KR102391895B1 - IoT platform for sensor integrated operation using existing sensors - Google Patents

Abstract

The present invention relates to a sensor integrated operation IoT platform system, and more specifically, to a sensor integrated operation IoT platform system, which converts digital signals and/or analog signals sensed by sensors (gas sensor, oxygen sensor, ammonia sensor, tilt sensor, crack sensor, temperature sensor, humidity sensor, fire detector, etc.) installed in a structure into digital data and transmits the data, so that the sensor monitor collects sensor data, detects disasters, generates warning signals and numerical data, transmits the same to a server in real time through wired or wireless methods, and the server monitors and controls the transmitted data. Therefore, through communication between existing sensors and monitors and the platform server, it is possible to help prevent accidents by sending drawings to pre-registered users by an SMS text message or e-mail push function.

Description

IoT platform system for sensor integrated operation using existing sensors

The present invention relates to a sensor integrated operation IoT platform system that integrates and operates various existing sensors, and more particularly, to a variety of existing sensors (gas sensor, oxygen sensor, ammonia sensor, tilt sensor, crack sensor, temperature sensor). , humidity sensor, fire detector, etc.) or sensor monitor (monitor) converts digital signal data and analog signals to digital data, collects the transmitted data or signals, and transmits the transmitted data in real time to the server through wired or wireless methods. It relates to a sensor integrated operation IoT platform system developed to control the

As technology advances, new types of disasters are continuously occurring, and in general, these disasters cause casualties and economic losses. It is most important to prevent such disasters in advance, but it is true that it is not easy. Therefore, in the event of a disaster, it is important to identify the occurrence of the disaster within the shortest time and minimize the loss of life and economic loss through rapid evacuation and suppression of the disaster.

Looking at the existing prior art literature, Domestic Patent Publication No. 10-2062462 IoT Fire Detector and IoT Smart Safety Management System (Registered on Dec. 27, 2019) (hereinafter referred to as 'Prior Art Document') are fire detection and evacuation This is a system that automatically transmits fire location information and evacuation information when a fire occurs.

However, since the prior art document includes only fire-related sensors, it was impossible to cope with various disasters such as gas accidents, earthquakes, and building collapses.

Therefore, it is urgently required to develop an integrated sensor IoT platform that can respond flexibly to various disasters by introducing various sensors (gas sensor, oxygen sensor, ammonia sensor, inclination sensor, crack sensor, temperature sensor, humidity sensor, fire detector, etc.). .

Republic of Korea Patent Publication No. 10-2062462 (Registration date: 2019.12.27.)

The technical task to be achieved by the present invention in order to solve the above-mentioned problems is a variety of existing sensors (eg, a gas sensor, an oxygen sensor, an ammonia sensor, a tilt sensor, a crack sensor, a temperature sensor, a humidity sensor, a fire detector, etc.) Alternatively, the digital signal data and analog signal of the sensor monitor (or monitoring device) are converted into digital data and the transmitted data or signal is transmitted to the server in real time. The purpose is to present a sensor integrated operation IoT platform system that enables evacuation and rescue in a short time by sending drawings or web images including the entry location (evacuation direction) through SMS text or application push function.

In addition, another technical task to be achieved by the present invention is to present a sensor integrated operation IoT platform system that implements the Internet of Things (IoT) with a smart phone drawing transmission system using an existing sensor.

In addition, another technical task to be achieved by the present invention is, the existing various sensors (gas sensor, oxygen sensor, ammonia sensor, inclination sensor, crack sensor, temperature sensor, humidity sensor, fire detector, etc.) or sensor monitor (monitoring device) ), the purpose is to present a sensor integrated operation IoT platform system that can transmit and manage data to a server in real time using various communication methods such as wired and wireless methods.

In addition, another technical task to be achieved by the present invention is to provide a sensor integrated operation IoT platform system that can register, manage, and control the installation location guide map of various sensors and monitors that have been installed in the past.

