KR20220014435A - IOT-based smart lighting automatic control system capable of measuring fine dust - Google Patents

Abstract

The present invention relates to an IOT-based smart lighting automatic control system capable of measuring fine dust, which provides real-time fine dust air quality information based on the current location of a user by referring to GPS information while composing a fine dust data distribution map in conjunction with the map, and utilizes fine dust concentration information for each area to quickly recognize and replace emergencies including fires. The system includes an LED lighting (10), an integrated management server (20), an IoT-based wireless network base station (30), and an IoT device (100).

Description

IOT-based smart lighting automatic control system capable of measuring fine dust}

The present invention relates to an IOT-based smart lighting automatic control system capable of measuring fine dust, and more specifically, fine dust based on the current user's location by referring to GPS information while composing a fine dust data distribution map in conjunction with a map. It relates to an automatic control system such as an IOT-based smart lighting system that provides air quality information in real time and can measure fine dust that can quickly recognize and replace sudden accidents including fires by using fine dust concentration information for each area.

The Internet of Things (IoT) refers to devices connected to a network smartly sending and receiving information to and from each other without human intervention. The concept that objects exchange communication without relying on humans is similar to ubiquitous or Machine to Machine (M2M). However, while M2M only emphasizes the concept of communication between devices, it refers to a technology that has been extended to the Internet so that all information can be interacted with.

Specifically, in order to implement the Internet of Things, a sensor that obtains information from the surrounding environment, a communication network that supports connection to a network, and a service interface technology that processes, processes, and processes information according to the service field and form are required. In addition, security technology to protect the collected data leakage and control of the device is also important.

A suitable network is needed to fully disseminate the Internet of Things. In general, the Wi-Fi network we use at home is not bad as a wireless network. However, since the bandwidth is large, the amount of data transmission is large, but power consumption is high and the signal reach is short.

The Internet of Things refers to a technology or environment in which sensors are attached to objects to exchange data in real time over the Internet. Devices connected to the Internet can send and receive information directly without human help, and in the past, technologies such as Bluetooth and Near Field Communication (NFC) were used. However, Bluetooth and Near Field Communication (NFC) were only available for short-distance communication and had to be linked with a separate wired/wireless Internet.

For this reason, there has been a movement to separately define and install a dedicated network optimized for IoT devices. IoT-only technologies include LTE-M and NB-IoT used in licensed bands, and SIGFOX and LORA in unlicensed bands.

The Internet of Small Things, created by low-power, long-distance wireless communication, is a network of things that transmit data through batteries without a constant power supply.

LORA is a technology that connects various things to a network using LTE. LORA can share all infrastructure information within LTE coverage.

LORA has a simpler structure than LTE-M. A protocol is performed between the device and the network server, and the base station simply forwards the wireless reception packet to the backhaul section. As such, the structure of the base station equipment and the terminal is simple.

LORA has a wide signal coverage area, low frequency interference, and high security, making it easy to distribute. In addition, it is a transmission technology characterized by low cost, low power, and low capacity that can be operated only with batteries without requiring a small amount of data transmission and constant power.

On the other hand, NB-IoT is one of the Low-Power Wide-Area (LPWA) Internet of Things (IoT) technologies using LTE frequencies, and is used for tracking, sensing, and meter reading that intermittently transmits low-capacity data. Specifically, for example, water/gas/electricity meter reading and air/water quality measurement system, location tracking service (locating the elderly, pet management, bicycle loss prevention), monitoring fire, hazardous substances, gas, etc. or detecting building cracks It is used for sensing services and control services such as building automation, home automation, and amusement park management. Because NB-IoT is ultra-low power, it can be used for a long time without replacing the battery.

Because objects with sensors are connected via LTE network, users can remotely control objects anytime, anywhere, and inter-object control is also possible through mutual communication. In particular, since it can be implemented only by software upgrade without building separate equipment, the cost burden is less compared to existing IoT networks such as Zegbee.

Meanwhile, with the exponential growth of LED lighting, various integrated circuit devices that supply regulated power to LEDs are emerging one after another. A DC current supply with high power consumption has been used as a standard for a long time, but in recent years, when the energy problem has become a serious issue, it is naturally being replaced by a switched-mode LED driver.

