KR101803775B1 - Glasses for night blindness - Google Patents

Abstract

The night vision glasses according to the present invention detect ambient brightness and emit a suitable amount of light in accordance with the intensity of the sensed light and gradually decrease the brightness of the light so as to gently change the brightness, Can help to adapt to.

Description

Glasses for night blindness [

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a night vision glasses, and more particularly, to night vision glasses capable of adjusting the intensity of light according to ambient brightness using an illuminance sensor and an OLED.

Night blindness is a symptom of an eye that can not adjust when entering a dark place, or can not identify objects under dim light or in dark places. When a normal person enters a dark place in a bright place, what he did not see first gradually becomes visible as he adapts. It is called dark matter to automatically acquire the visual function while going into the dark place, and the rhodopsin, which is a substance in the stomach cell, can be rapidly decomposed and re-synthesized to detect the image of the object by the minute light. However, in patients with night blindness, the synthesis of rhodopsin is inhibited, the visual function is significantly lowered in the dark, the dark angle is considerably lowered even if darkness occurs, and the time required to complete the darkness is long.

Treatment of these night blindness is only a diet containing vitamin A, and it is often difficult to treat except night blindness due to vitamin A deficiency.

Korean Patent No. 10-1113596

It is an object of the present invention to provide night vision glasses which can help adapt the eyes to darkness.

The night vision glasses according to the present invention include: an eyeglass frame provided with a light intensity sensor for sensing the intensity of ambient light; An OLED lens coupled to the spectacle frame and emitting light according to intensity of light sensed by the illuminance sensor; Wherein the OLED lens is driven to emit light when the intensity of light sensed by the illuminance sensor is less than a predetermined set value, A control circuit for gradually reducing the brightness; And a wireless communication module provided in the eyeglass frame for receiving a preset control signal of the mobile terminal through wireless communication and transmitting the control signal to the control circuit.

According to another aspect of the present invention, there is provided a night vision glasses, comprising: a bridge having an illuminance sensor for sensing the intensity of ambient light; a pair of rims formed on both sides of the bridge; An eyeglass frame including a temple of the frame; An OLED lens coupled to the pair of rims and adapted to emit light according to intensity of light sensed by the illuminance sensor; Wherein the OLED lens is driven to emit light when the intensity of light sensed by the illuminance sensor is less than a predetermined set value, A control circuit for gradually reducing the brightness and stopping the brightness of the OLED lens when the brightness of the OLED lens reaches a predetermined set brightness; A wireless communication module provided in any one of the pair of temples to transmit information on the brightness of the OLED lens to a predetermined mobile terminal through wireless communication; And a battery detachably coupled to the other of the pair of temples to supply power to the control circuit.

The night vision glasses according to the present invention detect ambient brightness and emit a suitable amount of light in accordance with the intensity of the sensed light and gradually decrease the brightness of the light so as to gently change the brightness, Can help to adapt to.

1 is a perspective view illustrating a night vision glasses according to a first embodiment of the present invention.
2 is a view showing the configuration of the OLED lens of the night vision glasses shown in Fig.
FIG. 3 is a diagram illustrating the light emission state of the night vision glasses shown in FIG. 1 according to the intensity of light.
4 is a view showing the configuration of an OLED lens of a night vision glasses according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view illustrating a night vision glasses according to a first embodiment of the present invention. 2 is a view showing the configuration of the OLED lens of the night vision glasses shown in Fig.

1 and 2, a night vision glasses 1 according to a first embodiment of the present invention includes an illuminance sensor 10, a spectacle frame 20, an OLED (Organic Light Emitting Diode) lens 30, A control circuit (not shown), a wireless communication module 40, and a battery 50.

The illuminance sensor 10 is a sensor for sensing the intensity of ambient light. The illuminance sensor 10 is provided in the spectacle frame 20. In the present embodiment, the brightness sensor 10 is provided in the bridge 24 to be described later. By mounting the light sensor 10 on the bridge 24, the intensity of light can be detected more accurately without being disturbed by the surroundings.

The eyeglass frame 20 includes a rim 22, a bridge 24, and a temple 26.

