KR20210124015A - Anti-virus sensor lighting module - Google Patents

Abstract

The present invention relates to an anti-virus sensor lighting module comprising: an LED PCB (230) in which a portion of a donut-shaped substrate is formed as a cut arc-shaped substrate, and UVC 275 nm LEDs (231) are formed protruding at equal intervals; a donut-shaped case (210) for housing the LED PCB (230) and having a through-hole penetrating the UVC 275 nm LEDs (231) at equal intervals in the lower direction; a light fastening tube (220) formed in the inner portion of the donut-shaped case (210) to fasten the lighting (100) from the lower side; a PIR sensor (110) formed on the lower side of the light fastening tube (220) or donut-shaped case (210); and a controller (300) for controlling an operation of the UVC 275 nm LED (231) and the lighting lamp (100) according to the detection information of the PIR sensor (110) when a power terminal of the LED PCB (230), the lighting lamp (100) power terminal, the PIR sensor (110), and external power are connected, and inserted into a remaining space of the LED PCB (230) in the donut-shaped case (210). When the lighting lamp (100) is inserted and fastened into the lighting lamp fastening tube (220), the UVC 275 nm LED for sterilization (231) and the lighting lamp (100) are automatically operated to drive the sterilization lamp and the sensor lamp according to motion detection of the PIR sensor (110).

Description

Anti-virus sensor lighting module}

The present invention relates to an anti-virus sensor, and more particularly, to an anti-virus sensor lamp module that combines a UVC 275 nm LED to a lighting lamp that detects motion and outputs light to transform it into a device that sterilizes a lighting space.

Recently, with the rapid development of means of transportation, as movement becomes free, exchanges between countries are active, and foreign travel culture is also rapidly increasing, which is a major cause of the spread of infectious diseases. In other words, global pandemic outbreaks such as MERS, H1N1 flu, SARS, Corona 19, etc., in which infectious viruses in a specific region contaminate other regions, occur frequently.

As global awareness of these global epidemics increases, a new virus sterilization service that makes virus sterilization routine is required. In particular, there is a need for a service that prevents the spread of the virus by periodically sterilizing the entrance of a building or residential area where people come and go, or a space where daily items such as shoe racks and hangers are placed.

In general, ultraviolet (UV) light is used as a means of sterilizing everyday items. In particular, the UV-C sterilization power having a wavelength range of 100 to 280 nm is very good, so it has the advantage of being able to sterilize 99.99% of viruses in a short time. However, UV sterilization has become a problem because it can be harmful to the human body, such as causing skin damage or aging.

In addition, a sterilizer in a modular form has not yet been developed. Conventionally, in order to install a sterilizer in a space such as an entrance or a shoe cabinet, a separate wiring has to be installed and connected to a power source. And there was a problem such as having to fix the sterilizer with nails or adhesives.

Korean Intellectual Property Office Registration Patent Publication No. 10-1565954 "Shoe disinfection device using ultraviolet light emitting diode" Korea Intellectual Property Office Laid-Open Patent Publication No. 10-2016-0109939 "Peace Control Device for Building Entrance"

The present invention is a UVC that irradiates ultraviolet rays during the standby time when the general lighting lamp is not operated by the sensor, etc. while operating as a sensor that is routinely arranged to illuminate the doorway of an apartment, such as an entrance or a shoe cabinet where daily products are stored. An object of the present invention is to provide an anti-virus lighting module that continuously sterilizes the lighting area by causing the 275nm LED to operate.

In addition, the present invention controls the UVC 275nm LED to operate ON only when there are no people or animals in order to use the UVC 275nm LED with a long sterilization effective distance in the lighting area to provide an anti-virus sensor module to prepare for a sterilization safety accident. aim to

In order to achieve the above object, the present invention is formed of an arc-shaped substrate in which a portion of the donut-shaped substrate is cut, and UVC 275nm LEDs are formed protruding at equal intervals; a donut-type case housing the LED PCB and having a hole through the LED at equal intervals in a downward direction; a light fastening tube formed in the inner circle of the donut-shaped case to fasten the light from the lower side; a PIR sensor formed on the lower side of the light fastening tube or donut-shaped case; And in the donut-shaped case, it is inserted in the remaining space of the LED PCB, and when the power terminal of the LED PCB, the power terminal of the lighting lamp, the PIR sensor, and the external power are connected, the UVC 275nm LED and the lighting lamp are operated according to the detection information of the PIR sensor Controller for controlling The technical gist of the module is the anti-virus sensor.

