KR102130310B1 - Optometer - Google Patents

Abstract

The present invention relates to an optometer, that is the invention relates to an ophthalmoscope, in which a rotating part is rotated based on a rotation axis so that a user can directly observe the eyes of an image. In addition, the present invention is portable and can measure the corneal curvature or retinal refractive index of the user.

Description

Optometry device {OPTOMETER}

The present invention relates to an optometrist device, and more specifically, to an optometrist that can be directly observed by the user's own eye by rotating the rotating part relative to the rotation axis with an ophthalmoscope.

Optometry is an examination of the eyes to see whether the eyesight is good or bad, color blindness, or abnormalities in the eyes. Mainly, the ophthalmologist uses an optometric device to check the eye condition of the subject.

In 1851, Helmholtz invented the ophthalmoscope.

Ophthalmoscopes are glasses that check the degree of the eyeball, nearsightedness, farsightedness, etc., and send reflected light to the eyeball in the darkroom to examine the reflected light directly or through a lens.

In particular, since the ophthalmoscope can change the frequency of the light source and the lens, it is possible to inspect the inside and the refractive index of the eye, and is largely divided into a direct ophthalmoscope and an iconography ophthalmoscope.

The direct ophthalmoscope is erect, and the observation range is narrow from 10 to 12°, but the structure is simple and easy to carry, and the retina of the subject can be observed.

Inverted ophthalmoscope is an inverted image by observing an image generated through an ophthalmoscope lens, and a wide range (60°) can be observed at a low magnification, but the size and structure of the device vary.

In 1895, Boman invented the retinoscope.

The screening machine is a device that objectively measures the refractive state of the eye by finding the location of the origin and proximity of the eye, where the light beams from the retina are collected by putting light sources in the eyes and pupils.

Later, standardization of the visual acuity test was required by German ophthalmologist Heinrich Kühller, and a chart or ophthalmometer of letters or figures was invented.

Recently, an automatic optometrist capable of automatic tracking and visual acuity measurement has been developed, but this has a problem that it cannot be moved because it can be installed and fixed at an optician or an ophthalmologist.

It has been developed in a form that can carry various types of ophthalmoscopes or devices combined with the functions of the optometrist.

As a background technology of the present invention, Republic of Korea Patent Publication No. 10-2017-0048072 (hereinafter referred to as Document 1), US Patent Registration No. US 9,427,156 (hereinafter referred to as Document 2), Republic of Korea Patent Publication No. 10-1451669 ( Hereinafter, there are document 3) and Republic of Korea Patent Publication No. 10-0252632 (hereinafter, document 4).

Literature 1 relates to an eye state inspection and related content providing service through wearables, and relates to a device for observing a user's eye state through a device to determine a state and to provide medical information and treatment information.

The device of Document 1 is to enlarge the user's eyeball through the photographing unit and analyze the state of the eyeball in the control unit to judge the eyeball, so it is difficult for the user to directly observe the eyeball in real time to confirm only the photographed screen.

In addition, the above device is configured in the form of glasses, as shown in FIG. 1, and thus a problem such as width of right and left, flowing, and tilting to one side may occur depending on the shape of the user's face. It cannot be used with the user.

Document 2 relates to a device including a lens for collecting a wavelength sensor and a machine for measuring the curvature of the cornea as a device and method for wavelength sensing and corneal topography.

As shown in FIG. 2, the device of Document 2 can be measured by placing the subject's eye in an eyecup 196, and the subject cannot check his/her eyes in real time.

Literature 3 relates to an automatic vision tester and a device capable of checking the correct visual acuity by inputting a user by using the first and second figures represented by the existing visual acuity chart and line as an automatic visual acuity test method.

As shown in FIG. 3, the device of Document 3 is difficult to carry because the test subject should be installed and used on the examination table to seat the chin on the chin holder.

In addition, the above device has a plurality of input buttons, and it may be difficult to accurately correct the visual acuity measurement value of the subject if it is incorrectly pressed during visual acuity measurement.

Document 4 relates to an apparatus for determining eye condition by collecting image data on the iris of the eye by eye contacting the user's eye with the eye examination apparatus.

As shown in FIG. 4, the device of Document 4 checks the eye state through a charge coupled device (CCD) that generates an electrical signal for an image formed by the lens unit by contacting the eye state input unit to the user's eye. However, there is a problem in that it is possible to distinguish colors only by recognizing black and white and having an RGB sensor.

In addition, the charge-coupled device can express a clear picture quality, but has a disadvantage that it is expensive and has high power consumption.

<Background technical literature>

(Document 1) Republic of Korea Patent Publication No. 10-2017-0048072

(Document 2) U.S. Patent No. 9,427,156

(Document 3) Republic of Korea Patent Publication No. 10-1451669

(Document 4) Republic of Korea Patent Publication No. 10-0252632

The present invention is intended to solve the problems of the background art, and it is an object of the subject, that is, a user can directly visually observe the eye condition of the user using an optometric apparatus.

In addition, the present invention is to adjust the optometric device irrespective of the shape of the face, such as the user's eye spacing, the height of the nose, and the like.

Furthermore, the present invention is intended to measure the corneal curvature or retinal refractive index of a user and to be portable.

In order to achieve the above object, the optometric apparatus of the present invention is fixed to the eyepiece 20, the support portion 10 that becomes a rotation axis of the rotating portion 30; The eyepiece 20 is formed at one end of the support portion 10, and the user's eye is in contact; And it is formed on one side of the support portion 10, characterized in that it comprises a rotating portion 30 that is enlarged without discriminating the position of the user's eye by using the support portion 10 as a rotation axis.

The eyepiece 20 of the present invention is characterized by being able to adjust between the first eyepiece 21 and the second eyepiece 22 according to the user's eye distance around the support portion 10.

