KR101668235B1 - Erbium YAG laser replaces articulated arm-type optical fiber device - Google Patents

Abstract

The present invention relates to a joint arm replacing-type optical fiber transferring device of medical erbium yag laser and, more specifically, to a joint arm replacing-type optical fiber transferring device of medical erbium yag laser which minimizes energy loss in comparison with a conventionally applied joint arm by replacing a joint arm outputting a 2940nm band.

Description

[0001] The present invention relates to an Erbium YAG laser replica articulated arm-type optical fiber device,

[0001] The present invention relates to an optical fiber transmission apparatus for replacing an articulated arm fiber of an erbium-YAG laser for medical use, and more particularly, to an optical fiber transmission apparatus for replacing an articulated arm that outputs a 2940nm band with an optical fiber, And to an optical fiber transmission device for replacing a joint of a medical Er-YAG laser.

The laser has a single wavelength, one color (monochromaticity) depending on the raw material generating the energy, and the light does not spread all the way and has a certain direction (collimation), and the phase and wavelength are temporally and spatially identical ) Characteristics.

In addition, when the energy is concentrated on the site to be treated by showing a strong brigthness temporarily and acts on a tissue composed of water, the tissue evaporates and disappears instantly while moisture is evaporated, and this principle can be used for skin treatment.

In addition, lasers can cut tissues instead of surgical knives and evaporate tissue to eliminate lesions.

The advantage of laser surgery is that it can be operated without hemorrhage, can eliminate skin diseases, improve cosmetics, and even treat fine parts.

It is also better than the general treatment that the inflammation reaction after the procedure is low, the pain is low, the scar remains small, the hospital stay is short or not necessary.

In dermatology, lasers are used extensively to remove hair, wrinkles, scars, dots, black spots, etc. In other medical subjects, lasers are used in otolaryngology, ophthalmology, and surgery.

The basic structure of an erbium-based laser consists of a power source, a medium, an optical resonator, and a transmission device.

Depending on the equipment, the light source for pumping uses a flash lamp or laser diode to pump the erbium laser to generate the laser.

When energy is transferred to the medium contained in the optical resonator, the atoms in the safe state are changed into an excited state and amplified in the optical resonator to emit laser light. At this time, the laser is named according to the kind of the medium, Because a solid medium is used, it is called an erbium-yag laser.

The Erbium-YAG laser uses a Yttrium-Aluminum-Garnet composite crystal coated with an erbium (Er) element as a medium to generate an invisible laser beam in the near-infrared region having a wavelength of 2,940 nm.

The Erbium-YAG laser absorbs about 96% of the water into the water and only about 4% of the water because it absorbs about 10 times as much water as the CO ₂ laser.

Compared to CO ₂ lasers with a vaporization threshold of 4.5 to 5 J / cm ² , which is the minimum energy density for vaporizing the skin, Er-YAG lasers have a relatively low energy density of 0.5 to 1.5 J / cm ² The skin can be vaporized.

J / cm ² and per tissue is about 2 ~ 4㎛ evaporation, it is peeled off the skin 20 ~ 25㎛ to pass (pass) of a time.

Because of these properties, less thermal damage to surrounding tissues than CO ₂ lasers, less pain during the procedure, and less erythema.

The CO ₂ laser is a part where the tissue is evaporated and disappears and the coagulated part is generated in the irradiated part. In the case of the erbium-magenta laser, less heat is transferred to the laser irradiation site than the CO ₂ laser,

Currently, companies developing laser therapy devices that dominate the domestic market are developing high peak energy.

The reason for this is to infiltrate energy into skin lesions using wide spots to penetrate deep into the skin and treat them by laser penetration.

However, there are not so many treatment lesions that require large energy in the treatment of erbium-lasers.

Most of the lesions are treated with 300 mJ and only about 1 to 4 mm of spot is used.

However, there is a need to solve the problem of price by developing the existing expensive products as target lesions by lowering the maximum peak energy.

