KR20170095712A - Optical Output Device of Rhinitis therapeutic Apparatus - Google Patents

Abstract

Provided is an optical output device for rhinitis treatment devices. The optical output device for the rhinitis treatment devices includes an optical fiber which penetrates optical energy generated from a light source in the rhinitis treatment device and then output optical energy to the outside. The width of a terminal end of the optical fiber where optical energy is output can be narrow so as to enlarge an irradiation angle or an irradiation area for optical energy.

Description

Technical Field [0001] The present invention relates to an optical output device of a rhinitis therapeutic device,

The present invention relates to an optical output device for a rhinitis treatment device, and more particularly to an optical output device for a rhinitis treatment device for efficiently transmitting light energy into the nasal cavity by expanding an irradiation area or irradiation angle of light energy will be.

The rhinitis treatment device is used for the treatment of nasal rhinitis, that is, inflammation of the nasal mucosa on the surface of the nasal cavity, which is an empty space inside the nose. A rhinitis treatment device using laser is effective in stimulating the meridian by irradiating the laser in the nasal cavity which can not be treated directly, thereby discharging the nasal discharge and eliminating the nasal obstruction.

The optical output device of the conventional rhinitis treatment device uses an optical fiber whose end is simply vertically polished. In the conventional optical output device of the rhinitis treatment apparatus, since the end of the optical fiber is simply polished vertically, the transmitted light is emitted only at the end of the optical fiber and the angle of emission is relatively small. Therefore, the nasal cavity It is difficult to apply therapeutic light to the part.

Korean Patent Laid-Open No. 10-2011-0125728 relates to such a nasal treatment apparatus, which discloses a technique for treating an inflammation in the nasal cavity by oscillating a laser beam from a semiconductor laser into the nasal cavity.

Embodiments describe an optical output device of an apparatus for treating rhinitis, and more specifically, a technique for efficiently transferring optical energy into a nasal cavity by expanding a light output surface in an optical output device of an apparatus for treating rhinitis.

Embodiments of the present invention provide an optical output device for a rhinitis treatment device that exposes light to a large surface inside the nasal cavity by inducing diffraction of light by narrowing the width of the end of the optical output device.

In addition, the embodiments of the present invention provide an optical output device for a rhinitis treatment device that is exposed to the nasal cavity by inducing photo-pricking because the surface of the optical output device is roughly formed and the exposed surface is widened.

The optical output device of the rhinophyta treatment device according to an embodiment includes an optical fiber for passing the optical energy output from the light source of the rhinitis treatment device and outputting it to the outside, The width of the end where the light energy is output may be narrowed.

At least a part of a core and a clad of the optical fiber on the side where the light energy is outputted is roughly formed by processing to induce light scattering.

The optical fiber includes a first optical fiber for passing light energy output from the light source; And a second optical fiber formed on one side of the first optical fiber and passing the optical energy passed through the first optical fiber to output the optical energy to the outside and narrowing the width of the end to induce a diffraction phenomenon have.

At least a part of the clad on the side of the first optical fiber connected to the second optical fiber is cut off and at least a part of the core is roughly formed by processing to induce the light propagation have.

The second optical fiber may be gradually narrowed from a portion connected to the first optical fiber toward the end.

The first optical fiber may have a cylindrical shape, and the second optical fiber may have a truncated conical shape.

The first optical fiber may have a polygonal columnar shape, and the second optical fiber may have a polygonal shape.

At least a part of the clad of the second optical fiber is cut and at least a part of the core is roughly formed by the working so that the optical fiber can be induced.

The light source may include at least one of a laser diode and an LED.

The optical fiber may have a planar or concave surface having an end surface on which the light energy is output, and at least a part of the optical fiber may be inserted into the nasal cavity of the user to output the optical energy.

The rhinitis treatment device according to another embodiment comprises a power source; A controller coupled to the power supply; A main body for receiving the power source and the control unit; At least one insertion rod coupled to the body and configured to be inserted into the nasal cavity for treatment; At least one light source formed in the at least one insertion rod; And an input unit formed in the main body and adapted to select whether to supply the light source from a user, wherein the control unit supplies the power source to the light source in accordance with an input inputted to the input unit, The optical fiber may include an optical fiber having a narrow width at an end where the light energy is outputted so that the light energy output from the light source of the treatment device is transmitted to the outside and the irradiation area or the irradiation angle of the light energy is expanded .

