KR102265975B1 - Smart led prevention system - Google Patents

Abstract

Provided is a smart LED disinfection system which emits UV-C rays to air to kill bacteria and viruses. According to the present invention, the smart LED disinfection system comprises: a case installed on the ceiling of a building and forming a purification area inside; a plurality of UV-C LEDs installed at regular intervals on the upper and lower surfaces of the case to perform sterilization by emitting UV-C rays to the air sucked into the purification area; a filter installed adjacent to the UV-C LEDs in the purification area to purify the introduced air; an air circulation device installed in the purification area to introduce the air from the indoor space into the purification area and circulate the sterilized and purified air to the indoor space; a PCB in which a plurality of lighting LEDs and a plurality of visible light LEDs are arranged at the lower part of the case to be exposed to the indoor space to provide lighting and visible light to the indoor space; and a control center controlling operation of the plurality of UV-C LEDs, the plurality of lighting LEDs, the plurality of visible light LEDs, and the air circulation device.

Description

Smart LED prevention system {SMART LED PREVENTION SYSTEM}

The present invention relates to a quarantine system, and more particularly, to a smart LED quarantine system.

In general, fine dust or dust is an air pollutant containing sulfurous acid gas, nitrogen oxides, lead, ozone, carbon monoxide, and the like as dust with small particles that are invisible to the naked eye. Fine dust is fine dust with a particle diameter of 10 μm or less that is generated in automobiles and factories and floats in the air for a long period of time, also called PM 10. When the particle size is 2.5㎛ or less, PM 2.5 is written and it is also called 'ultra-fine dust' or 'ultra-fine dust'. Scientifically, it is called an aerosol. Fine dust is also called suspended particles and particulate matter, and has slightly different meanings depending on the name. Particulate matter has a diameter of 100 μm to 10 nm, and if the diameter is larger than this, the residence time in the atmosphere is very short due to gravity. In addition, fine dust is a very small substance that is invisible to our eyes. It is a particulate matter with a diameter of 10 μm or less that floats or is blown down in the atmosphere.

The causes of fine dust emission are divided into anthropogenic and natural. The anthropogenic causes may be fine dust from China and incineration of soot waste from factories. The natural causes are dust from sand winds, volcanic ash, and dust from forest fires. Sea salt particles also have a significant impact on areas located close to the sea.

In modern times, due to urban development and industrial development, pollutants generated from factories and vehicles are excessive in the air, and the damage and inconvenience caused by fine dust has reached a point where it is indescribable. In particular, fine dust penetrates deeply into the respiratory tract of the human body and causes respiratory diseases such as asthma, bronchitis, and allergic rhinitis, or is a major cause of eye diseases such as conjunctivitis and dry eye, and causes allergic rhinitis of skin diseases. Infants, adolescents, and the elderly are particularly vulnerable to fine dust.

The air pollution accident that killed 20 people in Donora, Pennsylvania, USA in 1948 and London smog that caused about 4,000 deaths in 1952 are representative examples of how fine dust affects the human body. Since then, various epidemiological studies have been conducted on the effects of fine dust on the human body. In particular, there is a possibility that fine dust particles (PM 10) smaller than 10 μm may have a detrimental effect on the human body, such as increasing the disease incidence and mortality in vulnerable groups. turned out to be large. After the results of these studies were published, governments around the world started to prepare air pollution countermeasures, and air pollution standards are also being prepared to reduce the harmful effects of fine dust on the human body and the environment.

Meanwhile, bacteria and viruses that pose a fatal threat to human survival can cause transmission between humans. Bacteria are a representative taxon of prokaryotes occupying one of the three domains of living organisms along with archaebacteria and eukaryotes. More than 13,000 species are known so far, and 600 new species are newly reported every year, and the number is continuously increasing. Bacteria surpass other organisms in their distribution to the extent that they can be found anywhere on the planet, and their metabolic diversity is also phenomenal.

Bacteria contain industrially important taxa along with various pathogens and are inextricably linked with humans in daily life. It provides important information that can be the basis for a holistic understanding.

