KR101386496B1 - The multi-laser generating system - Google Patents

Abstract

The present invention relates to a multi-laser oscillator, and long pulse endiyag laser and Q-switch endiyag laser can not be used together in one optical base due to the optical characteristics to solve the problem that was sold to each device as a single device It was developed to allow the selective use of long pulse endyag lasers and Q-switch endyag lasers;
By the light emitted from the first lamp, the first rod oscillates the laser in one direction, passes only the laser with a certain wavelength, and passes the first rod again by an out coupler that reflects the other wavelength in the opposite direction. An oscillating part that is moved in the opposite direction, the shifted wavelength passes through the polarizer and is reflected by the rear mirror in the opposite direction to pass through the first rod and then to the out coupler; A laser oscillation apparatus comprising an amplifying unit for amplifying a wavelength passing through the out coupler through a second rod including a second lamp;
A light modulator (Pockels cell) is mounted between the polarizing prism and the rear mirror;
Between the optical modulator and the rear mirror, a through hole through which the wavelength passed through the optical modulator passes, and a Q-lens for aligning a different refraction angle with the long pulse endiyag laser when used as a Q-switch endiyag laser. And a converting device including a moving member including a blocked portion that cannot pass a wavelength, and a first motor for selectively moving the through-hole and Q-lens and the blocked portion of the moving member on a path of the wavelength. The present invention relates to a multi-laser oscillation apparatus.

Description

Multi-Laser Oscillation System

The present invention relates to a multi-laser oscillator, which will be described in more detail. The long-pulse endiyag laser and the Q-switch endiyag laser cannot be used together in one optical base due to its optical characteristics, thereby solving the problem of being sold in each device. Therefore, the present invention relates to a multi-laser oscillation device developed to selectively use a long pulse end device and a q-switch end device.

Since the discovery of the laser has been steadily applied to the medical field, especially Nd: Yag Laser (Hd) laser and helium neon laser and pigment laser have excellent effect in the treatment of skin diseases, the demand is increasing.

FIG. 9 is a conceptual view showing the structure of a long pulse endiyag laser oscillation apparatus, in which the first rod 12 oscillates a laser in one direction by light emitted from the first lamp 11 and has a predetermined wavelength (light quantity). It passes through the first rod 12 again in the opposite direction by the out coupler 13 which passes only the laser and reflects the other direction in the opposite direction, and then again in the opposite direction by the rear mirror 15. An oscillation part 1 which is reflected by the first rod 12 and passes through the first coupler 12 to the out coupler 13;

The long-pulse end device laser oscillator having an amplifying unit 2 for amplifying the wavelength passing through the out coupler 13 through the second rod 22 having the second lamp 21 is shown. .

In this case, when the devices are arranged in a line, the device is very long. Thus, the path between the oscillation unit 1 and the amplification unit 2 is changed by 180 degrees by two first and second reflection mirrors 23 and 24. In addition, it is common for the laser that has passed through the amplifier 2 to be supplied with the path changed vertically by the third reflection mirror 25.

The above configuration has a principle that only other wavelengths than the predetermined wavelengths are repeated by the out coupler 13 to continue to pass through the out coupler 13 so that only a laser having a constant wavelength is oscillated.

The long pulsed Nd: YAG laser is a laser of 1,064nm wavelength whose medium is Nd: YAG (Yttrium Aluminum Garnate (YAG) with Neodymuim (Nd)). Laser, which can vary up to 300 ms, is most widely used for the treatment of peripheral telangiectasia caused by vasodilation, vascular lesions less than 4 mm in diameter, especially legveins, and long pulse endi The main advantage of a yag laser is its low absorption into melanin and its deep penetration depth.

In addition, the absorption coefficients of methemoglobin and deoxyhemoglobin, the major pigments of blue vascular lesions, are high at 1,064 nm, which is most useful for the treatment of blue vascular lesions.