The present invention is characterized in that at least one lens unit 200 and at least one prism 400 are included inside the support unit 10.

The present invention is characterized in that at least one light splitting part 100 is included inside the eyepiece 20 and/or inside the rotating part 30.

In addition, the present invention is characterized in that at least one lens unit 200 and one or more reflective units 300 are included inside the rotating unit 30.

Furthermore, the present invention is characterized in that one or more light emitting units 500 are further included on one side of the light splitting unit 100.

Furthermore, the present invention includes one or more lens units 200 inside the rotating unit 30; At least one reflector 300; One or more light splitting units 100; Characterized in that at least one light emitting unit 500 is included.

Moreover, the present invention is characterized in that the auxiliary part 40 is further included at the other end of the support part 10 in order to clearly process the user's eye image.

The present invention allows the user to visually observe the eye condition of the user himself using an optometric device.

That is, the user has the effect of immediately checking his or her eye condition without visiting an ophthalmologist or an optician.

In addition, the present invention has an effect that can be adjusted for each individual user by adjusting the optometrist device regardless of the shape of the face, such as the user's eye spacing, nose height.

Furthermore, the present invention measures the corneal curvature or retinal refractive index of the user, and has the effect of being portable.

In particular, the present invention is efficient because the inspection time is shortened and the cost is also reduced compared to the existing inspection method, since inspection can be performed without an inspector.

1 to 4 are prior art.
5, 6 is a plan view of the optometric apparatus according to the present invention,
7 is a plan view showing a state in which the user using the optometric apparatus according to the present invention,
8 is a plan view showing the inside of the optometric apparatus according to the present invention,
9 is a flow chart for the user to check his left eye,
Figure 10 is a schematic diagram showing the position of the rotating portion of the ophthalmic device according to the invention around the rotation axis,
11 is a flowchart for a user to check his/her right eye.
12 is a plan view showing the inside of an optometric apparatus according to another embodiment.
13 is a plan view showing the inside of an optometric apparatus according to another embodiment.
14, 15 is a plan view of an optometric device according to the present invention,
16 is a plan view showing the inside of another optometric apparatus of the present invention,
17 is a flowchart for a user to check his/her left eye,
18 is a schematic view showing another ophthalmic device according to the present invention, the position of the rotating part around the rotation axis,
19 is a flowchart for a user to check his/her right eye.
20 is a plan view showing the inside of another optometric device of the present invention,
21 is a flowchart for a user to check his left eye,
22 is a schematic diagram showing the position of the rotating part of the ophthalmic device of another form of the present invention around the rotation axis,
23 is a flowchart for a user to check his/her right eye.
24 is a plan view showing the inside of another optometric device of the present invention,
25 is a flowchart for a user to check his left eye,
Figure 26 is a schematic diagram showing the position of the rotating portion of the ophthalmic device of another form of the present invention around the rotation axis,
27 is a flowchart for a user to check his/her right eye.
<Description of code>
1: optometry, 2: electric field display,
10: support, 20: eyepiece, 21: first eyepiece, 22: second eyepiece, 30: rotating part, 40: auxiliary part,
100: light splitting unit, 110: first light splitting unit, 120: second light splitting unit, 130: third light splitting unit,
200: lens unit, 210: first lens unit, 220: second lens unit, 230: third lens unit, 240: fourth lens unit, 250: fifth lens unit,
300: reflector, 310: first reflecting portion, 320: second reflecting portion,
400: prism, 410: first prism, 420: second prism,
500: light emitting unit, 510: first light emitting unit, 520: second light emitting unit, 530: third light emitting unit,
600: sensor, 610: first sensor,
700: processing unit,
800: control unit,
900: pattern generation unit, 910: first pattern generation unit, 920: second pattern generation unit,

Hereinafter, the present invention will be described in detail through examples.

The objects, features, and advantages of the present invention will be readily understood through the following examples.

The present invention is not limited to the embodiments disclosed herein, and may be embodied in other forms. The embodiments disclosed herein are provided to sufficiently transmit the spirit of the present invention to a person having ordinary knowledge in the technical field to which the present invention pertains, and all conversions included in the technical spirit and technical scope of the present invention It should be understood to include, for example, equivalents or substitutes.

Therefore, the present invention should not be limited by the following examples, and it should be understood that all conversions included in the technical spirit and technical scope of the present invention are included. That is, a person having ordinary knowledge in the technical field to which the present invention pertains may variously modify the present invention by adding, changing, deleting, or adding components, without departing from the spirit of the present invention as set forth in the claims, or It will be changed, and it will be said that it is also included in the scope of the present invention.

The present invention can be applied with various transformations and can have various embodiments, and specific embodiments are illustrated in the drawings and described in detail. In the drawings, the size of an element or a relative size between elements may be somewhat exaggerated for a clear understanding of the present invention. In addition, the shape of the elements shown in the drawings may be somewhat changed due to variations in the manufacturing process.

Therefore, the embodiments disclosed herein should not be limited to the shapes shown in the drawings, unless otherwise specified, it should be understood to include some degree of modification.

On the other hand, various embodiments of the present invention can be combined with any other embodiments, unless otherwise indicated. Any feature indicated as particularly preferred or advantageous may be combined with any other feature or features indicated as preferred or advantageous. That is, various aspects, features, embodiments or implementations of the invention may be used alone or in various combinations.

It should be understood that the terminology used herein is for describing a specific embodiment and is not intended to be limited by the claims, and all technical terms and scientific terms used in the present specification are conventional technology unless otherwise stated. It has the same meaning as commonly understood by people with. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In the description of the present invention, when it is determined that a detailed description of related known technologies may obscure the subject matter of the present invention, the detailed description will be omitted.

In the present invention, when the optometrist device 1 is used by itself, it can be said to be a user.

In addition, in the present invention, when the optometric apparatus 1 is used for a user in a space where there is an examiner such as an ophthalmologist or an optician, the user may be referred to as a subject.