The PIR sensor of the present invention is formed in the center of the light fastening tube, and the light fastened to the lighting light fastening tube is an antivirus sensor light module, characterized in that the through hole for exposing the PIR sensor is formed in the coupling part. It is preferable to become

In addition, the PIR sensor is preferably an anti-virus sensor, etc. module, characterized in that by forming additional through-holes at equal intervals with the through-holes formed on the lower side of the donut-shaped case, and disposing them under the controller.

In addition, the controller includes: a lighting-on operation control unit for turning on the lighting for a set lighting time (T1) from the generation time of the motion detection signal of the PIR sensor; a UVC 275nm LED on standby unit for turning on the UVC 275nm LED after a set waiting time (T2) from the time when the lighting lamp is turned off; a UVC 275nm LED on operation control unit that maintains the ON operation of the UVC 275nm LED for a set sterilization time T3, and turns off the UVC 275nm LED when the motion detection signal is generated; and a UVC 275nm LED off operation maintenance unit that maintains an OFF operation of the UVC 275nm LED when the lighting lamp is turned on. It is preferable to become

In addition, it is preferable that a Fresnel lens is attached to the PIR sensor to be an anti-virus sensor module, characterized in that the lower monitoring area can be optimally monitored.

The present invention is a UVC that irradiates ultraviolet rays during the standby time when the general lighting lamp is not operated by the sensor, etc. while operating as a sensor that is routinely arranged to illuminate the doorway of an apartment, such as an entrance or a shoe cabinet where daily products are stored. By operating the 275nm LED, it continuously sterilizes the lighting area, and in order to use the long UVC 275nm LED with a long sterilization effective distance in the lighting area, the UVC 275nm LED is controlled to operate ON only when there are no people or animals to prevent sterilization safety accidents. There is an advantage that a module such as an anti-virus sensor is provided.

1 is an exploded perspective view illustrating a module such as an anti-virus sensor according to an embodiment of the present invention.
2 is an assembled perspective view illustrating a module such as an anti-virus sensor according to another embodiment of the present invention.
3 is a view showing an example in which an anti-virus sensor lamp (a state in which a lighting lamp is coupled to an anti-virus sensor lamp module, hereinafter referred to as 'anti-virus sensor lamp') according to an embodiment of the present invention is applied to a doorway.
4 is a view showing an example in which an anti-virus sensor according to an embodiment of the present invention is applied to a shoe closet.
5 is a diagram illustrating a structure of a PIR sensor mounted on a module such as an anti-virus sensor according to an embodiment of the present invention.
6 is a block diagram of a controller according to an embodiment of the present invention.
7 is a diagram showing the configuration of a sterilization operation control algorithm of an anti-virus sensor or the like according to an embodiment of the present invention.
8 is a flowchart illustrating a sterilization operation control algorithm of an anti-virus sensor according to another embodiment of the present invention.
9 is an ultraviolet frequency characteristic graph.

Hereinafter, the present invention will be described with reference to the drawings, and in the description of the present invention, if it is determined that a detailed description of a related known technology or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. will be.

And, the terms described below are terms defined in consideration of functions in the present invention, which may vary depending on the intention or custom of the user or operator, so the definition should be made based on the content throughout this specification describing the present invention.

Hereinafter, an embodiment of the present invention will be described in detail based on the accompanying drawings 1 to 9.

The present invention relates to an anti-virus sensor light module, and as shown in FIGS. 1 and 2 , largely UVC 275nm LED 231 , LED PCB 230 , donut-shaped case 210 , lighting light fastening tube 220 , PIR It is composed of a sensor 110 and a controller 300 .

As shown in FIG. 1, the LED PCB 230 of the present invention has a morphological feature in that a portion of the donut-shaped substrate is formed as an arc-shaped substrate, and the UVC 275nm LEDs 231 are protruded at equal intervals. have characteristics.