Currently, precise control of constant current is required in a wide range of fields from flashlights to electronic signboards in stadiums, and in most cases, it is necessary to adjust the LED output intensity every moment. This function is called dimming control, and various dimming control methods have been developed.

In addition, there is a trend to adopt LED lighting that saves power consumption in street lamps and security lamps. In particular, it is common for streetlights and security lights employing LED lighting to have a poor installation environment, so that the set rated power of the LED lighting cannot be used accurately. LED lighting used for street lamps and security lamps is characterized by its power consumption being very flexible in 180-240W depending on the supply voltage state. If the failure of the LED lighting to be used with the set rated power is repeated over a long period of time, the lifespan of the LED lighting may be affected.

Accordingly, the present applicant in Patent Registration No. 10-2060572, a plurality of LED street lights and security lights; an integrated management server that remotely monitors and controls the plurality of LED street lights and security lights using an IoT-based wireless network; and a LORA or NB-IoT wireless network base station 30 that wirelessly communicates with the plurality of LED street lights and security lights and an integrated management server, wherein each of the plurality of LED street lights and security lights 10 has an IoT-based wireless network An IoT device including a dimming controller that transmits/receives street light/security light information to each other using technology and controls the illuminance of each LED street light and security light is installed, and each LED street light and The technology to perform remote control and monitoring for security, etc. has been registered in advance.

The prior art is operated for the purpose of inducing a smooth vehicle flow by adjusting the LED brightness of a street lamp and a security lamp device according to a change in ambient illuminance and preventing power consumption by power saving operation.

On the other hand, as the interest in air quality is increasing due to the rapid increase in respiratory diseases caused by fine dust in recent years, air quality information is provided in real time by measuring fine dust based on detailed distance location information using existing IoT-based LED street lights. There is an urgent need to develop a platform that collects and provides.

KR 10-2060572 B1 (2019.12.23.) KR 10-1713297 B1 (2017.02.28.) KR 10-1306762 B1 (2013.09.04.)

Accordingly, the present invention was conceived to solve the above problems, and while compiling a fine dust data distribution map in conjunction with a map, it provides real-time fine dust air quality information based on the current user's location with reference to GPS information, In particular, the purpose of this is to provide an automatic control system such as IOT-based smart lighting that can measure fine dust that can quickly recognize and replace sudden accidents including fires by using fine dust concentration information for each area.

Features of the present invention to achieve this object, a plurality of LED lights (10); an integrated management server 20 having an AI module 23 to remotely control the plurality of LED lighting lamps 10 using a LORA wireless network; IoT-based wireless network base station 30 for wireless communication with the plurality of LED lighting lamps 10 and the integrated management server 20; and an IoT device 100 that is provided in a predetermined area of the holding 12 where the plurality of LED lighting lamps 10 are installed, and transmits and receives information about the LED lighting lamp 10 to and from each other through an IoT-based wireless network;

The IoT device 100 includes a microcontroller (MCU) 101 that processes all functions of information transmission, information storage, and status display, a sensor module 102 including a function of detecting fine dust, and IoT-based wireless It consists of a network module 103, a GPS module 104, a dimming controller 105 for LED lighting, and an event detection module 106, wherein the event detection module 106 is a micrometer measured by the sensor module 102. It is characterized in that it is provided to transmit an emergency notification signal when the dust detection value is detected to be higher than the value set in the integrated management server 20, or is increased by 10% or more compared to the detected value of the fine dust of the neighboring sensor module 102 do.

At this time, the integrated management server 20 manages the air quality information based on the detected value of the fine dust of the sensor module 102, and the integrated management server 20 is linked with the application of the user terminal 40, , the application of the user terminal 40 is provided to display the location of the user terminal 40 in real time by organizing a GPS-based map, and air quality on the user's moving route based on the GPS information of the user terminal 40 It is characterized in that it is provided to provide information in real time.

In addition, when at least two sensor modules 102 for which the emergency notification signal is activated by the event detection module 106 are consecutive, the GPS coordinates in which the event detection module 106 is located are connected to each other to provide a traffic caution line It is characterized in that it is provided to form (106a).

