KR20200065345A - Laser devices for treating high intensity pain using complex wavelengths and programmed scanning handpieces - Google Patents

Abstract

The present invention relates to a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece, and more specifically, to increase the effect of high-intensity pain treatment using a complex wavelength and to diversify the penetration depth according to the wavelength. High-intensity pain treatment laser using complex wavelengths and programmed scan handpieces that provide a programmed scan handpiece with a handling method that provides the effect of widening the range of pain treatment and always has the same treatment effect on laser output It is about.

Description

Laser devices for treating high intensity pain using complex wavelengths and programmed scanning handpieces

The present invention relates to a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece, and more specifically, to increase the effect of high-intensity pain treatment using a complex wavelength and to diversify the penetration depth according to the wavelength. High-intensity pain treatment laser using complex wavelengths and programmed scan handpieces that provide a programmed scan handpiece with a handling method that provides the effect of widening the range of pain treatment and always has the same treatment effect on laser output It is about.

In the medical field, laser devices are actively used for examination, surgery, and treatment purposes.

In the field of diagnostic medicine, the chemical component change, color change, morphological displacement, and tissue hardness displacement of the cell tissues in the body are measured using the coherence characteristics of the laser to determine the degree of disease discovery and progression, and Laser procedures are widely applied for incision, destruction of cancer tissue, and haemostasis.

In addition, by using a low-energy energy laser light, such as a laser treatment known as LLTT (Low Level Laer Treatment) in recent years, as if stimulating the human body's pulse points or skin as moxibustion, the pain of the skin or muscles is removed or the affected area is affected. Methods to promote cure are being performed.

In order to use the laser for therapeutic purposes, low energy density light must be irradiated for a long time, and it is currently applied in various fields such as ophthalmology, dermatology, gynecology, plastic surgery, pediatrics, neurosurgery, urology, general surgery, dentistry and laser acupuncture. .

Low-power lasers, such as the Helium Neon (He-Ne) laser in the 650 nm band, significantly increase blood vessel expansion and new blood vessels through bio-stimulation effects to prevent muscle degeneration and reduce swelling by regulating the osmotic pressure of blood vessels and tissues. And has the effect of suppressing pain.

The conventional medical laser device is a simple function of irradiating it to the affected area according to the occurrence of a simple frequency, and thus has a disadvantage in that the penetration effect is weak and the effect is insignificant and uncomfortable to use.

On the other hand, the laser device for pain treatment related to the present invention is used for degenerative diseases and pain in the spinal region depending on the short wavelength, and has an excellent effect, and mostly relies on machining.

As shown in FIG. 1, the conventional technology is effective by transmitting any one of 1064nm and 980nm wavelength bands, and the handpiece for transmission is manufactured in an adjustable form with a size of 10 to 30mm in diameter, so that the therapist directly Patients are being treated for an appropriate amount of time.

The laser output should not stay in one place during treatment.

The reason is that if it stays on, the laser is highly damaged by the heat of the skin's epidermal layer, and thus the skin is burned.

Therefore, the therapist continues to move the pain area and surrounding areas to perform the procedure.

Accordingly, a dedicated therapist is essential, and the clinical results were inevitably different depending on the treatment technique of the therapist.

In the end, in the present invention, in order to solve the above problems, to determine the shape of the output combining the wavelength of 1064nm and 980nm effective for pain, and to provide a technique to treat the output by uniformly programming the pain area do.

(Prior literature) Republic of Korea Patent No. 10-2010-0092077

Therefore, the present invention has been proposed in view of the problems of the prior art as described above, and the first object of the present invention is to increase the effect of high-intensity pain treatment using a complex wavelength and to diversify the penetration depth according to the wavelength to provide a range of pain treatment. I want to expand.

The second object of the present invention is to provide a scan handpiece programmed with a handling method that always gives the same therapeutic effect on laser power.

The third object of the present invention is to apply a black cream which is a catalyst capable of deeply penetrating a laser when irradiating a laser to a pain area at a wavelength of 1064 nm among the wavelengths of a combination treatment laser, so as to mark the pain target to be treated and view the treatment target. It is to be seen, and by performing laser treatment on the black cream, it is to effectively increase the depth of treatment and the penetration depth of the laser.

