JP2018189711A - Smart glass for augmented reality - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a protection shade for eyes of a smart glass for augmented reality.SOLUTION: A protection shade for eyes of a smart glass for augmented reality comprises mainly, a protection unit for eyes, and shade parts for shading provided on both sides thereof are provided to correspond to a front surface of a translucent display part on each of both sides of the smart glass, and changes to partial transparent or complete opacity with respect to the external part. On a constant area of the surrounding of the shade part, a convex lens is installed, size of an area of the convex lens is not restricted, as a user can clearly visually recognize the surrounding environment, there is no problem. Therefore, under any light source, by browsing by combining the protection unit for eyes to the smart glass for augmented reality, both eye balls and yellow parts are protected from light, and the surrounding retinas are brought into contact with an external light source continuously, and a user can clearly visually recognize the surrounding environment. For browsing and reading, a browsing and reading method of a human being is changed, and fatigue on eyes is reduced.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an eye protection shade for augmented reality smart glasses, and more particularly, an eye protection unit is installed in front of the augmented reality smart glasses to avoid eye fatigue during use and to reduce myopia. This is related to augmented reality smart glass eye protection shades that prevent people from altering their reading habits.

  According to the ophthalmology community, today, people often work with their eyes close to objects, so they spend less time outside and more time watching TVs, computers, mobile phones, etc. 1. The ciliary muscle is contracted for a long time. 2. The medial rectus muscle is contracted for a long time. 3. The field of view is narrow. Insufficient time to contact sunlight is one of the four major causes of myopia and eye strain. In addition, it is one of the factors that cause relative peripheral hyperopia in students whose myopia persisted and deteriorated.

US Patent Publication No. US6042231A US Patent Publication No. US6533417B1 US Patent Publication No. US20120236256A1 Chinese Patent Publication No. CN102499863A Chinese Patent Publication No. CN200939208Y

  The eye of an uncorrected myopic person should be in the center of the retina (macular area), but the object image from a distance should be in front of the retina, and the surrounding retina is behind the retina. This is called target peripheral hyperopia. Conventional myopia glasses correct the central retinal part and move the focus of the image backward to position it in the macular part, but the relative hyperopia of the peripheral retina is not corrected. If the light rays are outside the retina, the eyeball tends to be long and large, and the light rays are collected on the retina, making myopia more serious.

  In addition, when a person watches a book, a mobile phone, a TV, etc., the human eye actively looks for the screen. When the distance to the screen is within 6 meters, the ciliary muscle contracts, and the closer it is, the stronger the contraction is. The eye fatigue increases, and the longer the time, the higher the possibility of myopia.

  When a person views a single screen of a book, a personal computer, a television, etc. with both eyes, both eyes become a crossed eye, and the crossed eye is a result of contraction of the medial rectus muscle. Constriction of the medial rectus muscle for a long time causes eye strain and an increase in the internal pressure of the eye. As the internal pressure of the eye increases, the posterior pole portion of the eyeball is expanded backward to become myopic.

  As shown in FIG. 11, the neck is stiffened when the head is read for a long time and fixed.

  Situations such as looking at books or computers or sitting for long periods of time can easily cause cardiovascular disease and muscle and skeletal weakness problems.

  When people read or work indoors for most of the time, there is a danger that the distance between eyes and objects will be close, the field of view will be narrowed, contact with sunlight will be insufficient, eyes will soon fatigue and myopia There is sex.

  When viewing books, mobile phones, personal computers, etc., regardless of whether they are indoors or outdoors, the eyes become tired due to the interference of refraction and reflection of the surrounding light sources.

  For example, in a transportation system such as a train or car that is in operation, if the vehicle vibrates, the screen of the mobile phone and the vibration of the eyes do not synchronize and become unstable and difficult to read. Causes fatigue.

In recent decades, there are already many eye training methods and therapeutic devices for vision enhancement in the prior art. Some use electronic imaging techniques to train the ciliary muscles of the eye of a trainee by changing the image. Some use the machine movement method to allow the trainee to achieve the purpose of training the ciliary muscles by gazing at objects that change in perspective.
For example, Patent Document 1 describes a method for training eye muscles using an image on a personal computer screen. Further, Patent Document 2 describes a method of taking a strain on the eye muscles by relaxing an eye by pressing an image that moves in a specific manner on a screen of a personal computer and changing its moving position and size. In addition, there are various glasses specially manufactured for preventing myopia, for example, Patent Document 3. Furthermore, for example, the method for reducing eye strain described in Patent Document 4 and the electronic eyesight enhancer described in Patent Document 5 can be mentioned. These conventional training methods and treatment instruments have universal drawbacks. It has a complicated structure, a long operation time, a tedious treatment process, an inconvenient application, and a poor effect.

