KR20230088935A - A patch-type rhinitis treatment system using laser beam and optical module manufacturing method therein - Google Patents

Abstract

It relates to the patch-type rhinitis treatment device of the present application, a flexible substrate; and a VCSEL chip and an aspheric microlens, a first layer to which the VCSEL chip is attached, a second layer for securing a distance between the VCSEL chip and the aspherical microlens and supporting the aspheric microlens, and the aspheric microlens. A laser light source module composed of a third layer for inserting and fixing a lens; and a plurality of the laser light source modules are attached on a flexible substrate.

Description

A patch-type rhinitis treatment system using laser beam and optical module manufacturing method therein}

The present invention relates to a patch-type rhinitis treatment device using a laser beam and a method for manufacturing an optical module used therein.

Recently, the number of rhinitis patients due to seasonal temperature change and air pollution is steadily increasing. In particular, in the case of infants and children, it often occurs that they experience great difficulties in daily life due to rhinitis accompanied by an allergic reaction.

As a treatment method for rhinitis, pharmacological treatment methods using anticystamines, steroids, anticholinergic sprays, etc. have been mainly used, but recently, a semiconductor laser using Low Level Laser Therapy (LLLT) has been irradiated into the nasal cavity to treat rhinitis. Various rhinitis treatment devices for treating or alleviating symptoms have been disclosed.

For example, Korean Patent Registration No. 1947661 discloses a rhinitis treatment device for treating allergic rhinitis symptoms through a bio-stimulating effect by irradiating a laser in a state inserted into the nose.

In addition, Korean Patent Registration No. 0987729 discloses a main body including a light source unit composed of a blue LED and a red LED, worn on a part of the patient's head, and inserting a part of the main body into the patient's nose to have a therapeutic effect on rhinitis. A rhinitis treatment device that maximizes is disclosed.

In addition, Korean Patent Registration No. 1834267 includes a main body including a light irradiation unit for rhinitis treatment for irradiating light for rhinitis treatment into the nose of the treatment target, and the main body portion is seated on the nose of the treatment target and at the same time There is disclosed a rhinitis treatment device that is seated at a spaced position below the eye and can be worn on the face by a subject to be treated.

All of the above rhinitis treatment devices are accompanied by inconvenience in use because they have to fix the laser emitting part by hand or fix it in the nose through an additional device to bring the laser emitting part into contact with the nose so as to irradiate the laser into the nose.

In addition, while all of the rhinitis treatment devices described above irradiate the laser into the nose, recent research results show that even if the laser is irradiated to the nose at a certain depth under the skin layer, there is an effect of treating and alleviating rhinitis It is known.

Korean Registered Patent Publication No. 1947661 (2019.02.07.) Korean Registered Patent Publication No. 0987729 (2010.10.07.) Korean Registered Patent Publication No. 1834267 (2018.02.26.)

An object of the present invention is to provide a patch-type rhinitis treatment device that can comfortably and safely attach a laser light emitting unit for rhinitis treatment to the bridge of the nose and a method for manufacturing an optical module used therein.

In order to achieve the above object, the patch-type rhinitis treatment device according to the present invention includes a laser light source module 500 bonded on a flexible substrate 1000, and the laser beam emitted from the laser light source module 500 is applied to the skin It is characterized in that it includes an aspherical lens 400 capable of condensing the laser beam so as to transmit it down to a certain depth and a driving unit for driving the laser light source module 500.