In order to achieve the problem to be solved by the present invention, a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece,

A handpiece body 100 for providing a laser beam provided from the composite wavelength laser unit 300 to the galvano scanner unit 180 formed therein;

A galvano scanner unit 180 for setting a pain irradiation area range of the laser beam under the control of the galvano motor control control unit;

It consists of a galvano motor control control unit 240 and an LCD monitor unit 280, and obtains information when the laser beam output from the composite wavelength laser unit 300 is a short wavelength or a complex wavelength. A main control means 200 for providing a laser output information for each position to the no-motor control control unit to control the galvano scanner unit, and for providing information set in the LCD monitor unit 280;

It includes; when obtaining a laser beam output signal by the main control means 200, a composite wavelength laser unit 300 for providing a laser beam to the galvano scanner unit 180.

Through the laser device for high-intensity pain treatment using the complex wavelength and the programmed scan handpiece according to the present invention having the above configuration and action, the effect of high-intensity pain treatment is increased by using the complex wavelength, and the penetration depth is varied according to the wavelength It exerts an effect to widen the range of pain treatment by becoming angry.

In addition, it has the effect of providing a programmed scan handpiece with a handling method that always gives the same treatment effect to the laser output.

That is, the treatment behavior using the general output handpiece of the existing laser therapist differs for each individual, thereby providing different effects and different results on the treatment result, thereby providing low reliability of treatment.

However, in the present invention, it is possible to provide a uniform result value and high reliability of treatment for each treatment result by providing a scan handpiece programmed with a handling method for always giving the same treatment effect to the output.

In addition, by applying a black cream, a catalyst capable of deeply penetrating the laser when irradiating a laser to a pain area at a wavelength of 1064 nm among the wavelengths of the combination therapy laser, the pain target to be treated is displayed so that the treatment target is visible. , By performing the laser treatment on the black cream, it exhibits an effect of effectively increasing the depth of laser penetration and treatment of the exact pain area.

1 is a state diagram of the use of a laser device for general pain treatment.
2 is an overall configuration diagram of a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece according to an embodiment of the present invention.
3 is a control block diagram of a high intensity pain treatment laser apparatus using a complex wavelength and a programmed scan handpiece according to an embodiment of the present invention.
4 is an exemplary view showing various pattern shapes that are programmed information of a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece according to an embodiment of the present invention.

The following is merely illustrative of the principles of the invention. Therefore, those skilled in the art, although not explicitly described or illustrated in the specification, can implement the principles of the present invention and invent various devices included in the concept and scope of the present invention.

In addition, all conditional terms and examples listed herein are intended to be understood in principle only for the purpose of understanding the concept of the present invention, and should not be construed as being limited to the specifically listed embodiments and conditions. do.

Means for solving the problems of the present invention are as follows.

That is, the laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece,

A handpiece body 100 for providing a laser beam provided from the composite wavelength laser unit 300 to the galvano scanner unit 180 formed therein;

A galvano scanner unit 180 for setting a pain irradiation area range of the laser beam under the control of the galvano motor control control unit;

It consists of a galvano motor control control unit 240 and an LCD monitor unit 280, and obtains information when the laser beam output from the composite wavelength laser unit 300 is a short wavelength or a complex wavelength. A main control means 200 for providing a laser output information for each position to the no-motor control control unit to control the galvano scanner unit, and for providing information set in the LCD monitor unit 280;

When the laser beam output signal is obtained by the main control means 200, a composite wavelength laser unit 300 for providing the laser beam to the galvano scanner unit 180; characterized in that it comprises a.

At this time, it characterized in that it further comprises a; a zoom focus unit 170 for adjusting the size of the laser beam that is formed and output on the lower side of the galvano scanner unit 180.

On the other hand, the laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece according to another embodiment,

A handpiece body 100 for providing a laser beam provided from the composite wavelength laser unit 300 to the galvano scanner unit 180 formed therein;

A focus unit 160 formed on an upper side of the handpiece body to provide a laser beam to a galvano scanner unit formed on the lower side;

A galvano scanner unit 180 for providing a laser beam provided through the focus unit to the zoom focus unit 170 formed on the lower side, and for setting a pain irradiation area range under the control of the galvano motor control unit;

It is formed on the lower side of the galvano scanner unit, by adjusting the distance (C) with the F-theta mirror unit 150, a zoom focus unit 170 for adjusting the output laser beam size;

An F-theta mirror unit 150 formed under the zoom focus unit 170 to provide a laser output range;

It is configured to include a galvano motor control control unit 240, and obtains information in the case of a short wavelength or a complex wavelength of the laser beam output from the complex wavelength laser unit 300 to locate the galvano motor control control unit. Main control means (200) for providing the laser output information to control the galvano scanner unit, and to provide information set in the LCD monitor unit (280);

When the laser beam output signal is obtained by the main control means 200, a composite wavelength laser unit 300 for providing the laser beam to the galvano scanner unit 180; characterized in that it comprises a.

