JP2017181967A - Progressive refractive power lens - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a progressive refractive power lens that allows wearers to select a diopter at a fitting point.SOLUTION: In a progressive refractive power lens 10 including: a near vision part 14 that is located downward a lens and handles with near vision; and a progression part 16 which extends upward from a top end of the near vision part 14 and in which refractive power progressively varies, a reference mark 38 indicative of a standard fitting point, and a scale mark 40 arranged upward the reference mark 38 are put in place on a lens surface as a layout mark. The scale mark 40 has a plurality of scale lines 41a,41b, ..., and 41j intersecting a vertical reference line 40K extending in a vertical direction from the reference mark 38, and indicative of each different diopter point within the progression part 16.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a progressive-power lens, and more particularly to a progressive-power lens that is suitably used when performing near-field work.

  Conventionally, progressive-power lenses have been used as spectacle lenses to compensate for lack of adjustment power such as presbyopia. A progressive-power lens usually has a distance portion for far vision located above the lens, a near portion for near vision located below the lens, and the distance portion and the near portion. There is a progressive portion for intermediate vision provided, and there is an advantage that a clear vision can be made continuously from a long distance to a short distance. In such a progressive power lens, specific specifications of the lens to be worn are determined based on the prescription information of the lens such as the dioptric power, the addition power, and the progressive zone length.

FIG. 6 shows a layout mark provided on the surface of the progressive-power lens described in Patent Document 1 below. In the figure, 100 is a progressive-power lens, 102 is a left / right identification mark (R or L), 103 is a dot indicating the geometric center O of the lens, 106 is an alignment reference mark, and 108 is a distance measurement unit. A circular distance measurement area mark indicating a place, 110 is an oval near area measurement area mark indicating a place where the power of the near area is measured, and 104 is a fitting point which is a reference for frame setting. Is a crosshair. Here, the fitting point is a point on the lens side that matches the pupil position of the wearer.
In the figure, when the progressive power lens 100 is put into a spectacle frame, the outer shape of the lens is processed so that the cross line 104 indicating the fitting point coincides with the pupil position of the wearer. Fit into the frame. For this reason, when a wearer views horizontally, the wearer visually recognizes an object through a fitting point in the lens 100.

  This fitting point is designated in advance at one point in the vicinity of the geometric center O of the circular lens or in the vicinity thereof, but for the purpose of focusing on near vision, the near portion is set large and the progressive zone length is increased. In the set progressive-power lens, the fitting point is positioned on the progressive part. In this case, the wearer can freely select the distance power and the near power within a range in which there is no problem, but can freely select the power at the fitting point located on the progressive part. There was a problem that could not be done.

JP 2005-338590 A

  The present invention has been made for the purpose of providing a progressive-power lens capable of selecting the power at the fitting point by the wearer against the background described above.

  Thus, according to the first aspect of the present invention, there is provided a near portion corresponding to near vision and a progressive portion extending upward from the upper end of the near portion and having a refractive power gradually changing. A progressive power lens having, on the surface of the lens, a reference mark indicating a standard fitting point as a layout mark, and a vertical reference line extending in a vertical direction from the reference mark, and different degrees in the progressive portion And a plurality of scale lines indicating the points.

  A second aspect is characterized in that, in the first aspect, the reference mark is provided at the near portion or a boundary between the near portion and the progressive portion.

  A third aspect of the present invention is characterized in that, in the first aspect, a boundary between the near portion and the progressive portion is provided at or near the geometric center of the lens.

  A fourth aspect is characterized in that, in the third aspect, the near portion is set in the entire area below the geometric center of the lens.

  A fifth aspect of the present invention is the method according to the first aspect, wherein the peak of astigmatism is on the side of the progressive portion, and the ratio of the clear vision region in the area below the geometric center of the lens is 70% or more. It is characterized by that. Here, the clear vision region refers to a low aberration region having an aberration amount of less than 0.50 diopter in the astigmatism distribution.