Bacteria are single-celled organisms made up of one cell, but they have organs that allow them to live on their own. In other words, they can reproduce while eating their own food and making their own organic matter.

Unlike the bacteria, viruses have a simple structure composed of nucleic acids and proteins such as DNA and RNA. Most living things make necessary proteins using organs such as ribosomes based on genetic information in DNA. However, since viruses do not have organs like ribosomes, unlike bacteria, they cannot make their own necessary energy or organic matter. Therefore, viruses do not fully belong to the category of living things. This is because it cannot live alone, and only when there is an organism that becomes a host, it grows by borrowing the power of that organism.

A disease that collectively spreads to living organisms including humans through the above bacteria or viruses is called an infectious disease, and refers to the transfer of pathogens such as bacteria, viruses, rickettsia, spirochetes, fungi, and protozoa to other organisms.

From a historical perspective, from the 14th-century Black Death in Europe to the recent novel coronavirus, mankind has been constantly fighting the worst epidemics. Infectious diseases are an unavoidable enemy of mankind. The Spanish flu, which terrified mankind more than 100 years ago, took the lives of more than 25 million people. About 10 years ago, the H1N1 flu hit the global village and more than 280,000 people around the world were infected. In 2014, the Ebola virus swept through Africa. As such, the World Health Organization (WHO) defines the 21st century as the era of epidemics. This is because the speed of transmission is beyond imagination as transportation develops and human-to-human contact increases rapidly.

UV sterilization is a method of sterilization using ultraviolet rays. Ultraviolet rays are light with a wavelength range of 10 to 400 nm (energy range 3 eV to 124 eV), and are a generic term for electromagnetic waves having a shorter wavelength than visible light and longer than X-rays. In the ultraviolet rays as described above, ultraviolet C having a wavelength range of 100 to 280 nm and an energy range of 4.43 to 12.4 eV has a sterilizing action.

As a prior art related to fine dust reduction and bacteria and virus sterilization as described above, domestic patent registration No. 10-1102616 absorbs moisture generated by condensation of condensate from fine dust mixed in the air, An air purifying device for fine dust to filter out is disclosed, and after primary treatment of dust, fine dust and odors in Domestic Utility Model Registration No. 20-0425412, the odor gas is mixed with the purification solution and the residence time A polluted gas purification device using a deodorizing tower and a mixing system configured to improve the polluted gas purification performance by increasing the contact area with the purification solution and to extend the cleaning solution replacement cycle is disclosed, and Korean Patent Laid-Open Publication No. 10-2018- A gas processing chamber installed in the polluting gas transport path to process and discharge the polluting gas introduced in No. 0051923, an electromagnetic wave wave generator that generates and provides electromagnetic wave waves into the gas processing chamber, and a uniform temperature inside the gas processing chamber Air pollution gas and fine dust reduction system is disclosed, characterized in that it comprises a heat generation and temperature control unit for maintaining the temperature, and a plasma generator for maintaining the inside of the gas processing chamber in a plasma state, published in Korea Patent Publication Prior art that had disadvantages such as increased cost and inconvenience due to frequent filter replacement due to the use of a filter or spraying water in No. 10-2018-0027128, and complicated overall device configuration and high energy consumption In order to solve the problems of fine dust reduction devices and air purification devices of As water particles and external air pass through the inside of the vortex tube together, the contact time and area are maximized to effectively reduce fine dust. Using a vortex tube that is configured to improve A fine dust reduction device and an air purification system using the same are disclosed. In addition, in Korea Patent Publication No. 10-2016-0054730, a UV LED for photocatalyst installed on a UV LED substrate and a photocatalyst filter are configured to enable deodorization, dust collection and sterilization, and a robust and easy-to-maintain air purifier is disclosed. has been

However, the above prior art has a problem in that it is difficult to install and the cost is increased because the configuration for reducing fine dust and sterilizing bacteria and viruses is complicated.

