KR200492363Y1 - Test box for glasses lens - Google Patents

Abstract

The present invention is a housing formed with a stepped groove in which the spectacle lens can be located; A light emitting part provided on an inner side of the stepped groove to emit light; A light-emitting notification lamp provided on the front surface of the housing and indicating whether light is emitted through the light-emitting unit; A light-receiving unit disposed at a position opposite to the light emission direction of the light-emitting unit on the other side of the stepped groove to receive light; A light-receiving notification lamp provided on the front surface of the housing and indicating whether light is received through the light-receiving unit; A transmittance display unit provided on the front surface of the housing to display transmittance of the spectacle lens; When the spectacle lens is positioned between the inner one side of the stepped groove and the other side of the inner side, the light emitting unit is driven to emit light to pass through the spectacle lens to determine the transmittance received from the light receiving unit and display the transmittance test on the transmittance display unit. And a control unit that controls a mode, displays whether light is emitted from the light emitting unit through the light emission notification lamp, and controls whether or not light is received from the light receiving unit through the light reception notification lamp.

Description

Test box for glasses lens

The present invention relates to a spectacle lens test box device that tests the UV, blue, infrared, near infrared, and visible light blocking conditions of the spectacle lens.

In general, green and red parts of visible light and electromagnetic waves with long wavelengths such as infrared, microwave, and radio waves are not significantly harmful to the human body or eyes, but blue light or infrared, ultraviolet and X-rays, gamma rays, etc. in the purple to blue part of visible light In the case of an electromagnetic wave with a short wavelength of, it has extremely harmful effects on the human body or eyes.

At this time, since X-rays or gamma rays are not included in general natural light such as sunlight, there is rarely a case of harmful effects on the human body if not approaching the surroundings, but infrared, ultraviolet rays, and blue light in visible rays are also included in sunlight. For the protection of the human body, especially the eyes, it is beneficial to the human body such as the eyes to wear a dedicated blocking lens that blocks ultraviolet (UV) and blue light. Accordingly, A technology is being developed to protect the eyes by reflecting and absorbing blue light.

Accordingly, various technologies related to spectacle lenses for blocking and absorbing ultraviolet or blue light have been developed in the past, and these technologies include attaching a polarizing film incorporating a cut-on filter, or attaching a polarizing film with an integrated cut-on filter to the colored dye at high temperature. Immersion in the lens surface, or a technology to form a plastic resin film or polarizing film containing silver and halogen elements that change color and color density depending on the amount of ultraviolet rays on the lens surface, or a high refractive index material on the surface of a plastic substrate When a multilayer film in which a plurality of and low refractive index materials are stacked is provided, it has been developed in various ways, such as a technology of laminating a functional thin film between a plastic substrate and a multilayer film.

As described above, by various technologies to block ultraviolet rays, countless companies have produced and sold harmful light blocking lenses such as ultraviolet rays, blue light, and infrared rays and distributed them to retail stores such as opticians. In order to develop a lens with better performance than the company's lens, it is necessary to compare various UV, blue, and infrared ray blocking lenses. In the case of each retail store, it is necessary to show the UV blocking performance of various UV blocking lenses to consumers, or The importance of test devices for showing UV, blue, and infrared blocking rates is increasing because consumers must sell lenses that consumers want by showing blue light blocking performance or infrared blocking performance of infrared blocking lenses.

Korean Patent Publication 10-2000-0012562

The technical problem of the present invention is to provide a box device capable of testing the UV, blue, infrared (near-infrared), and visible light blocking conditions of spectacle lenses.

The technical problem of the present invention is a housing having a stepped groove in which the spectacle lens can be located; A light emitting part provided on an inner side of the stepped groove to emit light; A light-emitting notification lamp provided on the front surface of the housing and indicating whether light is emitted through the light-emitting unit; A light-receiving unit disposed at a position opposite to the light emission direction of the light-emitting unit on the other side of the stepped groove to receive light; A light-receiving notification lamp provided on the front surface of the housing and indicating whether light is received through the light-receiving unit; A transmittance display unit provided on the front surface of the housing to display transmittance of the spectacle lens; When the spectacle lens is positioned between the inner one side of the stepped groove and the other side of the inner side, the light emitting unit is driven to emit light to pass through the spectacle lens to determine the transmittance received from the light receiving unit and display the transmittance test on the transmittance display unit. And a control unit that controls a mode, displays whether light is emitted from the light emitting unit through the light emission notification lamp, and controls whether or not light is received from the light receiving unit through the light reception notification lamp.