In addition, when at least two sensor modules 102 in which the emergency notification signal is activated by the event detection module 106 are consecutive, the LED lighting lamp 10 of the GPS coordinates in which the event detection module 106 is located It is characterized in that the output color is changed or the concentration of fine dust in the air is displayed in stages using a gauge light 107 installed in the longitudinal direction on the outer peripheral surface of the LED lighting lamp post 12 .

In addition, the application of the user terminal 40 receives the fine dust information detected by the sensor module 102 in real time through the integrated management server 20, and within the surrounding area set based on the location of the user terminal 40 In the condition in which the emergency notification signal is activated in the located event detection module 106, the event detection module 106 in which the emergency notification signal is activated is concentrated in a predetermined number consecutively, so that the emergency notification signal is activated for a predetermined time. In this case, it is determined that it is fine dust due to fire and is characterized in that it is provided to transmit an evacuation signal from the user terminal 40 .

In addition, the sensor module 102 is provided so as to be replaceable by a high-place replacement module 200 installed adjacent to the IoT device 100, and the high-place replacement module 200 has a conical docking groove 212 formed therein. A rope 220 that is wound on the housing 210 and the winding roller 222 installed on the housing 210, and whose end is moved to the lower end of the LED lighting lamp post 12 via the docking groove 212, A conical docking shuttle 230 connected to the rope 220, engaged with the conical docking groove 212, and fitted with the sensor module 102 detachably installed at the lower portion, and the conical docking groove 212 formed on the inner circumferential surface A housing terminal 240 connected to the IoT device 100 and a shuttle terminal formed on the outer circumferential surface of the conical docking shuttle 230 to be grounded with the housing terminal 240 and connected so that one end is energized with the sensor module 102 ( 250), and when the rope 220 is released by the winding roller 222, the conical docking shuttle 230 moves to the lower end of the LED lighting lamp post 12, and the sensor module 102 is replaced, and then the winding roller ( 222) When the rope 220 is wound by reverse operation, the conical docking shuttle 230 moves upward and is mounted in the conical docking groove 212 while the housing terminal 240 and the shuttle terminal 250 are grounded. characterized in that

In addition, a stop groove 231 is formed on the outer peripheral surface of the docking shuttle 230, a ball plunger 211 is installed on the inner peripheral surface of the housing 210 corresponding to the stop groove 231, and the docking shuttle 230 is a rope. The stop groove 231 and the ball plunger 211 are engaged with each other at the time of moving upward by 220 and meshing with the conical docking groove 212, and the position is fixed, and the take-up roller 222 and the pinion gear operated in conjunction ( 260) is provided, and a mill piece 270 that is installed on the docking groove 212 and is linearly moved in the vertical direction by the rack 272 meshed with the pinion gear 260 is installed, and the mill piece 270 is placed on the top An elastic body 274 for pulling in the direction is provided, and the rack 272 is locally formed in an upper section of the mill piece 270. When the winding roller 222 rotates to unwind the rope 220, the pinion gear The push piece 270 is linearly moved downward to a predetermined position by the driving force of the 260 and the rack 272 to press and separate the conical docking shuttle 230 coupled to the docking groove 212 and then the rack 272 and the pinion. When the meshing state of the gear 260 is released, the power transmission is released, and when the winding roller rotates in the reverse direction to wind the rope 220, the push piece 270 by the driving force of the pinion gear 260 and the rack 272. After moving upward to this predetermined position, in a state in which the meshing state between the rack 272 and the pinion gear 260 is released, the winding roller 222 is continuously rotated in the reverse direction so that the rope 220 is wound. do it with

According to the above configuration and operation, the present invention provides fine dust air quality information based on the current user's location in real time with reference to GPS information while compiling a fine dust data distribution map in conjunction with the map, and in particular fine dust by area It has the effect of quickly recognizing and replacing a sudden accident including a fire by using the concentration information.