At least a part of a core and a clad of the optical fiber on the side where the light energy is outputted is roughly formed by processing to induce light scattering.

The optical fiber includes a first optical fiber for passing light energy output from the light source; And a second optical fiber formed on one side of the first optical fiber and passing the optical energy passed through the first optical fiber to output the optical energy to the outside and narrowing the width of the end to induce a diffraction phenomenon have.

The second optical fiber may be gradually narrowed from a portion connected to the first optical fiber toward the end.

At least a part of the clad on the side of the first optical fiber connected to the second optical fiber is cut off and at least a part of the core is roughly formed by processing to induce the light propagation have.

At least a part of the clad of the second optical fiber is cut and at least a part of the core is roughly formed by the working so that the optical fiber can be induced.

Embodiments of the present invention can provide an optical output device for a rhinitis treatment device that exposes light to a large surface inside the nasal cavity by inducing diffraction of light by narrowing the width of the end of the optical output device.

In addition, according to embodiments, the surface of the optical output device is roughly formed and the exposed surface is formed to be wide, thereby providing an optical output device of a rhinitis treatment device capable of efficiently laser treatment by inducing light scattering.

1 is a view for explaining an optical output apparatus of a general rhinitis treatment apparatus.
2 is a block diagram showing a configuration of an apparatus for treating rhinitis according to an embodiment of the present invention.
3 is a view for explaining an optical output apparatus of the rhinitis treatment apparatus according to one embodiment.
4 is a view for explaining an optical output apparatus of the rhinitis treatment apparatus according to another embodiment.
5 is a view for explaining the end surface of the optical output device of the rhinophyta treatment device according to the embodiment.
6 is a view for explaining an apparatus for treating rhinitis according to an embodiment.
FIG. 7 is a view for explaining depth of skin penetration according to wavelength of a light source according to an embodiment.

Hereinafter, embodiments will be described with reference to the accompanying drawings. However, the embodiments described may be modified in various other forms, and the scope of the present invention is not limited by the embodiments described below. In addition, various embodiments are provided to more fully describe the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

The following examples provide techniques for efficiently delivering light energy for treatment of rhinitis within the nasal cavity (nostril) by extending the light output surface in an optical output device of the rhinitis treatment device.

1 is a view for explaining an optical output apparatus of a general rhinitis treatment apparatus.

The rhinitis treatment device can transmit the light energy output through the light source to the output device of the rhinitis treatment device through the optical fiber. Where the end of the output device of the rhinitis treatment device must transmit the light energy through the optical fiber to the widest part of the nasal cavity. For this purpose, it is possible to improve the efficiency of rhinitis treatment by effectively transferring the light energy to the treatment site by modifying the shape of the end portion of the optical fiber.

An optical fiber may be used to transmit a laser beam and / or light output from the LED to a treatment unit for inserting the light into the nasal cavity, which belongs to the main body of the rhinitis treatment apparatus using light such as an infrared wavelength. The light transmitted through this optical fiber can be emitted from the end of the optical fiber and irradiated to the wall in the nasal cavity.

1, the optical fiber includes a core 10 for propagating light energy (light) 20 therein and a light energy source 20 for blocking progressive light energy 20 to the core 10 according to the principle of total internal reflection And a clad 11 as shown in FIG. Further, the optical fiber may further include an outer coating layer (not shown). In this case, the optical fiber has a double structure in which the core 10 having a high refractive index is covered with the clad 11 having a low refractive index.

Referring to FIG. 1A, a single mode optical fiber is shown. The movement of the optical energy 20 can be confirmed within the core 10, and the transmission band can be 10 GHz / km or more. 1B shows a multimode optical fiber, which is a step index type and can have a transmission band of about 10 to 50 MHz / km. FIG. 1C shows a multimode optical fiber, which is a clad index type, GHz / km.

2 is a block diagram showing a configuration of an apparatus for treating rhinitis according to an embodiment of the present invention.

2, the rhinitis treatment device 200 may include a light irradiation unit 210, a control unit 220, an input unit 230, and a power supply 240. The rhinitis treatment device 200 may further include a display unit according to an embodiment.

