JP2014085575A - Ophthalmic lens design method, ophthalmic lens and ophthalmic lens manufacturing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ophthalmic lens that satisfies individual needs for each wearer as to visibility in the vicinity of an eye point.SOLUTION: The ophthalmic lens design method of designing an ophthalmic lens including a portion for distance vision having a refracting power corresponding to a distant view, a portion for near vision having a refracting power corresponding to a near view and an intermediate portion provided between the portion for distance vision and the portion for near vision and continuously connecting the refracting powers of the portion for distance vision and the portion for near vision is configured to design the ophthalmic lens such that as to a parameter for determining an addition power to be added to a position in the vicinity of the eye point in the ophthalmic lens, an optional value is designated by an order-placing party and the addition power to be determined by the designated parameter is added at a position in the vicinity of the eye point.

Description

  The present invention relates to a spectacle lens design method, a spectacle lens, and a spectacle lens manufacturing method.

  As a corrective spectacle lens to compensate for the decline in adjustment power due to presbyopia, in the wearing state, a distance portion that is located above the lens and has a refractive power corresponding to a distant view, and a near view located below the lens A near portion that is a region having a refractive power corresponding to, and a region that is located between the distance portion and the near portion and that is connected by continuously and smoothly changing the refractive power of the distance portion and the near portion. There is known a progressive-power lens having an intermediate portion.

  As a type of progressive power lens, there is known a type called a progressive power lens for the middle and near term (hereinafter referred to as a mid and near lens). The lens for middle and near is a lens that is designed to be suitable for viewing an intermediate distance (about 0.5m to 2.0m) in the vicinity of the eye point of the lens. It is.

JP 2010-145637 A

  The ratio of the addition at the eye point to the addition of the entire lens in a conventional near-near lens is uniquely determined by the designer from the specified distance power, the addition of the entire lens, and the progressive zone length. Or fixed for each spectacle lens product. Therefore, the individual needs for each wearer cannot be satisfied with respect to the appearance in the vicinity of the eye point.

(1) A spectacle lens design method according to the first aspect of the present invention includes a distance portion having a refractive power corresponding to a distant view, a near portion having a refractive power corresponding to a distant view, a distance portion, and a near portion. A spectacle lens design method for designing a spectacle lens having a middle portion that continuously connects refractive power from a distance portion to a near portion, and in the spectacle lens, near an eye point As for the parameter for determining the addition added to the position, an arbitrary value is designated by the orderer, and the addition determined by the designated parameter is added at the position near the eye point. It is characterized by designing.
(2) The spectacle lens according to the invention described in claim 4 is designed by the spectacle lens design method according to any one of claims 1 to 3.
(3) A spectacle lens manufacturing method according to the invention described in claim 5 is characterized in that the spectacle lens designed by the spectacle lens design method according to any one of claims 1 to 3 is manufactured.

  ADVANTAGE OF THE INVENTION According to this invention, the spectacle lens which satisfy | fills the individual needs for every wearer about the appearance in the eyepoint vicinity vicinity can be provided.

It is a figure which shows the outline | summary of the progressive-power lens which concerns on one embodiment of this invention. It is a figure which shows the structure of the spectacle lens provision system which concerns on one embodiment of this invention. It is a flowchart explaining the procedure which provides a spectacles lens. It is a figure which shows an example of an ordering screen. It is a figure which shows the example of a change of the addition degree of the lens for middle and near.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the following description, the unit of refractive power is represented by diopter (D) unless otherwise specified. Further, in the following description, when the progressive power lens is described as “upper”, “lower”, “upper”, “lower”, etc., the glasses are used when the progressive power lens is processed for spectacles. It is based on the positional relationship of the lenses when worn. In each of the following drawings, the positional relationship (up / down / left / right) of the lens is the same as the positional relationship (up / down / left / right) in the drawing.

  FIG. 1 is a diagram showing an outline of a progressive-power lens according to this embodiment. As shown in FIG. 1, the progressive addition lens LS is in a state before processing the lens according to the shape of the spectacle frame (a state before lashing processing), and is formed in a circular shape in plan view. Yes. The progressive-power lens LS is arranged on the upper side in the figure when worn, and the lower side in the figure is arranged on the lower side when worn. The progressive-power lens LS has a distance portion F, a near portion N, and an intermediate portion P. The progressive-power lens LS according to the present embodiment is a kind of progressive-power lens called a medium-to-near progressive-power lens (hereinafter, referred to as a “middle-and-near lens LS”).

