KR101045215B1 - Radiation energy density automatic control variable spot hand-piece - Google Patents

Abstract

PURPOSE: A radiation energy density automatic control variable spot hand-piece is provided to transfer a signal to a control device. CONSTITUTION: A radiation energy density automatic control variable spot hand-piece comprises: a radiation energy transfer unit which is provided with radiation energy; a focus bar guide module(300) which changes the density of radiation energy by adjusting a distance that the radiation energy is radiated to the skin; a focus control unit(400) controlling the density of the radiation energy according to the density of the radiation energy; and a signal wire(500) offering resistance value for density adjustment to the control device.

Description

Radiation energy automatic control variable spot handpiece {RADIATION ENERGY DENSITY AUTOMATIC CONTROL VARIABLE SPOT HAND-PIECE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a variable spot handpiece that automatically adjusts radiation energy density, and more particularly, to a handpiece capable of variably converting the density of radiation energy that the laser strikes the skin.

Human skin tissue is composed of the epidermis and the subcutaneous tissue below it, the epidermal layer having a stratum corneum acts as a biological barrier to the environment, the melanin cells that determine the skin color is present in the base layer.

In addition, the lower subcutaneous tissue maintains the structure of the skin by the extracellular protein collagen serves as a support.

Collagen is synthesized by fibroblasts and is a protein in which three polypeptides form a helix.

When wounded, the body activates a complex remedy, of which fibroblasts are present under the skin and are activated to temporarily enter the extracellular matrix (ECM) to cover the wound as soon as possible. Secrete.

As fibroblasts slowly move around the matrix, attracting fibers to recombine the matrix, making the matrix more rigid, and because of the growth factors contained in the matrix that were initially soft, the fibroblasts expressed contractile proteins by the growth factors, At some point, the fibroblasts stop moving and turn into strong contractile cells, such as popeye, that settle in the matrix and attract the wound edges, resulting in scarring or uneven surface of the skin.

At this time, the collagen fibrous tissue is heated by a predetermined energy source, degeneration of physical properties of the protein matrix occurs at a specific temperature, molecular binding of the matrix is broken, and the condition of the skin is evened, and also the collagen layer is activated. The elasticity of the skin can be restored.

By using the above principle, conventionally by cooling the skin surface for wrinkle removal and lifting of the skin, by irradiating energy such as laser, light or high frequency to the lower subcutaneous tissue, by raising the temperature of the subcutaneous tissue Organizational remodeling methods are suggested.

Unlike conventional methods that can damage the top layer of the skin, the method of irradiating the laser is characterized by being able to maintain a wide beam without generating much heat.

The present invention is to solve the above-mentioned problems, the operator can recognize the change of the radiation energy beam size in the handpiece as well as the change of the various beam size required for each lesion size can be adjusted through one handpiece. It is an object of the present invention to provide a variable spot handpiece that automatically adjusts the radiation density to provide a signal to the controller.

According to one aspect of the present invention, the radiation energy density control variable spot handpiece includes radiation energy delivery means for receiving radiation energy from a control device; And it may include a focus bar guide module for changing the density of the radiation energy by adjusting the distance the radiation energy provided from the radiation energy transfer means is irradiated to the skin.

According to the above-described configuration, the radiation energy density automatic variable variable spot handpiece according to the present invention can be adjusted through a single handpiece in which various beam sizes required for each lesion size can be changed, and the operator changes the beam size in the handpiece. The effect is to provide a signal to the controller so that it can be recognized.

1 is a functional block diagram showing a radiation energy density automatic adjustable variable spot handpiece according to the present invention.
Figure 2 is an exploded perspective view of the radiation energy density automatic variable variable spot handpiece according to the present invention.
Figure 3 is a side view showing a state in which the radiation energy density automatic variable variable spot handpiece according to Figure 2 is coupled.
4 is a cross-sectional view of the radiation energy density automatic control variable spot handpiece according to FIG.
5 is an exploded perspective view of the focus bar guide module in the radiation energy density automatic variable variable spot handpiece according to FIG.

The following detailed description of specific embodiments provides several descriptions of specific embodiments of the present invention. However, the present invention can be implemented in many different ways, which are defined and covered by the claims. The detailed description is described with reference to the drawings, wherein like reference numerals refer to the same or functionally similar elements.

The terminology used in the description provided herein is for the purpose of describing particular embodiments of the invention only and should not be construed as limiting or limiting the invention to any particular method. Furthermore, embodiments of the present invention may include a number of novel features which are necessary to represent the overall desirable properties of the invention or to practice the invention provided herein.

Furthermore, embodiments of the present invention may include a number of novel features which are necessary to represent the overall desirable properties of the invention or to practice the invention provided herein.

Figure 1 is a functional block diagram showing the radiation energy density automatic variable variable spot handpiece according to the present invention, Figure 2 is an exploded perspective view of the radiation energy density automatic variable variable spot handpiece according to the invention, Figure 3 is a radiation according to Figure 2 4 is a side view showing the energy density automatic control variable spot handpiece is coupled, Figure 4 is a cross-sectional view of the radiation energy density automatic control variable spot handpiece according to FIG.