In addition, another technical task to be achieved by the present invention is to provide a sensor integrated operation IoT platform system that automatically transmits a control page or message when a risk occurs so that a rapid response and lifesaving are made.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

As a means for solving the above technical problem, the sensor integrated operation IoT platform system according to the present invention is installed inside and/or outside a building to detect fire, earthquake, building collapse and gas leakage, and a gas sensor, tilt a plurality of sensors including a sensor, a crack sensor, a temperature and humidity sensor, and a fire detector; A plurality of sensor monitors that detect a disaster by the digital data or signal collected from the sensor, turn on an alarm lamp, generate an alarm sound, and transmit the signal or data received from the sensor to the platform server in real time through a wired or wireless communication network Wow; When a warning signal and numerical data are received from the plurality of sensor monitors, the web address of the drawing route including the location of the sensor, sensor monitor, emergency exit, and evacuation direction to the contact registered in the system through SMS text, email, and application push function Transmit at least one or more, guide safety rules, response methods, suppression methods, and emergency phone numbers, register drawings or web images and installation information for each sensor and sensor monitor, and register the sensor and sensor monitor in the drawing or web image includes an image of, and includes the management number, facility name, last event occurrence date, address, and installation date of the sensor and sensor monitor in the installation information, and includes a drawing or web image, a contact information to transmit installation information when a disaster is detected, and the a platform server for registering a mobile phone number in advance; It is installed and operated on the platform server and accesses the main page through login, and through the menu on the main page, the device name, device number, sensor type, target facility, installation location, installation date, and installation location of the sensor and sensor monitor Name, boundary area name, signal location, emergency exit location, evacuation direction, registration date, receiver number, sensor and sensor monitor specifications, text recipient contact information, SMS sending cycle time in case of disaster, and location and area where the sensor is installed It is displayed as a drawing or web image of the inside of the building for each location, and the type, ID, installation location, last warning time, and status check of the sensor installed in each category area are output on the screen, and the sensor detection history of the sensor installed in each category area is displayed. a home page of the sensor integrated operation IoT platform that displays the measured values of the sensor on the screen; Log in to the home page of the sensor integrated operation IoT platform and register drawings or web images of the inside of the building for each location of the sensor and sensor monitor, and register the management number, facility name, last event occurrence date, address, and installation date in the installation information. and a customer PC for modifying and registering the name of the boundary area, the location of the emergency exit, and the evacuation direction in the drawing or web image; And when receiving one or more of SMS text, e-mail, and application push function including drawing path from the platform server and clicking the drawing path, the drawing or web image corresponding to the sensor and sensor monitor registered in the customer PC is displayed on the screen In the sensor integrated operation IoT platform system comprising an output mobile phone, the sensor converts digital signal data and analog signals that detect fire, earthquake, building collapse, and gas leakage into digital data together with a unique identification number to be wired or to the sensor monitor via wireless; The sensor monitor displays a signal or measurement value received from the sensor in real time on the screen, receives the measurement value from the sensor, and inputs a setting value for detecting an abnormal signal; a test button for checking and a reset button for returning the device to an initial state; And when the sensor is a tilt sensor, the homepage of the sensor integrated operation IoT platform sets the X-axis and Y-axis tilt to determine the range of safety diagnosis or disaster detection from the measured values of the X-axis and Y-axis tilt of the structure or building in which the sensor is installed. accepts a value; The sensor integrated operation IoT platform system compares the X-axis and Y-axis inclination set values input through the home page of the sensor integrated operation IoT platform with the measured values of the X-axis and Y-axis inclination of the structure or building in which the sensor is installed to generate a disaster characterized by judging.
The SMS text may be configured to include a web address or an application push function of the location, date, time, drawing path, and warning signal and numerical data of the sensor and sensor monitor.
In the event of a disaster, the mobile phone touches a button on the screen of an emergency action button that provides information on situation propagation, evacuation tips, suppression method, mobile equipment, and pedestrian safety, and an emergency phone number button that connects a call to the person in charge of the disaster or the 119 center can be provided as

delete

delete

delete

delete

delete

delete

According to the present invention, the location, emergency exit location, entry location (evacuation direction), etc. registered in the corresponding sensor and monitor as registered contact information in case of disaster notification by utilizing signals or data of the existing sensor or sensor monitor (monitoring device) are included. By sending a drawing or web image to an SMS text message or an application push function, it is possible to quickly respond to an accident.