  Therefore, the present inventor considered that the above-mentioned drawbacks can be improved, and as a result of intensive studies, the present inventor has arrived at a proposal of the present invention that effectively improves the above-described problems by rational design.

  The present invention has been made in view of such conventional problems. In order to solve the above problems, an object of the present invention is to provide an eye protection shade of augmented reality smart glasses.

  In order to solve the above-described problems and achieve the object, the augmented reality smart glasses eye protection shade according to the present invention mainly comprises an eye protection unit installed in front of the augmented reality smart glasses. The shade portions provided on both sides correspond to the translucent display portions on both sides of the augmented reality smart glass and change partially transparent or completely opaque to the outside. In addition, a convex lens is installed in a certain area around the shade portion, and the light rays of the display portion are condensed on the macular portion and the light rays around the display portion are condensed in the retina. The size of the convex lens region is not limited, and it is sufficient that the user can clearly see the surrounding environment. Persons who are prone to myopia and those who are already myopic can reduce the deterioration of myopia by using a convex lens eye protection unit. The power of the convex lens may be any number of times as long as the relative peripheral hyperopia can be changed to peripheral myopia.

  As a result, the eyeball and the macula of both eyes are protected from light by protecting the eyeball and the macula of both eyes by browsing the augmented reality smart glasses with the eye protection unit under any light source, and the surrounding retina is continuously protected from the outside world. The user can see the surrounding environment clearly. When reading, the head and neck can be freely rotated. Can be read while moving. The tension of the ciliary muscle and the medial rectus muscle is released. Can change people's reading habits.

  When reading using an augmented reality smart glass equipped with an eye protection shade according to the present invention, the following four major causes of myopia can be overcome when using an eye protection unit without a convex lens. 1. 1. Ciliary muscle contracts for a long time. 2. Both eyes are crossed for a long time. 3. The field of view is too narrow. The contact time with sunlight is insufficient. In addition, when an eye protection unit using a convex lens is used, other causes of myopia deterioration 5. Can overcome relative peripheral hyperopia.

The present invention has the following advantages in application.
When the eye protection shade according to the present invention is browsed in combination with a smart glass having two display parts,
1. As shown in FIG. 6, the screen of the personal computer is actively projected onto the retina, and the retina passively receives the screen. This process is purely an optical physical action, has no physiological action, the ciliary muscle does not contract, and the tension is released.
2. As shown in FIG. 5, a smart glass having two display parts has a display part in front of each eyeball, and each eyeball visually observes each display part. Muscles do not contract, eye pressure does not increase, and myopia worsens.
3. As shown in FIG. 10, the neck can be freely rotated during reading, and it is not necessary to look at the book by fixing the head in a bald state, thereby preventing the neck from becoming stiff.
4). Can be read while moving. Because the smart glasses and the eyes vibrate synchronously, the screen becomes stable and easy to see. Reading while moving for a long time has a great effect on health, and at the same time prevents cardiovascular disease caused by sitting and moving for a long time.
5. It can be used outdoors. The eyeball and the macula are shielded and protected by the light-shielding plate, and are not affected by the refraction or reflection of sunlight and other light sources during reading.
6). In the eye protection unit according to the present invention, the remaining part other than the shade part is kept transparent, so that the field of view in the outdoor area reaches 180 degrees. Further, contact with an appropriate amount of sunlight every day for 2-3 hours reduces myopia deterioration. The wider the field of view, the more comfortable it is for the human eye.
7). Big screen. When viewed using the present invention, the screen becomes larger as the distance increases. Taking a viewing angle of 23 ° as an example, the screen becomes 160 inches at a distance of 10 meters, and the screen becomes 320 inches at a distance of 20 meters.
8). Not affected by vibration. Because the smart glasses and eyes vibrate synchronously, even when used in transportation, for example, in cars or trains, the screen is stably held so that the screen can be clearly seen. I'm not tired.
9. Change human education system. Augmented reality smart glasses with two display units can display 2D and 3D images and videos, making learning more enjoyable and easier to understand when used in the educational field.