  The distance portion F is disposed above the middle and near lens LS and becomes a portion having a refractive power corresponding to a distant view after the middle and near lens LS is processed for spectacles. The near portion N is disposed below the middle and near lenses LS, and becomes a portion having a refractive power corresponding to the near view after the middle and near lenses LS are processed for glasses. The intermediate portion P is disposed in the middle between the distance portion F and the near portion N of the middle and near lens LS, and the refractive power between the distance portion F and the near portion N is continuously smoothed. It is the part that is changed and connected.

  The middle and near lens LS has a plurality of reference points. Examples of such a reference point include an eye point (also called a fitting point) EP, a distance reference point FV, and a near reference point NV, as shown in FIG. The eye point EP is a reference point when the wearer wears the lens. The distance reference point FV is a measurement reference point for measuring the distance power of the lens. The near reference point NV is a measurement reference point for measuring the near power of the lens in the near portion N. The refractive power at the distance reference point FV is set based on, for example, the distance power specified by the prescription (hereinafter, referred to as distance prescription power). The refractive power at the near reference point NV is set based on, for example, the addition specified by the prescription (hereinafter referred to as prescription addition) and the distance prescription power.

  The middle and near lens LS according to the present embodiment is a lens that is designed to be suitable for viewing an intermediate distance near the eye point EP of the lens. In the middle and near lens LS, the distance reference point FV is disposed above the eye point EP, and the addition is also added to the eye point EP.

  In conventional middle and near-field lenses, the ratio of the addition at the eye point to the prescription addition (addition of the entire lens) (hereinafter referred to as addition ratio) is the specified distance prescription power and prescription addition. In addition, it was decided by the designer from the progressive zone length, or fixed for each spectacle lens product. For example, in a spectacle lens product in which the addition ratio at the eye point is fixed at 40%, the spectacle lens is designed according to the distance prescription power, prescription addition degree, and progressive band length according to the wearer. The spectacle lens is designed so that the addition ratio at points is uniformly 40% regardless of the wearer. For this reason, regarding the way the eyepoint looks, the individual needs of each wearer cannot be reflected in the design of the spectacle lens. Therefore, in the present embodiment, in order to satisfy the individual needs of the wearer with respect to the appearance at the eye point, an arbitrary value corresponding to the individual needs of the wearer is set for the addition ratio at the eye point. The design of middle- and near-end lenses has been started.

  For example, an example where the wearer has an adjustment force (adjustment force actually used) of 2.00 D, the wearer's distance prescription power is 0.00 D, and the prescription addition power is 2.00 D is an example. Think about it. In this case, assuming that the addition ratio at the eye point is 40%, for example, the refractive power in the state where the adjusting force is not applied at the eye point is 0.80D, and in the state where the adjusting force is applied to the maximum. The refractive power is 2.80D. Therefore, the far point at the eye point is 125 cm and the near point is 36 cm. The far point is a position where the focus is achieved with no adjustment force applied, and the near point is a position where the focus is achieved with the adjustment force applied to the maximum.

  Here, the wearer considers a case where the closest distance that can be seen at the eye point may be about 40 cm, and there is a need to see farther than 125 cm at the eye point. In this case, if the addition ratio at the eye point is changed to, for example, 25%, the refractive power in the state where no adjustment force is applied at the eye point becomes 0.50D, and the adjustment force is maximized. The refractive power is 2.50D. Therefore, the far point at the eye point is 200 cm, and the near point is 40 cm. Therefore, it is possible to satisfy the needs of the wearer who wants to look farther at the eye point.

  On the other hand, consider a case where the wearer has a need to make the distance seen by the eye point closer than 36 cm. In this case, when the addition ratio at the eye point is changed to, for example, 50%, the refractive power at the eye point when the adjusting force is not applied at all becomes 1.00D, and the refraction at the state where the adjusting force is applied at the maximum is performed. The force is 3.00D. Therefore, since the far point at the eye point is 100 cm and the near point is 33 cm, it is possible to satisfy the needs of the wearer who wants to look closer at the eye point.