The rhinitis treatment device 200 is a treatment device for treating the inside of the nasal cavity (i.e., affected part) of a patient to be treated with rhinitis using at least one of a laser diode and a light emitting diode. The laser can be irradiated to the lesion portion by locating at least one of the diodes adjacent to the lesion portion.

The operation of at least one of the laser diode and the light emitting diode included in the light irradiation unit 210 may be driven according to a program input to the control unit 220.

The program of the control unit 220 may store the light emitting duration and the blinking time of the light irradiating unit 210. For example, when the affected part treatment program is configured to irradiate the laser for 1 minute, the laser is irradiated for 1 minute by pressing the start button of the input unit 230. [ The laser emission is stopped after 1 minute, which is a luminescence sustain time point according to the lesion treatment program of the control unit 220. In this way, the program of the control unit 220 stores the light emission duration time and the blinking time of the light irradiation unit 210, and the light irradiation unit 210 operates according to the program.

Here, the light emission duration and the blinking time input to the program of the control unit 220 may be changed through the input unit 230.

The input unit 230 may include one or more input buttons, and may adjust an emission sustain time and a blinking time by using an input button.

The power source 240 can supply power to the light irradiation unit 210 and the control unit 220. Also, when the display unit is provided, power can be supplied to the display unit. The power source 240 may be constructed using a battery or the like, and other power sources may be used, but the present invention is not limited thereto.

In addition, the display unit can display the flash duration information and the flash duration information adjusted through the input button of the input unit 230 in real time. The remaining power of the power source 240 may be displayed and the operation state of the light irradiating unit 210 may be displayed. At this time, the information displayed on the display unit is not limited.

3 is a view for explaining an optical output apparatus of the rhinitis treatment apparatus according to one embodiment.

Referring to FIG. 3, the optical output device of the rhinitis treatment device according to one embodiment may include an optical fiber 300.

The optical fiber 300 can pass the light energy 330 output from the light source of the rhinitis treatment device and output it to the outside. The width of the end surface 313 of the optical fiber 300 where the light energy 330 is output may be narrow to extend the irradiation area or the irradiation angle of the light energy 330.

Here, the light source may include at least one of a laser diode and a light emitting diode (LED). The light emitting diode may include at least one of an ultraviolet light emitting diode (UV LED) and an infrared light emitting diode (IR LED).

At least a part of the core on the side where the light energy 330 is output and the clad disposed on the outside of the core are roughly formed on the surface of the optical fiber 300 by the processing so that the optical fiber 300 can induce the light propagation. In other words, the clad and core of the optical fiber 300 can be processed by a method such as cutting, polishing or the like to form a rugged surface to enlarge the irradiation range due to diffuse reflection. At this time, at least a part of the clad is cut, and at least a part of the core is roughly formed by the working so that irregular reflection can be induced.

The optical fiber 300 may have a flat or concave surface on which the end surface 313 from which the light energy 330 is output.

When the end face 313 of the optical fiber 300 is concave, the reflection angle can be widened by the concave lens effect. Since it is not easy to concave the end surface 313, the end surface 313 is formed to be narrow and flat. If a predetermined angle inclined surface is formed inward to form concave, the reflection angle can be enlarged while passing through a narrow plane.

At least a portion of the optical fiber 300 may be inserted into the nasal cavity of the user to output the light energy 330.

More specifically, the optical fiber 300 may include a first optical fiber 310 and a second optical fiber 312. Here, the optical fiber 300 is divided into a first optical fiber 310 and a second optical fiber 312 for the sake of explanation, and at least a part of the optical fiber 300 integrally formed is processed.

The first optical fiber 310 may pass the light energy 330 output from the light source.

The second optical fiber 312 may be formed on one side of the first optical fiber 310 to allow the light energy 330 passing through the first optical fiber 310 to pass therethrough and output the light energy to the outside. The second optical fiber 312 may have a narrow width of the end surface 313 to induce diffraction of light.

The second optical fiber 312 may be gradually narrowed from the portion connected to the first optical fiber 310 to the end surface 313 side.

For example, the first optical fiber 310 may have a cylindrical shape and the second optical fiber 312 may have a truncated conical shape. At this time, the width of the end surface 313 of the second optical fiber 312 may be narrower than the width of the side connected to the first optical fiber 310.

