KR102190881B1 - 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 composite wavelength and a programmed scan handpiece, and more particularly, to increase the effect of high-intensity pain treatment by using a composite wavelength, and by diversifying the penetration depth according to the wavelength. A laser device for high-intensity pain treatment using a multi-wavelength and programmed scan handpiece that provides the effect of widening the pain treatment range and provides a programmed scan handpiece with a handling method that always gives the same treatment effect on the 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 composite wavelength and a programmed scan handpiece, and more particularly, to increase the effect of high-intensity pain treatment by using a composite wavelength, and by diversifying the penetration depth according to the wavelength. A laser device for high-intensity pain treatment using a multi-wavelength and programmed scan handpiece that provides the effect of widening the pain treatment range and provides a programmed scan handpiece with a handling method that always gives the same treatment effect on the 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 degree of detection and progression of a disease is grasped by measuring changes in chemical composition, color change, shape displacement, and tissue hardness displacement of tissues in the body using the coherence characteristics of lasers. Laser procedures are being applied considerably for incisions, destruction of cancerous tissues, and hemostasis.

In addition, like laser treatment, recently known as LLTT (Low Level Laer Treatment), by using low-energy laser light to stimulate the human body's pulse or skin like moxibustion, it removes skin or muscle pain or Methods to promote cure are being practiced.

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

Low-power lasers such as 650 nm band helium-neon (He-Ne) lasers significantly increase blood vessel dilation and new blood vessels through biostimulation effects to prevent muscle degeneration, and reduce edema by regulating the osmotic pressure of blood vessels and tissues. And has the effect of suppressing pain.

The conventional medical laser device has a simple function of irradiating the affected area according to a simple frequency generation, and has a disadvantage in that the use effect is insignificant and the use is inconvenient due to weak penetration power.

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 by relying on a short wavelength to achieve excellent effects, and most rely on mechanical processing.

As shown in Figure 1, the conventional technology is effective by transmitting any one of 1064nm and 980nm wavelength band, the transmission handpiece is manufactured in a form that can be adjusted to a size of 10 ~ 30mm diameter, the therapist directly The patient is being treated for an appropriate amount of time.

During treatment, the laser output should not stay in one place.

The reason is that if it stays there, the laser is highly damaged by heat in the epidermal layer of the skin, and the epidermis is burned.

Therefore, the therapist continuously moves the pain area and the surrounding area to perform the procedure.

Accordingly, a dedicated therapist is essential, and clinical results are inevitably different depending on the therapist's handling technique.

In the end, in the present invention, in order to solve the above problems, the form of the output that combines the wavelength of 1064nm and the wavelength of 980nm, which is effective for pain, is determined, and the handling of the output is also to provide a technology that can be uniformly programmed to treat the pain area. do.

(Prior literature) Korean Patent Publication No. 10-2010-0092077

Therefore, the present invention has been proposed in consideration 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 depth of penetration according to the wavelength to treat pain I want to widen it.

A second object of the present invention is to provide a scanning handpiece programmed with a handling method that always gives the same treatment effect on laser output.

A third object of the present invention is to mark the pain area to be treated by applying a black cream, which is a catalyst that allows the laser to penetrate deeply when laser irradiation, to the pain area at a wavelength of 1064 nm among the wavelengths of the laser for complex therapy. It is intended to be able to effectively increase the depth of laser penetration and treatment of the exact pain area by performing laser treatment on the black cream.

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 complex 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 according to the control of the galvano motor control unit;

It is composed of a galvano motor control unit 240 and an LCD monitor unit 280, and obtains information on the case where the laser beam output from the complex wavelength laser unit 300 is a short wavelength or a complex wavelength. A main control means 200 for providing position-specific laser output information to the furnace motor control unit to control the galvano scanner unit and providing information set to the LCD monitor unit 280;

And a combined wavelength laser unit 300 for providing a laser beam to the galvano scanner unit 180 when the laser beam output signal is obtained by the main control unit 200.

Through the laser device for high-intensity pain treatment using the composite wavelength and 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 composite wavelength, and the penetration depth is varied according to the wavelength. It has an effect that can broaden the range of pain treatment.

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

That is, since the treatment behavior using the conventional laser therapist's general output handpiece is different for each individual, different effects and different result values are provided 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, respectively, by providing a scan handpiece programmed with a handling method for giving the same treatment effect on output at all times.

