KR20140047475A - Pinhole contact lens with intensity reinforcements of symmetric type - Google Patents

Abstract

The present invention relates to a pinhole contact lens having a symmetric light quantity reinforcement part formed around a pinhole of a lens. The pinhole contact lens having a symmetric light quantity reinforcement part comprises: a transparent lens body; a light blocking part inserted in the lens body; a pinhole formed at the center of the light blocking part; and a symmetric light quantity reinforcement part arranged on the light blocking part to be symmetric with respect to the pinhole. The symmetric light quantity reinforcement part comprises: one or more ring-shaped light quantity reinforcement parts concentrically formed on the pinhole; a linear slit radially formed from the pinhole; a light quantity reinforcement pinhole formed on the concentric circles around the pinhole; or a combination of aforementioned parts. The pinhole contact lens having the symmetric light quantity reinforcement part according to the present invention can be comfortably worn by evenly increasing the brightness of phase formed on a retina by the pinhole.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a pinhole contact lens having a symmetrical light quantity reinforcing portion,

The present invention relates to a pinhole contact lens in which a pinhole is perforated at the center of a contact lens, and more particularly to a pinhole contact lens in which a symmetrical light quantity enhancing portion is formed around a pinhole at the center of the lens.

Visual perception is achieved by the light emitted from the subject passing through the cornea, being refracted by the lens, passing through the vitreous body, forming an image on the retina, and transmitting the image information to the cerebrum through the optic nerve. At this time, if the light emitted from the subject is long-lasting because the lens is thick or the axial length (front and rear length of eyeball) is long, the light emerges from the front of the retina and becomes nearsighted. If the surface of the cornea or lens is not uniform and the light does not focus at one point, it appears as astigmatism.

As a means for correcting such nearsightedness, primordial astigmatism, astigmatism, and the like, glasses and contact lenses for refracting light entering the eyeball to focus on the retina are widely known. In recent years, the width of the light beam entering the eye has been limited, The pinhole contact lens is formed so that the image does not spread on the pinhole contact lens, and the phase is focused on the pinhole contact lens.

However, when the light beam width is limited to the pinhole size, there is a problem that the amount of light entering the eye becomes small, so that the subject looks dark. To solve this problem, the brightness of the image formed on the retina is improved by puncturing a plurality of fine holes around the pinhole Technology has been developed.

Patent Document 1 discloses a contact lens in which a plurality of fine holes are perforated in the periphery of an opening. As shown in Fig. 1, a light-shielding portion 1 for shielding incident light incident on a cornea, a light- And a lens body 2 covering the front and rear surfaces of the light-shielding portion 1. The light-shielding portion 1 is provided with an opening 3 and a plurality of holes 4 having a smaller diameter than the opening, A lens is disclosed. When the conventional soft contact lens disclosed in Patent Document 1 is worn, the light emitted from the subject is transmitted through the lens body 2, the opening 3, and the lens body 2 ), And enters the cornea. Light passing through the cornea is imaged on the retina through the lens and the vitreous body. At this time, since the width of the light beam is limited narrowly by the aperture 3, a relatively clear image is formed on the retina, and the brightness of the image is improved by the light passing through the minute hole 4 around the aperture 3 do.

However, in the conventional contact lens in which a plurality of fine holes are perforated around the aperture, a plurality of fine holes 4 are randomly arranged around the aperture 3, and the brightness of the image formed on the retina through the aperture There is a problem that the visual acuity correction effect is deteriorated due to irregularity of the visual field on both eyes and the wearer feels discomfort such as dizziness and foreign body sensation.

KR 10-2012-0098641E (September 5, 2012)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a pinhole contact lens that uniformly improves the brightness of an image formed on a retina through a pinhole.

According to an aspect of the present invention, there is provided a pinhole contact lens having a symmetrical light quantity enhancing portion, comprising: a transparent lens body; A light shielding part inserted into the lens body; A pinhole formed at the center of the light blocking portion; And a symmetrical light quantity enhancing unit formed on the light intercepting unit so as to be symmetrical about the pinhole.

Wherein the symmetrical optical power enhancing portion comprises at least one ring-shaped optical power enhancing portion formed concentrically with the pinhole, a linear slit formed radially around the pinhole, a pinhole for reinforcing the light quantity formed on a concentric circle centering on the pinhole, or a combination thereof As a technical feature.

