KR102257526B1 - Li-Fi LED Module - Google Patents

Abstract

The present invention relates to a Li-Fi LED lamp module, wherein the Li-Fi LED lamp module transmits a Li-Fi signal by emitting a visible light region from the LED lamp and receives a Li-Fi signal in the visible light region from a smartphone, wherein the LED lamp module includes a case (2). ), a light source, an LED lamp 300 is installed on the inner side of the case 2, and a light guide plate 100 is installed on the back side of the case 2 so that the light of the LED lamp 300 is reflected from the light guide plate 100 and directed forward, A Li-Fi filter 200 is installed on the front of the case 2 to filter and transmit only the visible light region,
The Li-Fi LED lamp module of the present invention transmits and receives light in a specific frequency band using a Li-Fi filter, so that the data transmission speed by the light is fast and there is no noise.

Description

Li-Fi LED Lamp Module {Li-Fi LED Module}

The present invention relates to a Li-Fi LED lamp module, and more particularly, to a Li-Fi LED lamp module that transmits and receives light of a specific frequency band by using a Li-Fi filter, so that the data transmission speed by the light is fast and there is no noise.

In general, in order to improve the limited frequency range of Wi-Fi technology, a communication method by light has been developed with Li-Fi technology. As an example, Registration No. 10-1831308 discloses a base film 10 formed of a transparent material made of a flexible material. ), a plurality of LEDs 20 are installed on one side of the base film 10, a plurality of LED drivers 30 are installed on the other side of the base film 10, and the LED driver 30 so that information is displayed by the LEDs 20 Including a control unit 50 for controlling, and the control unit 50 includes an electronic chip 51 equipped with a Li-Fi optical sensor to receive data through the Li-Fi signal, and the Li-Fi signal received in the form of light as digital data. And a data conversion module 52 for converting, wherein the LED 20 is made of copper foil and is connected to a first circuit 21 formed on an auxiliary film 23 disposed on one side of the base film 10, and the The LED driver 30 is made of copper foil and is connected to the second circuit 31 formed on the auxiliary film 33 disposed on the other side of the base film 10, and the plating layer 16 is provided on the base film 10. A flexible transparent LED display capable of Li-Fi communication, characterized in that via holes 15 are formed to connect the first circuit 21 and the second circuit 31, has been disclosed.

In addition, Korean Patent Application Publication No. 10-2016-0063518 includes a wired/wireless communication unit for performing communication through a wired/wireless communication network;

A traffic information acquisition unit that acquires real-time traffic information from a traffic information providing server through the wired/wireless communication unit, and checks a traffic congestion section using the acquired real-time traffic information;

A confirmation unit for checking a LiFi capable mobile vehicle within the traffic congestion section; And

A Li-Fi network management apparatus including a network configuration unit for generating a Li-Fi network composed of the Li-Fi-enabled mobile object is disclosed.

However, the prior art has a disadvantage in that there is a lot of noise and a transmission speed is low in data transmission by light by an LED lamp or the like.

Therefore, the present invention was conceived to solve the above problems, and the present invention is to provide a Li-Fi LED lamp module with fast data transmission speed and no noise by transmitting and receiving light of a specific frequency band using a Li-Fi filter. It is to do.

The present invention relates to a Li-Fi LED lamp module, wherein the Li-Fi LED lamp module transmits a Li-Fi signal by emitting a visible light region from the LED lamp and receives a Li-Fi signal in the visible light region from a smartphone, wherein the LED lamp module includes a case (2). The LED lamp 300, which is a light source, is installed on the inner side of the case 2, and a light guide plate 100 is installed on the back side of the case 2 so that the light of the LED lamp 300 is reflected from the light guide plate 100 to face the front, A Li-Fi filter 200 is installed on the front of the case 2 to filter and transmit only the visible light region.

Accordingly, the Li-Fi LED lamp module of the present invention transmits and receives light in a specific frequency band using a Li-Fi filter, so that the data transmission speed by the light is fast and there is no noise.