The rim 22 is a portion in which a pair of the OLED lenses 30 are fitted and joined. The rims 22 are formed as a pair.

The bridge 24 is a portion connecting the pair of rims 22. The light sensor (10) is mounted on the bridge (24).

One end of the temple 26 is coupled to the pair of rims 22 by a hinge and the other end is a portion of the user's ear that wears the night vision glasses 1. The temples 26 are formed as a pair.

The OLED lens 30 is coupled to the pair of rims 22, respectively. The OLED lens 30 is a lens that emits light by the control circuit.

The OLED lens 30 includes an upper electrode 31, a zinc oxide (ZnO) nanoparticle 32, an electron injection layer (EIL) 33, an emission layer (EML) 34, A hole transport layer (Hole Transfer Layer) 35, a lower electrode 36, and a glass 37 are sequentially stacked. An encapsulation 38 is formed on one side of the upper electrode 31.

The upper electrode 31 and the lower electrode 36 may use at least one of ITO, Thin metals, silver nanowires, and silver nanofibers. The ITO or the metal thin film can transmit light and can be used as a transparent electrode of OLED glasses.

As the electron injection layer 33, PFN, LiF, or the like is used. The PFN (9,9-bis (3 '(N, N-dimethylamino) propyl) -2,7-flourene-alt-2,7- (9,9-dioctylfluorene) It acts to lower the electron injection barrier through metal interaction. The lithium fluoride (LiF) has a large dipole moment and serves to lower the electron injection barrier by using a coupling effect.

The light emitting layer 34 is a layer having a single color. As the light emitting layer 34, super yellow (Superyellow (Merck)), TBADN: DPAVBi and the like can be used. However, the present invention is not limited to this, and the light emitting layer can be used if it includes a fluorescent or phosphorescent organic material having a bandgap of between 1.7 eV and 3.2 eV and emitting visible light.

As the hole transport layer 35, poly (3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT: PSS) may be used.

It is of course possible that the glass 37 is made of glass for visual correction.

The ZnO nanoparticle layer 32 functions as a filler of the electrodes when silver nanowires or nanofibers are used as a cathode. The ZnO nanoparticles 32 fill the voids, .

The control circuit (not shown) is provided in the temple 26 of the spectacle frame 20. The control circuit (not shown) is inserted into the temple 26 and is electrically connected to the upper electrode 31 and the lower electrode 36 of the OLED lens 30. The control circuit (not shown) compares the intensity of the light sensed by the illuminance sensor 10 with a predetermined set value, and when the sensed light intensity is less than the preset value, the OLED lens 30 emits light The OLED lens 30 is driven. In addition, the control circuit (not shown) gradually decreases the brightness of the OLED lens 30 as the emission time of the OLED lens 30 elapses. The relationship between the light emission time of the OLED lens 30 and the brightness reduction of the OLED lens 30 is set in advance by experiment or the like. In addition, the control circuit (not shown) stops reducing the brightness of the OLED lens 30 when the brightness of the OLED lens 30 reaches a predetermined set brightness.

The wireless communication module 40 is provided in at least one of the pair of temples 26, for example. However, the present invention is not limited to this, and it is of course possible that the spectacle frame 20 is provided at another position. The wireless communication module 40 wirelessly communicates with a predetermined mobile terminal 60 and transmits a control signal received by the mobile terminal 60 to the control circuit (not shown). The mobile terminal 60 includes a smartphone, a tablet PC, and the like of a user wearing the night vision glasses 1. The wireless communication includes Bluetooth, Wi-Fi, NFC, and the like.

The battery (50) is provided in one of the pair of temples (26). The battery (50) is detachably coupled to the temple (26). The battery 50 is a power supply unit that supplies power to the control circuit (not shown). The battery 50 may be externally charged or automatically charged using solar heat.

The operation of the night vision glasses according to the first embodiment of the present invention will now be described.