As another example, the first optical fiber 310 may have a polygonal columnar shape such as a triangular prism, a quadrangular prism, a pentagonal prism, a hexagonal prism, an octagonal prism, etc., and the second optical fiber 312 may have a polyhedral shape. At this time, the width of the end surface 313 of the second optical fiber 312 may be narrower than the width of the side connected to the first optical fiber 310.

At least a part of the clad disposed outside the core is cut and at least a part of the core is roughly formed by processing to induce the light propagation . In particular, since the second optical fiber 312 is roughly formed to have a wide exposure surface, it is possible to effectively treat rhinitis by transferring light energy 330 for treatment to the corners of the nasal cavity.

For example, the rhinitis treatment device using the optical output device of the rhinitis treatment device according to one embodiment irradiates nascent cells sensitized with a wavelength of 650 nm and a low output laser of 5 mW to relax the tension, Tissue can be activated and returned to normal cells. The effects of low power laser exposure on many nasal cavities can be even greater.

Accordingly, the rhinitis treatment apparatus to which the optical output apparatus of the rhinitis treatment apparatus according to one embodiment is applied is effective in treating allergic rhinitis by increasing exposure of light through deformation of the output surface.

According to one embodiment, the light output surface of the optical output device of the rhinitis treatment device can be expanded to efficiently transmit light energy 330 into the nasal cavity. In other words, since the surface of the optical output device is roughly formed to have a large exposing surface, it is possible to induce light scattering to expose more in the nasal cavity. Thus, effective rhinitis treatment is possible.

In addition, according to one embodiment, the width of the end surface 313 of the optical output device is narrow to induce diffraction of light, thereby exposing light to a wide surface inside the nasal cavity.

A rhinitis treatment device to which an optical output device of the rhinitis treatment device according to an embodiment is applied is a device for treating rhinitis by irradiating light. The rhinitis treatment device changes the shape of the end surface 313 of the optical fiber that transmits light, . Hereinafter, the rhinitis treatment device to which the optical output device of the rhinitis treatment device according to one embodiment is applied will be described in detail.

4 is a view for explaining an optical output apparatus of the rhinitis treatment apparatus according to another embodiment.

Referring to FIG. 4, the optical output device of the rhinitis treatment device according to another embodiment may include an optical fiber 400. The optical output device of the rhinophyta treatment device according to another embodiment is the same as the optical output device of the rhinophyta treatment device according to the embodiment described with reference to FIG. 3, and will not be repeatedly described.

The optical fiber 400 may include a core 410 and a clad 420.

The core 410 of the optical fiber 400 is guided by the clad 420 and can pass the light energy 430 output from the light source of the rhinitis treatment device and output the light energy to the outside through the end surface 413. The optical fiber 400 is formed to have a narrow width of the end surface 413 from which the light energy 430 is outputted, thereby enlarging the irradiation area and the irradiation angle of the light energy 430.

The optical fiber 400 is formed such that at least a part of the core 410 on the side where the light energy 430 is output and the cladding 420 disposed on the outside of the core 410 are roughly formed to be rugged by the processing, . In other words, the core 410 of the optical fiber 400 or the clad 420 outside the core 410 is processed by a method such as cutting and polishing to form uneven surfaces 421 and 422 to enlarge the range of irradiation due to diffuse reflection can do. Particularly, in the optical fiber 400, at least a part of the clad 420 is cut, and at least a part of the core 410 is roughly formed by the processing so that irregular reflection can be induced.

The optical fiber 400 may have a planar or concave surface on which the end surface 413 from which the light energy 430 is output. When the end face 413 of the optical fiber 400 is concave, the reflection angle can be widened by the concave lens effect. When the end face 413 of the optical fiber 400 is concave, the reflection angle can be widened by the concave lens effect. It is not easy to concave the end surface 413, so that the end surface 413 is formed to be narrow and flat. If a predetermined angle inclined surface is formed inward to form concave surface, the reflection angle can be enlarged while passing through a narrow plane.

At least a portion of the optical fiber 400 may be inserted into the nasal cavity of the user and the light energy 430 may be output.

More specifically, the optical fiber 400 may include a first optical fiber 411 and a second optical fiber 412. Here, the optical fiber 400 is divided into a first optical fiber 411 and a second optical fiber 412 for convenience of explanation, and at least a part of the optical fiber 400 integrally formed is processed.