1 is a cross-sectional view showing a structure of a conventional articulated arm and its drawbacks.

As shown in FIG. 1, the laser beam transmission path of the conventional articulated arm is 1-> 2-> 3-> 4-> 5-> 6-> 7, energy loss occurs in each section, Is about 15 ~ 30%.

In addition, mirror damage was inevitable in each section.

More specifically, conventional products have a maximum peak output energy of about 1.5J and an external ARM output stage of about 1.2J.

The reason for this phenomenon is that an energy loss of about 0.3 J (300 mJ, about 30% of total energy) is generated due to interference during movement of the laser through the reflector and lens.

However, if the actual maximum peak energy is 500 mJ, warts, scars and wrinkles can be treated sufficiently.

Wounds, scars, wrinkles, etc., can be treated by laser irradiation, so the maximum peak energy of 1.2J is not necessary.

Accordingly, in the present invention, by replacing the articulated arm that outputs the 2940 nm band with an optical fiber, it is possible to minimize the energy loss compared to the conventionally applied articular arm, It is.

(Prior art) Korea Patent No. 10-1494683

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above-mentioned problems occurring in the prior art, and it is a first object of the present invention to provide an optical fiber which can reduce the energy loss To be minimized.

A second object of the present invention is to minimize the parts of the main body of the apparatus, to significantly reduce the manufacturing cost, and to reduce the weight of the main body.

In order to accomplish the object of the present invention, there is provided an optical fiber transmission device for substituting an articulated arm of an erbium-

An optical fiber aligning mount 200 coupled to an end of an optical fiber input unit 150 receiving a laser beam of 2940 nm band generated from the Erbium Nad Laser resonator 100 and including a focus lens 210 therein;

An optical fiber input section bracket 300 having one side coupled to the optical fiber array mount and the other side coupled to a 2940 nm backlight fiber input;

A 2940 nm opaque fiber input unit 400 formed of a fluoride glass fiber material for outputting a 2940 nm band, one side connected to an optical fiber input unit bracket and the other side connected to an optical fiber;

An optical fiber 500 having one side coupled to the 2940 nm backlight fiber input unit and the other side coupled to a 2940 nm backlight fiber output unit;

And a 2940 nm opponent fiber output unit 600 coupled to the tip of the optical fiber and coupled to the handpiece treatment tip 700 on the other side.

By replacing the articulated arm that outputs the 2940 nm band with an optical fiber through the optical fiber replacement device of the articulated arm replacement type of erbium laser according to the present invention having the above-described constitution and function, The effect of minimizing the loss is exhibited.

In addition, since the parts of the main body of the apparatus can be minimized, the manufacturing cost can be significantly lowered, and the weight can be reduced, so that it is possible to provide a simplicity of carrying.

1 is a cross-sectional view showing a structure of a conventional articulated arm and its drawbacks.
FIG. 2 is an overall configuration diagram of an articulated fiber optical fiber transmission device of a medical Er-YAG laser according to an embodiment of the present invention.
FIG. 3 is a view illustrating an optical fiber transmission device for replacing an articulated arm of a medical Er-YAG laser according to an embodiment of the present invention with a treatment tip for a handpiece.
FIG. 4 illustrates an optical fiber input unit formed on one side of an erbium-maggot laser resonator of an optical fiber replacement apparatus of the articulated-arm type of Erbium YAG laser according to an exemplary embodiment of the present invention. The optical fiber input unit includes a fiber- Fig.
FIG. 5 is a view illustrating a comparison between a defocus aligning method provided through an optical fiber replacement device of the articulated arm type of Erbium YAG laser according to an embodiment of the present invention and a conventional general focus alignment method.
FIG. 6 is an optical fiber alignment mount of an optical fiber replacement device of an articulated arm type of medical Er-YAG laser according to an embodiment of the present invention, and FIG. 7 is a perspective view.