Patent Registration No. 10-1102616 {Registration Date: December 28, 2011}

The present invention sterilizes (sterilizes) bacteria and viruses by irradiating UV-C ultraviolet rays to the inhaled air by means of a UV-C LED installed inside the case, and at the same time includes fine dust or dust contained in the air sucked by the filter. The purpose is to provide a smart LED prevention system that can remove foreign substances.

Another object of the present invention is a lighting mode in which only a plurality of lighting LEDs arranged on a PCB are lit according to an operation signal according to a user's selection under the control of a control center or through a smart phone linkage, a sterilization in which only a plurality of visible light LEDs are turned on The purpose of this is to provide a smart LED prevention system that can distinguish and control operation in a mixed mode in which a mode, a lighting LED, and a visible light LED are mixed.

Another object of the present invention is to monitor the virus outbreak status data anytime and anywhere by wirelessly communicating with the control center by the indoor space management app of the smart phone, and a plurality of UV-C LEDs, lighting LEDs and visible light LEDs, and air circulation The goal is to provide a smart LED prevention system that can be remotely controlled by providing user commands including the operating conditions of the device to the control center.

Smart LED quarantine system according to the present invention is installed on the ceiling of a building and forming a purification area inside the case; A plurality of UV-C LEDs installed at regular intervals on the upper and lower surfaces of the case to sterilize by irradiating UV-C ultraviolet rays to the air sucked into the purification area; A filter installed in the purification area adjacent to the UV-C LED to purify the introduced air; installed in the purification area to introduce the air from the indoor space into the purification area, and the sterilized and purified air an air circulation device that circulates the air into the indoor space; a PCB in which a plurality of lighting LEDs and a plurality of visible light LEDs are arranged at the lower portion of the case to be exposed to the indoor space to provide illumination to the indoor space and to irradiate the visible light; and a control center for controlling the operation of the plurality of UV-C LEDs, the plurality of lighting LEDs and the plurality of visible light LEDs, and controlling the operation of the air circulation device.

The filter may include: a pre-filter for filtering foreign substances including dust contained in the sucked air; And it may include a celite filter for deodorizing and purifying odors, including odors discharged together with the air, by compression molding a powder composed of a mixture of silicon dioxide, germanium, and carbon components into pellets. The control center may include: a memory for storing dataized past virus information, operating conditions of the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of visible light LEDs; a smart display input/output unit that receives the user command and displays the detected indoor space temperature and humidity, and operating states of the ventilation blower and the dehumidifying humidifier according to the determination result; generating a control signal to set, change, and store the operation conditions of the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of visible light LEDs, and the operation of the ventilation blower and the dehumidifying humidifier; Controls the operation of the warning system to warn of the current virus outbreak, and according to the user command, a lighting mode in which only the plurality of lighting LEDs are turned on, a sterilization mode in which only the plurality of visible LEDs are turned on, and the lighting LEDs and the A control unit for controlling the division operation in a mixed mode in which visible light LEDs are mixed; and a communication unit communicating with the smart phone through wireless communication.

Irradiation of UV-C ultraviolet light by the UV-C LED and irradiation of visible light by the visible light LED may be limited to 3 consecutive hours and 3 times a day or less by the smart display input/output unit. The smart LED prevention system includes a sensor module for recognizing indoor conditions by detecting human movement, indoor space temperature and humidity; a first power control unit for controlling power supply for on/off of the plurality of lighting LEDs and on/off of the plurality of visible light LEDs according to a control signal from the control center; and a second power control unit controlling power supply for the operation of the ventilation blower and the operation of the dehumidifying humidifier according to the control signal from the control center, wherein the control center recognizes the indoor situation by the sensor module. According to the analysis and determination of the virus outbreak situation, it is possible to control the operation of the plurality of UV-C LEDs, the plurality of lighting LEDs, and the plurality of visible light LEDs according to the determination result.