It is also possible that the user wears the night vision glasses 1 and then wirelessly drives the night vision glasses 1 using the mobile terminal 60. The automatic night vision glasses 1 may be automatically driven It is possible. Hereinafter, a user will wirelessly drive the night vision glasses 1 using the mobile terminal 60, for example. The power of the night vision glasses 1 can be applied by using the application installed in advance in the mobile terminal 60. [

When the night vision glasses 1 are turned on, the illuminance sensor 10 senses the intensity of ambient brightness. The control circuit compares the intensity of the light sensed by the illuminance sensor 10 with the predetermined set value.

When the user enters a dark place, the intensity of the light sensed by the illuminance sensor 10 falls below the set value. The control circuit drives the OLED lens 30 so that the OLED lens 30 emits light when the intensity of the light sensed by the illuminance sensor 10 falls below the set value.

The control circuit calculates the light emission time of the OLED lens 30 and gradually decreases the light emitted from the OLED lens 30 as the light emission time passes. By gradually reducing the brightness of the light of the OLED lens 30, it is possible to help the eye adapt to darkness.

Thereafter, when the brightness of light of the OLED lens 30 reaches a predetermined set brightness, the control circuit stops decreasing the brightness of the light of the OLED lens 30. [

FIG. 3 is a diagram illustrating the light emission state of the night vision glasses shown in FIG. 1 according to the intensity of light.

FIG. 3A shows a state in which the user is in a bright place. 3B shows a state in which the OLED lens 30 emits light when the user enters a dark place. FIG. 3C shows a state in which the brightness of light of the OLED lens 30 gradually decreases with the lapse of the light emission time. 3B and FIG. 3C, the initial brightness of the OLED lens 30 is different from the brightness of the OLED lens 30 according to the light emission time in FIG. 3C.

Therefore, after the OLED lens 30 emits light, the brightness of light can be gradually reduced to help adapt the eyes to darkness. That is, it is possible to alleviate the symptoms of night blindness by moderating the light brightness change to the night blind patients who can not immediately adapt to the brightness change of light.

Meanwhile, the control circuit can transmit the brightness information of the OLED lens 30 to the mobile terminal 60 through wireless communication in real time.

The user can check the brightness information received from the mobile terminal 60 and control the brightness of the OLED lens 30 if necessary. That is, the user can control the brightness of light of the OLED lens 30 to be further increased if it is determined that the light is difficult to distinguish or recognize due to insufficient light intensity. Further, if it is determined that the user can distinguish or recognize an object due to sufficient light intensity, the brightness of light of the OLED lens 30 can be further reduced. Therefore, it is possible to control the user to emit light with a desired brightness.

4 is a view showing the configuration of an OLED lens of a night vision glasses according to a second embodiment of the present invention.

4, the OLED lens 130 includes an upper electrode 131, an electron injection layer 132, a light emitting layer 133 of RGB pixels, a hole transport layer 134, the pixel defining layer (PDL) 135, the lower electrode 136, the glass 137, and the sealing film 138 are similar to those of the first embodiment, , Only different configurations will be described in detail, the same reference numerals are used for similar configurations, and a description thereof will be omitted.

The light emitting layer 133 is implemented with RGB pixels, and the upper electrode 131 and the lower electrode 136 are separately provided according to RGB pixels.

A TFT (Thin Film Transistor) (not shown) is provided in the OLED lens 130 to selectively implement a hue of a specific wavelength.

The operation of the night vision glasses 2 according to the second embodiment of the present invention will be described below.

It is also possible to wirelessly drive the night vision glasses 2 using the mobile terminal 60 after the user wears the night vision glasses 2 and the automatic night vision glasses 2 can be automatically driven It is possible. Hereinafter, the user will wirelessly drive the night vision glasses 2 using the mobile terminal 60, for example. The power of the night vision glasses 2 can be applied by using an application installed in advance in the mobile terminal 60. [

When the night vision glasses 1 are turned on, the illuminance sensor 10 senses the intensity of ambient brightness. The control circuit compares the intensity of the light sensed by the illuminance sensor 10 with the predetermined set value.

When the user enters a dark place, the intensity of the light sensed by the illuminance sensor 10 falls below the set value. The control circuit drives the OLED lens 130 so that the OLED lens 130 emits light when the intensity of the light sensed by the illuminance sensor 10 falls below the set value.