As described above, the present invention is a lens of a progressive power lens having a near portion corresponding to near vision and a progressive portion extending upward from the upper end of the near portion and having a progressive change in refractive power. On the surface, as a layout mark, a reference mark indicating a standard fitting point, and a plurality of graduation lines indicating points of different frequencies in the progressive portion intersecting with a vertical reference line extending vertically from the reference mark are applied. It is characterized by being.
In the conventional progressive-power lens, only one point that can be selected as a fitting point is shown in the layout mark, whereas according to the present invention, the fitting point is a standard fitting point. In addition, it is possible to select from a plurality of points having different frequencies in the progressive part. For this reason, in this invention, the focal distance in the state which the wearer looked horizontally, ie, the focal distance in a fitting point, can be adjusted to a desired value.

  In this case, if the reference mark is provided at the near portion or at the boundary between the near portion and the progressive portion, the near power can be selected as the frequency at the fitting point.

In the present invention, the boundary between the near portion and the progressive portion can be provided at or near the geometric center of the lens.
With such a lens configuration, the near portion starts substantially immediately below the geometric center of the lens, and as a result of adjusting the focal length at the fitting point, the lens moves downward relative to the spectacle frame. Even when the near portion is lowered below the spectacle frame, the line of sight of the wearer can reach the near portion with a small amount of movement.

  In this case, the near portion can be set over the entire area below the geometric center of the lens (claim 4). In this way, an area that can be used for near vision can be secured widely in the vertical direction and the horizontal direction.

  According to claim 5, if the peak of astigmatism is formed on the side of the progressive portion and the ratio of the clear vision region in the area below the geometric center of the lens is 70% or more, the fitting point Even when the near-use part is lowered in accordance with the adjustment of the focal length, it is possible to suppress discomfort and discomfort due to the limited field of view in the left-right direction during near vision.

  According to the present invention as described above, it is possible to provide a progressive-power lens that allows the wearer to select the power at the fitting point.

(A): It is the figure which showed the outline of the area | region division of the progressive-power lens of one Embodiment of this invention. (B): It is the figure which showed the layout mark of the lens. (C) is a diagram showing a power distribution of the lens. It is the figure which expanded and showed the scale mark and its peripheral part of FIG. It is the figure which showed distribution of astigmatism of the progressive-power lens of an Example. It is the figure which showed the state which encased the progressive-power lens of FIG. It is the figure which showed other embodiment of this invention. It is the figure which showed an example of the conventional layout mark given to the surface of a progressive-power lens.

  Next, a progressive-power lens according to an embodiment of the present invention will be described with reference to the drawings. In the following description, “upper” and “lower” of a progressive-power lens are defined as “upper” and “lower” for a wearer wearing spectacles using the lens.

  FIG. 1A is a front view of a progressive-power lens (hereinafter may be simply referred to as a lens) 10 according to an embodiment of the present invention, and shows an outline of lens area divisions. This lens 10 has a shape before processing the outer shape of the lens in accordance with the shape of the spectacle frame, and has a circular shape in plan view. The front surface of the lens 10 is a spherical surface, and a progressive refractive surface is formed on the rear surface of the lens 10.

On the rear surface of the lens 10, a distance portion 12 located above the lens and corresponding to far vision, a near portion 14 located below the lens and corresponding to near vision, and a distance portion 12 and a near portion 14. And a progressive portion 16 which is located between and has a refractive power that changes progressively.
In FIG. 1A, an axis extending in the left-right direction through the geometric center O of the lens 10 is defined as an X axis, and an axis extending in the vertical direction through the geometric center O is defined as a Y axis.

