KR20240001675A - Method for making contact lens emit far infrared rays, contact lens container and contact lens - Google Patents

Abstract

The present invention relates to a method of causing a contact lens to emit far-infrared rays, a contact lens container, and a contact lens. It solves the problem of the conventional far-infrared ray lens being less effective by maintaining a certain distance from the eye and the complicated manufacturing process and structure. You can. In the present invention, when a far-infrared material is coated on the container body of the contact lens container, an immersion liquid is placed in the accommodation space of the container body, and the contact lens is placed in the immersion liquid, the far-infrared material has a wavelength of 4 ㎛ to 14 ㎛. Far-infrared rays are emitted into the receiving space, and the contact lens absorbs the far-infrared rays and then emits far-infrared rays when taken out from the receiving space. According to the test, the far-infrared emissivity of the contact lens is between 0.70 and 0.91. Through this, contact lenses emit far-infrared rays and are closer to the eyes, improving health functions, and lowering the manufacturing process and structural difficulty, making it possible to achieve effects that are suitable and convenient to perform at home.

Description

Method for making contact lenses emit far infrared rays, contact lens container and contact lens {Method for making contact lens emit far infrared rays, contact lens container and contact lens}

The present invention relates to a method of causing a contact lens to emit far-infrared rays, a contact lens container, and a contact lens. In particular, a far-infrared material is coated on the container body of the contact lens container, so that the contact lens absorbs the far-infrared rays emitted by the far-infrared material. It relates to an invention that, after wearing, is close to the eye and can itself emit far-infrared rays with a wavelength between 4 ㎛ and 14 ㎛.

In recent years, people's awareness of their health has been increasing, and in addition to supplementing the nutrients the body needs with healthy foods, it is also leading the market for medical products that are beneficial to the human body. According to medical research, far-infrared rays with a wavelength in the range of 4 ㎛ to 14 ㎛ resonate with body molecules and have been confirmed to promote blood circulation, improve metabolism, and strengthen immunity. Far-infrared rays in that range are also the “light of life.” ” or “ray of life.”

Accordingly, Republic of China Patent Publication No. I293287 proposed a lens that emits far-infrared rays to the eyes and improves the health of the eyes and their surroundings. The invention uses materials with a far-infrared ray emission function, such as ceramic powder, and adds plastic-based polymers such as plasticizers and plastic ester granules to mix and dissolve them. After going through the mixing and manufacturing process, the materials are supplied to the injection molding machine. Mold filling, holding pressure, and extrusion demolding are performed, and further, a finished lens product with a far-infrared ray emission function is manufactured. Here, the ceramic powder can be more uniformly dispersed in the lens through the kneading manufacturing process, so that the lens has a high It creates a state of clairvoyance.

However, when injection molding is performed after mixing the ceramic powder that emits far-infrared energy with the lens raw material, if the mixing manufacturing process step is not performed or the ceramic powder ratio is not accurately controlled, the lens having the far-infrared radiation function may not be produced. The light transmittance is reduced, which blurs the user's line of sight after wearing it and affects walking safety. The manufacturing process steps and lens structure are relatively complex, and the lens and eye must maintain a certain distance, so far-infrared rays are healthy. The effectiveness for is relatively low.

Considering this, the present inventor proposes a method of making contact lenses emit far-infrared rays in order to improve eye health functions and reduce the complexity of the manufacturing process and structure.

A method according to one aspect of the present invention includes coating the container body with a far-infrared material; It includes the step of placing the immersion liquid and the contact lens in the receiving space of the container body; The far-infrared material emits far-infrared rays with a wavelength between 4 μm and 14 μm into the receiving space; Accordingly, after absorbing far-infrared rays, the contact lens emits far-infrared rays with a wavelength between 4 ㎛ and 14 ㎛ when taken out from the receiving space, and the far-infrared ray emissivity of the contact lens is between 0.70 and 0.91.

Here, the far-infrared material is coated on the inner surface and/or the outer surface of the container body.

Furthermore, the far-infrared material includes far-infrared powder and an adhesive, and the proportion of the far-infrared powder is between 5 wt% and 30 wt%, and the proportion of the adhesive is between 70 wt% and 95 wt%.

Here, the far-infrared powder is one or a combination of ceramic powder, bamboo charcoal powder, tourmaline powder, germanium powder, titanium powder, graphene powder, nano copper powder, cordierite powder, and mullite powder.

Here, the adhesive is a natural resin, an artificial resin, or a combination of the natural resin and the artificial resin.

Here, the time for placing the contact lens in the receiving space is between 4 hours and 24 hours.