In this case, since the OLED lens 130 is implemented as an RGB pixel instead of a single color, the light emitting layer 133 of the R, G, and B pixels can control light emission in units of pixels. For example, when a user inputs a control signal including a color of a desired wavelength through the mobile terminal 60, the control circuit transmits a control signal of the mobile terminal 60 through the wireless communication module 40 And controls the light emitting layer 133 of the R, G, and B pixels on a pixel-by-pixel basis to emit light of the wavelength that the user inputs according to the received control signal. Therefore, it is possible to emit light of a suitable wavelength depending on the user.

Then, the control circuit calculates the light emission time of the OLED lens 130, and gradually decreases the light emitted from the OLED lens 130 as the light emission time elapses. By gradually reducing the brightness of the light of the OLED lens 130, it is possible to help adapt the eyes to darkness.

Thereafter, when the brightness of light of the OLED lens 30 reaches a predetermined set brightness, the control circuit stops decreasing the brightness of the light of the OLED lens 30. [

As described above, when the user inputs a signal for a desired wavelength through the mobile terminal 60, the night vision glasses (2) according to the second embodiment of the present invention transmits the signal to the user through the wireless communication module (40) And the control circuit controls the light emission in the light emitting layer 133 of the RGB pixel in units of pixels according to the received signal.

Accordingly, since the OLED lens 130 is implemented as RGB pixels, light of a suitable wavelength can be emitted according to a user.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: illuminance sensor 20: eyeglass frame
30, 130: OLED lens 40: wireless communication module
50: Battery

Claims (10)

An eyeglass frame provided with an illuminance sensor for sensing the intensity of ambient light;
An OLED lens coupled to the spectacle frame and emitting light according to intensity of light sensed by the illuminance sensor;
Wherein the OLED lens is driven to emit light when a user enters a dark place and the intensity of light sensed by the illuminance sensor falls below a predetermined set value,
Calculating a light emission time of the OLED lens, gradually decreasing the brightness of the OLED lens as the light emission time elapses,
When the brightness of the OLED lens reaches a predetermined set brightness, stopping the brightness of the OLED lens is decreased,
A control circuit for controlling the adaptation of the eyes to the darkness by moderating a change in the brightness of the ambient light;
And a wireless communication module provided in the spectacle frame for receiving a preset control signal of the mobile terminal through wireless communication and transmitting the control signal to the control circuit,
Wherein the control circuit transmits information on the brightness of the OLED lens to the mobile terminal via the wireless communication module,
The user transmits a control signal for increasing the brightness of the OLED lens to the control circuit through the wireless communication module by using the mobile terminal when it is determined that the light is difficult to distinguish or recognize due to insufficient light intensity,
And transmits a control signal for reducing the brightness of the OLED lens to the control circuit through the wireless communication module using the mobile terminal if it is determined that the light can be distinguished or recognized because of sufficient intensity. delete delete The method according to claim 1,
The OLED lens includes an upper electrode, zinc oxide (ZnO NP), an electron injection layer, a single color luminescent layer, a hole transport layer, a lower electrode, and a glass layer. The method according to claim 1,
The OLED lens includes an upper electrode, an electron injection layer, an emission layer of RGB pixels, a hole transport layer, a pixel defining layer (PDL), a lower electrode, and a glass layer. The method of claim 5,
The control circuit comprising:
Wherein the control signal of the mobile terminal is received through the wireless communication module and the light emission of the RGB pixel is controlled in units of pixels in the light emitting layer of the RGB pixel according to the received control signal. The method according to claim 1,
Wherein the spectacle frame comprises a pair of rims to which the OLED lenses are respectively coupled, a bridge connecting the pair of rims, and a pair of temples hingedly coupled to the pair of rims,
Wherein the illumination sensor is installed in the bridge. The method of claim 7,
Wherein the wireless communication module is installed in at least one of the pair of temples,
The wireless communication includes night vision glasses including Bluetooth, Wi-Fi, and NFC. The method of claim 7,
Wherein one of the pair of temples is coupled to the wireless communication module and the other battery is detachably coupled to a battery that supplies power to the control circuit. delete

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