The light emitting unit includes at least one ultraviolet light emitting module emitting ultraviolet light, a blue light emitting module emitting blue light, an infrared light emitting module emitting infrared light, and a visible light emitting module emitting visible light, and the light receiving unit includes the ultraviolet light An ultraviolet light sensor provided at a position opposite to the light emitting module to sense the amount of ultraviolet light, a blue light sensor provided at a position opposite to the blue light emitting module to sense the amount of blue light, and a position opposite to the infrared light emitting module to sense the amount of infrared light At least one infrared light sensor and at least one visible light sensor provided at a position opposite to the visible light emitting module to sense a visible light dose may be provided.

The control unit drives the ultraviolet light emitting module and the ultraviolet light sensor to determine the ultraviolet transmittance of the spectacle lens and displays the ultraviolet transmittance test mode on the transmittance display unit, and the blue light transmittance of the spectacle lens by driving the blue light emitting module and the blue light sensor. A blue light transmittance test mode displayed on the transmittance display unit, an infrared transmittance test mode displaying the infrared transmittance of the spectacle lens by driving the infrared light emitting module and the infrared light sensor, and displaying the visible light emission module on the transmittance display unit. One or more test modes among visible light transmittance test modes displayed on the transmittance display unit may be controlled by determining the visible light transmittance of the spectacle lens by driving the light light sensor.

The light emission notification lamp includes: an ultraviolet light emission notification lamp that emits light when the ultraviolet light emission module is operated and the ultraviolet light emission is ON; A blue light emission notification lamp that emits light when the blue light emission module is operated and the blue light emission is turned on; An infrared light emission notification lamp that emits light when the infrared light emission module is operated and the infrared light emission is ON; And a visible light emission notification lamp that is emitted when the visible light emission module is operated and the visible light emission is ON.

The light-receiving notification lamp may include an ultraviolet light-receiving notification lamp that emits light when ultraviolet rays are received through the ultraviolet light sensor; A blue light receiving notification lamp that emits light when blue light is received through the blue light sensor; An infrared light receiving notification lamp that emits light when infrared light is received through the infrared light sensor; And a visible light receiving notification lamp that emits light when visible light is received through the visible light sensor.

According to an embodiment of the present invention, by providing a spectacle lens test device that can compare various ultraviolet, blue, and infrared blocking spectacle lenses, each retail store shows the ultraviolet blocking performance of various ultraviolet blocking spectacle lenses to consumers, or It can show the blue light blocking performance of blue light blocking spectacle lenses, or the infrared blocking performance of infrared blocking spectacle lenses. Therefore, it can show UV, blue light, and infrared ray blocking rate, thereby increasing the reliability of spectacle lenses desired by consumers.

1 is a perspective view of a spectacle lens test box device according to an embodiment of the present invention.
2 is a front view of the spectacle lens test box device according to an embodiment of the present invention.
3 is a configuration diagram of a spectacle lens testing apparatus according to an embodiment of the present invention.
4 is a diagram illustrating a state in which transmittance is displayed when a spectacle lens is positioned between a light emitting unit and a light receiving unit according to an embodiment of the present invention.
5 is an exemplary illustration of light emission of a notification lamp when a UV-blocking spectacle lens is positioned between a light-emitting unit and a light-receiving unit according to an embodiment of the present invention.
6 is an exemplary illustration of light emission of a notification lamp when a blue light blocking spectacle lens is positioned between a light emitting unit and a light receiving unit according to an embodiment of the present invention.
7 is an exemplary illustration of light emission of a notification lamp when an infrared ray blocking spectacle lens is positioned between a light emitting part and a light receiving part according to an embodiment of the present invention.
8 is a photograph of an actual product test when an ultraviolet and blue light blocking spectacle lens is positioned between a light emitting unit and a light receiving unit according to an embodiment of the present invention.
9 is a diagram showing a state of reading an NFC tag attached to a spectacle lens positioned between a light emitting unit and a light receiving unit according to an embodiment of the present invention.