1 is a block diagram showing the overall configuration of an IOT-based smart lighting automatic control system capable of measuring fine dust according to an embodiment of the present invention.
2 is a configuration diagram schematically showing an IoT device of an IOT-based smart lighting automatic control system capable of measuring fine dust according to an embodiment of the present invention.
3 is a block diagram illustrating an integrated management server and a user terminal of an IOT-based smart lighting automatic control system capable of measuring fine dust according to an embodiment of the present invention;
4 is a configuration diagram illustrating a traffic caution line of an IOT-based smart lighting automatic control system capable of measuring fine dust according to an embodiment of the present invention.
5 is a configuration diagram showing a gauge of an IOT-based smart lighting automatic control system capable of measuring fine dust according to an embodiment of the present invention.
6 to 7 are block diagrams showing a high-altitude replacement module of an IOT-based smart lighting automatic control system capable of measuring fine dust according to an embodiment of the present invention.

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

The present invention relates to an IOT-based smart lighting automatic control system capable of measuring fine dust, which is linked to a map to compose a fine dust data distribution map and refer to GPS information to provide fine dust air quality information based on the current user's location LED lighting (10), integrated management server (20), IoT-based wireless network base station (30) to provide real-time provision and, in particular, use fine dust concentration information for each area to quickly recognize and replace unexpected accidents including fires , characterized in that it includes the IoT device (100).

The LED lighting lamp 10 according to the present invention is installed in plurality based on a passage including roads and sidewalks, and uses LORA wireless network technology to transmit and receive information to and from each other and an integrated management server 20 to be described later. ) by transmitting the information, remote control and monitoring of the LED lighting lamp 10 is performed by the integrated management server 20 . At this time, the LED lighting lamp 10 includes a street lamp and a security lamp.

In addition, the integrated management server 20 according to the present invention is provided with an AI module 23 to remotely control the plurality of LED lighting lamps 10 using a LORA wireless network. The integrated management server 20 receives the use current, power, average voltage, blackout, short circuit, on and off, temperature, humidity, etc. of each LED lighting lamp 10, and the LED lighting lamp 10 on/off state and short circuit, Real-time detection of failure situations, etc., and prompt response.

In addition, the integrated management server 20 not only saves energy by adjusting the on and off times of each LED lighting lamp 10 based on LED lighting information, but also eliminates inconvenience to residents due to the failure of each LED lighting lamp 10 . and prevention of safety accidents.

On the other hand, the integrated management server 20 provides information on the LED lighting lamp 10 to the mobile terminal possessed by the field engineer, so that not only the integrated management server 20 but also a plurality of LED lighting lamps 10 by the field engineer can be directly controlled. Make it possible to perform control and monitoring.

In addition, the IoT-based wireless network base station 30 according to the present invention is provided to wirelessly communicate with the plurality of LED lighting lamps 10 and the integrated management server 20 .

In addition, the IoT device 100 is provided in a predetermined area of the post 12 where the plurality of LED lighting lamps 10 are installed, and transmits and receives information about the LED lighting lamp 10 to and from each other through an IoT-based wireless network.

Here, the integrated management server 20 includes a control monitoring module and an integrated management DB, and the control monitoring module 21 is from one LED lamp 10 to a plurality of LED lamps 10 through a LORA wireless network base station. Receives street light information for the city and stores it as an integrated management DB.

In this specification, the term "DB" may refer to a functional and structural combination of software and hardware for storing information corresponding to each database. The DB may be implemented as at least one table, and may further include a separate DBMS (Database Management System) for searching, storing, and managing information stored in the database.

In FIG. 2 , the IoT device 100 includes a microcontroller (MCU) 101 that processes all functions of information transmission, information storage, and status display, and a sensor module 102 including a function of detecting fine dust; , an IoT-based wireless network module 103, a GPS module 104, a dimming controller 105 for LED lighting, and an event detection module 106.

Here, the sensor module 102 includes a road user detection sensor, a power/voltage/current measurement sensor, a temperature/humidity sensor, a blackout and leakage detection sensor, an illuminance sensor, a water level detection sensor, a fire detection sensor, and the like, so that each LED The used power, average voltage, blackout, short circuit, on and off, temperature, humidity, etc. of the lighting lamp 10 are sensed to generate packetized street lamp information and provided to the MCU 101 .

And, the microcontroller 101 transmits/receives street light information based on the LORA wireless network through data transmission/reception with other LED lighting lamps 10 through the IoT-based wireless network module 103, and the microcontroller 101 By transmitting the LED lighting information to the integrated management server 20, remote control and monitoring of the LED lighting 10 is performed by the integrated management server 20, and sunrise/sunset times based on the regional sunrise/sunset database It may be provided with a real-time clock (RTC) that can check the .

