KR20230032567A - Ultra Violet Sterilization System Using Lighting - Google Patents

Abstract

The present invention is mounted on a lighting system (10) equipped with: a lighting (11) installed in an indoor space to illuminate the indoor space; a power supply unit (12) for supplying power to the lighting (11); and a power switch (13) for switching the lighting (11) to on/off state. The present invention comprises: a plurality of sterilizing lights (21) installed in the indoor space to sterilize pathogenic microorganisms through ultraviolet rays; an on-off detection unit (26) for detecting whether the power switch (13) is on/off; a control module (22) for controlling the sterilizing light (21) to turn off when the lighting (11) is turned on, and controlling the sterilizing lights (21) to turn on when the lighting (11) is turned off; and a battery unit (25) that is charged by the power supplied to the power supply unit (12) and supplies power to the sterilizing lights (21). It is possible to automatically sterilize multiple pathogenic microorganisms.

Description

UV Sterilization System Using Lighting {Ultra Violet Sterilization System Using Lighting}

The present invention relates to a UV sterilization system using lighting, and more particularly, a plurality of lights installed in an indoor space, charged by a certain amount or more when a light illuminating the indoor space is turned on, and turned on through the charged electricity when the light is turned off. , It relates to a UV sterilization system using a lighting lamp having an LED sterilization lamp that sterilizes a number of pathogenic microorganisms contained in indoor air through ultraviolet rays.

Recently, as interest in personal hygiene increases, a number of LED germicidal light systems for sterilizing pathogenic microorganisms such as germs, bacteria, and viruses contained in indoor air using ultraviolet rays are installed in indoor spaces. The LED germicidal lamp system is provided in an indoor space equipped with a lighting system for brightly illuminating the inside at a constant intensity.

Since ultraviolet rays mainly irradiated through the LED sterilization lamp system are harmful to the human body, the LED sterilization lamp system is automatically turned on when there is no person in the indoor space, and can sterilize a number of microorganisms contained in the indoor air, When there is a person in the indoor space, it needs to be configured to be automatically turned off and harmless to the human body.

However, there is a problem in that the configuration of the control circuit becomes complicated in order to implement an LED germicidal lamp system that is turned on when a person leaves the room and turned off when a person enters the room.

In addition, in the existing LED sterilization lamp system, there was a problem that a separate electric line for supplying power to the LED sterilization lamp was required.

KR 10-0960216 B1

The present invention has been made to solve the above problems, and an object of the present invention is to install a plurality of lights in an indoor space, charge a certain amount or more when a light illuminating the indoor space is turned on, and charge electricity when the light is turned off. To provide a UV sterilization system using a lighting lamp having an LED sterilization lamp that is lit through and sterilizes a number of pathogenic microorganisms contained in indoor air through ultraviolet rays.

In order to solve the above technical problems, the UV sterilization system 20 using a light according to the present invention is installed in an indoor space, and supplies power to the light 11 and the light 11 that illuminate the indoor space. It is mounted on the lighting system 10 having a power supply 12 for supplying and a power switch 13 for switching the lighting 11 to an on/off state, and is installed in the indoor space in multiple numbers, When the sterilization lamp 21 for sterilizing pathogenic microorganisms, the on/off detection unit 26 for detecting whether the power switch 13 is turned on/off, and the lighting lamp 11 are turned on, the sterilization lamp ( 21) is turned off, and when the lighting lamp 11 is turned off, the control module 22 for controlling the sterilizing lamp 21 to turn on and the power supplied to the power supply unit 12 are charged by, It is characterized in that it includes a battery unit 25 for supplying power to the sterilization lamp 21.