In the drawing, K ₀ is a near design reference point located at the upper end of the near portion 14 on the rear surface of the lens 10 and is set on the geometric center O in this example. In this example, the near design reference point K ₀ , that is, the geometric center O is located at the boundary between the near portion 14 and the progressive portion 16, and the prescribed near power is set in the area below the geometric center O. Is set. Thus, in the lens 10, the near portion 14 is set in the entire area below the geometric center O.
On the other hand, E ₀ is a distance design reference point located at the lower end of the distance portion 12 on the rear surface of the lens 10 and is set on the Y axis above the lens. The frequency continuously changes from the near design reference point K ₀ to the far design reference point E ₀ , and the region between them corresponds to the progressive portion 16. The distance L in the vertical direction between the distance design reference point E ₀ and the near design reference point K ₀ is the progressive zone length.

FIG. 1C is a diagram showing the power change of the lens 10 on the Y-axis line including the distance design reference point E ₀ and the near design reference point K ₀ . While near power which is a more downward near design reference point K ₀ as shown in FIG formulated is set, leading to distance design reference point E ₀ from the near design reference point K ₀ progressive In the part 16, the frequency is set to change at a constant rate. Further, a predetermined distance power is set above the distance design reference point E ₀ .

  In FIG. 1A, reference numeral 18 denotes a side part having large aberration on both sides of the lens 10 in the left-right direction (X-axis direction). In the progressive-power lens, the central portion of the lens along the Y axis used when gazing at the object is set as a low aberration region, while a region with large aberration is generated in the peripheral portion of the lens. In this example, particularly in the near portion 14 below the lens used for short distance work such as reading or desk work, the side portion 18 having large aberration is located above the near portion 14 in order to secure a wide low aberration region as much as possible. Specifically, the aberration is designed so that the peak of astigmatism generated in the side portion 18 is located on the side of the progressive portion 16 so as to be positioned.

FIG. 1B is a diagram showing layout marks provided on the convex (front) side surface of the lens 10. The layout mark clearly indicates information necessary for the measurement of the power with a lens meter and the frame processing into the spectacle frame, and the ink jet method using ink that can be removed with a solvent such as alcohol. It is printed on the lens surface by the printing method. In the figure, 32 is a left / right identification mark (R or L) indicating whether the eye is for the right eye or left eye, 34 is a horizontal reference line indicating the horizontal direction of the lens, and 36 is a check mark.
Reference numeral 38 denotes a reference mark formed of a cross line indicating a standard fitting point which becomes a reference for frame placement, and is positioned at the geometric center O in this example. Reference numeral 35 denotes a near portion measurement area mark indicating a place where the frequency of the near portion 14 is measured, and is provided below the reference mark 38. On the other hand, 40 is a scale mark arranged above the reference mark 38.

  FIG. 2 is an enlarged view of the scale mark 40 and its peripheral part. The scale mark 40 is composed of a vertical reference line 40k extending upward from the geometric center O, that is, perpendicular to the reference mark 38, and ten scale lines 40a, 40b,..., 40j extending in the left-right direction. ing. The graduation line 40a is located 1 mm above the reference mark 38, and the 10 graduation lines including 40a are arranged at equal intervals (1 mm interval) in the vertical direction. For easy identification, the fifth scale line 40e and the tenth scale line 40j are formed longer in the left-right direction than the other scale lines. Reference numerals 41a, 41b,..., 41j are intersections of the ten scale lines 40a, 40b,.

In this example, the scale mark 40 is disposed in the progressive portion 16 where the frequency changes,
The frequencies at the intersections 41a, 41b,..., 41j are different from each other, and as shown in FIG. 1 (C), the frequency decreases gradually from 41a close to the reference mark 38 toward 41j located at the uppermost position. Yes.
Therefore, when the frame is inserted, the intersection points 41a, 41b,..., 41j of the graduation mark 40 are replaced with the reference mark 38 indicating the standard fitting point as a lens side point to be matched with the wearer's pupil position. By selecting and changing the fitting position of the lens 10 with respect to the spectacle frame in the vertical direction, the focal length at the fitting point, that is, the focal length in a state where the wearer sees horizontally can be appropriately adjusted.