When the indoor space management app is executed, the smart LED prevention system wirelessly communicates with the control center to monitor virus outbreak data, and the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of It may further include a smart phone that provides a user command including the operating conditions of the visible light LED to the control center. The smart phone may include: an input unit for receiving a user's command including operating conditions of the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of visible light LEDs; By executing an app according to a signal from the input unit, a control signal is provided to set, change, and store the operating conditions of the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of visible light LEDs. a control unit to output; a wireless communication unit communicating with the control center in a communication format set according to the control signal from the control unit; And the plurality of UV-C LEDs, the air circulation device, the plurality of LEDs for lighting and the plurality of visible light LEDs may include a display unit for displaying, setting, change, and storage information.

The smart LED prevention system according to the present invention has the following effects.

First, by UV-C LED installed inside the case, UV-C ultraviolet rays are irradiated to the inhaled air to sterilize (disinfect) bacteria and viruses, and at the same time, it is possible to sterilize (disinfect) bacteria and viruses with fine dust or dust contained in the air inhaled by the filter. It is possible to purify and disinfect indoor air at the same time by circulating the air filtered by foreign substances to the indoor space by the air circulation device. Since UV-C LED is installed inside the case, it is harmless to the human body even when irradiated for a long time.

Second, a lighting mode in which only a plurality of lighting LEDs arranged on the PCB installed in the lower part of the case are turned on according to a manipulation signal according to a user's selection under the control of the control center or through a smart phone linkage, and only a plurality of visible light LEDs are turned on It has a general lighting and sterilization effect because it can be controlled separately in a sterilization mode that is used, a mixed mode in which a LED for lighting and a visible light LED are mixed.

Third, by wirelessly communicating with the control center by the indoor space management app of the smartphone, the virus outbreak status data is monitored anytime and anywhere, and a plurality of UV-C LEDs 100, the air circulation device, a plurality of lighting LEDs and a plurality of By providing a user command including the operating conditions of the visible light LED of the control center to the control center can be remotely controlled. This smart LED prevention system can be used in various places where there are many people, such as home, office, auditorium, and school.

1 is a block diagram showing the configuration of a smart LED prevention system according to the present invention.
2 is a view showing a state in which a smart LED prevention system according to an embodiment of the present invention is installed in an indoor space.
FIG. 3 is a front perspective view of the case shown in FIG. 2 .
4 is a bottom view illustrating a sensor module and a PCB installed under the case shown in FIG. 2 .
FIG. 5 is a plan view illustrating a control center installed on an upper portion of the case shown in FIG. 2 .
6 is a view showing a smart display input/output unit, a ventilation blower, a dehumidifying humidifier, and first and second power control units of the main control center shown in FIG. 1 .
7 is a block diagram illustrating the detailed configuration of the control center and the smart phone shown in FIG. 1 .
8 is a view comparing the ultraviolet sterilization spectrum of UV LED (UVC 100-280nm, UVB 280-315nm, UVA 315-400nm) compared to sunlight.
9 is a view for explaining the characteristics of ultraviolet rays that can be applied to the present invention.
10 is a diagram illustrating an example of the application of UV LEDs for each wavelength region.

Hereinafter, a smart LED prevention system according to an embodiment of the present invention according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of a smart LED prevention system according to the present invention. 2 is a view showing a state in which the smart LED prevention system according to an embodiment of the present invention is installed in an indoor space.

The smart LED prevention system according to the present invention is a case 300, a UV-C LED 100, a filter 900, an air circulation device 950, a sensor module 200, a PCB 400, and a control center 500 ), a first power control unit 1000 , a second power control unit 1100 , and a smart phone 600 .

The case 300 is installed on the ceiling 10 of the building and forms a purification area 310 therein.

FIG. 3 is a front perspective view of the case shown in FIG. 2 . Referring to FIG. 3 , a plurality of UV-C LEDs 100 are installed at regular intervals on the upper and lower surfaces of the case 300 , and are sterilized by irradiating UV-C ultraviolet rays to the air sucked into the purification area 310 . (sterilize)

A filter 900 is installed adjacent to the UV-C LED 100 in the purification area 310 to purify the introduced air. The filter 900 includes a pre-filter for filtering foreign substances including fine dust contained in the sucked air; And it may include a celite filter for deodorizing and purifying odors, including odors discharged together with the air, by compression molding a powder composed of a mixture of silicon dioxide, germanium, and carbon components into pellets.