  As described above, in the middle and near lens according to the present embodiment, by setting the addition ratio at the eye point according to the individual needs of the wearer, the eye point can be seen without changing the prescription addition degree. The individual needs of each wearer regarding distance can be satisfied.

  Next, the spectacle lens providing system according to the present embodiment will be described. The spectacle lens providing system according to the present embodiment is a system that can provide a mid-range lens designed by setting an addition ratio at an eye point in accordance with the individual needs of the wearer as described above. .

  FIG. 2 is a diagram illustrating a configuration of the eyeglass lens providing system according to the present embodiment. The spectacle lens providing system includes an ordering device 1 installed on the spectacle store side, an order receiving device 2 installed on the lens manufacturer side, a processing machine control device 3, and a spectacle lens processing machine 4. The ordering device 1 and the order receiving device 2 are communicably connected via a network 5 such as the Internet. A processing machine control device 3 is connected to the order receiving device 2, and a spectacle lens processing machine 4 is connected to the processing machine control device 3. In FIG. 2, only one ordering device 1 is shown for the sake of illustration, but actually, a plurality of ordering devices 1 installed in a plurality of spectacle stores are connected to the order receiving device 2.

  The ordering device 1 is a computer that performs an ordering process for eyeglass lenses, and includes a control unit 11, a storage unit 12, a communication unit 13, a display unit 14, and an input unit 15. The control unit 11 performs overall control of the ordering device 1 by executing a program stored in the storage unit 12. The communication unit 13 communicates with the order receiving device 2 via the network 5. The display unit 14 is a display device such as a CRT or a liquid crystal display, for example, and displays an ordering screen for inputting information (ordering information) about spectacle lenses to be ordered. The input unit 15 includes, for example, a mouse and a keyboard. For example, ordering information corresponding to the content of the ordering screen is input via the input unit 15.

  The order receiving device 2 is a computer that performs spectacle lens order receiving processing, design processing, optical performance calculation processing, and the like, and includes a control unit 21, a storage unit 22, a communication unit 23, a display unit 24, and an input unit 25. It is comprised including. The control unit 21 performs overall control of the order receiving device 2 by executing a program stored in the storage unit 22. The communication unit 23 communicates with the ordering device 1 via the network 5 and communicates with the processing machine control device 3. The storage unit 22 stores various data for eyeglass lens design in a readable manner. The display unit 24 is a display device such as a CRT or a liquid crystal display, for example, and displays a design result of the spectacle lens. The input unit 25 includes, for example, a mouse and a keyboard.

  Next, a procedure for providing a spectacle lens in the spectacle lens providing system will be described with reference to a flowchart shown in FIG. The left side of FIG. 3 shows the procedure performed on the spectacle store side, and the right side of FIG. 3 shows the procedure performed on the lens manufacturer side. In step S1, the orderer determines ordering information for the spectacle lens to be ordered. Then, the orderer displays an ordering screen on the display unit 14 of the ordering apparatus 1 and inputs ordering information via the input unit 15.

  FIG. 4 is a diagram illustrating an example of the ordering screen 100. In the lens information item 101, items related to the lens order power such as the product name of the lens to be ordered, spherical power (S power), astigmatism power (C power), astigmatism axis degree, and addition power are input. The processing designation information item 102 is used when designating the outer diameter of the lens to be ordered or designating an arbitrary point thickness. The staining information item 103 is used when a lens color is designated. The eye point information 104 inputs the position information of the wearer's eyes. In the frame information item 105, a frame model name, a frame type, and the like are input.

  In addition, when the lens to be ordered is the above-described middle or near lens, an addition ratio information item 106 is further displayed on the ordering screen 100. The addition ratio information item 106 is an area for designating the addition ratio at the eye point, and an arbitrary value can be input within a predetermined range (for example, 15 to 50%). As for the addition ratio at the eye point, for example, a salesperson (orderer) of an eyeglass store hears the needs of customers (wearers), and determines the addition ratio that meets the needs of the customers. For example, as described above, the distance that the customer wants to see at the eye point is interviewed, and the addition ratio is determined according to the distance. The addition ratio is increased as the distance desired to be viewed at the eye point is closer, and the addition ratio is determined as lower as the distance desired to be viewed at the eye point is longer.

  When the orderer inputs each item on the ordering screen 100 in FIG. 4 and clicks a transmission button (not shown), the ordering apparatus 1 acquires information (ordering information) input in each item on the ordering screen 100. Then, the process proceeds to step S12. In step S <b> 12, the ordering device 1 transmits the ordering information to the order receiving device 2 via the communication unit 13.