In the present invention, the optometrist device 1 is a device that allows a user to visually observe his or her own eyes, and may also be referred to as a self optometrist device or an optometrist.

<Example 1>

According to FIGS. 5 and 6, the ophthalmic device 1 may include a support portion 10, an eyepiece portion 20, and a rotating portion 30, and may be made of synthetic resin or metal, but is not limited thereto.

The synthetic resin is high-density polyethylene (HDP), polypropylene (PP), polyethylene terephthalate (PET), polystyrene (PS), poly It may be manufactured using any one or more of carbonate (polycarbonate, PC), but is not limited thereto.

The metal may be manufactured by using any one or more of titanium, stainless steel, iron, aluminum, brass, etc. in order to firmly manufacture the optometric apparatus 1, but is not limited thereto.

The support portion 10 is fixed to the eyepiece 20, becomes a rotation axis of the rotating portion 30, and may be formed in a three-dimensional shape, that is, a pillar body surrounded by a pillar surface, an upper surface, and a lower surface, but is not limited thereto.

In particular, it is preferable that the shape of the supporting portion 10 is formed in a cylindrical shape or a shape close to a cylindrical shape so that the rotating portion 30 formed on one side of the supporting portion 10 is smoothly rotated.

The eyepiece 20 may be formed at one end of the support portion 10, and may be formed in a cylindrical shape or a shape close to a cylindrical shape in which a user's eye is in contact and the user's eye magnified through the user's eye can be observed. Does not work.

In addition, the eyepiece 20 is formed of a first eyepiece 21 and a second eyepiece 22 around the support portion 10, and when viewed from the right with reference to the plan view of FIG. ∞), but is not limited thereto.

In particular, as shown in FIG. 7, it is preferable that the user is formed in an 8-shape lying down to confirm the state of one's left or right eye, that is, one eye, with both eyes through the optometric apparatus 1.

Humans do not see blind spots due to overlapping parts that are visually deficient because they live the visual field of both eyes.

That is, when the state of one eye of a user is checked with the corresponding eye, a blind spot is felt and a part of the eyepiece 20 is formed in an elongated shape in order to solve the problem of invisibility.

Furthermore, the eyepiece 20 may include an angle adjustment indicator (not shown) that can adjust between the first eyepiece 21 and the second eyepiece 22 according to the distance between the user's eyes and the eyes.

Even if the user changes by the angle adjustment indicator, the distance between the user's eyes and the eyes can be adjusted so that the user can personally adjust the eyes to check the eye condition.

Furthermore, when the user uses the optometric apparatus 1, an anti-slip (not shown) may be formed at the bottom of the eyepiece 20 to prevent slipping.

The anti-skid portion may form protrusions and irregularities, but is not limited thereto.

The rotating part 30 is formed on one side of the supporting part 10, and the supporting part 10 can be enlarged without discriminating the position of the user's eye by using the rotating part as a rotating shaft.

That is, the rotating part 30 is not fixed to the support part 10, but the protrusion is formed on the outer surface of the support part 10, and the protrusion is formed on the inner surface of the rotating part 30 that comes into contact with the support part 10 and rotates while biting each other. can do.

In FIG. 5, assuming that the surface of the rotating portion 30 contacting the second eyepiece portion 22 is 0°, the rotating portion 30 may rotate up to 180° using the support portion 10 as a rotation axis, as shown in FIG. 6.

In the present invention, the inside of the optometric apparatus 1 includes a light splitting part 100, a lens part 200, a reflecting part 300, and a prism 400, as shown in FIG. 8.

As shown in FIG. 8, the light splitting unit 100 includes a first light splitting unit 110 and a second light splitting unit 120 inside the eyepiece 20, preferably a second light splitting in the first eyepiece 21. The installment part 120 is included, and the first light splitting part 110 is included in the second eyepiece part 22.

In addition, the light splitting unit 100 reflects a part of the incident light, and the other part is an optical device that transmits, and either a plate glass or a beam splitter can be used, and preferably a beam splitter can be used. However, it is not limited thereto.

The beam splitter may be either plate-shaped or cube-shaped.

The plate type has the advantage of being light and relatively inexpensive, and the cube type has the advantage that the optical path length transmitted through the reflected light is the same, so that the optical path difference does not occur.

In the present invention, it is best to use a plate type beam splitter.

As illustrated in FIG. 8, the first light splitting unit 110 and the second light splitting unit 110 and the second light splitting unit 110 of the eyepiece 20 of the eyepiece 20 are based on the first light splitting unit 110 and the second light splitting unit 120 as shown in FIG. 8. 120) may each form an angle of 40 to 50°, preferably an angle of 45°, but is not limited thereto.

In particular, in the case of a plate-shaped beam splitter, when the angle is 45°, the light transmittance and reflectance can be adjusted and used.

When the sum ratio (%) of the light transmittance and the reflectance is 100, the ratio (%) of the light transmittance and the reflectance may be composed of 25 to 60 to 75 to 40, preferably 30 to 55 to 70 to 45, More preferably, it may be composed of 40 to 55 to 60 to 45, and most preferably 50 to 50, but it is not limited to this because it can be used by adjusting light transmittance and reflectance according to a user.

If the light transmittance (%) is less than 30 and the reflectance (%) is more than 70, the image may appear dark, and if the light transmittance (%) is greater than 55 and the reflectance (%) is less than 45, the image may appear too bright. have.

Therefore, when the light transmittance (%) and reflectance (%) are composed of 40 to 55 vs. 60 to 45, the image does not look too dark or bright.

The lens part 200 is included inside the support part 10 and inside the rotation part 30, preferably, the second lens part 220 is included inside the support part 10, and the first part is inside the rotation part 30. The lens unit 210 is included.