In addition, the control module 22 provides a communication unit 23 for communication between the lighting system 10 and the charging sterilizing lamp 21 system and the power supply unit 12 when the lighting 11 is turned on. Using the supplied power, the battery unit 25 is charged to a certain amount or more, the sterilization lamp 21 is controlled to be immediately turned off, and when the lighting lamp 11 is turned off, the sterilization lamp 21 A control unit 24 controls to be turned on for a certain period of time, and the on/off detection unit 26 receives an on signal when the power switch 13 is switched to an on state and the lamp 11 is locked. and the communication unit 23 transmits the on signal generated by the on/off detection unit 26 to the control unit 24, and the control unit 24 generates a charging signal according to the on signal. After generating, by transmitting the charging signal to the battery unit 25 through the communication unit 23, the battery unit 25 is controlled to be charged using the power supplied to the power supply unit 12, , The control unit 24 generates a stop signal according to the on signal, and then transmits the stop signal to the germicidal lamp 21 through the communication unit 23, so that the germicidal lamp 21 turns off immediately. It is characterized by controlling as much as possible.

In addition, the on/off detection unit 26 generates an off signal when the power switch 13 is switched to an off state and the lighting 11 is turned off, and the communication unit 23 detects the on/off The off signal generated by the unit 26 is transmitted to the control unit 24, and the control unit 24 generates an operation signal according to the off signal and then transmits the sterilizing lamp through the communication unit 23. By transmitting the operation signal to (21), it is characterized in that the sterilizing lamp 21 is controlled to be turned on for a certain period of time.

In addition, the UV sterilization system 20 using the lighting lamp includes a motion detection sensor 30 for generating a motion detection signal when a motion of the human body is detected indoors, and an optical sensor for measuring the irradiation intensity of the lighting light 11 ( 31), the rotation unit 32 provided to be able to rotate according to the flow of air flowing in the room, and when the lighting lamp 11 is maintained in an on state, the flow rate of indoor air flowing into the rotation unit 32 is adjusted in advance. Characterized in that it further includes a flow rate sensor 37 that measures once per set set time, and an irradiation amount calculator 40 that controls the sterilization lamp 21 to vary the irradiation intensity according to the degree of contamination of indoor air. do.

In addition, the communication unit 23 transmits the motion detection signal, the irradiation intensity data of the lighting 11, the flow rate data of indoor air, and an on signal and an off signal to the irradiation amount calculating unit 40, and the irradiation amount calculating unit (40) When the motion detection signal is not transmitted by the communication unit 23, the turn-on time at which the on/off detection unit 26 generates an on signal and the on/off detection unit 26 generates an off signal Each turn off time is checked, the turn on time of the lighting lamp 11 is calculated by subtracting the turn on time from the turn off time, and the flow rate of indoor air measured by the flow sensor 37 is summed up. It is characterized in that the average flow rate of indoor air divided by the on-time of the lighting 11 is calculated.

In addition, the irradiation amount calculation unit 40 calculates a reference irradiation amount obtained by multiplying the on-time of the lighting lamp 11, the irradiation intensity of the lighting lamp 11, and the average flow rate of air, and the sterilizing lamp 21 proportional to the standard irradiation amount It is characterized in that by calculating the irradiation intensity of and transmitting it to the sterilizing lamp 21 through the communication unit 23, the sterilizing lamp 21 is controlled to be radiated according to the reference irradiation amount.

The UV sterilization system using a light according to the present invention is equipped with an LED sterilization lamp that is automatically turned off when a light illuminating an indoor space is turned on, and is automatically turned on when the light is turned off, and is more controllable than the existing LED sterilization lamp system. There is an effect of simplifying the configuration of the circuit.

In addition, in the UV sterilization system using a lighting lamp according to the present invention, when the lighting lamp is turned on, the LED sterilizing lamp can be charged using the power supplied to the lighting lamp, and a separate electric line for supplying power to the LED sterilizing lamp is installed. There is an effect that is not necessary.

In addition, the UV sterilization system using lighting according to the present invention is installed in a separate space where lighting is always used day and night, such as kitchens, elevators, warehouses, and bathrooms, to automatically sterilize a number of pathogenic microorganisms contained in indoor air. There are possible effects.