Patch-type rhinitis treatment device of the present invention is a flexible substrate (1000); and a laser light source module 500, including a VCSEL chip 10 and an aspheric micro lens 400, and a first layer 100 to which the VCSEL chip 10 is attached, the VCSEL chip 10 and the aspheric surface Consisting of a second layer 200 for securing a distance between the micro lenses 400 and supporting the aspheric micro lenses 400 and a third layer 200 for inserting and fixing the aspheric micro lenses 400 , a laser light source module 500; a plurality of the laser light source modules 500 are attached on a flexible substrate 1000, the laser light source module 500 includes a first laser light source module 510, It is characterized by at least one of the second laser light source module 520 and the third laser light source module 530 . In addition, only the first laser light source module 510 may be attached to the flexible substrate 1000, and only the second laser light source module 520 may be attached to the flexible substrate 1000. Only the third laser light source module 530 may be attached to the substrate 1000 . In addition, the first laser light source module 510, the second laser light source module 520, and the third laser light source module 530 are attached to adjacent positions to form a group, and a plurality of the groups are attached to the flexible substrate It can also be attached on (1000). In addition, each of the first, second, and third laser light source modules 510, 520, and 530 has a laser beam of a first wavelength of 600 to 700 nm, a laser beam of a second wavelength of 700 to 810 nm, and a laser beam of 810 to 1300 nm A laser beam of a third wavelength of may be emitted. Each of the first, second, and third laser light source modules 510, 520, and 530 may emit a laser beam according to a continuous wave laser, a manual pulse laser, an automatic pulse laser, or any combination thereof. The curvature of the incident surface of the laser beam and the curvature of the emission surface of the laser beam of the aspheric microlens 400 are changed, so that the focal length of the aspheric microlens 400 can be changed within a range of 1 mm to 5 mm.

In addition, as a skin thickness measuring unit, a near-infrared irradiation module for irradiating near-infrared rays to the skin; a measurement module for measuring near-infrared rays reflected from each skin tissue among irradiated near-infrared rays; And a control module for controlling them; including, skin thickness measuring unit; and a skin color measuring unit, comprising: a photographing module; conversion module; and a skin color measuring unit including a measuring module, wherein the first, second and third wavelengths emitted from the VCSEL chip 10; a continuous wave laser emitted from the VCSEL chip 10, a manual pulse laser, an automatic pulse laser, or a laser according to any combination thereof; and the focal length of the aspherical micro lens 400 is controlled by the output values of the skin thickness measurement unit and the skin color measurement unit.

In addition, as a method of manufacturing the patch-type rhinitis treatment device, the laser light source module array 550 includes a plurality of the laser light source modules 500, and each of the plurality of the laser light source modules 500 has a VCSEL chip 10 A first layer 100 to be attached, a second layer 200 for securing a distance between the VCSEL chip 10 and the aspheric micro lens 400 and supporting the aspheric micro lens 400, and the aspheric micro lens 400 It is composed of a third layer 200 for inserting and fixing lenses, a plurality of the aspheric micro lenses 400 are fixed to the lens fixing frame 600, and an epoxy 610 is applied to the rear surface of the plurality of micro lenses. , The side of the laser light source module array 550 to which the VCSEL chip 10 is attached is oriented and pressed toward the plurality of aspherical micro lenses 400, so that the laser light source module array 550 and the plurality of aspheric micro lenses 400 The lens 400 is bonded, and the laser light source module array is divided into each laser light source module 500 at the PCB cutting position 700 using a circular saw blade 710, and each of the laser light source modules 500 The ± electrode pads 130 and 140 located on the lower surface are electrically coupled with each ± electrode pad disposed on the flexible substrate 1000 through the ACF film 800, and during the bonding, It is characterized in that predetermined heat and force are applied from the rear surface of the flexible board (1000).

In addition, in the system for transmitting the user's treatment rate to an external terminal using the patch-type rhinitis treatment device, the system includes: a laser light receiving module for receiving a laser beam reflected from the skin as a treatment monitoring unit; and a monitoring unit, wherein the treatment monitoring unit compares the energy of the entire laser beam emitted from the laser light source module 500 with the energy of the laser beam received from the laser light receiving module and emits the energy from the laser light source module 500. The treatment rate of the user is calculated by calculating the skin absorption rate of the laser beam, and the calculation result of the treatment rate is transmitted to a remotely located wireless terminal through a wireless transmission module according to the user's request.