The following merely illustrates the principles of the invention. Therefore, those skilled in the art will be able to devise various apparatuses which, although not explicitly described or illustrated herein, embody the principles of the invention and are included in the concept and scope of the invention.

Furthermore, all of the conditional terms and embodiments listed herein are, in principle, only intended for the purpose of enabling understanding of the concepts of the present invention, and are not to be construed as limited to such specifically recited embodiments and conditions do.

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

The present invention provides a fiber-to-the-lens substitution type optical fiber transmission device for a medical Er-YAG laser,

An optical fiber aligning mount 200 coupled to an end of an optical fiber input unit 150 receiving a laser beam of 2940 nm band generated from the Erbium Nad Laser resonator 100 and including a focus lens 210 therein;

An optical fiber input section bracket 300 having one side coupled to the optical fiber array mount and the other side coupled to a 2940 nm backlight fiber input;

A 2940 nm opaque fiber input unit 400 formed of a fluoride glass fiber material for outputting a 2940 nm band, one side connected to an optical fiber input unit bracket and the other side connected to an optical fiber;

An optical fiber 500 having one side coupled to the 2940 nm backlight fiber input unit and the other side coupled to a 2940 nm backlight fiber output unit;

And a 2940 nm counterbore fiber output unit 600 coupled to an end of the optical fiber and coupled to the treatment tip 700 for handpiece.

In addition, the optical fiber alignment mount 200 includes:

A Y-axis adjuster 200a is formed at an upper end thereof, an X-axis adjuster 200b is formed at one side of the center hole, Axis adjuster body 10 including a Y-axis adjuster body 15 for moving the Z-axis mount 40 up and down when the Y-axis adjuster 200a is vertically adjusted,

An XY-axis guide bracket 20 installed between the X-axis guide mount 30 and the XY-axis adjuster body 10 and moved in the X-axis and Y-axis,

The X-axis guide mount 30 is formed on the front surface of the guide bracket 20 and has a central hole formed at a central portion thereof to be inserted into one side of the Z-axis mount 40,

Axis guiding mount 30 and the X-axis guide bracket 20 and the X-axis guide mount 30 are housed in the X-axis guide mount 30. The rear surface of the guide bracket 20 is coupled to the front surface of the XY- A first stationary mount 50,

An end mount 60 having a central hole formed at a central portion thereof and coupled to a front surface of the first fixing mount 50,

A Z axis mount 40 having one side screwed to the Z axis adjuster 200c and the other side inserted into the center hole of the ending mount,

And a cylindrical Z-axis adjuster 200c including a focus lens 210 therein and having the Z-axis mount screwed on one side thereof,

And adjusts the distance of the focus lens through the Z axis adjuster 200c and adjusts the distance of the laser beam to the center position of the horizontal axis and the vertical axis of the end face of the optical fiber through the X axis adjuster 200b and the Y axis adjuster 200a Is adjusted.

Further, in the optical fiber input section bracket 300,

It is possible to set the focusing distance of the focus lens within the range of 0.1 mm to 10 mm without focusing on the end face of the optical fiber when the 2940 nm counterweight optical fiber input unit 400 is coupled, So that damage to the end face of the optical fiber due to the passage of time can be prevented.

Hereinafter, a detailed description will be given of embodiments of an optical fiber replacement device of the articulated arm type of Erbium YAG laser according to the present invention.

FIG. 2 is an overall configuration diagram of an articulated fiber optical fiber transmission device of a medical Er-YAG laser according to an embodiment of the present invention.

As shown in FIG. 2, the optical fiber replacement device of the Er-YAG laser of the present invention includes an optical fiber alignment mount 200, an optical fiber input section bracket 300, a 2940 nm broadband fiber input section (400), an optical fiber (500), and a 2940 nm banding fiber output unit (600).

In the present invention, by using an optical fiber, loss of energy can be reduced to a maximum as compared with a joint arm that has been used in the past.