Furthermore, when the contact lens is placed in the receiving space, the container body is maintained at a default temperature between 40°C and 80°C.

Furthermore, before or after coating the container body with the far-infrared material, the container body and the energy material are placed together in a heating space with a temperature of 35°C to 90°C for 2 to 24 hours.

Here, the energy material is one or a combination of elvanite, spar, granite, tourmaline, serpentine, dolomite, bamboo charcoal mineral, carbonate, and titanium hertz energy stone.

Here, the immersion solution is a contact lens tonic or a drug specifically for contact lenses.

The present inventor also proposes a contact lens container, comprising: a container body having a corresponding receiving space; It includes the far-infrared material coated on the container body; The far-infrared material emits far-infrared rays with a wavelength between 4 μm and 14 μm into the receiving space.

Here, the container body is a personal contact lens storage case or contact lens storage box.

The present invention also proposes a contact lens that emits far-infrared rays, which is manufactured by a method that causes the contact lens to emit far-infrared rays.

Furthermore, the contact lenses further add an ultraviolet absorber to allow the contact lenses to block ultraviolet radiation.

Furthermore, the contact lens further adds a Blu-ray absorber so that the contact lens blocks Blu-ray radiation.

Here, the light transmittance of the contact lens is 90% or more.

Here, the contact lenses in question are colored or transparent.

Here, the contact lenses are for 1 day, 1 month, 3 months or 1 year.

The following effects can be achieved by the above technical features.

1. The container body is coated with a far-infrared material, and the far-infrared material can emit far-infrared rays. As a result, the contact lens placed in the container body emits far-infrared rays that are beneficial to the human body with a wavelength between 4 ㎛ and 14 ㎛ when taken out from the receiving space. The average far-infrared emissivity of contact lenses is 0.86, and the maximum emissivity is 0.91.

2. When you are not wearing contact lenses, simply place them in the container body containing the immersion liquid. The container body is already coated with far-infrared ray material, so not only is moisturizing and antibacterial possible through the immersion liquid, but the contact lenses also have the effect of emitting far-infrared rays. The implementation process is simple and time-saving, and conforms to the operator's daily usage habits.

3. When the user wears contact lenses that emit far-infrared rays, the contact lenses come close to the eyeball, improving the health function of the eye area, and promoting oxygen supply and blood circulation around the eyes, effectively improving and preventing eye disease problems. .

4. When the energy material and the container body are placed in a heating space for a certain period of time, the container body strengthens the far-infrared ray emission and improves the far-infrared ray absorption effect of the contact lens.

5. Contact lenses with added UV absorbers and Blu-ray absorbers protect the eyes when worn and prevent them from being damaged by UV rays and Blu-rays. Here, they can block more than 95% of UV rays with a wavelength between 280 nm and 315 nm. .

6. Contact lenses that emit far-infrared rays do not contain any far-infrared materials, so the light transmittance can reach over 90% without affecting the line of sight after wearing.

7. Regardless of whether the contact lenses are transparent, tinted, colored, 1 day, 1 month, 3 months or 1 year, all types of contact lenses can emit far infrared rays through the container body coated with far infrared material.

1 is a three-dimensional external view of the container body of the present invention.
Figure 2 is a manufacturing flow chart of the present invention.
Figure 3 is a view showing the energy material of the present invention and the container body located in a heating space.
Figure 4 is a step flowchart of the first implementation method of the present invention.
Figure 5 is a step flowchart of the second implementation method of the present invention.
Figure 6 is a diagram showing the relationship between the far-infrared emissivity and wavelength of the contact lens emitting far-infrared rays of the present invention.
Figure 7 is a diagram showing the relationship between the far-infrared ray emissivity and wavelength of a typical conventional contact lens.

In summary of the above technical features, the method of causing the contact lens of the present invention to emit far-infrared rays, the contact lens container, and the main effects of the contact lens will become clearer through the following examples.

Referring first to Figures 1 and 2, which show a method of causing the contact lens of an embodiment of the present invention to emit far-infrared rays, a contact lens container, and a contact lens, including a container body (1), a far-infrared material (2), and immersion. Comprising a liquid (3) and a contact lens (4), wherein the container body (1) has a receiving space (11), an inner surface (12) and an outer surface (13), and the far-infrared material (2) ) includes an adhesive 21 and a far-infrared powder 22, and the inner surface 12 and/or the outer surface 13 of the container body 1 are coated with the far-infrared material 2, After pouring the immersion liquid into the receiving space 11, the contact lens 4 is placed. This embodiment coats the far-infrared material 2 on both the inner surface 12 and the outer surface 13.