1 is a block diagram of a UV sterilization system using a lighting lamp according to the present invention.
2 is a flowchart illustrating a process of charging the battery unit and turning off the LED sterilization lamp when the lighting lamp is turned on.
3 is a flowchart for explaining a process of turning on the LED sterilizing lamp when the lighting lamp is turned off.
4 is a flowchart for explaining the flow of data acquired by various sensors.
5 is a flowchart illustrating a process of controlling the sterilizing lamp 21 by the irradiation amount calculator 40.
6 is a cross-sectional view for explaining the configuration of the rotation unit.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings in order to describe in detail enough for those skilled in the art to easily implement the technical idea of the present invention.

However, the following examples are merely examples to aid understanding of the present invention, and the scope of the present invention is not reduced or limited thereby. In addition, the present invention may be embodied in many different forms and is not limited to the embodiments described herein.

The UV sterilization system 20 using a lighting lamp according to the present invention is installed in an indoor space and includes a lighting lamp 11 that illuminates the indoor space, a power supply unit 12 for supplying power to the lighting lamp 11, and a lighting lamp 11 It is mounted on a lighting system 10 having a power switch 13 for switching to an on/off state.

1 is a block diagram of a UV sterilization system 20 using a lighting lamp according to the present invention.

2 is a flowchart for explaining a process of charging the battery unit 25 and turning off the sterilizing lamp 21 when the lighting lamp 11 is turned on, and FIG. It is a flow chart to explain the process.

Referring to FIG. 1, a UV sterilization system 20 using a lighting lamp according to the present invention includes a sterilization lamp 21, an on/off detection unit 26, a control module 22, and a battery unit 25. .

First, a plurality of sterilizing lamps 21 are installed in an indoor space, and sterilize pathogenic microorganisms such as viruses and bacteria through ultraviolet rays irradiated to the outside.

At this time, the sterilization lamp 21 is preferably implemented in the form of a UV-C LED for sterilization that can effectively sterilize pathogenic microorganisms such as viruses and bacteria with an emission wavelength of 275 nanometers.

In addition, an AlGaN chip in a 3.5 mmx3.5 mm ceramic package having high thermal conductivity may be provided inside the UV-C LED for sterilization, and a transparent glass cover shielded may be provided outside the UV-C LED for sterilization. In addition, UV-C LEDs for sterilization can achieve high efficiency with a long lifetime of 10,000 hours or more.

Here, AlGaN (Aluminium Gallium Nitride) is an alloy of aluminum nitride and gallium nitride, and is mainly used to manufacture a light emitting diode capable of operating from a blue region to an ultraviolet region.

Also, the on/off detection unit 26 detects whether the power switch 13 is turned on/off.

Also, the control module 22 controls the sterilizing lamp 21 to be turned off when the lighting lamp 11 is turned on, and controls the sterilizing lamp 21 to be turned on when the lighting lamp 11 is turned off.

In addition, the battery unit 25 is charged by the power supplied to the power supply unit 12 and serves to supply power to the sterilization lamp 21 .

The control module 22 includes a communication unit 23 and a control unit 24.

First, the communication unit 23 serves to communicate with each other between the lighting system 10 and the charging sterilizing lamp 21 system. Specifically, the communication unit 23 transmits an off signal or an on signal generated by the on/off detection unit 26 to the control unit 24, and transmits an operation signal, a charging signal, or a stop signal generated by the control unit 24. It is transmitted to the sterilization lamp (21).

In addition, the control unit 24 controls that when the lighting lamp 11 is turned on, the battery unit 25 is charged to a predetermined amount or more using the power supplied to the power supply unit 12, and the sterilizing lamp 21 is immediately turned off. and, when the lighting lamp 11 is turned off, the sterilization lamp 21 is controlled to be turned on for a certain period of time.

Referring to FIG. 2 , when the user turns the power switch 13 into an on state, the on/off detector 26 generates an on signal. The communication unit 23 transmits the on signal generated by the on/off detection unit 26 to the control unit 24 .

