed of the heat absorbing operation of the contact cooling device.

Further, the cooling control device increases or decreases the amount of output for cooling the contact cooling apparatus and the jet cooling apparatus, respectively, in proportion to the increase or decrease in the laser output amount, and when the laser spot size increases, Increases in proportion to the increase of the spot size, and the output amount of the spray cooling device decreases in proportion to the increase of the spot size, and when the laser spot size decreases, And the output amount of the spray cooling apparatus can be increased in proportion to the decrease of the spot size.

The solution of the above-mentioned problems is merely illustrative and should not be construed as limiting the present invention. In addition to the exemplary embodiments described above, there may be additional embodiments described in the drawings and the detailed description of the invention.

As described above, the present invention has the following effects.

First, by selectively using the contact cooling method and the spray cooling method, a more appropriate skin cooling effect can be obtained according to the use of the laser from the low output to the high output.

Second, the contact and spray cooling methods are respectively adjusted and used according to the amount of laser output or the spot size, so that the operator can easily change the laser output or focus without adjusting the cooling function separately.

Third, when the contact and spray cooling methods are used together, it is possible to obtain an asymmetrical and immediate effect on the contrary to the contact cooling method, based on the contact cooling method in which the effect is asymmetrical with respect to the laser irradiation path, By using the spray cooling method which is complementary to the contact cooling method, it is possible to realize the safety of the subject to be inspected by implementing a proper cooling function at the time, and also to reduce the waste cooling process.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view showing the overall appearance of a laser handpiece according to an embodiment of the present invention.
2 is a partial exploded view showing a detailed configuration of a laser output device of a laser handpiece according to an embodiment of the present invention.
3 is a partial side view showing a detailed configuration of a contact cooling apparatus according to an embodiment of the present invention
4 is a partial view showing the detailed structure of the spray cooling apparatus according to an embodiment of the present invention.
5 is a block diagram showing a configuration of a cooling control device according to an embodiment of the present invention.
6 is a flow chart illustrating a method for controlling two types of cooling devices in accordance with one embodiment of the present invention.

The preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, in which the technical parts already known will be omitted or compressed for simplicity of explanation.

FIG. 1 is a perspective view showing the overall appearance of a laser handpiece according to an embodiment of the present invention, FIG. 2 is a partially exploded view showing a detailed configuration of a laser output device of a laser handpiece according to an embodiment of the present invention, 3 is a partial side view showing a detailed structure of a contact cooling apparatus according to an embodiment of the present invention, and FIG. 4 is a partial view showing a detailed structure of a spray cooling apparatus according to an embodiment of the present invention.

As shown in FIG. 1, a laser handpiece LH (hereinafter referred to as a "laser handpiece") equipped with two types of cooling apparatuses of the present invention irradiates the skin of a subject to be examined with a laser, The laser output device 100, the contact cooling device 200, the spray cooling device 200, and the cooling device 200 are provided for reducing or preventing thermal damage to the skin caused by the laser using two cooling methods, Device 300 and the cooling control device 400. [

Referring to FIG. 2, the laser output apparatus 100 receives a laser output from a laser generator (not shown) provided outside the handpiece and adjusts a laser focus, that is, a spot size, The lens barrel 110, the lens 120, and the configuration of the lens movement dial 130. [0064]

The lens barrel 110 is provided in a shape penetrating through the lens barrel so that a plurality of lenses 120 can be installed therein. The lens barrel 110 is provided with an optical fiber (not shown) And receives the laser from the apparatus, and irradiates the focused laser to the output end.

The lens 120 is disposed in a plurality of positions along the irradiation path of the laser in the lens barrel 110 and adjusts the focus of the laser. The lens 120 includes the moving lens 121, The focus of the laser can be adjusted.

The lens moving dial 130 is provided at one end of the barrel 110 to rotate the outer periphery of the barrel 110 to change the position of the moving lens 121 and adjust the focus of the laser to be transmitted, Adjust the laser spot size.

The configuration of the above-described laser generator (not shown) and the laser output apparatus 100 is a driving apparatus of a laser used in any other laser handpiece, and a detailed description thereof will be briefly described as described above. A cooling device for cooling the skin of the subject to be heated, and a control method of the cooling device will be described in detail.

Referring to FIG. 3, the contact cooling apparatus 200 absorbs and dissipates the heat of the skin that is directly contacted with the skin of the subject to be heated. The contact window 210 includes a contact window 210, a thermoelectric couple 220, And a water jacket 240.