It is an exploded view showing a preferred embodiment of the present invention. FIG. 3 is a combination diagram in which the present invention is connected to a host. It is the combination figure by which the eye protection unit of this invention is arrange | positioned at a convex lens. It is the combination figure where the convex lens of the present invention is connected to a host. It is the schematic which an eye does not condense when using this invention. When using this invention, it is the schematic by which the image of a display part is directly projected on a retina. When the present invention uses a convex lens, it is a schematic diagram in which the retina around the eyeball comes into contact with sunlight. When the present invention uses a convex lens, it is the schematic which changes peripheral hyperopia to peripheral myopia. It is an application example of the outdoor education of this invention. It is an application example of the normal posture of the present invention. This is an example of looking down at a mobile phone.

  Preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below do not limit the contents of the present invention described in the claims. In addition, all of the configurations described below are not necessarily essential requirements of the present invention.

The eye protection shade of the augmented reality smart glass according to the present invention mainly includes the eye protection unit 2 installed on the front surface of the augmented reality smart glass 1, and the shade portions 21 for light shielding provided on both sides thereof are as follows. This corresponds to the translucent display portions 10 on both sides of the augmented reality smart glass 1.
In practice, the shade part 21 of the eye protection unit 2 is manufactured by selecting different materials, and the semi-transparent display parts 10 on both sides of the smart glass 1 change partially transparent or completely opaque to the outside. In addition, the convex lens 3 is installed in a certain area around the shade portion 21. The size of the area of the convex lens 3 is not limited, and it is sufficient that the user can clearly see the surrounding environment. The power of the convex lens 3 may be any number as long as the relative peripheral hyperopia changes to peripheral myopia (see FIGS. 1 to 5).

  More specifically, the augmented reality smart glass 1 includes a host 11 or a conventional smartphone (not shown) connected to each other by transmitting information in a wired or wireless manner, and prescription glasses 14 of a user. ) And a frame unit 12. Lenses 13 are installed on both sides of the frame unit 12, and the translucent display unit 10 is provided on the lenses 13 on each side.

  The eye protection unit 2 is a lens and is installed in front of the lens 13 of the augmented reality smart glass 1. The eye protection unit 2 further includes a light transmission part 22 provided in a region other than the eye protection unit shade part. The two light-shielding shade portions 21 that are provided separately correspond to the semi-transparent display portions 10 on both sides of the lens 13 of the augmented reality smart glass 1, and change them partially transparent or completely opaque. .

  A convex lens 3 is installed in a certain area around the shade portion 21. There is no restriction | limiting in the magnitude | size of the area | region of the convex lens 3, and the user should just be able to visually recognize the surrounding environment clearly. Myopia and those who are already myopic can reduce the tendency of myopia to deteriorate by using the eye protection unit 2 having the convex lens 3. The power of the convex lens 3 may be any number, and it is preferable that the relative peripheral hyperopia changes to peripheral myopia.

  In a preferred embodiment, the eye protection unit 2 is integrally formed on the augmented reality smart glass 1 (not shown) or installed as an independent plate and is movably coupled to the augmented reality smart glass 1. (See figure).

A specific method for adding the eye protection unit 2 to the augmented reality smart glass 1 is as follows.
1) In the manufacturing process, the translucent display unit 10 directly becomes a completely opaque display unit, thereby simultaneously forming a shade unit, and the above-described eye protection unit 2 is configured. Further, the convex lens 3 is installed in a certain area around the shade portion 21, and the size of the area of the convex lens 3 is not limited, and it is sufficient that the user can clearly see the surrounding environment.
2) A light shielding plate is added in front of the translucent display unit 10 of the conventional augmented reality smart glass to form the eye protection unit 2. Further, the convex lens 3 is installed in a certain area around the shade portion 21, and the size of the area of the convex lens 3 is not limited, and it is sufficient that the user can clearly see the surrounding environment.
3) As shown in FIG. 4, a person who is already myopic uses the convex lens 3. The convex lens 3 and the eye protection unit 2 are combined into one, or are added to the front surface of the eye protection unit 2 (the shape and size are not limited to those in the drawing).

  As shown in FIG. 6, in the case of reading by applying the present invention, the augmented reality smart glass 1 has a translucent display unit 10 about 2 cm in front of the eye so that the screen displayed on the personal computer is displayed on the retina. Directly projected. At this time, the ciliary muscle does not contract, and the tension is relaxed.

