KR20140014578A - Nd:yag laser and dual laser integrated system - Google Patents

Abstract

The present invention relates to ND:YAG laser and dual laser integrated system. An example of the ND:YAG laser and dual laser integrated system comprises: ND:YAG laser part mounted in a first mounting part which is located in the upper end part; a dual laser part mounted in a second mounting part which is located alongside of the first mounting part; a power supply unit which is located in the lower end part located in the lower side of the upper end part, and supplies the approved power source to the ND:YAG laser part and the dual laser part separately; a cooling part which is located in the lower end part, and cools the ND:YAG laser part and the dual laser part respectively; a controlling part which controls the operation of the ND:YAG laser part and the dual laser part separately. Accordingly, the user is capable of selectively using various kinds of laser through one laser integrated system thereby improving the convenience of the user, and economic feasibility by not purchasing an individual laser irradiating device. Furthermore, the size and the power consumption of the ND:YAG laser and dual laser integrated system is decreased by supplying the power source to multiple laser part and performing a necessary cooling operation by using one power supply unit and one cooling part.

Description

ND: YAG LASER AND DUAL LASER INTEGRATED SYSTEM}

The present invention relates to an Endi: Yag laser and a dual laser integrated system.

In 1960, the first laser, the ruby laser, was developed and introduced to the medical profession. Nd: YAG laser, helium neon laser and pigment laser have been developed to excel in the treatment of skin diseases.

The basic principle of the laser is that targets such as water, melanin, and oxyhemoglobin have inherent vibration frequencies, and when irradiating a laser with a vibration frequency similar to that of the target, the reaction with the desired target occurs. The reaction between the target and the laser produces a skin disease effect.

Therefore, a desired procedure is performed by irradiating a laser having a corresponding wavelength that generates a reaction with a desired target.

Therefore, various lasers having different wavelengths of light to be output may be divided into excimer lasers, diode lasers, CO ₂ lasers, and endagazine lasers.

Depending on the scope of application, such lasers are used for incisions in surgical sites, treatment of vascular diseases, removal of ulcers or tattoos (or scars), etc., and also for removal of tooth decay or implant surgery.

In addition, such a laser treatment is applied to the dermatology field, and the laser is used not only for vascular lesions, pigmentation lesions and hair removal, but also for skin elasticity and regeneration treatment, which is excellent in preventing skin aging and skin regeneration.

Therefore, the technical problem to be achieved by the present invention is to improve the convenience of the user by configuring a single laser unit for outputting different wavelengths.

Endi: Yag laser and dual laser integrated system according to an aspect of the present invention is the endi: Yag (ND: YAG) laser unit mounted to the first seating portion located in the upper end, located in parallel with the first seating portion in the upper end A dual laser unit mounted to a second seating unit, a lower end portion positioned below the upper end portion, and an endi: a power unit for supplying power applied to the yag laser unit and the dual laser unit, respectively; And a cooling unit for cooling the dual laser unit, and a control unit for controlling operations of the endi: yag laser unit and the dual laser unit, respectively.

The endi: Yag laser and the dual laser integrated system according to the above features are located in front of the upper end of the endi: yag laser and the dual laser integrated system so as to be connected to the control unit, and the operating state of the endi: yag laser unit and the dual laser unit. The display unit may further include a display unit configured to display or set operating conditions of the endi: yag laser unit and the dual laser unit.

The endi: yag laser unit may output a Q-switched ND (YAG laser) having a wavelength of 1064 nm.

The dual laser unit may output a long pulse alexandrite laser having a wavelength of 755 nm or a long pulse endi: yag laser having a wavelength of 1064 nm.

According to this feature, the user can selectively use several types of lasers by using a single laser integrated system, thereby improving user convenience and economic efficiency since there is no need to purchase a device for irradiating each laser separately. do.

In addition, power is supplied to the plurality of laser units by using one power supply unit and one cooling unit, and the required cooling operation is performed, thereby reducing the size and size of the laser integrated system and reducing power consumption.

1 is a schematic perspective view of an Endi: Yag laser and dual laser integrated system according to one embodiment of the present invention.
FIG. 2 is a schematic block diagram of the Endi: Yag laser and dual laser integrated system shown in FIG.
3 is a plan view of the endi: yag laser and dual laser integrated system shown in FIG.
4 is a schematic block diagram of a dual laser unit applied to the endi: yag laser and dual laser integrated system shown in FIG.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement 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. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Next, with reference to the accompanying drawings will be described endi: Yag laser and dual laser integrated system according to an embodiment of the present invention.