An air circulation device 950 is installed in the purification area 310 to introduce the air from the indoor space 20 into the purification area 310 and to supply the sterilized and purified air to the indoor space 20 . cycle with

4 is a bottom view illustrating a sensor module and a PCB installed under the case shown in FIG. 2 . Referring to FIG. 4 , the sensor module 200 recognizes an indoor situation by detecting a human body motion, indoor space temperature, and humidity.

The PCB 400 has a plurality of lighting LEDs 410 and a plurality of visible light LEDs 420 arranged in the lower portion of the case 300 to be exposed to the indoor space 20 to provide lighting to the indoor space and provide visibility irradiate the light

FIG. 5 is a plan view illustrating the control center installed on the upper part of the case 300 shown in FIG. 2 . The control center 500 is installed on the upper surface of the case 300 and analyzes and determines the virus outbreak situation by comparing the currently detected data with the stored data of the past virus information according to the indoor situation recognition result by the sensor module 200, and , control the operation of the plurality of UV-C LEDs 100, the plurality of lighting LEDs 410 and the plurality of visible light LEDs 420 according to the determination result, and control the operation of the air circulation device 900 do.

The control center 500 includes a memory 510 , a smart display input/output unit 530 , a control unit 560 , and a communication unit 570 .

The memory 510 has data of past virus information, the plurality of UV-C LEDs 100 , the air circulation device 700 , the plurality of lighting LEDs 410 and the operating conditions of the plurality of visible light LEDs 420 . Save it.

6 is a view showing the smart display input/output unit, the ventilation blower, the dehumidifying humidifier, and the first and second power control units of the main control center shown in FIG. 2 , and FIG. 7 is the control center and the smart unit shown in FIG. 1 . It is a block diagram showing the detailed configuration of the phone.

The smart display input/output unit 530 receives the user command, and displays the detected indoor space temperature and humidity, and operating states of the ventilation blower 700 and the dehumidifying humidifier 800 according to the determination result. Irradiation of UV-C ultraviolet light by the UV-C LED 100 and the irradiation of visible light by the visible light LED 420 are performed continuously for 3 hours and 3 times a day or less by the smart display input/output unit 530. Limits can be set.

The control unit 560 sets, changes, and stores the operating conditions of the plurality of UV-C LEDs 100 , the air circulation device 900 , the plurality of lighting LEDs 410 and the plurality of visible light LEDs 420 . The operation of the ventilation blower 700 and the dehumidifying humidifier 800 that generates a control signal to make this happen, exhausts the indoor polluted air to the outdoors and introduces clean external air into the indoor space, and the current virus outbreak situation Controls the operation of the warning system 550 to alert. The control unit 560 is a lighting mode in which only a plurality of LEDs 410 for lighting are turned on according to the user command, a sterilization mode in which only a plurality of visible LEDs 420 are turned on, LEDs for lighting 410 and visible LEDs 420 It controls the operation separated by the blending mode used for blending.

The communication unit 570 communicates with the smart phone 600 through any one of wireless communication of 2.4GHz Bluetooth Low Energy (BLE), Wi-Fi, ZigBee, and Z-Wave.

The first power control unit 1000 supplies power for on/off of the plurality of lighting LEDs 410 and on/off of the plurality of visible light LEDs 420 according to a control signal from the control center 500 . to control

The second power control unit 1100 controls power supply for the operation of the ventilation blower 700 and the operation of the dehumidifying humidifier 800 according to a control signal from the control center 500 .

When the indoor space management app is executed, the smart phone 600 wirelessly communicates with the control center 500 to monitor virus outbreak data, and the plurality of UV-C LEDs 100 and the air circulation device 950 . , provides a user command including operating conditions of the plurality of lighting LEDs 410 and the plurality of visible light LEDs 420 to the control center 500 .

The smart phone 600 includes an input unit 610 , a control unit 630 , a wireless communication unit 650 , and a display unit 670 .