The first optical fiber 411 can pass the light energy 430 output from the light source. At least a part of the clad 420 disposed outside the core 410 connected to the second optical fiber 412 is cut off and at least a part of the core 410 is cut, It is polished and roughened by the rugged surface 421 to induce light blast.

The second optical fiber 412 may be formed on one side of the first optical fiber 411 to allow the optical energy 430 passing through the first optical fiber 411 to pass therethrough and to be output to the outside. In addition, the second optical fiber 412 has a narrow end surface 413, which can induce diffraction of light.

The second optical fiber 412 may be gradually narrowed from the portion connected to the first optical fiber 411 to the end surface 413 side.

For example, the first optical fiber 411 may have a cylindrical shape and the second optical fiber 412 may have a truncated conical shape. At this time, the width of the end surface 413 of the second optical fiber 412 may be narrower than the width of the end surface 413 connected to the first optical fiber 411.

As another example, the first optical fiber 411 may have a polygonal columnar shape such as a triangular prism, a quadrangular prism, a pentagonal prism, a hexagonal prism, and an octagonal prism, and the second optical fiber 412 may have a polyhedral shape. At this time, the width of the end surface 413 of the second optical fiber 412 may be narrower than the width of the end surface 413 connected to the first optical fiber 411.

The second optical fiber 412 is formed such that at least a part of the clad 420 disposed on the outer side of the core 410 and the core 410 forms an inclined surface having a narrow width of the end surface 413, Can be roughened by the rugged surface 422 to induce light blast. More specifically, at least a portion of the cladding 420 disposed outside the core 410 is cut, and at least a portion of the core 410 is cut and polished to form a rugged surface 422 ) So as to induce light scattering.

In particular, the second optical fiber 412 is roughly formed to have a wide exposure surface, thereby transmitting light energy 430 for treatment in the nasal passages of the nasal cavity, thereby effectively treating rhinitis.

According to the embodiments as described above, the optical fiber peels off at least a part of the output side cladding, and the outer surface is formed as a rugged surface, so that the irradiation range of light energy can be widened. According to the embodiments, the width of the output end face of the optical fiber is narrowly formed to form the inclined face, thereby increasing the irradiation area of the slope side light energy due to irregular reflection of the inclined face portion, The angle of irradiation of energy can be increased.

5 is a view for explaining the end surface of the optical output device of the rhinophyta treatment device according to the embodiment.

Referring to FIG. 5, the optical fiber may include a core 510 and a clad. The core 510 of the optical fiber can be guided by the clad and can transmit the light energy output from the light source of the rhinitis treatment device and output to the outside through the end surface 513.

At this time, as shown in FIG. 5B, the optical fiber is formed to have a narrow width of the end surface 513 from which the light energy is outputted, so that the irradiation area and the irradiation angle of the light energy can be extended.

The width of the output side end face 513 of the optical fiber is gradually narrowed to form the plane 511 and the inclined face 512 to enlarge the slope side irradiation area due to irregular reflection of the inclined face 512, The cross section of the optical fiber is formed to be narrow, and the irradiation angle of light energy can be enlarged.

Moreover, the optical fiber has a flat or concave surface on which the end surface 513 from which the light energy is outputted, so that the irradiation range and the irradiation angle of the light energy can be adjusted.

6 is a view for explaining an apparatus for treating rhinitis according to an embodiment.

Referring to FIG. 6, an apparatus for treating rhinitis according to an embodiment includes a main body 605, at least one insertion rod 601a, 601b, and a switch 607. Also, although not shown in the drawings, it may include a power source, a control unit, and a light source. And a touch sensor 603 according to an embodiment.

The main body 605 may include at least a power source such as a battery. Here, the power source may be a battery or a terminal connected to an external power source.

In addition, the body 605 may include a control unit that can be implemented as a semiconductor chip, a microprocessor, or the like. The control unit can supply the power source to the light source in accordance with the input inputted to the input unit of the switch or the like.

At least one of the insertion rods 601a, 601b may be inserted into the nasal cavity in case of need for rhinitis treatment. In the case of treatment, the user can turn the switch 607 ON. So that the light from the light source can be irradiated into the nasal cavity through at least one of the insertion rods 601a and 601b. Here, at least one of the insertion rods 601a and 601b may be formed as a pair.

Here, the switch 607 may be formed in the main body 605 and may be an input unit for selecting whether to supply the light source from the user.