Specifically, the container body 1 is a personal contact lens storage case or contact lens storage box; The proportion of the adhesive 21 is between 70 wt% and 95 wt%, the proportion of the far-infrared powder 22 is between 5 wt% and 30 wt%, and the adhesive 21 is a semi-solid or secreted from animals or plants. It is a natural resin made of solid organic colloids or an artificial resin produced by artificial synthesis. The far-infrared powder 22 emits far-infrared ray emission energy such as one or a combination of ceramic powder, bamboo charcoal powder, tourmaline powder, germanium powder, titanium powder, graphene powder, nano copper powder, cordierite powder, and mullite powder. It is a powder manufactured by grinding a powder or material, but is not limited thereto; The immersion liquid (3) is a contact lens tonic solution or a contact lens-specific drug for moisturizing, cleaning, and sterilizing contact lenses; The contact lens 4 may be a colored or transparent contact lens for 1 day, 1 month, 3 months, or 1 year with a light transmittance of 90% or more, and furthermore, the contact lens 4 may be exposed to ultraviolet rays and Blu-ray radiation. An ultraviolet absorber and a blue-ray absorber are added to block, where the effect of blocking ultraviolet rays with a wavelength between 315 nm and 380 nm reaches 50% or more, and the effect of blocking ultraviolet rays with a wavelength between 280 nm and 315 nm is achieved. It reaches more than 95%.

2 to 4, this shows a first embodiment of the present invention, wherein the energy material 5 and the container body 1 are first heated at a temperature of 35°C to 90°C. After being placed together in the heating space 6 between °C for 2 to 24 hours, the far-infrared powder 22 is again applied to the inner surface 12 and the outer surface 13 of the container body 1 with an adhesive ( Coat using 21). The energy material (5) is one of ores or energy stones with far-infrared emission energy, such as one or a combination of elvanite, spar, granite, tourmaline, serpentine, dolomite, bamboo charcoal mineral, carbonate, titanium Hertz energy stone, or A combination of these, but is not limited to this.

2, 3 and 5, this shows a second embodiment of the present invention, through which the inner surface 12 and the outer surface 13 of the container body 1 are first formed. ), the far-infrared powder 22 is coated using an adhesive 21, and then the container body 1 and the energy material 5 coated with the far-infrared material 2 are heated at a temperature of 35°C. Place them together in a heating space (6) at a temperature between 2 and 90°C for 2 to 24 hours. As in the first embodiment described above, the energy material 5 emits far-infrared rays, such as one or a combination of elvanite, spar, granite, tourmaline, serpentine, dolomite, bamboo charcoal mineral, carbonate, and titanium Hertz energy stone. One or a combination of ore or energy stone with energy may be used, but is not limited thereto.

After performing the first or second implementation method, the immersion liquid (3) is placed in the receiving space (11) of the container body (1), and then the contact lens (4) is placed again, In addition, the far-infrared material (2) coated on the container body (1) emits far-infrared rays with a wavelength between 4 ㎛ and 14 ㎛ into the receiving space (11), and the contact lens (4) emits far-infrared rays (2) coated on the container body (1). ) is immersed in the coated container body 1 and maintained at a default temperature of 40°C to 80°C for a period between 4 hours and 24 hours, the contact lens 4 absorbs the corresponding far-infrared rays, After the contact lens 4 is taken out of the receiving space 11, far-infrared rays with a wavelength between 4 μm and 14 μm may be emitted by the contact lens 4 itself.

Referring to Figures 6 and 7, this shows the far-infrared emissivity and wavelength relationship of the contact lens 4 of the present invention and a conventional general contact lens. In addition, referring to Figure 2, the present invention as a whole shows the container body (1) is coated with the far-infrared material (2), and the immersion liquid (3) is placed in the receiving space (11) of the container body (1) to contain the contact lens (4), and the contact lens (4) can be contained. (4) forms the contact lens container capable of absorbing the far-infrared rays, so that when the contact lens 4 is taken out of the receiving space 11, the far-infrared rays having a wavelength between 4 μm and 14 μm are emitted; , Also at a temperature of 40° C., the far-infrared emissivity of the contact lens 4 is between 0.70 and 0.91, and the overall average emissivity is 0.86; Conventional contact lenses that emit far-infrared rays without carrying out the present invention can only emit far-infrared rays with a wavelength between 6 ㎛ and 14 ㎛, and at the same temperature of 40 ° C, the far-infrared emissivity of the conventional contact lenses is is only between 0.76 and 0.79, with an overall average emissivity of 0.78. According to experiments, the method of causing the contact lens of the present invention to emit far infrared rays, the contact lens container and the contact lens effectively enable a common contact lens to be converted into the contact lens 4 emitting far infrared rays, and the contact lens Moreover, the maximum emissivity of the far-infrared rays in (4) can reach 0.91, which improves the eye health function close to the eyes after wearing, and is also easy to implement and has an effect suitable for all users.