In addition, through communication between the existing sensor and monitor and the platform server, it is possible to help prevent accidents by sending drawings to pre-registered users with SMS text or e-mail push function.

Through communication between the existing sensors and monitors and the platform server, drawings can be sent to pre-registered users via SMS text message, e-mail, or push function to help in the initial suppression of disasters.

In addition, it can be easily introduced at a low cost by using an existing sensor without purchasing or reinstalling a separate sensor.

In addition, if you click the URL received via SMS, it is possible to respond urgently by guiding drawings, measures and emergency guides to the location of the corresponding sensor and monitor.

In addition, it is possible to register, manage, and control the installation location guide map of sensors and monitors that have been installed previously, to easily check safety rules and emergency phone connections, and to reduce accident damage by preventing accidents in advance.

In addition, when a warning message is transmitted to the safety officer, fire station, or police station in case of a disaster, information including the location of the disaster, the location of the emergency exit, and the internal structure of the building is transmitted together, so that more rapid disaster suppression and lifesaving can be achieved. there is.

In addition, it is possible to occupy a leading position in Korea and abroad by preoccupying the development of an intelligent and unmanned disaster prevention platform.

In addition, it can be applied to the site immediately in line with the trend of building enlargement, intelligence, and automation, contributing to the enhancement of technology and market competitiveness in the disaster prevention industry.

In addition, when a disaster occurs, it is possible to quickly and accurately know the start point of the disaster, so that it is possible to suppress the initial disaster by linking the unmanned control system and valve installed in the building.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a block diagram of a sensor integrated operation IoT platform system according to the present invention;
2 is an internal network configuration diagram of a sensor integrated operation IoT platform system according to the present invention;
3 is a configuration diagram showing an example of a sensor integrated operation IoT platform system using a communication network such as an IoT hub and IoT communication, Wi-Fi, Bluetooth, and a wired network according to the present invention;
4 is a product photograph showing an example of a sensor monitor used in the present invention;
5 is a photograph showing the installation state of the crack sensor and the inclination sensor according to the present invention;
6 is a view showing a disaster facility registration screen on the web screen of the platform
7 is a view showing the input screen of the SNS reception period, the X-axis and Y-axis setting values of the tilt sensor, and the tilt correction value when an abnormality occurs on the web screen of the platform
8 is a view showing the X-axis and Y-axis setting values, calibration values, sensor measurement values, temperature, humidity, and remaining battery capacity of the inclination sensor as the measurement year, month, day, and time on the web screen of the platform
9 is a view showing a screen for receiving an SMS text including a sensor value and a drawing path to a mobile phone of a registered contact
10 and 11 are screen examples of the sensor integrated operation IoT platform implemented on the screen of the mobile phone when the drawing path of the SMS text is clicked.
12 is a screen example of disaster situation propagation, evacuation tips, suppression method, and mobile equipment / pedestrian safety implemented on the screen of the mobile phone when 'emergency action tips' is selected on the screen of the sensor integrated operation IoT platform
13 to 17 are screens showing examples of application of the gas sensor control system using the sensor integrated operation IoT platform system according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the description of the invention.

Hereinafter, specific technical contents to be practiced in the present invention will be described in detail with reference to the accompanying drawings.