The focal length at each intersection 41a, 41b,..., 41j can be obtained by the following equation.
Near-use refraction adjusting power (unit: diopter (hereinafter referred to as "D")) = 1 / near focal length (m)
FP power (D) = add power (D) × addition ratio Focal length at each intersection (m) = 1 / (FP power + near refractive adjustment power)
Here, the addition is the difference between the refractive power of the near portion and the refractive power of the far portion and is indicated by a negative value.

  Table 1 below shows changes in focal length at intersections 41a, 41b,..., 41j of the scale mark 40 drawn in the layout mark in a progressive-power lens having a progressive zone length of 20 mm. According to Table 1, for example, in the progressive addition lens 10 having an addition power of −2.00 D, if the near focal length is 30 cm when the reference mark 38 and the pupil position of the wearer are matched, As shown in the upper right block of Table 1, by selecting each of the intersection points 41a, 41b,..., 41j of the scale mark 40 in place of the reference mark 38, the focal length at the fitting point, that is, the wearer becomes horizontal. It can be seen that the focal length when viewed can be adjusted between 30.9 cm and 42.9 cm.

FIG. 3 is a diagram showing the astigmatism distribution of the lens 50 as a specific example of the present embodiment. The main data of this lens 50 is as follows.
Near-use frequency: 0.00 (D),
Addition: -2.00 (D)
Progressive zone length: 20 (mm),
Refractive index n: 1.608,
Lens outer diameter: 75 (mm)

In the lens 50, it is set near design reference point K ₀ in the geometric center O, is set near zone 14 in the entire area of the lower area from the geometric center O of the lens. A progressive portion 16 is set in a range of 20 mm upward from the geometric center O.
The distribution diagram of astigmatism shown in FIG. 3 is represented by contour lines with a step width of an aberration amount of 0.50D, and a low aberration region (based on the minimum contour line (aberration amount of 0.50D)). The white area in the figure is the clear vision area. In this lens 50, the astigmatism peaks 51a and 51b are designed to be located on the side of the progressive portion 16, and a low aberration region (clear vision) having an aberration amount of less than 0.50D in the area below the geometric center O. The ratio of (region) is 70.6%.

FIG. 4 is a view showing a state in which the lens 50 is put in the spectacle frame 52. In the figure, the two-dot chain line indicates the outer shape of the lens 50 before the outer shape is processed. A white background portion of the lens 50 indicates a clear vision region having an aberration amount of less than 0.50D. Although the layout mark shown in FIG. 1B is provided on the front surface of the lens 50, only necessary marks are shown here, and the other marks are not shown.
In the example of FIG. 4, the upper distance portion 12 in the lens 50 is removed by outer shape processing, and only the near portion 14 and the progressive portion 16 are fitted in the spectacle frame 52.

FIG. 4A shows a state where the reference mark 38 is framed as a fitting point, and the reference mark 38 coincides with the pupil position 54 on the frame side.
As shown in the figure, a wide low aberration region is formed below the pupil position 54, and a wide field of view can be secured in the near portion 14. In this case, the focal length obtained by the wearer in the horizontal view through the reference mark 38 having the same power 0.00D as the near power is 30 cm.

On the other hand, FIG. 4B shows a state in which the intersection 41e 5mm above the reference mark 38 is selected as a fitting point and framed. In this case, the focal length that the same wearer can obtain in the horizontal view is changed from 30 cm in the case of FIG. 4A to 35.3 cm.
In this case, the entire lens is lowered 5 mm below the spectacle frame 52, but in this example, the portion below the geometric center O of the lens is used as the near portion 14, so the wearer increases the line of sight. Even if it is not moved, it can be viewed near at a predetermined frequency if it is moved 5 mm downward.
The lens 50 has a low aberration region (clear vision region) of 70.6% secured in the near portion 14 below the geometric center O, and as a result, the lens 50 moves downward by 5 mm. Even if the area of the near portion 14 in 52 decreases in the vertical direction, a wide clear vision region is secured in the left and right direction of the near portion 14.