FIG. 10 is a conceptual diagram showing the structure of a Q-switch end device laser oscillation device, which is different from the above-mentioned long pulse end device laser oscillation device, except that the light is interposed between the polarizer 14 and the rear mirror 15; Pockels cell (modulator 14) and a quarter wave mirror is configured to obtain a short pulse.

The Q-Switched Nd: YAG laser is widely used as a laser for treating pigmented diseases such as freckles, blemishes, pigmentation, and otaban spots, which are caused by increased melanin pigmentation. Since the melanin pigment, which is composed of small particles, needs to be fired for a very short time to break up the melanin, the Q-switched laser can restrain the laser and emit the laser in a very short time. So that it can effectively destroy melanin.

That is, when the light is reflected and amplified between both mirrors while the cue switch is turned on, the laser beam is prevented from being amplified and the density reversal of the laser light is maximized. When the cue switch is turned off at the moment when the density reversal is maximized, a strong laser is emitted in a short time. It acts as a gateway (switch).

Q-Switch Endiyag laser using this characteristic is a laser of 1,064nm wavelength consisting of Nd: YAG (Yttrium Aluminum Garnate (YAG) with Neodymuim (Nd)), and the pulse width is about 5 ~ 12ns and penetration depth at 1,064nm wavelength. Because it is the deepest among the lasers used in medical applications, it is used to treat pigmented lesions deep in the dermis such as Ota nevus, and it uses the wavelength conversion method by harmonic generation using nonlinear crystals such as KTP. It can be used to treat pigmented lesions in the epidermis layer with a small penetration depth by making it 532 nm wavelength, which is half of 1,064 nm. Therefore, the endijag laser capable of oscillating two wavelengths in the treatment of pigmented lesions caused by melanin in the endothelium and dermis is most frequently used, and the therapeutic effect is also excellent.

Roll-pulse endyag lasers and Q-switch endyag lasers are used for skin diseases, but due to their optical properties, they cannot be used together in an optical base, so each device is purchased separately and used accordingly. There were problems in climbing and securing the installation space of equipment.

(Patent Document 1) Republic of Korea Utility Model Registration No. 20-0300584-0000 (December 27, 2002) (Patent Document 2) Korean Patent Registration No. 10-1174392-0000 (August 09, 2012) (Patent Document 3) Korean Patent Registration No. 10-1229111-0000 (January 28, 2013)

The present invention was developed in order to solve the above problems, the object of which is to use a different angle in the optically aligned state based on any one of the long pulse endiyag laser and Q-switch endiyag laser The present invention is to develop a multi-laser oscillation device that can easily correct a path shifted by a deviation so that it can be selectively used as a device to treat skin diseases.

In order to achieve the above object, the present invention provides an out-coupler for oscillating a laser in one direction by light emitted from a first lamp, passing only a laser having a predetermined wavelength, and reflecting the other wavelength in an opposite direction. Out through the first rod again through the first rod to move in the opposite direction, the shifted wavelength is passed through the polarizer and reflected back in the opposite direction by the rear mirror and passed through the first rod. After oscillation unit to send to the out coupler; A laser oscillation apparatus comprising an amplifying unit for amplifying a wavelength passing through the out coupler through a second rod including a second lamp;

A light modulator (Pockels cell) is mounted between the polarizing prism and the rear mirror;

Between the optical modulator and the rear mirror, a through hole through which the wavelength passed through the optical modulator passes, and a Q-lens for aligning a different refraction angle with the long pulse endiyag laser when used as a Q-switch endiyag laser. And a converting device including a moving member including a blocked portion that cannot pass a wavelength, and a first motor for selectively moving the through-hole and Q-lens and the blocked portion of the moving member on a path of the wavelength. It is done.

In addition, a drive gear is mounted on the shaft of the first motor, and the movable member is formed in the shape of a gear meshing with the drive gear.

In addition, a drive gear is mounted on the shaft of the first motor, and a lower end of one side of the moving member is integrally formed with a lever for horizontally engaging with the drive gear.