  In the ordering apparatus 1, the process of displaying the ordering screen 100, the process of acquiring the ordering information input on the ordering screen 100, and the process of transmitting the ordering information to the ordering apparatus 2 are performed by the control unit 11 of the ordering apparatus 1. Is performed by executing a predetermined program installed in the storage unit 12 in advance.

  In step S21, when the order receiving device 2 receives the ordering information from the ordering device 1 via the communication unit 23, the order receiving device 2 proceeds to step S22. In step S22, the control unit 21 of the order receiving device 2 designs a spectacle lens based on the received ordering information.

  Specifically, in the case where the lens to be designed is the above-described middle- or near-lens, the order receiving device 2 satisfies the addition degree specified by the ordering information, and the addition degree of the entire lens satisfies the addition degree specified by the ordering information. The spectacle lens is designed so that the addition determined by the addition ratio is added at the eye point.

  For example, in the graph shown in FIG. 5, the addition specified by the ordering information (that is, the addition of the entire lens) is 2.00D, and the addition ratios specified by the ordering information are 15%, 25%, and 40, respectively. It is a graph which shows the example of a change of the addition degree of the middle and near lens designed by the order receiving apparatus 2 in the case of% and 50%. In addition, the vertical axis | shaft of a graph shows addition power (D), and the horizontal axis of a graph shows the position in the Y coordinate which made the up-down direction of FIG. 1 the Y axis.

  For example, in a middle and near lens whose addition ratio specified by the ordering information is 15%, the addition at the eye point EP determined by the addition ratio is 0.30D. Therefore, in the order receiving device 2, the addition at the distance reference point FV satisfies 0.00D, the addition at the eye point EP satisfies 0.30D, and the addition at the near reference point NV satisfies 2.00D. The spectacle lens is designed so that the change in addition from the reference point FV to the near reference point NV through the eye point EP becomes smooth.

  The order receiving device 2 similarly uses the distance reference point FV, the eye point EP, and the near reference point NV in the middle and near lenses whose addition ratios specified by the ordering information are 25%, 40%, and 50%, respectively. The eyeglass lens is designed so that the addition and the addition ratio specified by the ordering information are satisfied and the change in addition is smooth. Further, the order receiving device 2 designs the spectacle lens so as to satisfy the target optical performance for other optical performances (for example, distance diopter, astigmatism, distortion, etc.).

  Note that the order receiving device 2 may not be able to design an appropriate spectacle lens with the specified addition ratio in consideration of the specified distance dioptric power, the addition power of the entire lens, the progressive zone length, and the like (for example, If the target optical performance cannot be achieved or is not suitable for eyeglass lens processing), information indicating that is transmitted to the ordering apparatus 1 to prompt the orderer to specify the addition ratio again. It may be.

  In step S23, the order receiving device 2 outputs the spectacle lens design data designed in step S22 to the processing machine control device 3. The processing machine control device 3 sends a processing instruction to the spectacle lens processing machine 4 based on the design data output from the order receiving device 2. As a result, a spectacle lens based on the design data is processed and manufactured by the spectacle lens processing machine 4. Then, the spectacle lens manufactured by the spectacle lens processing machine 4 is shipped to the spectacle store and is fitted into the spectacle frame and provided to the customer.

  In the order receiving device 2, processing for receiving order information from the ordering device 1, processing for designing a spectacle lens based on the received ordering information, and processing for outputting spectacle lens design data to the processing machine control device 3. This is performed by the control unit 21 of the order receiving device 2 executing a predetermined program installed in the storage unit 22 in advance.

According to the embodiment described above, the following operational effects can be obtained.
The spectacle lens design method of the present embodiment is provided between a distance portion having a refractive power corresponding to a distant view, a near portion having a refractive power corresponding to a close view, and a distance portion and a near portion. An eyeglass lens design method for designing an eyeglass lens having an intermediate portion for continuously connecting refractive power from a use portion to a near portion, and an addition power added to an eye point with respect to the addition power of the entire eyeglass lens The spectacle lens is designed so that an arbitrary value is designated by the orderer and the addition determined by the specified addition ratio is added at the eye point. In this way, the orderer designates a value according to the wearer's desire for the addition ratio at the eye point, and the designer designs the mid-range lens so as to satisfy the designated addition ratio. Thus, it is possible to provide a mid-to-neighboring lens that satisfies the individual needs of each wearer in terms of how the eyepoints are visible.