At this time, the wavelength band of the laser beam,

However, in the case of a wavelength, it is characterized by being one of 980nm and 1064nm,

In the case of a composite wavelength, it is characterized by providing a combined wavelength of 980nm and 1064nm, or providing a diode laser beam within a range of 300 to 1500nm, and providing an energy-changed output according to the duty ratio of each output. Is done.

In addition, the LCD monitor unit 280,

When the laser is output, the setting page information for the range of output and the setting page information for the pattern shape during treatment are displayed on the screen.

The pattern shape information is characterized by being programmed information.

At this time, the wavelength band of the output laser beam,

In the case of a wavelength of 1064 nm, by applying a black cream to the pain area, it is characterized in that the laser beam can penetrate deep into the skin during laser beam irradiation.

At this time, the high-intensity pain treatment laser device,

By outputting the laser beam output by using the X-axis galvano motor 130 and the Y-axis galvano motor 140 configured in the galvano scanner unit 180 in various angles and directions, pain along a programmed pattern shape It is characterized in that the treatment can be performed.

In addition, the main control means 200,

A galvano motor control control unit 240 for providing a control signal to the galvano scanner unit according to the control of the main control unit,

A laser energy setting unit 260 for storing the energy value for each pain-provided position provided by the main control unit as individual information, and providing the stored individual information to the main control unit,

Obtaining energy and treatment information for the number of each pain position from the laser energy setting unit, and setting and storing the laser beam size individually, and storing the stored individual information to the main control unit, the beam size setting unit 270,

When acquiring the size and location information of the pain area set through the LCD monitor unit 280, the acquired information is provided to the galvano motor control control unit 240, and the individual energy information for the location of pain is lasered. It is provided as an energy setting unit, and the main control unit 210 for obtaining an energy value and a laser beam size value set by the laser energy setting unit and the beam size setting unit and providing them to the composite wavelength laser unit 300,

LCD monitor unit 280 for displaying the size and location information of the pain area, the parameters for the pain treatment, the parameters and the treatment range information for the region, and displaying the respective short wavelength and complex wavelength information on the screen Characterized in that it comprises a.

In addition, the galvano scanner unit 180,

X-axis galvano motor 130,

The X-axis galvanometer mirror (130a) formed on the rotation axis of the X-axis galvano motor,

Y-axis galvano motor 140,

It comprises a Y-axis galvanometer (140a) formed on the rotation axis of the Y-axis galvano motor can set the pain irradiation area range, and irradiates pain according to the focus range area of the F-theta mirror unit 150 It is characterized by being able to determine the area range.

Hereinafter, it will be described in detail through an embodiment of a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece according to the present invention.

2 is an overall configuration diagram of a laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece according to an embodiment of the present invention.

As shown in Figure 2, the present inventor high-intensity pain treatment laser device largely includes a handpiece body 100, a galvano scanner unit 180, a main control means 200, a complex wavelength laser unit 300 It is configured by.

Specifically, the handpiece body 100 provides a laser beam provided from the composite wavelength laser unit 300 to the galvano scanner unit 180 formed therein, as shown in FIG. 1, which can be gripped by hand. It has a shape.

At this time, it has a range from irradiation range A to section B that can be obtained from the handpiece body, and transmits the laser power to the pain treatment site.

And, the section A to B can be adjusted by the operation of the galvano scanner unit 180, and is set according to the output range section of the galvano scanner unit 180.

In addition, the galvano scanner unit 180 sets the pain radiation area of the laser beam under the control of the galvano motor control unit.

In addition, the main control means 200 comprises a galvano motor control control unit 240 and an LCD monitor unit 280, the laser beam output from the composite wavelength laser unit 300 is a short wavelength or By obtaining the information in the case of a complex wavelength, the laser output information for each position is provided to the galvano motor control control unit to control the galvano scanner unit, and information set in the LCD monitor unit 280 is provided.