The contact window 210 is coupled to the output end of the laser output device 100 and is spaced apart from the output end so that the focused laser output from the laser output device 100 is focused on the skin of the subject So that the laser output device 100 coupled to the contact window 210 can be fixed without being shaken through the contact window 210 that contacts and supports the skin of the subject to be examined. .

The contact window 210 of the present invention also serves to cool the skin of the subject to be heated by the laser. For this, the contact window 210 is provided in a shape having a circular rim around the laser irradiation point, so that the transmitted heat radially absorbs heat around the laser irradiation point, and is provided with a material having a high thermal conductivity, So that it can easily proceed.

The thermoelectric couple 220 may be made of a material having a high thermal conductivity such as the same material as the contact window 210 or a contact window 210 so as to contact or be integrated with one side of the contact window 210, Is formed to extend vertically in the direction of the output end of the laser output device 100 in the contact window 210 so as to form a wide contact surface with the skin of the subject to be examined.

The thermoelectric element 230 cools the contact window 210 connected to the thermoelectric conversion diagram 220 and the thermoelectric conversion diagram 220 by using the cooling surface and the heat generating surface formed using the Peltier effect. So that the cooling surface is in contact with the thermally conductive surface 220 extending in the direction of the cooling surface 220 to cool the thermally conductive surface 220.

The water jacket 240 is positioned so as to be in contact with the heat generating surface of the thermoelectric element 230 and dissipates heat generated on the heat generating surface of the thermoelectric element 230 through the cooling water flowing therein.

In this case, the contact window 210 and the thermally conductive layer 220 are made of a material having a high thermal conductivity so as to realize a cooling function by heat conduction. However, this is merely an example, and a flow path of the cooling medium So that the cooling function by the coolant can be implemented.

The spray cooling apparatus 300 includes a solenoid valve 310 and a spray nozzle 320. The spray cooling apparatus 300 includes a solenoid valve 310 and a spray nozzle 320. The spray cooling apparatus 300 includes a solenoid valve 310 and a spray nozzle 320, do.

The solenoid valve 310 automatically opens and closes the valve using the electromagnetic force of the electromagnetic coil, and the amount of the cooling gas injected through the opening time of the valve is determined.

The spray nozzle 320 is an output portion for spraying the cooling gas to be sprayed with the solenoid valve 310 opened. The direction of the output portion of the spray nozzle 320 is directed to a portion where the laser is irradiated onto the skin of the subject, The jetting range of the jetting gas can be adjusted by varying the interval between the nozzles, and the jetting angle can be adjusted by changing the direction of the output portion of the jetting nozzle 320.

Here, a universal joint or a ball joint may be used as an input portion of the injection nozzle 320, so that the direction of the output portion of the injection nozzle 320 may be oriented vertically and horizontally.

5 is a block diagram showing a configuration of a cooling control device according to an embodiment of the present invention.

As described above, in the laser handpiece (LH) of the present invention, the contact cooling method and the spray cooling method are selectively used or used together to prevent damage to the subject's skin due to the heating amount of the irradiated laser. .

As shown in FIG. 5, the laser handpiece LH of the present invention controls the contact cooling apparatus 200 and the spray cooling apparatus 300, as well as the other cooling apparatus A cooling control device 400 is provided to control the cooling function to realize a more efficient cooling function.

The cooling control device 400 of the present invention includes the configuration of the output amount sensor 410, the spot recognition sensor 420 and the control unit 430. [

The output amount sensor 410 is installed in the laser generation unit and measures the energy of the set laser output amount when the user starts laser irradiation and discriminates the output amount of the measured laser and provides the data to the control unit 430.

The spot recognition sensor 420 is installed inside the lens barrel 110 and when the user moves the position of the moving lens 121 in the lens barrel 110 by manipulating the lens movement dial 130 for treatment, And provides the data to the controller 430.

The control unit 430 calculates the laser output amount provided by the output amount sensor 410 and the spot recognition sensor 420 and the laser spot size formed by the focus adjustment to determine the laser spot size of the contact cooling apparatus 200 and the spray cooling apparatus 300 The cooling function is controlled by each or in conjunction with each other.