The optical fiber should preferably be configured such that light passing through the center glass is totally reflected by using a glass having a high refractive index at the center and a glass having a low refractive index at the outer portion.

This is to minimize the energy loss rate.

The optical fiber aligning mount 200 is coupled to an end of an optical fiber input unit 150 receiving a laser beam of 2940 nm band generated from the Erbium YAG laser resonator 100 and includes a focus lens 210 therein .

4, the optical fiber input unit 150 is formed on one side of the Er-YAG laser resonator 100. At this time, the laser beam of 2940 nm band generated from the Er-YAG laser resonator is incident on the optical fiber input unit 150, And is focused through a focus lens formed on an optical fiber alignment mount coupled to the end of the optical fiber array.

Next, referring to FIG. 5, the general focus alignment method and the defocus direction method of the present invention will be compared.

The defocus aligning method described in the present invention is a name defining a method for preventing damage to the optical fiber.

5 is a view showing a general focus alignment method, and a right side view of FIG. 5 is a view showing a defocus aligning method according to the present invention.

A 'shown in the optical fiber input unit bracket 300 of FIG. 5 represents a cross section of the optical fiber, and focuses or defocuses the laser beam output from the Erbium YAG laser resonator through the focus lens to the A point, which is an end face of the optical fiber.

In the case of the general focus alignment method, the laser beam is transmitted without loss by minimizing the laser beam to the diameter of the end face of the optical fiber by maximally focusing the beam to the end of the optical fiber.

In the above-described method, the output of the laser is not a problem in the low-power system. However, when the output power of 0.5 W or more is used, the peak of the peak power at which the end face of the optical fiber is damaged There has been a serious problem that the reliability of the equipment is seriously deteriorated.

If the end face of the optical fiber is damaged, the energy of the output stage that can be used by the user is lost and the energy output from the Erbium YAG laser resonator can not be transmitted.

On the other hand, if the defocus-angle method of the present invention is used, an appropriate distance among the distances within the range of the focusing distance of 0.1 mm to 10 mm is set without focusing on the end face of the optical fiber, To the optical fiber.

At this time, since the laser beam is not focused on the end face of the optical fiber, the energy output from the Erbium-YAG laser resonator is as large as the area of the difference between the defocus distance diameter and the optical fiber cross-section distance. However, It does not affect the amount of transmission.

By setting as described above, the end face of the optical fiber is damaged during the alignment and the end face of the optical fiber is not damaged due to the lapse of time.

Thus, the reliability of the entire equipment can be improved, and the loss of process production (LOSS) can also be reduced.

The optical fiber alignment mount (200)

An X-axis adjuster 200b, a Y-axis adjuster 200a, and a Z-axis adjuster 200c so as to be adjustable in X-axis, Y-axis, and Z-

And adjusts the distance of the focus lens through the Z axis adjuster 200c and adjusts the distance of the laser beam to the center position of the horizontal axis and the vertical axis of the end face of the optical fiber through the X axis adjuster 200b and the Y axis adjuster 200a Is adjusted.

To be more specific, the optical fiber alignment mount 200 may be configured such that,

A Y-axis adjuster 200a is formed at an upper end thereof, an X-axis adjuster 200b is formed at one side of the center hole, Axis adjuster body 10 including a Y-axis adjuster body 15 for moving the Z-axis mount 40 up and down when the Y-axis adjuster 200a is vertically adjusted,

An XY-axis guide bracket 20 installed between the X-axis guide mount 30 and the XY-axis adjuster body 10 and moved in the X-axis and Y-axis,

The X-axis guide mount 30 is formed on the front surface of the guide bracket 20 and has a central hole formed at a central portion thereof to be inserted into one side of the Z-axis mount 40,

Axis guiding mount 30 and the X-axis guide bracket 20 and the X-axis guide mount 30 are housed in the X-axis guide mount 30. The rear surface of the guide bracket 20 is coupled to the front surface of the XY- A first stationary mount 50,