At this time, the composite wavelength laser unit 300 is to provide a laser beam to the galvano scanner unit 180 when obtaining a laser beam output signal by the main control means 200.

On the other hand, according to an additional aspect of the present invention, the high-intensity pain treatment laser device of the present invention,

The handpiece body is formed on the upper side to provide a laser beam to the galvano scanner portion formed on the lower side of the focus unit 160; further comprises a configuration.

That is, in order to provide the laser beam provided from the composite wavelength laser unit 300 to the galvano scanner unit formed on the lower side, it is formed on the upper side of the handpiece body.

On the other hand, according to another aspect of the present invention, the high-intensity pain treatment laser device of the present invention,

It is formed on the lower side of the galvano scanner unit, by adjusting the distance (C) with the F-theta mirror unit 150, a zoom focus unit 170 for adjusting the output laser beam size;

It may be configured to further include; F-theta mirror unit 150 formed on the lower side of the zoom focus unit 170 to provide a laser output range.

Specifically, the zoom focus unit 170 is formed under the galvano scanner unit, and by adjusting the distance C with the F-theta mirror unit 150, the output laser beam size is adjusted.

To this end, the F-theta mirror unit 150 is formed under the zoom focus unit 170, and the distance between the zoom focus unit 170 and the F-theta mirror unit 150, that is, the distance C ) To adjust the laser beam size.

In addition, the zoom focus unit 170 can set the size of the laser beam according to the specification and distance of the focal length of the zoom focus.

The size of the laser beam may be determined through the zoom focus unit, and the laser beam size may be adjusted in an area having a range C in FIG. 2.

In addition, the position of the zoom focus unit may be changed according to the designer, and a general technique includes a technique in which the beam size is changed through adjustment of the zoom focus unit.

On the other hand, the galvano scanner unit 180 of the present invention,

X-axis galvano motor 130,

The X-axis galvanometer mirror (130A) formed on the rotation axis of the X-axis galvano motor,

Y-axis galvano motor 140,

It is configured to include a Y-axis galvanometer 140A formed on the rotation axis of the Y-axis galvanomotor to set a pain irradiation area range, and irradiates pain according to the focus range area of the F-theta mirror unit 150 It is characterized by being able to determine the area range.

As described above, the pain irradiation area range can be set through the X-axis and Y-axis variations, and the pain irradiation area range can be determined according to the focus range area of the F-theta mirror unit 150.

For example, it is composed of an X-axis galvanometer motor 130A with an X-axis galvanometer mirror 130 and a Y-axis galvanometer motor 140 with a Y-axis galvanometer mirror 140A. It can be set, it is possible to determine the range according to the focus range area of the F-theta Mirror 150.

For example, if the F-theta Mirror has a range of 30 mm x 30 mm in the horizontal range of f=100 mm, the galvano motor control control unit can treat the pain with an area of 30 mm x 30 mm in width. .

3 is a control block diagram of a high intensity pain treatment laser apparatus using a complex wavelength and a programmed scan handpiece according to an embodiment of the present invention.

3, the main control means 200 is a main control unit 210, a galvano motor control control unit 240, a laser energy setting unit 260, a beam size setting unit 270, LCD It will be configured to include a monitor unit 280.

The galvano motor control control unit 240 provides a control signal to the galvano scanner unit according to the control of the main control unit.

For example, the main control unit quantifies the analysis values for the coordinate values of the grid array that analyze the location and size of the pain area, and receives the coordinate values (for the location) to secure the overall value for the pain area, The partial coordinate values for the entire value are stored for each location.

In addition, since it has information about the delay time, it is possible to control so that different treatments for each pain area can be performed in parallel.

As a result, the above information is transmitted to the galvano scanner unit.

On the other hand, if the motor unit formed in the galvano scanner unit fails or cannot process information about the operation value, the pain control may be stopped by sending error information about the feedback value to the main control unit.

Then, the laser energy setting unit 260 stores the energy value for each pain-provided position provided by the main control unit as individual information, and provides the stored individual information to the main control unit.

That is, all energy values for the location of the pain area are stored as individual information, and the stored information is provided back to the main control unit so that control can be performed.

In addition, the beam size setting unit 270 obtains energy and treatment information for the number of each pain position from the laser energy setting unit, sets and stores the laser beam size individually, and provides the stored individual information to the main control unit Will be.

In addition, the main control unit 210 is a configuration means for performing overall control, and specific control is as follows.