In addition, the lens unit 200 was used to serve as an eyepiece, an objective lens, a focusing lens, or an illumination lens, respectively. In the drawing, each lens is indicated by one lens, but one or more lenses each for the purpose of improving refractive index and removing aberrations. It can be used, but is not limited thereto.

The objective lens serves to enlarge the image, and the eyepiece serves to focus the enlarged image on the eye.

The focusing lens serves to form an image on the image sensor with an enlarged image from the objective lens when using the image sensor.

The illumination lens passes through the light of the light emitting unit 500 to form parallel light, and when the parallel light enters the eye to be observed by the user, the scattering occurs in the retina.

Since the first lens unit 210 uses an objective lens and the second lens unit 220 uses an eyepiece lens, the eye image to be observed by the user can be enlarged and visually identified.

The reflection part 300 includes a first reflection part 310 and a second reflection part 320 inside the rotation part 30.

In addition, the reflector 300 is a mirror that can reflect the light or the image of the eye to be observed and check the condition of the eye to be observed by shining on both eyes. At least one of a glass mirror, an aluminum mirror, a silver mirror, or a gold mirror It can be used, but is not limited thereto.

The glass mirror has a high light reflectance in the visible light region, and the aluminum mirror has a light reflectance in the infrared region a little lower than gold or silver, but the light reflectance in the ultraviolet or visible region is good.

Silver and gold mirrors have high light reflectance in the infrared region.

Therefore, the mirror used in the reflector 300 is for confirming a human eye condition, and it is preferable to use a glass mirror or an aluminum mirror having a high light reflectance in a visible light region visible to the human eye.

The prism 400 may include a first prism 410 and a second prism 420 inside the support 10.

In addition, the prism 400 is a transparent object having two or more optical planes capable of refracting light, and at least a pair of surfaces should not be parallel.

The prism 400 may be any one or more of a triangular prism, a polygonal prism, a polygonal pyramid, a cone, or a spherical shape. Preferably, any one of a triangular prism or a polygonal prism may be used, but is not limited thereto.

In the present invention, the first prism 410 and the second prism 420 are most preferably using a triangular prism.

In this case, one side of the first prism 410 and one side of the second prism 420 may be contacted and disposed in a shape such as a pentagonal column in which a pair of surfaces are parallel.

In addition, the prism 400 is made of any one of optical glass, crystal, and rock salt, and may be preferably made of optical glass, but is not limited thereto.

The user should be positioned as shown in FIG. 9 to observe his left eye.

The left eye image of the user passes through the first light splitting unit 110 through the second eyepiece 22 to enlarge the left eye image in the first lens unit 210, and the enlarged image is the first reflecting unit 310 To join.

Thereafter, an image of the left eye incident on the first reflecting part 310 is reflected by the second reflecting part 320 on the second reflecting part 320, which is arranged to face the first reflecting part 310, and then reflected by the second reflecting part 320. Through the unit 220, the left eye image can be seen with the eye.

The left eye image magnified through the second lens unit 220 is partially reflected from the first prism 410 so that the left eye image is visible to the right eye through the second light splitting unit 120, and the other part is passed through the second 2 Reflected by the prism 420 and the left eye image is visible to the left eye through the first light splitting unit 110, the user can observe his left eye on both sides.

If the user observes his right eye, as shown in FIG. 10, when observing the left eye, the position of the rotating portion 30 is rotated as shown in B as opposed to A indicating the location of the rotating portion 30.

That is, the user should be placed as shown in Figure 11 to observe his right eye.

The right eye image of the user passes through the second light splitting unit 120 through the first eyepiece 21 to enlarge the right eye image from the first lens unit 210 to enter the first reflecting unit 310.

Thereafter, the image of the right eye incident on the first reflecting part 310 is reflected on the second reflecting part 320 by the second reflecting part 320 to the second reflecting part 320 disposed to face the first reflecting part 310. The right eye image can be seen with the eye through the portion 220.

The right eye image enlarged through the second lens unit 220 is partially reflected from the first prism 410 so that the right eye image is visible to the right eye through the second light splitting unit 120, and the other part is passed through the second By reflecting from the 2 prism 420, the right eye image is visible to the left eye through the first light splitting unit 110, so that the user can observe his right eye on both sides.

As described above, as the user directly visually observes his/her eyes, the eye condition can be periodically checked and carried, so it can be used with various people.

<Example 2>

In the configuration of the first embodiment, a light emitting unit 500 may be further included inside the eyepiece 20.

12, a light emitting unit 500 is further included in the front end of the light splitting unit 100.

Preferably, the first light emitting unit 510 is formed at the front end of the first light splitting unit 110, and the second light emitting unit 520 is formed at the front end of the second light splitting unit 120.

The light-emitting unit 500 is a lighting device for generating light to more clearly form an eye image to be observed by a user. There is no invisible flicker, less glare, and a light-emitting diode that generates uniform light. (LED) may be used, but is not limited thereto.

In addition, the shape of the light emitting unit 500 may use one or more light emitting diodes, and a ring shape including one or more light emitting diodes in a ring shape may be used, but is not limited thereto.

The first light-emitting unit 510 and the second light-emitting unit 520 is best to use a light-emitting diode to increase the brightness of the eye and to make the eye image more vivid.

The path of the eye image is the same as in Example 1.

<Example 3>

In the configuration of the first embodiment, the third light splitting unit 130 and the third light emitting unit 530 may be further included inside the rotating unit 30.

13, a third light splitting unit 130 is further included between the second reflecting unit 320 and the first lens unit 210.

As the third light emitting unit 530 is formed under the third light splitting unit 130, the brightness of the eye is increased, so that an eye image to be checked by the user is more vivid.

The third light splitting unit 130 uses the same as that of the first embodiment, and is arranged to face the first reflecting unit 310 so that the light of the third light emitting unit 530 is reflected on the third light splitting unit 130. .