As described above, the patch-type rhinitis treatment device according to the present invention has a laser light source module 500 attached to a flexible substrate 1000, and the flexible substrate 1000 has a patch shape, so that the user can apply the patch type to the bridge of the nose. It has the advantage of being able to attach and use the rhinitis treatment device conveniently and stably. In addition, the patch-type rhinitis treatment device according to the present invention is manufactured by its unique optical module manufacturing method to secure flexibility between the plurality of laser light source modules 500, minimizing discomfort between various users with different nose shapes. has the effect of

1 shows an embodiment of a conventional nose implantable laser rhinitis treatment device.
Figure 2 shows the appearance of a patch-type rhinitis treatment device according to an embodiment of the present invention.
3 shows one embodiment of a laser light source module 500 of the present invention.
FIG. 4 shows an embodiment of a laser light source module 500 having first and second via holes 110 and 120, +electrode pads 130, and -electrode pads 140.
5 shows an embodiment of an aspherical micro lens 400 included in the laser light source module 500 .
FIG. 6 shows an embodiment in which a vertical-cavity surface-emitting laser (VCSEL) chip is attached on the first layer 100, which is a PCB substrate.
7 shows an embodiment in which epoxy 610 is applied to each aspherical micro lens 400 and fixed to a lens fixing frame array having a plurality of lens fixing frames 600 .
FIG. 8 shows an embodiment in which an array type laser light source module 500 and a plurality of aspheric micro lenses 400 are bonded.
9 shows an embodiment of individually cutting the laser light source module 500 in the form of an array.
10 shows an embodiment in which the laser light source module 500 is attached on the flexible substrate 1000 using an ACF film 800 (anisotropic conductive film).
11 shows an embodiment of the patch-type rhinitis treatment device of the present invention in which the laser light source module 500 is attached on a flexible substrate 1000.
FIG. 12 shows an embodiment in which only the first laser light source module 510 is attached on the flexible substrate 1000 .
13 shows an embodiment in which each of the first laser light source module 510, the second laser light source module 520, and the third laser light source module 530 are alternately attached line by line on a flexible substrate 1000. do.
14 shows that a first laser light source module 510, a second laser light source module 520, and a third laser light source module 530 are attached to adjacent positions on a flexible substrate 1000 to form a group, and the group One embodiment arranged in the form of a line is shown.
Figure 15 shows an embodiment in which the user is equipped with the patch-type rhinitis treatment device of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The patch-type rhinitis treatment device of the present application,

flexible substrate 1000; and

A laser light source module 500, including a VCSEL chip 10 and an aspheric micro lens 400, and a first layer 100 to which the VCSEL chip 10 is attached, the VCSEL chip 10 and the aspheric micro lens 400 Consisting of a second layer 200 for securing a distance between the lenses 400 and supporting the aspheric microlenses 400 and a third layer 200 for inserting and fixing the aspheric microlenses 400, A laser light source module 500; and a plurality of the laser light source modules 500 are attached on the flexible substrate 1000.

1 shows an embodiment of a conventional nose implantable laser rhinitis treatment device. Referring to Figure 1, as a structure for inserting a conventional laser rhinitis treatment device into the nose, it can be seen that the structure should be continuously positioned in the nose using a hand or other additional configuration.

Figure 2 shows an embodiment of the patch-type rhinitis treatment device of the present invention. The patch-type rhinitis treatment device of the present invention can be attached in the form of a patch along the bridge of the nose as shown in FIG. 2 by bonding the laser light source module 500 on a flexible substrate 1000, so that In comparison, it is convenient to use. In addition, the patch-type rhinitis treatment device of the present application does not seal the nostrils because the laser light is irradiated to the back of the nose, so that it does not cause breathing difficulties or foreign body sensation that may occur when the user cannot breathe through the nose.

3 shows one embodiment of a laser light source module 500 of the present disclosure. The laser light source module 500 of the present application secures the focal distance between the first layer 100 for attaching the VCSEL chip 10, the VCSEL chip 10 and the aspheric micro lens 400, and the aspheric micro lens ( 400) for supporting a portion of the second layer 200, and a third layer 200 for inserting and fixing the aspheric micro lens 400.