Hereinafter, the advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described later in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and is provided to completely inform the scope of the design to those of ordinary skill in the art to which the present invention belongs. As such, the invention is only defined by the scope of the claims. In addition, in describing the present invention, when it is determined that related well-known technologies may obscure the gist of the present invention, a detailed description thereof will be omitted.

1 is a perspective view of a spectacle lens test box device according to an embodiment of the present invention, Figure 2 is a front view of a spectacle lens test box device according to an embodiment of the present invention, and Figure 3 is a spectacle lens according to an embodiment of the present invention It is a configuration diagram of a test apparatus, and FIG. 4 is a diagram showing a state in which transmittance is displayed when a spectacle lens is positioned between a light emitting part and a light receiving part according to an embodiment of the present invention. Accordingly, it is an exemplary picture of light emission of a notification lamp when a UV-blocking spectacle lens is positioned between the light-emitting unit and the light-receiving unit, and FIG. 6 is a notification when a blue light blocking spectacle lens is positioned between the light-emitting unit and the light-receiving unit according to an embodiment of the present invention. It is an exemplary picture of light emission of a lamp, and FIG. 7 is an exemplary picture of light emission of a notification lamp when an infrared ray blocking spectacle lens is positioned between a light emitting unit and a light receiving unit according to an embodiment of the present invention. This is an actual product test picture when the UV and blue light blocking spectacle lenses are positioned between the light emitting unit and the light receiving unit, and Fig. 9 is for reading the NFC tag attached to the spectacle lens positioned between the light emitting unit and the light receiving unit according to an embodiment of the present invention. It is a picture showing the appearance.

The spectacle lens test box device of the present invention has a rectangular body-shaped housing 10 structure as shown in FIGS. 1 and 2 so that a stepped groove in which the spectacle lens can be positioned is formed in the housing 10. This is a device that tests whether the spectacle lens blocks light by placing the spectacle lens between the stepped grooves.

The spectacle lens test box device of the present invention having such a housing structure, as shown in FIG. 3, is provided on the inner side of the stepped groove to emit light, and light is emitted through the light emitting unit 100 Through the light-emitting notification lamp 600 indicating whether or not, the light-receiving unit 200 provided at a position opposite to the light emission direction of the light-emitting unit 100 on the other side of the stepped groove to receive light, and the light-receiving unit 200 A light-receiving notification lamp 700 indicating whether or not light is received, a transmittance display unit 400 provided on the front surface of the housing 10 to display the transmittance of the spectacle lens, and between one inner side and the other inner side of the stepped groove When the spectacle lens is positioned in the light emitting unit 100 to emit light to transmit light through the spectacle lens to determine the transmittance received by the light receiving unit 200 to control the transmittance test mode displayed on the transmittance display unit 400, A control unit 300 that displays whether or not light is emitted from the light-emitting unit 100 through the light-emitting notification lamp 600 and controls whether or not light is received by the light-receiving unit 200 through the light-receiving notification lamp 700 ). In addition, an amplification unit 500, a light emission notification lamp 600, a light reception notification lamp 700. A temperature sensor 800 may be further included. It will be described in detail below.

The light-emitting unit 100 is a module provided on an inner side of the stepped groove to emit light. The light emitting unit 100 includes an ultraviolet light emitting module that emits ultraviolet (UV) light, a blue light emitting module that emits blue light (BLUE, UV420), an infrared light emitting module that emits infrared light, and a visible light emitting visible light (500nm to 700nm). At least one light emitting module is provided. In this way, the ultraviolet light emitting module, the blue light emitting module, the infrared light emitting module, and the visible light emitting module each include light emitting diodes to emit light that matches. Here, the infrared light emitting module may emit near-infrared (NIR) light having a wavelength of 780 nm to 1400 nm, preferably 900 nm to 1000 nm.