The at least one light source formed in the at least one insertion rod 601a, 601b may include, for example, a laser diode and / or a light emitting diode (LED).

The contact sensor 603 is electrically coupled to a control unit in the main body, and the control unit determines whether or not the contact sensor 603 has contacted the human body. When the contact sensor 603 contacts the human body, a light source such as a laser diode and / And the like. This contact sensor 603 may be omitted depending on the embodiment.

The position of the contact sensor 603 according to one embodiment is the inside of at least one of the insertion rods 601a and 601b. When the insertion rods 601a and 601b are moved for insertion into the nasal cavity in the state that the laser is turned on, if the user's eyes are irradiated with the laser for 0.25 seconds or more for a certain period of time, It is possible to arrange the contact sensor 603 on the inner side. In addition, when the insertion rods 601a and 601b detect the skin contact after insertion into the nasal cavity, the laser is automatically turned on to prevent the laser light from being irradiated to the user's eyes.

Since the rhinitis treatment device according to one embodiment has the nipping structure, it is preferable that the rhinitis treatment device is located at the upper part of the inside as shown in the drawing. However, the present invention is not limited thereto, and it is also possible to provide the contact sensor 603 in a position where it can be contacted with the septum of the nose.

The pair of pushing portions 611a and 611b are formed on both sides of the main body 605 so that the pushing portions 611a and 611b are pressed from both sides so that at least one of the insertion rods 601a and 601b is opened, It is also possible to make insertion easier.

At least one of the insertion rods 601a and 601b may include an optical fiber through which the light energy output from the light source of the rhinitis treatment device is transmitted to the outside and the width of the end where the light energy is outputted is formed narrow.

At least a part of the optical fiber can be inserted into the nasal cavity of the user and light energy can be output.

More specifically, the optical fiber may be composed of the first optical fiber and the second optical fiber.

The first optical fiber can pass the light energy output from the light source.

The second optical fiber is formed on one side of the first optical fiber, and can transmit the light energy passing through the first optical fiber to the outside. Further, the second optical fiber is formed to have a narrow width at its end, which can induce a diffraction phenomenon of light.

Such a second optical fiber can be gradually narrowed from a portion connected to the first optical fiber to an end side.

For example, the first optical fiber may have a cylindrical shape, and the second optical fiber may have a truncated conical shape. At this time, the width of the end of the second optical fiber may be narrower than the width of the side connected to the first optical fiber.

In another example, the first optical fiber may have a polygonal columnar shape such as a triangular prism, a quadrangular prism, a pentagonal prism, a hexagonal prism, and an octagonal prism, and the second optical fiber may have a polyhedral shape. At this time, the width of the end of the second optical fiber may be narrower than the width of the side connected to the first optical fiber.

And, the second optical fiber can be roughened to induce light propagation. Particularly, since the surface of the second optical fiber is roughly formed and the exposed surface is formed wide, it is possible to effectively treat rhinitis by transferring light energy for treatment to every corner of the nasal cavity.

According to one embodiment, the rhinitis treatment device is a narrow modification of the optical fiber end of a conventional rhinitis treatment device. When the light passes through a narrow section, the rhinitis treatment device utilizes the physical property that the diffraction phenomenon occurs more easily, Can be exposed.

Further, the optical fiber of the output portion can be formed as a rough surface, so that the light propagation can be induced. Therefore, laser treatment can be more effective than conventional rhinitis treatment devices due to the effects of lightning strikes.

FIG. 7 is a view for explaining depth of skin penetration according to wavelength of a light source according to an embodiment.

A number of studies have been carried out on the wavelength band with the therapeutic effect of rhinitis. Studies have shown that laser diodes or light-emitting diodes (LEDs) with wavelengths of 650 nm and 830 nm are effective in treating rhinitis. Since the treatment effect may be different depending on the wavelength range of the light source, it is possible to arrange the light source in various forms to increase the therapeutic effect.

Referring to FIG. 7, the penetration depth of the light irradiated from the light source varies depending on the wavelength range. Therefore, if the location of the nasal mucus is in the epidermis, or if it is located under the skin, it may be deep in the skin. In order to more effectively treat such variously spread rhinitis, it is possible to enhance the therapeutic effect by using a combination of light sources having different wavelength ranges. In particular, 650nm wavelength can be used for treatment of rhinitis, and 830nm can be used for complex wavelengths. Here, the 830 nm wavelength band is a non-visible near infrared (NIR) region that penetrates deeper into the skin.