When the left eye is checked through the first lens unit 210 and the left eye is checked, the first light splitting unit 110 is transmitted and the left eye is brightened and sharpened. When the right eye is checked, the second light splitting unit 120 is applied. It has a light path through which the right eye becomes brighter and clearer as it is transmitted.

Thereafter, the path of the eye image is the same as in Example 1.

The third light emitting unit 530 is the same as the second embodiment.

In particular, the third light emitting unit 530 is best to use a light emitting diode (LED) that has no visible flicker, less glare, and generates uniform light.

<Example 4>

An auxiliary part 40 may be further included in the appearance of the optometric apparatus 1 of the first embodiment.

14 to 19, the same configuration as in Example 1 is omitted.

14 and 15, the auxiliary part 40 is formed at the other end of the support part 10.

At this time, the rotating portion 30 is formed in the same way as in the first embodiment, the protrusion is formed on the outer surface of the support portion 10, the protrusion is formed on the inner surface of the rotating portion 30 contacting the support portion 10 is rotated while biting each other .

The auxiliary unit 40 may be connected to an external electric field display device 2 to output information displayed on the processing unit 700 as an image to the outside.

The electric field display device may be a flat or curved display device, that is, a display, but is not limited thereto.

16, the third lens unit 230, the fourth lens unit 240, the sensor 600, and the processing unit 700 in a configuration excluding the reflective unit 300 of the first embodiment as shown in FIG. And the control unit 800 may be further included in the optometric apparatus (1).

16, the second prism 420, the first prism 410, the second lens unit 220, the fourth lens unit 240, and the processing unit 700 are sequentially included inside the support unit 10. .

The first prism 410, the second prism 420, and the second lens unit 220 are the same as in the first embodiment.

The fourth lens unit 240 is included behind the second lens unit 220 and is combined with the second lens unit 220 using the eyepiece using an objective lens to obtain an eye image output by the processing unit 700. Zooming in, the user can visually check the magnified eye image by himself.

The processing unit 700 is included behind the fourth lens unit 240.

In addition, the processing unit 700 is a display, a liquid crystal display (LCD, Liquid Crystal Display) or an organic light emitting diode (OLED) display that is a device that outputs a clearly processed eye image from the control unit 800. In order to carry the optometric apparatus 1, a display having a size of 5 inches or less may be used, but is not limited thereto.

The size of the display means the length of the diagonal line, not the horizontal/vertical size, and 1 inch means 2.54 cm.

In particular, it is best to use a display having a size of 1 to 3 inches for use while carrying the optometric apparatus 1.

Inside the eyepiece 20, the first light splitting section 110 and the second light splitting section 120 are formed in the same manner as in the first embodiment.

As shown in FIG. 16, the first lens unit 210, the third lens unit 230, and the sensor 600 are sequentially included inside the rotating unit 30.

The first lens unit 210 is the same as in the first embodiment.

The third lens unit 230 is included behind the first lens unit 210 and uses a focusing lens.

The sensor 600 includes a first sensor 610.

The first sensor 610 is an image sensor, a device that detects the intensity and color of an optical image and converts it into digital image data. It is an electronic component for storing, transmitting, and reproducing image images. Device) or a Complementary Metal Oxide Semiconductor (CMOS), but is not limited thereto.

The CCD has features that have low noise and excellent image quality to output electrons by light as it is, and CMOS has a feature of high processing speed and low power consumption.

16, the control unit 800 is included inside the auxiliary unit 40, and the control unit 800 is formed at the rear end of the processing unit 700 formed inside the support unit 10.

The control unit 800 may process the blurred eye image more vividly by mathematically processing the image of the user's eye enlarged through the lens unit 200 by the electronic board.

In addition, the control unit 800 may display the user's eye information as text and images to the processing unit 700.

Furthermore, the user's eye image, which is clear and cleanly processed, may be connected to the external electric field display device 2 as shown in FIG. 16 through the controller 800 to output the eye image.

Moreover, as it is possible to connect to the control unit 800 and an external computer or smartphone, telemedicine is possible by connecting the server of the ophthalmologist or the optician and transmitting the same information as seen by the processing unit 700.

The user should be positioned as shown in Figure 17 to observe his left eye.

When the user's two eyes are placed on the eyepiece 20, first, the left eye image of the user passes through the first light splitting unit 110 through the second eyepiece 22 and the left eye image is transmitted through the first lens unit 210. To bear

Thereafter, the left eye image formed in the first lens unit 210 is focused before entering the first sensor 610 through the third lens unit 230, so that the left eye image is more vivid.

Next, the left eye image sharpened through the third lens unit 230 detects the strength and color of the left eye image by the first sensor 610, converts it into digital image data, and stores the image, which is then controlled by the controller 800. To be transferred to.

The controller 800 processes the image information received by the first sensor 610 and transmits information on the left eye to the processor 700 as text and images.

In the processing unit 700, the left eye information is enlarged through the fourth lens unit 240 and the second lens unit 220 through text information and an image (hereinafter referred to as “left eye information”) of the user's left eye.

Subsequently, the enlarged left eye information is partially reflected from the first prism 410 so that the left eye information is visible to the right eye through the second light splitting unit 120, and the other part is passed through and reflected to the second prism 420. As the left eye information is visible to the left eye through the first light splitter 110, the user can observe his left eye on both sides.

If the user observes his right eye, as shown in FIG. 18, when observing the left eye, the position of the rotating part 30 is rotated as shown in B, as opposed to A indicating the position of the rotating part 30.

As the rotating part 30 is rotated as shown in FIG. 18B, the first lens part 210, the third lens part 230, and the first sensor 610 are in order in the rear end of the second light splitting part 120. It is arranged as shown in FIG. 19.