  As shown in FIG. 7, when digital information is read by combining the eye protection unit 2 and the convex lens 3 with the smart glass 1 according to the present invention, the eyeballs and the macula of both eyes are shielded and protected mainly, and the peripheral retina is protected. The portion has a feature of continuously contacting an external light source, and the user can clearly see the surrounding environment.

  As shown in FIG. 8, when the convex lens 3 is used, first, the peripheral light rays are collected on the broken line portion outside the retina, and are corrected as indicated by the solid line in the drawing to enter the retina. That is, relative peripheral hyperopia changes to peripheral myopia.

  As shown in FIG. 5, when reading by applying the present invention, each has a translucent display unit 10 in front of the left and right eyes, so when viewing each display unit with the left and right eyes, There is no need to look inward and the rectus medial muscles do not contract.

  The present invention simplifies the overall design, is convenient to carry, and can be used in combination with the augmented reality smart glass 1 in a simple manner.

  As shown in FIGS. 2, 4 and 9, in a more specific application, the reading system 40 is constructed in the host 11 or cloud of the augmented reality smart glass 1 according to the present invention. The content includes various subjects such as various subject classes, such as national language, nature, English, geography, geography, history, civil, physics, chemistry, health education, art, and music. However, it is not limited to these.

  By the way, when the present invention is universally adopted in schools, most teaching materials substitute text descriptions with 2D and 3D images or videos, so that the fun of learning increases and the learning effect also improves.

  The above-described embodiments are merely for explaining the technical idea and features of the present invention, and are intended to allow those skilled in the art to understand the contents of the present invention and to carry out the same with the present invention. It is not intended to limit the scope of the claims. Accordingly, improvements or modifications having various similar effects made without departing from the spirit of the present invention shall be included in the following claims.

DESCRIPTION OF SYMBOLS 1 Smart glass 2 Eye protection unit 21 Shade part 10 Display part 11 Host 12 Frame unit 13 Lens 14 Glasses with user's degree 22 Light transmission part 3 Convex lens 40 Reading system

The present invention relates to augmented reality smart Gras scan, and more particularly, eye protection unit is installed in front of the smart glass augmented reality, to avoid eye fatigue during use, from myopia worse prevent, about the augmented reality of the smart glass vinegar alter the reading habits of people.

  According to the ophthalmology community, today, people often work with their eyes close to objects, so they spend less time outside and more time watching TVs, computers, mobile phones, etc. 1. The ciliary muscle is contracted for a long time. 2. The medial rectus muscle is contracted for a long time. 3. The field of view is narrow. Insufficient time to contact sunlight is one of the four major causes of myopia and eye strain. In addition, it is one of the factors that cause relative peripheral hyperopia in students whose myopia persisted and deteriorated.

US Patent Publication No. US6042231A US Patent Publication No. US6533417B1 US Patent Publication No. US20120236256A1 Chinese Patent Publication No. CN102499863A Chinese Patent Publication No. CN200939208Y

  The eye of an uncorrected myopic person should be in the center of the retina (macular area), but the object image from a distance should be in front of the retina, and the surrounding retina is behind the retina. This is called target peripheral hyperopia. Conventional myopia glasses correct the central retinal part and move the focus of the image backward to position it in the macular part, but the relative hyperopia of the peripheral retina is not corrected. If the light rays are outside the retina, the eyeball tends to be long and large, and the light rays are collected on the retina, making myopia more serious.

  In addition, when a person watches a book, a mobile phone, a TV, etc., the human eye actively looks for the screen. When the distance to the screen is within 6 meters, the ciliary muscle contracts, and the closer it is, the stronger the contraction is. The eye fatigue increases, and the longer the time, the higher the possibility of myopia.

  When a person views a single screen of a book, a personal computer, a television, etc. with both eyes, both eyes become a crossed eye, and the crossed eye is a result of contraction of the medial rectus muscle. Constriction of the medial rectus muscle for a long time causes eye strain and an increase in the internal pressure of the eye. As the internal pressure of the eye increases, the posterior pole portion of the eyeball is expanded backward to become myopic.

  As shown in FIG. 11, the neck is stiffened when the head is read for a long time and fixed.