1 is an internal front view of a vacuum deposition coating apparatus used in the coating layer forming method of the present invention
Figure 2 is an overall external view of the vacuum deposition coating device used in the coating layer forming method of the present invention
3 is a layout diagram schematically showing the configuration of an example of a vacuum deposition apparatus used in a general coating layer forming method
Figure 4 is a cross-sectional view of a coating layer according to an embodiment of the present invention
5 is a cross-sectional view of a coating layer according to a second embodiment of the present invention
6 is a cross-sectional view of a coating layer according to three embodiments of the present invention
7 is a cross-sectional view of a coating layer according to a fourth embodiment of the present invention
8 is a cross-sectional view of a Li-Fi LED lamp module of the present invention

The present invention relates to a Li-Fi LED lamp module, wherein the Li-Fi LED lamp module transmits a Li-Fi signal by emitting a visible light region from the LED lamp and receives a Li-Fi signal in the visible light region from a smartphone, wherein the LED lamp module includes a case (2). The LED lamp 300, which is a light source, is installed on the inner side of the case 2, and a light guide plate 100 is installed on the back side of the case 2 so that the light of the LED lamp 300 is reflected from the light guide plate 100 to face the front, A Li-Fi filter 200 is installed on the front of the case 2 to filter and transmit only the visible light region.

In addition, the Li-Fi filter 200 is characterized in that a coating layer 220 is formed on the front or rear surface of the diffusion plate 210 for brightly diffusing the light reflected on the light guide plate.

In addition, the Li-Fi filter 200 is characterized in that a film is attached to the surface of the diffusion plate 210.

The present invention will be described in detail with reference to the accompanying drawings as follows. 1 is an inner front view of a vacuum evaporation coating apparatus used in the coating layer forming method of the present invention, FIG. 2 is an overall exterior view of the vacuum evaporation coating apparatus used in the coating layer forming method of the present invention, and FIG. 3 is a general coating layer forming method. A layout diagram schematically showing the configuration of an example of a vacuum deposition apparatus to be used, FIG. 4 is a cross-sectional view of a coating layer according to an embodiment of the present invention, FIG. 5 is a cross-sectional view of a coating layer according to a second embodiment of the present invention, and FIG. 7 is a cross-sectional view of a coating layer according to a fourth embodiment of the present invention, and FIG. 8 is a cross-sectional view of a Li-Fi LED lamp module of the present invention.

In the LED lamp module of the present invention itself, an LED lamp, which is a light source, is installed on the side of a rectangular parallelepiped case made of metal or plastic, and a light guide plate is installed on the back of the case, so that the light of the LED lamp is reflected from the front of the light guide plate and directed to the front. In addition, a diffuser plate is installed in front of the case to brightly diffuse the light reflected from the light guide plate. In the present invention, a vacuum deposition coating layer is formed on the front or rear surface of the diffusion plate, or a film is attached to be used as a Li-Fi filter.

The present invention technology transmits a Li-Fi signal by emitting a visible light region from a lamp and receives a Li-Fi signal in the visible light region from a smartphone.

In addition, the visible light region and the near-infrared region are transmitted together as a Li-Fi signal, and the visible light region and the near-infrared region Li-Fi signal are received from the smartphone.

In addition, a smartphone is used instead of the lamp to transmit, but the near-infrared region is used as the transmission/reception wavelength region.

In addition, a filter is used to transmit only the visible light region, and the filter is coated on the surface of a glass or lens or a plastic plate so that only the visible light wavelength range is passed.

In addition, a filter is used to transmit only the visible light region, and the filter is coated on the surface of a film to form a coating layer, and then adhered to the surface of a glass or lens or a plastic plate so that only the visible light wavelength range is passed.

In addition, a filter is used to transmit only the visible and near-infrared regions, but the filter is coated on the surface of the film to form a coating layer, and then adhered to the surface of a glass or lens or plastic plate to transmit the visible and near-infrared rays. It is to allow only the domain wavelength band to pass.

In addition, the lamp is an LED lamp.

The present invention transmits a Li-Fi signal by emitting a visible light region from a lamp, particularly an LED lamp, and receives a Li-Fi signal in the visible light region from a smartphone. The received Li-Fi signal is converted into a digital signal by a data conversion module composed of digital electronic devices.

Meanwhile, as another embodiment, the visible light region and the near-infrared region may be transmitted as signals together, and the visible ray region and the near-infrared region signal may be received from the smartphone.

In addition, as another embodiment, the present invention transmits using a smartphone instead of the lamp, but uses the near-infrared region for transmission and reception.

In the present invention, a filter is used to transmit only the visible light region, but the filter forms a coating layer on the surface of glass, lens, or plastic, especially acrylic, so that only the visible light wavelength range is passed.