1 and 2, an endi: yag laser and a dual laser integrated system (hereinafter, referred to as a 'laser integrated system') 100 according to an embodiment of the present invention is an endi: yag (ND: YAG). Laser unit 10, dual laser unit 20, endi: Yag laser unit 10 and the power supply unit 30 is connected to the dual laser unit 20, Endi: Yag laser unit 10 and dual laser unit ( And a display unit 60 connected to the cooling unit 40, an end: Yag laser unit 10, and a dual laser unit 20, connected to the control unit 50, and the control unit 50. have.

The endi: yag laser unit 10 outputs a laser having a wavelength of about 1064 nm as a Q-switched ND: YAG laser output device.

This endi: yag laser unit 10 is located at the upper end of the laser integrated system 10, as shown in FIG.

As shown in FIG. 4, the dual laser unit 20 includes a first laser generator 21 for outputting a long pulsed alexandrite laser and a long pulse enddy: yag laser. And a second laser generator 22 for outputting YAG laser.

The first laser generator 21 outputs a laser having a wavelength of about 755 nm in which the medium is made of alexandrite, and the second laser generator 22 is a laser having a wavelength of about 1064 nm in which the medium is made of Endi: Yag. Outputs

The dual laser unit 20 is located at the upper end of the laser integrated system 10, as shown in FIG. 1, and the endi: yag laser unit 10 at the upper end of the laser integrated system 10, as shown in FIG. Located alongside For this reason, as shown in FIG. 3, the endi: yag laser part 10 and the dual laser part 20 are located adjacent to each other, and are attached to the upper end in the same direction.

Therefore, the upper end of the laser integrated system 10 is divided into a first mounting portion 101 on which the N: Yag laser portion 10 is mounted and a second mounting portion 102 on which the dual laser portion 20 is mounted.

The structure of the dual laser unit 20 will be described in detail with reference to FIG. 4.

The dual laser unit 20 desires the laser output from the first laser laser generator 21, the second laser generator 22, the first laser generator 21 and the second laser generator 22, respectively. The mirror unit 23 outputting in the direction, the reflection detector 24 which detects the amount of light output through the mirror unit 23 and outputs a sensing signal of a corresponding size, and the first and second laser generators ( The controller 25 and the controller 25 for controlling the operations of the first and second laser generators 21 and 22 by controlling the operations of the first and second laser generators 21 and 22 and using the detection signals output from the reflectance detector 24. And a laser display unit 26 connected to the control unit and controlled by the user to control the state of the output signal, and a warning display unit 27 connected to the control unit 25.

The first laser generator 21 generates a first laser having a wavelength of about 755 nm, which is the first wavelength, and the second laser generator 22, has a second laser having a wavelength of about 1064 nm, which is the second wavelength. And the structures of the first and second laser generators 21 and 22 have the same structure except for the wavelength of the generated laser.

Therefore, in this specification, only the structure of the first laser generator 21 will be described.

Referring to FIG. 1, the first wavelength oscillator 211, the first total reflection mirror 212 positioned in front of the first wavelength oscillator 211, and the first partially reflective mirror positioned at the rear end of the first wavelength oscillator 211. 213 is provided.

The first wavelength oscillator 211 is a laser of about 755 nm wavelength and is outputted as a crystal which collects and outputs a flash lamp such as a xenon lamp and light emitted from the flash lamp. The laser rod is formed to surround the laser rod, and reflects the light emitted from the flash lamp toward the laser rod.

Therefore, under the control of the controller 25, when a high power of about 500 to 700 V is charged in the power supply unit (not shown) connected to both terminals of the flash lamp and then discharged momentarily, the flash lamp is turned on, and Light energy is supplied to the laser rods to cause induced emission of light.

The light emitted from the induced emission is laser oscillated by the operations of the first total reflection mirror 212 and the first partial mirror 213 to amplify the intensity of the induced emission light and output it to the mirror unit 23. Through this process, only side-by-side light having the same phase, wavelength, and direction is output, and the wavelength of the light may be determined by the size of a pump wavelength, which is a natural vibration frequency of the laser rod.

 By operation of the first wavelength oscillator 211, the first total reflection mirror 112, and the second partial reflection mirror 113, light having a desired wavelength, that is, 755 nm wavelength, is selected from the light output from the flash lamp. It is output toward the mirror part 23.