When the user's two eyes are placed on the eyepiece 20, first, the user's right eye image is transmitted through the second eye splitter 120 through the first eyepiece 21, so that the right eye image is transmitted through the first lens unit 210. To bear

Thereafter, the right eye image formed by the first lens unit 210 focuses before entering the first sensor 610 through the third lens unit 230, thereby making the right eye image more vivid.

Next, the right eye image sharpened through the third lens unit 230 detects the intensity and color of the right eye image by the first sensor 610, converts it into digital image data, and stores the image. To be transferred to.

The controller 800 processes the image information received by the first sensor 610 and transmits the information of the right eye to the processor 700 as text and images.

In the processing unit 700, right eye information is enlarged through the fourth lens unit 240 and the second lens unit 220 through text information and an image (hereinafter referred to as “right eye information”) of the user's right eye.

Subsequently, the enlarged right eye information is partially reflected from the first prism 410 so that the right eye information is visible to the right eye through the second light splitting unit 120, and the other part is passed through and reflected to the second prism 420. As the right eye information is visible to the left eye through the first light splitter 110, the user can observe his right eye on both sides.

<Example 5>

In the configuration of the fourth embodiment, the light emitting unit 500 may be further included inside the eyepiece 20.

20, a light emitting unit 500 is further included in the front end of the light splitting unit 100.

Preferably, the first light emitting unit 510 is formed at the front end of the first light splitting unit 110, and the second light emitting unit 520 is formed at the front end of the second light splitting unit 120.

In order to utilize a method of measuring corneal curvature by illuminating a ring pattern light on the user's eyes, it is preferable that the first light emitting unit 510 and the second light emitting unit 520 use a ring-shaped lighting device.

In the ring-shaped lighting device, light generated by a dot of an infrared light emitting diode causes a ring image to be reflected on the user's cornea, and the reflected image reaches the controller 800 to measure the curvature of the user's cornea. .

The infrared light emitting diode uses a wavelength of 760 ~ 800nm, preferably a wavelength of 770 ~ 790nm, most preferably a wavelength of 780nm, but is not limited thereto.

The external and internal components of the optometric apparatus 1 are the same as in Example 4 except for the light emitting part 500.

In order to calculate the corneal curvature of the user, the control unit 800 shows the user's eye information as text and images in the processing unit 700 in the same manner as in Example 4, and at the same time, the corneal curvature measurement calculation information is included.

In addition, as shown in FIG. 20, the optometric apparatus 1 may be connected to an external electric field display device 2 to output eye images and corneal curvature values.

Furthermore, as the control unit 800 of the optometric apparatus 1 can be connected to an external computer or smartphone, it is possible to perform telemedicine by connecting to an ophthalmology or optician's server and transmitting the same information shown in the processing unit 700. .

It should be arranged as shown in Fig. 20 to measure the corneal curvature while the user observes his left eye.

The path of the image for observing the left eye is the same as in Example 4 above.

However, the method of measuring the curvature of the cornea of the left eye of the user through the left eye image path is as follows.

When the user's eyes are placed on the eyepiece 20, first, the first light emitting portion 510 included inside the second eyepiece 22 is turned on, and a ring pattern is formed on the cornea of the user's left eye.

The left eye image with the ring pattern is more clear by passing the first light splitting unit 110 through the first lens unit 210 and focusing through the third lens unit 230 through the first lens unit 210. Becomes

Next, the left eye image formed with the sharpened ring pattern is detected by the first sensor 610 by detecting the intensity and color of the left eye image, converted into digital image data, and stores the image, and transmits the image to the controller 800.

The control unit 800 processes the image information transmitted to the first sensor 610, and at the same time measures the corneal curvature of the left eye using the image information of the left eye, and processes the left eye information into the text and image processing unit 700. send.

The left eye information further includes a measurement of corneal curvature.

The control unit 800 extracts the size and shape of the ring through the image information of the eye received from the first sensor 610, and based on this, the corneal curvature measurement calculation information is automatically calculated to derive the corneal curvature measurement value. .

At this time, corneal curvature measurement calculation information was generally performed by measuring the corneal curvature by illuminating the ring pattern light on the eyes used in an optometrist.

In the processing unit 700, the left eye information is enlarged through the fourth lens unit 240 and the second lens unit 220 through text information and an image (hereinafter referred to as “left eye information”) of the user's left eye.

Subsequently, the enlarged left eye information is partially reflected from the first prism 410 so that the left eye information is visible to the right eye through the second light splitting unit 120, and the other part is passed through and reflected to the second prism 420. The left eye information is visible to the left eye through the first light splitting unit 110.

That is, the user can directly observe his left eye with both eyes and check the corneal curvature of his left eye.

If the user observes his right eye and measures corneal curvature at the same time, as shown in FIG. 22, as shown in FIG. 22, as opposed to A indicating the position of the rotating part 30 when observing the left eye, as shown in FIG. Rotate position.

22B, as the rotating part 30 is rotated, the first lens part 210, the third lens part 230, and the first sensor 610 are in order in the rear end of the second light splitting part 120. It is arranged as shown in FIG. 23.

The path of the image for observing the right eye is the same as in Example 4 above.

However, the method of measuring the corneal curvature of the user's right eye through the right eye image path is as follows.

When the user's two eyes are placed on the eyepiece 20, first, the second light emitting portion 520 included inside the first eyepiece 21 is turned on, and a ring pattern is formed on the cornea of the user's right eye.

The right eye image with the ring pattern is transmitted through the second light splitting unit 120 to focus through the third lens unit 230 through the first lens unit 210 to make the right eye image with the ring pattern clearer. Becomes

Next, the right eye image with the sharpened ring pattern is detected by the first sensor 610 to detect the intensity and color of the right eye image, converts it into digital image data, stores the image, and transmits the image to the controller 800.