The pinhole contact lens formed with the symmetrical light quantity enhancing portion according to the present invention can uniformly improve the brightness of the image formed on the retina by the pinhole, thereby eliminating unnaturalness when worn.

Further, by adjusting the radius of curvature, width, shape, and the like of the symmetrical light quantity enhancing portion, it is possible to correct the visual acuity of both eyes equally even when the visual acuity of both eyes of the wearer is different.

FIG. 1 is a cross-sectional view of a conventional contact lens, in which a plurality of fine holes are perforated around a pinhole,
Fig. 2 is a view showing a state in which the contact lens shown in Fig.
3 is a cross-sectional view of a pinhole contact lens
4 is a cross-sectional view of a pinhole contact lens in which a symmetrical light amount reinforcing portion according to the present invention is formed
5 is a sectional view
6 to 10 are plan views of the light shielding portion formed with the symmetrical light quantity enhancing portion
11 is a view
FIG. 12 is a view showing a view of a case in which a pinhole contact lens in which a symmetrical light quantity reinforcing portion according to the present invention shown in FIG.

Hereinafter, a pinhole contact lens having a symmetrical optical fiber reinforcing portion according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a perspective view of a pinhole contact lens having a symmetrical light quantity enhancing portion according to the present invention, FIG. 4 is a perspective view of a pinhole contact lens having a symmetrical light quantity enhancing portion according to the present invention, FIG. Sectional view.

The pinhole contact lens in which the symmetrical light amount enhancing part according to the present invention is formed includes a lens body 10 made of a transparent material, a light blocking part 20 inserted into the lens body 10, And a symmetrical light quantity enhancing part 40 formed on the light intercepting part 20 so as to be symmetrical about the pinhole 30 and the pinhole 30. [ The pinhole contact lens having the symmetrical light quantity enhancing portion according to the present invention is configured to reduce the light flux width of the light emitted from the subject through the pinhole 30 so as to form a clear image on the retina and to provide a symmetrical light quantity enhancing portion 40 formed around the pinhole 30, So as to uniformly improve the brightness of the image formed by the light source. Each component will be described in detail below.

The lens body 10 is a transparent circular member having a shape that can be brought into close contact with the surface of the cornea when the wearer wears the lens with a curved surface. The material of the lens body 10 is a polymer in which various monomers are cross-linked, such as MEMA (2-hydroxy-Ethyl Methacrylate), Glycerol Methachrylate, Silicone Hydrogel Lens (Silicone Hydrogellens) (Phosphorylcholine) are mainly used. The diameter D of the lens body 10 used for the soft contact lens should be at least larger than the diameter of the cornea. In a typical human being, the diameter of the cornea is within about 12 mm. To about 14 mm. However, the diameter D of the lens body 10 can be appropriately selected in consideration of the wearer's corneal diameter and the like.

The lens body 10 may be formed in two types. First, as shown in FIG. 5 (a), the lens body 10 is formed with an insertion slot 12 into which a light shield 20 can be inserted. The lens body 10 having the insertion slot 12 as shown in FIG. 5 (a) can be manufactured by inserting and molding a material such as hemming into a mold having a protrusion so as to form an insertion slot. When the light intercepting portion 20 is inserted into the lens body 10 having the insertion slot 12 formed therein, the pinhole contact lens having the symmetrical light amount reinforcing portion according to the present invention is completed.

Second, as shown in Fig. 5 (b), the lens body 10 is composed of two lens members 14 and 16 and is sealed or fused. In the case of the lens body 10 composed of the two lens members 14 and 16 as shown in Fig. 5 (b), after the light intercepting portion 20 is inserted between the two lens members 14 and 16, The pinhole contact lenses 14 and 16 are sealed or fused to each other, thereby completing the pinhole contact lens in which the symmetrical light quantity reinforcing portion according to the present invention is formed.

6 to 10 are plan views of the light shielding portion 20 in which the symmetrical light quantity enhancing portion 40 is formed. 6 to 10 show various embodiments of the light intercepting portion 20 applicable to a pinhole contact lens having a symmetrical light amount enhancing portion according to the present invention.