Example of sensor integrated operation IoT platform system

1 is a configuration diagram of a sensor integrated operation IoT platform system according to an embodiment of the present invention, FIG. 2 is a configuration diagram of an internal network of a sensor integrated operation IoT platform system according to the present invention, and FIG. 3 is an IoT hub according to the present invention It is a configuration diagram showing an example of a sensor integrated operation IoT platform system using communication networks such as and IoT communication, Wi-Fi, Bluetooth, and wired networks. 4 is a product photograph showing an example of the sensor monitor used in the present invention, and FIG. 5 is a photograph showing the installation of the crack sensor and the inclination sensor according to the present invention. 6 is a view showing a disaster facility registration screen on the web screen of the platform, and FIG. 7 is an input screen of the SNS reception cycle, the X-axis and Y-axis setting values of the tilt sensor, and the tilt correction value when an abnormality occurs on the web screen of the platform. 8 is a diagram showing the X-axis and Y-axis setting values, calibration values, sensor measurement values, temperature, humidity, and remaining battery capacity of the inclination sensor in the web screen of the platform as the measurement year, month, day, and time. 9 is a view showing a screen for receiving an SMS text including a sensor value and a drawing path to a mobile phone of a registered contact, and FIGS. 10 and 11 are a sensor integration implemented on the screen of the mobile phone when the drawing path of the SMS text is clicked. This is an example of a screen of an operating IoT platform.

As shown in FIG. 1, the sensor integrated operation IoT platform of the present invention can be configured to include a sensor 100, a sensor monitor 200, a platform server 300, a customer PC 400, and a mobile phone 500 there is.

The sensor 100 may be installed inside and/or outside a structure or building, and may be configured to detect an abnormal value at a place where the sensor is installed to generate a warning signal.

The sensor 100 may be configured to include an existing sensor installed in a structure or building. For example, the sensor 100 may include a gas sensor, an oxygen sensor, an ammonia sensor, a tilt sensor, a crack sensor, a temperature sensor, and a humidity sensor. (humidity sensor), it may be configured to include a fire detector.

Alternatively, it may be configured to include at least one or more of these sensors 100 . In the present invention, it is preferable to include a gas sensor, a tilt sensor, a crack sensor, a temperature and humidity sensor, and a fire detector to prepare for various disasters such as fire, earthquake, building collapse accident, and gas leak accident.

The gas sensor is a sensor for detecting gas, and after measuring a gas component, a sensor that transmits a signal according to the amount of a specific gas component contained in the gas in order to control the device or send an alarm according to the result am.

The oxygen sensor is a sensor for measuring the partial pressure of oxygen (O ₂ ) in a gas, and may measure oxygen using zirconia, an electromechanical (or galvanic), infrared, ultrasonic wave, laser, or the like.

The ammonia sensor is a sensor for measuring ammonia concentration and may be used to measure industrial environmental pollution such as factory wastewater.

The inclination sensor is a sensor that detects the inclination and change in inclination of the structure and converts it into a measurable signal, also called an inclinometer.

The crack sensor is a sensor that detects cracks occurring in walls, floors, ceilings, pillars, etc. of buildings and converts them into measurable signals.

The temperature sensor is a sensor that detects a temperature change and converts it into a measurable signal.

The humidity sensor is a sensor that electrically detects humidity by using the property that the resistance value and dielectric constant of organic polymers or ceramics change due to water vapor in the air, and measures the amount of water vapor in the air.

The fire detector is a sensor for detecting the occurrence of a fire by heat and/or smoke, and a fire detector (or temperature sensor) for detecting a fire by detecting heat, a smoke detector for alerting a fire by detecting smoke, and smoke; It includes both smart fire detectors that simultaneously detect and temperature (heat).

The sensor 100 generates a warning signal by detecting an abnormal value at a location where the sensor is installed. The sensor 100 has its own identification number (ID), and transmits the warning signal and numerical data by wire or wirelessly. When transmitting the warning signal and numerical data, its own identification number (ID) By transmitting it together, it informs its location information. A plurality of the sensors 100 may be installed inside and outside the building.

The sensor monitor 200 is a monitoring device that collects the signal or data of the sensor 100 and transmits it to the platform server 300 in real time through a wired or wireless communication network. The sensor monitor 200 displays the signal or measurement value received from the sensor 100 on a screen in real time, and enables wired and/or wireless communication with the sensor 100 .

