KR20160080208A - UV transmittance of the other spectacle lens refractive power measuring apparatus and method - Google Patents

Abstract

The present invention relates to an apparatus and a method to measure a UV transmission ratio of an eyeglasses lens having different refractive power capable of simply and accurately measuring the UV transmission ratio without correcting the UV transmission ratio, even measuring the eyeglasses lens having different refractive power. The apparatus to measure the UV transmission ratio comprises: a UV light source to emit a UV light to a measuring target; a UV diffuser to equal the UV light emitted by the UV light source; a pin-hole to pass the UV light equalized by the UV diffuser to a minute penetration hole; a light path setting unit to set a light path of the UV light source passing through the pin-hole; and a UV detector to detect the UV light passing through a measuring target located on the light path.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus and a method for measuring UV transmittance of a spectacle lens having different refractive powers,

The present invention relates to measurement of ultraviolet rays (UV) transmittance of spectacle lenses having different refractive powers. In particular, even when a spectacle lens having different refractive powers is measured, a refractive power such that a UV transmittance can be easily and accurately specified without correcting the UV transmittance And an apparatus and method for measuring the UV transmittance of other spectacle lenses.

Generally, UV shielding coatings are performed on spectacle lenses (including lenses for sunglasses) to shield harmful ultraviolet (UV) light from the sunlight. The UV transmittance of such a spectacle lens is measured by a UV transmittance measurement module comprising a UV light source for irradiating UV light (UV ray, ultraviolet ray) with a lens and a UV sensor for detecting UV light passing through the lens. That is, after the measured lens is placed on the measurement module and the UV light is irradiated, the intensity of the UV light passing through the measured lens is detected by the UV sensor, and the UV transmittance of the lens is measured.

Generally, in order to measure the transmittance of the entire UV band, a Xenon bulb, a UV LED emitting a short wavelength light of 400 nm or shorter, or the like is used as the UV light source. The UV transmittance of the lens to be measured can be calculated by comparing the intensity of the UV light thus detected with previously calibrated data.

Since the conventional UV transmittance measurement module measures and calculates the UV transmittance under the assumption that the refractive power of the lens is 0D (diopter), there is a difference between the calculated UV transmittance and the actual UV transmittance of the spectacle lens.

That is, in a general spectacle lens having a refractive power, incident light and transmitted light proceed at different angles in proportion to the focal length of the lens. For example, when parallel light enters a lens of (-) diopter, The transmitted light diverges, and when the parallel light enters the (+) diopter lens, the transmitted light converges to an arbitrary point. Since the UV sensor is located at a certain distance from the lens to be measured, the intensity of the transmitted UV light basically varies depending on the UV transmittance of the lens but also on the focal length of the lens. Therefore, when the measurement lens is not a plano lens, errors occur in the actual UV transmittance and the measured UV transmittance.

In this case, the same UV-blocking coating as that coated on the spectacle lens is coated on the planar lens in the same manner, and the UV transmittance of the planar lens is measured and used as the UV transmittance value of the spectacle lens. In this case, There is a disadvantage in that the measurement value is inaccurate because the measurement work is troublesome and the UV transmittance is indirectly measured.

In order to overcome such drawbacks, a conventionally proposed technique is disclosed in the following Patent Document 1: Korean Published Patent Application No. 10-2012-0115017 (published on October 17, 2012).

The prior art disclosed in Patent Document 1 includes a refractive power measurement light source unit for irradiating a refractive power measurement light with a measured lens and a refractive power measurement light beam having a changed optical path according to the refractive power of the measured lens while passing through the measured lens, The detected refractive power measurement light

A lens metering section including a refractive power detecting section for calculating an optical characteristic of the lens from the light amount distribution and the imaging position; A UV transmittance measuring unit for measuring a UV transmittance of the lens to be measured, the UV transmittance measuring unit including a UV light source for irradiating the UV light with the measured lens and a UV sensor for detecting the UV light passing through the measured lens; And a calculator receiving the refractive power of the lens to be measured from the lens metering unit, receiving the UV transmittance of the lens to be measured from the UV transmittance measuring unit, and correcting the UV transmittance according to the refractive power of the input lens.

In the conventional technique configured as described above, the optical characteristic including the refractive power of the measured lens is measured, the UV transmittance of the measured lens is measured, and the UV transmittance is corrected according to the refractive power of the measured lens.