The control unit 800 processes the image information received by the first sensor 610, and simultaneously measures the corneal curvature of the right eye using the image information of the right eye, and transmits the information of the right eye to the processing unit 700 as text and images. send.

The information on the right eye further includes corneal curvature measurements.

In the processing unit 700, right eye information is enlarged through the fourth lens unit 240 and the second lens unit 220 through text information and an image (hereinafter referred to as “right eye information”) of the user's right eye.

Subsequently, the enlarged right eye information is partially reflected from the first prism 410 so that the right eye information is visible to the right eye through the second light splitting unit 120, and the other part is passed through and reflected to the second prism 420. The right eye information is visible to the left eye through the first light splitting unit 110.

That is, the user can directly observe his right eye with both eyes and check the corneal curvature of his right eye.

In the present invention, while the user can directly check his or her eyes while carrying the optometric apparatus 1, there is an effect that can simultaneously measure the corneal curvature of the eye.

<Example 6>

In the configuration of the fourth embodiment, a third light splitting unit 130, a fifth lens unit 250, a third light emitting unit 530, and a pattern generating unit 900 may be further included inside the rotating unit 30.

The fifth lens unit 250 is best to use an illumination lens to pass the light of the third light emitting unit 530 to form parallel light.

The pattern generator 900 includes a first pattern generator 910 and a second pattern generator 920.

The first pattern generator 910 may use a cone lens to greatly enlarge and observe the pattern generated when measuring the retinal refractive index, but is not limited thereto.

The second pattern generator 920 is a mask plate, and may be formed of a black acrylic resin or an iron plate coated with black paint, but is not limited thereto.

In particular, by using a black mask plate, it is possible to prevent it from being reflected on the surrounding substrate or the like when measuring the retinal refractive index.

That is, as the cone lens and the mask plate are formed inside the rotating part 30, a specific pattern can be made to measure the refractive index of the retina.

As shown in FIG. 24, the third light splitting unit 130, the second pattern generating unit 920, and the first pattern generating unit 910 are in order between the first lens unit 210 and the third lens unit 230. Can be deployed.

In addition, the fifth lens unit 250 and the third light emitting unit 530 may be disposed under the third light splitting unit 130 in order.

It is preferable that the third light emitting unit 530 uses an infrared light emitting diode illumination device in order to utilize a method of measuring a retinal refractive index by scattering light generated by a momentary lighting on the user's eye to the user's retina.

The infrared light emitting diode uses a wavelength of 820 to 900 nm, preferably 840 to 890 nm, more preferably 860 to 880 nm, and most preferably a wavelength of 870 nm, but is not limited thereto.

The external and internal components of the optometric apparatus 1 are the same as in Example 4 except for the third light splitting unit 130, the fifth lens unit 250, the third light emitting unit 530, and the pattern generating unit 900. Do.

In order to calculate the retinal refractive index of the user, the controller 800 shows the user's eye information in text and images to the processing unit 700 in the same way as in the fourth embodiment, and simultaneously includes retina refractive index measurement calculation information.

Also, as shown in FIG. 24, the optometrist device 1 may be connected to an external electric field display device 2 to output an eye image and a retinal refractive index value.

Furthermore, as the control unit 800 of the optometric apparatus 1 can be connected to an external computer or smartphone, it is possible to perform telemedicine by connecting to an ophthalmology or optician's server and transmitting the same information shown in the processing unit 700. .

It should be arranged as shown in Fig. 24 to measure the refractive index of the retina while the user observes his left eye.

The path of the image for observing the left eye is the same as in Example 4 above.

However, the method for measuring the refractive index of the left eye retina through the left eye image path is as follows.

When the user's eyes are placed on the eyepiece 20, first, the third light emitting part 530 included inside the rotating part 30 is turned on, and when passing through the fifth lens part 250, the light becomes parallel light.

At this time, the parallel light is reflected from the third light splitting unit 130, and the reflected light is transmitted through the first lens unit 210 and the first light splitting unit 110 and is scattered in the retina as it enters the user's left eye. Occurs.

Thereafter, the scattered light is transmitted through the first light splitting unit 110, the first lens unit 210, and the third light splitting unit 130 in order, and the second pattern generating unit 920 and the first pattern generating unit ( 910) In order to make a specific pattern.

The specific pattern focuses through the third lens unit 230 to form an image on the first sensor 610.

The first sensor 610 detects the strength and color of the left eye image and a specific pattern, converts it into digital image data, stores the image, and transmits it to the controller 800.

The controller 800 processes the image information transmitted to the first sensor 610, and at the same time, measures the refractive index of the left eye retina using specific pattern image information of the left eye, and processes the left eye information into text and images (700) ).

The left eye information further includes a retinal refractive index measurement.

The control unit 800 analyzes the pattern information through the image information of the eye received from the first sensor 610 to automatically calculate the refractive index of the retina to derive the measured value.

At this time, the method for measuring the refraction index used was a method for measuring the refraction index by scattering light used in an optometrist into the retina.

In the processing unit 700, the left eye information is enlarged through the fourth lens unit 240 and the second lens unit 220 through text information and an image (hereinafter referred to as “left eye information”) of the user's left eye.

Subsequently, the enlarged left eye information is partially reflected from the first prism 410 so that the left eye information is visible to the right eye through the second light splitting unit 120, and the other part is passed through and reflected to the second prism 420. The left eye information is visible to the left eye through the first light splitting unit 110.

That is, the user can directly observe his left eye with both eyes and check the retinal refractive index of his left eye.

If the user observes his right eye and measures retinal refractive index at the same time, as shown in FIG. 26, as shown in FIG. 26, when the left eye is observed, as opposed to A indicating the position of the rotating part 30, as shown in B, Rotate position.

As shown in B of FIG. 26, as the rotating part 30 is rotated, the first lens part 210, the third light splitting part 130, the second pattern generating part 920, the second The first pattern generation unit 910, the third lens unit 230, and the first sensor 610 are arranged in order, as shown in FIG.