An end mount 60 having a central hole formed at a central portion thereof and coupled to a front surface of the first fixing mount 50,

A Z axis mount 40 having one side screwed to the Z axis adjuster 200c and the other side inserted into the center hole of the ending mount,

And a cylindrical Z-axis adjuster 200c including a focus lens 210 therein and having the Z-axis mount screwed on one side thereof,

And adjusts the distance of the focus lens through the Z axis adjuster 200c and adjusts the distance of the laser beam to the center position of the horizontal axis and the vertical axis of the end face of the optical fiber through the X axis adjuster 200b and the Y axis adjuster 200a Is adjusted.

The X-axis adjuster body 10 has a central hole formed at a central portion thereof to be inserted into one side of the Z-axis mount 40, a Y-axis adjuster 200a formed at an upper end thereof, , As shown in Figs. 6 to 7, the X-axis adjuster 200b is formed on the side surface.

The Y axis adjuster 200a includes a Y axis guide line portion 15 for moving the Z axis mount 40 upward and downward when the Y axis adjuster 200a is vertically adjusted.

In addition, the XY-axis adjuster body 10 is formed by, for example, a bolt-screw-shaped X-axis adjuster 200b having a pitch of 0.35 mm and a Y-axis adjuster 200a The Z-axis mount 40 including the focus lens and the function of the mount which is fixed so as to be adjustable and the Y-axis guide line portion can be moved up and down along the guide line by adjusting the Y-axis adjuster 200a .

The XY-axis guide bracket 20 is installed between the X-axis guide mount 30 and the XY-axis adjuster body 10 and is configured to move in the X-axis and the Y-axis.

That is, the guide bracket is a guide bracket for X and Y axes and is installed between the X-axis guide mount 30 and the XY-axis adjuster body 10 and is movable along the guide line.

The X-axis guide mount 30 is formed on the front surface of the X-axis guide joint bracket 20 and has a center hole formed at a central portion thereof to be inserted into one side of the Z-axis mount 40.

That is, an X-axis guide groove is formed on the rear surface, and a protrusion formed on the front surface of the XY-axis guide line bracket 20 is positioned in the X-axis guide groove.

At this time, by adjusting the X-axis adjuster 200b, it is possible to move left and right along the X-axis guide groove.

In addition, one side of the Z-axis mount 40 is screwed to the Z-axis adjuster 200c, and the other side is inserted into the center hole of the end mount.

The Z-axis adjuster 200c has a cylindrical shape, includes a focus lens 210 therein, and the Z-axis mount is screwed to one side.

As described above, the Z-axis adjuster having the interval of 1 mm pitch is used to adjust the pitch interval back and forth so as to be adjustable in the Z-axis.

The first fixed mount 50 is formed on the front surface of the X-axis guide mount 30 and is configured to store the XY-axis guide bracket 20 and the X-axis guide mount 30 therein. And has a rectangular shape in which an inner space is formed, as shown in the figure.

At this time, the rear surface is coupled to the front surface of the XY-axis adjuster body 10.

That is, by engaging with the XY-axis adjuster body 10, the XY-axis guide bracket 20 and the X-axis guide mount 30, which are located between the XY-axis adjuster body and the first fastening mount, are internally fixed.

At this time, it is assembled together with the ending mount 60 and closed.

The ending mount 60 has a center hole formed at a central portion thereof and is coupled to the front surface of the first fixing mount 50.

At this time, the Z-axis adjuster 200c is inserted into the center hole.

As described above, the optical fiber aligning mount 200 of the present invention includes the X-axis adjuster 200b, the Y-axis adjuster 200a, and the Z-axis adjuster 200c, And focuses or defocuses the laser beam to the end face of the optical fiber to perform accurate energy transfer.