Korean Patent Publication No. 10-2012-0115017 (published on October 17, 2012)

However, the conventional technique described above has the inconvenience that the UV transmittance specified according to the refractive power of the measured lens must be corrected again.

For example, the UV transmittance of the spectacle lens having different refractive powers can not be directly measured using one UV transmittance measuring apparatus, and the UV transmittance of the spectacle lens is first measured, and then the measurement is made according to the refractive power of the spectacle lens The UV transmittance must be corrected through calculation.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve all of the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a spectacle lens which can measure a UV transmittance easily and accurately without correcting the UV transmittance, And an object of the present invention is to provide an apparatus for measuring the UV transmittance of a spectacle lens and a method thereof.

Another object of the present invention is to provide an apparatus and a method for measuring the UV transmittance of a spectacle lens having different refractive powers so that the UV transmittance can be accurately measured by a single UV transmittance measurement operation with respect to spectacle lenses having different refractive powers.

According to an aspect of the present invention, there is provided an apparatus for measuring UV transmittance of a spectacle lens having different refractive powers, including: a UV light source for irradiating UV light to a measurement object; A UV diffuser to uniformize the UV light emitted from the UV light source; A pin-hole through which uniform UV light is passed through the fine penetrating hole in the UV diffuser; A light path setting unit for setting an optical path of the UV light source that has passed through the pin-hole; And a UV detector for detecting UV light having passed through the measurement object located on the optical path.

Wherein the optical path setting unit sets the optical path so that the UV light source passing through the pin-hole reaches only a part of the UV detector.

In the above, the optical path setting unit uses a focusing lens.

And a measurement reference plane for setting a measurement position of the measurement object between the optical path setting unit and the UV detector.

In this case, the measurement reference plane is a position where the error of the measured value is minimized even when the refractive power of the measurement object changes.

In this case, the measurement reference plane is set at a position where the refractive power of the measurement object does not deviate from the detection area of the UV detector even at a value of -25D to + 25D.

The UV detector may include a cover for setting an incident area of the UV light set by the light path setting unit in the light incidence part.

The UV detector includes a fluorescent lamp and an ultraviolet filter for blocking direct sunlight and passing only UV light of a specific wavelength.

The UV detector includes a cover on the upper part, a detector for detecting UV light at the lowermost part, and an ultraviolet filter between the cover and the detector.

According to another aspect of the present invention, there is provided a method of measuring a UV transmittance of a spectacle lens having different refractive powers, the method comprising the steps of: (a) (b) uniformizing the irradiated UV light; (c) setting an optical path of the uniformed UV light; (d) detecting UV light having passed through the measurement object located on the optical path.

Wherein the step (c) is characterized in that the optical path is set so that UV light reaches only a part of the UV detector.

The measurement reference plane for setting the measurement position of the measurement object is formed on the optical path of the step (c) and the step (d).

Wherein the measurement reference plane is a position where an error of the measurement value is minimized even when the refractive power of the measurement subject is changed and the refractive power of the measurement subject is set at a position that does not deviate from the detection area of the UV detector even at a value of -25D to + do.

According to the present invention, even when a spectacle lens having different refractive powers is measured, the UV transmittance can be measured simply and accurately without correcting the UV transmittance.

Further, according to the present invention, there is an advantage that the UV transmittance can be accurately measured by a single UV transmittance measurement operation for a spectacle lens having different refractive powers.

1 is an external perspective view of a UV transmittance measuring apparatus of a spectacle lens having a different refractive power according to the present invention,
FIG. 2 is a view showing a configuration of an apparatus for measuring the UV transmittance of a spectacle lens having different refractive powers according to the present invention,
3 is a diagram illustrating an example of a user interface screen for measuring UV transmittance in the present invention,
4 is a graph showing a UV transmittance characteristic graph in the present invention,
5 is a flowchart showing a UV transmittance measuring method of a spectacle lens having different refractive powers according to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an apparatus and method for measuring UV transmittance of a spectacle lens having different refractive powers according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an external perspective view of a lens meter 10 to which an apparatus for measuring UV transmittance of a spectacle lens having different refractive powers according to a preferred embodiment of the present invention is applied. In order to measure the optical characteristics of the spectacle lens 1 according to the corrected visual acuity A lens meter unit 20; And a UV transmittance measuring device 30 for measuring the UV transmittance. The optical characteristics may include a spherical power, a cylindrical power, and a cylindrical axis.