The plurality of UV-C LEDs 100 , the air circulation device 900 , the plurality of lighting LEDs 410 , and the plurality of visible light LEDs 420 receive user commands including operating conditions.

The control unit 630 executes the app 635 according to the signal from the input unit 610, and the plurality of UV-C LEDs 100, the air circulation device 950, the plurality of lighting LEDs 410 and the A control signal is output to set, change, and store the operating conditions of the plurality of visible light LEDs 420 .

The wireless communication unit 650 communicates with the control center 500 in a communication format set according to the control signal from the control unit 630 .

The display unit 670 sets, changes, and operates operating conditions of the plurality of UV-C LEDs 100 , the air circulation device 950 , the plurality of lighting LEDs 410 and the plurality of visible light LEDs 420 , and Displays storage information.

Hereinafter, the lighting or sterilization function by the plurality of UV-C LEDs 100 , the plurality of lighting LEDs 410 and the plurality of visible light LEDs 420 will be described in detail.

8 is a view comparing the UV sterilization spectrum of UV LEDs (UVC 100-280 nm, UVB 280-315 nm, UVA 315-400 nm) compared to sunlight, and FIG. 9 is a UVC LED having a wavelength of 254 nm and a wavelength of 405 nm. It is a view showing the scientific name of sterilization of UVA LED, and FIG. 10 is a view showing an example of utilization by wavelength of UV LED.

UV LED provides an ultraviolet sterilization effect, and uses LEDs having a wavelength of UVC 100-280nm, UVB 280-315nm, UVA 315-400nm, or visible UV 405nm-415nm by wavelength. Ultraviolet (UV) light is a type of light and has a wavelength of 100 to 380 nm. Ultraviolet rays have a sterilization effect for each wavelength, and even in this ultraviolet light, the wavelength of 253.7nm is the most easily absorbed by DNA (deoxyribonucleic acid) such as bacteria and viruses, and the absorbed ultraviolet rays destroy the DNA necessary for maintaining life and transferring genetic information. It destroys and prevents regeneration or stops activity such as bacteria and causes death. Sterilization by ultraviolet rays has little effect on water quality compared to sterilization by chemicals or the like. Moreover, since the processing time is short and the apparatus is also compact, it is utilized for a wide range of uses.

UV (ultra violet) can be classified into visible light UV 405 to 415 nm, UVA 315 to 400 nm, UVB 280 to 315 nm, and UVC 100 to 280 nm according to the length of the wavelength.

UV-A ultraviolet rays have a long wavelength of about 315-400 nm and account for about 1% of the sunlight, and are used for industrial purposes because they cause a photochemical reaction, and are used for printing coatings, including UV curing, atopy, psoriasis. It is used for skin treatment and medical purposes, such as for counterfeit money, biochemical weapons, and air purifiers. UV-B ultraviolet rays have a wavelength of about 280-315 nm and can reach the basal layer of the epidermis or the upper dermis.

UV-C ultraviolet rays are ultraviolet rays with high energy and are called germicidal rays. It provides a bactericidal effect by destroying the DNA and RNA of microorganisms. Because UVC has a short wavelength and almost all of it is absorbed by the ozone layer, the amount that reaches the surface is very small. UV-C is highly bactericidal and can be used to kill bacteria, viruses and unicellular tissues. On the other hand, when UV-C is irradiated to a material such as polyester or vinyl, fine crystals can be formed. In the wavelength range of UV LED used for UV sterilization, the wavelength of 254 nm has the greatest sterilization power when directly irradiated to the DNA of microorganisms. In addition, ultraviolet rays show a great sterilization effect because of their high transmittance even in water. The components of microorganisms consist of proteins and nucleic acids, and when UV light is irradiated, the DNA of the microorganisms is destroyed and eventually sterilized. Therefore, it is possible to sterilize microorganisms (eg, bacteria, anthrax, typhoid, Pseudomonas aeruginosa, Escherichia coli, cholera, blue mold, various microbial viruses) in air and water by using ultraviolet rays.