Then, the control unit 24 generates a charging signal according to the on signal and transmits the charging signal to the battery unit 25 through the communication unit 23 so that the battery unit 25 is supplied from the power supply unit 12. It is controlled to be charged with the power that is available.

In addition, the control unit 24 controls the sterilizing lamp 21 to immediately turn off by generating a stop signal according to the on signal and then transmitting the stop signal to the sterilizing lamp 21 through the communication unit 23.

Therefore, when a user enters an indoor space equipped with a lighting lamp 11 and turns on the lighting lamp 11, the battery unit 25 is charged with the power supplied from the power supply unit 12, and the sterilizing lamp 21 The ultraviolet rays emitted from the sterilizing lamp 21 may be immediately turned off so that the user is not irradiated.

Referring to FIG. 3 , when the user switches the power switch 13 to an off state, the on/off detection unit 26 generates an off signal. The communication unit 23 transmits the off signal generated by the on/off detection unit 26 to the control unit 24 .

Then, the control unit 24 generates an operation signal according to the off signal transmitted by the communication unit 23, and then transmits the operation signal to the sterilization lamp 21 through the communication unit 23, so that the sterilization lamp 21 It is controlled to light up for a certain period of time.

After turning off the light 11, the user leaves the indoor space equipped with the light 11. Therefore, a number of pathogenic microorganisms contained in indoor air can be effectively sterilized by the sterilizing lamp 21 .

The UV sterilization system 20 using a lighting lamp according to the present invention is provided with a sterilization lamp 21 that is automatically turned off when the lighting lamp 11 that illuminates the indoor space is turned on and automatically turned on when the lighting lamp 11 is turned off, There is an effect that the configuration of the control circuit is simplified compared to the existing germicidal lamp 21 system.

In addition, in the UV sterilization system 20 using the lighting lamp according to the present invention, when the lighting lamp 11 is turned on, the sterilizing lamp 21 can be charged using the power supplied to the lighting lamp 11, so that the sterilizing lamp ( 21), there is no need to install a separate electric line to supply power.

In addition, the UV sterilization system 20 using a light according to the present invention is installed in a separate space where the light 11 is always used day and night, such as a kitchen, an elevator, a warehouse, a bathroom, etc., and a number of pathogenic microorganisms contained in indoor air There is an effect that can be automatically sterilized.

4 is a flow chart for explaining the flow of data acquired by various sensors, FIG. 5 is a flow chart for explaining the process of controlling the sterilization lamp 21 by the irradiation amount calculator 40, and FIG. 6 is a rotation unit ( 32) is a cross-sectional view for explaining the configuration.

4 to 6, the UV sterilization system 20 using a lighting lamp according to the present invention includes a motion detection sensor 30, an optical sensor 31, a rotating part 32, a flow detection sensor 37, and a dose calculation It may be configured to further include a unit 40.

First, the motion detection sensor 30 generates a motion detection signal when a motion of the human body is detected indoors. At this time, the motion detection sensor 30 is preferably implemented in the form of an infrared sensor.

The motion detection signal generated by the motion detection sensor is transmitted to the radiation amount calculator 40 through the communication unit 23 .

And, the optical sensor 31 is provided on one side of the lighting lamp 11 and measures the irradiation intensity of the lighting lamp 11 . The irradiation intensity data of the lighting lamp 11 measured by the optical sensor 31 is transmitted to the irradiation amount calculator 40 through the communication unit 23 .

And, the rotation unit 32 is provided on one side of the room so as to be able to rotate according to the flow of air flowing through the room. At this time, the rotation unit 32 is configured to include a main body 33, wings 34 and rotational shaft 35.

First, the main body 33 includes an inlet 33a through which indoor air is introduced and an outlet 33b through which air accommodated in the main body 33 is discharged.

And, the rotating shaft 35 is provided inside the main body 33 and is formed long in the longitudinal direction of the main body 33 .

In addition, a plurality of wings 34 are provided on the outside of the rotation shaft 35 in the circumferential direction of the rotation shaft 35 so as to be able to rotate by indoor air flowing into the body 33 . At this time, the wing 34 is preferably made of a light and thin material so that it can easily rotate even when indoor air is finely introduced.