Here, the configuration and method of measuring the optical characteristics of the spectacle lens 1 in the lens metering section 20 are the same as those in the conventional method of measuring the optical characteristics of the spectacle lens in the lens meter. Is omitted.

2, the UV transmittance measuring apparatus 30 includes a UV light source 31, a UV diffuser 32, a pin-hole 33, a light path setting unit 34, a measurement reference plane 35, And a UV detector 36.

The UV light source 31 serves to irradiate the UV light to the object 1 to be measured. Here, it is preferable that the UV light source 31 uses a UV LED having a wavelength of 385 to 395 nm.

The UV diffuser 32 serves to uniformly irradiate the UV light emitted from the UV light source 31. The UV diffuser 32 serves to diffuse and uniformize the UV light.

The pin-hole 33 serves to pass the UV light uniformized in the UV diffuser 32 through a fine through hole (? 0.6).

The optical path setting unit 34 sets the optical path of the UV light source that has passed through the pin-hole 33. It is preferable that the light path setting unit 34 sets the light path so that the UV light source that has passed through the pin-hole 33 reaches only a part of the UV detector 36. Various lenses can be used for optical path setting. In the present invention, a focusing lens (fused lens) having f = 12 mm is used.

The UV detector 36 detects the UV light having passed through the measurement object 1 located on the optical path. The UV detector 36 includes a COVER 36a for setting an incident area of the UV light set by the light path setting unit 34 in the light incidence portion, and blocks external fluorescent light and direct sunlight, (Detection area: 13 mm 2) 36 c that includes an ultraviolet filter (UV filter) 36 b for passing only UV light of a wavelength (for example, a wavelength of 400 nm or less) .

The UV detector 36 is provided with a cover 36a on its upper portion and a detector 36c for detecting UV light on its lowermost portion and an ultraviolet filter 36b is provided between the cover 36a and the detector 36c. .

The measurement reference plane 35 is formed between the optical path setting unit 34 and the UV detector 36 and serves to set the measurement position of the measurement target 1. The measurement reference plane 35 is a position at which the error of the measurement value is minimized even when the refractive power of the measurement target 1 is changed. Even when the refractive power of the measurement target 1 is -25D to + 25D, As shown in FIG.

The operation of the apparatus for measuring the UV transmittance of a spectacle lens having different refractive powers according to a preferred embodiment of the present invention will be described in detail as follows.

First, in a state in which driving power is supplied to the lens meter 10, a program for measuring the UV transmittance is activated through the operation. When a program for measuring the UV transmittance is activated, a UV transmittance measurement user interface (UI) screen as shown in Fig. 3 is displayed on the screen of the display device.

In this state, the inspector puts the spectacle lens, which is the UV transmittance measurement object 1, on the predetermined measurement reference plane 35 and inputs an operation command for measuring the UV transmittance.

Here, the spectacle lens measurement reference plane 35 is formed on the optical path set by the optical path setting unit 34. [ Preferably, a convex lens (0 to + 25D) and a concave lens (0 to -25D) having different diopters are placed in the optical path to be set so as to set the position where the error of the measured value is minimized with respect to the change in refractive power of the spectacle lens desirable. More preferably, a position at which the refractive power of the spectacle lens as the measurement object 1 does not deviate from the active area of the UV detector 36 is set as the measurement reference plane even at a value of -25D to + 25D. Even when the UV transmittance of the spectacle lens having different refractive powers is measured through the measurement reference surface, the error can be minimized.

When the UV transmittance measurement command is inputted, the UV light source 31 irradiates the UV light to the measurement object 1. [ Here, the UV light source 31 may use a UV LED having a wavelength of 385 to 395 nm.

When UV light is irradiated from the UV light source 31, the UV diffuser 32 diffuses and uniformizes the irradiated UV light, and the thus uniformized UV light is formed in the pin-hole 33 Through a fine through hole (? 0.6).

The optical path setting unit 34 sets the path of the UV light to be irradiated through the pin-hole 33. Here, the light path setting unit 34 sets the light path so that the UV light source that has passed through the pin-hole 33 reaches only a part of the UV detector 36. Various lenses can be used for optical path setting, but in the present invention, a focusing lens (fused lens) having f = 12 mm is used.