In addition, the sensor monitor 200 may be configured to turn on an alarm lamp and generate an alarm sound when a disaster is detected by a signal or data of the sensor 100 at all times.

For reference, FIG. 4 is a photograph showing an example of a product of the sensor monitor 200 , and shows a sensor monitor for monitoring oxygen (O ₂ ) gas.

Referring to FIG. 4 , the sensor monitor 200 displays the measured value of oxygen (O ₂ ) gas detected from the sensor of the gas detector on the screen (numerical instrument panel) in real time, and displays a set value input button and a reset button , a test (TEST) button is provided, and an alarm lamp (or alarm lamp) that turns on when a disaster is detected and a speaker that sounds an alarm are provided.

Here, the set value input button is a button for receiving a measurement value from the sensor 100 and inputting a set value for detecting an abnormal signal (disaster). For example, when the measured value of the sensor 100 exceeds the set value, it is determined that a disaster has occurred and an alarm lamp (or an alarm lamp) and an alarm sound are activated. The test (TEST) button is a button for testing the operation of the sensor monitor 200 and checks whether there is an abnormal operation. And, the reset (RESET) button is an operation initialization button to return the data processing device to the initial state.

The wired and/or wireless communication may be configured to include Internet communication, LPWAN (Low-power wide area network; low-power long-distance communication technology), NB-IoT (Narrowband Internet of Things), and LoRa communication (Fig. see 3).

Here, the Internet of Things (IoT) refers to intelligent technologies and services that connect all things based on the Internet to mutually communicate information between people and things and between things and things.

The IoT devices do not require large amounts of data and use low-power wide area networks (LPWANs; 'low-power long-distance communication technology') because they do not require large amounts of data and require less power consumption and a wider data connection range for users to conveniently use them. LPWAN also has the advantage of having a battery life of several years.

The communication that grafted such LPWAN is NB-IoT (Narrowband Internet of Things) and LoRa. Here, LoRa is a Low Power Wide Area (LPWA) technology that helps objects to communicate with each other. Compared to other communication networks, it can communicate over long distances with less power, so it is also called as an Internet of Things (IoT) dedicated network (see FIG. 3 ).

The NB-IoT and LoRa have less restrictions in a wide space in that they have an LPWAN with long-distance characteristics, and have a range of 10 to 15 km. NB-IoT, suitable for tracking, has the technology to last for years with a single battery.

In addition, the biggest advantage is that it is possible to build a network with an existing base station without the need to build an additional base station at a low price. That is, the service is possible through the existing LTE network. This can also solve the security problem and can be used in the future 5G system.

The NB-IoT (Narrowband Internet of Things) is a 3GPP standard and is used as a licensed band frequency. In addition, it is a network suitable for a small amount of data that can be processed in real time.

Continuing to describe with reference to FIG. 1 , the platform server 300 is a server of a company that operates and manages the sensor integrated operation IoT platform, and the sensor 100 and the sensor monitor through communication networks 10 to 30 . 200 , the customer PC 400 , and the mobile phone 500 are connected.

The platform server 300 receives a warning signal and numerical data from the sensor 100 and the sensor monitor 200 through the communication network 10 . In this case, the communication network 10 may be configured using a wired/wireless communication network, an Internet communication network, a mobile communication network, a LoRa communication network, and the like (see FIGS. 1 to 3 ).

In the platform server 300 , drawings or web images and installation information are registered for each sensor 100 and sensor monitor 200 . The drawings or web images include images of the sensor 100 and the sensor monitor 200, and the installation information includes the management number, facility name, last event occurrence date, and address of the sensor 100 and sensor monitor 200. , installation date, etc. are included, and when a disaster is detected, the drawing or web image, contact information to transmit installation information, and the number of the mobile phone 500 are registered in advance.