In this case, the first total reflection mirror 212 and the first partial reflection mirror 213 are respectively positioned at the same position as the extension lines of both terminals of the laser rod, so that the first total reflection mirror 212 and the first partial reflection mirror Reference numeral 213 faces each terminal of the laser rod.

Therefore, the light output from one terminal of the laser rod toward the first total reflection mirror 212 is reflected by the first total reflection mirror 212 and flows back into the laser rod, and at the other terminal of the laser rod, the first partially reflective mirror portion. The light output toward 213 passes through the first partial reflection mirror 213 and is output toward the mirror 23.

In this case, each of the first total reflection mirror 212 and the first partial reflection mirror 213 may include at least one mirror.

The repetitive reflection operation by the first total reflection mirror 212 and the first partial reflection mirror 213 increases the amount of light having the first wavelength (eg, about 755 nm), and the desired amount of first Light having a wavelength is transmitted through the first partially reflective mirror 213 and outputted toward the mirror 23.

As described above, since the second laser generator 22 also has the same structure as the first laser generator 21 except for the magnitude of the wavelength of light to be output, the second wavelength generator 221 and the second total reflection The mirror part 222 and the 2nd partial reflection mirror part 223 are provided.

Therefore, in order to output the laser of the second wavelength (about 1064 nm), the natural frequency of the laser rod of the second wavelength oscillation unit 221 is different from the natural vibration frequency of the laser rod of the first wavelength oscillation unit 211, and thus light of about 1064 nm. The second total reflection mirror 222 also has a characteristic of total reflection only light of 1064nm.

The second total reflection mirror 222 also totally reflects only light having a second wavelength (about 1064 nm) and transmits light having the remaining wavelength.

The structure and operation of the second partial reflection mirror 223 are the same as those of the first partial reflection mirror 213, respectively.

The mirror unit 23 is positioned in front of the first laser generator 21 and positioned in front of the first mirror 231 and the second laser generator 22 that totally reflects the light output from the first laser generator 21. A second mirror which transmits a part of the light of the first wavelength transferred by the mirror 231 or the light of the second wavelength output from the second laser generator 22 and reflects the remainder toward the reflectance sensing unit 24 ( 232).

In this case, the first mirror 231 is a total reflection mirror, and the second mirror 232 is a partially reflective mirror having a reflectance of about 70% and a transmittance of about 30%.

The reflection detection unit 24 detects an amount of light reflected by the second mirror 232 of the mirror unit 23 and outputs a signal having a corresponding magnitude to the controller 25 according to the detected amount of light.

The laser selector 26 is operated by a user, and is a selection switch in which a selection signal output when the first laser generator 21 is selected and the second laser generator 22 is varied. The control unit 25 determines whether the wavelength of the laser selected by the user is 755 nm or 1064 nm using the signal applied from the laser selection unit 26.

The controller 25 operates the first or second laser generators 21 and 22 to output the laser of the wavelength selected by the user, and is driven by using the signal output from the reflectance detector 24. It is determined whether the state of the laser output from the first or second laser generators 21 and 22 is a normal state or an abnormal state.

The warning display unit 27 includes a display device such as a warning lamp or a liquid crystal display device, and displays an abnormal state of the first or second laser generators 21 and 22 selected by the user to inform the user.

Referring back to FIGS. 1 and 2, the power supply unit 30 supplies power to the endi: yag laser unit 10 and the dual laser unit 20 in common. Accordingly, the laser integrated system 100 does not need to include a power supply unit for the endi: yag laser unit 10 and a power supply unit for the dual laser unit 20, respectively. As a result, the volume of the laser integrated system 100 is reduced, and since the two laser units 10 and 20 are commonly managed by one power supply unit 30, unnecessary power consumption is reduced.

As shown in FIG. 1, the power supply unit 30 is located at the side of the laser integrated system 100 under the upper end where the endi: yag laser unit 10 and the dual laser unit 20 are located.

Since the cooling unit 40 also manages the endi: yag laser unit 10 and the dual laser unit 20 in common, the endi: yag laser unit 10 and the dual laser unit 20 to cool one cooling Only part 40 is required.

This greatly reduces the volume of the laser integrated system 100.

The cooling unit 40 is controlled by the control unit 50 operation.