In addition, the flow rate sensor 37 is provided on one side of the rotation unit 32, and when the lighting lamp 11 is maintained in an on state, the flow rate of indoor air flowing into the rotation unit 32 is measured once for each preset setting time. Measure.

For example, when the lighting 11 is turned on for 1 hour, the flow rate sensor 37 may measure the flow rate of indoor air flowing into the rotating unit 32 once every 10 minutes. Flow rate data of indoor air measured by the flow sensor 37 is transmitted to the irradiation amount calculator 40 through the communication unit 23 .

In addition, the irradiation amount calculator 40 controls the sterilization lamp 21 to vary the intensity of irradiation according to the degree of contamination of indoor air.

Meanwhile, the communication unit 23 transmits an off signal or an on signal generated by the on/off detection unit 26 to the radiation amount calculator 40 .

In addition, when the motion detection signal is not transmitted by the communication unit 23, the irradiation amount calculator 40 determines the turn-on time when the on/off detector 26 generates an on signal and the on/off detector 26 generates an off signal. The turn-on time of the lamp 11 obtained by subtracting the turn-on time from the turn-off time is calculated. Here, the on time of the lighting lamp 11 means the duration of the lighting lamp 11 maintaining the on state.

In addition, the irradiation amount calculating unit 40 calculates an average flow rate of indoor air divided by the on-time of the lighting 11 after summing up the flow rates of indoor air measured by the flow sensor 37 .

In addition, the irradiation amount calculator 40 calculates a reference amount of irradiation obtained by multiplying the on-time of the lighting lamp 11 , the irradiation intensity of the lighting lamp 11 and the average flow rate of indoor air.

At this time, the turn-on time of the lighting 11, the intensity of irradiation of the lighting 11, and the average flow rate of indoor air are used as major indicators for measuring the pollution degree of indoor air.

In other words, when the lighting lamp 11 is turned on for a long time, the irradiation intensity of the lighting lamp 11 is high, or the flow rate of air flowing in the room is high, it can be determined that the indoor air has a high degree of contamination.

In addition, the irradiation amount calculation unit 40 calculates the irradiation intensity of the sterilizing lamp 21 in proportion to the standard irradiation amount and transmits it to the sterilizing lamp 21 through the communication unit 23, so that the sterilizing lamp 21 corresponds to the standard irradiation amount. control so that it can be investigated accordingly.

As described above, in the UV sterilization system 20 using the lighting lamp according to the present invention, the irradiation amount calculator 40 can control the irradiation intensity of the sterilization lamp 21 to be variable according to the degree of contamination of the indoor air, so that the indoor air can be improved. There is an effect that can be maintained at a clean level.

As described above, the main technical idea of the present invention is to provide a UV sterilization system 20 using a lighting lamp, and the embodiment described above with reference to the drawings is only one embodiment, and the true rights of the present invention The scope is based on the claims, but will extend to equivalent embodiments that may exist in various ways.

10: light system
11: lights
12: power supply
13: power switch
20: UV sterilization system
21: sterilization lamp
22: control module
23: Ministry of Communications
24: control unit
25: battery part
26: on/off detection unit
30: motion detection sensor
31: light sensor
32: rotating part
33: body
33a: inlet
33b: discharge unit
34: Wings
35: axis of rotation
37: flow detection sensor
40: irradiation amount calculation unit

Claims (6)