The light emission notification lamp 600 is provided on the front surface of the housing 10 and indicates whether or not light is emitted through the light emitting unit 100. The light emission notification lamp 600 includes an ultraviolet light emission notification lamp 610 that emits light when the ultraviolet light emission module is operated and the ultraviolet light emission is ON, and when the blue light emission module is operated and the blue light emission is on, When the blue light emission notification lamp 620 and the infrared light emission module are operated and the infrared emission is turned on, the infrared emission notification lamp 630 and the visible light emission module are operated and the visible light emission is turned on. A visible light emission notification lamp 640 that emits light may be provided.

For example, when the ultraviolet light emitting module is operated and the ultraviolet light emission is on (ON), the ultraviolet light emission notification lamp 610 is turned on, and when the ultraviolet light emission module is not operated and light emission is off (OFF), the ultraviolet light emission notification lamp 610 is turned off. Let it.

In addition, when the blue light emitting module is operated and the blue light emission is turned on, the blue light emission notification lamp 620 is turned on, and when the blue light emission module is not operated and the light emission is off (OFF), the blue light emission notification lamp 620 is turned off. .

In addition, when the infrared light emitting module is operated and the infrared light emission is on (ON), the infrared light emission notification lamp 630 is turned on, and when the infrared light emission module is not operated and light emission is off (OFF), the infrared light emission notification lamp 630 is turned off. .

In addition, when the visible light emitting module is operated to turn on the visible light emission notification lamp 640 when the visible light emission is turned on, and when the visible light emission module is not operated and the light emission is off (OFF), the visible light emission notification lamp ( 640) is turned off.

Therefore, the user can easily know the type of light that is currently being emitted through whether the ultraviolet light emitting module, the blue light emitting module, the infrared light emitting module, and the visible light emitting module are turned on.

The light receiving unit 200 is a module that is provided at a position opposite to the light emission direction of the light emitting unit 100 on the other side of the stepped groove to receive light. The light-receiving unit 200 is provided at a position opposite to the ultraviolet light-emitting module to sense the amount of ultraviolet light, a blue light sensor provided at a position opposite to the blue light-emitting module to sense the amount of blue light, and at a position opposite to the infrared light-emitting module. At least one infrared light sensor is provided to sense an amount of infrared light, and at least one light sensor is provided at a position opposite to the visible light emitting module to sense the amount of visible light. Accordingly, as shown in FIG. 3, the light emitting unit 100 and the light receiving unit 200 are provided at opposite positions, respectively. That is, the light emitted from each light-emitting module of the light-emitting unit 100 is received by each matched light-receiving sensor in the light-receiving unit 200. Further, a signal of the amount of light received and sensed by the light receiving unit 200 may be amplified by the amplifying unit 500 and transmitted to the control unit 300.

The light-receiving notification lamp 700 is provided on the front surface of the housing 10 and notifies whether or not light is received through the light-receiving unit 200. Accordingly, the type of light received by the optical sensor can be notified to the user through the light-receiving notification lamp 700. The light-receiving notification lamp 700 includes an ultraviolet light-receiving notification lamp 710 that emits light when ultraviolet light is received through the ultraviolet light sensor, and a blue light-receiving notification lamp 720 that emits light when blue light is received through the blue light sensor. , An infrared light receiving notification lamp 730 that emits light when infrared rays are received through the infrared light sensor, and a visible light receiving notification lamp 740 that emits light when visible light is received through the visible light sensor.

The transmittance display unit 400 is a module provided on the front surface of the housing 10 to display transmittance of the spectacle lens. That is, the spectacle lens is positioned between the light-emitting unit 100 and the light-receiving unit 200 and transmits the spectacle lens by emitting ultraviolet, blue, visible, or infrared rays, and then the amount of light received by the light receiving unit 200 is measured. It is expressed as transmittance compared to the amount of light emitted.

When the spectacle lens is positioned between the inner one side of the stepped groove and the other inner side of the stepped groove, the control unit 300 drives the light emitting unit 100 to emit light and transmits light through the spectacle lens to receive light from the light receiving unit 200. To control the transmittance test mode displayed on the transmittance display unit 400. For reference, the selection of the transmittance test mode may be provided to the controller 300 by receiving a test mode selection through an external terminal (eg, a user computer).