Next, the UV detector 36 receives the UV light that has passed through the measurement object 1 located on the optical path, and measures the UV transmittance of the measurement object. The measured UV transmittance is displayed on the user interface screen as shown in Fig.

For example, the UV detector 36 is provided with a cover 36a at a portion where UV light is incident, and sets an incident area of the UV light set by the light path setting unit 34. [ The UV light having passed through the cover 36a passes only UV light of a specific wavelength band through the ultraviolet filter 36b. In other words, the ultraviolet filter 36b blocks UV light having a wavelength of 400 nm or more, and passes only UV light having a wavelength lower than that. By this action, it is possible to block external fluorescent lamps and direct rays having wavelength bands of the specific wavelength or more.

Next, the detector (detection area: 13 mm2) 36c receives the UV light that has passed through the ultraviolet filter 36b, processes it by a normal signal processing method, and measures the UV transmittance. The UV transmittance thus measured is displayed on the UV transmittance measurement user interface screen so that the user can easily recognize the UV transmittance.

4 is a graph showing a UV transmittance characteristic applied in the present invention. The UV transmittance characteristics for the two series (series 1, series 2) are shown.

According to the present invention, even when the spectacle lens having different refractive powers is measured, the UV transmittance can be measured simply and accurately without correcting the UV transmittance.

5 is a flow chart showing a method of measuring the UV transmittance of a spectacle lens having different refractive powers according to the present invention, and S shows a step.

The UV transmittance measurement method of spectacle lenses having different refractive powers according to the present invention comprises the steps of: (a) irradiating UV light to a measurement object (S10); (b) uniformizing the irradiated UV light (S20); (c) setting an optical path of the uniformed UV light (S30); (d) detecting UV light having passed through the measurement object located on the optical path (S40 to S50).

In the step (c), it is preferable to set the optical path so that the UV light reaches only a part of the UV detector. On the optical path of the step (c) and the step (d) Is preferably formed.

The measurement reference plane is a position where an error of the measurement value is minimized even when the refractive power of the measurement object changes, and the refractive power of the measurement object is set at a position that does not deviate from the detection area of the UV detector even at a value of -25D to + 25D.

The operation of the UV transmittance measuring method of the spectacle lens having different refractive powers according to the preferred embodiment of the present invention will be described in detail as follows.

First, in a state in which driving power is supplied to the lens meter 10, a program for measuring the UV transmittance is activated through the operation. When a program for measuring the UV transmittance is activated, a UV transmittance measurement user interface (UI) screen is displayed on the screen of the display device.

In this state, the inspector puts the spectacle lens, which is the UV transmittance measurement object 1, on the predetermined measurement reference plane 35 and inputs an operation command for measuring the UV transmittance.

When the UV transmittance measurement command is input, the UV light source 31 irradiates the UV light to the measurement object 1 in step S10. Here, the UV light source 31 may use a UV LED having a wavelength of 385 to 395 nm.

When the UV light is irradiated from the UV light source 31, the UV diffuser 32 diffuses and uniformizes the irradiated UV light in step S20, and the thus uniformized UV light passes through a pin-hole 33 Through a fine through-hole (?

Next, in step S30, the optical path setting unit 34 sets the path of the UV light to be irradiated through the pin-hole 33. [ Here, the light path setting unit 34 sets the light path so that the UV light source that has passed through the pin-hole 33 reaches only a part of the UV detector 36. Various lenses can be used for optical path setting, but in the present invention, a focusing lens (fused lens) having f = 12 mm is used.

In step S40, the UV light having passed through the measurement lens 1 placed on the measurement reference surface 35 positioned on the optical path is transmitted to the UV detector 36. [ Here, the spectacle lens measurement reference plane 35 is formed on the optical path set by the optical path setting unit 34. [ Preferably, a convex lens (0 to + 25D) and a concave lens (0 to -25D) having different diopters are inserted into the optical path to be set, and the position is set to a position where the error of the measured value is minimized even when the refractive power of the spectacle lens is changed desirable. More preferably, a position at which the refractive power of the spectacle lens as the measurement object 1 does not deviate from the active area of the UV detector 36 is set as the measurement reference plane even at a value of -25D to + 25D. The error can be minimized even if the UV projection ratio of the spectacle lens having different refractive powers is measured through the measurement reference plane.