  As described above, in the present embodiment, when the progressive addition lens 10 (50) is framed in the spectacle frame, the reference mark 38 indicating a standard fitting point as a point on the lens side that matches the pupil position of the wearer. In addition, the intersection points 41a, 41b,..., 41j having different frequencies in the progressive portion 16 can be selected. For this reason, in this embodiment, the focal distance in the state which the wearer viewed horizontally, ie, the focal distance in a fitting point, can be adjusted to a desired value.

  In the present embodiment, the reference mark 38 is provided at the boundary between the near portion 14 and the progressive portion 16, and the near power can be selected as the frequency at the fitting point.

  In the present embodiment, the boundary between the near portion 14 and the progressive portion 16 is provided at the geometric center O of the lens. With such a lens configuration, the near portion 14 starts immediately below the geometric center O of the lens. As a result of adjusting the focal length at the fitting point, the lens moves downward with respect to the spectacle frame, Even when the near portion 14 is lowered below the spectacle frame, the line of sight of the wearer can reach the near portion 14 with a small amount of movement.

  In the present embodiment, the near portion 14 is set in the entire area below the geometric center O of the lens, and it is possible to secure a wide area that can be used for near vision in the vertical and horizontal directions. it can. In particular, in the present embodiment, astigmatism peaks 51a and 51b are formed on the side of the progressive portion 16, and the ratio of the clear vision region in the area below the geometric center O of the lens is 70% or more. Therefore, even when the near portion 14 is lowered downward in accordance with the adjustment of the focal length at the fitting point, it is possible to suppress discomfort and discomfort due to the limited visual field in the left-right direction.

FIG. 5 shows a lens according to another embodiment of the present invention. In the above embodiment, the near portion 14 is set in the entire area below the geometric center O of the lens. However, in the lens 60 shown in FIG. The prescribed near power is set in a region partitioned by a boundary line 61L extending downward and a boundary line 61R extending diagonally rightward and downward through the geometric center O, and used as the near portion 14 Yes. In this case, it is desirable that the angles θ ₁ and θ _{2 with} respect to the X-axis of each boundary line are within 25 °, and the near portion 14 is secured at 130 ° or more in the circumferential direction.

Although the embodiments of the present invention have been described in detail above, these are merely examples.
For example, the number and interval of a plurality of scale lines provided on the progressive part can be changed as appropriate. Further, if an astigmatism power is prescribed for the progressive power lens, an astigmatism power component can be added to the rear surface of the lens. In addition, the present invention can be configured in various forms without departing from the gist of the present invention, such as a lens configuration in which progressive components and power components are set on the front and rear surfaces, that is, both surfaces.

10, 50, 60 Progressive power lens 14 Near portion 16 Progressive portion 38 Reference mark 40k Vertical reference lines 40a, 40b, 40c, 40d, 40e, 40f, 40g, 40h, 40i, 40j Scale lines 41a, 41b, 41c, 41d, 41e, 41f, 41g, 41h, 41i, 41j Intersection O Geometric center

Claims (5)

A progressive power lens having a near portion corresponding to near vision and a progressive portion that extends upward from the upper end of the near portion and progressively changes its refractive power. ,
On the lens surface, as a layout mark, a reference mark indicating a standard fitting point, and a plurality of graduation lines indicating points of different degrees in the progressive portion crossing a vertical reference line extending in a vertical direction from the reference mark, Progressive power lens characterized by being applied.   2. The progressive power lens according to claim 1, wherein the reference mark is provided at the near portion or a boundary between the near portion and the progressive portion.   2. The progressive power lens according to claim 1, wherein a boundary between the near portion and the progressive portion is provided at or near the geometric center of the lens.   4. The progressive power lens according to claim 3, wherein the near portion is set in the entire area below the geometric center of the lens.   2. The astigmatism peak according to claim 1, wherein the peak of astigmatism is on the side of the progressive portion, and the ratio of the clear vision region in the area below the geometric center of the lens is 70% or more. Progressive power lens.

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