According to the present invention, the radiation energy density control variable spot handpiece includes a radiation energy transmitting means 100 and a focus bar guide module 300.

The radiation energy transfer means 100 irradiates the skin with the radiation energy provided from the control device 10. Here, the radiant energy transmitting means 100 may use an optical fiber, a waveguide, or the like as a means of the optical transmission path.

The focus bar guide module 300 changes the density of the radiation energy by adjusting a distance at which the radiation energy provided from the radiation energy transfer means 100 is irradiated to the skin. Here, the radiant energy may use one of a laser beam, xenon, and halogen, but is not limited thereto.

The focus bar guide module 300 may further include a focus bar 200 and information providing means 401.

The focus bar 200 includes a fixing protrusion 210 on a cylindrical outer side in a cylindrical shape so that the focal length of the radiant energy irradiated while the focus bar 200 moves up and down is adjusted.

The focus bar guide module 300 includes a focus lens 310, a guide groove 320, a focus bar guide 330, and a focus bar guide assembly 340.

The focus bar guide module 300 is fastened to the cylindrical focus lens 310 therein.

Here, the cylindrical focus bar guide 330 of the focus bar guide module 300 is fixed for the vertical movement of the focus bar 200 while the cylindrical focus bar 200 is fastened between the focus lenses 310. Induction groove 320 for fastening the protrusion 210 is formed on the outer side of the cylinder.

Meanwhile, the focus bar guide assembly 340 of the focus bar guide module 300 moves the focus bar 200 up / down through the fixing protrusion 210 penetrating the guide groove 320 as shown in FIG. 4. A spring-shaped adjustment groove 341 is formed therein and coupled to surround the focus bar guide 330.

The information providing means 401 may include a PCB part 410, a focus adjusting body 420, a POGO pin 430, and a focus adjusting part 440 of the focus adjusting means 400. When the density is adjusted, the density of the radiant energy adjusted according to the resistance value of the contact portion 411 of the PCB unit 410 is controlled through the PCB unit 410 and the signal line 500 of the focus control unit 400. Is fed back to (10).

The PCB part 410 of the focus adjusting means 400 has at least one or more contact parts 411 and is fixed in the focus adjusting part 440. In this case, the contact unit 411 may use a variety of sensors.

The focus adjusting body 420 of the focus adjusting means 400 is rotated by the focus bar 200, and the POGO pins 430 are formed therein, and the focus bar is rotated according to the rotation of the focus adjusting means 400. When the guide module 300 rotates, the focus bar 200 interlocked with the fixing protrusion 210 rotates to move the focal point of the radiant energy irradiated through the focus lens 310.

Here, the POGO pin 430 of the focus adjusting means 400 is formed in the focus adjusting body 420 and rotates in conjunction with the focus adjusting body 420 while rotating the contact portion 411 of the PCB 410. In contact with the contact portion 411 is connected.

Meanwhile, the focus adjusting unit 440 of the focus adjusting unit 400 is formed by fixing the PCB unit 410 therein and is fastened to the focus adjusting body 420.

The signal line 500 connects the PCB unit 410 of the focus adjusting means 400 with the control device 10.

Hereinafter, a description will be given of the operation process of the automatic control of the radiation energy density variable spot handpiece.

First, the focus bar 200, the focus bar guide module 300, the focus adjusting means 400, and the signal line 500 are fastened and coupled while the radiation energy transmitting means 100 is inserted.

At this time, when the focus bar 200 and the focus bar guide module 300 are fastened, the fixing protrusion 210 of the focus bar 200 penetrates the guide groove 320 of the focus bar guide module 300.

In addition, the focus bar 200 is also fastened to the focus bar guide assembly 340 of the focus bar guide module 300.

At this time, the fixing protrusion 210 of the focus bar 200 is inserted into the adjustment groove 341 formed in the spring shape in the focus bar guide assembly 340.

Thereafter, the focus bar guide module 300 and the focus adjusting means 400 are fastened.

At this time, the PCB control unit 410 and the POGO pin 430 is inserted inside the focus adjusting means 400.

Here, the PCB unit 410 is fixed inside the focus adjusting unit 440 and the POGO pin 430 is fixed inside the focus adjusting body 420.

The focus adjusting means 400 fastened in this way is fastened outside the stopper 600.

At this time, the contact portion 411 of the PCB 410 fixed inside the focus adjusting means 400 is connected to the signal line 500. In this case, the signal line 500 is connected to the control device 10.

Therefore, for any radiation energy treatment by holding the focus control means 400 to rotate the focus bar guide assembly 340.

Then, the PCB part 410 fixed inside the focus adjusting means 400 has the PCB part 410 having the POGO pin 430 fixed inside the focus adjusting body 420 of the focus adjusting means 400 in a fixed state. Will rotate in phase.

In addition, when the POGO pin 430 is rotated on the PCB unit 410 by the rotation of the focusing body 420 and is located at the contact unit 411 of the PCB unit 410, the contact unit 411 is connected and controlled. It is possible to detect the resistance value of the contact portion 411 through the device 10. Here, the PCB unit 410 may have at least one or more contact parts 411 having different resistance values.