FIG. 4 shows an embodiment in which the first layer 100 of the laser light source module 500 includes two via holes 110 and 120 and +/- electrode pads 130 and 140 . The VCSEL chip 10 is attached to one side of the first layer 100, and the ± electrode pads 130 and 140 attached to the other side of the first layer 100 form two via holes 110 and 120, respectively. is electrically coupled to the VCSEL chip 10 through

5 shows an embodiment of an aspherical micro lens 400 included in the laser light source module 500 . The aspherical micro lens 400 has a different curvature between an incident surface on which the laser emitted from the VCSEL chip 10 is incident and an emitting surface on which the laser passing through the lens is emitted. The laser emitted from the VCSEL chip 10 can be focused at a distance of 1 mm to 5 mm from the emitting surface of the aspheric micro lens 400, and the incident surface and the emitting surface of the aspheric micro lens 400 depend on the focal length. The curvature of can be changed. In addition, the VCSEL chip 10 may emit a laser beam according to a continuous wave (CW) laser, a manual pulse laser, an automatic pulse laser, or any combination thereof, as needed. Here, the continuous wave laser refers to a laser in which the laser beam is continuously and continuously generated without interruption, and the manual pulse laser refers to a laser in which the laser beam continues for a very short time in a pulse form only while a laser generation signal is input, and an automatic pulse laser A laser refers to a laser in which a laser beam is continuously generated in a pulsed form. In addition, the VCSEL chip 10 may individually generate beams of a first wavelength of 600 to 700 nm, a second wavelength of 700 to 810 nm, or a third wavelength of 810 to 1300 nm, and the laser light source module 500 may include a plurality of VCSEL chips 10 generating beams of respective wavelengths.

Hereinafter, a method of providing each laser light source module 500 and a patch-type rhinitis treatment device using the same will be described in detail with reference to the drawings.

6 shows an embodiment in which the VCSEL chip 10 is attached on the first layer 100, which is a PCB substrate. The VCSEL chip 10 is attached to the top of the first layer 100 of the laser light source module 500, and each electrode of the VCSEL chip 10 connects a wire connected to each electrode through wire bonding through via holes 110 and 120. ) to be connected to the electrode pads 130 and 140 of the laser light source module located on the lower surface of the laser light source module 500, respectively.

After that, as shown in FIG. 7, each aspherical micro lens 400 is fixed to a lens fixing frame array having a plurality of lens fixing frames 600, and epoxy is applied to the upper periphery of the aspheric micro lens 400. 610 is applied, and then, as shown in FIG. 8, the laser light source module 500 to which only the VCSEL chip 10 is attached is directed toward the aspherical micro lens 400 on the side to which the VCSEL chip 10 is attached. The aspheric micro lens 400 is attached to the laser light source module 500 by pressing the aspheric micro lens 400 to which the epoxy 610 is applied.

Subsequently, as shown in FIG. 9 , the laser light source module array 550 is cut from the PCB cutting position 700 to each laser light source module 500 using a cutting tool, for example, a circular saw blade 710. Divided.

After that, each of the divided laser light source modules 500, as shown in FIG. 10, is attached on the flexible substrate 1000 using the ACF film 800. During attachment, heat is applied from the rear surface of the flexible substrate 1000 to conduct the ACF film 800 so that each of the electrode pads 130 and 140 of the laser light source module 500 and each disposed on the flexible substrate 1000 electrically connect the electrodes of

In an exemplary embodiment, the laser light source module 500 includes a first laser light source module 510 emitting a beam with a wavelength of 600 to 700 nm and a second laser light source module 520 emitting a beam with a wavelength of 700 to 810 nm. , or a third laser light source module 530 emitting beams of 810 to 1300 nm wavelength.

As shown in FIG. 12, in one embodiment, only the first laser light source module 510 may be attached to the flexible substrate 1000 of the present application, and similarly, only the second laser light source module 520 may be attached there is. In addition, only the third laser light source module 530 may be attached to the flexible substrate 1000 of the present application.

In another embodiment, as shown in FIG. 13, the first laser light source module 510, the second laser light source module 520, and the third laser light source module 530 are formed on the flexible substrate 1000 in a line shape. may be arranged intersecting with .

In another embodiment, as shown in FIG. 14, the first laser light source module 510, the second laser light source module 520, and the third laser light source module 530 are attached in close proximity to form a group, The groups may be arranged at regular intervals on the flexible board 1000 .

The plurality of laser light source modules 500 are spaced apart and attached on the flexible substrate 1000 at regular intervals so that the laser light source modules 500 do not overlap each other when the flexible substrate 1000 is curved, Here, the intervals may be equal intervals or may not be equal intervals.