In addition, by the light emitted from the first lamp, the first rod oscillates the laser in one direction, passes only the laser having a certain wavelength, and the other wavelength passes through the first rod again by an out coupler that reflects in the opposite direction. Moving in the direction, the oscillating portion is passed through the polarizing prism and the optical modulator again reflected by the rear mirror in the opposite direction, passing through the first rod and sent to the out coupler; A laser oscillation apparatus comprising an amplifying unit for amplifying a wavelength passing through the out coupler through a second rod including a second lamp;

First to fourth auxiliary reflecting mirrors, wherein the wavelengths are 90 degrees refracted and reflected four times horizontally just before passing through the polarizing prism, which are directly transmitted to the rear mirror and reflected and then reflected in the same path again; A movable bed to which the auxiliary reflecting mirror is mounted, and a pair of M / L guides formed at the lower part of the moving bed to guide a path through which the first and fourth auxiliary reflecting mirrors enter or exit both sides of the polarizing prism and the optical modulator. And a path converting device comprising a pinion gear mounted to a shaft of a second motor and a rack gear mounted to the movable bed and coupled to the pinion gear to move the movable bed along the path of the M / L guide. It is characterized by.

As described above, the present invention makes it easy to selectively use a long pulse endiyag laser and a Q-switch endiyag laser having a deflection angle in an optical movement path for forming a laser as a single device, and thus the cost of equipment purchase. To reduce the cost, and to reduce the movement of doctors and patients for treatment is more effective treatment is possible.

FIG. 1 is a conceptual diagram according to an embodiment of the present invention.
2 is a perspective view showing a converter according to an embodiment of the present invention
3A to 3B are conceptual views illustrating the operation of the converter according to an embodiment of the present invention.
4 is a conceptual diagram according to another embodiment of the present invention.
5 is a perspective view showing a converter according to another embodiment of the present invention
6A to 6B are conceptual views illustrating the operation of the converter according to another embodiment of the present invention.
7 to 8 is a conceptual diagram according to another embodiment of the present invention
9 is a conceptual diagram showing the structure of a long pulse endagazine laser oscillator
10 is a conceptual diagram showing the structure of a Q-switch endiyag laser oscillator

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram according to an embodiment of the present invention, Figure 2 is a perspective view showing a converter according to an embodiment of the present invention, Figure 3a to 3b is the operation of the converter according to an embodiment of the present invention As a conceptual diagram showing, the first rod 12 oscillates the laser in one direction by the light irradiated from the first lamp 11, and passes only the laser having a predetermined wavelength and reflects the other wavelength in the opposite direction ( 13 through the first rod 12 again by the out coupler and moved in the opposite direction, and the shifted wavelength passes through the polarizer 14 and again by the rear mirror 15 in the opposite direction. An oscillation part 1 which is reflected by the first rod 12 and passes through the first coupler 12 to the out coupler 13; A laser oscillation apparatus comprising an amplifying unit (2) for amplifying a wavelength passing through the out coupler (13) through a second rod (22) having a second lamp (21);

A light modulator (Pockels cell) 16 is mounted between the polarizer 14 and the rear mirror 15;

Between the optical modulator 16 and the rear mirror 15, a through-hole 31 through which the wavelength passing through the optical modulator 16 passes, and a long pulse endiyag laser when used as a Q-switch endiyag laser. Q-lens 32 to allow different refractive angles to be aligned, a movable member 33 including a blocked portion that cannot pass through wavelengths, and a through-hole 31 and Q-lens 32 of the movable member 33. And a converter 3 comprising a first motor 34 for selectively moving the blocked portion on the path of the wavelength.

As described above, Q Switch Nd-Yag Laser and Long Pulse Nd-Yag Laser are developed and sold among Nd-Yag Laser. It is difficult to find a device that can be used together at home and abroad, even in the same optical medium, even if the laser of the same medium cannot be used together in one optical base.

However, the present application was developed to solve the optical alignment and electronic power, which are problematic in using the two lasers together, and to include a shutter function.