Specifically, the control unit 430 may control the thermoelectric elements 230 of the contact cooling apparatus 200 according to the laser output amount and the laser spot size to vary the heat absorption or cooling efficiency of the contact cooling apparatus 200, Not only the opening time of the solenoid valve 310 of the spray cooling apparatus 300 can be controlled but also the spray range can be controlled together with the spray angle of the spray nozzle 320. [

The cooling device 300 can instantaneously obtain the cooling effect by instantaneously injecting the cooling gas by opening and closing the solenoid valve 310 while the contact cooling device 200 is able to obtain the heat absorption and heat generation The effect is delayed until the operation and the thermal conduction phenomenon between the contact window 210 and the contact window 210. Therefore, when the contact cooling apparatus 200 and the spray cooling apparatus 300 are not used separately but are used together, It is preferable to control and use the spray cooling apparatus 300 that exhibits an immediate effect based on the contact cooling apparatus 200 that appears.

6 is a flow chart illustrating a method for controlling two types of cooling devices in accordance with one embodiment of the present invention.

As shown in FIG. 6, the laser handpiece (LH) of the present invention selectively uses the contact cooling apparatus (200) and the spray cooling apparatus (300) to cool the skin of the subject during laser treatment As a matter of course, it is possible to use more effectively, if necessary, to enable more effective cooling (S1100)

First, when the spray cooling apparatus 300 is used together with the contact cooling apparatus 200, the spray angle of the spray cooling apparatus 300 must be determined.

Specifically, the contact window 210 of the contact cooling apparatus 200 is formed in a circular shape, and the thermoelectric drawing 220 including the thermoelectric element 230 absorbing the contact window 210 is formed on the outer periphery of the contact window 210 The endothermic structure of the contact window 210 due to the heat absorption operation of the thermoelectric element 230 can not be symmetrical with respect to the laser irradiation path and the farther from the contact point of the thermoelectric conversion element 220 is, The cooling efficiency is lowered.

Accordingly, the spray cooling apparatus 300 of the present invention is provided such that the cooling gas is injected in a slanting line at a point symmetrical to the thermal transfer diagram 220 based on the skin point irradiated with the laser, so that the injected cooling gas is also asymmetric , And is provided asymmetrically opposite to that of the contact cooling apparatus (200).

However, it is preferable that the spray angle of the spray cooling apparatus 300 has different spray intensity and spray angle depending on the change of the cooling output amount of the contact cooling apparatus 200, and as the cooling output amount of the contact cooling apparatus 200 is higher, It is preferable that the spray angle of the cooling apparatus 300 is directed to a point near the laser irradiation point and the spray angle of the spray cooling apparatus 300 becomes lower as the cooling output amount of the contact cooling apparatus 200 is lower It is preferable to point to a point that is away in a direction symmetrical with respect to the direction of the axis.

In other words, the control unit 430 of the cooling control device 400 calculates the asymmetric heat absorption structure of the contact window 210 based on the heat absorbed by the thermoelectric element 230, and calculates the opening / closing time of the solenoid valve 310, Controlling the degree of opening and closing of the nozzle 320 to control the injection intensity and controlling the injection direction of the injection nozzle 320 to control the injection angle so that the asymmetric endothermic structure can be completed with a symmetrical endothermic structure. S1200)

Next, since the cooling function of the contact cooling apparatus 200 is operated based on the thermal conductivity of the material, the effect is inevitably delayed. Therefore, the spray cooling apparatus 300, which exhibits an immediate effect, can complement the cooling process of the contact cooling apparatus 200 because instant response can not be immediately responded to the response to the laser irradiation process.

That is, the amount of output for cooling the jet chiller 300 is increased by the delay time of the response speed of the heat-absorbing operation of the contact cooling apparatus 200, so that the shortage of the contact cooling apparatus 200 can be compensated for. (S1300)

If the basic complementary operations of the two cooling apparatuses are established through the operation of the spray cooling apparatus 300 that complements the cooling function of the contact cooling apparatus 200 on the basis of the contact cooling apparatus 200, The complementary behavior of both cooling units is set below when the laser power or output focus is changed.

First, when the laser output amount measured by the output amount sensor 410 of the laser generating apparatus 410 is increased (S1400, Yes) or decreased (S1400, No), the output amounts of the contact cooling apparatus 200 and the spray cooling apparatus 300 (S1510) or decrease (S1520).

If the size of the laser spot is increased or decreased (S1600, Yes) according to the position of the movable lens 121 measured by the spot recognition sensor 420 in the lens barrel 110 (S1600, No) 200 and the jet cooling apparatus 300 are increased or decreased in inverse proportion to each other.