In addition, the dimming controller 105 can induce a smooth traffic flow by adjusting the brightness of the LED 60 of the LED lighting lamp 10 according to changes in ambient illuminance through two-way wireless communication, and can prevent power wastage by power saving operation. can

In addition, the event detection module 106 detects that the fine dust detection value measured by the sensor module 102 is greater than or equal to the value set in the integrated management server 20, or the fine dust of the neighboring sensor module 102 is detected. It is provided to transmit an emergency notification signal when it is increased by more than 10% compared to the value.

In FIG. 3 , the integrated management server 20 manages air quality information based on the detected value of fine dust of the sensor module 102 , and the integrated management server 20 includes an application of the user terminal 40 and It is linked, and the application of the user terminal 40 is provided to display the location of the user terminal 40 in real time by organizing a GPS-based map, and based on the GPS information of the user terminal 40, on the user's movement path It is equipped to provide air quality information in real time.

In FIG. 4, when at least two sensor modules 102 in which the emergency notification signal is activated by the event detection module 106 are consecutive, the GPS coordinates in which the event detection module 106 is located are connected to each other to pass It is characterized in that it is provided to form the attention line (106a).

In addition, when at least two sensor modules 102 in which the emergency notification signal is activated by the event detection module 106 are consecutive, the LED lighting lamp 10 of the GPS coordinates in which the event detection module 106 is located It is provided so that the output color is changed or the fine dust concentration in the air is displayed in stages by using the gauge light 107 installed in the longitudinal direction on the outer circumferential surface of the LED lighting post 12 as shown in FIG. 5 . It will visually output air quality to pedestrians and drivers.

In addition, the application of the user terminal 40 receives the fine dust information detected by the sensor module 102 in real time through the integrated management server 20, and within the surrounding area set based on the location of the user terminal 40 In the condition in which the emergency notification signal is activated in the located event detection module 106, the event detection module 106 in which the emergency notification signal is activated is concentrated in a predetermined number consecutively, so that the emergency notification signal is activated for a predetermined time. In this case, it is determined that it is fine dust due to fire and is characterized in that it is provided to transmit an evacuation signal from the user terminal 40 .

In addition, the integrated management server 20 provides real-time fine dust air quality information based on the current user's location by referring to the GPS information by the user terminal 40 while composing a fine dust data distribution map in conjunction with the map. In particular, it has the advantage of quickly recognizing and replacing sudden accidents including fires by utilizing the fine dust concentration information for each area.

In addition, the sensor module 102 is provided to be replaceable by the high-place replacement module 200 installed adjacent to the IoT device 100 .

6 to 7, the high-place replacement module 200 is wound around a housing 210 in which a conical docking groove 212 is formed, and a winding roller 222 installed on the upper portion of the housing 210, and the end is A rope 220 that is moved to the lower end of the LED lighting lamp post 12 via the docking groove 212, is connected to the rope 220, is engaged with the conical docking groove 212, and is coupled to the lower portion of the sensor module 102 ) is formed on the conical docking shuttle 230 to be detachably installed, the conical docking groove 212 is formed on the inner circumferential surface and the housing terminal 240 is connected to the IoT device 100, and the conical docking shuttle 230 is formed on the outer circumferential surface. It consists of a shuttle terminal 250 that is connected to the housing terminal 240 and grounded so that one end is energized with the sensor module 102 .

As such, when the rope 220 is released by the winding roller 222, the conical docking shuttle 230 moves to the lower end of the LED lighting lamp post 12, and the sensor module 102 is replaced, and then the winding roller 222 is in the reverse operation. When the rope 220 is wound by the rope 220, the conical docking shuttle 230 moves upward and is mounted in the conical docking groove 212 while the housing terminal 240 and the shuttle terminal 250 are grounded so that the operator is positioned at a high place. The sensor module 102 is simply replaced on the floor without moving to the bottom.