The laser has a rear mirror (15) and an out coupler (13) on both sides of the first rod (12) and induces emission when strong energy light is applied to the first rod (12) from the first lamp (11). The laser oscillation is generated by installing a polarizing prism 14 and a light modulator 16 at the front of the rear mirror 15. The light modulator 16 applies a high pressure to a nano second (ns). It outputs a short pulse of and obtains a cuswitch pulse of about 1-2Jules. The long pulse endiyag laser obtains a large energy by applying a long pulse without the need of an optical modulator.

However, if the laser oscillation is used in the same optic, the alignment of each laser is misaligned, but even if the oscillation is made with one optical structure, there is a slight deviation of refraction angle, and the optic is damaged due to free running when using the cue switch. .

In other words, if the alignment of one side is correct, the other side must be abandoned, but it is impossible to use it together. In the case of using the yag laser, the movable member 33 can be moved to compensate for the deflection of the deflection angle that is shifted through the Q-lens 32 so that the combined use is possible. In front of the mirror (15) was also able to act as a shutter to block the laser of the induced emission.

In a more specific configuration of the conversion device, the drive gear 35 is mounted on the shaft of the first motor 34, and the movable member 33 is formed in the shape of a gear engaged with the drive gear 35. As the moving member 33 rotates, the through hole 31, the Q-lens 32, and a portion through which the laser cannot penetrate are selectively positioned on the path of the laser.

At this time, the portion through which the laser cannot penetrate is positioned between the through-hole 31 and the Q-lens 32, and closed. It is desirable to make it possible.

4 is a conceptual diagram according to another embodiment of the present invention, Figure 5 is a perspective view showing a converter according to another embodiment of the present invention, Figure 6a to 6b is an operation of the converter according to another embodiment of the present invention As a conceptual diagram showing, the drive gear 35 is mounted on the shaft of the first motor 34, and the lower end of one side of the movable member 33 is engaged with the drive gear 35 and the legs 36 move horizontally. An embodiment formed integrally is presented.

The above embodiment shows an example in which the moving member 33 is not rotated but moves horizontally to change modes.

7 to 8 are conceptual views according to still another embodiment of the present invention, in which the first rod 12 oscillates a laser in one direction by light emitted from the first lamp 11, and only a laser having a predetermined wavelength The other wavelength passes through the first rod 12 again and moves in the opposite direction by the out coupler 13 reflecting in the opposite direction, and the shifted wavelength is the polarizer and the light modulator. An oscillation part 1 passing through the Pockels cell and reflected by the rear mirror 15 in the opposite direction and passing through the first rod 12 to the out coupler 13; A laser oscillation apparatus comprising an amplifying unit (2) for amplifying a wavelength passing through the out coupler (13) through a second rod (22) having a second lamp (21);

The first to fourth auxiliary reflecting mirrors 41, which have a 90-degree refraction of the wavelength four times immediately before passing through the polarizing prism 14, are transmitted directly to the rear mirror 15, are reflected, and are then reflected in the same path again. , 42, 43, 44, a movable bed 45 to which the first to fourth auxiliary reflector mirrors 41, 42, 43, and 44 are mounted, and a lower portion of the movable bed 45, which is formed on a first side of the movable bed 45. And a pair of M / L guides 46 and a second motor 47 for guiding a path through which the fourth auxiliary reflection mirrors 41 and 44 enter or exit both sides of the polarizing prism 14 and the optical modulator 16. Pinion gear 48 mounted on the shaft of the shaft and the movable bed 45 and coupled to the pinion gear 48 to move the movable bed 45 along the path of the M / L guide 46 The multi-laser oscillation apparatus is characterized by further including the path converting apparatus 4 which consists of the recreation gear 49. As shown in FIG.

In the above embodiment, in order to use the long-switch end-yag laser in the structure for using the q-switch end-yag laser, the moving bed 45 is moved by operating the path conversion device 4 so that the laser is modulated by the optical modulator 16. By passing through the first to fourth auxiliary reflection mirrors (41, 42, 43, 44) without passing through to reach the rear mirror 15 to be able to oscillate the long pulse endiyag laser.