The light blocking portion 20 is a non-transparent member and has a curved surface shape conforming to the surface shape of the cornea. There is no limitation on the planar shape of the light shielding portion 20, but it is preferable that the light shielding portion 20 is circular in which the pupil is completely shielded. The light blocking portion 20 may include a coloring agent so that red, blue, or the like appears when worn, so that a color contact lens function can be performed. Since the size of the light blocking portion 20 should be at least larger than the size of the pupil, it is less than about 9 mm when the size of the pupil is maximized for a typical person. Therefore, when the light blocking portion 20 is formed in a circular shape, It is preferable that the diameter d of the base 20 is 9 mm or more.

It is preferable that the pinhole 30 is formed in a circular shape to penetrate the center of the light intercepting portion 20 and allow the light emitted from the subject to enter the cornea. It is preferable that the diameter of the pinhole 30 is 0.1 to 2.0 mm because the diameter of the pinhole 30 is 0.1 to 2.0 mm. When the pinhole contact lens with the symmetrical light quantity reinforcing portion according to the present invention is worn, It is experimentally measured that the visual acuity is corrected to a maximum of 1.0, depending on the visual acuity. In this case, when the diameter of the pinhole 30 is less than 0.1 mm, the amount of light entering the eyeball through the pinhole 30 is small and the image becomes dark and the image is blurred due to the diffraction phenomenon. The diameter of the light entering the eyeball through the pinhole 30 is wide and the image is blurred on the retina, so that the visual correction effect is significantly reduced. Therefore, it is preferable that the diameter of the pinhole 30 is suitably selected according to the condition of the wearer in the range of 0.1 to 2.0 mm.

The symmetrical light quantity enhancing portion 40 is symmetrical about the pinhole 30 punctured at the center of the light intercepting portion 20 so that the symmetrical light quantity enhancing portion 40 is symmetrical about the pinhole 30, As shown in FIG. The width of the symmetrical light quantity enhancing portion 40 is preferably smaller than the diameter of the pinhole 30, and the radius of curvature (when the light quantity enhancing portion is a ring shape) should be smaller than the radius of the pupil. In order to enhance the brightness of the image formed by the light passing through the pinhole 30, a part of the light emitted from the subject through the symmetrical light quantity enhancing part 40 must enter the eye. The curvature of the symmetrical light quantity enhancing part 40 If the radius or length is larger than the pupil, light can not enter the eye through the symmetrical light quantity enhancing part 40.

Next, an embodiment of the light shielding portion 20 in which the symmetrical light quantity enhancing portion 40 is formed will be described in detail.

Fig. 6 shows a light shielding portion 20 in which a ring-shaped symmetrical light quantity enhancing portion 40 is formed. One ring-shaped symmetrical light quantity enhancing portion 40 is formed concentrically with the pinhole 30 formed at the center of the light intercepting portion 20 so that light passing through the symmetrical light quantity enhancing portion 40 is guided to the pinhole 30, And can enter the eyeball symmetrically with the light passing through the eye.

7 shows another type of light blocking portion 20 having a ring-shaped symmetrical light quantity enhancing portion 40. The ring-shaped symmetrical light quantity enhancing portion 40, that is, the first ring-shaped symmetrical light quantity enhancing portion 40, The second ring-shaped symmetrical light amount enhancing portion 44 and the second ring-shaped symmetrical light amount enhancing portion 44 are formed concentrically with the pinhole 30 formed at the center of the light intercepting portion 20. The embodiment as shown in Fig. 7 is for increasing the amount of light entering the eyeball, and is particularly suitable for wearers with a small iris. In the present invention, since the width of the symmetrical optical power enhancing portion 40 can not be formed to a certain size or larger due to diffraction, limitation of the light beam width, and the like, a method of increasing the number of the ring-shaped symmetrical optical intensity reinforcing portions is adopted. Although only two ring-shaped symmetrical type optical quantity reinforcing parts are shown in Fig. 7, three or more ring-shaped symmetrical type optical quantity reinforcing parts may be formed in the light blocking part 20. [

8 shows a light shielding portion 20 in which a radial slit-shaped symmetrical light quantity enhancing portion 40 is formed. A linear slit 46 is radially formed around the pinhole 30. As shown in Fig. The embodiment as shown in FIG. 8 is for solving a phenomenon in which a phase that may occur when the symmetrical optical power enhancing portion is in the shape of a ring, and can be selectively adopted according to the preference of the wearer.