In another embodiment, it may further include a skin thickness measuring unit (not shown), wherein the skin thickness measuring unit includes: a near infrared ray irradiation module for radiating near infrared rays to the skin; a measurement module for measuring near-infrared rays reflected from each skin tissue (epidermis, dermis, and subcutaneous fat) among irradiated near-infrared rays; and a control module for controlling them. The skin thickness measuring unit may measure the skin thickness and classify the user's skin thickness into thin skin, normal skin, and thick skin. For example, the thin skin may have a thickness of less than 1 cm, the normal skin may have a thickness of 1 cm, and the thick skin may have a thickness of more than 1 cm.

In another embodiment, it may further include a skin color measurement unit (not shown), wherein the skin color measurement unit includes a photographing module, a conversion module, and a measurement module, and the skin color measurement unit measures the user's skin as yellow or dark. , classified as redness, and for each of them, the value is divided into high, medium, and low, that is, 01, 02, and 03. For example, if the output values from the skin color measuring unit are 03, 00, 00, it indicates that the skin contains a lot of yellowish tinge, but does not contain blackish tinge or reddish tinge at all, and the output value is 00, 03, If the value is 00, it indicates that the skin contains a lot of blackness, but does not contain yellowness or redness at all. If the output value is 00, 00, or 03, the skin contains a lot of redness, but does not contain yellowishness or blackness at all. indicates that If the output value is 03, 03, 03, it indicates that the skin contains a lot of yellow, black, and red.

The focal length of the laser beam emitted from the VCSEL chip 10 may be controlled according to the output values of the skin thickness measurement unit and the skin color measurement unit, and the first wavelength of the beam emitted from the VCSEL chip 10 , the second wavelength and the third wavelength and the continuous wave laser of the VCSEL chip 10, a manual pulse laser, an automatic pulse laser, or any combination thereof, etc. can also be controlled.

In another embodiment, a treatment monitoring unit for calculating a rate of absorption of a laser beam emitted from the laser light source module 500 into the skin and calculating a treatment rate of the user by the laser beam is further included, wherein the treatment monitoring unit calculates a skin absorption rate. and a laser light receiving module that receives the reflected laser beam, and calculates the user's treatment rate by comparing the energy of the entire laser beam emitted from the laser light source module 500 with the energy of the laser beam received from the laser light receiving module. do. The calculation result may be transmitted to a wireless terminal located remotely through a wireless transmission module according to a user's request.

10: VCSEL chip
100: first layer
110: first via hole
120: second via hole
130: of the laser light source module 500 - electrode pad
140: + electrode pad of the laser light source module 500
200: second layer
300: 3rd layer
400: aspheric lens
500: laser light source module
510: first laser light source module
520: second laser light source module
530: third laser light source module
550: laser light source module array
600: lens fixing frame
610: Epoxy
700: PCB cutting position
710: circular saw blade
800: ACF film
1000: flexible substrate

Claims (16)