Summarizing the description of the above embodiments, the present invention has been shown and described with respect to specific embodiments above, but the present invention is not limited to the above-described embodiments, and those skilled in the art It may be implemented with various changes without departing from the gist of the technical idea of the present invention as set forth in the claims below.

1. Container body
2: Far infrared material
3: Immersion liquid
4: Contact lenses
5: Energy materials
6: Heating space
11: Accommodation space
12: inner surface
13: outer surface
21: Adhesive
22: Far infrared powder

Claims (18)

In a method of causing a contact lens to emit far infrared rays,
coating the container body with a far-infrared material;
It includes the step of placing the immersion liquid and the contact lens in the receiving space of the container body,
The far-infrared material emits far-infrared rays with a wavelength between 4 ㎛ and 14 ㎛ into the receiving space, so that the contact lens absorbs the far-infrared rays and then emits far-infrared rays with a wavelength between 4 ㎛ and 14 ㎛ when taken out from the receiving space. A method of causing a contact lens to emit far-infrared rays, characterized in that the far-infrared emissivity of the contact lens is between 0.70 and 0.91. According to paragraph 1,
A method of causing a contact lens to emit far-infrared rays, characterized in that the far-infrared material is coated on at least one of the inner surface and the outer surface of the container body. According to paragraph 1,
The far-infrared material includes far-infrared powder and an adhesive, and the proportion of the far-infrared powder is between 5 wt% and 30 wt%, and the proportion of the adhesive is between 70 wt% and 95 wt%. A method of emitting far-infrared rays. According to paragraph 3,
The far-infrared powder is a contact lens, characterized in that it is one or a combination of ceramic powder, bamboo charcoal powder, tourmaline powder, germanium powder, titanium powder, graphene powder, nano copper powder, cordierite powder, and mullite powder. A method of emitting far-infrared rays. According to paragraph 3,
A method of causing a contact lens to emit far infrared rays, wherein the adhesive is a natural resin, an artificial resin, or a combination of the natural resin and the artificial resin. According to paragraph 1,
A method of causing a contact lens to emit far infrared rays, characterized in that the time for placing the contact lens in the receiving space is between 4 hours and 24 hours. According to paragraph 1,
A method of causing a contact lens to emit far infrared rays, characterized in that the container body maintains a default temperature between 40°C and 80°C when the contact lens is placed in the receiving space. According to paragraph 1,
Contact lenses, characterized in that the container body and the energy material are placed together in a heating space with a temperature of 35°C to 90°C for 2 to 24 hours before or after coating the container body with the far-infrared material. A method of emitting far-infrared rays. According to clause 8,
A method of causing a contact lens to emit far-infrared rays, wherein the energy material is one or a combination of elvan stone, spar, granite, tourmaline, serpentine, dolomite, bamboo charcoal mineral, carbonate, and titanium Hertz energy stone. According to paragraph 1,
A method of causing a contact lens to emit far-infrared rays, wherein the immersion solution is a contact lens tonic or a drug specifically for contact lenses. In the contact lens container for carrying out the method of causing the contact lens of any one of claims 1 to 10 to emit far infrared rays,
The container body having the accommodation space,
It includes the far-infrared material coated on the container body;
A contact lens container, characterized in that the far-infrared material emits far-infrared rays with a wavelength between 4 μm and 14 μm into the receiving space. According to clause 11,
A contact lens container, wherein the container body is a personal contact lens storage case or contact lens storage box. A far-infrared ray-emitting contact lens manufactured by a method such that the contact lens according to any one of claims 1 to 10 emits far-infrared rays. According to clause 13,
The contact lens is a far-infrared ray-emitting contact lens, characterized in that it further contains an ultraviolet absorber to resist ultraviolet rays. According to clause 13,
The contact lens is a far-infrared ray-emitting contact lens, characterized in that it further contains a Blu-ray absorber to block Blu-ray radiation. According to clause 13,
A far-infrared ray-emitting contact lens, characterized in that the contact lens has a light transmittance of 90% or more. According to clause 13,
The contact lens is a far-infrared ray-emitting contact lens, characterized in that it is colored or transparent. According to clause 13,
The contact lens is a far-infrared ray-emitting contact lens, characterized in that it is for 1 day, 1 month, 3 months, or 1 year.