When acquiring the size and location information of the pain area set by the therapist through the LCD monitor unit 280, the acquired information is provided to the galvano motor control control unit 240.

For example, when acquiring the size and position information of the pain area set by the therapist through the LCD monitor unit 280, the position of the analysis value for the grid array coordinate values analyzing the size and position of the pain area is numerically located. The star information is provided to the galvano motor control control unit 240.

In addition, the individual energy value information for the location of each pain is provided to the laser energy setting unit, and the energy value and the laser beam size value set by the laser energy setting unit and the beam size setting unit are obtained to obtain a composite wavelength laser unit 300. Will be provided.

In addition, the LCD monitor unit 280 displays the size and location information of the pain area, and displays the parameters for the pain treatment, the parameters and the treatment range information for the region, and displays the respective short wavelength and complex wavelength information on the screen. Will be displayed.

At this time, when the size and position of the pain area are set in the LCD monitor unit 280, the main control unit 210 provides a control signal to the galvano motor control control unit 240 through the galvano scanner unit 180. The complex wavelength laser unit 300 irradiates the laser beam to the pain area.

Then, when all the setting information for the treatment and the correction information of the therapist are confirmed from the LCD monitor unit and the laser output decision is input from the therapist to the LCD monitor unit, the main control unit issues a laser final irradiation command to the complex wavelength laser unit 300 ).

On the other hand, the wavelength band of the laser beam provided by the composite wavelength laser unit 300 of the present invention,

However, in the case of a wavelength, it is characterized by being one of 980nm and 1064nm,

In the case of a composite wavelength, it is characterized in that a wavelength of 980 nm and 1064 nm is combined, or a diode laser beam within a range of 300 to 1500 nm is provided.

Therefore, when the therapist selects one of the short wavelengths of 980nm and 1064nm through the LCD monitor unit 280, the laser beam of the corresponding wavelength band is output.

In addition, when the therapist selects a composite wavelength through the LCD monitor unit 280, the wavelength of 980nm and 1064nm is combined, or the diode laser beam within the range of 300 to 1500nm is provided.

At this time, the composite wavelength laser unit 300 of the present invention is to provide an energy-changed output according to the duty ratio of each output.

Therefore, it is possible to provide an effect of increasing the effect of high-intensity pain treatment using a complex wavelength and widening the range of pain treatment by diversifying the penetration depth according to the wavelength.

Meanwhile, the LCD monitor unit 280,

When the laser is output, the setting page information for the range of output and the setting page information for the pattern shape during treatment are displayed on the screen.

The pattern shape information is characterized by being programmed information.

For example, as shown in FIG. 4, the setting page information for the pattern shape is output on the screen, and the setting page of the square pattern shape and the spiral pattern shape is provided, among which the therapist sets the square pattern shape Then, the control signal is provided to the main control unit 210 according to the programmed information.

On the other hand, the pattern shape means not only the square pattern shape and the spiral pattern shape suggested in the example of the present invention, but also means a pattern shape of various shapes such as a triangle, pentagon, hexagon, and rhombus, and that the pattern shape of various shapes can be programmed. This is obvious.

Further, preferably, the programmed information includes pain treatment position value, treatment time information, and repetition number information.

For example, (0,1), (1,1), (2,1), (3,1), (4,1), (4,0), (3,0) as position values for pain treatment. , (2,0), (1,0), (0,0), and the like, and treatment time information may mean 1 second for each location and 2 times of repetition information.

Therefore, according to the programmed information, the laser beam is emitted at a wavelength of 1064 nm for 1 second at the (0,1) position, the laser beam is emitted at a wavelength of 1064 nm for 1 second at the (1,1) position, at the position (2,1) Laser beam emission at 1064nm wavelength for 1 second, laser beam emission at 1064nm wavelength for 1 second at position (3,1), laser beam emission at 1064nm wavelength for 1 second at position (4,1), position (4,0) Laser beam emission at 980nm wavelength for 1 second at, Laser beam emission at 980nm wavelength for 1 second at (3,0) position, Laser beam at wavelength of 980nm and 1064nm combined for 1 second at (2,0) position At the (1,0) position, 980nm and 1064nm wavelengths are combined for 1 second, and the laser beam emission at the wavelength range of 1400nm is performed for 1 second at the (0,0) position.

Then, the above process is repeated once more.

As a result, providing the programed information as described above, it has the effect of providing a scan handpiece provided by a handling method that always gives the same treatment effect to the laser output.