A light 11 installed in an indoor space to illuminate the indoor space, a power supply unit 12 for supplying power to the light 11, and a power switch for turning the light 11 on/off In the UV sterilization system 20 using a lighting lamp mounted on the lighting system 10 having (13),
The UV sterilization system 20 using the lighting lamp
sterilization lamps 21 installed in the indoor space to sterilize pathogenic microorganisms through ultraviolet rays;
an on/off detection unit 26 for detecting whether the power switch 13 is turned on/off;
a control module 22 for controlling the sterilizing lamp 21 to be turned off when the lighting lamp 11 is turned on, and to control the sterilizing lamp 21 to be turned on when the lighting lamp 11 is turned off; and
A UV sterilization system using a lighting lamp, characterized in that it comprises a; battery unit 25 for supplying power to the sterilization lamp 21 by being charged by the power supplied to the power supply unit 12. According to claim 1,
The control module 22 is
a communication unit 23 for communication between the lighting system 10 and the charging sterilizing lamp 21 system; and
When the lighting lamp 11 is turned on, the battery unit 25 is charged to a predetermined amount or more using the power supplied to the power supply unit 12, and the sterilization lamp 21 is controlled to turn off immediately, , When the lighting lamp 11 is turned off, a control unit 24 for controlling the sterilization lamp 21 to be turned on for a certain period of time; includes,
The on/off detection unit 26
When the power switch 13 is switched to an on state and the lighting lamp 11 is locked, an on signal is generated,
The communication unit 23 is
Transmitting the on signal generated by the on/off detection unit 26 to the control unit 24,
The controller 24 is
After generating a charging signal according to the on signal, by transmitting the charging signal to the battery unit 25 through the communication unit 23, the battery unit 25 is supplied to the power supply unit 12. Using power, control to be charged,
The controller 24 is
After generating a stop signal according to the on signal, the stop signal is transmitted to the sterilization lamp 21 through the communication unit 23, so that the sterilization lamp 21 is immediately turned off. UV sterilization system using lighting. According to claim 2,
The on/off detection unit 26
When the power switch 13 is switched to an off state and the lighting lamp 11 is turned off, an off signal is generated,
The communication unit 23 is
The off signal generated by the on/off detection unit 26 is transmitted to the control unit 24;
The controller 24 is
After generating an operating signal according to the off signal, the operating signal is transmitted to the sterilizing lamp 21 through the communication unit 23, thereby controlling the sterilizing lamp 21 to be turned on for a certain period of time. A UV sterilization system using a lighting lamp. According to claim 2,
The UV sterilization system 20 using the lighting lamp
a motion detection sensor 30 generating a motion detection signal when a motion of a human body is detected indoors;
an optical sensor 31 for measuring the irradiation intensity of the lighting lamp 11;
Rotating part 32 provided to be able to rotate according to the flow of air flowing in the room;
a flow rate detection sensor 37 for measuring the flow rate of indoor air flowing into the rotating part 32 once per preset setting time when the lighting lamp 11 maintains an on state;
UV sterilization system using a lighting lamp, characterized in that it further comprises: an irradiation amount calculation unit 40 for controlling the irradiation intensity of the sterilization lamp 21 to be varied according to the degree of contamination of indoor air. According to claim 4,
The communication unit 23 is
Transmitting the motion detection signal, the irradiation intensity data of the lighting lamp 11, the flow rate data of indoor air, and an on signal and an off signal to the irradiation amount calculator 40;
The irradiation amount calculation unit 40
When the motion detection signal is not transmitted by the communication unit 23, the turn-on time when the on/off detector 26 generates an on signal and the turn-off time when the on/off detector 26 generates an off signal By checking each, the on time of the lighting 11 obtained by subtracting the on time from the off time is calculated,
UV sterilization system using a light, characterized in that after adding the flow rate of indoor air measured by the flow sensor (37), the average flow rate of indoor air divided by the on-time of the light (11) is calculated. According to claim 5,
The irradiation amount calculation unit 40
Calculate a reference irradiation amount by multiplying the on time of the lighting lamp 11, the irradiation intensity of the lighting lamp 11, and the average flow rate of air;
By calculating the irradiation intensity of the sterilizing lamp 21 in proportion to the standard irradiation amount and transmitting it to the sterilizing lamp 21 through the communication unit 23, the sterilizing lamp 21 can be irradiated according to the standard irradiation amount. UV sterilization system using a lighting, characterized in that for controlling.

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