In the ultraviolet transmittance test mode, the ultraviolet light emitting module and the ultraviolet light sensor are driven to determine the ultraviolet transmittance of the spectacle lens and display it on the transmittance display unit 400. If the ultraviolet ray-blocking spectacle lens is positioned between the light-emitting unit 100 and the light-receiving unit 200 as shown in FIG. By comparing the amount of ultraviolet light emitted from the light emitting module with the amount of ultraviolet light received from the ultraviolet light sensor, the transmittance of ultraviolet rays may be determined and displayed on the transmittance display units 400 and 400. Therefore, the smaller the displayed ultraviolet transmittance, the more intuitively it is possible to inform the customer that the ultraviolet rays are blocked by the ultraviolet ray blocking spectacle lens.

In the blue light transmittance test mode, a blue light emission module and a blue light sensor are driven to determine the blue light transmittance of the spectacle lens and display it on the transmittance display unit 400. If the blue light-blocking spectacle lens is positioned between the light-emitting unit 100 and the light-receiving unit 200 as shown in FIG. 4, the blue light-emitting module is emitted so that the blue light-blocking spectacle lens is transmitted through the blue light sensor, The blue light transmittance may be determined by comparing the amount of blue light emitted from the blue light emitting module with the amount of blue light received by the blue light sensor and displayed on the transmittance display unit 400. Therefore, the smaller the displayed blue light transmittance, the more intuitively it is possible to inform the customer that the blue light is blocked by the blue light blocking spectacle lens.

In the infrared transmittance test mode, the infrared light emitting module and the infrared light sensor are driven to determine the infrared transmittance of the spectacle lens and display it on the transmittance display unit 400. If the infrared ray-blocking spectacle lens is positioned between the light-emitting unit 100 and the light-receiving unit 200, as shown in FIG. The infrared transmittance may be determined by comparing the amount of infrared light emitted from the infrared light emitting module with the amount of infrared light received by the infrared light sensor and displayed on the transmittance display unit 400. Accordingly, the smaller the displayed infrared transmittance, the more intuitively it is possible to inform the customer that the infrared ray blocking spectacle lens is blocking infrared rays.

The visible light transmittance test mode is a mode in which the visible light emission module and the visible light sensor are driven to determine the visible light transmittance of the spectacle lens and display it on the transmittance display unit 400. If the visible ray blocking spectacle lens is positioned between the light emitting unit 100 and the light receiving unit 200 as shown in FIG. 4, the visible ray emitting module is emitted to transmit the visible ray blocking spectacle lens and receive it from the visible ray optical sensor. If so, the visible light transmittance may be determined by comparing the amount of visible light emitted from the visible light emitting module to the amount of visible light received from the visible light sensor and displayed on the transmittance display unit 400.

On the other hand, the control unit 300 displays whether or not light is emitted from the light emitting unit 100 through the light emission notification lamp 600, and displays whether the light is received by the light receiving unit 200 through the light reception notification lamp 700. Control can be performed.

For example, as shown in FIG. 5, after placing an ultraviolet ray blocking spectacle lens between the light emitting unit 100 and the light receiving unit 200, an ultraviolet emission notification lamp 610, a blue emission notification lamp 620, and an infrared emission notification lamp 630, when all the visible light emission notification lamps 640 are emitted, only the ultraviolet rays are blocked by the ultraviolet ray-blocking spectacle lenses and light is not received, and the remaining rays are transmitted, so that only the ultraviolet light receiving notification lamp 710 is turned off, and the remaining blue light is received. The notification lamp 720, the infrared light receiving notification lamp 730, and the visible light receiving notification lamp 740 maintain a lit state.

Similarly, as shown in FIG. 6, after placing the blue light blocking spectacle lens between the light emitting unit 100 and the light receiving unit 200, an ultraviolet light emission notification lamp 610, a blue light emission notification lamp 620, and an infrared emission notification lamp When all the visible light emission notification lamps 640 are emitted, only blue light is blocked by the blue light blocking spectacle lens and is not received, and the remaining light is transmitted, so that only the blue light receiving notification lamp 720 is turned off, and the remaining ultraviolet rays are received. The notification lamp 710, the infrared light receiving notification lamp 730, and the visible light receiving notification lamp 740 maintain a lit state.