In other words, there is a difference in the behavior of treatment using the general output handpiece of the existing laser therapist, and thus improves the problem of providing low reliability of treatment by providing different effects and different result values to the treatment result. Providing a scan handpiece programmed as a handling method to always give the same treatment effect to the output, it is possible to provide a uniform result value and high reliability of treatment, respectively.

On the other hand, the wavelength band of the output laser beam,

In the case of a wavelength of 1064 nm, by applying a black cream to the pain area, it is characterized in that the laser beam can penetrate deep into the skin during laser beam irradiation.

If the therapist selects a wavelength of 1064nm among the short wavelengths, the LCD monitor unit 280 may provide a guide message to apply the black cream, through which the therapist applies the black cream to the pain area. .

At this time, when a laser beam having a wavelength of 1064 nm is irradiated to the pain area, the laser beam penetrates deep into the skin.

In addition, when irradiating the wavelength of 1064nm among the wavelengths of the combination treatment laser to the pain area, by applying a black cream, a catalyst that can penetrate deeply into the laser, the pain area to be treated is marked so that the treatment target is visible. By performing the laser treatment on the black cream, it has the effect of effectively increasing the depth of laser penetration and treatment of the exact pain area.

After all, through the above-described configuration and operation, the laser beam output using the X-axis galvano motor 130 and the Y-axis galvano motor 140 configured in the galvano scanner unit 180 in various angles and directions. Reliability to provide the same treatment effect on the laser output regardless of the therapist's handling technique, regardless of the therapist's handling technique. Will be able to secure it.

In addition, although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. In addition, various modifications may be implemented by a person having ordinary knowledge in the art, and these modifications should not be individually understood from the technical idea or prospect of the present invention.

100: handpiece body
200: main control means
300: composite wavelength laser

Claims (6)

In the laser device for high-intensity pain treatment using a complex wavelength and a programmed scan handpiece,
A handpiece body 100 for providing a laser beam provided from the composite wavelength laser unit 300 to the galvano scanner unit 180 formed therein;
A galvano scanner unit 180 for setting a pain irradiation area range of the laser beam under the control of the galvano motor control control unit;
It consists of a galvano motor control control unit 240 and an LCD monitor unit 280, and obtains information when the laser beam output from the composite wavelength laser unit 300 is a short wavelength or a complex wavelength. A main control means 200 for controlling the galvano scanner unit by providing laser output information for each position to the no-motor control control unit;
When the laser beam output signal is obtained from the main control means 200, a complex wavelength laser unit 300 for providing a laser beam to the galvano scanner unit 180; High-intensity pain treatment laser device using a scan handpiece.
According to claim 1,
High-strength using a composite wavelength and a programmed scan handpiece, further comprising; a zoom focus unit 170 for adjusting the size of the laser beam that is formed and output on the lower side of the galvano scanner unit 180. Laser device for pain treatment.
The method according to claim 1 or 2,
The wavelength band of the laser beam,
However, in the case of a wavelength, it is characterized by being one of 980nm and 1064nm,
In the case of a composite wavelength, it is characterized by providing a combined wavelength of 980nm and 1064nm, or providing a diode laser beam within a range of 300 to 1500nm, and providing an energy-changed output according to the duty ratio of each output. High-intensity pain treatment laser device using complex wavelength and programmed scan handpiece.
The method according to claim 1 or 2,
The LCD monitor unit 280,
When the laser is output, the setting page information for the range of output and the setting page information for the pattern shape during treatment are displayed on the screen.
The pattern shape information is a high-intensity pain treatment laser device using a complex wavelength and a programmed scan handpiece, characterized in that it is programmed information.
The method according to claim 1 or 2,
The wavelength band of the output laser beam,
For high-intensity pain treatment using a complex wavelength and a programmed scan handpiece, characterized in that by applying a black cream to the pain area in the case of a wavelength of 1064 nm, the laser beam can penetrate deep into the skin during laser beam irradiation. Laser device.
The method according to claim 1 or 2,
The high-intensity pain treatment laser device,
By outputting the laser beam output by using the X-axis galvano motor 130 and the Y-axis galvano motor 140 configured in the galvano scanner unit 180 in various angles and directions, pain along a programmed pattern shape High-intensity pain treatment laser device using a complex wavelength and a programmed scan handpiece, characterized in that the treatment can be performed.

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