In addition, the fifth lens unit 250 and the third light emitting unit 530 are disposed in order under the third light splitting unit 130.

The path of the image for observing the right eye is the same as in Example 4 above.

However, the method of measuring the refractive index of the user's right eye retina through the right eye image path is as follows.

When the user's eyes are placed on the eyepiece 20, first, the third light emitting part 530 included inside the rotating part 30 is turned on, and when passing through the fifth lens part 250, the light becomes parallel light.

At this time, the parallel light is reflected from the third light splitting unit 130, and the reflected light is transmitted through the first lens unit 210 and the second light splitting unit 120 and is scattered in the retina as it enters the user's right eye. Occurs.

Thereafter, the scattered light is transmitted through the second light splitting unit 120, the first lens unit 210, and the third light splitting unit 130 in order, and the second pattern generating unit 920 and the first pattern generating unit ( 910) In order to make a specific pattern.

The specific pattern focuses through the third lens unit 230 to form an image on the first sensor 610.

The first sensor 610 detects the strength and color of the right eye image and a specific pattern, converts it into digital image data, stores the image, and transmits it to the controller 800.

The controller 800 processes the image information transmitted to the first sensor 610, and simultaneously measures the retinal index of the right eye using specific pattern image information of the right eye to process the right eye information into text and an image (700) ).

The right eye information further includes a retinal refractive index measurement.

In the processing unit 700, right eye information is enlarged through the fourth lens unit 240 and the second lens unit 220 through text information and an image (hereinafter referred to as “right eye information”) of the user's right eye.

Subsequently, the enlarged right eye information is partially reflected from the first prism 410 so that the right eye information is visible to the right eye through the second light splitting unit 120, and the other part is passed through and reflected to the second prism 420. The right eye information is visible to the left eye through the first light splitting unit 110.

That is, the user can directly observe his right eye with both eyes and check the retinal refractive index of his right eye.

In the present invention, while the user can directly check his or her eyes while carrying the optometric apparatus 1, there is an effect that can simultaneously measure the retinal refractive index of the eye.

<Example 7>

A fixing device (not shown) may be further included in any one of the first to sixth embodiments.

The fixation device is coupled to the other side of the support portion 10 of the ophthalmologic device 1 to fix the angle and height between the user and the ophthalmologic device 1 to measure the corneal curvature or retinal refractive index. Can be maintained.

The fixing device is composed of a plurality of legs on one side of the fixing rod, and more than three legs, more preferably four or more, and most preferably five or more legs to stably support the optometric device (1). It may be, but is not limited to this.

The present invention is an industrially available invention that allows a user to directly observe his or her eyes by rotating a rotating part based on a rotation axis with an optometric device.

Claims (8)

Fixing the eyepiece 20 and includes one or more prisms 400 inside to refract light, but a support portion 10 that becomes a rotation axis of the rotating portion 30;
The first eyepiece part 21 and the second eyepiece part 22 are included at one end of the support part 10, and one or more light splitting parts 100 are included inside to adjust the transmittance and reflectance of the incident light, but the user's eyes make contact. Eyepiece 20; And
The support part 10 is formed on one side, and includes a first reflecting part 310 and a second reflecting part 320 facing each other to reflect light or an eye image to be observed, but the support part 10 is a rotating shaft. It includes a rotating part 30 that is rotated,
One or more lens units 200 are included inside the support unit 10 and inside the rotation unit 30 to enlarge the eye image to be observed without discriminating the position of the user's eyes, and to observe the state of one eye with both eyes Optometrist. The method according to claim 1,
The eyepiece 20,
Optometry device, characterized in that it can be adjusted between the first eyepiece (21) and the second eyepiece (22) according to the user's eye distance around the support (10). The method according to claim 1,
Optometry device,
One or more light emitting units 500 on one side of the light splitting unit 100, characterized in that, the optometric apparatus. The method according to claim 1,
Optometry device,
Optometry device, characterized in that further comprises at least one light splitting unit 100 and at least one light emitting unit 500 inside the rotating unit 30. The eyepiece 20 is fixed and includes at least one prism 400 inside to refract light, and includes a processing unit 700 including a display for outputting the processed eye image from the control unit 800. 30) the support portion 10 that serves as a rotating shaft;
The first eyepiece part 21 and the second eyepiece part 22 are included at one end of the support part 10, and one or more light splitting parts 100 are included inside to adjust the transmittance and reflectance of the incident light, but the user's eyes make contact. Eyepiece 20;
The support unit 10 is formed on one side and includes a sensor 600 on the inside to detect the intensity and color of the optical image and convert it into digital image data, the rotation unit 30 being rotated using the support unit 10 as a rotation axis; And
An auxiliary unit 40 formed at the other end of the support unit 10 and including a control unit 800 inside to process the enlarged user's eye image clearly, and provide the processing unit 700 with user's eye information as text and images It includes,
One or more lens units 200 are included inside the support unit 10 and inside the rotation unit 30 to enlarge the eye image to be output to the processing unit 700 to observe the condition of one eye with both eyes. Optometrist. The method according to claim 5,
The control unit 800 is characterized in that it is connected to the electric field display device 2, a computer or a smartphone in order to output information visible to the processing unit 700 to the outside, an optometric device. The method according to claim 5,
To measure the curvature of the cornea, characterized in that the optometric device further comprises a light emitting unit 500 including one or more ring patterns inside the eyepiece 20. The method according to claim 5,
A third light splitting unit 130 that reflects and transmits parallel light between the lens units 200 formed inside the rotating unit 30, an illumination lens that passes light and forms parallel light, and infrared light for scattering light on the user's retina An optometrist, characterized in that it further comprises a conical lens and a mask plate for measuring the refractive index of the illumination device and the retina.

Images