The donut-shaped case 210 of the present invention is a case in which a donut-type is adopted for housing the LED PCB 230, and a through hole penetrating the UVC 275 nm LED 231 is formed in the lower direction at equal intervals.

In general, UV sterilization LEDs used in people's residential environments have a frequency band formed close to the visible light region, and are characterized by a very short sterilization distance.

This is the reason why it was selected as a device for human safety, but it is also because UV rays cannot pass through common transparent casing materials as the frequency band is further away from visible light.

That is, in the case of a UV sterilization LED using a transparent casing material such as general acrylic or glass, the effective sterilization distance is very short, so there is a problem that an effective function cannot be exhibited at the entrance to the apartment entrance, the entrance to the laboratory, or the entrance to the elevator.

The UVC 275nm LED (231) emitted in the present invention is a UV frequency band far from visible light, and has a very long sterilization effective distance, so it is mainly used for industrial and medical purposes. , and has excellent sterilization ability, but it is harmful to the human body, so there is a limitation that it must be handled very carefully.

On the other hand, as shown in FIG. 9, the UVC 275nm LED 231 does not pass through a general transparent casing material in the frequency characteristic of ultraviolet rays, but passes through topaz or quartz. is casing.

Therefore, it can be seen that in order to effectively use the UVC 275 nm LED 231 , the UVC 275 nm LED 231 should not be housed with another transparent casing material.

The present invention forms holes at equal intervals in the donut-shaped case 210 in order to effectively use the UVC 275nm LEDs 231 as described above, and exposes the UVC 275nm LEDs 231 to the outside through the holes so that the sterilization function is operated. are doing

The lighting coupling tube 220 of the present invention is a lighting coupling part formed in the inner part of the donut-shaped case 210, and a lighting coupling plate ( 221) is formed.

The lighting lamp 100 coupled to the lighting coupling tube 220 is a general optical lighting lamp, and according to the present invention, the PIR sensor 110 detects motion and generates a motion detection signal, and operates as a sensor that outputs light.

Although the present invention provides a device that provides a device for operating a general light illuminator as a sensor, etc., even if a commercially available sensor is attached to the illuminating light fastening tube 220, it is normally operated as a sensor.

The lighting area (A) in which the present invention is installed may be an entrance or exit of a building or residence as shown in FIG. 3 or an interior space of a shoe closet as shown in FIG. 4 , and the lighting lamp 100 includes a light output unit 130 and a glass cover 150 ) may be included.

In addition, as shown in FIG. 6 , it is preferable to provide a connector 320 for connection with the controller 300 to be described later so that the power of the lighting lamp can be applied by the fastening of the lighting lamp fastening tube 220 .

The PIR sensor 110 of the present invention is formed on the lower side of the light fastening tube 220 or the donut-shaped case 210 .

In the case of forming the PIR sensor 110 in the center of the lighting light fastening tube 220, the lighting 100 fastened to the lighting light fastening tube 220 forms a through hole exposing the PIR sensor 110 to the coupling part. It is preferable to do

However, in such a case, it may be necessary to repair the lighting lamp 100 or use a dedicated lamp, so that additional holes are formed at equal intervals with the holes formed on the lower side of the donut-shaped case, and the PIR sensor ( 110) is preferred.

In this case, as shown in FIG. 1 , the PIR sensor 110 will be disposed below the controller due to the morphological characteristics of the LED PCB 230 .

The PIR sensor 110 is a device for detecting a movement by a person or an animal in the illumination area A, and in the present invention, a Fresnel lens 111 as shown in FIG. ) can be combined.

The Fresnel lens 111 shown in FIG. 7 collects infrared rays from a large aperture and focuses them on the PIR sensor 110, and improves the detection sensitivity of infrared rays emitted from people or animals inside the illumination area A.

The PIR sensor 110 senses the amount of change in the input infrared rays and transmits them to the controller, and the controller generates a motion detection signal when the change amount of the sensed infrared rays is greater than a preset motion determination reference amount.

The process of generating such a motion detection signal may be controlled by the controller 300 , and the controller 300 of the present invention may set the sensitivity of the PIR sensor 110 to the amount of infrared change.

The reason for using the PIR sensor 110 and the Fresnel lens 111 as the motion sensor in the present invention is to ensure safety against the human risk of the UVC 275nm LED 231 used in the present invention as described above.