1: oscillation part
11: first lamp 12: first rod
13: out coupler 14: polarization prism
15 rear mirror 16 light modulator
2: amplification unit
21: second lamp 22: second rod
23: first reflecting mirror 24: second reflecting mirror
25: third reflecting mirror
3: inverter
31: through hole 32: Q-lens
33: moving member 34: first motor
35: drive gear 36: reco
4: Path converting device
41: first secondary reflection mirror 42: second secondary reflection mirror
43: third secondary reflection mirror 44: fourth secondary reflection mirror
45: moving bed 46: M / L guide
47: second motor 48: pinion gear
49: Recreational Gear

Claims (4)

By the light emitted from the first lamp 11, the first rod 12 oscillates the laser in one direction, passes only the laser having a predetermined wavelength, and reflects the other wavelength in the opposite direction. The first rod 12 passes through the first rod 12 and moves in the opposite direction. The shifted wavelength passes through the polarizer 14 and is reflected by the rear mirror 15 in the opposite direction. An oscillation unit 1 which passes through the rod 12 and is sent to the out coupler 13; A laser oscillation apparatus comprising an amplifying unit (2) for amplifying a wavelength passing through the out coupler (13) through a second rod (22) having a second lamp (21);
A light modulator (Pockels cell) 16 is mounted between the polarizer 14 and the rear mirror 15;
Between the optical modulator 16 and the rear mirror 15, a through-hole 31 through which the wavelength passing through the optical modulator 16 passes, and a long pulse endiyag laser when used as a Q-switch endiyag laser. Q-lens 32 to allow different refractive angles to be aligned, a movable member 33 including a blocked portion that cannot pass through wavelengths, and a through-hole 31 and Q-lens 32 of the movable member 33. And a converter (3) comprising a first motor (34) for selectively moving the blocked portion on the path of the wavelength.
The method of claim 1, wherein the drive shaft 35 is mounted on the shaft of the first motor 34, the moving member 33 is characterized in that the gear of the gear meshing with the drive gear (35). Multi laser oscillator.
According to claim 1, wherein the drive gear 35 is mounted to the shaft of the first motor 34, the lower end of one side of the movable member 33 is engaged with the drive gear 35, the legs 36 to move horizontally Multi laser oscillation apparatus characterized in that the integrally formed.
By the light emitted from the first lamp 11, the first rod 12 oscillates the laser in one direction, passes only the laser having a predetermined wavelength, and reflects the other wavelength in the opposite direction. The first rod 12 passes through the first rod 12 and moves in the opposite direction. The shifted wavelength passes through the polarizer 14 and the light modulator 16 and then the rear mirror 15. An oscillation part 1 which is reflected in the opposite direction by the first rod 12 and passes to the out coupler 13; A laser oscillation apparatus comprising an amplifying unit (2) for amplifying a wavelength passing through the out coupler (13) through a second rod (22) having a second lamp (21);
The first to fourth auxiliary reflecting mirrors 41, which have a 90-degree refraction of the wavelength four times immediately before passing through the polarizing prism 14, are transmitted directly to the rear mirror 15, are reflected, and are then reflected in the same path again. , 42, 43, 44, a movable bed 45 to which the first to fourth auxiliary reflector mirrors 41, 42, 43, and 44 are mounted, and a lower portion of the movable bed 45, which is formed on a first side of the movable bed 45. And a pair of M / L guides 46 and a second motor 47 for guiding a path through which the fourth auxiliary reflection mirrors 41 and 44 enter or exit both sides of the polarizing prism 14 and the optical modulator 16. Pinion gear 48 mounted on the shaft of the shaft and the movable bed 45 and coupled to the pinion gear 48 to move the movable bed 45 along the path of the M / L guide 46 A multi-laser oscillation device, characterized in that it further comprises a path converting device (4) consisting of a recreation gear (49).

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