Spectacle lens
Technical Field
The utility model relates to an eyeglass lens.
Background
The frame glasses adopt a single-optical concave lens, a double-optical concave lens and a progressive multi-focus lens, and the peripheral out-of-focus frame glasses lens control the myopic deepening. CN208921990U discloses a lens and glasses capable of controlling the increase of myopia degree, wherein the lens includes an upper lens and a lower lens, the diopter of the lens is higher than the diopter of the lower lens, the upper lens and the lower lens are connected through their respective connecting surfaces, and the adjacent two side surfaces of the upper lens and the lower lens are respectively connected to form a smooth curved surface. The lens and spectacles can control the myopia degree to increase too fast.
CN202339453U discloses a pair of special glasses for controlling myopia and reducing degree, which comprises a frame and lenses, wherein the lenses are fixed on the frame, the lenses are designed according to the principle of multiple focal points, have compact structure and multiple functions, are mainly suitable for being worn by teenagers, can eliminate asthenopia, effectively control the development of true myopia, improve eyesight, recover early myopia, and treat moderate or low myopia; different optical focuses of the lens gradual-changing area can stimulate visual cells of human eyes, and the lens has a remarkable effect on amblyopia of children of low ages by exercising the visual function. Experiments have demonstrated that myopia control is very limited with single concave, bifocal and progressive addition lenses.
CN104678572A discloses an ophthalmic lens comprising a first refractive area having a first refractive power based on a prescription for correcting ametropia of an eye; and a second dioptric region having a refractive power different from the first refractive power and having a function of focusing an image on a position other than a retina of the eye to suppress development of ametropia of the eye, wherein the second dioptric region is formed as a plurality of island-shaped regions independent of each other in the vicinity of a central portion of the lens, and the first dioptric region is formed as a region other than a region formed as the second dioptric region.
The patient visually recognizes the image of the object formed by the first refractive power using the spectacle lens in CN104678572A described above, and suppresses the progression of myopia by the image obtained in front of the retina by the refractive power other than the first refractive power. However, in the above-mentioned spectacle lens, since the second dioptric region is formed as a plurality of island-shaped regions independent of each other, all the light rays passing through the first dioptric region act on the retina of the patient concentratedly at the same time, and therefore, although the development of myopia is theoretically inhibited by the second dioptric region, the eye fatigue (which is a main factor causing myopia) due to the irritation and glare of the light rays passing through the first dioptric region to the eye and thus the development of myopia cannot be effectively inhibited is actually reduced.
Disclosure of Invention
The utility model provides a lens that the effect that makes the development of inhibition myopia obtains improving.
The technical scheme for solving the technical problems is as follows:
an ophthalmic lens comprising a plurality of first units for focusing an image at a location other than the retina of an eye to inhibit the development of ametropia of the eye, the first units having a first refractive power, further comprising:
a second unit that deflects the light away from the linear propagation, the plurality of first units being connected by the second unit;
a plurality of third cells for correcting myopia, the third cells being formed as regions other than the first and second cells;
the second unit and the third unit have diopter different from the first diopter, and form phase difference after the light passing through the second unit and the third unit acts on the retina.
The utility model has the advantages that: the utility model discloses in, the second unit of connecting a plurality of first units is utilized for the light that same light source sent is on line when respectively passing through second unit and third unit, and the relative third unit of second unit is bigger to the hindrance effect that light formed, consequently, produces the light path difference through the light of second unit and the light that passes through the third unit, and then the time of reacing the retina is inequality, thereby forms the phase difference. Through the phase difference, the phenomenon that light rays act on the retina at the same time in a concentrated mode is avoided, stimulation to eyes can be relieved, eye fatigue is reduced, glare is reduced, in addition, due to the structure, all parts of an object are decomposed and imaged, and the imaging brightness, the imaging outline and the imaging definition can be improved.