Next, in step S50, the UV detector 36 receives the UV light that has passed through the measurement object 1 positioned on the optical path, and measures the UV projection rate of the measurement object. And the measured UV projection rate is displayed on the user interface screen as shown in Fig.

For example, the UV detector 36 is provided with a cover 36a at a portion where UV light is incident, and sets an incident area of the UV light set by the light path setting unit 34. [ The UV light having passed through the cover 36a passes only UV light of a specific wavelength band through the ultraviolet filter 36b. In other words, the ultraviolet filter 36b blocks UV light having a wavelength of 400 nm or more, and passes only UV light having a wavelength lower than that. By this action, it is possible to block external fluorescent lamps and direct rays having wavelength bands of the specific wavelength or more.

Next, the detector (detection area: 13 mm2) 36c receives the UV light that has passed through the ultraviolet filter 36b, processes it by a normal signal processing method, and measures the UV projection rate. The measured UV projection rate is displayed on the UV projection rate measurement user interface screen, allowing the user to easily recognize the UV projection rate.

According to the present invention, even when the spectacle lens having different refractive powers is measured, the UV transmittance can be measured simply and accurately without correcting the UV transmittance.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

The present invention is applied to a technique for measuring the UV transmittance of a spectacle lens in a lens meter.

1: spectacle lens
10: Lens meter
30: UV transmittance measuring device
31: UV light source
32: UV diffuser
33: Pin-hole
34: Optical path setting unit
35: measurement reference plane
36: UV detector

Claims (13)

A UV light source for irradiating UV light to a measurement object;
A UV diffuser to uniformize the UV light emitted from the UV light source;
A pin-hole through which uniform UV light is passed through the fine penetrating hole in the UV diffuser;
A light path setting unit for setting an optical path of the UV light source that has passed through the pin-hole; And
And a UV detector for detecting UV light having passed through the measurement object located on the optical path.
The apparatus according to claim 1, wherein the optical path setting unit sets the optical path so that the UV light source that has passed through the pin-hole reaches only a part of the UV detector.
The apparatus for measuring UV transmittance of a spectacle lens according to claim 1 or 2, wherein the optical path setting unit uses a focusing lens.
The apparatus for measuring UV transmittance of a spectacle lens according to claim 1, further comprising a measurement reference surface for setting a measurement position of the measurement object between the optical path setting unit and the UV detector.
5. The apparatus according to claim 4, wherein the measurement reference plane is a position where an error of a measured value is minimized even when the refractive power of the measurement subject changes.
The spectacle lens according to claim 3 or 4, wherein the measurement reference plane is set at a position where the refractive power of the measurement object does not deviate from the detection area of the UV detector even at a value of -25D to + 25D. Device.
The apparatus according to claim 1, wherein the UV detector includes a cover for setting an incident area of UV light set by the light path setting unit in a light incidence part.
The apparatus according to claim 7, wherein the UV detector includes a fluorescent lamp and an ultraviolet filter for blocking direct sunlight and allowing only UV light of a specific wavelength to pass therethrough.
The UV detector according to any one of claims 1 to 7, wherein the UV detector is provided with a cover on its upper portion, a detector for detecting UV light is formed at the lowermost portion, and an ultraviolet filter is provided between the cover and the detector Wherein the UV transmittance is measured by a spectacle lens having different refractive powers.
A method for measuring a UV transmittance of a spectacle lens having a different refractive power,
(a) irradiating UV light to a measurement object;
(b) uniformizing the irradiated UV light;
(c) setting an optical path of the uniformed UV light; And
(d) detecting UV light having passed through the object to be measured located on the optical path.
The method according to claim 10, wherein the step (c) sets the optical path so that the UV light reaches only a part of the UV detector.
[12] The method according to claim 11, wherein a measurement reference surface for setting a measurement position of the measurement object is formed on the optical path of the step (c) and the step (d).
The apparatus according to claim 12, wherein the measurement reference plane is a position where an error of the measurement value is minimized even when the refractive power of the measurement object changes, and is set at a position where the refractive power of the measurement object does not deviate from the detection area of the UV detector, Wherein the UV transmittance is measured by a spectacle lens having different refractive powers.

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