In the patch-type rhinitis treatment device,
flexible substrate 1000; and
A laser light source module 500, including a VCSEL chip 10 and an aspheric micro lens 400, and a first layer 100 to which the VCSEL chip 10 is attached, the VCSEL chip 10 and the aspheric micro lens 400 Consisting of a second layer 200 for securing a distance between the lenses 400 and supporting the aspheric microlenses 400 and a third layer 200 for inserting and fixing the aspheric microlenses 400, Including; laser light source module 500,
A plurality of the laser light source modules 500 are attached on the flexible substrate 1000,
Patch-type rhinitis treatment device. According to claim 1,
The laser light source module 500 is at least one of the first laser light source module 510, the second laser light source module 520, or the third laser light source module 530,
Patch-type rhinitis treatment device. According to claim 2,
On the flexible substrate 1000, only the first laser light source module 510 is attached.
Patch-type rhinitis treatment device. According to claim 2,
On the flexible substrate 1000, only the second laser light source module 520 is attached,
Patch-type rhinitis treatment device. According to claim 2,
On the flexible substrate 1000, only the third laser light source module 530 is attached,
Patch-type rhinitis treatment device. According to claim 2,
The first laser light source module 510, the second laser light source module 520, and the third laser light source module 530 are attached to adjacent positions to form a group, and a plurality of the groups form a group on the flexible substrate 1000 ) attached to the
Patch-type rhinitis treatment device. According to claim 2,
The first, second, and third laser light source modules 510, 520, and 530 each include a laser beam of a first wavelength of 600 to 700 nm, a laser beam of a second wavelength of 700 to 810 nm, and a laser beam of a second wavelength of 810 to 1300 nm. Emitting a laser beam of 3 wavelengths,
Patch-type rhinitis treatment device. According to claim 7,
Each of the first, second, and third laser light source modules 510, 520, and 530 emits a laser beam according to a continuous wave laser, a manual pulse laser, an automatic pulse laser, or any combination thereof,
Patch-type rhinitis treatment device. According to claim 8,
The curvature of the incident surface of the laser beam and the curvature of the emission surface of the laser beam of the aspherical micro lens 400 are changed, so that the focal length of the aspheric micro lens 400 can be changed in the range of 1 mm to 5 mm,
Patch-type rhinitis treatment device. According to claim 9,
As a skin thickness measuring unit,
A near-infrared irradiation module for irradiating near-infrared rays to the skin;
a measurement module for measuring near-infrared rays reflected from each skin tissue among irradiated near-infrared rays; and
A control module for controlling them; including, skin thickness measuring unit; and
As a skin color measuring unit,
shooting module;
conversion module; and
A skin color measurement unit comprising a; measurement module;
the first, second and third wavelengths emitted from the VCSEL chip 10; a continuous wave laser emitted from the VCSEL chip 10, a manual pulse laser, an automatic pulse laser, or a laser according to any combination thereof; And the focal length of the aspherical micro lens 400 is controlled by the output values of the skin thickness measurement unit and the skin color measurement unit.
Patch-type rhinitis treatment device. A method for manufacturing a patch-type rhinitis treatment device according to any one of claims 1 to 10,
The laser light source module array 550 includes a plurality of the laser light source modules 500, and each of the plurality of the laser light source modules 500 includes a first layer 100 to which a VCSEL chip 10 is attached, and the VCSEL chip A second layer 200 for securing a distance between (10) and the aspheric microlens 400 and supporting the aspheric microlens 400 and a third layer 200 for inserting and fixing the aspheric microlens consists of,
A plurality of the aspherical micro lenses 400 are fixed to the lens fixing frame 600, epoxy 610 is applied to the rear surface of the plurality of micro lenses, and the VCSEL chip 10 of the laser light source module array 550 is The attached side surface is oriented toward the plurality of aspheric micro lenses 400 and compressed to bond the laser light source module array 550 and the plurality of aspheric micro lenses 400,
A method for manufacturing a patch-type rhinitis treatment device. According to claim 11,
The laser light source module array is divided into each laser light source module 500 at the PCB cutting position 700 using a circular saw blade 710,
A method for manufacturing a patch-type rhinitis treatment device. According to claim 12,
The ± electrode pads 130 and 140 located on the lower surface of each of the laser light source modules 500 are electrically coupled with each ± electrode pad disposed on the flexible substrate 1000 through the ACF film 800 (coupling),
A method for manufacturing a patch-type rhinitis treatment device. According to claim 13,
During the bonding, a predetermined heat and force are applied from the rear surface of the flexible substrate 1000,
A method for manufacturing a patch-type rhinitis treatment device. In the system for transmitting the user's treatment rate to an external terminal using the patch-type rhinitis treatment device according to any one of claims 1 to 10,
The system:
A treatment monitoring unit including a laser light receiving module for receiving a laser beam reflected from the skin as a treatment monitoring unit;
The treatment monitoring unit compares the energy of the entire laser beam emitted from the laser light source module 500 with the energy of the laser beam received from the laser light receiving module, and determines the skin absorption rate of the laser beam emitted from the laser light source module 500. Calculate the user's treatment rate by calculating
system. According to claim 15,
The calculation result of the treatment rate is transmitted to a wireless terminal located remotely through a wireless transmission module according to the user's request.
system.

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