When the platform server 300 receives a warning signal and numerical data detected from the sensor 100 and the sensor monitor 200, the sensor 100 and / Alternatively, the drawing path (web address) and installation information registered in the sensor monitor 200 are transmitted at least one of an SMS text message, an email, and an application push function (see FIG. 9 ). And, through the screen of the drawing route (web address), safety rules, response methods, and emergency phone numbers are provided.

Here, the SMS text includes a web address of the location, date, time, and drawing path of the warning signal and numerical data or an application push function (refer to FIG. 9).

The platform server 300 operates and manages the home page of the sensor integrated operation IoT platform. In this case, the homepage may be operated through a separate web server and DB server (see FIG. 2 ).

The home page of the sensor integrated operating IoT platform is installed and operated on the platform server 300, and is configured so that a customer or administrator accesses the main page through login.

The home page of the sensor integrated operation IoT platform is configured to register the device name, device number, sensor type, target facility, installation location, installation date, etc. of the sensor 100 and monitor 200 through the menu of the main page can be (see FIG. 6). And, through the menu of the main page, the name of the place where the sensor 100 and the sensor monitor 200 are installed, the name of the boundary area, the signal generation location, the emergency exit location, the evacuation direction, the registration date, the receiver number, the sensor 100 and The type and specification of the sensor monitor 200, the calibration values of the inclination X and Y axes, the notification reference values of the inclination X and Y axes, the contact information of the text recipient, and the SMS sending cycle time in case of a disaster are registered.

When the sensor is a tilt sensor, the X-axis and Y-axis inclination values obtained by measuring the X-axis and Y-axis inclination of a structure or building in which the inclination sensor is installed. Alternatively, the calibration value may be input by a system administrator as an arbitrary value.

The notification reference value may be a value that determines a safety diagnosis or a detection range of a disaster from the calibration value.

For example, if the slope X-axis value of the calibration value is 0.00, the slope Y-axis value is 0.00, the set value of the slope X-axis of the notification reference value is 0.10, and the set value of the slope Y-axis is 0.10, the X-axis of the inclination sensor and when the actual measured value on the Y-axis exceeds the set values of the X-axis and Y-axis of the notification reference value based on the calibration value, it is determined that a disaster has occurred and a disaster alarm and alarm are generated.

For example, referring to FIG. 7 , the reference values (calibration values) of the X-axis and Y-axis sensors of the inclination sensor are -3.82, -0.53, and the X-axis and Y-axis disaster detection setting values of the inclination sensor are If it is 0.10 or 0.10, when the X-axis and Y-axis measurement values of the inclination sensor exceed the disaster detection set value based on the reference value (calibration value) of the sensor, it is determined that a disaster has occurred.

Accordingly, the calibration value is a reference value for determining the magnitude of the measured value of the inclination sensor, and the alarm reference value is a value for determining a disaster detection range from the calibration value.

Although the inclination sensor has been described as an example, the crack sensor can also detect the occurrence of a safety diagnosis and disaster by setting a calibration value and a notification reference value like the inclination sensor to detect the occurrence of cracks in a building.

The home page of the sensor integrated operation IoT platform outputs the reference value, the set value, and the measured value of the sensor 100 on the screen for each installation location and area of the sensor 100, and the sensor 100 and the sensor monitor 200 ), real-time detection status and history, real-time control status of the sensor 100 and sensor monitor 200, real-time access status history for each place and area where the sensor 100 and sensor monitor 200 are installed on the screen in real time It can be configured to output, monitor and manage.

Subsequently, the customer PC 400 logs in to the homepage of the sensor integrated operation IoT platform, registers drawings or web images of the inside of the building for each location of the sensor 100 and sensor monitor 200, and manages the installation information Register and edit the number, facility name, date of event occurrence, address, and installation date.

The customer PC 400 accesses the main page by logging in to the home page of the sensor integrated operation IoT platform, and through the menu of the main page, the management number of the sensor 100 and the sensor monitor 200, the facility name, Register and edit the last event occurrence date, address, and installation date.