9 shows a light shielding portion 20 in which the ring-shaped symmetrical light intensity enhancing portion 40 shown in Figs. 6 and 7 and the radial slit symmetrical light intensity enhancing portion 40 shown in Fig. 8 are formed together The first ring-shaped symmetrical light quantity enhancing portion 42 is formed concentrically with the pinhole 30 and the linear slit 46 is formed radially with the pinhole 30 as the center. At this time, two or more ring-shaped symmetrical light quantity reinforcing portions may be formed as shown in Fig. The light intercepting portion 20 shown in FIG. 9 has the features of the light intercepting portion 20 shown in FIGS. 6 to 8 at the same time, the amount of light entering the eyeball increases and the image becomes brighter, . Therefore, the width and curvature radius of the ring-shaped symmetrical light quantity enhancing portion, the length of the straight slit 46, and the like should be appropriately adjusted within a range where the wearer does not feel inconvenience.

10 shows a light blocking portion 20 in which a light amount enhancing pinhole 48 is formed as a symmetrical light quantity enhancing portion 40. As shown in FIG. The light quantity enhancing pinhole 48 is formed concentrically with the pinhole 30 as the center. That is, the symmetrical light quantity enhancing portion 40 having a constant distance between the light quantity enhancing pinhole 48 and the pinhole 30 is formed. In the case of the light intercepting portion 20 shown in FIG. 10, since the amount of light entering the eyeball is small, the image is darkened. However, the light blocking portion 20 can be used in a bright environment such as a clear day,

FIG. 11 is a view of the naked eye, and FIG. 12 is a view when the pinhole contact lens with the symmetrical light quantity enhancing portion according to the present invention shown in FIG. 3 is worn.

When the pinhole contact lens in which the symmetrical light amount enhancing part according to the present invention is worn is worn, the sharpness and brightness of the image are remarkably improved as compared with the view of FIG. 2 when a contact lens in which a plurality of fine holes are perforated around the conventional pinhole is worn .

10 Lens body 12 insertion slot
14, 16 lens member 20 light blocking portion
30 pinhole 40 symmetrical light quantity reinforcement
42 first ring-shaped symmetrical light amount reinforcing portion
44 second ring-shaped symmetrical light amount reinforcing portion
46 Straight slit 48 Pinhole for light quantity reinforcement

Claims (8)

A lens body 10 of a transparent material;
A light blocking portion 20 inserted into the lens body 10;
A pinhole 30 formed at the center of the light shield 20,
The pinhole contact lens with a symmetrical light amount reinforcement portion is characterized in that it comprises a symmetrical light amount reinforcement portion 40 formed in the light blocking unit 20 to be symmetrical around the pinhole (30).
The method according to claim 1,
A pinhole contact lens having a symmetric light intensity reinforcement part is formed in the center of the lens body 10, an insertion slot 12 into which the light blocking part 20 can be inserted.
The method according to claim 1,
The lens body 10 is composed of two lens members 14 and 16,
Wherein the light intercepting portion (20) is inserted between the two lens members (14, 16).
The method according to any one of claims 1 to 3,
The symmetrical light quantity enhancing part (40) is ring-shaped and is formed concentrically with the pinhole (30).
The method according to any one of claims 1 to 3,
Wherein the symmetrical light quantity enhancing section (40) is a first ring-shaped symmetry type light quantity enhancing section (42) and a second ring symmetry type light quantity enhancing section (44) formed concentrically with the pinhole (30) A pinhole contact lens having an additionally formed portion.
The method according to any one of claims 1 to 3,
Wherein the symmetrical optical power enhancement unit (40) is a linear slit (46) formed radially around the pinhole (30).
The method according to any one of claims 1 to 3,
Wherein the symmetrical light quantity enhancing portion 40 is a symmetrical light quantity enhancing portion formed concentrically with the pinhole 30 and a linear slit 46 formed radially around the pinhole 30. [ A pinhole contact lens having an additionally formed portion.
The method according to any one of claims 1 to 3,
Wherein the symmetrical light quantity enhancing part (40) is a light quantity enhancing pinhole (48) formed on a concentric circle centering on the pinhole (30).

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