  Situations such as looking at books or computers or sitting for long periods of time can easily cause cardiovascular disease and muscle and skeletal weakness problems.

  When people read or work indoors for most of the time, there is a danger that the distance between eyes and objects will be close, the field of view will be narrowed, contact with sunlight will be insufficient, eyes will soon fatigue and myopia There is sex.

  When viewing books, mobile phones, personal computers, etc., regardless of whether they are indoors or outdoors, the eyes become tired due to the interference of refraction and reflection of the surrounding light sources.

  For example, in a transportation system such as a train or car that is in operation, if the vehicle vibrates, the screen of the mobile phone and the vibration of the eyes do not synchronize and become unstable and difficult to read. Causes fatigue.

In recent decades, there are already many eye training methods and therapeutic devices for vision enhancement in the prior art. Some use electronic imaging techniques to train the ciliary muscles of the eye of a trainee by changing the image. Some use the machine movement method to allow the trainee to achieve the purpose of training the ciliary muscles by gazing at objects that change in perspective.
For example, Patent Document 1 describes a method for training eye muscles using an image on a personal computer screen. Further, Patent Document 2 describes a method of taking a strain on the eye muscles by relaxing an eye by pressing an image that moves in a specific manner on a screen of a personal computer and changing its moving position and size. In addition, there are various glasses specially manufactured for preventing myopia, for example, Patent Document 3. Furthermore, for example, the method for reducing eye strain described in Patent Document 4 and the electronic eyesight enhancer described in Patent Document 5 can be mentioned. These conventional training methods and treatment instruments have universal drawbacks. It has a complicated structure, a long operation time, a tedious treatment process, an inconvenient application, and a poor effect.

  Therefore, the present inventor considered that the above-mentioned drawbacks can be improved, and as a result of intensive studies, the present inventor has arrived at a proposal of the present invention that effectively improves the above-described problems by rational design.

The present invention has been made in view of such conventional problems. For the above problems solved, the present invention aims at providing a smart Gras scan of augmented reality.

  In order to solve the above-described problems and achieve the object, the augmented reality smart glasses eye protection shade according to the present invention mainly comprises an eye protection unit installed in front of the augmented reality smart glasses. The shade portions provided on both sides correspond to the translucent display portions on both sides of the augmented reality smart glass and change partially transparent or completely opaque to the outside. In addition, a convex lens is installed in a certain area around the shade portion, and the light rays of the display portion are condensed on the macular portion and the light rays around the display portion are condensed in the retina. The size of the convex lens region is not limited, and it is sufficient that the user can clearly see the surrounding environment. Persons who are prone to myopia and those who are already myopic can reduce the deterioration of myopia by using a convex lens eye protection unit. The power of the convex lens may be any number of times as long as the relative peripheral hyperopia can be changed to peripheral myopia.

  As a result, the eyeball and the macula of both eyes are protected from light by protecting the eyeball and the macula of both eyes by browsing the augmented reality smart glasses with the eye protection unit under any light source, and the surrounding retina is continuously protected from the outside world. The user can see the surrounding environment clearly. When reading, the head and neck can be freely rotated. Can be read while moving. The tension of the ciliary muscle and the medial rectus muscle is released. Can change people's reading habits.

When reading using an augmented reality smart glass equipped with an eye protection shade according to the present invention, the following four major causes of myopia can be overcome when using an eye protection unit without a convex lens.
1. 1. Ciliary muscle contracts for a long time. 2. Both eyes are crossed for a long time. The field of view is too narrow,
4). The contact time with sunlight is insufficient. In addition, when an eye protection unit using a convex lens is used, other causes of myopia deterioration 5. Can overcome relative peripheral hyperopia.