Similarly, as shown in FIG. 7, after placing an infrared ray blocking spectacle lens between the light emitting unit 100 and the light receiving unit 200, an ultraviolet emission notification lamp 610, a blue emission notification lamp 620, and an infrared emission notification lamp When all the visible light emission notification lamps 640 are emitted, only the infrared rays are blocked by the infrared ray blocking glasses lens and the remaining rays are transmitted, so that only the infrared light reception notification lamp 730 is turned off, and the remaining ultraviolet rays are received. The notification lamp 710, the blue light receiving notification lamp 720, and the visible light receiving notification lamp 740 maintain a lit state.

If a spectacle lens capable of blocking both ultraviolet rays and blue light is positioned between the light emitting unit 100 and the light receiving unit 200 as shown in FIG. 8, the ultraviolet light emission notification lamp 610 and the blue light emission notification lamp 620 ), when the infrared light-emitting notification lamp 630 is emitted, since ultraviolet and blue light are blocked by the spectacle lens, the ultraviolet light-receiving notification lamp 710 and the blue light-receiving notification lamp 720 are turned off and the infrared light-receiving notification lamp 730 Will be lit. For reference, the product picture of FIG. 8 is a product picture to which visible light emission and light reception are not applied.

Meanwhile, the control unit 300 needs to calibrate the sensing value in order to accurately calculate the transmittance before proceeding to the test mode. This is because it can be dark or bright depending on the test environment, so the brightness varies depending on the test location.

Accordingly, the control unit 300 emits light in each light emitting module of the light emitting unit 100 in a state in which the spectacle lens is not positioned between the light emitting unit 100 and the light receiving unit 200 before the test mode. The maximum amount of light, which is the amount of received light, is determined, and the amount of off light, which is the amount of light received from the opposing optical sensor, is determined by turning off each light emitting module of the light emitting unit 100. Correct the sensing value of the optical sensor.

On the other hand, in addition to the calibration using the on-off measurement value described above, it is necessary to correct the sensing value in consideration of the temperature of the test place. This is because the optical sensor is sensitive to temperature. In consideration of this, the spectacle lens test apparatus includes a temperature sensor 800 positioned in the sensor unit to sense a temperature. The controller 300 corrects the UV transmittance, blue light transmittance, visible light transmittance, and infrared transmittance according to the sensed temperature.

On the other hand, after the inspector places the spectacle lens for the spectacle lens test between the light emitting unit 100 and the light receiving unit 200, any of the ultraviolet transmittance test mode, blue light transmittance test mode, infrared transmittance test mode, and visible light transmittance test mode You need to decide whether to proceed to.

In determining the test mode, a test mode suitable for the type of spectacle lens positioned between the light emitting unit 100 and the light receiving unit 200 should be determined. In consideration of this, the spectacle lens test apparatus as shown in FIG. 9 is provided with an NFC reader that reads the NFC tag attached to the spectacle lens and identifies the NFC unique number.

The controller 300 grasps the type of spectacle lens assigned to the NFC identification number through the read NFC tag, and according to the identified spectacle lens type, the ultraviolet transmittance test mode, the blue light transmittance test mode, the visible light transmittance test mode, Among the infrared transmittance test modes, a matching transmittance test mode is performed.

For example, if the spectacle lens located between the light emitting unit 100 and the light receiving unit 200 is an ultraviolet spectacle lens, it is possible to determine that the spectacle lens is an ultraviolet spectacle lens by reading the NFC tag attached to the tag of the ultraviolet spectacle lens. It is to proceed with the transmittance test mode.

The embodiments in the description of the present invention described above are presented by selecting the most preferable examples to aid the understanding of those skilled in the art among various possible examples, and the technical idea of the invention is not necessarily limited or limited only by this embodiment. , Various changes and changes, and other equivalent embodiments are possible within the scope of the technical idea of the present invention.