The mobile phone 500 is the contact information of the text receiver registered in the customer PC 400, and receives one or more of an SMS text message including a drawing path and installation information from the platform server 300, an email, and an application push function. (See Fig. 9). At this time, if you click the drawing path included in the SMS text, email, and application push function, the drawing or web image and installation information corresponding to the sensor 100 and sensor monitor 200 registered in the customer PC 400 are displayed on the screen. is output to (see FIGS. 10 and 11).

On the drawing or web image screen output on the screen of the mobile phone 500, an 'emergency action tip' button that guides the situation dissemination, evacuation tips, suppression method, mobile equipment / pedestrian safety in case of a disaster, and a disaster person in charge or 119 center It includes an 'emergency phone number' button to connect a call to the back by a touch method (refer to FIG. 10).

12 is an example of a screen for disaster situation propagation, evacuation tips, suppression method, and mobile equipment / pedestrian safety implemented on the screen of the mobile phone when 'emergency action tips' is selected on the screen of the sensor integrated operation IoT platform (FIG. 10) .

According to the present invention, IoT technology is grafted by utilizing existing sensors, and a disaster signal is detected through communication between the sensor and monitor and the platform server, and drawings are made in advance for each sensor and monitor on the platform server, and the corresponding sensor and monitor When the disaster alarm of This makes it possible to quickly spread the emergency situation, and it is convenient to respond by guiding how to deal with the situation in addition to the drawings.

Application example of gas detector control system

13 to 17 are screens showing examples of application of the gas sensor control system using the sensor integrated operation IoT platform system according to the present invention.

Referring to FIG. 13 , the gas sensor control system may be configured to log in by inputting an ID and password to a homepage.

Referring to FIG. 14 , on the main platform screen of the gas sensor control system, the places and areas where the sensors (or detectors) are installed are displayed as drawings or web images of the inside of the building for each location. And, the sensor real-time status, sensor detection history, sensor control, access status, and logout menu are configured.

15 is an output screen when the 'Detector Real-Time Status' menu is selected on the platform main screen of FIG. 14, and the type, ID, installation location, last warning time, and status check (normal) of the detector (or sensor) installed by category and area , caution, etc.) are displayed on the screen.

16 is an output screen when the 'sensor detection history' menu is selected on the platform main screen of FIG. 14, and shows the sensor detection history of the detectors (or sensors) installed in each category area.

The sensor detection history screen (FIG. 16) includes a search period, status (normal, detected, etc.), and a search window, and is configured to search by category (all view, normal, detected, etc.). The output screen of the sensor detection history includes affiliation, name, direct number, contact information, entry gate, entry time, exit gate, departure time, status check, and exit processing. Here, for the status check, if you do not check out after entering the room, the check-in time is displayed, and if you check out, the check-out is displayed.

FIG. 17 is an output screen when a 'sensor control' menu is selected on the main platform screen of FIG. 14, and a sensor measurement value of a place where a detector (or sensor) is installed is displayed on the screen. 17 shows the measured values of the oxygen sensor and the hydrogen sensor installed for each zone.

As described above, the sensor integrated operation IoT platform according to the present invention utilizes the existing sensors and monitors to register the corresponding management number, facility name, last event date, and address registered to the sensor and monitor as a registration contact for disaster notification. By sending installation information, drawings, or web images including , installation date, etc., via SMS text or application push function, so that an accident can be quickly dealt with, the technical problem of the present invention can be solved.

Preferred embodiments of the present invention described above are disclosed in order to solve the technical problems, and those of ordinary skill in the art to which the present invention pertains may make various modifications, changes, additions, etc. within the spirit and scope of the present invention. This will be possible, and such modifications and changes should be regarded as belonging to the following claims.