The utility model discloses in, connect first unit through the second unit, make every first unit become non-independent island shape region, the second unit is similar to the island chain, adjacent first unit passes through the island chain and connects the back, and every first unit is arranged respectively at intervals and forms a plurality of suppression layers on a plurality of rings, third unit in every intra-annular is confined, light is when through second unit and third unit except that first unit, the phase difference of cooperation formation through second unit and third unit, the dazzling light and the amazing that light produced to the eyes have been reduced, make the tired sense of patient's eyes obtain reducing. Therefore, through the cooperation of second unit and third unit, still played the effect that the myopia takes place of inhibition when correcting myopia, promptly the utility model discloses a lens makes the effect of inhibiting myopia development obtain improving.
Drawings
Fig. 1 is a plan view of an embodiment 1 of the spectacle lens of the present invention;
fig. 2 is a perspective view of a first unit in the present invention;
fig. 3 is a perspective view of a second unit in the present invention;
fig. 4 is a top view of embodiment 2 of an ophthalmic lens of the present invention;
FIG. 5 is a schematic diagram of the loop of FIG. 4 with the addition of a center of a first cell in each suppression layer;
reference numbers in the drawings:
a is an outermost inhibiting layer;
b is an innermost inhibiting layer;
c is an intermediate inhibiting layer;
1 is a spectacle lens;
10 is a first unit;
20 is a second unit;
and 30 is a third unit.
Detailed Description
Example 1
As the spectacle lens 1 shown in fig. 1, the spectacle lens 1 is a concave lens having an object side surface formed into a convex curved surface toward the object side and an eye side surface formed into a concave surface having a curvature larger than that of the object side surface. The spectacle lens 1 has a first unit 10 for focusing an image in a position other than the retina of the eye in order to inhibit the progression of the refractive error of the eye, a second unit 20 for deviating light from a straight line, a plurality of third units 30 for correcting myopia, each of which and the relationship between them being explained in detail below:
as shown in fig. 1, the first unit 10 is made of a material having a point for focusing an image on the front of the retina of the eye, and the second unit 20 and the third unit 30 have a function for focusing an image on the retina of the eye. Therefore, when the patient views an object using the eyeglass lens 1 that suppresses the development of myopia, an image of the object is formed on the retina while imaging the anterior square of the retina. The utility model discloses a lens 1 has following effect: the development of myopia is suppressed by an image obtained in front of the retina by the first unit 10 other than the third unit 30 while visually recognizing the image of the object formed by the second unit 20 and the third unit 30.
As shown in fig. 1, a plurality of first cells 10 are connected by second cells 20, and the third cells 30 are formed as regions other than the first cells 10 and the second cells 20; the second unit 20 and the third unit 30 have refractive power different from the first refractive power, and the light passing through the second unit 20 and the third unit 30 acts on the retina to form a phase difference. In the present invention, it is preferable that the first unit 10 and the second unit 20 protrude from the third unit 30, and the diopters of the second unit 20 and the third unit 30 are different.
Since the light advances at a constant speed (within a certain range), it has a fixed phase when reaching any point, and the phase difference is the difference between the phases of different light waves at the meeting point. The utility model discloses in, utilize the second unit 20 of connecting a plurality of first units 10 for the light that same light source sent is on line when respectively passing through second unit 20 and third unit 30, and second unit 20 is bigger to the hindrance effect that light formed for third unit 30, and consequently, the light through second unit 20 and the light through third unit 30 produce the light path difference, and then the time of arriving the retina is inequality, thereby forms the phase difference. Through the phase difference, the phenomenon that light rays act on the retina at the same time in a concentrated mode is avoided, stimulation to eyes can be relieved, eye fatigue is reduced, glare is reduced, in addition, due to the structure, all parts of an object are decomposed and imaged, and the imaging brightness, the imaging outline and the imaging definition can be improved. It can be seen that the cooperation of the second unit 20 and the third unit 30 can correct myopia and inhibit myopia. Therefore, the present invention is mainly used to inhibit the development of myopia by the first unit 10, but also by the combined structure of the second unit 20 and the third unit 30.