That is, the present invention secures the operation safety of the UVC 275nm LED 231 by maximally detecting the state where there is no person or animal inside the lighting area A.

The controller 300 of the present invention is preferably formed in an arc shape so as to be inserted and disposed in the remaining space of the LED PCB 230 in the donut-shaped case 210, but is not necessarily limited thereto.

As shown in FIG. 6 , the controller 300 is connected to the power terminal of the LED PCB 230 , the power terminal of the lighting 100 , the PIR sensor 110 , and an external power source, and the detection information of the PIR sensor 110 . Controls the operation of the UVC 275nm LED (231) and the lighting lamp (100) in accordance with the.

In detail, the controller 300 controls the lighting lamp 100 and the UVC 275 nm LED 200, and when a motion detection signal is received from the lighting lamp 100, the UVC 275 nm LED 200 according to the sterilization operation control algorithm 310. to control

At this time, the controller 300 controls the UVC 275nm LED 200 according to the set sterilization operation control algorithm 310 so that the UVC 275nm LED 200 is ON only when there is no person or animal inside the lighting area A. Control.

Specifically, the sterilization operation control algorithm 310, as shown in FIG. 8, includes a lighting lamp on operation control unit 311, a UVC 275nm LED on operation standby unit 313, a UVC 275nm LED on operation control unit 315 and a UVC 275nm LED off It may include an operation maintaining unit (317).

The lighting lamp on operation control unit 311 may control the lighting lamp 100 to be turned on for a set lighting time T1 from the generation time of the motion detection signal transmitted from the lighting lamp 100 .

In addition, the UVC 275nm LED on operation standby unit 313 may wait for the UVC 275nm LED 200 to be turned on after the set waiting time T2 from the time when the lighting lamp 100 is turned off.

Accordingly, it is possible to further contribute to safety by allowing the sterilization to proceed after a predetermined time from the point when the movement of the lighting area A is sensed and the lighting 100 is turned on.

The UVC 275nm LED on operation control unit 315 maintains the ON operation of the UVC 275nm LED 200 for a set sterilization time T3, and when a motion detection signal is generated, the UVC 275nm LED 200 can be controlled to be OFF. .

Accordingly, while the UVC 275nm LED 200 is ON and sterilization is in progress, when a movement is detected in the illumination area A and the illumination lamp 100 is ON, the sterilization can be stopped immediately.

The UVC 275nm LED OFF operation maintaining unit 317 may maintain the OFF operation of the UVC 275nm LED 200 when the lighting lamp 100 is ON.

Accordingly, if the lighting lamp 100 is turned on when the ON operation of the UVC 275 nm LED 200 starts, the UVC 275 nm LED 200 may not be turned on and maintain the OFF operation.

By the configuration of the sterilization operation control algorithm 310, the UVC 275nm LED 200 is controlled to be ON only when there is no person or animal inside the lighting area A, so that damage to the human body due to ultraviolet irradiation can be prevented. .

Accordingly, the sterilization operation control algorithm 310 follows the steps shown in FIG. 8 .

First, it is checked whether a motion detection signal is generated from the PIR sensor 110 . If a motion detection signal is generated, after turning off the UVC 275nm LED 200, the lighting 100 is controlled to be turned on for the set lighting time T1.

On the other hand, if the motion detection signal is not generated, it is checked whether the set waiting time T2 is exceeded from the time when the lighting lamp 100 is turned OFF. If the set standby time (T2) is exceeded, the lighting lamp 100 is turned OFF, and then the UVC 275nm LED 200 is controlled to be operated ON during the set sterilization time T3.

The sterilization operation control algorithm 310 as described above may be implemented differently depending on the nature, structure, shape, etc. of the illumination area A of the anti-virus sensor according to the present invention. That is, the sterilization operation control algorithm 310 may be configured in consideration of the inflow and outflow patterns of people or articles in the lighting area A.

According to the anti-virus sensor according to the present invention, the UVC 275 nm LED 200 having a virus sterilization function can be organically coupled to the lighting lamp 100 commonly used in daily life.