The present invention has the following advantages in application.
When the eye protection shade according to the present invention is browsed in combination with a smart glass having two display parts,
1. As shown in FIG. 6, the screen of the personal computer is actively projected onto the retina, and the retina passively receives the screen. This process is purely an optical physical action, has no physiological action, the ciliary muscle does not contract, and the tension is released.
2. As shown in FIG. 5, a smart glass having two display parts has a display part in front of each eyeball, and each eyeball visually observes each display part. Muscles do not contract, eye pressure does not increase, and myopia worsens.
3. As shown in FIG. 10, the neck can be freely rotated during reading, and it is not necessary to look at the book by fixing the head in a bald state, thereby preventing the neck from becoming stiff.
4). Can be read while moving. Because the smart glasses and the eyes vibrate synchronously, the screen becomes stable and easy to see. Reading while moving for a long time has a great effect on health, and at the same time prevents cardiovascular disease caused by sitting and moving for a long time.
5. It can be used outdoors. The eyeball and the macula are shielded and protected by the light-shielding plate, and are not affected by the refraction or reflection of sunlight and other light sources during reading.
6). In the eye protection unit according to the present invention, the remaining part other than the shade part is kept transparent, so that the field of view in the outdoor area reaches 180 degrees. Further, contact with an appropriate amount of sunlight every day for 2-3 hours reduces myopia deterioration. The wider the field of view, the more comfortable it is for the human eye.
7). Big screen. When viewed using the present invention, the screen becomes larger as the distance increases. Taking a viewing angle of 23 ° as an example, the screen will be 160 inches at a distance of 10 meters, and the screen will be 320 inches at a distance of 20 meters, making it easier to see a movie even when viewing a book.
8). Not affected by vibration. Because the smart glasses and eyes vibrate synchronously, even when used in transportation, for example, in cars or trains, the screen is stably held so that the screen can be clearly seen. I'm not tired.
9. Change human education system. Augmented reality smart glasses with two display units can display 2D and 3D images and videos, making learning more enjoyable and easier to understand when used in the educational field.

It is an exploded view showing a preferred embodiment of the present invention. FIG. 3 is a combination diagram in which the present invention is connected to a host. It is the combination figure by which the eye protection unit of this invention is arrange | positioned at a convex lens. It is a combination diagram in which the convex lens of the present invention is connected to a host. It is the schematic which an eye does not condense when using this invention. When using this invention, it is the schematic by which the image of a display part is directly projected on a retina. When the present invention uses a convex lens, it is a schematic diagram in which the retina around the eyeball comes into contact with sunlight. When the present invention uses a convex lens, it is the schematic which changes peripheral hyperopia to peripheral myopia. It is an application example of the outdoor education of this invention. It is an application example of the normal posture of the present invention. This is an example of looking down at a mobile phone.

  Preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below do not limit the contents of the present invention described in the claims. In addition, all of the configurations described below are not necessarily essential requirements of the present invention.

Smart Gras scan of augmented reality according to the present invention mainly includes a protection unit 2 of the eye which is placed in front of the smart glass of augmented reality, the shade portion 21 of the light-shielding provided on its both sides is augmented reality Smart This corresponds to the translucent display portions 10 on both sides of the glass 1.
In practice, the shade part 21 of the eye protection unit 2 is manufactured by selecting different materials, and the semi-transparent display parts 10 on both sides of the smart glass 1 change partially transparent or completely opaque to the outside. In addition, the convex lens 3 is installed in a certain area around the shade portion 21. The size of the area of the convex lens 3 is not limited, and it is sufficient that the user can clearly see the surrounding environment. The power of the convex lens 3 may be any number as long as the relative peripheral hyperopia changes to peripheral myopia (see FIGS. 1 to 5).

  More specifically, the augmented reality smart glass 1 includes a host 11 or a conventional smartphone (not shown) connected to each other by transmitting information in a wired or wireless manner, and prescription glasses 14 of a user. ) And a frame unit 12. Lenses 13 are installed on both sides of the frame unit 12, and the translucent display unit 10 is provided on the lenses 13 on each side.

  The eye protection unit 2 is a lens and is installed in front of the lens 13 of the augmented reality smart glass 1. The eye protection unit 2 further includes a light transmission part 22 provided in a region other than the eye protection unit shade part. The two light-shielding shade portions 21 that are provided separately correspond to the semi-transparent display portions 10 on both sides of the lens 13 of the augmented reality smart glass 1, and change them partially transparent or completely opaque. .

  A convex lens 3 is installed in a certain area around the shade portion 21. There is no restriction | limiting in the magnitude | size of the area | region of the convex lens 3, and the user should just be able to visually recognize the surrounding environment clearly. Myopia and those who are already myopic can reduce the tendency of myopia to deteriorate by using the eye protection unit 2 having the convex lens 3. The power of the convex lens 3 may be any number, and it is preferable that the relative peripheral hyperopia changes to peripheral myopia.

  In a preferred embodiment, the eye protection unit 2 is integrally formed on the augmented reality smart glass 1 (not shown) or installed as an independent plate and is movably coupled to the augmented reality smart glass 1. (See figure).