The cooling unit 40 operates according to a control signal of the control unit 50 to control the temperature of the cooling water present in the cooling unit 40, so that one of the endi: yag laser unit 10 and the dual laser unit 20 Cools the heat generated by the operation. This prevents overheating of the endi: yag laser unit 10 or the dual laser unit 20 in operation.

The controller 50 is located inside the laser integrated system 100, and controls the operations of the endi: yag laser unit 10 and the dual laser unit 20, and also controls the operation of the cooling unit 40.

The controller 50 may be located in the endi: yag laser unit or the dual laser unit or in a separate space in the laser integrated system 100 in which the endi: yag laser unit and the dual laser unit are not located. .

As shown in FIG. 3, the display unit 60 is located adjacent to the dual laser unit 20 on the front surface of the upper end of the laser integrated system 100 and is located in front of the dual laser unit 20. The display unit 60 is drawn out of the laser integrated system 100 so that the user can check the display state of the display unit 60 and change the setting conditions of the laser integrated system 100. Accordingly, the display unit 60 may be a display device that displays a state of the laser integrated system 100 currently in operation, and may be an operation switch unit that changes an operating condition of the laser integrated system by a user.

When the user changes the operating condition of the laser integrated system 100 displayed on the display unit 60, a signal corresponding to the changed condition is applied to the controller 50.

Accordingly, the controller 50 operates one of the endi: yag laser unit 10 and the dual laser unit 20 according to a user's setting condition using the applied signal to irradiate the laser to a desired portion.

At this time, the laser output from the endi: Yag laser unit 10 is desired output through the output unit 11 of the arm type (arm type), as shown in Figure 1, the user is the output unit 11 of the arm type ) To a desired position to irradiate a laser having a wavelength of 1064 nm.

In addition, the laser output from the dual laser unit 20 is the 755nm output from the first or second laser generator 21, 22 by moving the output portion 21 of the fiber type (fiber type) to a desired position Or output a laser having a wavelength of 1064 nm.

At this time, the output unit 11 is connected to the end: Yag laser unit 10 and protrudes to the front of the upper end of the laser integrated system 100, the output unit 12 is connected to the dual laser unit 20 laser It protrudes to the front of the upper end of the integrated system 100. Thus, the outputs 11, 21 protrude side by side in front of the laser integrated system 100.

Endi: Yag laser unit 10, dual laser unit 20, power supply unit 30, cooling unit 40, the control unit 50 according to the present embodiment, as shown in FIG. To form one laser integrated system 100.

As a result, the user can selectively use several types of lasers by using a single laser integrated system 100, thereby improving user convenience and eliminating the need to purchase a device for irradiating each laser separately. It is advantageous.

In addition, as described above, since the power is supplied to the plurality of laser units 10 and 20 by using one power supply unit 30 and one cooling unit 40, the cooling integrated system 100 is performed. Reduces the size and size of the power and also reduces the power consumption.

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.

100: integrated laser system 10: endi: Yag laser unit
20: dual laser unit 30: power supply unit
40: cooling unit 25, 50: control unit
60: display portion 21: first laser generating portion
22: second laser generator 211: first wavelength oscillator
221: second wavelength oscillation portion 212: first total reflection mirror portion
222: second total reflection mirror 213: first partial reflection mirror
223: second partial reflection mirror 23: mirror
231 and 232: mirror 24: reflectance detector
26: laser selector 27: warning display

Claims (4)

ND: YAG laser unit mounted to the first seating part located at the upper end,
Dual laser unit mounted to the second seating portion located in parallel with the first seating portion in the upper end,
A power supply unit located at a lower end of the lower end of the upper end and supplying power to the endi Yag laser unit and the dual laser unit;
A cooling unit located at the lower end and cooling the endi: yag laser unit and the dual laser unit, and
The endi: a control unit for controlling the operation of the yag laser unit and the dual laser unit, respectively
Endi including: Yag laser and dual laser integrated system. In claim 1,
The endi: It is located in front of the upper end of the Yag laser and dual laser integrated system and connected to the control unit, Endi: Display the operating state of the yag laser unit and the dual laser unit or Endi: Yag laser unit and the dual laser unit Endi: Yag laser and dual laser integrated system further comprising a display for setting the operating conditions. In claim 1,
And the endi: yag laser unit outputs a Q-switched ND: YAG laser having a wavelength of 1064 nm. In claim 1,
And the dual laser unit outputs a long pulse alexandrite laser having a wavelength of 755 nm or a long pulse endi: yag laser having a wavelength of 1064 nm.

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