Therefore, according to the present invention, there is an advantage that the general lighting lamp 100 can be used by extending the function of the anti-virus sterilizing lamp and the sensor by simply replacing the existing lighting lamp or adding some components.

In addition, when a sensor with a built-in motion sensor is used as the lighting lamp 100, a motion detection sensor built into the sensor is used to detect a movement in the lighting area (A), and the controller uses this to sterilize By having a sterilization operation control algorithm for determining whether or not there is an effect that the operation can be made simpler.

Therefore, the anti-virus sensor light module according to the present invention can be sterilized periodically without damage to the human body, but the manufacturing cost can be minimized, and at the same time, the function of a general lighting lamp can be expanded to a sterilization lamp and a sensor lamp by a simple combination. The user's accessibility to the invention can be improved.

The drawings shown above for the purpose of explanation of the present invention are one embodiment in which the present invention is embodied, and as shown in the drawings, it can be seen that various combinations of forms are possible in order to realize the gist of the present invention.

Therefore, the present invention is not limited to the above-described embodiments, and as claimed in the following claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications without departing from the gist of the present invention. It will be said that there is the technical spirit of the present invention to the extent possible.

A: Lighting area
1: anti-virus sensor, etc.
100: light
110: PIR sensor
111: Fresnel lens
130: light output unit
150: glass cover

220: lighting combination tube
221: lighting combination plate
230: led pcb
231: UVC 275nm LED
300 : controller
310: sterilization operation control algorithm
311: light on operation control unit
313: UVC 275nm LED on standby unit
315: UVC 275nm LED on operation control unit
317: UVC 275nm LED off operation maintenance unit
320: connector
T1 : Set lighting time
T2 : Setting waiting time
T3: Set sterilization time

Claims (5)

A portion of the donut-shaped substrate is formed as a cut arc-shaped substrate, and the UVC 275nm LEDs 231 are formed protruding at equal intervals from the LED PCBs 230;
a donut-shaped case 210 housing the LED PCB 230 and having a through hole penetrating the UVC 275nm LED 231 at equal intervals in the lower direction;
The light fastening tube 220 is formed in the inner portion of the donut-shaped case 210 to fasten the light 100 from the lower side;
PIR sensor 110 formed on the lower side of the light fastening tube 220 or donut-shaped case 210; and
In the donut-shaped case 210, the LED PCB 230 is inserted into the remaining space, and the power terminal of the LED PCB 230, the lighting lamp 100 power terminal, the PIR sensor 110, and an external power are connected, A controller 300 for controlling the operation of the UVC 275nm LED 231 and the lighting lamp 100 according to the detection information of the PIR sensor 110;
consists of
When the lighting 100 is inserted and fastened into the lighting fastening tube 220, the UVC 275nm LED 231 for sterilization and the lighting 100 are automatically operated according to the motion detection of the PIR sensor 110 to become a sterilization lamp and a sensor lamp. Anti-virus sensor module, characterized in that it drives. According to claim 1, wherein the PIR sensor 110 is
Formed in the center of the light fastening tube 220,
The anti-virus sensor light module, characterized in that the light 100 fastened to the light fastening tube 220 is provided with a through hole exposing the PIR sensor 110 in the coupling portion. According to claim 1, wherein the PIR sensor 110 is
Anti-virus sensor module, characterized in that by forming additional through-holes at equal intervals with the through-holes formed on the lower side of the donut-shaped case (210), and disposing the lower side of the controller (300). According to claim 1, wherein the controller (300)
a lighting-on operation control unit 311 for turning on the lighting lamp 100 for a set lighting time T1 from the motion detection signal generation time of the PIR sensor;
UVC 275nm LED on operation standby unit 313 for turning on the UVC 275nm LED 200 after a set waiting time T2 from the time when the lighting lamp 100 is turned off;
A UVC 275nm LED on operation control unit that maintains the ON operation of the UVC 275nm LED 200 for a set sterilization time T3, and turns OFF the UVC 275nm LED 200 when the motion detection signal is generated ( 315); and
The sterilization operation control algorithm 310 including; Anti-virus sensor module, characterized in that it is built-in. According to claim 1,
In the PIR sensor 110,
An anti-virus sensor module, characterized in that by attaching a Fresnel lens 111 to optimally monitor the lower monitoring area.

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