In addition, by applying a black cream, which is a catalyst that allows the laser to penetrate deeply when laser irradiated to the pain area at a wavelength of 1064 nm among the wavelengths of the laser for complex treatment, the pain area to be treated is marked so that the target of the treatment can be seen. , By performing laser treatment on the black cream, it has the effect of accurately treating the pain area and effectively increasing the laser penetration depth.

1 is a state diagram of a general pain treatment laser device used.
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 laser device for high intensity pain treatment 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 content merely illustrates the principles of the present invention. Therefore, a person skilled in the art can implement the principles of the present invention and invent various devices included in the concept and scope of the present invention, although not clearly described or illustrated herein.

In addition, all conditional terms and examples listed in this specification are, in principle, intended to be clearly intended only for the purpose of making the concept of the present invention understood, and should be understood as not limiting to the embodiments and states specifically listed as described above. do.

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

That is, 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 complex 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 according to the control of the galvano motor control unit;

It is composed of a galvano motor control unit 240 and an LCD monitor unit 280, and obtains information on the case where the laser beam output from the complex wavelength laser unit 300 is a short wavelength or a complex wavelength. A main control means 200 for providing position-specific laser output information to the furnace motor control unit to control the galvano scanner unit and providing information set to the LCD monitor unit 280;

And a combined wavelength laser unit 300 for providing a laser beam to the galvano scanner unit 180 when the laser beam output signal is obtained by the main control means 200.

In this case, a zoom focus unit 170 formed below the galvano scanner unit 180 and configured to adjust a size of a laser beam outputted from the galvano scanner unit 180 is further included.

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 complex wavelength laser unit 300 to the galvano scanner unit 180 formed therein;

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

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

A zoom focus unit 170 formed under the galvano scanner unit and configured to adjust a size of an output laser beam by adjusting a distance C with the F-theta mirror unit 150;

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

Consisting of a galvano motor control unit 240, the laser beam output from the multi-wavelength laser unit 300 acquires information on a single wavelength or a complex wavelength and is positioned in the galvano motor control unit A main control means 200 for providing individual laser output information to control the galvano scanner unit and providing information set to the LCD monitor unit 280;

And a combined wavelength laser unit 300 for providing a laser beam to the galvano scanner unit 180 when the laser beam output signal is obtained by the main control means 200.

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

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

In the case of a complex wavelength, a combined wavelength of 980 nm and 1064 nm is provided, or a diode laser beam within the range of 300 to 1500 nm is provided, but the energy changed according to the duty ratio of each output is provided. To do.

In addition, the LCD monitor unit 280,

During laser output, the setting page information for the output range and the setting page information for the pattern shape are displayed on the screen.

The pattern shape information is programmed information.

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

In the case of a wavelength of 1064 nm, a black cream is applied to the pain area, so that the laser beam can penetrate deeply into the skin when the laser beam is irradiated.

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

By using the X-axis galvano motor 130 and the Y-axis galvano motor 140 configured in the galvano scanner unit 180 to output laser beams at various angles and directions, pain according to the 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 position provided by the main control unit as individual information, but providing the stored individual information to the main control unit,

A beam size setting unit 270 for obtaining energy and treatment information for each pain location from the laser energy setting unit, setting and storing the laser beam size individually, and providing the stored individual information to the main control unit,

When acquiring the size and location information of the pain area set through the LCD monitor unit 280, the information acquired by the galvano motor control unit 240 is provided, and the energy value for each pain location is laser A main control unit 210 provided as an energy setting unit, 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 it to the complex wavelength laser unit 300,

LCD monitor unit 280 for displaying information on the size and location of the pain area, displaying parameters for pain treatment, parameters for the area, and treatment range information, and displaying information on each short wavelength and complex wavelength on the screen It characterized in that it is configured to include.

In addition, the galvano scanner unit 180,

X-axis galvano motor 130,

An X-axis galvano 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 galvano mirror 140a formed on the rotation axis of the Y-axis galvano motor to set a pain irradiation area range, and pain irradiation according to the focus range area of the F-theta mirror unit 150 It is characterized in that the area range can be determined.

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 inventors of the laser device for high-intensity pain treatment largely includes a handpiece main body 100, a galvano scanner unit 180, a main control means 200, a complex wavelength laser unit 300 It is composed by

Specifically, the handpiece body 100 provides the laser beam provided from the complex wavelength laser unit 300 to the galvano scanner unit 180 formed therein, and as shown in FIG. 1, the handpiece body 100 It has a shape.

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

Further, 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 a pain irradiation area range of the laser beam according to the control of the galvano motor control unit.