In addition, a stop groove 231 is formed on the outer peripheral surface of the docking shuttle 230, a ball plunger 211 is installed on the inner peripheral surface of the housing 210 corresponding to the stop groove 231, and the docking shuttle 230 is a rope. The stop groove 231 and the ball plunger 211 are engaged with each other at the time of moving upward by 220 and meshing with the conical docking groove 212, and the position is fixed, and the take-up roller 222 and the pinion gear operated in conjunction ( 260) is provided, and a mill piece 270 that is installed on the docking groove 212 and is linearly moved in the vertical direction by the rack 272 meshed with the pinion gear 260 is installed, and the mill piece 270 is placed on the top An elastic body 274 for pulling in the direction is provided, and the rack 272 is locally formed in an upper section of the mill piece 270 .

Accordingly, when the take-up roller 222 rotates to unwind the rope 220, the push piece 270 is linearly moved downward to a predetermined position by the driving force of the pinion gear 260 and the rack 272 as shown in FIG. After the conical docking shuttle 230 coupled to the groove 212 is pressurized and separated, the meshing state of the rack 272 and the pinion gear 260 is released to release the power transmission, and the rope 220 is wound as shown in FIG. When the winding roller 222 rotates in the reverse direction, the push piece 270 is moved upward to a predetermined position by the driving force of the pinion gear 260 and the rack 272, and then the rack 272 and the pinion gear 260. In a state in which the meshing state is released, rotation is continued in the reverse direction of the winding roller 222 so that the rope 220 is wound.

As such, even if the tension of the rope 220 is loosened by the fitting of the stop groove 231 and the ball plunger 211, the docking shuttle 230 is firmly positioned to prevent a fall accident, and the sensor module 102. The mill piece 270 is linearly moved downward for one section by the rotational force of the winding roller 222 to replace the docking shuttle 230, so that the docking shuttle 230 is simply separated.

In this way, by using a single motor for driving the winding roller 222 to control the rotational motion of the winding roller 222 and the linear motion of the push piece 270 in a complex manner, weight reduction and simplification of the control algorithm are promoted. .

Meanwhile, in the present specification, the term “module” may refer to a functional and structural combination of hardware for performing the technical idea of the present invention and software for driving the hardware. For example, a module may mean a logical unit of a predetermined code and a hardware resource for executing the predetermined code, and does not necessarily mean physically connected code or one type of hardware. For an average expert in the technical field, it can be easily inferred.

10: LED light 12: pole
20: integrated management server 30: IoT-based wireless network base station
40: user terminal 50: fire server
100: IoT device 101: microcontroller
102: sensor module 103: IoT-based wireless network module
104: GPS module 105: LED light dimming controller
106: event detection module 106a: traffic caution line
107: gauge light
200: high replacement module 210: housing
211: ball plunger 212: conical docking groove
220: rope 222: winding roller
230: docking shuttle 231: stop home
240: housing terminal 250: shuttle terminal
260: pinion gear 270: wheat pyeon
272: leg 274: elastic body

Claims (7)