The surface is to form a coating layer on the front or rear surface of a glass or lens or plastic, especially an acrylic surface.

A filter is used to transmit only the visible and near-infrared regions, and the filter forms a coating layer on the surface of the glass or lens so that only the visible and near-infrared wavelength bands pass through.

The surface is to form a coating layer on the front or rear surface of a glass or lens or plastic, especially an acrylic surface.

In another embodiment, the filter is coated on a film surface to form a coating layer, and then the film is adhered to the surface of a glass or lens or a plastic plate so that only the visible wavelength range is passed. The film is made of synthetic resin and mainly uses a transparent polyester (PET) film.

In another embodiment, the filter may be coated on a film surface to form a coating layer, and then the film may be adhered to the surface of a glass or lens or a plastic plate so that only the visible and near-infrared wavelength bands are passed.

The LED lamp module of the present invention itself installs an LED lamp as a light source on the side of a rectangular parallelepiped case, and a light guide plate is installed on the back of the case so that the light of the LED lamp is reflected from the light guide plate and faces forward, and a diffusion plate is installed on the front of the case. It diffuses the light brightly. The present invention is to be used as a filter by forming a vacuum evaporation coating layer or attaching a film to the front or rear surface of the diffusion plate.

The visible light region emitted from the LED bulb is in the wavelength range of 400 to 750 nm.

In the near-infrared region, a transmission filter with a wavelength of 750 ~ 850 is used.

A light-receiving smartphone is equipped with an optical sensor to receive visible light, or a near-infrared sensor is installed to receive near-infrared light.

Or it transmits near-infrared rays to another phone. In this case, no visible light is used.

The use of visible and near-infrared rays together is for the strength of light, that is, the signal, and there is no noise and the transmission speed is fast.

The method of forming a coating layer on the glass or lens surface or plastic plate is a vacuum deposition method,

1 is an interior of a vacuum deposition coating apparatus used in the coating layer forming method of the present invention

A plan view, FIG. 2 is an inner front view of a vacuum deposition coating apparatus used in the coating layer forming method of the present invention, and FIG. 3 is an overall vacuum deposition coating apparatus used in the coating layer forming method of the present invention.

An external view, FIG. 4 is a layout diagram schematically showing the configuration of an example of a vacuum deposition apparatus used in a general coating layer forming method, and FIG. 5 is a cross-sectional view of a coating layer according to an embodiment of the present invention.

Figure 6 is a cross-sectional view of the coating layer of the second embodiment of the present invention, Figure 7 is a cross-sectional view of the coating layer of the third embodiment of the present invention,

8 is a cross-sectional view of a coating layer according to a fourth embodiment of the present invention.

In the present invention, a coating layer is formed on the surface of a glass or lens or plastic, which is a diffusion plate, by a vacuum deposition method, and ZrO2, TiO2, which are the first layers from the surface to the top,

An Nb2O5 or Ti2O3 layer and a second SiO2 layer are sequentially formed, and a third layer of ZrO2, TiO2, Nb2O5, or Ti2O3 layer is formed on the second layer.

At this time, in order to more reliably form the coating layer, TiO2 layers may be formed respectively on the upper and lower surfaces of SiO2 as the second layer.

That is, the first layer of ZrO2, TiO2, Nb2O5 or Ti2O3 layer, the second layer of the upper TiO2 layer, the SiO2 layer, the lower TiO2 layer, and the third layer of the ZrO2, TiO2, Nb2O5 or Ti2O3 layer may be sequentially formed.

In addition, the present invention allows the first and second layers to be formed repeatedly in order to form the coating layer more reliably. That is, the first layer of ZrO2, TiO2, Nb2O5 or Ti2O3 layer, and the second layer of SiO2 layer are sequentially formed. I can.

In addition, a first layer of ZrO2, TiO2, Nb2O5, or Ti2O3 layer, and two layers of the upper TiO2 layer, the SiO2 layer, and the lower TiO2 layer are formed on the second layer. A TiO2 layer, a SiO2 layer, and a TiO2 layer may be further formed, and then a third layer of ZrO2, TiO2, Nb2O5, or Ti2O3 layer may be sequentially formed.

In the present invention, the thickness of one layer of high refraction for the refraction path of light for the Li-Fi filter is 5 to 125 nm, the thickness of the second layer of low refraction is 20 to 220 nm, and the thickness of the three layers of high refraction is the same as the thickness of the first layer.