In addition, the main control means 200 includes a galvano motor control control unit 240 and an LCD monitor unit 280, when the laser beam output from the complex wavelength laser unit 300 is a short wavelength or In the case of the 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.

In this case, the composite wavelength laser unit 300 provides the laser beam to the galvano scanner unit 180 when acquiring the laser beam output signal by the main control means 200.

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

The handpiece body is formed on the upper side of the focus unit 160 for providing the laser beam to the galvano scanner unit formed on the lower side; is configured to further include.

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

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

A zoom focus unit 170 formed under the galvano scanner unit and configured to adjust a size of an output laser beam by adjusting a distance C with the F-theta mirror unit 150;

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

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

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, a distance (C ), to adjust the laser beam size.

In addition, the zoom focus unit 170 may 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 can be determined through the zoom focus unit, and the size of the laser beam can be adjusted in a region having a range C of FIG. 2.

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

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

X-axis galvano motor 130,

An X-axis galvano 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 galvano mirror 140A formed on the rotation axis of the Y-axis galvano motor to set a pain irradiation area range, and to irradiate pain according to the focus range area of the F-theta mirror unit 150 It is characterized in that the area range can be determined.

As described above, the range of the pain irradiation area can be set through fluctuations in the X-axis and the Y-axis, 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 galvano motor 130 with an X-axis galvano mirror (130A) and a Y-axis galvano motor 140 with a Y-axis galvano mirror (140A), which is a two-dimensional range. May be set, and a range according to the focus range area of the F-theta Mirror 150 may be determined.

For example, if F-theta Mirror has a range of 30mm wide x 30mm long with f=100mm, you can treat with a pain irradiation area as much as 30mm wide x 30mm long in the galvano motor control unit. .

3 is a control block 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 Fig. 3, the main control means 200 includes a main control unit 210, a galvano motor control control unit 240, a laser energy setting unit 260, a beam size setting unit 270, an LCD It is 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 value for the grid array coordinate value that analyzes the location and size of the pain area, receives it as the corresponding coordinate value (for the location), and secures the total value for the pain area, Partial coordinate values for the entire value are stored for each location.

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

Eventually, the information is transmitted to the galvano scanner unit.

On the other hand, when the motor unit formed in the galvano scanner unit fails or fails to process information on the operation value, error information on the feedback value is sent to the main control unit to stop pain treatment.

Further, the laser energy setting unit 260 stores energy values for each pain position provided from 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 location 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. It becomes.

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

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

For example, when acquiring the size and location information of the pain area set by the therapist through the LCD monitor unit 280, the analysis value for the grid array coordinate value analyzed by analyzing the size and location of the pain area, etc. Star information is provided to the galvano motor control control unit 240.

In addition, the laser energy setting unit provides individual information on the energy value for each pain position, and obtains the energy value and the laser beam size value set by the laser energy setting unit and the beam size setting unit, and the composite wavelength laser unit 300 Will be provided as.

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

At this time, when the size and position of the pain area is 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 a laser beam onto the pain area.

In addition, when all setting information for treatment and correction information of the therapist are confirmed from the LCD monitor, and the laser output determination is input to the LCD monitor from the therapist, the main control unit sends the final laser irradiation command to the composite 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 in that it is any one of 980 nm and 1064 nm,

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

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

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

In this case, the composite wavelength laser unit 300 of the present invention provides 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 by using a complex wavelength and widening the range of pain treatment by varying the penetration depth according to the wavelength.

On the other hand, the LCD monitor unit 280,

During laser output, the setting page information for the output range and the setting page information for the pattern shape are displayed on the screen.

The pattern shape information is 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. If so, a control signal is provided to the main control unit 210 according to the programmed information.

On the other hand, the pattern shape means a pattern shape of various shapes, such as a triangle, a pentagon, a hexagon, a rhombus, as well as a square pattern shape and a spiral pattern shape suggested in the example of the present invention, and the pattern shape of various shapes can be programmed. It is self-evident.

In addition, preferably, the programmed information includes pain treatment location value, treatment time information, and repetition number information.

For example, as pain treatment location values (0,1), (1,1), (2,1), (3,1), (4,1), (4,0), (3,0) , (2,0), (1,0), (0,0), etc., and treatment time information may mean 1 second for each location, and repetition number information may mean 2 repetitions.