As shown in fig. 1, the plurality of first cells 10 are respectively arranged on the plurality of rings at intervals to form a plurality of inhibiting layers. Any two adjacent first cells 10 on each inhibiting layer are connected by a second cell 20. The ring can be regular ring or irregular ring, the regular ring can be round, regular polygon and the like, and the irregular ring can be any irregular shape. In this embodiment, the rings for the first unit arrangement are preferably irregular rings, and the irregular rings are arranged from the inside to the outside or from the outside to the inside.
As shown in fig. 1 and 2, the projection formed by the surface of the first unit 10 along the longitudinal direction of the spectacle lens 1 is circular, preferably, the first unit 10 is hemispherical as a whole, and the surface area of each first unit 10 is 0.50mm2To 3.14mm2. The utility model provides a vertically do: along the direction of rectilinear extension of the object-side surface of the spectacle lens 1 towards the eye-side surface, or along the direction of rectilinear extension of the eye-side surface of the spectacle lens 1 towards the object-side surface.
As shown in fig. 1 and 3, the projection formed by the surface of the second unit 20 along the longitudinal direction of the spectacle lens 1 is rectangular. The cross section formed by the second unit 20 is rectangular or arcuate in the longitudinal direction of the spectacle lens 1, preferably the cross section formed by the second unit 20 is arcuate in the longitudinal direction of the spectacle lens 1. The area of each second cell 20 is 2-10% of the area of each first cell 10. The thickness of the second cell 20 is less than or equal to the thickness of the first cell 10.
As shown in fig. 1, the ratio of the total area of the third cells 30 to the total area of the first and second cells 10 and 20 and the third cell 20 is 40% to 50%. Therefore, it is possible to obtain a good wearing feeling while maintaining sufficient visibility while ensuring a function of suppressing the progression of myopia.
Example 2
As shown in fig. 4 and 5, the plurality of first cells 10 are respectively arranged at intervals on a plurality of rings having the same center to form an outermost constraining layer a, an innermost constraining layer B, and at least one intermediate constraining layer C between the outermost and innermost constraining layers a and B. The center of each first cell 10 in each inhibition layer is located on the same ring, i.e., the center of each first cell 10 in the outermost inhibition layer a is located on the outermost ring, the center of each first cell 10 in the innermost inhibition layer B is located on the innermost ring, and the center of each first cell 10 in the intermediate inhibition layer C is located on the intermediate ring. The utility model discloses in, the quantity of middle suppression layer C preferentially adopts the three-layer.
As shown in fig. 4 and 5, each of the hexagonal rings is a non-regular hexagonal ring, and the centers of the first cells 10 are placed on the polygonal rings, so as to facilitate the arrangement of more first cells 10 and the arrangement of more connecting lines, thereby fully exerting the function of the spectacle lens 1 for inhibiting myopia. At the same time, the arrangement of the first unit 10 is also made easier.
As shown in fig. 4 and 5, two adjacent first cells 10 of the outermost inhibition layer a and the innermost inhibition layer B are connected by the second cell 20, so that the outermost inhibition layer a and the innermost inhibition layer B surrounded by the first cell 10 and the second cell 20 are closed spaces. Thereby, the area of the third unit 30 surrounded by the innermost restraining layer B and the plurality of second units 20 of the first unit 10 connected with the innermost restraining layer B is 28-227mm2Here, the area is largest among all the third cells 30. The diameter of the tube is 28-227mm2Is located in the central zone of the ophthalmic lens 1.
Only a part of two adjacent first cells 10 in each intermediate suppression layer C are connected by the second cells 20, and any one first cell 10 in each intermediate suppression layer C is connected with the first cell 10 in the adjacent outermost suppression layer a and/or innermost suppression layer B and/or further intermediate suppression layer C by the second cell 20. Such a structure allows the third unit 30 to be formed in different shapes (as shown in fig. 1 and 2), which is beneficial to reducing the area occupied by the second unit 20 on the third unit 30 when the suppression effect generated by the second unit 20 and the third unit 30 is ensured, so that the correction of vision can be ensured.