a plurality of LED lights (10);
an integrated management server 20 having an AI module 23 to remotely control the plurality of LED lighting lamps 10 using a LORA wireless network;
an IoT-based wireless network base station 30 that wirelessly communicates with the plurality of LED lighting lamps 10 and the integrated management server 20; and
The IoT device 100 is provided in a predetermined area of the holding 12 where the plurality of LED lighting lamps 10 are installed, and transmits and receives information about the LED lighting lamp 10 to and from each other by an IoT-based wireless network;
The IoT device 100,
A microcontroller (MCU) 101 that processes all functions of information transmission, information storage, and status display, a sensor module 102 including a function of detecting fine dust, an IoT-based wireless network module 103, and a GPS Consists of a module 104, an LED lighting dimming controller 105 and an event detection module 106,
The event detection module 106 detects that the fine dust detection value measured by the sensor module 102 is greater than or equal to the value set in the integrated management server 20, or compares the fine dust detection value of the neighboring sensor module 102 IOT-based smart lighting automatic control system capable of measuring fine dust, characterized in that it is provided to transmit an emergency notification signal when it is increased by more than 10%. The method of claim 1,
The integrated management server 20 manages air quality information based on the detected value of fine dust of the sensor module 102, and the integrated management server 20 is linked with an application of the user terminal 40, and the The application of the user terminal 40 is provided to display the location of the user terminal 40 in real time by organizing a GPS-based map, and air quality information on the user's moving route based on the GPS information of the user terminal 40 An IOT-based smart lighting automatic control system capable of measuring fine dust, characterized in that it is provided in real time. The method of claim 1,
When at least two sensor modules 102 for which the emergency notification signal is activated by the event detection module 106 are consecutive, the GPS coordinates in which the event detection module 106 is located are connected to each other and the traffic caution line 106a ), an IOT-based smart lighting automatic control system capable of measuring fine dust, characterized in that it is provided to form. The method of claim 1,
When at least two sensor modules 102 in which the emergency notification signal is activated by the event detection module 106 are consecutive, the output color of the LED lighting lamp 10 of the GPS coordinates where the event detection module 106 is located IOT-based smart lighting capable of measuring fine dust, characterized in that it is provided so that the concentration of fine dust in the air is displayed step by step using a gauge light 107 installed in the longitudinal direction on the outer peripheral surface of the LED lighting lamp post 12 automatic control system. The method of claim 1,
The application of the user terminal 40 receives the fine dust information detected by the sensor module 102 in real time through the integrated management server 20, and is located in the surrounding area set based on the location of the user terminal 40. When the emergency notification signal is activated in the event detection module 106, the event detection module 106 in which the emergency notification signal is activated is concentrated in a predetermined number successively and the emergency notification signal is activated for a predetermined time. IOT-based smart lighting automatic control system capable of measuring fine dust, characterized in that it is determined as fine dust due to fire and is provided to transmit an evacuation signal from the user terminal (40). The method of claim 1,
The sensor module 102 is provided to be replaceable by a high-place replacement module 200 installed adjacent to the IoT device 100, and the high-place replacement module 200 includes a housing in which a conical docking groove 212 is formed. 210, and a rope 220 that is wound on a winding roller 222 installed on the upper portion of the housing 210, the end of which is moved to the lower end of the LED lighting lamp post 12 via the docking groove 212, and the rope ( 220), the conical docking shuttle 230 that is engaged with the conical docking groove 212, and the sensor module 102 is detachably installed at the lower portion, and the conical docking groove 212 formed on the inner circumferential surface of the IoT A housing terminal 240 connected to the device 100 and a shuttle terminal 250 formed on the outer peripheral surface of the conical docking shuttle 230 and connected so that one end is energized with the sensor module 102 while being grounded with the housing terminal 240 ) When the rope 220 is released by the winding roller 222, the conical docking shuttle 230 moves to the lower end of the LED lighting lamp post 12, and the sensor module 102 is replaced, and then the winding roller 222) When the rope 220 is wound by reverse operation, the conical docking shuttle 230 moves upward and is mounted in the conical docking groove 212 while the housing terminal 240 and the shuttle terminal 250 are grounded. An IOT-based smart lighting automatic control system that can measure fine dust with 7. The method of claim 6,
A stop groove 231 is formed on the outer peripheral surface of the docking shuttle 230, a ball plunger 211 is installed on the inner peripheral surface of the housing 210 corresponding to the stop groove 231, and the docking shuttle 230 is connected to the rope 220 ), the stop groove 231 and the ball plunger 211 are engaged with each other at the point in time when they are moved upward and are engaged with the conical docking groove 212, and the position is fixed, and the take-up roller 222 and the pinion gear 260 operated in conjunction with each other. is provided, and the mil piece 270 is installed on the docking groove 212 and is linearly moved in the vertical direction by the rack 272 meshed with the pinion gear 260 is installed, and the mil piece 270 is moved upward. An elastic body 274 for pulling is provided, and the rack 272 is formed locally in an upper section of the push piece 270. When the winding roller 222 rotates to unwind the rope 220, the pinion gear 260 ) and the driving force of the rack 272, the push piece 270 is moved downward to a predetermined position in a straight line to press and separate the conical docking shuttle 230 coupled to the docking groove 212, and then the rack 272 and the pinion gear ( 260) is released, the power transmission is released, and when the winding roller rotates in the reverse direction to wind the rope 220, the push piece 270 is predetermined by the driving force of the pinion gear 260 and the rack 272. After moving upward to the position of IOT-based smart lighting automatic control system that can measure fine dust.

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