Therefore, according to the programmed information, laser beam emission of 1064 nm wavelength band for 1 second at (0,1) position, laser beam emission of 1064 nm wavelength band for 1 second at (1,1) position, and (2,1) position Laser beam emission of 1064 nm wavelength band for 1 second, laser beam emission of 1064 nm wavelength band for 1 second at (3,1) position, laser beam emission of 1064 nm wavelength band for 1 second at (4,1) position, (4,0) position Laser beam emission of 980 nm wavelength band for 1 second at (3,0) position, laser beam emission of 980 nm wavelength band for 1 second at (2,0) position, laser beam of wavelength band combined with wavelengths of 980 nm and 1064 nm for 1 second The emission, laser beam emission in the wavelength band combined with wavelengths of 980nm and 1064nm for 1 second at the (1,0) position, and diode laser beam emission in the 1400nm wavelength band for 1 second at the (0,0) position.

After that, the process is repeated once more.

Consequently, providing the programmed information as described above has the effect of providing a scan handpiece that is provided by a handling method that always gives the same treatment effect to the laser output.

In other words, since the treatment behavior using the conventional laser therapist's general output handpiece is different for each individual, different effects and different result values are provided on the treatment result to improve the problem of providing low reliability of treatment. By providing a scan handpiece programmed with a handling method to always give the same treatment effect on the output, it is possible to provide a uniform result value and high reliability of treatment for each treatment result.

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

In the case of a wavelength of 1064 nm, a black cream is applied to the pain area, so that the laser beam can penetrate deeply into the skin when the laser beam is irradiated.

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 of 1064 nm wavelength is irradiated onto the pain area, the laser beam penetrates deep into the skin.

In addition, when irradiating a wavelength of 1064 nm among the wavelengths of the laser for complex treatment to the pain area, a black cream, which is a catalyst that allows the laser to penetrate deeply, is applied to mark the area to be treated so that the target of the treatment can be seen. By performing laser treatment on the black cream, it has the effect of accurately treating the pain area and effectively increasing the depth of laser penetration.

In the end, through the above 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 is diverted to various angles and directions. Reliability that can always provide the same treatment effect with respect to laser output regardless of the treatment technique of the therapist, regardless of the treatment technique of the therapist. It will be possible to secure.

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 belongs without departing from the gist of the present invention claimed in the claims. In addition, various modifications can be implemented by those of ordinary skill in the art, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

100: handpiece body
200: main control means
300: complex wavelength laser unit

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 complex wavelength laser unit 300 to the galvano scanner unit 180 formed therein;
A focus unit 160 formed on the upper side of the handpiece body to provide the laser beam to the galvano scanner unit formed at the lower side;
A galvano scanner unit 180 for setting a pain irradiation area range of the laser beam according to the control of the galvano motor control unit;
A zoom focus unit 170 formed under the galvano scanner 180 unit and configured to adjust the output laser beam size by adjusting the distance C to the F-theta mirror unit 150;
An F-theta mirror unit 150 formed under the zoom focus unit 170 to provide a laser output range;
It is composed of a galvano motor control unit 240 and an LCD monitor unit 280, and obtains information on the case where the laser beam output from the complex 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 furnace control control unit;
A complex wavelength laser unit 300 for providing a laser beam to the galvano scanner unit 180 when acquiring a laser beam output signal from the main control means 200; Laser device for high-intensity pain treatment using a scanning handpiece.
delete The method of claim 1,
The wavelength band of the laser beam is,
However, in the case of a wavelength, it is characterized in that it is any one of 980 nm and 1064 nm,
In the case of a complex wavelength, a combined wavelength of 980 nm and 1064 nm is provided, or a diode laser beam within the range of 300 to 1500 nm is provided, but the energy changed according to the duty ratio of each output is provided. Laser device for high-intensity pain treatment using complex wavelength and programmed scan handpiece.
The method of claim 1,
The LCD monitor unit 280,
During laser output, the setting page information for the output range and the setting page information for the pattern shape are displayed on the screen.
The pattern shape information is a laser device for high intensity pain treatment using a complex wavelength and a programmed scan handpiece, characterized in that the programmed information.
The method of claim 1,
The wavelength band of the output laser beam,
For high-intensity pain treatment using a complex wavelength and programmed scan handpiece, characterized in that the laser beam penetrates deep into the skin when the laser beam is irradiated by applying a black cream to the pain area in the case of a wavelength of 1064 nm. Laser device.
The method of claim 1,
The laser device for high intensity pain treatment,
By using the X-axis galvano motor 130 and the Y-axis galvano motor 140 configured in the galvano scanner unit 180 to output laser beams at various angles and directions, pain according to the programmed pattern shape A laser device for high-intensity pain treatment using a multi-wavelength and programmed scan handpiece, which enables treatment to be performed.

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