100: light emitting unit
200: light receiving unit
300: control unit
400: transmittance display unit
500: amplification unit
600: luminescence notification lamp
700: light-receiving notification lamp

Claims (5)

A housing 10 with a stepped groove in which the spectacle lens can be positioned;
A light emitting unit 100 provided on an inner side of the stepped groove to emit light;
A light-emitting notification lamp 600 provided on the front surface of the housing 10 and indicating whether or not light is emitted through the light-emitting unit 100;
A light-receiving part 200 provided at a position opposite to the light emission direction of the light-emitting part 100 on the other side of the stepped groove to receive light;
A light-receiving notification lamp 700 provided on the front surface of the housing 10 and notifying whether or not light is received through the light-receiving unit 200;
A transmittance display unit 400 provided on the front surface of the housing 10 to display transmittance of the spectacle lens;
When the spectacle lens is positioned between the inner one side of the stepped groove and the other side of the inner side, the light emitting unit 100 is driven to emit light to pass through the spectacle lens to determine the transmittance received by the light receiving unit 200. Controls the transmittance test mode displayed on the transmittance display unit 400, displays whether light is emitted from the light emitting unit 100 through the light emission notification lamp 600, and displays the light receiving unit 200 through the light reception notification lamp 700. Including; a control unit 300 for performing control to display whether or not light is received in ),
The light-emitting unit 100 includes at least one ultraviolet light emitting module emitting ultraviolet light, a blue light emitting module emitting blue light, an infrared light emitting module emitting infrared light, and a visible light emitting module emitting visible light,
The light receiving unit 200 includes an ultraviolet light sensor provided at a position opposite to the ultraviolet light emitting module to sense an amount of ultraviolet light, a blue light sensor provided at a position opposite to the blue light light emitting module to sense the amount of blue light, and the infrared light emitting module At least one infrared light sensor provided at an opposite position to sense the amount of infrared light, and at least one visible light sensor provided at a position opposite to the visible light emitting module to sense the amount of visible light,
The control unit 300 drives the ultraviolet light emitting module and the ultraviolet light sensor to determine the ultraviolet transmittance of the spectacle lens and displays the ultraviolet transmittance test mode on the transmittance display unit 400, and drives the blue light emitting module and the blue light sensor. The blue light transmittance test mode to determine the blue light transmittance of the spectacle lens and display it on the transmittance display unit 400, and the infrared light transmittance of the spectacle lens is determined by driving the infrared light emitting module and the infrared light sensor and displayed on the transmittance display unit 400 One or more test modes are controlled among the infrared transmittance test mode, the visible light transmittance test mode displayed on the transmittance display unit 400 by determining the visible light transmittance of the spectacle lens by driving the visible light emitting module and the visible light sensor. ,
The light emission notification lamp 600 includes an ultraviolet light emission notification lamp 600 that emits light when the ultraviolet light emission module is operated and the ultraviolet light emission is ON; A blue light emission notification lamp 600 that emits light when the blue light emission module is operated and blue light emission is turned on; An infrared light emission notification lamp 600 that emits light when the infrared light emission module is operated and the infrared light emission is ON; Including; a visible light emission notification lamp 600 that emits light when the visible light emission module is operated and the visible light emission is ON,
The light-receiving notification lamp 700 may include an ultraviolet light-receiving notification lamp 710 that emits light when ultraviolet light is received through the ultraviolet light sensor; A blue light-receiving notification lamp 720 that emits light when blue light is received through the blue light sensor; An infrared light-receiving notification lamp 730 that emits light when infrared light is received through the infrared light sensor; Including; a visible light receiving notification lamp 740 that emits light when visible light is received through the visible light sensor,
A temperature sensor positioned in a sensor unit including the ultraviolet light sensor, the blue light sensor, the infrared light sensor, and the visible light sensor to sense a temperature; and
The control unit 300 is a spectacle lens test box device, characterized in that correcting the ultraviolet transmittance, blue light transmittance, visible light transmittance, and infrared transmittance according to the sensed temperature.
The method according to claim 1, wherein the spectacle lens test box device,
Includes; NFC reader for reading the NFC tag attached to the eyeglass lens to identify the NFC unique number,
The control unit 300 grasps the type of spectacle lens assigned to the read NFC identification number, and according to the identified spectacle lens type, an ultraviolet transmittance test mode, a blue light transmittance test mode, a visible light transmittance test mode, an infrared transmittance test A spectacle lens test box device, characterized in that the transmission test mode matching among the modes is performed.
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