10, 20, 30: communication network
100: sensor
200: monitor
300 : platform server
400 : Customer PC
500: mobile phone

Claims (5)

a plurality of sensors installed inside and/or outside the building to detect fire, earthquake, building collapse and gas leakage, and including a gas sensor, a tilt sensor, a crack sensor, a temperature and humidity sensor, and a fire detector; A plurality of sensor monitors that detect a disaster by the digital data or signal collected from the sensor, turn on an alarm lamp, generate an alarm sound, and transmit the signal or data received from the sensor to the platform server in real time through a wired or wireless communication network Wow; When a warning signal and numerical data are received from the plurality of sensor monitors, the web address of the drawing route including the location of the sensor, sensor monitor, emergency exit, and evacuation direction to the contact registered in the system through SMS text, email, and application push function Transmit at least one or more, guide safety rules, response methods, suppression methods, and emergency phone numbers, register drawings or web images and installation information for each sensor and sensor monitor, and register the sensor and sensor monitor in the drawing or web image includes an image of, in the installation information, the management number of the sensor and sensor monitor, the facility name, the date of the last event, the address, and the installation date, and includes a drawing or web image when a disaster is detected, a contact information to transmit installation information, and a mobile phone number a platform server for registering phone numbers in advance; It is installed and operated on the platform server and accesses the main page through login, and through the menu of the main page, the device name, device number, sensor type, target facility, installation location, installation date, and installation location of the sensor and sensor monitor Name, boundary area name, signal location, emergency exit location, evacuation direction, registration date, receiver number, sensor and sensor monitor specifications, text recipient contact information, SMS sending cycle time in case of disaster, and location and area where the sensor is installed It is displayed as a drawing or web image of the inside of the building for each location, and the type, ID, installation location, last warning time, and status check of the sensor installed in each category area are output on the screen, and the sensor detection history of the sensor installed in each category area is displayed. a home page of the sensor integrated operation IoT platform that displays the measured values of the sensor on the screen; Log in to the home page of the sensor integrated operation IoT platform and register drawings or web images of the inside of the building for each location of the sensor and sensor monitor, and register the management number, facility name, last event occurrence date, address, and installation date in the installation information. and a customer PC for modifying and registering the name of the boundary area, the location of the emergency exit, and the evacuation direction in the drawing or web image; And when receiving one or more of SMS text, e-mail, and application push function including drawing path from the platform server and clicking the drawing path, the drawing or web image corresponding to the sensor and sensor monitor registered in the customer PC is displayed on the screen In the sensor integrated operation IoT platform system comprising a mobile phone output,
The sensor converts digital signal data and analog signals that detect fire, earthquake, building collapse and gas leakage into digital data together with a unique identification number and transmits it to the sensor monitor through wire or wireless;
The sensor monitor displays a signal or measurement value received from the sensor in real time on a screen, receives the measurement value from the sensor and inputs a setting value for detecting an abnormal signal, and a setting value input button for detecting abnormal signals; a test button for checking and a reset button for returning the device to an initial state;
When the sensor is a tilt sensor, the home page of the sensor integrated operation IoT platform sets the X-axis and Y-axis inclination setting values that determine the range of safety diagnosis or disaster detection from the measured values of the X-axis and Y-axis inclination of a structure or building in which the sensor is installed. is input; and
The sensor integrated operation IoT platform system compares the X-axis and Y-axis inclination set values input through the home page of the sensor integrated operation IoT platform and the measured values of the X-axis and Y-axis inclination of the structure or building in which the sensor is installed to generate a disaster to judge,
Sensor integrated operation IoT platform system.
delete delete The method according to claim 1,
The SMS text is
Containing a web address or application push function of the location, date, time, drawing path of the warning signal and numerical data of the sensor and sensor monitor,
Sensor integrated operation IoT platform system.
The method according to claim 1,
The mobile phone is
In the event of a disaster, an emergency action button that provides information on situation propagation, evacuation tips, suppression methods, mobile equipment, and pedestrian safety, and an emergency phone number button that connects to the person in charge of the disaster or the 119 center, are provided on the screen in a touch method.
Sensor integrated operation IoT platform system.

Images