Embodiments of the present invention can provide an optical output device for a rhinitis treatment device that exposes light to a large surface inside the nasal cavity by inducing diffraction of light by narrowing the width of the end of the optical output device.

In addition, according to embodiments, the surface of the optical output device is roughly formed and the exposed surface is formed to be wide, thereby providing an optical output device of a rhinitis treatment device capable of efficiently laser treatment by inducing light scattering.

The rhinitis treatment device according to these embodiments is a device for treating rhinitis by irradiating light, and it can be attached to the rhinitis treatment device by changing the shape of the end of the optical fiber that transmits light. Also, it can be applied to a wide range of light emitted from the end of the optical fiber, for example, as an instrument for treating rhinitis, illumination, and the like.

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. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (15)

1. An optical output device for a rhinitis treatment device,
An optical fiber for passing the light energy output from the light source of the rhinophyta treatment instrument and outputting the light energy to the outside;
Lt; / RTI >
The optical fiber includes:
The width of the end at which the light energy is outputted is narrowed so as to extend the irradiation area or the irradiation angle of the light energy
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method according to claim 1,
The optical fiber includes:
At least a part of the core and the clad on the side from which the light energy is outputted is roughly formed by the processing to induce the light propagation
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method according to claim 1,
The optical fiber includes:
A first optical fiber for passing light energy output from the light source; And
A second optical fiber formed on one side of the first optical fiber and passing the optical energy passed through the first optical fiber to output to the outside,
And an optical output device for the rhinitis treatment device. The method of claim 3,
Wherein the first optical fiber comprises:
At least a part of the clad on the side connected to the second optical fiber is cut off and at least a part of the core is roughly formed by processing to induce the light propagation
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method of claim 3,
Wherein the second optical fiber comprises:
The width gradually decreases from the portion connected to the first optical fiber to the end side
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method of claim 3,
Wherein the first optical fiber has a cylindrical shape and the second optical fiber has a truncated cone shape
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method of claim 3,
Wherein the first optical fiber has a polygonal columnar shape and the second optical fiber has a polyhedral shape
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that 3. The method of claim 2,
Wherein the second optical fiber comprises:
At least a part of the clad is cut, at least a part of the core is roughly formed by the processing,
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method according to claim 1,
Wherein the light source comprises at least one of a laser diode and an LED
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that The method according to claim 1,
The optical fiber includes:
Wherein at least a part of the optical fiber is inserted into the nasal cavity of the user to output the light energy
Characterized in that the optical output device of the rhinitis treatment device is characterized by the fact that In rhinitis treatment devices,
power;
A controller coupled to the power supply;
A main body for receiving the power source and the control unit;
At least one insertion rod coupled to the body and configured to be inserted into the nasal cavity for treatment;
At least one light source formed in the at least one insertion rod; And
An input unit formed in the main body and adapted to select whether to supply the light source from a user,
Lt; / RTI >
The control unit supplies the power source to the light source in accordance with an input signal input to the input unit,
Wherein the at least one insertion rod comprises:
An optical fiber having a narrow width at an end where the light energy is outputted so as to enlarge an irradiation area or irradiation angle of the optical energy,
≪ / RTI > 12. The method of claim 11,
The optical fiber includes:
At least a part of the core and the clad on the side from which the light energy is outputted is roughly formed by the processing to induce the light propagation
Rhinitis < / RTI > 12. The method of claim 11,
The optical fiber includes:
A first optical fiber for passing light energy output from the light source; And
A second optical fiber formed on one side of the first optical fiber and passing the optical energy passed through the first optical fiber to output to the outside,
Lt; / RTI >
Wherein the second optical fiber comprises:
The width gradually decreases from the portion connected to the first optical fiber to the end side
Rhinitis < / RTI > 14. The method of claim 13,
Wherein the first optical fiber comprises:
At least a part of the clad on the side connected to the second optical fiber is cut off and at least a part of the core is roughly formed by the processing to induce the light propagation
Rhinitis < / RTI > 14. The method of claim 13,
Wherein the second optical fiber comprises:
At least a part of the clad is cut, at least a part of the core is roughly formed by the processing,
Rhinitis < / RTI >

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