Specifically, when the laser spot size increases (S1600, Yes), since the intensity of the laser is weakened as the laser range increases, the output amount of the contact cooling apparatus 200 that transfers cooling heat from outside the laser irradiation spot to the inside And decreases the output amount of the spray cooling apparatus 300 that transfers the cooling heat from the inside of the laser irradiation point to the outside (S1710)

At this time, the cooling gas injection range of the injection nozzle 320 may be increased (S1711)

Further, when the laser spot size decreases, the intensity of the laser becomes stronger as the laser range becomes smaller (S1600, No), so that the output amount of the contact cooling apparatus 200 that transfers the cooling heat from the outside of the laser irradiation spot to the inside And increases the amount of power of the spray cooling apparatus 300 that delivers the cooling heat to the outside of the laser irradiation point (S1720)

At this time, the cooling gas injection range of the injection nozzle 320 may be reduced (S1721)

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. And the scope of the present invention should be understood as the scope of the following claims and their equivalents.

LH: Laser handpiece
100: Laser output device
110: barrel
120: lens
121: Moving lens
130: Lens shift dial
200: contact cooling device
210: Contact window
220: Thermoelectric drawing
230: thermoelectric element
240: Water jacket
300: Spray cooling system
310: Solenoid valve
320: injection nozzle
400: cooling control device
410: Yield sensor
420: Spot recognition sensor
430:

Claims (5)

A laser output device for controlling a spot size of a laser beam transmitted from a laser generator and adjusting a position of a plurality of lenses provided along a laser irradiation path in a barrel;
A contact window is provided which is coupled with the output terminal of the laser output device so as to be in contact with the skin of the subject to be examined so that the laser output device is supported and fixed on the subject to be examined and transmitted to the contact window using a thermoelectric element A contact cooling device for absorbing heat to cool the skin of the subject to be heated which is heated by the irradiated laser; And
And a spray cooling device coupled to a side of the laser output device for spraying a cooling gas onto the skin of the subject to be heated, the material being heated by the laser to be irradiated,
Characterized in that the contact cooling apparatus and the spray cooling apparatus are selectively used and used
A laser handpiece with two types of cooling devices. The method according to claim 1,
The contact cooling apparatus includes:
A thermoelectric element provided with a material having a high thermal conductivity so as to contact the skin of the subject to be inspected, a thermoelectric element for allowing the cooling surface to absorb the heat of the contact window in contact with the contact window, A water jacket,
Wherein the spray cooling apparatus comprises:
A solenoid valve for controlling the injection time of the cooling gas; and a spray nozzle connected to the solenoid valve for controlling the spray range and the spray angle of the cooling gas to be sprayed,
An output amount sensor connected to the laser generation device and measuring an amount of laser energy output from the laser generation device; a spot recognition sensor connected to the lens to determine a position of the lens to calculate a spot size of the laser; A control unit for controlling the heat absorption amount of the thermoelectric element, the opening and closing time of the solenoid valve, the opening and closing degree of the injection nozzle, and the spray angle according to the output amount of the laser and the spot size measured by the recognition sensor, ≪ RTI ID = 0.0 >
A laser handpiece with two types of cooling devices. 3. The method of claim 2,
The contact cooling apparatus includes:
The contact window is provided in a circular or symmetrical polygonal shape around the irradiation path of the laser, and the thermoelectric element is provided at one side in the width direction of the contact window to absorb the contact window, Forming an asymmetric heat absorbing structure around the path,
The cooling control device includes:
Calculating an asymmetric endothermic structure of the contact window based on an amount of heat absorbed by the thermoelectric element, controlling an opening / closing time of the solenoid valve, an opening / closing degree of the injection nozzle, and an injection angle based on an asymmetric heat absorption structure of the contact window , Characterized in that the asymmetric endothermic structure is formed into a symmetrical endothermic structure
A laser handpiece with two types of cooling devices. 3. The method of claim 2,
The cooling control device includes:
So that the output amount for cooling the injection cooling apparatus is increased by a delay time of the response speed of the heat absorbing operation of the contact cooling apparatus
A laser handpiece with two types of cooling devices. 3. The method of claim 2,
The cooling control device includes:
Increases or decreases the amount of power for cooling the contact cooling apparatus and the injection cooling apparatus in proportion to the increase /
When the laser spot size increases,
The output amount of the contact cooling apparatus is increased in proportion to the increase of the spot size, the output amount of the spray cooling apparatus is decreased in proportion to the increase of the spot size,
When the laser spot size decreases,
Characterized in that the output amount of the contact cooling apparatus is reduced in proportion to the decrease of the spot size and the output amount of the spray cooling apparatus is increased in proportion to the decrease of the spot size
A laser handpiece with two types of cooling devices.

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