Ultraviolet sterilization can sterilize bacteria and viruses from 99% to 99.9% within 1 to 2 seconds, and it can effectively remove almost all bacteria and viruses, and since it does not add chemicals, secondary pollution of water bodies and surrounding environments is eliminated. Its use is increasing due to the small area of sterilization equipment and simple structure requirements as well as low operation and maintenance costs. Ultraviolet sterilization is effective for sterilization of all bacterial species, does not change the irradiated object, and is a simple and very economical sterilization method. In addition, the UV sterilization method has many advantages such as sterilization in a very short time without cost and time compared to other treatment methods. It is widely used for sterilization treatment of drinking water used in transportation means such as etc. and in each household. Since the sterilization effect of ultraviolet rays is related to the wavelength and irradiation amount (radiation intensity x irradiation time) of ultraviolet rays, a uniform sterilization effect can be expected only when a certain wavelength (250-260 nm), radiation intensity, and irradiation time are maintained.

On the other hand, although specific embodiments have been described in the detailed description and accompanying drawings of the present invention, the present invention is not limited to the disclosed embodiments, and the technical spirit of the present invention is provided to those of ordinary skill in the art to which the present invention pertains. Various substitutions, modifications, and changes are possible without departing from it. Accordingly, the scope of the present invention should not be limited to the described embodiments and should be construed as including not only the claims described below but also equivalents to these claims.

10: Building ceiling 20: Indoor space 100: UV-C LED
200: sensor module 300: case 310: purification area
400: PCB 410: LED for lighting 420: visible light LED
500: control center 510: memory
530: smart display input/output 550: warning system
560: control unit 570: communication unit 600: smart phone
610: input unit 630: control unit 635: app
650: wireless communication unit 670: display unit 700: ventilation blower
800: dehumidifying humidifier 900: filter 950: air circulation device
1000: first power control unit 1100: second power control unit

Claims (4)

a case installed on the ceiling of the building and forming a purification area inside;
A plurality of UV-C LEDs installed at regular intervals on the upper and lower surfaces of the case to sterilize by irradiating UV-C ultraviolet rays to the air sucked into the purification area;
a filter installed adjacent to the UV-C LED in the purification area to purify the sucked air;
an air circulation device installed in the purification area to introduce the air from the indoor space into the purification area and circulate the purified air to the indoor space;
a PCB in which a plurality of lighting LEDs and a plurality of visible light LEDs are arranged to be exposed to the indoor space at the lower portion of the case to provide lighting to the indoor space and to irradiate the visible light; and
A control center for controlling the operation of the plurality of UV-C LEDs, the plurality of lighting LEDs and the plurality of visible light LEDs, and controlling the operation of the air circulation device,
the control center
a memory for storing dataized past virus information, operating conditions of the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of visible light LEDs;
a smart display input/output unit that receives a user command, and displays the detected indoor space temperature and humidity, and operation states of the ventilation blower and the dehumidifying humidifier;
generating a control signal to set, change, and store the operation conditions of the plurality of UV-C LEDs, the air circulation device, the plurality of lighting LEDs and the plurality of visible light LEDs, and the operation of the ventilation blower and the dehumidifying humidifier; Controls the operation of the warning system to warn of the current virus outbreak, and according to the user command, a lighting mode in which only the plurality of lighting LEDs are turned on, a sterilization mode in which only the plurality of visible LEDs are turned on, and the lighting LEDs and the A control unit for controlling the division operation in a mixed mode in which visible light LEDs are mixed; and
A smart LED prevention system including a communication unit that communicates with a smart phone through wireless communication. The method of claim 1 , wherein the filter comprises: a pre-filter configured to filter foreign substances including dust contained in the suctioned air; and a celite filter that deodorizes and purifies odors including odors emitted with the air by compression molding a powder composed of silicon dioxide, germanium, and carbon components mixed into pellets. delete The method according to claim 1,
Irradiation of UV-C ultraviolet light by the UV-C LED and irradiation of visible light by the visible light LED are limited to 3 consecutive hours and 3 times a day or less by the smart display input/output unit.

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