(Modification 1)
In the above-described embodiment, the example in which an arbitrary value according to the wearer's desire is specified for the addition ratio at the eye point in the near-near lens has been described. However, the present invention is not limited to this. Other parameters may be designated as long as they are parameters for determining the addition power to be added. For example, the addition value added to the eye point may be designated directly, or the distance that the wearer wants to see at the eye point may be designated. When the distance that the wearer wants to see at the eye point is designated, an addition degree that allows the designated distance to be visually recognized may be added to the eye point at the time of designing the mid-to-near lens.

(Modification 2)
In the above-described embodiment, the example in which an arbitrary value according to the wearer's desire is specified for the addition ratio at the eye point in the middle and near lenses has been described. However, the position for designating the addition ratio is not limited to the eye point, and may be a position near the eye point. The position in the vicinity of the eye point is, for example, a lens for the near-neighbor from the position that is separated from the eye point by 10% of the progressive zone length of the lens for the near-near, including the position of the eye point. It is a position within a range up to a position separated by 25% of the progressive zone length.

(Modification 3)
In the above-described embodiment, the example in which the programs executed in the ordering device 1 and the order receiving device 2 are installed in advance has been described, but it is not necessary to limit to this content. The program to be executed and its installation program may be provided on a recording medium such as a CD-ROM. Note that the recording medium is not limited to the CD-ROM, and a DVD, a magnetic tape, a flexible disk, or any other recording medium may be used.

  Further, these programs can be provided via a transmission medium such as a communication line represented by the Internet. That is, it is possible to convert the program into a signal transmitted through the communication line and transmit it. Since the ordering device 1 and the order receiving device 2 are connected to the network 5, the program may be provided from another program server computer via the network 5.

  In the above-described embodiment, an example in which a predetermined program is executed in the ordering apparatus 1 has been described. However, the present invention is not limited to this content. For example, the lens manufacturer order receiving device 2 may present all information on a Web screen. The ordering apparatus 1 only needs to install browser software, and it is only necessary to input ordering information in accordance with instructions on the Web screen transmitted from the order receiving apparatus 2.

  The above description is merely an example, and is not limited to the configuration of the above embodiment. Moreover, you may combine the structure of each modification suitably with the said embodiment.

DESCRIPTION OF SYMBOLS 1 ... Ordering device, 2 ... Order receiving device, 3 ... Processing machine control device, 4 ... Eyeglass lens processing machine, 5 ... Network, 11, 21 ... Control part, 12, 22 ... Storage part, 13, 23 ... Communication part, 14 , 24 ... display section, 15, 25 ... input section

Claims (5)

A distance portion having a refractive power corresponding to a distant view, a near portion having a refractive power corresponding to a close view, and the distance portion to the near portion provided between the distance portion and the near portion. A spectacle lens design method for designing a spectacle lens having an intermediate portion for continuously connecting refractive powers up to
In the spectacle lens, an arbitrary value is designated by the orderer for the parameter for determining the addition added to the position in the vicinity of the eye point, and the addition determined by the designated parameter is in the vicinity of the eye point. The spectacle lens design method, wherein the spectacle lens is designed to be added at the position of the spectacle lens. In the spectacle lens design method according to claim 1,
The parameter for determining the addition added to the position in the vicinity of the eye point is a ratio of the addition added to the position in the vicinity of the eye point with respect to the addition of the entire spectacle lens, and the wearer sets the eye point in the eye point. A spectacle lens design method, which is one of a distance desired to be viewed at a nearby position and an addition added to a position near the eye point. The spectacle lens design method according to claim 1 or 2,
The position in the vicinity of the eye point is the position of the progressive zone length of the spectacle lens from the position that is 10% of the progressive zone length of the spectacle lens upward from the eye point, including the position of the eye point. A spectacle lens design method characterized by being a position within a range up to a position separated by 25%.   A spectacle lens designed by the spectacle lens design method according to claim 1.   The spectacle lens manufacturing method characterized by manufacturing the spectacle lens designed by the spectacle lens design method as described in any one of Claims 1-3.

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