A specific method for adding the eye protection unit 2 to the augmented reality smart glass 1 is as follows.
1) In the manufacturing process, the translucent display unit 10 directly becomes a completely opaque display unit, thereby simultaneously forming a shade unit, and the above-described eye protection unit 2 is configured. Further, the convex lens 3 is installed in a certain area around the shade portion 21, and the size of the area of the convex lens 3 is not limited, and it is sufficient that the user can clearly see the surrounding environment.
2) A light shielding plate is added in front of the translucent display unit 10 of the conventional augmented reality smart glass to form the eye protection unit 2. Further, the convex lens 3 is installed in a certain area around the shade portion 21, and the size of the area of the convex lens 3 is not limited, and it is sufficient that the user can clearly see the surrounding environment.
3) As shown in FIG. 4, a person who is already myopic uses the convex lens 3. The convex lens 3 and the eye protection unit 2 are combined into one, or are added to the front surface of the eye protection unit 2 (the shape and size are not limited to those in the drawing).

  As shown in FIG. 6, in the case of reading by applying the present invention, the augmented reality smart glass 1 has a translucent display unit 10 about 2 cm in front of the eye so that the screen displayed on the personal computer is displayed on the retina. Directly projected. At this time, the ciliary muscle does not contract, and the tension is relaxed.

  As shown in FIG. 7, when digital information is read by combining the eye protection unit 2 and the convex lens 3 with the smart glass 1 according to the present invention, the eyeballs and the macula of both eyes are shielded and protected mainly, and the peripheral retina is protected. The portion has a feature of continuously contacting an external light source, and the user can clearly see the surrounding environment.

  As shown in FIG. 8, when the convex lens 3 is used, first, the peripheral light rays are collected on the broken line portion outside the retina, and are corrected as indicated by the solid line in the drawing to enter the retina. That is, relative peripheral hyperopia changes to peripheral myopia.

  As shown in FIG. 5, when reading by applying the present invention, each has a translucent display unit 10 in front of the left and right eyes, so when viewing each display unit with the left and right eyes, There is no need to look inward and the rectus medial muscles do not contract.

  The present invention simplifies the overall design, is convenient to carry, and can be used in combination with the augmented reality smart glass 1 in a simple manner.

  As shown in FIGS. 2, 4 and 9, in a more specific application, the reading system 40 is constructed in the host 11 or cloud of the augmented reality smart glass 1 according to the present invention. The content includes various subjects such as various subject classes, such as national language, nature, English, geography, geography, history, civil, physics, chemistry, health education, art, and music. However, it is not limited to these.

  By the way, when the present invention is universally adopted in schools, most teaching materials substitute text descriptions with 2D and 3D images or videos, so that the fun of learning increases and the learning effect also improves.

  The above-described embodiments are merely for explaining the technical idea and features of the present invention, and are intended to allow those skilled in the art to understand the contents of the present invention and to carry out the same with the present invention. It is not intended to limit the scope of the claims. Accordingly, improvements or modifications having various similar effects made without departing from the spirit of the present invention shall be included in the following claims.

DESCRIPTION OF SYMBOLS 1 Smart glass 2 Eye protection unit 21 Shade part 10 Display part 11 Host 12 Frame unit 13 Lens 14 Glasses with user's degree 22 Light transmission part 3 Convex lens 40 Reading system

Claims (4)

An eye protection unit installed in augmented reality smart glasses,
Shade parts for light shielding installed on both sides,
It is mainly equipped with a translucent display part corresponding to both sides of the smart glass,
As the shade portion of the eye protection unit, one of partially transparent or completely opaque material is selected,
The eye protection unit further includes a light transmission part provided in a region other than the shade part,
Augmented reality smart glasses eye protection shade.   The augmented reality smart glasses eye protection shade according to claim 1, wherein a convex lens is installed in a certain area around the shade part.   The augmented reality smart glass further includes a host and a frame unit that are connected to each other by transmitting information, and the above-described translucent display units are provided on both sides of the frame unit, respectively, The eye protection shade of the augmented reality smart glass according to claim 2.   A reading system is further constructed in the host, and the contents include national language according to class, nature, English, geography, geography, history, civilian, physics, chemistry, health education, art, music, etc. The augmented reality smart glasses eye protection shade of claim 3, wherein one department is selected.

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