Then, the control device 10 displays the radiation energy density value corresponding to the resistance value of the contact portion 411. That is, the focus bar guide module 300 also rotates as the focus adjusting means 400 rotates.

Therefore, when the focus bar guide module 300 rotates, the focus bar 200 is also interlocked by the fixing protrusion 210 to rotate.

Then, the fixing protrusion 210 of the focus bar 200 passes through the guide groove 320 of the focus bar guide module 300 and then moves along the adjustment groove 341 of the focus bar guide assembly 340.

That is, as the fixing protrusion 210 moves along the adjustment groove 341, the focus bar guide module 300 moves along the guide groove 320 of the focus bar guide module 300.

At this time, when the focus bar 200 moves, the energy radiation density irradiated to the skin is also changed because the focus of the radiation energy irradiated through the focus lens 310 is changed.

On the other hand, the contact portion 411 of the PCB 410 is positioned to correspond to the radiation energy density preset for each skin.

For example, when the contact portion 411 of the PCB 410 is positioned at the first resistance value according to the rotation of the focus bar guide module 300, the radiation energy density is focused on the skin, and the second resistance When positioned at the value, the focus bar 200 moves so that the radiation energy density is lower than the position at the first resistance value, and when positioned at the third resistance value, the radiation energy density is at the second resistance value. The focus bar 200 may be moved to form a lower level to adjust the radiation energy density.

Although the foregoing detailed description has shown, described, and mentioned the basic novel features of the invention as applied to the various embodiments, various omissions, substitutions, and changes in the form and details of the illustrated system may be made without departing from the intention of the invention. It will be appreciated that changes may be made by those skilled in the art.

100: radiation energy transmission means 200: focus bar
210: fixing protrusion 300: focus bar guide module
310: focus lens 320: guide groove
330: focus bar guide 340: focus bar guide assembly
341: adjusting groove 400: focus adjustment means
401: information providing means 410: PCB part
411: contact portion 420: focusing body
430: POGO pin 440: focus control unit
500: signal line

Claims (10)

Radiation energy transfer means (100) which is an optical transmission path for receiving radiation energy provided from any one of the laser beam, xenon and halogen through the control device (10);
A focus bar guide module 300 for changing a density of radiation energy by adjusting a distance at which radiation energy provided from the radiation energy transmitting means 100 is irradiated to the skin; And
When adjusting the density of the radiant energy through the focus bar guide module 300, the control device may include preset resistance value information according to the density of the radiant energy such that the density of the radiant energy to be adjusted is displayed on the control device 10. Information providing means 401 for providing 10),
The information providing means 401 includes a PCB portion 410 having a contact portion 411 having a plurality of resistance values;
The PCB unit 410 is formed inside the focus adjusting body 420 which is rotated by the focus bar 200 which controls the density of the radiant energy and rotates together when the focus adjusting body 420 is rotated. POGO pin 430 connecting the contact portion 411 when the contact with the contact portion 411 of the;
A focus adjusting means (400) formed so that the PCB unit (410) is fixed therein and having a focus adjusting unit (440) fastened to the focus adjusting body (420); And
The PCB 410 and the control device 10 are connected to each other such that a resistance value of the contact controller 411 of the PCB 410 is provided to the control device 10 when the focusing body 420 rotates. Radiation energy density automatic adjustable variable spot handpiece comprising a signal line (500).
delete The method of claim 1,
The focus bar guide module 300,
A focus lens 310 for irradiating the skin with radiant energy provided through the radiant energy transfer means 100;
A focus bar 200 for adjusting a radiation density of radiation energy irradiated to the skin from the focus lens 310 by adjusting a distance from the focus lens 310; And
Radiation energy automatically adjustable variable spot handpiece comprising a focus bar guide 330 for moving the focus bar 200 up and down.
The method of claim 3,
The focus bar guide module 300,
Cylindrical focus bar 200 for adjusting the irradiation distance of the radiant energy, including a fixing projection 210 on the cylindrical outer one side in a cylindrical shape; And
The cylindrical focus lens 310 is fastened therein, and the cylindrical focus bar 200 is fastened between the focus lenses 310, and the fixing protrusion 210 is used to move the focus bar 200 up and down. Induction groove 320 for fastening the top of the focus bar 200 through the cylindrical focus bar guide 330 formed on one side of the cylinder and the fixing protrusion 210 penetrating the guide groove 320. Radiation energy automatically adjustable variable spot handpiece including a cylindrical focus bar guide assembly 340 is formed to form a spring-shaped adjustment groove (341) for moving downward and to surround the focus bar guide 330 .
delete delete The method of claim 1,
The contact portion 411,
Radiation energy density control variable spot handpiece, characterized in that consisting of a common contact terminal and a plurality of resistors.
delete The method of claim 7, wherein
The radiant energy transfer means 100,
Radiation energy density self-adjusting variable spot handpiece, characterized in that any one of the optical fiber, waveguide.
delete

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