For example, the distance is adjusted so that the focus lens can be focused and defocused through the Z-axis adjuster 200c. The X-axis adjuster 200b and the Y-axis adjuster 200a adjust the distance, The path of the laser beam is adjusted to the center position of the horizontal axis and the vertical axis of the cross section.

In addition, the optical fiber input unit bracket 300 is coupled to the optical fiber array mount on one side and the 2940 nm optical fiber input unit on the other side.

That is, it keeps a constant distance from the 2940 nm backlight fiber input unit to the focus point, and fixes the 2940 nm backlight fiber input unit.

In addition, the 2940 nm counterbore fiber input unit 400 is formed of a fluoride glass fiber material to output a 2940 nm band.

At this time, one side is coupled to the optical fiber input unit bracket and the other side is connected to the optical fiber.

The optical fiber 500 is coupled to a 2940 nm counterbore fiber input unit, and the other side is coupled to a 2940 nm counterbore fiber output unit.

In this case, the optical fiber should be formed of fluoride glass fiber material in the same manner as the 2940 nm op- tical fiber input unit.

In the case of the conventional silica optical fiber, the loss is increased by 5 dB / m at a wavelength of 3 μm. However, in the case of the optical fiber of the above-mentioned material, loss is remarkably reduced at 0.1 to 0.2 dB / m at a wavelength of 3 μm.

Therefore, as described above, the optical fiber is also formed of a fluoride glass fiber material.

As shown in FIG. 3, the 2940 nm backlight fiber output unit 600 is coupled to the end of the optical fiber, and the other side is coupled to the handpiece treatment tip 700.

By replacing the articulated arm that outputs the 2940 nm band with an optical fiber through the above-described configuration, the energy loss is minimized as compared with the conventional articulated arm.

In addition, since the parts of the main body of the apparatus can be minimized, the manufacturing cost can be significantly lowered, and the weight can be reduced, so that it is possible to provide a simplicity of carrying.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It should be understood that various modifications may be made by those skilled in the art without departing from the spirit and scope of the present invention.

200: Fiber Optic Align Mount
300: Optical fiber input section bracket
400: 2940 nm large-light fiber input unit
500: Optical fiber
600: 2940nm band light fiber output
700: Treatment Tips for Handpieces

Claims (3)

1. An optical fiber transmission device for replacing an articulated arm of a medical Erbium-YAG laser,
An optical fiber aligning mount 200 coupled to an end of an optical fiber input unit 150 receiving a laser beam of 2940 nm band generated from the Erbium Nad Laser resonator 100 and including a focus lens 210 therein;
An optical fiber input section bracket 300 having one side coupled to the optical fiber array mount and the other side coupled to a 2940 nm opposed fiber input;
A 2940 nm opaque fiber input unit 400 formed of a fluoride glass fiber material for outputting a 2940 nm band, one side connected to an optical fiber input unit bracket and the other side connected to an optical fiber;
An optical fiber 500 having one side coupled to the 2940 nm backlight fiber input unit and the other side coupled to a 2940 nm backlight fiber output unit;
And a 2940 nm counterbore fiber output unit 600 coupled to the tip of the optical fiber and coupled to the handpiece treatment tip 700 on the other side,
The focusing distance of the focus lens can be set within the range of 0.1 mm to 10 mm so as not to focus on the end face of the optical fiber when the optical fiber input unit 400 is coupled to the optical fiber input unit bracket 300, Thereby preventing damage to the end face of the optical fiber and damage of the end face of the optical fiber due to the elapse of time.
The method according to claim 1,
The optical fiber alignment mount (200)
An X-axis adjuster 200b, a Y-axis adjuster 200a, and a Z-axis adjuster 200c so as to be adjustable in X-axis, Y-axis, and Z-
The X axis adjuster 200b and the Y axis adjuster 200a adjust the distance between the focus lens 210 and the Y axis adjuster 200c through the Z axis adjuster 200c. Wherein the path of the laser beam is adjusted to a center position of the optical fiber of the Er-YAG laser.


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