The vacuum deposition technology used in the present invention uses a conventional vacuum deposition (evaporating) technology, and for the vacuum coating method, the evaporator is coated by melt evaporation of the coating material by resistance heating or electron beam method.

For general evaporating vacuum deposition, Patent Publication No. 2002-0081104 describes detailed technology as follows.

An apparatus for forming a thin film by a vacuum evaporation method is called a vacuum evaporation apparatus. 4 is a layout diagram schematically showing the configuration of an example of a general vacuum evaporation apparatus. The vacuum evaporation apparatus includes the evaporation source container 2 and the inside of the vacuum container 1 connected to the vacuum system.

It is made by arranging the substrate holder 3. The evaporation source 4 is accommodated in the evaporation source container 2. Further, the substrate holder 3 is equipped with a substrate 5 on which a thin film is formed, and a mask 6 defining a deposition area. A vacuum system comprising a vacuum pump 7 and an exhaust valve 8 used for depressurizing the inside of the vacuum container is connected to the vacuum container 1. Then, a heating power supply 9 is connected to the evaporation source container 2.

In a general vacuum evaporation apparatus, the evaporation source container 2 is disposed below the inside of the vacuum container (along the direction of gravity), and the substrate holder 3 is disposed above the inside of the vacuum container.

For forming a thin film and setting a shape of the thin film, first, the evaporation source 4 is accommodated in the evaporation source container 2, and the substrate 5 having the thin film attached to the substrate holder 3 is fixed. Further, in order to set the shape of the thin film by the mask method, the mask 6 in which the openings are formed in the required thin film shape on the substrate 5 is adhered and fixed.

Then, the inside of the vacuum container 1 is depressurized by a vacuum pump 7 to make a vacuum state, and then the evaporation source 4 accommodated in the evaporation source container 2 is heated. Molecules evaporated by heating fly inside the vacuum container 1 in the direction of the substrate 5 (in a general vacuum deposition apparatus, from the bottom to the top), and adhere (deposit) on the surface of the substrate 5 to form a thin film. Conventionally, an organic EL device was also manufactured with a vacuum evaporation apparatus having this configuration.

In addition, in the vacuum deposition apparatus of the present invention, a dome on which a plurality of protective films, which are coated, are mounted is installed on the upper part of the chamber, and the dome is rotated by a dome table of a substrate that is rotated by a motor. . Vacuum evaporation is the electron at the bottom

The evaporation source is heated by a beam (electron beam) to fly into the air and deposited on the surface of the protective film.

Accordingly, the Li-Fi LED lamp module of the present invention transmits and receives light in a specific frequency band using a Li-Fi filter, so that the data transmission speed by the light is fast and there is no noise.

1: chamber 10: smartphone protective film
20: dome 30: substrate dome table
40: electron beam
41: ion beam source 42: oil diffusion pump
43: vacuum pump
61: first floor 62: second floor
63: third layer 64: TiO2 layer
100: light guide plate 200: Li-Fi filter
210: diffusion plate 220: coating layer
300: LED lamp
2: case

Claims (3)

As a Li-Fi LED lamp module that transmits a Li-Fi signal by emitting a visible light area from the LED lamp and receives a Li-Fi signal in the visible light area from a smartphone, the LED lamp module is an LED lamp 300 as a light source on the inner side of the case (2). Is installed, and a light guide plate 100 is installed on the back side of the case 2 so that the light of the LED lamp 300 is reflected from the light guide plate 100 to face the front side. In the Li-Fi LED lamp module that is installed to filter and transmit only the visible light region,
A coating layer is formed on the surface of a glass or lens or plastic as a diffusion plate by a vacuum deposition method, but the first layer is ZrO2, TiO2,
An Nb2O5 or Ti2O3 layer and a second layer of SiO2 are sequentially formed, and a third layer of ZrO2, TiO2, Nb2O5 or Ti2O3 layer is formed on the second layer.
At this time, in order to more reliably form the coating layer, TiO2 layers are formed on the upper and lower surfaces of SiO2, which is the second layer, respectively,
For the Li-Fi filter, the thickness of one layer of high refraction for the refraction path of light is 5 to 125 nm, the thickness of the second layer of low refraction is 20 to 220 nm, and the thickness of the three layers of high refraction is the same as the thickness of the first layer. Li-Fi LED lamp module delete delete

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